measurement and instrumentation
MEASUREMENT
AND INSTRUMENTATION
FLS
The FLS Measurement and Instrumentation line consists of a
comprehensive range of Flow, pH, ORP, Conductivity Sensors,
Monitors and Transmitters.
INDEX
SYSTEM SELECTION GUIDE..................................................................................... 3
APPLICATIONS TABLE..............................................................................................4
FLS PRODUCTS COMPATIBILITY CHART.............................................................6
1. MONITORS FOR FLOW, pH/ORP, CONDUCTIVITY MEASUREMENT
AND CONTROL
Main Features.......................................................................................................10
FLS M9.02 Flow Monitor & Transmitter.................................................................12
FLS M9.00 2-Wires Flow Monitor & Transmitter....................................................15
FLS M9.20 Battery Powered Flow Monitor............................................................18
FLS M9.50 Batch Controller..................................................................................21
FLS M9.05 Conductivity Monitor & Transmitter.....................................................24
FLS M9.06 pH/ORP Monitor & Transmitter...........................................................27
FLS M9.07 Dual-Parameter Conductivity and Flow Monitor & Transmitter........... 30
FLS M9.10 Dual-Parameter Analog Monitor & Transmitter...................................33
2. INSERTION PADDLEWHEEL, TURBINE AND ELECTROMAGNETIC FLOW SENSORS
FLS F3.00 Paddlewheel Flow Sensor...................................................................36
FLS F3.20 High Pressure Paddlewheel Flow Sensor...........................................43
FLS F6.30 Paddlewheel Flow Transmitter.............................................................46
FLS F3.10 Paddlewheel Mini Flow Sensor............................................................50
FLS F3.05 Paddlewheel Flow Switch....................................................................53
FLS F6.60 Magmeter Flow Sensor........................................................................57
FLS F6.61 Hot Tap Magmeter Flow Sensor..........................................................60
FLS F111 Hot Tap Paddlewheel & Turbine Flow Sensors.....................................63
Installation & Operating Guidelines for Insertion Flow Sensors................................67
3. IN LINE ULTRA LOW FLOW AND OVAL GEAR SENSORS
FLS ULF Ultra Low Flow Sensor...........................................................................72
FLS F3.80 Oval Gear Flow Sensor.......................................................................76
Installation & Operating Guidelines for In line Flow Sensors....................................81
4. BULB AND FLAT pH/ORP ELECTRODES WITH EPOXY, PVC-C, RYTON
OR GLASS BODY
FLS pH/ORP 200 Epoxy body Bulb Electrode......................................................84
FLS pH/ORP 400 Glass body Bulb Electrode.......................................................87
FLS pH/ORP 600 PVC-C body Flat Surface Electrode.........................................90
FLS pH 800 Ryton Body Flat Surface Electrode...................................................95
Installation & Operating Guidelines for pH/ORP Electrodes......................................99
5. POTENTIOMETRIC AND INDUCTIVE CONDUCTIVITY SENSORS
FLS C150-200 Graphite or Platinum Conductivity Sensor..................................100
FLS C100-300 Stainless Steel Conductivity Sensor...........................................103
FLS C6.30 Inductive Conductivity Transmitter....................................................106
Installation & Operating Guidelines for Conductivity Sensors................................. 110
6. INSTALLATION FITTINGS FOR FLOW SENSORS
AND ANALYTICAL ELECTRODES
Standard Insertion Installation............................................................................. 113
Hot Tap Insertion Installation................................................................................129
Specific adapters for Analytical Electrodes Installation........................................131
7. SPARE PARTS AND ACCESSORIES FOR MONITORS,
FLOW SENSORS AND ANALYTICAL ELECTRODES
Spare Parts..........................................................................................................135
Accessories.........................................................................................................139
8. TECHNICAL INFORMATION
Flow measurement..............................................................................................143
Analytical measurement......................................................................................150
The data given in this leaflet are offered in good faith. No liability can be accepted concerning technical data
that are not directly covered by recognized international standards. FIP-FLS reserves the right to carry out any
modification to the products shown in this Ieaflet.
Installation and maintenance operations should be made by professionals.
SYSTEM SELECTION GUIDE
HOW TO CHOOSE THE MEASURING SYSTEM
The present section gives suggestions to select the proper instruments according to your
specific liquids and applications.
1
DEFINE THE WORKING CONDITIONS
Clarifying the following data is critical to make the proper system choices and to get
the best performances.
- Type of measurement
- Range of measurement
- Pipe material, size and standard
- Media (for chemical compatibility evaluation)
- Temperature & Pressure required
- Performances required
- Presence of solids
- Liquid viscosity
2
CHOOSE THE SENSOR TECHNOLOGY
Looking at the Application Table is possible to determine which sensor family can be
applied to your specific process. In case you are interested to deepen, you can also
refer to the Technical Information section for additional information.
3
CHOOSE THE INSTRUMENT
Look at the FLS Products Compatibility Chart for an overview of all the possible
sensor-monitor-transmitter combinations. Different input/output options, different
visualization options and different installation options are available to perfectly fit
your process needs.
4
DEFINE THE INSTALLATION CONDITIONS
The last step is related to the process connection: a wide range of fittings and
accessories is available for the installation on different pipe sizes and materials as
well as for hot tap or submersible installations.
APPLICATIONS TABLE
PRODUCT SELECTION GUIDE BY LIQUID/OPERATIVE CONDITIONS
FLS Insertion Paddlewheel and Electromagnetic Flow Sensors
F3.00
F3.20
F6.30
F3.10
F3.05
F6.60
F111
F6.61
clean liquid
1
1
1
1
1
1
1
1
dirty liquid
3
3
3
3
3
1
3
1
low viscous liquid
2
2
2
3
2
2
2
2
high viscous liquid
3
3
3
3
2
3
3
3
low corrosive liquid
1
1
1
2
1
1
1
1
high corrosive liquid
1
2
1
3
1
2
2
2
fibrous slurry
3
3
3
3
3
1
3
1
abrasive slurry
3
3
3
3
3
1
3
1
no conductive liquid
1
1
1
1
1
3
1
3
pulsating flow
3
3
3
3
3
3
3
3
high temperature
1
1
2
3
1
1
2
2
high pressure
2
1
2
3
2
3
2
2
big pipes
3
3
3
3
3
3
1
1
FLS In line Ultra low
Flow and Oval Gear
Sensors
FLS Bulb and Flat pH/ORP
Electrodes
pH/ORP pH/ORP pH/ORP
200
400
600
FLS Potentiometric and
Inductive Conductivity Sensors
pH
800
C150-200
C100-300
C6.30
1
1
1
1
1
3
1
1
2
1
1
2
2
2
1
2
1
1
1
3
3
3
3
3
2
1
1
1
1
1
1
1
3
2
1
high corrosive liquid
1
1
2
2
1
1
3
3
1
fibrous slurry
3
3
2
3
1
1
3
1
1
abrasive slurry
3
3
2
3
2
1
3
2
1
no conductive liquid
1
1
3
1
2
2
3
1
3
pulsating flow
3
2
1
1
1
1
1
1
1
high temperature
2
3
3
1
2
2
3
2
3
high pressure
3
3
2
1
2
2
2
2
3
big pipes
3
3
3
1
1
2
3
3
3
ULF
F3.80
clean liquid
1
1
1
1
dirty liquid
3
3
2
low viscous liquid
2
1
high viscous liquid
3
low corrosive liquid
LEGENDA
1 = Generally Suitable
2 = Worth Consideration
3 = Unsuitable
4
PRODUCT SELECTION GUIDE BY PROCESS/MARKET
FLS Insertion Paddlewheel and Electromagnetic Flow Sensors
F3.00
fertigation / agriculture
■
swimming pool &
SPAs
■
F3.20
F6.30
F3.10
F3.05
F111
F6.61
■
■
■
■
■
waste water treatment
water and pure water
treatment
F6.60
■
■
■
■
food & beverages
water distribution &
leak detection
sewage
■
■
mining slurries
■
■
dosing system
■
pump protection
HVAC & Heat
exchangers
■
■
■
detergents/disinfectant
production & dosing
metal finishing/ textile
process
■
■
FLS In line Ultra low
Flow and Oval Gear
Sensors
ULF
F3.80
FLS Bulb and Flat pH/ORP
Electrodes
pH/ORP pH/ORP pH/ORP
200
400
600
fertigation / agriculture
■
swimming pool &
SPAs
■
pH
800
FLS Potentiometric and
Inductive Conductivity Sensors
C150-200
C100-300
C6.30
■
■
■
waste water treatment
water and pure water
treatment
■
food & beverages
■
■
■
■
■
water distribution &
leak detection
sewage
■
■
■
mining slurries
■
■
■
dosing system
■
■
■
pump protection
HVAC & Heat
exchangers
detergents/disinfectant
production & dosing
metal finishing/textile
process
■
■
■
■
■
■
■
■
LEGENDA
■ = Best cost effective option
WWW.FLSNET.IT
5
FLS PRODUCTS COMPATIBILITY CHART
FLS Insertion Paddlewheel and Electromagnetic Flow Sensors compatibility
with FLS Instruments
F3.00
Paddlewheel Flow sensor
F3.20
High pressure Paddlewheel
Flow sensor
F6.30
Paddlewheel Flow
Transmitter
F3.10
Paddlewheel Mini Flow
sensor
M9.02
M9.00
M9.20
■
■
(only coil
version)
■
■
■
M9.50
M9.05
M9.06
M9.07
M9.10
■
■
■
■
■
■
■
■
■
■
■
■
■
■
■
■
■
■
■
■
■
■
■
F3.05
Paddlewheel Flow switch
F6.60
Magmeter Flow Sensor
F6.61
Hot Tap
Magmeter Flow Sensor
F111
Hot Tap Paddlewheel and
Turbine Flow sensor
■
■
■
(only coil
version)
In Line Ultra Low Flow and Oval Gear Sensors compatibility with FLS Instruments
M9.02
M9.00
ULF
Ultra Low Flow sensor
■
(only reed
version)
F3.80
Oval Gear Flow sensor
■
6
■
M9.20
■
(only reed
version)
M9.50
M9.05
M9.06
M9.07
M9.10
■
■
■
■
■
■
Bulb and Flat pH/ORP Electrodes
M9.02
M9.00
M9.20
M9.50
M9.05
M9.06
pH/ORP 200
Epoxy body Bulb electrodes
■
pH/ORP 400
Glass body Bulb electrodes
■
pH/ORP 600
PVCC Body Flat Surface
electrodes
pH 800
Ryton Body Flat
Surface electrodes
M9.07
M9.10
■
■
Potentiometric and Inductive Conductivity Sensors
M9.02
C150-200
Graphite or Platinum
Conductivity sensors
C100-300
Stainless steel Conductivity
sensors
C6.30
Inductive Conductivity
transmitter
M9.00
M9.20
M9.50
M9.05
M9.06
M9.07
■
■
■
■
M9.10
■
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7
MONITORS FOR FLOW, PH/ORP,
CONDUCTIVITY MEASUREMENT
AND CONTROL
HIGH VISIBLE SCREEN
AND QUICK CALIBRATION SYSTEM
FOR MAXIMISED PERFORMANCES
INSTRUMENTS TECHNICAL FEATURES
Single Parameter
M9.02
Flow Monitor and
Transmitter
M9.00
2-Wires Flow Monitor
and Transmitter
M9.20
Battery Powered
Flow Monitor
M9.05
Conductivity Monitor
and Transmitter
M9.06
pH/ORP Monitor
and Transmitter
Digital Outputs
Analog Outputs
Relay Outputs
Power Supply
Mounting
2 * Solid State
Relays
1 * 4-20mA
1 * mechanical
relay
24VDC/220VAC
Compact/Panel/
Wall
1 * Solid State
Relay
1 * 4-20mA
-
24VDC/220VAC
Compact/Panel/
Wall
-
-
-
-
Compact/Panel/
Wall
2 * Solid State
Relays
2 * 4-20mA
2 * mechanical
relays
24VDC/220VAC
Panel/Wall
2 * Solid State
Relays
2 * 4-20mA
2 * mechanical
relays
24VDC/220VAC
Panel/Wall
Dual Parameter
M9.07
Dual-Parameter
Conductivity and Flow
Monitor and Transmitter
M9.10
Dual-Parameter Analog
Monitor and Transmitter
10
Digital Outputs
Analog Outputs
Relay Outputs
Power Supply
Mounting
2 * Solid State
Relays
2 * 4-20mA
2 * mechanical
relays
24VDC/220VAC
Panel/Wall
2 * Solid State
Relays
2 * 4-20mA
2 * mechanical
relays
24VDC/220VAC
Panel/Wall
MONITORS
INSTALLATION AND DIMENSIONS
COMPACT MOUNTING - FOR M9.02, M9.00 AND M9.20
PANEL MOUNTING - FOR M9.02, M9.00 AND M9.20
PANEL MOUNTING - ALL MONITORS EXCEPT M9.02, M9.00 AND M9.20
WALL MOUNTING
WWW.FLSNET.IT
11
FLS M9.02
FLOW MONITOR & TRANSMITTER
APPLICATIONS
The new FLS M9.02 is a
powerful flow monitor designed
to convert the frequency signal
of FLS flow sensors into a
flow rate. M9.02 is equipped
with a wide full graphic display
4” which shows measured
values clearly and a lot of other
useful information. Moreover,
due to a multicolor display
plus a powerful backlight,
measurement status can
be determined easily from
afar also. A tutorial software
guarantees a mistake-proof
and fast set up of every
parameters. Calibration can
be performed just fixing
installation features or using a
reference value through a new
“in-line calibration”. A 4-20mA
output is available to remote
flow rate to a external device.
A proper combination of digital
outputs allows customized
setups for any process to be
controlled.
12
• Water treatment systems
• Industrial waste water treatment and recovery
• Water distribution
• Filtration systems
• Swimming pools & SPA
• Irrigation & Fertigation
• Leak detection
• Cooling water monitoring
• Processing and manufacturing industry
• Chemical production
MAIN FEATURES
• Wide full graphic display
• Multicolor backlight
• Help on board
• Installation flexibility
• Fast, intuitive and mistake-proof calibration software
• Mechanical relay for external device control
• Solid State Relays for programmable alarms
• Multilanguage menu
MONITORS
TECHNICAL DATA
General
• Associated sensors: FLS hall effect flow sensors with
frequency output or FLS F6.60 Flow sensor magmeters
• Materials:
- Case: ABS
- Display window: PC
- Panel & Wall gasket: silicone rubber
- Keypad: 5-button silicone rubber
• Display:
- LC full graphic display
- Backlight version: 3-colours
- Backlight activation: User adjustable with 5 levels of
timing
- Update rate: 1 second
- Enclosure: IP65 front
• Flow input range (frequency): 0÷1500Hz
• Flow input accuracy (frequency): 0,5%
Electrical
• Supply Voltage: 12 to 24 VDC ± 10% regulated
• FLS hall effect flow Sensor power:
- 5 VDC @ < 20 mA
- Optically isolated from current loop
- Short circuit protected
• 1 x Current output:
- 4-20 mA, isolated, fully adjustable and reversible
- Max loop impedance: 800 Ω @ 24 VDC - 250 Ω @
12 VDC
• 2 x Solid State Relay output:
- User selectable as MIN alarm, MAX alarm, Pulse
Out, Window alarm, Off
- Optically isolated, 50 mA MAX sink, 24 VDC MAX
pull-up voltage
- Max pulse/min: 300
- Hysteresis: User selectable
• 1 x Relay output:
- User selectable as MIN alarm, MAX alarm, Pulse
Out, Window alarm, Off
- Mechanical SPDT contact
- Expected mechanical life (min. operations): 107
- Expected electrical life (min. operations): 105 N.O./
N.C.switching capacity 5A/240VAC
- Max pulse/min: 60
- Hysteresis: User selectable
Environmental
• Operating temperature: -20 to +70°C (-4 to 158°F)
• Storage temperature: -30 to +80°C (-22 to 176°F)
• Relative humidity: 0 to 95% not condensing
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
WIRING CONNECTIONS
Rear Terminal View
WWW.FLSNET.IT
13
ORDERING DATA
M9.02 Flow Monitors
Description
/Name
Power
supply
Wire power
Technology
Sensor Input
Output
Weight
(gr.)
M9.02.P1
Panel mount
Flow monitor
12 - 24 VDC
3/4 wire
Flow (Frequency)
1*(4-20mA), 2*(S.S.R.), 1*(mech. relay)
500
M9.02.W1
Wall mount
Flow monitor
12 - 24 VDC
3/4 wire
Flow (Frequency)
1*(4-20mA), 2*(S.S.R.), 1*(mech. relay)
550
M9.02.W2
Wall mount
Flow monitor
110 - 230 VAC
3/4 wire
Flow (Frequency)
1*(4-20mA), 2*(S.S.R.), 1*(mech. relay)
650
Part No.
M9.02 Flow Monitors Field mount
Description
/Name
Power
supply
Wire power
Technology
Sensor Input
Output
Lenght
Main Wetted
Materials
Weight
(gr.)
M9.02.01
Field mount
Flow monitor
12 - 24
VDC
3/4 wire
Flow (Frequency)
1*(4-20mA),
2*(S.S.R.),
1*(mech. relay)
L0
PVCC/EPDM
550
M9.02.02
Field mount
Flow monitor
12 - 24
VDC
3/4 wire
Flow (Frequency)
1*(4-20mA),
2*(S.S.R.),
1*(mech. relay)
L0
PVCC/FPM
550
M9.02.03
Field mount
Flow monitor
12 - 24
VDC
3/4 wire
Flow (Frequency)
1*(4-20mA),
2*(S.S.R.),
1*(mech. relay)
L1
PVCC/EPDM
550
M9.02.04
Field mount
Flow monitor
12 - 24
VDC
3/4 wire
Flow (Frequency)
1*(4-20mA),
2*(S.S.R.),
1*(mech. relay)
L1
PVCC/FPM
550
M9.02.05
Field mount
Flow monitor
12 - 24
VDC
3/4 wire
Flow (Frequency)
1*(4-20mA),
2*(S.S.R.),
1*(mech. relay)
L0
PVDF/EPDM
550
M9.02.06
Field mount
Flow monitor
12 - 24
VDC
3/4 wire
Flow (Frequency)
1*(4-20mA),
2*(S.S.R.),
1*(mech. relay)
L0
PVDF/FPM
550
M9.02.07
Field mount
Flow monitor
12 - 24
VDC
3/4 wire
Flow (Frequency)
1*(4-20mA),
2*(S.S.R.),
1*(mech. relay)
L1
PVDF/EPDM
550
M9.02.08
Field mount
Flow monitor
12 - 24
VDC
3/4 wire
Flow (Frequency)
1*(4-20mA),
2*(S.S.R.),
1*(mech. relay)
L1
PVDF/FPM
550
M9.02.09
Field mount
Flow monitor
12 - 24
VDC
3/4 wire
Flow (Frequency)
1*(4-20mA),
2*(S.S.R.),
1*(mech. relay)
L0
SS316L/EPDM
600
M9.02.10
Field mount
Flow monitor
12 - 24
VDC
3/4 wire
Flow (Frequency)
1*(4-20mA),
2*(S.S.R.),
1*(mech. relay)
L0
SS316L/FPM
600
M9.02.11
Field mount
Flow monitor
12 - 24
VDC
3/4 wire
Flow (Frequency)
1*(4-20mA),
2*(S.S.R.),
1*(mech. relay)
L1
SS316L/EPDM
600
M9.02.12
Field mount
Flow monitor
12 - 24
VDC
3/4 wire
Flow (Frequency)
1*(4-20mA),
2*(S.S.R.),
1*(mech. relay)
L1
SS316L/FPM
600
Part No.
14
MONITORS
FLS M9.00
2-WIRES FLOW MONITOR & TRANSMITTER
APPLICATIONS
The new FLS M9.00 is a
powerful flow monitor and
transmitter based on 2-wire
technology designed to
convert the frequency signal
of FLS flow sensors into a
flow rate. M9.00 is equipped
with a wide 4” display which
shows measured values
clearly. Moreover the standard
backlight improves further the
display visibility.
The first procedure will
grant a easy set up of main
parameters. A flow rate
reference can be used for a
recalibration or a alignment
through a intuitive “in-line
calibration”. A 2 wires 4-20mA
output combined with a solid
state relay allow to remote
instant flow rate as well as an
alarm. M9.00 is equipped with
a USB port which permits a
easy updating of instrument
software by customer.
• Water treatment systems
• Industrial waste water treatment and recovery
• Water distribution
• Filtration systems
• Swimming pools & SPA
• Irrigation & Fertigation
• Leak detection
MAIN FEATURES
• Wide display
• Bright backlight
• Installation flexibility
• Solid State Relays for programmable alarms
• Multilanguage menu
• USB port for software updating
WWW.FLSNET.IT
15
TECHNICAL DATA
General
• Associated flow sensor: FLS Hall effect with
frequency output
• Materials:
- Case: ABS
- Display window: PC
- Panel & Wall gasket: silicone rubber
- Keypad: 5-button silicone rubber
• Display
- transflective technology
- backlight version: mono colour
- backlight activation: available without analog
output activation
- Update rate: 1 second
- Enclosure: IP65 front
• Flow input Range (frequency): 0.5 to 500 Hz
• Flow input accuracy: 0,5%
Electrical
• Supply Voltage: 12 to 24 VDC ± 10% regulated
• Backlight is available with power supply >= 12 VDC
• FLS hall effect flow Sensor power:
- 3,8 VDC @ < 20 mA
- Optically isolated from current loop
- Short circuit protected
• 1 x Current output (Not available with backlight ON):
- 4…20 mA, isolated, fully adjustable and reversible
- Max loop impedance: 150Ω @ 12 VDC, 600Ω @ 24 VDC
• Solid-State relay output:
- User selectable as MIN alarm, MAX alarm, Pulse Out,
Window alarm, Off
- Optically isolated, 50 mA MAX sink, 24 VAC/VDC MAX
pull-up voltage
- Max pulse/min: 300
- Hysteresis: User selectable
WIRING CONNECTIONS
Rear Terminal View
16
Environmental
• Operating temperature: -20 to +70°C (-4 to 158°F)
• Storage temperature: -30 to +80°C (-22 to 176°F)
• Relative humidity: 0 to 95% not condensing
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
MONITORS
ORDERING DATA
M9.00 2-Wires Flow Monitor and Transmitter
Description
/Name
Power
supply
Wire power
Technology
Sensor Input
Output
Weight
(gr.)
M9.00.P1
Panel mount
Flow Monitor
12 - 24 VDC
2 wire
Flow (Frequency)
1*(4-20mA),
1*(S.S.R.)
500
M9.00.W1
Wall mount
Flow Monitor
12 - 24 VDC
2 wire
Flow (Frequency)
1*(4-20mA),
1*(S.S.R.)
550
M9.00.W2
Wall mount
Flow Monitor
110 - 230 VAC
2 wire
Flow (Frequency)
1*(4-20mA),
1*(S.S.R.)
650
Part No.
M9.00 2-Wires Flow Monitor and Transmitter Field mount
Description /
Name
Power
supply
Wire power
Technology
Sensor Input
Output
Lenght
Main Wetted
Materials
Weight
(gr.)
M9.00.01
Field mount
Flow Monitor
12 - 24
VDC
2 wire
Flow (Frequency)
1*
(4-20mA),
1*(S.S.R.)
L0
PVCC/EPDM
550
M9.00.02
Field mount
Flow Monitor
12 - 24
VDC
2 wire
Flow (Frequency)
1*
(4-20mA),
1*(S.S.R.)
L0
PVCC/FPM
550
M9.00.03
Field mount
Flow Monitor
12 - 24
VDC
2 wire
Flow (Frequency)
1*
(4-20mA),
1*(S.S.R.)
L1
PVCC/EPDM
550
M9.00.04
Field mount
Flow Monitor
12 - 24
VDC
2 wire
Flow (Frequency)
1*
(4-20mA),
1*(S.S.R.)
L1
PVCC/FPM
550
M9.00.05
Field mount
Flow Monitor
12 - 24
VDC
2 wire
Flow (Frequency)
1*
(4-20mA),
1*(S.S.R.)
L0
PVDF/EPDM
550
M9.00.06
Field mount
Flow Monitor
12 - 24
VDC
2 wire
Flow (Frequency)
1*
(4-20mA),
1*(S.S.R.)
L0
PVDF/FPM
550
M9.00.07
Field mount
Flow Monitor
12 - 24
VDC
2 wire
Flow (Frequency)
1*
(4-20mA),
1*(S.S.R.)
L1
PVDF/EPDM
550
M9.00.08
Field mount
Flow Monitor
12 - 24
VDC
2 wire
Flow (Frequency)
1*
(4-20mA),
1*(S.S.R.)
L1
PVDF/FPM
550
M9.00.09
Field mount
Flow Monitor
12 - 24
VDC
2 wire
Flow (Frequency)
1*
(4-20mA),
1*(S.S.R.)
L0
SS316L/EPDM
600
M9.00.10
Field mount
Flow Monitor
12 - 24
VDC
2 wire
Flow (Frequency)
1*
(4-20mA),
1*(S.S.R.)
L0
SS316L/FPM
600
M9.00.11
Field mount
Flow Monitor
12 - 24
VDC
2 wire
Flow (Frequency)
1*
(4-20mA),
1*(S.S.R.)
L1
SS316L/EPDM
600
M9.00.12
Field mount
Flow Monitor
12 - 24
VDC
2 wire
Flow (Frequency)
1*
(4-20mA),
1*(S.S.R.)
L1
SS316L/FPM
600
Part No.
WWW.FLSNET.IT
17
FLS M9.20
BATTERY POWERED FLOW MONITOR
APPLICATIONS
The new M9.20 is a smart
battery powered flow monitor
designed to convert
the frequency signal of FLS
sensors into a flow rate.
M9.20 is equipped by a long
life lithium battery which
powers the sensor also.
A wide 4” display is used to
show measured values clearly.
A first procedure will grant
a easy set up of main
parameters. A flow rate
reference can be used for a
recalibration or a alignment
through a intuitive
“in-line calibration”.
A safe icon alerts when it’s
time to replace battery and
instrument stores all main
parameters automatically. A
customizable string allows
to tailor easily the view level.
M9.20 is equipped with a USB
port which permits an easy
update of the software by the
end users.
18
• Remote distribution system
• Mobile monitoring system
• Irrigation & Fertigation
• groundwater remediation
• swimming pool & SPA
• Liquid delivery system
MAIN FEATURES
• Wide display
• long-lasting battery
• installation flexibility
• Multilanguage menu
• No data loss at battery replacement
• USB port for software updating
MONITORS
TECHNICAL DATA
General
• Associated flow sensor: FLS Coil effect with frequency output and FLS Reed effect
• Materials:
- Case: ABS
- Display window: PC
- Panel & Wall gasket: silicone rubber
- Keypad: 5-button silicone rubber
• Display
- transflective technology
- Update rate: 1 second
- Enclosure: IP65 front
• Flow input Range (frequency): 0.5 to 500 Hz
• Flow input accuracy: 0,5%
Electrical
Supply Voltage: 3.6 volt Lithium Thionylchloride Battery, size B, 8.5 AHr 3
• Battery life: nominal 5 years
• FLS Coil effect flow Sensor power:
- 3.6 Volts
Environmental
• Operating temperature: -5 to +60°C (23 to 140°F)
• Storage temperature: -10 to +80°C (14 to 176°F)
• Relative humidity: 0 to 95% not condensing
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
WIRING CONNECTIONS
Rear Terminal View
WWW.FLSNET.IT
19
ORDERING DATA
M9.20 Battery Powered Flow Monitor
Description
/Name
Power
supply
Wire power
Technology
Sensor Input
Output
Weight
(gr.)
M9.20.P1
Panel mount
Battery Powered
Flow Monitor
Battery
Powered
-
Flow (Frequency)
-
500
M9.20.W1
Panel mount
Battery Powered
Flow Monitor
Battery
Powered
-
Flow (Frequency)
-
550
Part No.
M9.20 Field Mount Battery Powered Flow Monitor
Description /
Name
Power
supply
Wire power
Technology
Sensor Input
Output
Lenght
Main Wetted
Materials
Weight
(gr.)
M9.20.01
Field mount
Battery Powered
Flow Monitor
Battery
Powered
-
Flow
(Frequency)
-
L0
PVCC/EPDM
550
M9.20.02
Field mount
Battery Powered
Flow Monitor
Battery
Powered
-
Flow
(Frequency)
-
L0
PVCC/FPM
550
M9.20.03
Field mount
Battery Powered
Flow Monitor
Battery
Powered
-
Flow
(Frequency)
-
L1
PVCC/EPDM
550
M9.20.04
Field mount
Battery Powered
Flow Monitor
Battery
Powered
-
Flow
(Frequency)
-
L1
PVCC/FPM
550
M9.20.05
Field mount
Battery Powered
Flow Monitor
Battery
Powered
-
Flow
(Frequency)
-
L0
PVDF/EPDM
550
M9.20.06
Field mount
Battery Powered
Flow Monitor
Battery
Powered
-
Flow
(Frequency)
-
L0
PVDF/FPM
550
M9.20.07
Field mount
Battery Powered
Flow Monitor
Battery
Powered
-
Flow
(Frequency)
-
L1
PVDF/EPDM
550
M9.20.08
Field mount
Battery Powered
Flow Monitor
Battery
Powered
-
Flow
(Frequency)
-
L1
PVDF/FPM
550
M9.20.09
Field mount
Battery Powered
Flow Monitor
Battery
Powered
-
Flow
(Frequency)
-
L0
SS316L/EPDM
600
M9.20.10
Field mount
Battery Powered
Flow Monitor
Battery
Powered
-
Flow
(Frequency)
-
L0
SS316L/FPM
600
M9.20.11
Field mount
Battery Powered
Flow Monitor
Battery
Powered
-
Flow
(Frequency)
-
L1
SS316L/EPDM
600
M9.20.12
Field mount
Battery Powered
Flow Monitor
Battery
Powered
-
Flow
(Frequency)
-
L1
SS316L/FPM
600
Part No.
20
MONITORS
FLS M9.50
BATCH CONTROLLER
APPLICATIONS
The new FLS M9.50 is a
electronic device dedicated
to control accurately batching
or blending of different
liquids. A 4” wide full graphic
display shows measured
values clearly and a lot of
other useful information.
Moreover, thanking to a
multicolor display plus a
powerful backlight, batching
status can be determined
easily from afar also. A
tutorial software guarantees
a mistake-proof and fast set
up of every settings. Few
advanced options are available
to increase precision as well
as timing of batch. Possibility
of setting different volumes
(up to 10 batches) correlated
to specific calibration factors
maximizes system flexibility
guaranteeing highest level of
accuracy. A proper package of
outputs grants to control and
to monitor the batching system
remotely.
• Batch processes
• Chemical additions
• Filling processes
• Blending applications
• Dosing system
• Bottling processes
MAIN FEATURES
• Wide full graphic display
• Multicolor backlight visualization
• Help on board
• External start, stop and resume
• Intuitive batch volumes setting
• Two stage shutdown control
• Overrun compensation and alarm
• Missing signal alarm
WWW.FLSNET.IT
21
TECHNICAL DATA
General
• Associated sensors: FLS hall effect flow sensors with
frequency output or FLS F6.60 Flow sensor magmeters
• Materials:
- case: ABS
- display window: PC
- panel & wall gasket: silicone rubber
- keypad: 5-button silicone rubber
• Display:
- LC full graphic display
- backlight version: 3-colours
- backlight activation: User adjustable with 5 levels of
timing
- update rate: 1 second
- enclosure: IP65 front
• Flow input range (frequency): 0÷1500Hz
• Flow input accuracy (frequency): 0,5%
Electrical
• Supply Voltage: 12 to 24 VDC ± 10% regulated
• FLS hall effect flow Sensor power:
- 5 VDC @ < 20 mA
- Optically isolated from current loop
- Short circuit protected
• 2 x Solid State Relay output:
- Optically isolated, 50 mA MAX sink, 24 VDC MAX
pull-up voltage
- Max pulse/min: 300
- Hysteresis: user selectable
- User selectable as: Two-stage shutdown, overrun or
missing signal alarm
• 2 x Relay output:
- Mechanical SPDT contact
- Expected mechanical life (min. operations): 107
WIRING CONNECTIONS
Rear Terminal View
22
- Expected electrical life (min. operations): 105 N.O./
N.C.switching capacity
5A/240VAC
- Max pulse/min: 60
- Hysteresis: User selectable
- User selectable as:
OUT1 - Option: Two-stage shutdown, overrun or
missing signal alarm
OUT2 - Batch: Batch in progress indication
Environmental
• Operating temperature: -20 to +70°C (-4 to 158°F)
• Storage temperature: -30 to +80°C (-22 to 176°F)
• Relative humidity: 0 to 95% not condensing
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
M9.50 Batch Controllers
Description
/Name
Power
supply
Wire power
Technology
Sensor Input
Output
Weight
(gr.)
M9.50.P1
Panel
mount Batch
controller
12 - 24 VDC
-
Flow (Frequency)
2*(S.S.R.), 2*(mech. relay)
550
M9.50.W1
Wall mount
Batch
controller
12 - 24 VDC
-
Flow (Frequency)
2*(S.S.R.), 2*(mech. relay)
650
M9.50.W2
Wall mount
Batch
controller
110 - 230 VAC
-
Flow (Frequency)
2*(S.S.R.), 2*(mech. relay)
750
Part No.
WWW.FLSNET.IT
23
MONITORS
ORDERING DATA
FLS M9.05
CONDUCTIVITY MONITOR & TRANSMITTER
APPLICATIONS
The new FLS M9.05 is a
powerful conductivity monitor
and transmitter studied to fit
a broad range of applications
included ultrapure water
process. A 4” wide full graphic
display shows measured
values clearly together with
many other useful information.
Moreover, due to the
multicolor bright backlight,
measurement status can
be determined easily also
from very long distance. A
tutorial software guarantees
a mistake-proof and fast
set up of every parameter.
Measured values can be
showed as resistivity or TDS
in according with customer
needs. A cell constant freely
fixable allows to use all types
of 2-cell conductivity probe.
Two 4-20mA output grants to
remote values of conductivity
and temperature to external
devices. A proper combination
of digital outputs allows
customized setups for any
process to be controlled.
24
• Water treatment and regeneration
• Industrial waste water treatment and recovery
• Softener process
• Filtration systems
• Desalination process
• Demineralized water production
• Reverse osmosis/EDI process
• Cooling water monitoring
• Processing and manufacturing industry
• Chemical production
MAIN FEATURES
• Wide full graphic display
• Multicolor backlight visualization
• Help on board
• UPW temperature compensation
• Cell constant settable freely
• Values in conductivity, resistivity, TDS
• Analog output for temperature remoting
• Mechanical relay for external device control
• Solid State Relays for programmable alarms
General
• Associated sensors: FLS conductivity sensors and
FLS temperature sensors
• Materials:
- case: ABS
- display window: PC
- panel & wall gasket: silicone rubber
- keypad: 5-button silicone rubber
• Display:
- LC full graphic display
- backlight version: 3-colours
- backlight activation: User adjustable with 5 levels of
timing
- update rate: 1 second
- enclosure: IP65 front
• Conductivity input range: 0,055÷200000μS
• Conductivity measurement accuracy: ± 2.0 % of
reading value
• Temperature input range: -50÷150°C (-58÷302°F)
(with Pt100-Pt1000)
• Temperature measurement resolution: 0,1°C/°F
(Pt1000); 0,5°C/°F (Pt100)
Electrical
• Supply Voltage: 12 to 24 VDC ± 10% regulated
• 2 x Current output:
- 4-20 mA, isolated, fully adjustable and reversible
- max loop impedance: 800 Ω @ 24 VDC - 250 Ω @
12 VDC
• 2 x Solid State Relay output:
- user selectable as ON-OFF, Proportional frequency
output, Proportional Pulse, Timed Pulse, Off
- optically isolated, 50 mA MAX sink, 24 VDC MAX
pull-up voltage
- max pulse/min: 300
- hysteresis: User selectable
• 2 x Relay output:
- user selectable as ON-OFF, Proportional frequency
output, Proportional Pulse, Timed Pulse, Off
- mechanical SPDT contact
- expected mechanical life (min. operations): 107
- expected electrical life (min. operations): 105 N.O./
N.C.switching capacity 5A/240VAC
- max pulse/min: 60
- hysteresis: User selectable
Environmental
• Operating temperature: -20 to +70°C (-4 to 158°F)
• Storage temperature: -30 to +80°C (-22 to 176°F)
• Relative humidity: 0 to 95% not condensing
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
WIRING CONNECTIONS
Rear Terminal View
WWW.FLSNET.IT
25
MONITORS
TECHNICAL DATA
ORDERING DATA
M9.05 Conductivity Monitors and Transmitters
Description
/Name
Power
supply
Wire power
Technology
Sensor Input
Output
Weight
(gr.)
M9.05.P1
Panel mount
Conductivity
monitor
12 - 24 VDC
3/4 wire
Conductivity
2*(4-20mA), 2*(S.S.R.), 2*(mech. relay)
550
M9.05.W1
Wall mount
Conductivity
monitor
12 - 24 VDC
3/4 wire
Conductivity
2*(4-20mA), 2*(S.S.R.), 2*(mech. relay)
650
M9.05.W2
Wall mount
Conductivity
monitor
110 - 230 VAC
3/4 wire
Conductivity
2*(4-20mA), 2*(S.S.R.), 2*(mech. relay)
750
Part No.
26
MONITORS
FLS M9.06
PH/ORP MONITOR & TRANSMITTER
APPLICATIONS
The new FLS M9.06 is a
powerful pH/ORP monitor and
transmitter designed to satisfy
a broad range of applications.
A 4” wide full graphic display
shows measured values
clearly together with many
other useful information.
Moreover, due to the multicolor
bright backlight, measurement
status can be determined
easily also from very long
distance. A tutorial software
guarantees a mistake-proof
and fast set up of every
parameter. A calibration based
on automatic buffer recognition
plus a in line adjustment allow
to achieve a precise and a
reliable measurement in every
conditions. FLS M9.06 offers
a diagnostic of electrode
condition with practical
tips for maximizing probe
performances.
• Water treatment and regeneration
• Industrial waste water treatment and recovery
• Scrubber control
• Neutralization systems
• Heavy metals recovery
• Metal surface coating
• Processing and manufacturing industry
• Chemical production
• Swimming pools and SPA
MAIN FEATURES
• Wide full graphic display
• Multicolor backlight visualization
• Help on board
• Automatic recognition of pH buffers
• In line adjustment
• Analog output for temperature remoting
• Mechanical relay for external device control
• Solid State Relays for programmable alarms
WWW.FLSNET.IT
27
TECHNICAL DATA
General
• Associated sensors: FLS pH/ORP electrodes and
FLS temperature sensors
• Materials:
- Case: ABS
- Display window: PC
- Panel & Wall gasket: silicone rubber
- Keypad: 5-button silicone rubber
• Display:
- LC full graphic display
- Backlight version: 3-colours
- Backlight activation: User adjustable with 5 levels of
timing
- Update rate: 1 second
- Enclosure: IP65 front
• pH input range: -2÷16pH
• pH measurement resolution: ± 0.01 pH
• ORP input range: -2000÷ +2000mV
• ORP measurement resolution: ± 1 mV
• Temperature input range: -50÷150°C (-58÷302°F)
(with Pt100-Pt1000)
• Temperature measurement resolution: 0,1°C/°F
(Pt1000); 0,5°C/°F (Pt100)
Electrical
• Supply Voltage: 12 to 24 VDC ± 10% regulated
• 2 x Current output:
- 4-20 mA, isolated, fully adjustable and reversible
- Max loop impedance: 800 Ω @ 24 VDC - 250 Ω @
12 VDC
WIRING CONNECTIONS
Rear Terminal View
28
• 2 x Solid State Relay output:
- User selectable as ON-OFF, Proportional frequency
output, Proportional Pulse, Timed Pulse, Off
- Optically isolated, 50 mA MAX sink, 24 VDC MAX
pull-up voltage
- Max pulse/min: 300
- Hysteresis: User selectable
• 2 x Relay output:
- User selectable as ON-OFF, Proportional frequency
output, Proportional Pulse, Timed Pulse, Off
- Mechanical SPDT contact
- Expected mechanical life (min. operations): 107
- Expected electrical life (min. operations): 105 N.O./
N.C.switching capacity 5A/240VAC
- Max pulse/min: 60
- Hysteresis: User selectable
Environmental
• Operating temperature: -20 to +70°C (-4 to 158°F)
• Storage temperature: -30 to +80°C (-22 to 176°F)
• Relative humidity: 0 to 95% not condensing
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
M9.06 pH/ORP Monitor and Transmitter
Description
/Name
Power
supply
Wire power
Technology
Sensor Input
Output
Weight
(gr.)
M9.06.P1
Panel mount
pH/ORP
monitor
12 - 24 VDC
3/4 wire
pH/ORP
2*(4-20mA), 2*(S.S.R.), 2*(mech. relay)
550
M9.06.W1
Wall mount
pH/ORP
monitor
12 - 24 VDC
3/4 wire
pH/ORP
2*(4-20mA), 2*(S.S.R.), 2*(mech. relay)
650
M9.06.W2
Wall mount
pH/ORP
monitor
110 - 230 VAC
3/4 wire
pH/ORP
2*(4-20mA), 2*(S.S.R.), 2*(mech. relay)
750
Part No.
WWW.FLSNET.IT
29
MONITORS
ORDERING DATA
FLS M9.07
DUAL-PARAMETER CONDUCTIVITY
AND FLOW MONITOR & TRANSMITTER
APPLICATIONS
The new FLS M9.07 is a dual
monitor and transmitter which
combines conductivity and
flow measurements. A 4” wide
full graphic display shows
measured values clearly
together with many other
useful information. Moreover,
due to a multicolor display
plus a powerful backlight,
measurement status can
be determined easily from
afar also. A tutorial software
guarantees a mistake-proof
and fast set up of every
parameters. Different type of
calibrations can be performed
to fit user needs for both
measurements. A 4-20mA
output dedicated to each
measurement grants to remote
values to a external device. A
proper combination of digital
outputs allows customized
setups for any process to be
controlled.
30
• Water treatment and regeneration
• Industrial waste water treatment and recovery
• Softener process
• Filtration systems
• Desalination process
• Demineralized water production
• Reverse osmosis process
• Cooling water monitoring
• Processing and manufacturing industry
• Chemical production
MAIN FEATURES
• Wide full graphic display
• Multicolor backlight
• Help on board
• Simultaneous measurement of conductivity, temperature and flow
• Fast, intuitive and mistake-proof calibration software
• Mechanical relay for external device control
• Solid State Relays for programmable alarms
• Multilanguage menus
MONITORS
TECHNICAL DATA
General
• Associated sensors: FLS conductivity/temperature
sensors & FLS hall effect flow sensors or FLS F6.60
Flow sensor magmeters
• Materials:
- case: ABS
- display window: PC
- panel & wall gasket: silicone rubber
- keypad: 5-button silicone rubber
• Display:
- LC full graphic disply
- backlight version: 3-colours
- backlight activation: User adjustable with 5 levels of
timing
- update rate: 1 second
- enclosure: IP65 front
• Conductivity input range: 0,055÷200000μS
• Conductivity measurement accuracy: ± 2.0 % of
reading value
• Temperature input range: -50÷150°C (-58÷302°F)
(with Pt100-Pt1000)
• Temperature measurement resolution: 0,1°C/°F
(Pt1000); 0,5°C/°F (Pt100)
• Flow input range (frequency): 0÷1500Hz
• Flow input accuracy (frequency): 0,5%
• 2 x Solid State Relay output:
- (Flow) user selectable as MIN alarm, MAX alarm,
Pulse Out, Window alarm, Off
- (Conductivity) user selectable as ON-OFF,
Proportional frequency output, Timed Pulse, Off
- optically isolated, 50 mA MAX sink, 24 VDC MAX
pull-up voltage
- max pulse/min: 300
- hysteresis: user selectable
• 2 x Relay output:
- (Flow) user selectable as MIN alarm, MAX alarm,
Pulse Out, Window alarm, Off
- (Conductivity) user selectable as ON-OFF,
Proportional frequency output, Timed Pulse, Off
- mechanical SPDT contact
- expected mechanical life (min. operations): 107
- expected electrical life (min. operations): 105 N.O./
N.C.switching capacity 5A/240VAC
- max pulse/min: 60
- hysteresis: user selectable
Electrical
• Supply Voltage: 12 to 24 VDC ± 10% regulated
• FLS hall effect flow Sensor power:
- 5 VDC @ < 20 mA
- optically isolated from current loop
- short circuit protected
• 2 x Current output:
- 4-20 mA, isolated, fully adjustable and reversible
- max loop impedance: 800 Ω @ 24 VDC - 250 Ω @
12 VDC
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
Environmental
• Operating temperature: -20 to +70°C (-4 to 158°F)
• Storage temperature: -30 to +80°C (-22 to 176°F)
• Relative humidity: 0 to 95% not condensing
WIRING CONNECTIONS
Rear Terminal View
WWW.FLSNET.IT
31
ORDERING DATA
M9.07 Dual-Parameter Conductivity and Flow Monitor and Transmitter
Description
/Name
Power
supply
Wire power
Technology
Sensor Input
Output
Weight
(gr.)
M9.07.P1
Panel mount
Conductivity &
Flow monitor
12 - 24 VDC
3/4 wire
Conductivity,
Temperature,
Flow (Frequency)
2*(4-20mA), 2*(S.S.R.), 2*(mech. relay)
550
M9.07.W1
Wall mount
Conductivity &
Flow monitor
12 - 24 VDC
3/4 wire
Conductivity,
Temperature,
Flow (Frequency)
2*(4-20mA), 2*(S.S.R.), 2*(mech. relay)
650
M9.07.W2
Wall mount
Conductivity &
Flow monitor
110 - 230 VAC
3/4 wire
Conductivity,
Temperature,
Flow (Frequency)
2*(4-20mA), 2*(S.S.R.), 2*(mech. relay)
750
Part No.
32
MONITORS
FLS M9.10
DUAL-PARAMETER ANALOG
MONITOR & TRANSMITTER
APPLICATIONS
The new FLS M9.10 is
a powerful monitor and
transmitter designed to
manage analog and frequency
signals (or two analog signals)
from every types of device
which provide a 4-20mA or
a frequency output. M9.10
is equipped with a wide full
graphic display 4” which shows
measured values clearly and a
lot of other useful information.
Moreover, due to a multicolor
display plus a powerful
backlight, measurement status
can be determined easily from
afar also. A tutorial software
guarantees a mistake-proof
and fast set up of every
parameters. Calibration
of 4-20mA input can be
performed just fixing 2 points
as well as 1 point or using a
reference value through a new
“in-line calibration”.
Calibration of frequency input
can be performed just fixing
installation features or using a
reference value through a new
“in-line calibration”.
Two independent 4-20mA
outputs are available to remote
measures to external devices.
A proper combination of
digital outputs (2 x SSR and
2 x relays) allows customized
setups for any process to be
controlled.
• Industrial waste water treatment
• Civil waste water treatment
• Water treatment processes
• Processing and Manufacturing industry
• Chemical processing
• Industrial environment with electromagnetic interferences
MAIN FEATURES
• Wide graphic display
• Multicolor backlight
• Help on board
• Simultaneous visualization of two parameters
• Free setting of engineering unit
• Intuitive calibration procedure
• In line adjustment
• Able to handle active and passive analog signal
WWW.FLSNET.IT
33
TECHNICAL DATA
General
• Associated sensors: FLS hall effect flow sensors with
frequency output, FLS F6.60 Flow sensor magmeters
and every devices which generate a passive or active
4-20mA signal.
• Materials:
- case: ABS
- display window: PC
- panel & wall gasket: silicone rubber
- keypad: 5-button silicone rubber
• Display:
- LC full graphic display
- backlight version: 3-colours
- backlight activation: User adjustable with 5 levels of
timing
- update rate: 1 second
- enclosure: IP65 front
• Frequency input range (frequency): 0÷1000Hz
• Frequency accuracy (frequency): 0,5%
• Analog input range (frequency): 3,8÷21,0mA
• Analog input accuracy (frequency): 0,01mA
• 2 x Solid State Relay output:
- User selectable as MIN alarm, MAX alarm, Pulse Out
(only for frequency input), Window alarm, Off
- Optically isolated, 50 mA MAX sink, 24 VDC MAX
pull-up voltage
- Max pulse/min: 300
- Hysteresis: User selectable
• 2 x Relay output:
- User selectable as MIN alarm, MAX alarm, Pulse Out
(only for frequency input), Window alarm, Off
- Mechanical SPDT contact
- Expected mechanical life (min. operations): 107
- Expected electrical life (min. operations): 105 N.O./
N.C. switching capacity 5A/240VAC
- Max pulse/min: 60
- Hysteresis: User selectable
Electrical
• Supply Voltage: 12 to 24 VDC ± 10% regulated
• FLS hall effect flow Sensor power:
- 5 VDC @< 20 mA
- Optically isolated from current loop
- Short circuit protected
• 2 x Current input power:
- 18VDC @ ≤ 20mA
• 2 x Current output:
- 4-20 mA, isolated, fully adjustable and reversible
- Max loop impedance: 800 Ω @ 24 VDC - 250 Ω @
12 VDC
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
WIRING CONNECTIONS
Rear Terminal View
34
Environmental
• Operating temperature: -20 to +70°C (-4 to 158°F)
• Storage temperature: -30 to +80°C (-22 to 176°F)
• Relative humidity: 0 to 95% not condensing
M9.10 Dual-Parameter Analog Monitor and Transmitter
Part No.
M9.10.P1
M9.10.W1
M9.10.W2
Description
/Name
Power
supply
Wire power
Technology
Sensor Input
Output
Weight
(gr.)
Panel
mount Dual
Parameter
Analog
monitor &
transmitter
12 - 24 VDC
3/4 wire
2 * 4-20mA
2*(4-20mA), 2*(S.S.R.), 2*(mech. relay)
550
12 - 24 VDC
3/4 wire
2 * 4-20mA
2*(4-20mA), 2*(S.S.R.), 2*(mech. relay)
650
110 - 230 VAC
3/4 wire
2 * 4-20mA
2*(4-20mA), 2*(S.S.R.), 2*(mech. relay)
750
Wall mount
DualParameter
Analog
monitor &
transmitter
Wall mount
DualParameter
Analog
monitor &
transmitter
WWW.FLSNET.IT
35
MONITORS
ORDERING DATA
INSERTION PADDLEWHEEL,
TURBINE AND ELECTROMAGNETIC
FLOW SENSORS
INSTALLATION VERSATILITY
COMBINED TO APPLICATION
FLEXIBILITY
FLS F3.00
PADDLEWHEEL FLOW SENSOR
APPLICATIONS
The simple and reliable
paddlewheel flow sensor type
F3.00 is designed for use with
every kind of solid-free liquids.
The sensor can measure
flow from 0.15 m/s (0.5 ft/s)
producing a frequency output
signal highly repeatable.
A rugged construction and a
proven technology guarantee
exceptional performances
with little or no maintenance
required.
A dedicated electronic, with a
push-pull output, is available
for a safe connection to any
kind of PLC/Instrument digital
input.
A specially designed family of
fittings ensures an easy and
quick installation into all pipe
materials in sizes from DN15
to DN600 (0.5” to 24”).
36
• Water treatment and regeneration
• Industrial wastewater treatment and recovery
• Textile finishing
• Water distribution
• Processing and manufacturing industry
• Filtration systems
• Chemical production
• Liquid delivery systems
• Cooling water monitoring
• Heat Exchangers
• Swimming pools
• Pump protection
MAIN FEATURES
• C-PVC, PVDF or Stainless Steel sensor body
• Two sensor lenghts to cover from DN15 up to DN600
• Easy insertion system
• IP65 or IP68 protection class
• Measurement range over 50:1
• High chemical resistance
• Version for battery powered system
• Push-Pull output for universal electrical connection
TECHNICAL DATA
Specific for F3.00.H
• Supply voltage: 5 to 24 VDC ± 10% regulated
• Supply current: < 30 mA @ 24 VDC
• Output signal:
- square wave
- frequency: 45 Hz per m/s nominal
(13.7 Hz per ft/s nominal)
- type: transistor NPN open collector
- output current: 10 mA max
• Cable length: 8 m (26.4 ft) standard, 300 m (990 ft)
maximum
• Output signal:
- square wave
- frequency: 45 Hz per m/s nominal
(13.7 Hz per ft/s nominal)
- min. input impedance: 100 KΩ
• Cable length: 8 m (26.4 ft) standard, 16 m (52.8 ft)
maximum
Specific for F3.00.P
• Supply voltage: 12 to 24 VDC ± 10% regulated
• Supply current: < 30 mA @ 24 VDC
• Output signal:
- square wave
- frequency: 45 Hz per m/s nominal
(13.7 Hz per ft/s nominal)
- type: Push-Pull (for connection to NPN and PNP
inputs)
- output current: 20 mA max
• Cable length: 8 m (26.4 ft) standard, 300 m (990 ft)
maximum
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
Specific for F3.00.C
• Supply voltage: 3 to 5 VDC regulated or
3.6 Volt Lithium battery
• Supply current: < 10 µA max
Maximum Operating Pressure / Temperature (25 years lifetime)
F3.00.H or F3.00.P Sensor
• C-PVC body:
- 10 bar (145 psi) @ 25°C (77°F)
- 1,5 bar (22 psi) @ 80° C (176°F)
• PVDF body:
- 10 bar (145 psi) @ 25°C (77°F)
- 2,5 bar (36 psi) @ 100°C (212°F)
• SS body:
- 25 bar (363 psi) @ 120°C (248°F)
F3.00.C Sensor
• C-PVC body:
- 10 bar (145 psi) @ 25°C (77°F)
- 1,5 bar (22 psi) @ 80° C (176°F)
• PVDF body:
- 10 bar (145 psi) @ 25°C (77°F)
- 2,5 bar (36 psi) @ 100°C (212°F)
• SS body:
- 25 bar (363 psi) @ 100°C (212°F)
WWW.FLSNET.IT
37
INSERTION FLOW SENSORS
General
• Pipe Size Range: DN15 to DN600 (0.5” to 24”)
Please refer to Installation Fittings section for more
details
• Flow Rate Range: 0.15 to 8 m/s (0.5 to 25 ft./s)
• Linearity: ± 0.75 % of full scale
• Repeatability: ± 0.5 % of full scale
• Minimum Reynolds Number Required: 4500
• Enclosure: IP68 or IP65
• Wetted Materials:
- sensor Body: C-PVC, PVDF or 316L SS
- o-rings: EPDM or FPM
- rotor: ECTFE (Halar®)
- shaft: Ceramic (Al2O3)/316L SS (only for metal
sensors)
- bearings: Ceramic (Al2O3)
DIMENSIONS
A F3.00 IP68 Remote Sensor
B F3.00 IP65 Remote Sensor
C F3.01 Compact Sensor
D F3.01 Compact Sensor + Transmitter
(sold separately)
E Paddlewheel system
1 Electrical cable: 8 m. (26.4 ft) standard
2 4 pole cable plug according to DIN
43650-B/ISO 6952
3 UPVC cap for installation into fittings
4 O-Ring seals available in EPDM or
FPM
5 C-PVC, PVDF or Stainless Steel
sensor body
6 ECTFE Halar® (registered trademark
of Ausimont-Solvay) Open-cell rotor
7 Ceramic shaft
8 Ceramic bearings
WIRING CONNECTIONS
F3.00 IP68 Sensor wiring connection
38
F3.00 IP65 Sensor wiring connection
ORDERING DATA
F3.00.H.XX Paddlewheel Flow Sensors (Remote version)
Power
supply
Length
Main wetted
materials
Enclosure
Flow Rate Range
Weight
(gr.)
F3.00.H.01
Hall
5 - 24 VDC
L0
C-PVC/ EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.H.02
Hall
5 - 24 VDC
L0
C-PVC/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.H.03
Hall
5 - 24 VDC
L1
C-PVC/ EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.H.04
Hall
5 - 24 VDC
L1
C-PVC/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.H.05
Hall
5 - 24 VDC
L0
PVDF/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.H.06
Hall
5 - 24 VDC
L0
PVDF/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.H.07
Hall
5 - 24 VDC
L1
PVDF/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.H.08
Hall
5 - 24 VDC
L1
PVDF/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.H.09
Hall
5 - 24 VDC
L0
316SS/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.00.H.10
Hall
5 - 24 VDC
L0
316SS/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.00.H.11
Hall
5 - 24 VDC
L1
316SS/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
F3.00.H.12
Hall
5 - 24 VDC
L1
316SS/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
F3.00.H.13
Hall
5 - 24 VDC
L0
C-PVC/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.H.14
Hall
5 - 24 VDC
L0
C-PVC/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.H.15
Hall
5 - 24 VDC
L1
C-PVC/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.H.16
Hall
5 - 24 VDC
L1
C-PVC/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.H.17
Hall
5 - 24 VDC
L0
PVDF/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.H.18
Hall
5 - 24 VDC
L0
PVDF/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.H.19
Hall
5 - 24 VDC
L1
PVDF/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.H.20
Hall
5 - 24 VDC
L1
PVDF/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.H.21
Hall
5 - 24 VDC
L0
316SS/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.00.H.22
Hall
5 - 24 VDC
L0
316SS/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.00.H.23
Hall
5 - 24 VDC
L1
316SS/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
F3.00.H.24
Hall
5 - 24 VDC
L1
316SS/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
WWW.FLSNET.IT
39
INSERTION FLOW SENSORS
Version
Part No.
ORDERING DATA
F3.00.C.XX Paddlewheel Flow Sensors (Remote version)
Version
Power
supply
Length
Main wetted
materials
Enclosure
Flow Rate Range
Weight
(gr.)
F3.00.C.01
Coil
3 - 5 VDC
L0
C-PVC/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.C.02
Coil
3 - 5 VDC
L0
C-PVC/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.C.03
Coil
3 - 5 VDC
L1
C-PVC/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.C.04
Coil
3 - 5 VDC
L1
C-PVC/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.C.05
Coil
3 - 5 VDC
L0
PVDF/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.C.06
Coil
3 - 5 VDC
L0
PVDF/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.C.07
Coil
3 - 5 VDC
L1
PVDF/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.C.08
Coil
3 - 5 VDC
L1
PVDF/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.C.09
Coil
3 - 5 VDC
L0
316SS/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.00.C.10
Coil
3 - 5 VDC
L0
316SS/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.00.C.11
Coil
3 - 5 VDC
L1
316SS/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
F3.00.C.12
Coil
3 - 5 VDC
L1
316SS/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
F3.00.C.13
Coil
3 - 5 VDC
L0
C-PVC/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.C.14
Coil
3 - 5 VDC
L0
C-PVC/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.C.15
Coil
3 - 5 VDC
L1
C-PVC/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.C.16
Coil
3 - 5 VDC
L1
C-PVC/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.C.17
Coil
3 - 5 VDC
L0
PVDF/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.C.18
Coil
3 - 5 VDC
L0
PVDF/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.C.19
Coil
3 - 5 VDC
L1
PVDF/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.C.20
Coil
3 - 5 VDC
L1
PVDF/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.C.21
Coil
3 - 5 VDC
L0
316SS/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.00.C.22
Coil
3 - 5 VDC
L0
316SS/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.00.C.23
Coil
3 - 5 VDC
L1
316SS/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
F3.00.C.24
Coil
3 - 5 VDC
L1
316SS/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
Part No.
40
ORDERING DATA
F3.00.P.XX Paddlewheel Flow Sensors (for direct connection to PLC)
Power
supply
Length
Main wetted
materials
Enclosure
Flow Rate Range
Weight
(gr.)
F3.00.P.01
Push-Pull
12 - 24 VDC
L0
C-PVC/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.P.02
Push-Pull
12 - 24 VDC
L0
C-PVC/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.P.03
Push-Pull
12 - 24 VDC
L1
C-PVC/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.P.04
Push-Pull
12 - 24 VDC
L1
C-PVC/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.P.05
Push-Pull
12 - 24 VD C
L0
PVDF/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.P.06
Push-Pull
12 - 24 VDC
L0
PVDF/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.P.07
Push-Pull
12 - 24 VDC
L1
PVDF/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.P.08
Push-Pull
12 - 24 VDC
L1
PVDF/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.P.09
Push-Pull
12 - 24 VDC
L0
316SS/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.00.P.10
Push-Pull
12 - 24 VDC
L0
316SS/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.00.P.11
Push-Pull
12 - 24 VDC
L1
316SS/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
F3.00.P.12
Push-Pull
12 - 24 VDC
L1
316SS/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
F3.00.P.13
Push-Pull
12 - 24 VDC
L0
C-PVC/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.P.14
Push-Pull
12 - 24 VDC
L0
C-PVC/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.P.15
Push-Pull
12 - 24 VDC
L1
C-PVC/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.P.16
Push-Pull
12 - 24 VDC
L1
C-PVC/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.P.17
Push-Pull
12 - 24 VDC
L0
PVDF/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.P.18
Push-Pull
12 - 24 VDC
L0
PVDF/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.00.P.19
Push-Pull
12 - 24 VDC
L1
PVDF/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.P.20
Push-Pull
12 - 24 VDC
L1
PVDF/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.00.P.21
Push-Pull
12 - 24 VDC
L0
316SS/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.00.P.22
Push-Pull
12 - 24 VDC
L0
316SS/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.00.P.23
Push-Pull
12 - 24 VDC
L1
316SS/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
F3.00.P.24
Push-Pull
12 - 24 VDC
L1
316SS/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
WWW.FLSNET.IT
41
INSERTION FLOW SENSORS
Version
Part No.
ORDERING DATA
F3.01.X.XX Paddlewheel Flow Sensors (Compact version)
Version
Power
supply
Length
Main wetted
materials
Enclosure
Flow Rate Range
Weight
(gr.)
F3.01.H.01
Hall
5 - 24 VDC
L0
C-PVC/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.01.H.02
Hall
5 - 24 VDC
L0
C-PVC/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.01.H.03
Hall
5 - 24 VDC
L1
C-PVC/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.01.H.04
Hall
5 - 24 VDC
L1
C-PVC/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.01.H.05
Hall
5 - 24 VDC
L0
PVDF/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.01.H.06
Hall
5 - 24 VDC
L0
PVDF/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.01.H.07
Hall
5 - 24 VDC
L1
PVDF/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.01.H.08
Hall
5 - 24 VDC
L1
PVDF/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.01.H.09
Hall
5 - 24 VDC
L0
316SS/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.01.H.10
Hall
5 - 24 VDC
L0
316SS/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.01.H.11
Hall
5 - 24 VDC
L1
316SS/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
F3.01.H.12
Hall
5 - 24 VDC
L1
316SS/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
F3.01.C.01
Coil
3 - 5 VDC
L0
C-PVC/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.01.C.02
Coil
3 - 5 VDC
L0
C-PVC/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.01.C.03
Coil
3 - 5 VDC
L1
C-PVC/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.01.C.04
Coil
3 - 5 VDC
L1
C-PVC/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.01.C.05
Coil
3 - 5 VDC
L0
PVDF/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.01.C.06
Coil
3 - 5 VDC
L0
PVDF/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
250
F3.01.C.07
Coil
3 - 5 VDC
L1
PVDF/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.01.C.08
Coil
3 - 5 VDC
L1
PVDF/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
300
F3.01.C.09
Coil
3 - 5 VDC
L0
316SS/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.01.C.10
Coil
3 - 5 VDC
L0
316SS/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
600
F3.01.C.11
Coil
3 - 5 VDC
L1
316SS/EPDM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
F3.01.C.12
Coil
3 - 5 VDC
L1
316SS/FPM
IP68
0.15 to 8 m/s (0.5 to 25 ft./s.)
650
Part No.
42
FLS F3.20
INSERTION FLOW SENSORS
HIGH PRESSURE PADDLEWHEEL
FLOW SENSOR
APPLICATIONS
FLS F3.20 is a paddlewheel
flow sensor suitable for system
at high pressure and at critical
temperature. F3.20 is designed
for use with every kind of solidfree liquids in compliance with
chemical compatibilities of
wetted materials. First quality
materials used, as SS for body/
shaft and Halar® for rotor,
grant high mechanical
performances and an
appreciated reliability.
Sensor needs a very limited
maintenance and, in those
cases, it’s easy to perform due
to a 4 screws system and to a
graphite flat gasket.
F3.20 sensor is available for
connection to FLS monitors
and for PLC connection
directly.
SS weld on adapter is
available for sensor installation
on pipe range from 1 ½” to 8”
(DN40 to DN200).
• Heat Exchangers
• Reverse osmosis
• Cooling systems
• HVAC systems (heating, ventilation and air conditioning)
• Boiler feedwate
MAIN FEATURES
• Working range up to 110 bar (1600 PSI)and up to 248°F (120 °C)
• Wide operating range (from 0,15 to 8 m/s)
• Just one sensor and one fitting for a wide range of pipe dimensions (from
1 ½” to 8”)
• High linearity and repeatability
• Limited maintanance need and easy execution
• Available special version for direct connection to PLC
WWW.FLSNET.IT
43
TECHNICAL DATA
General
• Pipe Size Range: DN40 to DN200
(0.5 to 8 in). Refer to Installation Fittings section for
more details
• Flow Rate Range: 0.15 to 8 m/s (0.5 to 25 ft./s)
• Linearity: ± 0.75% of full scale
• Repeatability: ± 0.5% of full scale
• Pressure: 110 bar (1600 psi)
• Temperature: 120 °C (248 °F)
• Minimum Reynolds Number Required: 4500
• Enclosure: IP68
• Wetted Materials:
- sensor Body: 316L SS
- sealing system: graphite flat gasket
- rotor: ECTFE (Halar®)
- shaft: AISI316L
Specific for F3.20.H
• Supply voltage: 5 to 24 VDC regulated
• Supply current: < 30 mA @ 24 VDC
• Output signal:
- square wave
- frequency: 45 Hz per m/s nominal(13.7 Hz per ft/s
nominal)
- output type: transistor NPN open collector
- output current: 10 mA max
• Cable length: 8 m (26.4 ft) standard,300 m (990 ft)
maximum
Specific for F3.20.P
• Supply voltage: 12 to 24 VDC regulated
• Supply current: < 30 mA @ 24 VCC
• Output signal:
- square wave
- output frequency: 45 Hz per m/s nominal (13.7 Hz per
ft/s nominal)
- output type: Push - Pull (digital input NPN or PNP)
- output current: IOut max < 20 mA
• Cable length: 8 m (26.4 ft) standard,300 m (990 ft)
maximum
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
DIMENSIONS
1 Electrical cable: 8 m. (26.4 ft) standard
2 Flat gasket
3 316L SS sensor body
4 ECTFE Halar® Open-cell rotor and
Stainless Steel Shaft
44
WIRING CONNECTIONS
F3.20 IP68 Sensor wiring connection
INSERTION FLOW SENSORS
ORDERING DATA
F3.20.X.01 High Pressure Paddlewheel Flow Sensors
Version
Power
supply
Length
Main Wetted
Materials
Enclosure
Flow Rate Range
Weight
(gr.)
F3.20.H.01
Hall
5- 24 VDC
107 mm
316L SS
IP 68
0.15 to 8 m/s (0.5 to 25 ft./s)
600
F3.20.P.01
Push-Pull
12- 24 VDC
107 mm
316L SS
IP 68
0.15 to 8 m/s (0.5 to 25 ft./s)
600
Part No.
WWW.FLSNET.IT
45
FLS F6.30
PADDLEWHEEL FLOW TRANSMITTER
APPLICATIONS
The new FLS F6.30 is a
blind transmitter based on
paddlewheel. It can be applied
for the measurement of every
kind of solid-free liquids. The
F6.30 can provides different
output options using a 4-20
mA and a Solid State Relay.
Analog output can be used for
long distance transmission and
SSR can be set as an alarm or
as a volumetric pulse output.
F6.30 Paddlewheel Flow
Transmitter is provided with an
USB interface and a dedicated
software (freely downloadable
from FLS web site) which
allows to easily calibrate
instrument and to intuitively set
outputs by a PC.
The specific design allows an
accurate flow measurement
over a wide dynamic range in
pipe sizes from DN15 (0.5”) to
DN600 (24”).
46
• Industrial water and wastewater treatment
• Cooling water systems
• Swimming pools
• Flow control and monitoring
• Water treatment
• Water regeneration plant
• Processing and manufacturing industry
• Water distribution
MAIN FEATURES
• High chemical resistance
• Pipe size range: from DN15 (0,5”) to DN600 (24”)
• Low pressure drop
• Friendly calibration procedure
• 4-20 mA, frequency or volumetric pulse output settable by USB
• SSR settable as alarm by PC
TECHNICAL DATA
Environmental
• Storage Temperature: -30°C to +80°C (-22°F to
176°F)
• Ambient Temperature: -20°C to +70°C (-4°F to
158°F)
• Relative Humidity: 0 to 95% (non-condensing)
INSERTION FLOW SENSORS
General
• Pipe Size Range: DN15 to DN600 (0.5” to 24”)
Please refer to Installation Fittings section for more
details
• Flow Rate Range: 0.15 to 8 m/s (0.5 to 25 ft./s)
• Linearity: ± 0.75 % of full scale
• Repeatability: ± 0.5 % of full scale
• Minimum Reynolds Number Required: 4500
• Enclosure: IP65
• Wetted Materials:
- sensor Body: C-PVC, PVDF or 316L SS
- o-rings: EPDM or FPM
- rotor: ECTFE (Halar®)
- shaft: Ceramic (Al2O3)/ 316L SS (only for metal
sensors)
- bearings: Ceramic (Al2O3)
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
Electrical
• Power Supply:
- 12 to 24 VDC ± 10% regulated (reverse polarity and
short circuit protected)
- maximum current: consumption: 150 mA
- protective earth: < 10 Ω
• 1 X Current output:
- 4-20 mA, isolated
- max. loop impedance: 800 Ω @ 24 VDC - 250 Ω @
12 VDC
• 1 X Solid State Relay output:
- user selectable as MIN alarm, MAX alarm,
Volumetric, Pulse Out, Window alarm, Off
- optically isolated, 50 mA MAX sink, 24 VDC MAX
pull-up voltage
- max pulse/min: 300
- hysteresis: User selectable
Maximum Operating Pressure / Temperature (25 years lifetime)
F6.30 Transmitter
• C-PVC body:
- 10 bar (145 psi) @ 25°C (77°F)
- 1,5 bar (22 psi) @ 80° C (176°F)
• PVDF body:
- 10 bar (145 psi) @ 25°C (77°F)
- 2,5 bar (36 psi) @ 100°C (212°F)
• SS body:
- 25 bar (363 psi) @ 100°C (212°F)
WWW.FLSNET.IT
47
DIMENSIONS
A Sensor body
B F6.30 Paddlewheel Flow Transmitter
WIRING CONNECTIONS
Rear Terminal View
48
1 O-Ring (EPDM or FPM)
2 Sensor body PVCC, PVDF, 316L SS
3 Halar Rotor, Ceramic shaft & bearings
4 Cable Gland
5 ABS cap for installation into fittings
6 Electronic box
ORDERING DATA
FLS F6.30.XX Paddlewheel Flow Transmitters
Power
supply
Length
Main wetted
materials
Enclosure
Flow Rate Range
Weight
(gr.)
F6.30.01
Hall
12 - 24 VDC
L0
C-PVC/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
750
F6.30.02
Hall
12 - 24 VDC
L0
C-PVC/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
750
F6.30.03
Hall
12 - 24 VDC
L1
C-PVC/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
800
F6.30.04
Hall
12 - 24 VDC
L1
C-PVC/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
800
F6.30.05
Hall
12 - 24 VDC
L0
PVDF/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
750
F6.30.06
Hall
12 - 24 VDC
L0
PVDF/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
750
F6.30.07
Hall
12 - 24 VDC
L1
PVDF/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
800
F6.30.08
Hall
12 - 24 VDC
L1
PVDF/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
800
F6.30.09
Hall
12 - 24 VDC
L0
316SS/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
950
F6.30.10
Hall
12 - 24 VDC
L0
316SS/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
950
F6.30.11
Hall
12 - 24 VDC
L1
316SS/EPDM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
1000
F6.30.12
Hall
12 - 24 VDC
L1
316SS/FPM
IP65
0.15 to 8 m/s (0.5 to 25 ft./s.)
1000
WWW.FLSNET.IT
49
INSERTION FLOW SENSORS
Version
Part No.
FLS F3.10
PADDLEWHEEL MINI FLOW SENSOR
APPLICATIONS
The simple and reliable
paddlewheel technology
has been moved into this
MINIFLOW sensor type FLS
F3.10, designed for use with
every kind of solid-free liquids.
The sensor can measure
flow from 0.25 m/s (0.8 ft/s)
producing a frequency output
signal highly repeatable. A
rugged construction and a
proven technology guarantee
exceptional performances
with little or no maintenance
required. The very small
dimension and a special
design make it suitable for
installation on FIP standard
Tee-fittings from DN15 to DN40
(0.5 to 1.5 in.).
50
• Water treatment
• Filtration systems
• Pure water production
• Water monitoring
• Fertigation
MAIN FEATURES
• IP68 enclosure
• ABS body with EPDM or FPM seal
• ABS 4-blade paddlewheel (no bearings)
• Mono-directional design
• Installation on standard FIP tees
• PVDF body version on request
TECHNICAL DATA
maximum
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
INSERTION FLOW SENSORS
General
• Pipe Size Range: DN15 to DN40 (0.5 to 1 1/2”)
Please refer to Installation Fittings section for more
details
• Flow Rate Range: 0.25 to 4 m/s (0.8 to 12,5 ft./s)
• Linearity: ± 1 % of full scale
• Repeatability: ± 0.5 % of full scale. Minimum
Reynolds Number Required: 4500
• Enclosure: IP68
• Operating Pressure:
- max 10 bar (145 psi) @ 20 °C (68°F)
- max 2 bar (30 psi) @ 70 °C (158°F)
• Operating Temperature: -20°C to 70°C
(-4°F to 158°F).
• Wetted Materials:
- sensor Body: ABS (PVDF for special version)
- o-rings: EPDM or FPM
- rotor: ABS (PVDF for special version)
- shaft: 316L SS
- magnets: SmCo5
Electrical
• Supply current: < 30 mA @ 24 VDC
• Output signal:
- square wave
- output frequency: 15 Hz per m/s nominal (4,6 Hz per
ft/s nominal)
- output type: transistor NPN open collector
- output current: 10 mA max
• Cable length: 2 m (6,5 ft) standard, 300 m (990 ft)
DIMENSIONS
1 Electrical cable: 8 m. (26.4 ft) standard
2 UPVC cap for installation into fittings
3 O-Ring seals available in EPDM or
FPM
4 ABS 4-blade rotor and SS shaft
WWW.FLSNET.IT
51
WIRING CONNECTIONS
F3.10 IP68 Sensor wiring connection
ORDERING DATA
F3.10.H.XX Paddlewheel Miniflow Sensors
Version
Power
supply
Length
Main wetted
materials
Enclosure
Flow Rate Range
Weight
(gr.)
F3.10.H.01
Hall
5 - 24 VDC
41 mm
ABS/EPDM
IP68
0.25 to 4 m/s (0.8 to 12,5 ft./s)
100
F3.10.H.02
Hall
5 - 24 VDC
41 mm
ABS/FPM
IP68
0.25 to 4 m/s (0.8 to 12,5 ft./s)
100
Part No.
52
FLS F3.05
INSERTION FLOW SENSORS
PADDLEWHEEL FLOW SWITCH
APPLICATIONS
The simple insertion
paddlewheel flow switch
type F3.05 is designed to
protect a pump from running
dry or pumping against a
closed valve. lt is equipped
with a mechanical SPST
contact activated when the
flow velocity drops below
the factory preset value of
0.15 m/s (0.5 ft/s). The F3.05
features a LED which shows
the flow status locally.
A specially designed family of
fitting ensures an easy and
quick installation into all pipe
materials in sizes from DN15
to DN600 (0.5” to 24”).
• Pump protection
• Filtration systems
• Cooling water systems
MAIN FEATURES
• C-PVC, PVDF, Stainless Steel body
• Easy insertion system
• High chemical resistance
• No-Flow alarm relay output
• Highly visible Local Bicolour Status lndicator
• Maintenance free
• Very low pressure drop
WWW.FLSNET.IT
53
TECHNICAL DATA
General
• Pipe Size Range: DN15 to DN600 (0.5 to 24 in.)
Please refer to Installation Fittings section for more
details
• Supply voltage: 12 to 24 VDC ± 10% regulated
• Supply current: < 50 mA
• Relay Output: mechanical SPDT contact, 1A @ 24
VDC, 0.1A @ 230 VAC
• Local Status Indicator:
- GREEN Led = Flow
- RED Led = No Flow
• No-Flow Rate Point: 0.15 m/s (0.5 ft./s)
• Enclosure: IP65
• Wetted Materials:
- sensor Body: C-PVC or PVDF or 316L SS
- o-rings: EPDM or FPM
- rotor: ECTFE (Halar®)
- shaft: Ceramic (Al2O3)
- bearings: Ceramic (Al2O3)
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
Maximum Operating Pressure / Temperature (25 years lifetime)
F3.05 Sensor
• C-PVC body:
- 10 bar (145 psi) @ 25°C (77°F)
- 1,5 bar (22 psi) @ 80° C (176°F)
• PVDF body:
- 10 bar (145 psi) @ 25°C (77°F)
- 2,5 bar (36 psi) @ 100°C (212°F)
• SS body:
- 25 bar (363 psi) @ 120°C (248°F)
54
DIMENSIONS
5 C-PVC, PVDF or Stainless Steel
sensor body
6 ECTFE (Halar®) Open-cell rotor, brass
sensor body
7 Ceramic shaft
8 Ceramic bearings
WIRING CONNECTIONS
F3.05 sensor wiring connection
WWW.FLSNET.IT
55
INSERTION FLOW SENSORS
1 4 pole cable plug according to DlN
43650-B/lSO 6952
2 Local Bicolour Status LED
3 UPVC cap for installation into fittings
4 O-Ring seals available in EPDM or
FPM
ORDERING DATA
F3.05.XX Paddlewheel Flow Switches
Version
Power
supply
Length
Main wetted
materials
Enclosure
Flow Rate Range
Weight
(gr.)
F3.05.01
Hall
12 to 24 VDC
L0
C-PVC/EPDM
lP65
-
250
F3.05.02
Hall
12 to 24 VDC
L0
C-PVC/FPM
lP65
-
250
F3.05.03
Hall
12 to 24 VDC
L1
C-PVC/EPDM
lP65
-
300
F3.05.04
Hall
12 to 24 VDC
L1
C-PVC/FPM
lP65
-
300
F3.05.05
Hall
12 to 24 VDC
L0
PVDF/EPDM
lP65
-
250
F3.05.06
Hall
12 to 24 VDC
L0
PVDF/FPM
lP65
-
250
F3.05.07
Hall
12 to 24 VDC
L1
PVDF/EPDM
lP65
-
300
F3.05.08
Hall
12 to 24 VDC
L1
PVDF/FPM
lP65
-
300
F3.05.09
Hall
12 to 24 VDC
L0
316L SS/EPDM
lP65
-
600
F3.05.10
Hall
12 to 24 VDC
L0
316L SS/FPM
lP65
-
600
F3.05.11
Hall
12 to 24 VDC
L1
316L SS/EPDM
lP65
-
650
F3.05.12
Hall
12 to 24 VDC
L1
316L SS/FPM
lP65
-
650
Part No.
56
FLS F6.60
INSERTION FLOW SENSORS
MAGMETER FLOW SENSOR
APPLICATIONS
The new F6.60 and F6.63 are
flow meters without moving
mechanical parts which can be
applied for the measurement of
dirty liquids so long as they are
conductive and homogeneous.
The F6.60 family can
provide three different
options: frequency output to
be connected to FLS flow
monitors, 4-20 mA output for
long distance transmission
and PLC connection and the
new volume pulse output freely
settable.
The insertion magmeter family
is provided with an USB
interface and a dedicated
software (freely downloadable
from FLS web site) which
allows to easily set by a PC
all parameters according
to specific installation
requirements (as full scale and
cut off).
The specific design allows an
accurate flow measurement
over a wide dynamic range in
pipe sizes from DN15 (0.5”) to
DN600 (24”).
• Water and waste water treatment
• Raw water intake
• Industrial water distribution
• Textile industry
• Pools, spas and aquariums
• HVAC
• Processing and manufacturing industry
• Sea water applications
MAIN FEATURES
• No moving parts, no wear, maintenance free
• High mechanical resistance
• Accurate measurement of dirty liquids
• Pipe size range: from DN15 (0,5”) to DN600 (24”)
• Adjustable Flow Rate Range
• Low pressure drop
• User Settable Operating Parameters
• 4-20 mA, frequency or volumetric pulse output
• Bi-directional flow measurement selectable
• Special versions for salt-water applications (high concentrations of
chlorides like sea water) and for high temperature conditions
WWW.FLSNET.IT
57
TECHNICAL DATA
General
• Pipe Size Range: DN15 to DN600 (0.5” to 24”)
Please refer to Installation Fitting section for more
details
• Max Flow Rate Range:
- F6.60: from 0,05 to 8 m/s
- F6.63: from 0,15 to 8 m/s
• Full Scale: 8 m/s (26.24 ft/s)
• Linearity: ± 1% of reading + 1,0 cm/s
• Repeatability: ± 0.5% of reading
• Enclosure: IP65
• Materials:
- case: PC/ABS
- gasket: EPDM
• Wetted Materials:
- sensor body: 316L SS/PVDF; 316L SS/ PEEK; CuNi
alloy/PVDF
- o-rings: EPDM or FPM
- electrodes: 316L SS or CuNi alloy
Electrical
• Power Supply:
- 12 to 24 VDC ± 10% regulated (reverse polarity and
short circuit protected)
- maximum current: consumption: 250 mA
- protective earth: < 10 Ω
• Current output:
- 4-20 mA, isolated
- max. loop impedance: 800 Ω @ 24 VDC - 250 Ω @
12 VDC
- positive or negative flow indication
• Solid State Relay output:
- user selectable as MIN alarm, MAX alarm,
Volumetric, Pulse Out, Window alarm, Off
- optically isolated, 50 mA MAX sink, 24 VDC MAX
pull-up voltage
- max pulse/min: 300
- hysteresis: User selectable
• Open Collector output (Frequency):
- Ttype: Open Collector NPN
- frequency: 0 – 800 Hz
- max. Pull-up Voltage: 24 VDC
- max. Current: 50 mA, current limited
- compatible with M9.02, M9.50, M9.07 and M9.10 (only F6.63)
• Open Collector output (Direction not available
on F6.63):
- type: Open Collector NPN
- max. Pull-up Voltage: 24 VDC
- max. Current: 50mA, current limited
- flow direction:
0 VDC arrow-wise
+ VDC anti arrow-wise
Enviromental
• Storage Temperature: -30°C to +80°C (-22°F to
176°F)
• Ambient Temperature: -20°C to +70°C (-4°F to
158°F)
• Relative Humidity:0 to 95% (non-condensing)
• Fluid conditions:
- homogeneous liquids, pastes or slurries, also with
solid content
- min electrical conductivity: 20 μS
- temperature:
PVDF bottom version: -10 °C to +60 °C (14 °F to 140
°F)
PEEK bottom version: -10 °C +150 °C (14 °F to 302
°F)
• Max. operating pressure:
- 16 bar @ 25°C (232 psi @ 77°F)
- 8.6 bar @ 60°C (124 psi @ 140°F)
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
DIMENSIONS
A Sensor body
B F6.60 Magmeter
58
1 O-Ring (EPDM or FPM)
2 Sensor body (316L SS or CuNi)
3 Isolation Plate (PVDF or PEEK)
4 Electrodes (316L SS or CuNi)
5 Cable Gland
6 ABS cap for installation into fittings
7 Electronic box
WIRING CONNECTIONS
Rear Terminal View
INSERTION FLOW SENSORS
ORDERING DATA
F6.60.XX Magmeter Flow Sensor
Version
Power
supply
Length
Main wetted
materials
Enclosure
Flow Rate Range
Weight
(gr.)
F6.60.09
Blind
12 - 24 VDC
L0
316L SS/ PVDF/ EPDM
IP65
0,05 – 8 m/s bi-directional
950
F6.60.10
Blind
12 - 24 VDC
L0
316L SS/ PVDF/ FPM
IP65
0,05 – 8 m/s bi-directional
950
F6.60.11
Blind
12 - 24 VDC
L1
316L SS/ PVDF/ EPDM
IP65
0,05 – 8 m/s bi-directional
1000
F6.60.12
Blind
12 - 24 VDC
L1
316L SS/PVDF/FPM
IP65
0,05 – 8 m/s bi-directional
1000
F6.60.33
Blind
12 - 24 VDC
L0
CuNi/ PVDF/ EPDM
IP65
0,05 – 8 m/s bi-directional
950
F6.60.34
Blind
12 - 24 VDC
L0
CuNi/ PVDF/ FPM
IP65
0,05 – 8 m/s bi-directional
950
F6.60.35
Blind
12 - 24 VDC
L1
CuNi/PVDF/EPDM
IP65
0,05 – 8 m/s bi-directional
1000
F6.60.36
Blind
12 - 24 VDC
L1
CuNi/ PVDF/ FPM
IP65
0,05 – 8 m/s bi-directional
1000
F6.60.38
Blind
12 - 24 VDC
L0
316L SS/ PEEK/ FPM
IP65
0,05 – 8 m/s bi-directional
950
F6.60.40
Blind
12 - 24 VDC
L1
316L SS/ PEEK/ FPM
IP65
0,05 – 8 m/s bi-directional
1000
Part No.
F6.63.XX Magmeter Flow Sensor
Version
Power
supply
Length
Main wetted
materials
Enclosure
Flow Rate Range
Weight
(gr.)
F6.63.09
Blind
12 - 24 VDC
L0
316L SS/ PVDF/ EPDM
IP65
0,15 - 8 m/s mono-directional
950
F6.63.10
Blind
12 - 24 VDC
L0
316L SS/ PVDF/ FPM
IP65
0,15 - 8 m/s mono-directional
950
F6.63.11
Blind
12 - 24 VDC
L1
316L SS/ PVDF/ EPDM
IP65
0,15 - 8 m/s mono-directional
1000
F6.63.12
Blind
12 - 24 VDC
L1
316L SS/PVDF/FPM
IP65
0,15 - 8 m/s mono-directional
1000
F6.63.33
Blind
12 - 24 VDC
L0
CuNi/ PVDF/ EPDM
IP65
0,15 - 8 m/s mono-directional
950
F6.63.34
Blind
12 - 24 VDC
L0
CuNi/ PVDF/ FPM
IP65
0,15 - 8 m/s mono-directional
950
F6.63.35
Blind
12 - 24 VDC
L1
CuNi/PVDF/EPDM
IP65
0,15 - 8 m/s mono-directional
1000
F6.63.36
Blind
12 - 24 VDC
L1
CuNi/ PVDF/ FPM
IP65
0,15 - 8 m/s mono-directional
1000
F6.63.38
Blind
12 - 24 VDC
L0
316L SS/ PEEK/ FPM
IP65
0,15 - 8 m/s mono-directional
950
F6.63.40
Blind
12 - 24 VDC
L1
316L SS/ PEEK/ FPM
IP65
0,15 - 8 m/s mono-directional
1000
Part No.
WWW.FLSNET.IT
59
FLS F6.61
MAGMETER FLOW SENSOR
APPLICATIONS
The new FLS F6.61 Hot Tap
Insertion Magmeter Flow
Sensor is a flowmeter without
moving mechanical parts
which can be applied for the
measurement of dirty liquids
so long as they are conductive
and homogeneous. The sensor
can provide three different
options: frequency output to
be connected to FLS flow
monitors, 4-20 mA output for
long distance transmission
and PLC connection and the
new volume pulse output freely
settable. FLS F6.61 Insertion
Magmeter is provided with an
USB interface and a dedicated
software (freely downloadable
from FLS web site) which
allows to easily set by a PC
all parameters according
to specific installation
requirements.
The sensor can be assembled
in a wide dynamic range of
pressurized pipe sizes from
DN50 (2”) to DN900 (36”)
using a standard clamp saddle
and an isolation ball valve.
60
• Water distribution
• Leak Detection or Monitoring
• Raw water intake
• Water and waste water treatment
• Ground water remediation
• Irrigation
MAIN FEATURES
• Adjustable sensor position
• Hot-Tap installation
• Operating parameters settable by PC interface
• Pressure intake
• Standard 1 ¼” BSP process connection
• No moving parts, no wear, maintenance free
• Flow Rate Range settable from 0.05 to 8 m/s (0.15 to 25 ft/s)
• Accurate measurement of dirty liquids
• 4-20 mA, frequency or volume pulse outputs
• Bi-directional flow measurement selectable
TECHNICAL DATA
Electrical
• Power Supply:
- 12 to 24 VDC ± 10% regulated (reverse polarity and
short circuit protected)
- maximum current: consumption: 250 mA
- protective earth: < 10 Ω
• Current output:
- 4-20 mA, isolated
- max. loop impedance: 800 Ω @ 24 VDC - 250 Ω @
12 VDC
- positive or negative flow indication
• Solid State Relay output:
- user selectable as MIN alarm, MAX alarm,
Volumetric, Pulse Out, Window alarm, Off
- optically isolated, 50 mA MAX sink, 24 VDC MAX
pull-up voltage
- max pulse/min: 300
- hysteresis: User selectable
• Open Collector output (Frequency):
- type: Open Collector NPN
- frequency: 0 – 800 Hz
- max. pull-up voltage: 24 VDC
- max. current: 50 mA, current limited
- compatible with M9.02, M9.50 and M9.07
• Open Collector output (Direction):
- type: Open Collector NPN
- max. Pull-up Voltage: 24 VDC
- max. Current: 50mA, current limited
- flow direction:
0 VDC arrow-wise
+ VDC anti arrow-wise
Enviromental
• Storage Temperature: -30°C to +80°C (-22°F to
176°F)
• Ambient Temperature: -20°C to +70°C (-4°F to
158°F)
• Relative Humidity:0 to 95% (non-condensing)
• Fluid conditions:
- homogeneous liquids, pastes or slurries, also with
solid content
- Min Electrical Conductivity: 20 μS
- Temperature:
PVDF bottom version: -10 °C to +60 °C (14 °F to 140
°F)
PEEK bottom version: -10 °C +150 °C (14 °F to 302
°F)
• Max. operating pressure:
- 16 bar @ 25°C (232 psi @ 77°F)
- 8.6 bar @ 60°C (124 psi @ 140°F)
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
DIMENSIONS
1 Magmeter electronic device
5 Process connection 1 ¼” gas threaded
2 Sliding rod
6 AISI 304 SS adjustable sensor body
3 AISI 304 SS joint for sensor installation 7 AISI 316 L electrodes and PVDF
4 Pressure intake
bottom
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INSERTION FLOW SENSORS
General
• Pipe Size Range: DN50 to DN900 (2” to 36”). Special
version on request for other sizes. Please refer to
Installation Fitting section for more details
• Max Flow Rate Range:
from 0.05 to 8 m/s (0.15 to 26.24 ft/s)
• Full Scale: 8 m/s (26.24 ft/s)
• Linearity: ± 1% of reading + 1,0 cm/s
• Repeatability: ± 0.5% of reading
• Enclosure: IP65
• Materials:
- case: PC/ABS
- gasket: EPDM
• Wetted Materials:
- sensor body: 304 SS/PVDF
- o-rings: EPDM or FPM
- electrodes: 316LSS
WIRING CONNECTIONS
Rear Terminal View
ORDERING DATA
F6.61.XX Hot Tap Magmeter Flow Sensor
Part No.
F6.61.01
62
Version
Power
supply
Length
Main wetted
materials
Enclosure
Flow Rate Range
Weight
(gr.)
Hot-tap
12-24 VDC
615mm
304 SS/
PVDF/316L SS
IP65
0,05 – 8 m/s bi-directional
6000
FLS F111
INSERTION FLOW SENSORS
HOT TAPPADDLEWHEEL
& TURBINE FLOW SENSORS
APPLICATIONS
The metal flow sensor type
F111 offers high strength and
mechanical resistance applied
to hot-tap insertion technology.
The sensor can be assembled
in pressurized pipes using
a proper clamp saddle for a
precise positioning into the
pipe and get the maximum
accuracy.
The sensor is available with
both paddlewheel and turbine
technologies.
The paddlewheel sensor can
measure flow from 0.15 m/s
(0.5 ft/s) while the turbine
sensor can start measuring
from 0.08 m/s (0.26 ft/s) and
the bi-directional version is
able to recognize the direction
of the flow. The F111 hot tap
sensor can fit for a wide range
of pipe dimensions starting
from DN50 up to DN900.
• Water distribution
• Leak Detection or Monitoring
• lrrigation
• Water treatment and regeneration
• Ground Water Remediation
• Filtration systems
MAIN FEATURES
• Adjustable sensor position
• Stainless steel or brass construction
• Paddlewheel or Turbine technology
• E-CTFE rotor with ceramic shaft and bearings or PVDF turbine
• Hot-Tap installation
• Safety chain
• Pressure intake
• Standard 1 ¼” BSP process connection
• Battery powered version
• Compatible with most Data Loggers
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TECHNICAL DATA
General
• Pipe Size Range: DN50 to DN900 (2” to 36”). Special
versions on request for other sizes
• Linearity: ± 0.75 % of full scale
• Repeatability: ± 0.5 % of full scale
• Minimum Reynolds Number Required: 4500
• Enclosure: lP68
• Maximum operating pressure/temperature: 20 bar
(290 psi) @ 80°C (176°F)
• Sensor fitting joint: 1 1/4” BSP (male)
• Pressure lntake: quick connection 3/8”
• Wetted Materials:
- sensor Body: AlSl 304 Stainless Steel (or Brass)
- sensor joint: AlSl 304 Stainless Steel (or Brass)
- o-rings: EPDM
- rotor: ECTFE (Halar®)
- turbine: PVDF
- shaft: Ceramic (Al2O3)
- bearings: Ceramic (Al2O3)
Specific for F111.H
• Flow Rate Range: 0.15 to 8 m/s (0.5 to 25 ft/s)
• Supply voltage: 5 to 24 VDC ±10%, regulated
• Supply current: < 30mA @ 24 VDC
• Output signal:
- square wave
- output frequency: 45 Hz per m/s nominal (13.7 Hz per
ft/s nominal)
- output type: transistor NPN open collector
- output current: 10 mA max
• Cable length: 8 m (26.4 ft) standard, 300 m (990 ft)
maximum
Specific for F111.C
• Flow Rate Range: 0.15 to 8 m/s (0.5 to 25 ft/s)
• Supply voltage: 3 to 5 VDC ±10%, regulated or 3.6
Volt Lithium battery
• Supply current: < 10 µA
• Output signal:
- square wave
- output frequency: 45 Hz per m/s nominal (13.7 Hz per
ft/s nominal)
- min. input impedance: 100 kΩ
• Cable length: 8 m (26.4 ft) standard, 16 m (52.8 ft)
maximum
Specific for F111.HT
• Flow Rate Range: 0.08 to 8 m/s (0.26 to 25 ft/s)
• Supply voltage: 5 to 24 VDC ± 10%, regulated
• Supply current: < 30mA @ 24 VDC
• Output Signal:
- square wave
- output frequency: 20 Hz per m/s nominal (6.1 Hz per
ft/s)
- output type: transistor NPN open collector
- output current: 10 mA max
• Cable length: 8 m (26.4 ft) standard, 300 m (990 ft)
maximum
Specific for F111.HT.BD
• Flow Rate Range: 0.08 to 1.5 m/s (0.26 to 4.9 ft/s)
• Supply voltage: 4 to 5 VDC ±10%, regulated
• Supply current: 0.6 mA @ 5 VDC
• Output Signal:
- square wave
- output frequency: 10 Hz per m/s nominal (3.05 Hz per
ft/s nominal)
- output type: CMOS active output
• Cable length: 8 m (26.4 ft) standard, 100 m (330 ft)
maximum
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
DIMENSIONS
A F111 Paddlewheel Sensor
B F111 Turbine Sensor
64
1 Sliding Rod
2 Pressure intake
3 ECTFE (Halar®) Open-cell rotor
4 PVDF Turbine
5 Clinching Ring
WIRING CONNECTIONS
F111 Monodirectional sensor wiring connection
F111 Bi-directional sensor wiring connection
INSERTION FLOW SENSORS
ORDERING DATA
F111.X.XX Hot Tap Insertion Flow Sensors
Version
Power
supply
Length
Main wetted
materials
Enclosure
Flow Rate Range
Weight
(gr.)
F111.H.01
Hall
Paddlewheel
5 - 24 VDC
550mm
SS AISI 304/EPDM
IP 68
0.15 to 8 m/s
(0.5 to 25 ft./s.)
5000
F111.H.02
Hall
Paddlewheel
5 - 24 VDC
550mm
BRASS/EPDM
IP 68
0.15 to 8 m/s
(0.5 to 25 ft./s.)
5000
F111.C.01
Coil
Paddlewheel
3 - 5 VDC
550mm
SS AISI 304/EPDM
IP 68
0.15 to 8 m/s
(0.5 to 25 ft./s.)
5000
F111.C.02
Coil
Paddlewheel
3 - 5 VDC
550mm
BRASS/EPDM
IP 68
0.15 to 8 m/s
(0.5 to 25 ft./s.)
5000
F111.HT.01
Hall Turbine
5 - 24 VDC
550mm
SS AISI 304/EPDM
IP 68
0.08 to 8 m/s
(0.26 to 25 ft./s.)
5000
F111.HT.BD
Turbine
Bi-directional
4 - 5 VDC
550mm
SS AISI 304/EPDM
IP 68
0.08 to 1.5 m/s
(0.26 to 4.9 ft./s.)
5000
Part No.
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65
INSTALLATION
& OPERATING GUIDELINES
FOR INSERTION FLOW SENSORS
INSTALLATION GUIDELINES
•All the insertion technology flow sensors are velocity-based flow
measurement devices;
•The installation typically requires only a small hole in the pipe for sensor
perpendicular mounting;
•Sensors dimension are not pipe size specific: almost independent from
pipe cross section.
Flow Sensor Installation
The placement of a flow meter is critical to get an accurate and reliable
reading. For a flow meter proper performance it is necessary to check:
•Full pipe at every time;
•Uniform flow velocity into the pipe.
Full Pipe Condition
If the pipe is not full the flow meter will give inaccurate reading even if the
sensor is always completely submerged.
Sensor will make the flow rate calculation on the assumption that the pipe
is full, leading to overestimation of the flow. A pump intake or an outlet on
the bottom of a tank does not necessary ensure the pipe always running
full; air can be sucked by pumps or it could remain entrapped when the
pipe was empty.
Anyway the flowmeter should be always situated in the lowest point of
the pipe and there should be downstream the flowmeter a part of the pipe
placed 1 x ID higher than where the flow meter is located.
Uniform Flow Velocity
Insertion flow meters measure the velocity of the liquid. It is important
the velocity is uniform across the entire cross section of the pipe in the
location of the sensor. Flow patterns are distorted both downstream and
upstream of any disturbance.
In a pipe, liquid at the edge of the pipe moves slower than towards the
center because of friction along the walls.
In a straight run of pipe, area with similar velocities can be depicted as
concentric rings.
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67
INSERTION FLOW SENSORS
Insertion Technology Main
Features
Pipe Location
Fig.1
Fig.2
Fig.3
Fig.4
68
•The six most common installation configurations shown in fig. 1 help in
selecting the best location in the pipeline for paddlewheel flow sensor as
well for magmeter flow sensor.
•The three configurations in fig. 2 ensure that the pipe is always full: for
a correct measurement the sensor can NOT be exposed to air bubbles at
any time.
•The three installations in Fig. 3 should be avoided unless you are
absolutely sure the sensor is not exposed to air bubbles.
•In gravity-flow systems the connection to the tank must be designed so
the level does not drop below the outlet: this to avoid pipe to draw air in
from the tank causing a inaccurate measurement of sensor (see Fig. 4).
•For more information, please refer to EN ISO 5167-1.
•Always maximize distance between flow sensors and pumps.
Mounting Positions
Measuring part of sensor (rotor for paddlewheel and pins for magmeter)
should be positioned at 12% of ID where, basing on insertion theory,
average velocity can be measured.
The reading accuracy of insertion flow sensors can be affected by:
•air bubbles;
•sediments;
•friction between shaft and bearings (only for paddlewheel).
K-Factor
K factor is a conversion value which has to be fixed in order to convert
sensor output (frequency) to a flow rate.
K factor depends on ID of pipe where sensor has been installed and,
as each pipe has a specific wall thickness, in general it’s necessary to
know pipe size (external diameter), pipe material and all info which can
determine internal diameter.
Provided k- factors are referred to water so in case sensors are applied
to measure a different liquid (with a different viscosity and/or density) a
recalibration on-site can be needed using a secondary standard.
Maximize sensor performances
In order to get the maximum accuracy, a recalibration using a reference
value of flow rate could help to evaluate a fine tuning of k-factor in
according with specifications of installation site. This procedure is strongly
suggested when sensors are applied to measure a different liquid than
water and in case distances reported into EN ISO 5167-1 can’t be
respected in the installation.
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69
INSERTION FLOW SENSORS
In a horizontal pipe runs, the mounting position to get the best
performances is at a 45° angle (Fig. 3) to avoid air bubbles as well
sediments. Vertical position (Fig. 2) can be chosen in case air bubbles
are not present. Do not mount the sensor on the bottom of the pipe (Fig.
1) if sediments are likely. Do not mount paddlewheel at 90° otherwise
friction can affect measurement. Except last consideration about 90°
installation, all previous evaluations are valid for magmeter sensor also.
Installation in a vertical pipe runs can be done fixing any orientation.
Upward flow is preferred to ensure full pipe.
OPERATING GUIDELINES
Paddlewheel Flow Sensors
Rotor and shaft are in direct contact with the fluid. Since the paddle will
spin at a velocity that is directly proportional to the rate of flow, these
components will wear over time. Rotors which have operated at high
velocity will tend to wear more than units operated at low velocities.
Because every fluid has different characteristics, it is difficult to estimate
the life expectancy of these components. The chemical compatibilities
of each wetted component to the chemical being measured should be
considered to choose the best material option. Axles and paddles can be
easily replaceable in order to maintain better performances. Avoid using
paddlewheel flowmeters for measuring very dirty fluid, or liquids with rocks
or pebbles that could break or damage the rotor or the axle.
Solids could affect sensor response also modifying friction of shaft. Don’t
use paddlewheel in case liquid contains fibers.
A neglected paddlewheel will in time have degraded accuracy. Even if in
case liquid contains solids we suggest to apply a magmeter, you can use
a paddlewheel but in such case it’s strongly suggested to plan a cleaning
procedure of wetted parts periodically. For cleaning procedure use
detergent or chemicals compatible with wetted materials.
Magmeter Flow Sensor
In general magmeter flow sensor doesn’t need a specific maintenance.
In case magmeter is used to measure a very dirty liquid it can be
suggested to clean periodically the device with a cloth slightly dampened
with water or a liquid compatible with the materials of the device and cloth.
Dirty electrodes may cause measurement inaccuracy. Do not use abrasive
materials to take maintenance.
Hot tap Insertion Flowmeters
The use of hot tap instrumentation is suggested for installation in
pressurized pipes and when it is impossible to stop the flow rate into the
pipeline.
Hot tap version is available for magmeter, paddlewheel and turbine
sensors.
Previous advices are valid for these versions also.
The sensors designed for hot tap installation are suitable also for pipes
with a diameter larger than the maximum covered by traditional sensors
(typically DN600/24”).
Hot tap sensors have to be combined with hot tap fitting only.
70
IN LINE ULTRA LOW FLOW AND OVAL
GEAR SENSORS
LIGHT AND COMPACT DESIGN
FOR RELIABLE LOW FLOW
MEASUREMENT
FLS ULF
ULTRA LOW FLOW SENSOR
APPLICATIONS
The FLS compact Ultra Low
Flow sensors ULF have
been for use with every kind
of aggressive and solid-free
liquids.
The sensor can be fixed
to flexible or rigid pipes via
1/4” GAS threaded process
connections. The paddlewheel
sensor produces a frequency
output proportional to the flow
velocity that can be easily
transmitted and processed.
The ULF sensor offers two
different flow ranges starting
from 1.5 or 6 l/h (0.0066 or
0.0264 gpm). The construction
materials, POM or ECTFE
(Halar®), provide high strength
and chemical resistance.
72
• Water treatment
• Chemical industry
• Pharmaceutical industry
• Dosing systems
• Laboratory plants
MAIN FEATURES
• POM or ECTFE (Halar®) wetted parts
• Two flow ranges available:
- 1.5 - 100 l/h (0.0066 - 0.44 gpm)
- 6 - 250 l/h (0.0264 - 1.1 gpm)
• High chemical resistance
• Easy mounting
TECHNICAL DATA
Specific for ULF01.R I ULF03.R
• Supply voltage: none
• Output signal: square wave
• Output type: Reed Contact
• K-factor:
- ULF01 version: 2108 Pulses/Liter (7978 Pulses/U.S.
Gallon) in linear range from 8 to 100 l/h
- ULF03 version: 848 Pulses/Liter (3210 Pulses/U.S.
Gallon) in linear range from 15 to 250 l/h
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
IN LINE FLOW SENSORS
General
• Flow Rate Range:
- ULF01 version: 1.5 to 100 l/h (0.0066 to 0.44 gpm)
- ULF03 version: 6 to 250 l/h (0.0264 to 1.1 gpm)
• Linearity: ± 1 % of full scale
• Repeatability: ± 0.5 % of full scale
• Working Temperature: -10°C to 80°C (14°F to 176°F)
• Working Pressure: 5 bar (70 psi) max @ 22°C (72°F)
• Viscosity of fluid: 1 to 10 cST
• Enclosure: IP65
• Wetted materials:
- POM version:
sensor body: POM
o-ring: FPM
rotor: POM
shaft: corepoint
magnets: SmCo5
- ECTFE version:
sensor Body: ECTFE(Halar®)
o-ring: FPM or KALREZ
rotor: ECTFE (Halar®)
shaft: Sapphire
bearings: Sapphire
• Connections: 1/4” GAS male threaded
• Cable length: 2 m (6.5 ft) standard
Specific for ULF01.H I ULF03.H
• Supply voltage: 5 to 24 VDC ±10%, regulated
• Supply current: < 15 mA @ 24 VDC
• Output signal: square wave
• K-factor:
- ULF01 version: 8431 Pulses/Liter (31569 Pulses/
U.S. Gallon) in linear range from 8 to 100 l/h
- ULF03 version: 3394 Pulses/Liter (12846 Pulses/
U.S. Gallon) in linear range from 15 to 250 l/h
Pressure Drop
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DIMENSIONS
1 Electrical cable: 2 m. (6.5 ft) standard
2 Completely encapsulated electronics
3 Connection (other versions available
on request according to body material)
4 POM or ECTFE Halar® (registered
trademark of Ausimont-Solvay) sensor
body
5 PP fixing plate
WIRING CONNECTIONS
ULFXX.H Sensor wiring connection
74
ULFXX.R Sensor wiring connection
ORDERING DATA
ULF0X.X.X Ultra Low Flow Sensors
Power
supply
Length
Main wetted
materials
Enclosure
Flow Rate Range
Weight
(gr.)
ULF01.H.0
Hall
5 - 24 VDC
77mm
POM / FPM
IP65
1.5 to 100 l/h (0.0066 to 0.44 gpm)
170
ULF01.H.2
Hall
5 - 24 VDC
77mm
ECTFE / FPM
IP65
1.5 to 100 l/h (0.0066 to 0.44 gpm)
200
ULF01.H.3
Hall
5 - 24 VDC
77mm
ECTFE / KALREZ
IP65
1.5 to 100 l/h (0.0066 to 0.44 gpm)
200
ULF01.R.0
Reed
None
77mm
POM / FPM
IP65
1.5 to 100 l/h (0.0066 to 0.44 gpm)
170
ULF01.R.2
Reed
None
77mm
ECTFE / FPM
IP65
1.5 to 100 l/h (0.0066 to 0.44 gpm)
200
ULF01.R.3
Reed
None
77mm
ECTFE / KALREZ
IP65
1.5 to 100 l/h (0.0066 to 0.44 gpm)
200
ULF03.H.0
Hall
5 - 24 VDC
77mm
POM / FPM
IP65
6 to 250 l/h (0.0264 to 1.1 gpm)
170
ULF03.H.2
Hall
5 - 24 VDC
77mm
ECTFE / FPM
IP65
6 to 250 l/h (0.0264 to 1.1 gpm)
200
ULF03.H.3
Hall
5 - 24 VDC
77mm
ECTFE / KALREZ
IP65
6 to 250 l/h (0.0264 to 1.1 gpm)
200
ULF03.R.0
Reed
None
77mm
POM / FPM
IP65
6 to 250 l/h (0.0264 to 1.1 gpm)
170
ULF03.R.2
Reed
None
77mm
ECTFE / FPM
IP65
6 to 250 l/h (0.0264 to 1.1 gpm)
200
ULF03.R.3
Reed
None
77mm
ECTFE / KALREZ
IP65
6 to 250 l/h (0.0264 to 1.1 gpm)
200
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IN LINE FLOW SENSORS
Version
Part No.
FLS F3.80
OVAL GEAR FLOW SENSOR
APPLICATIONS
The FLS Oval Gear Flow
sensors F3.80 have been
designed following the
main industrial application
requirements: high mechanical
resistance and reliable
performances.These sensors
are suitable to measure a wide
range of viscous solid-free
liquids with a very high accuracy
and repeatability.
The sensors can be fixed
to flexible or rigid pipes via
1/4” GAS threaded process
connections. The construction
materials, ECTFE (Halar®) or
PP or Stainless steel, provide
high strength and chemical
resistance.
76
• Chemical industry
• Laboratory plants
• Dosing systems
• Pulsating flows measurement
• High viscosity and not conductive fluid measurement
• Oil measurement
MAIN FEATURES
• Compact dimensions
• Easy installation
• High chemical resistance
• High viscosity fluids measurement
• Low pressure loss
TECHNICAL DATA
shaft: Stainless Steel
• Connections: 1/4” GAS female
• Cable length: 2 m (6.5 ft) standard
Specific for F3.81.H
• Supply voltage: 5 to 24 VDC ±10%, regulated
• Supply current: < 15 mA @ 24 VDC
• Output signal: square wave Cmos (NPN / PNP)
• K-factor = 5950 Pulses/Liter (22521 Pulses/U.S.
Gallon)
Specific for F3.82.H
• Supply voltage: 5 to 24 VDC ±10%, regulated
• Supply current: < 15 mA @ 24 VDC
• Output signal: square wave Cmos (NPN / PNP)
• K-factor = 3400 Pulses/Liter (12869 Pulses/U.S.
Gallon)
IN LINE FLOW SENSORS
General
• Flow Rate Range:
- F3.81.H: 10 to 100 l/h (0.044 up to 0.44 gpm)
- F3.82.H: 25 to 150 l/h (0.11 up to 0.66 gpm)
• Linearity: 1 % of full scale
• Repeatability: < 0,3% of full scale
• Working Temperature: -10°C to 60°C (14°F to 140°F)
• Max. Fluid Viscosity : 1000 cP (mPas)
• Working Pressure:
- PP body:
6 bar (87 psi) @ 25°C (77°F)
3 bar (44 psi) @ 60°C (140°F)
- ECTFE body:
8 bar (116 psi) @ 25°C (77°F)
5 bar (73 psi) @ 60°C (140°F)
- SS body:
8 bar (116 psi) @ 60°C (140°F)
• Enclosure: lP65
• Wetted Materials:
- PP version:
sensor body: PP
o-ring: FPM
gear: ECTFE (Halar)
shaft: zircone
- ECTFE version:
sensor body: ECTFE (Halar)
o-ring: FPM
gear: ECTFE (Halar)
shaft: zircone
- Stainless Steel:
sensor body: SS AlSl 316L
o-ring: FPM
gear: ECTFE (Halar)
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
Pressure Drop
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DIMENSIONS
1 ECTFE Halar® oval gears
2 1/4” GAS threaded pipe connection
3 Electrical cable: 2m. (6.5 ft) standard
4 Completely encapsuled electronics
WIRING CONNECTIONS
F3.8X.H Sensor Connection
78
5 PP or ECTFE Halar® (registered
trademark of Ausimont-Solvay) or SS
sensor body
ORDERING DATA
F3.8X.H.XX Oval Gear Flow Sensors
Power
supply
Length
Main wetted
materials
Enclosure
Flow Rate Range
Weight
(gr.)
F3.81.H.01
Hall
5 - 24 VDC
54 mm
PP/ ECTFE/ FPM
IP65
10 to 100 l/h (0.044 to 0.44 gpm)
200
F3.81.H.02
Hall
5 - 24 VDC
54 mm
ECTFE/ ECTFE/
FPM
IP65
10 to 100 l/h (0.044 to 0.44 gpm)
300
F3.81.H.03
Hall
5 - 24 VDC
54 mm
316L SS/ ECTFE/
FPM
IP65
10 to 100 l/h (0.044 to 0.44 gpm)
800
F3.82.H.01
Hall
5 - 24 VDC
54 mm
PP/ ECTFE/ FPM
IP65
25 to 150 l/h (0.11 to 0.66 gpm)
200
F3.82.H.02
Hall
5 - 24 VDC
54 mm
ECTFE/ ECTFE/
FPM
IP65
25 to 150 l/h (0.11 to 0.66 gpm)
300
F3.82.H.03
Hall
5 - 24 VDC
54 mm
316L SS/ ECTFE/
FPM
IP65
25 to 150 l/h (0.11 to 0.66 gpm)
800
WWW.FLSNET.IT
79
IN LINE FLOW SENSORS
Version
Part No.
INSTALLATION
& OPERATING GUIDELINES
FOR IN LINE FLOW SENSORS
INSTALLATION GUIDELINES
OPERATING GUIDELINES
FLS can supply two different kinds of in-line sensors for low flow rates
to cover different applications according to operating range and specific
viscosity of liquid.
ULF flow sensor can be generally applied to measure liquids with a
viscosity up to 10 cP while F3.80 oval gear flow sensor up to 1000cP.
Both sensors have to be applied for the measurement of solid-free liquids
as movement parts are present.
Abrasive or dirty liquids can potentially damage the sealing surfaces, the
bearings and/or plugging of the sensor. A filter may be required to remove
dirt.
Since these types of instruments are mainly used in dosing system,
aggressive chemical solutions are very frequenty measured. Take care
about following cases:
•Chemicals could crystallize if left for a long time into sensor without flow
so it’s strongly advised to plan a cleaning of sensor in case it’s requested
a irregular use. For cleaning procedure can be used water as well other
solutions compatible with wetted material and with measured chemical.
•Chemicals could release gas so it’s strongly advised to pay attention on
this issue especially during inoperative period.
Be sure that gas bubbles are removed from liquid flow streams when
using in line sensors. For F3.80 family sensors, flow measurements
taken with bubbles present will be higher than the true liquid flow
because the bubble volumes will be measured as if they were a volume
of liquid. For ULF family sensors, flow measurements taken with gas
bubble is inaccurate as this presence produces a turbulence into sensor
measurement chamber.
In case viscosity of the operating fluid is far from calibrated liquid (water)
a recalibration of sensor itself could be necessary to fix the proper
k-factor because the different amounts of slippage exhibited by different
fluids can cause measurement error. Consider that increasing viscosity
decreases slippage and increases the pressure drop across the in line
sensor.
WWW.FLSNET.IT
81
IN LINE FLOW SENSORS
In-line flow sensor can be installed in any position, both horizontally or
vertically, although horizontal flow is preferred.
A non horizontal installation may cause a greater error in the lower part of
the measurement range.
Anyway a positioning with a slightly tilt angle is suggested in case
bubbles air could be present.
Install the sensor with the arrow pointing the direction of the flow.
Always maximize distance between sensor and pump. Do not install
the sensor immediately downstream of valves, elbows or any kind of
obstacles: 150 mm of straight pipe are suggested before and after the
sensor.
Consider pressure drop correlated to in-line flow sensors, especially in
case you use them in a pipeline with a different diameter than ¼” (male
for ULF family and female for F3.80 family). A large pressure drop across
in line sensor can prematurely wear and/or damage bearings and/or
seals.
BULB AND FLAT pH/ORP
ELECTRODES WITH EPOXY, C-PVC,
RYTON OR GLASS BODY
THE MOST APPROPRIATE
ELECTRODE FOR EACH APPLICATION
FLS pH/ORP 200
EPOXY BODY BULB ELECTRODE
APPLICATIONS
This FLS line of electrodes
has been designed to
provide a cost effective multipurpose solution for in line or
submersion measurement of
pH and ORP in a wide range of
applications.
Single and double junction
versions are available as well
as models with or without quick
disconnect top caps. Moreover
for automatic temperature
compensation function (ATC)
a pH option with temperature
sensor integrated is available.
These epoxy body electrodes
can stand several applications
thanks to the high chemical
resistance of the material. A
simple and reusable gland
can be used for economic
electrode in-line mounting
while a ½” or ¾” coupler with
a pipe extension is enough
for submersion mounting. A
special version is dedicated to
installation on FLS T fitting as
well as to FLS clamp saddle
adding just a nut.
84
• Water treatment
• Neutralization systems
• Water quality monitoring
• Swimming Pools and spas
• Aquaculture
• Agriculture and fertilizing systems
• Process control
MAIN FEATURES
• Epoxy body
• Single or double junction technology
• Large gel reference volume
• Easy and quick installation system
• Outline cable or BNC connection
• Version with temperature sensor combined
• Special versions on request
• Low cost fittings
TECHNICAL DATA
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• GOST R
Specific for pH-ORP.200
Model
Body
Junction
material/type
Reference
solution
Sensing
surface
O-ring
Connection
Max working
pressure
@ working
temperature
PH200C
epoxy
nylon/S.J.
3,5M KCl
glass membrane
-
5 mt. (16.5 ft.) Cable
7 bar @ 25°C/ 1 bar
@ 65°C
(100 psi @ 77°F/
14,5 psi @ 149°F)
PH222CD
epoxy
nylon/D.J.
3,5M KCl/
Sat’d KNO3
glass membrane
silicone
Twist-Lock (BNC)
7 bar @ 25°C/ 1 bar
@ 65°C
(100 psi @ 77°F/
14,5 psi @ 149°F)
glass membrane
silicone
Twist-Lock (BNC)
7 bar @ 25°C/ 1 bar
@ 65°C
(100 psi @ 77°F/
14,5 psi @ 149°F)
PH223CD
epoxy
nylon/D.J.
3,5M KCl/
Sat’d KNO3
ORP200C
epoxy
nylon/S.J.
3,5M KCl
platinum
-
5 mt. (16.5 ft.) Cable
7 bar @ 25°C/ 1 bar
@ 65°C
(100 psi @ 77°F/
14,5 psi @ 149°F)
ORP222CD
epoxy
nylon/D.J.
3,5M KCl/
Sat’d KNO3
platinum
silicone
Twist-Lock (BNC)
7 bar @ 25°C/ 1 bar
@ 65°C
(100 psi @ 77°F/
14,5 psi @ 149°F)
nylon/D.J.
3,5M KCl/
Sat’d KNO3
Twist-Lock (BNC)
7 bar @ 25°C/ 1 bar
@ 65°C
(100 psi @ 77°F/
14,5 psi @ 149°F)
nylon/D.J
3,5M KCl/
Sat’d KNO3
5 mt (16,5 ft)
7bar @ 25°C/ 1 bar
@ 65°C
(100 psi @ 77°F/
14,5 psi @ 149°F)
ORP223CD
PH222CDTC
epoxy
epoxy
platinum
Glass membrane
silicone
-
WWW.FLSNET.IT
85
pH/ORP ELECTRODES
General
• Operating Range:
- pH Electrodes: 0 - 14 pH (0 - 12.3 pH without Na+
error)
- ORP Electrodes: ± 2000 mV
• Temperature compensation device (for TC model):
PT1000
• Pipe Size Range: DN15 to DN100 (0.5” to 4”)
• Zero voltage point new electrode performances:
7.00pH ± 0.2pH
• Efficiency new electrode performances: > 97% @
25°C (77°F)
• Response time new electrode performances:
- pH: 2 sec for 95% of signal change
- ORP: application dependent
•Reference:
- electrolyte:
solidified gel 3.5M KCl for single junction versions
KCl-KNO3 for double junction versions
•Process Connection:
- in-line installation with:
threaded nipple ½”, ¾” or PG13,5
FLS installation fittings
- submersible installation
• Max Working pressure/ working temperature:
- 7 bar (100 psi) @ 25°C (77°F)
- 1 bar (14,5 psi) @ 65°C (149°F)
• Wetted materials:
- body: epoxy
- o-ring junction: silicone
- junction: Pellon®
- sensing surface: glass membrane (pH) platinum
(ORP)
• O-ring: Buna-N (PH222 CD, PH223 CD, ORP222
CD, ORP223 CD)
DIMENSIONS
A PH200C PH222CDTC ORP200C
B PH222CD ORP222CD
C PH223CD ORP223CD
1 Cable: 5 mt (6,5 ft.)
2 Epoxy body
3 pH glass bulb
4 BNC connector
5 Buna-N O-rings
6 FPM O-rings
ORDERING DATA
PH2XX Bulb pH Electrodes with epoxy body
Description /Name
Applications/
Operative Range
Cable
(sold separately)
Connection
Installation
Weight
(gr.)
Combination pH/Reference
Electrode
0 - 14 pH (0 - 12.3 pH
without Na+ error)
not required
5 mt. (16.5 ft.)
Cable
EG50P,
EG75P,
MK150200,
MIFV20X05,
MIMC20X05
200
PH222CD
Cartridge-type Double
Junction Combination pH/
Reference Electrode
0 - 14 pH (0 - 12.3 pH
without Na+ error)
CN 653, CN 653 TC1
Twist-Lock
(BNC)
EG50P,
EG75P,
MIFV20X05,
MIMC20X05
90
PH223CD
Cartridge-type Double
Junction Combination pH/
Reference Electrode for
FLS fittings
0 - 14 pH (0 - 12.3 pH
without Na+ error)
CN 653
Twist-Lock
(BNC)
F3.SP2.4
100
PH222CDTC
Cartridge-type Double
Junction Combination pH/
Reference Electrode with
Pt1000
0-14 pH (Na+ error
>12.3 pH)
5 mt (16,5 ft)
EG50P,
EG75P,
MK150200,
MIFV20X05,
MIMC20X05
220
Part No.
PH200C
Not required
ORP2XX Bulb ORP Electrodes with epoxy body
Part No.
Description /Name
Applications/
Operative Range
Cable
(sold separately)
Connection
Installation
Weight
(gr.)
EG50P,
EG75P,
MK150200,
MIFV20X05,
MIMC20X05
200
Combination ORP/
Reference Electrode
± 2000 mV
not required
5 mt. (16.5 ft.)
Cable
ORP222CD
Cartridge-type Double
Junction Combination
ORP/Reference Electrode
± 2000 mV
CN 653
Twist-Lock
(BNC)
EG50P,
EG75P,
MIFV20X05,
MIMC20X05
90
ORP223CD
Cartridge-type Double
Junction Combination
ORP/Reference Electrode
for FLS fittings
± 2000 mV
CN 653
Twist-Lock
(BNC)
F3.SP2.4
100
ORP200C
86
FLS pH/ORP 400
GLASS BODY BULB ELECTRODE
APPLICATIONS
pH/ORP ELECTRODES
This FLS line of pH/ORP
electrodes with glass body
has been designed to fit a
wide range of applications.
Different type of junctions
guarantee to find the proper
solution in according with
application needs: version
with open junction for a fast
response time, version with
ceramic junction useful for high
pressure application. Moreover
it’s available a version with
a special barriered single
junction which combine the
typical short response time of
standard single junction and
the contamination protection
of reference solution typical of
double junction. A dedicated
version for high temperature
application is present in our
range. Version with outline
cable or with head connection
(S7) are available also.
• Water treatment
• Neutralization systems
• Water quality monitoring
• Process control
• Agriculture and fertilizing systems
• Plating plant and tannery
• Cooling towers and scrubbers
MAIN FEATURES
• Glass body
• Cost effective electrodes
• Sensors suitable for extreme applications
• Installation easy and cheap
• Innovative reference solutions
• Cheap adaptors for installations
• Special versions available on request
WWW.FLSNET.IT
87
TECHNICAL DATA
General
• Operating range:
- pH electrodes: 0 - 14 pH (0 - 12.3 pH without Na+
error)
- ORP electrodes: ± 1000 mV
• Pipe size range: DN15 to DN100 (0.5” to 4”)
• Zero point voltage point new electrode performances:
7pH ± 0.2pH
• Efficiency new electrode performances: > 97% @
25°C (77°F)
• Response time new electrode performances:
- pH: 2 sec for 95% of signal change
- ORP: application dependent
• Reference:
- electrolyte: 3M KCl polymeric gel (different substrates
in according with model)
• Process connection:
- in-line installation with: PG13,5
• Max working pressure/ working temperature:
- 6 bar (90psi) @ 130°C (266°F) (PH435CD)
- 10 bar (145psi) @ 80°C (175°F) (PH430CD)
- 6 bar (90psi) @ 60°C (140°F) (PH425C, ORP425C)
• Wetted materials:
- body: glass
- junction: Open (PH435CD), Ceramic (PH430CD),
Open (PH425C, ORP425C)
- sensing surface: glass membrane (pH); platinum
(ORP)
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• GOST R
Specific for pH-ORP.400
Body
Junction
material/type
Reference
solution
Sensing
surface
O-ring
Connection
Max working
pressure
@ working
temperature
PH435CD
glass
Open/Double
junction
KCl 3M
Glass type H
Silicone
S7
6bar @ 130°C/
(85psi @ 266°F)
PH430CD
glass
Ceramic/Double
junction
KCl 3M
Glass type H
Silicone
S7
10bar @ 80°C/
(145psi @ 176°F)
ORP430CD
glass
Ceramic/Double
junction
KCl 3M
Glass type H
Silicone
S7
10bar @ 80°C/
(145psi @ 176°F)
PH425C
glass
Open/Single
junction
KCl 3M
Glass type H
Silicone
5 mt. (16.5 ft.) Cable
6bar @ 60°C/
(87psi @ 140°F)
ORP425C
glass
Open/Single
junction
KCl 3M
Glass type H
Silicone
5 mt. (16.5 ft.) Cable
6bar @ 60°C/
(87psi @ 140°F)
Model
88
DIMENSIONS
A PH425C, ORP425C
B PH435CD, PH430CD, ORP430CD
ORDERING DATA
pH4XX Bulb pH Electrodes with glass body
Description /Name
Applications/
Operative Range
Cable
(sold separately)
Connection
Installation
Weight
(gr.)
PH425C
Combination pH/Reference
electrode
0 - 14 pH (0 - 12.3 pH
without Na+ error)
Not Required
5 mt (16.5 ft)
GEG135
200
PH430CD
Double Junction
combination pH/Reference
electrode
0 - 14 pH (0 - 12.3 pH
without Na+ error)
CE5S7
S7
PH435CD
Double Junction
combination pH/Reference
electrode
For high temperature/0
- 14 pH (0 - 12.3 pH
without Na+ error)
CE5S7
S7
Part No.
GEG135
GEG135SE
EG135FS
EG135FL
GEG135
GEG135SE
EG135FS
EG135FL
200
200
ORP4XX Bulb ORP Electrodes with glass body
Description /Name
Applications/
Operative Range
Cable
(sold separately)
Connection
Installation
Weight
(gr.)
ORP425C
Combination ORP/
Reference electrode
± 1000 mV
Not Required
5 mt (16.5 ft)
GEG135
200
ORP430CD
Double Junction
combination ORP/
Reference electrode
± 1000 mV
CE5S7
S7
GEG135
GEG135SE
EG135FS
EG135FL
200
Part No.
WWW.FLSNET.IT
89
pH/ORP ELECTRODES
1 Cable: 5mt
2 Glass body
3 pH glass bulb
4 S7
FLS pH/ORP 600
PVCC BODY FLAT SURFACE ELECTRODE
APPLICATIONS
This is the rugged version of
the traditional flat electrodes
with an improved selfcleaning effect. Installation
and maintenance are easy
due to the quick disconnect
BNC connectors. Built into the
electrode’s body is a sealed,
gel-filled double junction
reference design. This
design provides an extra
barrier against reference
side contamination and
allows the electrodes to be
used in severe applications
prolonging electrode life.
The pH-responsive flat glass
surface is placed in the center
of the measuring surface and
surrounded by the flat porous
plastic reference junction
providing an excellent sample
contact.
A wide range of installation
accessories allows in line,
submersion or hot tap
installation.
90
• Water & Wastewater treatment
• Pre-chlorination & de-chlorination
• Neutralization systems
• Water quality monitoring
• Ozone treatment
• Coolingtowers
• Boiler systems
• Bleach production
• Pulp bleaching
• Aquaculture
• Fruit and vegetables washing
• Textile Dye Process
MAIN FEATURES
• pH and ORP versions
• Flat electrodes
• Double junction technology
• Large gel reference volume
• High protection from process contamination
• Easy and quick installation system
• BNC connector
• In line, submersion or hot tap installation
• Low cost fittings
• HF option (pH) for liquids with HF (max. 2%) inside
• DI option (pH) on request for pure water (<100uS)
• DA option for presence of stray currents or for long distance
due to signal amplification
TECHNICAL DATA
General
• Operating Range:
- pH Electrodes: 0 - 14 pH (0 - 12.3 pH without Na+
error)
- ORP Electrodes: ± 2000 mV
• Pipe Size Range: DN15 to DN100 (0.5” to 4”)
• Zero voltage point new electrode performances:
7.00pH ± 0.2pH
• Efficiency new electrode performances: > 97% @
25°C (77°F)
• Response time new electrode performances:
- pH: < 6 sec for 95% of signal change
- ORP: application dependent
• Reference
- type: sealed double junction
- electrolyte: Solidified Gel 3.5M KCl 0.1M KCl for LC
electrode version / solidified gel KCl 3.5M
- secondary junction: Nylon filament
- wire: Ag/AgCl.
• Process Connection:
- In-line installation:
threaded nipple ½”, ¾”
FLS installation fittings
- submersible installation
- hot-tap installation
• Max Working pressure/ working temperature:
- 6,7bar@75°C (100psi@170°F)
- 5,7bar@81°C (85psi@180°F)
• Wetted materials:
- body: C-PVC (PVDF only on request)
- reference Junction: porous HDPE
- sensing surface: glass membrane (pH),platinum
sealed in glass (ORP)
• O-ring: FPM (Viton)
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• GOST R
Body
Junction
material/type
Reference
solution
Sensing
surface
O-ring
Connection
Max working
pressure
@ working
temperature
PH660CD
C-PVC
HDPE porous/
D.J.
3,5M KCl
flat glass
membrane
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
ORP660CD
C-PVC
HDPE porous/
D.J.
3,5M KCl
platinum
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
PH650CD
C-PVC
HDPE porous/
D.J.
3,5M KCl
flat glass
membrane
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
ORP650CD
C-PVC
HDPE porous/
D.J.
3,5M KCl
platinum
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
PH655CD
C-PVC
HDPE porous/
D.J.
3,5M KCl
flat glass
membrane
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
ORP655CD
C-PVC
HDPE porous/
D.J.
3,5M KCl
platinum
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
Model
WWW.FLSNET.IT
91
pH/ORP ELECTRODES
Specific for pH-ORP.600
Specific for pH-ORP.600
Body
Junction
material/type
Reference
solution
Sensing
surface
O-ring
Connection
Max working
pressure
@ working
temperature
PH660CDHF
C-PVC
HDPE porous/
D.J.
3,5M KCl
flat glass
membrane
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
PH650CDHF
C-PVC
HDPE porous/
D.J.
3,5M KCl
flat glass
membrane
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
PH655CDHF
C-PVC
HDPE porous/
D.J.
3,5M KCl
flat glass
membrane
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
PH660CDDA
C-PVC
HDPE porous/
D.J.
3,5M KCl
flat glass
membrane
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
ORP660CDDA
C-PVC
HDPE porous/
D.J.
3,5M KCl
platinum
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
PH650CDDA
C-PVC
HDPE porous/
D.J.
3,5M KCl
flat glass
membrane
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
ORP650CDDA
C-PVC
HDPE porous/
D.J.
3,5M KCl
platinum
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
PH660CDLC
C-PVC
HDPE porous/
D.J.
0,1M KCl
flat glass
membrane
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
PH650CDLC
C-PVC
HDPE porous/
D.J.
0,1M KCl
flat glass
membrane
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
PH655CDLC
C-PVC
HDPE porous/
D.J.
0,1M KCl
flat glass
membrane
FPM
Twist-Lock (BNC)
6,7bar@75°C
(100psi@170°F)
Model
92
DIMENSIONS
1 BNC receptacle
2 Viton O-rings
3 Porous HDPE junction
4 pH glass or platinum
ORDERING DATA
ORP6XX CD Flat surface electrodes
Description /Name
Applications/
Operative Range
Cable
(sold separately)
Connection
Installation
Weight
(gr.)
ORP660CD
C-PVC Double Junction
ORP Combination Flat
surface Electrode
-
CN653
Twist-Lock
(BNC)
EG66P,
MK660
100
ORP650CD
C-PVC Double Junction
ORP Combination Flat
surface Electrode
-
CN653/CN653 TC1
Twist-Lock
(BNC)
MIFV20X05,
MIMC20X05
100
ORP655CD
C-PVC Double Junction
ORP Combination Flat
surface Electrode with
pressurized filling gel
-
CN653
Twist-Lock
(BNC)
WT675,
WT675TC1
100
ORP660CDDA
Ground Loop interrupt
Flat Surface pH/ORP
combination Electrode
Presence of stray
currents/ Signal
amplified
CN653
Twist-Lock
(BNC)
EG66P,
MK660
200
ORP650CDDA
Ground Loop interrupt
Flat Surface pH/ORP
combination Electrode
Presence of stray
currents/ Signal
amplified
CN653/CN653 TC1
Twist-Lock
(BNC)
MIFV20X05,
MIMC20X05
200
Part No.
WWW.FLSNET.IT
93
pH/ORP ELECTRODES
A Submersible PH650, ORP650
B In-line PH660, ORP660
C Insertion/Hot-tap PH655, ORP655
ORDERING DATA
pH6XX CD Flat surface electrodes
Description /Name
Applications/
Operative Range
Cable
(sold separately)
Connection
Installation
Weight
(gr.)
PH660CD
C-PVC Double Junction pH
Combination Flat surface
Electrode
-
CN653
Twist-Lock
(BNC)
EG66P,
MK660
100
PH650CD
C-PVC Double Junction pH
Combination Flat surface
Electrode
-
CN653/CN653TC1
Twist-Lock
(BNC)
MIFV20X05,
MIMC20X05
100
PH655CD
C-PVC Double Junction pH
Combination Flat surface
Electrode with pressurized
filling gel
-
CN653
Twist-Lock
(BNC)
WT675,
WT675TC1
100
PH660CDHF
C-PVC Double Junction pH
Combination Flat surface
Electrode
Liquids with HF (max
2%)
CN653
Twist-Lock
(BNC)
EG66P,
MK660
100
PH650CDHF
C-PVC Double Junction pH
Combination Flat surface
Electrode
Liquids with HF (max
2%)
CN653/CN653TC1
Twist-Lock
(BNC)
MIFV20X05,
MIMC20X05
100
PH655CDHF
C-PVC Double Junction pH
Combination Flat surface
Electrode with pressurized
filling gel
Liquids with HF (max
2%)
CN653
Twist-Lock
(BNC)
WT675,
WT675TC1
100
PH660CDDA
Ground Loop interrupt Flat
Surface pH combination
Electrode
Presence of stray
currents/ Signal
amplified
CN653
Twist-Lock
(BNC)
EG66P,
MK660
200
PH650CDDA
Ground Loop interrupt Flat
Surface pH combination
Electrode
Presence of stray
currents/ Signal
amplified
CN653/CN653TC1
Twist-Lock
(BNC)
MIFV20X05,
MIMC20X05
200
PH660CDLC
C-PVC Double Junction pH
Combination Flat surface
Electrode
Liquids with low
conductivity (<100 ms)
CN653
Twist-Lock
(BNC)
EG66P,
MK660
100
PH650CDLC
C-PVC Double Junction pH
Combination Flat surface
Electrode
Liquids with low
conductivity (<100 ms)
CN653/CN653TC1
Twist-Lock
(BNC)
MIFV20X05,
MIMC20X05
100
PH655CDLC
C-PVC Double Junction pH
Combination Flat surface
Electrode with pressurized
filling gel
Liquids with low
conductivity (<100 ms)
CN653
Twist-Lock
(BNC)
WT675,
WT675TC1
100
Part No.
94
FLS pH 800
RYTON BODY FLAT SURFACE ELECTRODE
APPLICATIONS
pH/ORP ELECTRODES
The new pH electrodes line
870 combines a tough ryton
body with auto-cleaning flat
pH surface and with a reliable
Pt1000 for an accurate
measurement in dirty liquid as
well as in aggressive solutions.
In addiction a wide junction
improves performances in
presence of suspended solids.
The new 870 electrodes allow
a direct installation by their
¾” threaded included in the
body: in-line installation using
the threads on the electrode
bottom or submersible
installation using the threads
on the electrode head.
Availability of specific versions
for special applications as:
horizontal mounting (-HM),
low conductive samples (-LC),
aggressive solutions (HF<2%)/
low values of pH (-HF).
• Processing and Manufacturing industry
• Chemical processing
• Water treatment processes
• Cooling processes
• Heating processes
MAIN FEATURES
• Temperature sensor combined
• Flat surface electrodes
• Tough Ryton body
• Double threaded body for in line and submersion installation
• Double junction technology
• HM option for horizontal mounting
• HF option for liquids with HF (max 2%)
• LC option for liquid with a conductivity lower than 100µS
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95
TECHNICAL DATA
General
• Operating Range:
- pH Electrodes : 0-14 pH (0-12,3 pH without Na+ error )
• Pipe Size Range: DN15 to DN100 (0.5” to 4”)
• Zero voltage point new electrode performances:
7.00pH ± 0.2pH
• Efficiency new electrode performances: > 97% @
25°C (77°F)
• Response time new electrode performances:
- pH: < 6 sec for 95% of signal change
• Reference
- type: sealed double junction
- electrolyte: Solidified Gel 3.5M KCl 0.1M KCl for LC
electrode version / solidified gel KCl 3.5M
- secondary junction: Nylon filament
- wire: Ag/AgCl.
• Process Connection:
- 3/4” NPT threaded body for submersion or in-line
installation”
• Max Working pressure/ working temperature:
- 6,7bar@75°C (100psi@170°F)
- 5,7bar@81°C (85psi@180°F)
- 3,3bar@100°C (50 psi@212°F)
• Wetted materials:
- body: PPS (Ryton®), HDPE, pH Glass, leaded glass
- reference Junction: porous HDPE
- sensing surface: glass membrane
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• GOST R
Specific for pH.800
Body
Junction
material/type
Reference
solution
Sensing
surface
O-ring
Connection
Max working pressure @
working temperature
PH870CDTC
Ryton
HDPE porous/
D.J.
3,5M KCl
Flat glass
membrane
-
5 mt (16,5 ft)
cable
75°C(170°F)/6,7 bar (100psi),
80°C(180°F)/5,5bar (85psi),
100°C(212°F)/3,3bar (50 psi)
PH870CDTCHM
Ryton
HDPE porous/
D.J.
3,5M KCl
Flat glass
membrane
-
5 mt (16,5 ft)
cable
75°C(170°F)/6,7 bar (100 psi),
80°C(180°F)/5,5bar (85 psi),
100°C(212°F)/3,3bar (50 psi)
PH870CDTCLC
Ryton
HDPE porous/
D.J.
0,1M KCl
Flat glass
membrane
-
5 mt (16,5 ft)
cable
75°C(170°F)/6,7 bar (100 psi),
80°C(180°F)/5,5bar (85 psi),
100°C(212°F)/3,3bar (50 psi)
PH870CDTCHF
Ryton
HDPE porous/
D.J.
3,5M KCl
Flat glass
membrane
-
5 mt (16,5 ft)
cable
75°C(170°F)/6,7 bar (100 psi),
80°C(180°F)/5,5bar (85 psi),
100°C(212°F)/3,3bar (50 psi)
Model
96
DIMENSIONS
pH/ORP ELECTRODES
1 Cable: 5 m (16,5 ft)
2 Ryton body
3 Flat pH glass
4 Porous HDPE junction
5 Temperature sensor inside pH stem
6 ¾” NPT threads
7 Wrench flat
ORDERING DATA
PH870CDTCXX Ryton Body Flat Surface Electrodes
Description /Name
Applications/
Operative Range
Cable
(sold separately)
Connection
Installation
Weight
(gr.)
PH870CDTC
Ryton double junction flat
surface pH electrode with
Pt1000
0-14 pH
(0-12,3 pH without Na+
error)
Not required
5 mt (16,5 ft)
3/4” NPT
250
PH870CDTCHM
Ryton double junction flat
surface pH electrode with
Pt1000
0-14 pH
(0-12,3 pH without
Na+ error)/Horizontal
mounting
Not required
5 mt (16,5 ft)
3/4” NPT
250
PH870CDTCLC
Ryton double junction flat
surface pH electrode with
Pt1000
0-14 pH
(0-12,3 pH without Na+
error)/ Low conductivity
(<100µS)
Not required
5 mt (16,5 ft)
3/4” NPT
250
PH870CDTCHF
Ryton double junction flat
surface pH electrode with
Pt1000
0-14 pH
(0-12,3 pH without Na+
error)/Presence of HF
(max 2%)
Not required
5 mt (16,5 ft)
3/4” NPT
250
Part No.
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97
INSTALLATION
& OPERATING GUIDELINES
FOR pH/ORP ELECTRODES
98
INSTALLATION GUIDELINES
In line installation is available for all pH/ORP sensor families.
In line installation is suggested for application in a pipe range from DN15
up to DN100.
For installation in small pipes pay attention that pH glass is not in contact
with pipe surface.
pH/ORP electrodes can be installed at 30° maximum from vertical
position (except for hot tap version of 600 electrodes family) being sure
that sensor is completely in contact with the measured solution. (Fig. A)
Submersible
Submersible installation is available for 200 electrodes family and for 600
electrodes family.
Electrode should be installed near tank outlet away from addition areas in
order to measure a representative solution.
Sensor should be below the drain level to prevent the electrode from
drying out (in case CN653TC1 is applied, take care about positioning of
temperature sensor pin). (Fig. B)
Hot-tap
Hot tap installation is available only for a special version of 600 electrodes
family (PH655CD, ORP655CD) combined with WT675 or WT675TC1 (in
case temperature compensation is requested).
Hot tap installation can be useful in case application needs a positioning
of electrode different than standard 30° (sensor can work in all positions)
as well for in line application where it can’t be depressurized during
maintenance.
Hot tap installation can also solve problem to perform a in-line installation
on pipes bigger than DN100. (Fig. C)
WWW.FLSNET.IT
pH/ORP ELECTRODES
In line
99
OPERATING GUIDELINES
Storage
When pH readings are made infrequently, for example, several days
or weeks apart, the electrode can be stored simply by replacing it in its
soaker bottle/protection cap. If the storage solution in the soaker bottle is
missed/dried, use 3M KCl or pH 4 buffer.
Care & Cleaning
Coating of an electrode’s measuring surface can lead to erroneous
readings including shortened span and slow response times.
The type of coating determines the type of cleaning technique.
Soft coatings can be removed by vigorous stirring, by use of a squirt bottle
or, very carefully, by gently wiping with a soft and clean non-abrasive
paper or cloth.
Do not use any brush or abrasive cleaner on pH glass. Hard Coatings
should be chemically removed. The chemical used to remove the coating
should be the least harsh chemical that dissolves the coating in 1 or 2
minutes and does not attack the electrode’s materials of construction.
Abrading or sanding a pH electrode’s surface should never be done.
ORP/REDOX: electrode may be gently abraded by use of 600 grade wet
silicon carbide paper, jeweler’s rouge or very fine steel wool, but try to
clean chemically before abrading with 600 grade paper.
Reconditioning
When reconditioning is required due to electrode aging (see Operating
Instruction), the following chemical treatments can be tried.
They are presented in the order of the severity of attack on the pH glass
and may not improve (and in some cases actually further deteriorate)
electrode performance.
NOTE: Use proper precautions when handling these hazardous chemicals.
Ammonium bifluoride and HF (hydrofluoric acid) are extremely hazardous
and should only be used by qualified personnel.
1. Immerse the electrode tip in 0.1 N HCl for 15 seconds, rinse in tap water
and then immerse tip in 0.1 M NaOH for 15 seconds and rinse in tap water.
Repeat this sequence three times and then recheck the electrode’s
performance. If performance has not been restored, try Step 2.
2. Immerse the tip in a 20% solution of NH4F-HF (ammonium bifluoride)
for 2 to 3 minutes, rinse in tap water and recheck performance.
If performance has not been restored try Step 3.
3. Immerse electrode tip in 5% HF for 10-15 seconds, rinse well in
tap water, quickly rinse in 5N HCl, rinse well in tap water and recheck
performance.
If performance has not been restored, it is time to get another pH
electrode.
ORP/REDOX: clean metal surfaces with a mildly abrasive medium, e.g.
toothpaste of very fine scouring powder.
Calibration
Calibration is fundamental to achieve a good accuracy and a reliable
measurement.
The frequency of calibration is function of the electrode, the pH meter and
the solutions the electrode is exposed to.
Moreover this frequency is correlated to temperature of application and to
how much critical the measurement is.
Automatic calibration with standard value of buffer (pH7, pH4, pH10) can
be used for general purpose.
Consider that pH 10 buffer is less stable than pH 4 buffer as CO2 can
be dissolved in. So, in case User wants to use the same buffer bottle for
several calibration, it’s better to prefer pH 4. Don’t forget to clean electrode
in some water before to dip it in each buffer in order to avoid a buffer
contamination.
In case User needs a higher precision at a fixed value, a manual
calibration could help this need as User can perform a calibration using
buffers around expected value.
WWW.FLSNET.IT
100
POTENTIOMETRIC AND INDUCTIVE
CONDUCTIVITY SENSORS
A WIDE RANGE OF MEASUREMENT
OPTIONS FROM ULTRA PURE WATER
TO DIRTY LIQUIDS
FLS C150-200
GRAPHITE OR PLATINUM CONDUCTIVITY
SENSOR
APPLICATIONS
The FLS C150-200
conductivity sensors feature
graphite or high resolution
platinum ring technology.
Durable epoxy body
construction provides rugged
and dependable sensors.
These sensors provide
accurate and high resolution
measurement thanks to the
included temperature sensor
(Pt100) combined with the
ATC (Automatic Temperature
Compensation) function of the
monitor/transmitter. They can
be used for both laboratory
and industrial applications.
Sensor electrodes are well
protected so cell constant can’t
be easily damaged by solids
presence. Three cell constants
are available depending on
the operating range required.
A simple and reusable gland
can be used for economic
electrode in-line mounting
while a ½” or ¾” coupler with
a pipe extension is enough
for submersion mounting. A
specific kit allows to mount
these probes on FLS T fitting
as well as to FLS clamp
saddle.
100
• Chemical concentrations
• Foods industry
• Steam generation
• Metal finishing and mining
• Textile industry
• Pulp and paper
• Water treatment
• Reverse osmosis
• Softener regeneration
• De-ionization
• Distillation
• Aquaculture
• Agriculture and fertilizing systems
MAIN FEATURES
• Graphite or Platinum measuring surfaces
• Suitable for laboratory, industrial or portable applications
• In line and submersion installation
• Temperature sensor included
• Cell constant choices of 0.1 and 10
TECHNICAL DATA
General
• Operating Range:
- C150.01 TC, C200.01 TC: 0.1 µS to 2000 µS
(10 MΩ to 500 Ω)
- C150.1 TC, C200.1 TC: 1 µS to 20000 µS
- C200.10 TC: 10 µS to 200000 µS
• Temp. compensation device (for TC models): Pt100
• Cable length: 5 meter (16 ft.)
• Max. distance electrode-controller (without signal
conditioning): 20 meter (66 ft)
• Process Connection:
- in-line installation with:
threaded nipple ½” or ¾”
FLS installation fittings
submersible installation
• Working temperature: 0°C to 70°C (32°F to 158°F)
• Max. Working Pressure: 7 bar (100 psi)
• Wetted materials:
- body: epoxy
- measuring surface: graphite (C150 version) or
platinum (C200 version)
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
CONDUCTIVITY SENSORS
DIMENSIONS
A C150.01 TC
B C150.1 TC
C C200.01 TC
D C200.1 TC
E C.200.10 TC
1 Cable: 5m (16,5 ft.)
2 Epoxy body
3 Graphite electrodes
4 Platinum electrodes
WWW.FLSNET.IT
101
ORDERING DATA
C150 Epoxy body Conductivity Sensors
Description /Name
Applications/
Operative Range
Cell Constant
Connection
Installation
Weight
(gr.)
C150.01TC
Graphite Conductivity
Sensor with Temperature
Sensor included
0.1 µS to 2000 µS
0,1 Cell
5 m (16,5 ft.)
EG50P,
EG75P,
MIFV20X05,
MIMC20X05
200
C150.1TC
Graphite Conductivity
Sensor with Temperature
Sensor included
5 m (16,5 ft.)
EG50P,
EG75P,
MIFV20X05,
MIMC20X05,
MK150200
200
Part No.
1 µS to 20000 µS
1,0 Cell
C200 Epoxy body Conductivity Sensors
Description /Name
Applications/
Operative Range
Cell Constant
Connection
Installation
Weight
(gr.)
C200.01TC
Platinum Conductivity
Sensor with Temperature
Sensor included
0.1 µS to 2000 µS
0,1 Cell
5 m (16,5 ft.)
EG50P,
EG75P,
MIFV20X05,
MIMC20X05
200
C200.1TC
Platinum Conductivity
Sensor with Temperature
Sensor included
1 µS to 20000 µS
1,0 Cell
5 m (16,5 ft.)
EG50P,
EG75P,
MIFV20X05,
MIMC20X05
200
C200.10TC
Platinum Conductivity
Sensor with Temperature
Sensor included
5 m (16,5 ft.)
EG50P,
EG75P,
MIFV20X05,
MIMC20X05
200
Part No.
102
10 µS to 200000 µS
10,0 Cell
FLS C100-300
STAINLESS STEEL CONDUCTIVITY SENSOR
APPLICATIONS
MAIN FEATURES
• Stainless steel measuring surfaces
• Considerable ratio performance/price
• Temperature sensor included
• Wide range of cell constant
• Rugged sensor body in PP (C100)
• Sensor in SS completely (C300)
• C300.001TCCK with certified cell constant
CONDUCTIVITY SENSORS
The FLS conductivity sensors
with stainless steel electrodes
(C100 series) are designed
for agriculture application and
for light industrial application
obviously where sample
conditions allow a steel
using (water treatment, foods
industry and others). This type
of sensors are characterized
by a considerable ratio
performance/price. The
combination of temperature
sensor with the ATC
(Automatic Temperature
Compensation) function of the
monitor/transmitter allow to
get a precise measurement.
Moreover a wide number of
cell constants grants to choose
the best item for specific
application.
C300 serie has been designed
for ultrapure water monitoring
(certified cell constant 0,01)
and for waste water application
(cell constant 10). C300
sensors are completely made
in SS ensuring suitability for
a wide range of applications.
• Agriculture and fertilizing system
• Water treatment
• Foods industry
• Aquaculture
• Ultrapure water application: production and use
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103
TECHNICAL DATA
General
• Operating range:
- C300.001 TC: 0,055 µS to 200 µS (18,2 MΩ to 5 KΩ)
- C100.01 TC: 0.1 µS to 2000 µS (10 MΩ to 500 Ω)
- C100.02 TC: 0.2 µS to 4000 µS
- C100.1 TC: 1 µS to 20000 µS
- C300.10 TC: 10 µS to 200000 µS
• Temperature compensation device (for TC models):
- Pt 100 (C100TC), Pt1000 (C300TC)
• Cable length:
- C100.01 TC, C100.02 TC, C100.1 TC: no cable
available
- C300 TC: 3m
• Process connection:
- C100.01 TC, C100.02 TC, C100.1 TC: ¾” male BSP
- C300.TC: ¾” male BSP fitting
• Max. Working Temperature:
- C100.01 TC, C100.02 TC, C100.1 TC : 80°C (176°F)
- C300TC: 80°C (PP fitting), 120°C (SS fitting)
• Max. Working Pressure:
- C100.01 TC, C100.02 TC, C100.1 TC: 6 bar (85 psi)
- C300 TC: 7 bar (PP fitting), 13 bar (SS fitting)
• Wetted materials:
- body:
C100.01 TC, C100.02 TC, C100.1 TC: PP;
C300 TC: SS 316
- measuring surface: stainless steel AISI 316
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
DIMENSIONS
A C100.01 TC
B C100.1 TC, C100.02 TC
C C300.001 TC
D C300.10 TC
104
2 PP body ½ “ male threaded BSP
3 Stainless Steel electrodes
4 4-Poles connector
5 PP body ¾” male threaded BSP
6 Cable: 3m (10 ft.)
ORDERING DATA
C100 Stainless Steel Electrodes Conductivity Sensors
Description /Name
Applications/
Operative Range
Cell Constant
Connection
Installation
Weight
(gr.)
C100.01TC
PP body sensor with SS
Conductivity Electrode
and Temperature Sensor
included
0.1 µS to 2000 µS
0,1
4 poles
connector
¾” male
BSP (parallel
threaded)
350
C100.02TC
PP body sensor with SS
Conductivity Electrode
and Temperature Sensor
included
0.2 µS to 4000 µS
0,2
4 poles
connector
¾” male
BSP (parallel
threaded)
350
C100.1TC
PP body sensor with SS
Conductivity Electrode
and Temperature Sensor
included
1 µS to 20000 µS
1
4 poles
connector
¾” male
BSP (parallel
threaded)
350
Part No.
C300 Stainless Steel Electrodes Conductivity Sensors
Part No.
C300.001TC
C300.001TCCK
Applications/
Operative Range
Cell Constant
Connection
Installation
Weight
(gr.)
Body sensor and
conductivity electrodes
in SS
0,055 µS to 200 µS
0,01
3m
EG12 SS
150
Body sensor
and conductivity electrodes
in SS with certified
cell constant
0,055 uS to 200 µS
0,01
3m
EG12SS
150
Body sensor and
conductivity electrodes
in SS
10 µS to 200000 µS
10
3m
EG12 SS
150
WWW.FLSNET.IT
105
CONDUCTIVITY SENSORS
C300.10TC
Description /Name
FLS C6.30
INDUCTIVE CONDUCTIVITY TRANSMITTER
APPLICATIONS
FLS C6.30 is a family
of inductive conductivity
transmitters which are
made by a 4-20mA output
device (two wire technology)
integrated onto an inductive
conductivity sensor. This type
of measurement technology
allows a broad range of
applications especially
to measure high values
of conductivity (till 1000
millisiemens) in aggressive
fluids (PVCC is the only wetted
material). As no electrodes
are directly in contact with
liquid, a reliable and stable
measurement is guaranteed
for a long operating time. A
proper automatic temperature
compensation (ATC) is granted
by a Pt100 integrated into
instrument body. The isolated
4-20mA output is perfect for
direct connections to PLCs or
data loggers without any extra
interfaces. Transmitter as well
as temperature sensor are
supplied already calibrated.
106
• Water treatment
• Waste water treatment
• Cooling towers
• Scrubber systems
• Metal finishing Coating and corrosion fluid measurement
MAIN FEATURES
• Corrosion & coating resistant
• Compact transmitter
• No calibration required
• Easy installation
• Pt100 sensor integrated
• Suitable for submersible installation
TECHNICAL DATA
General
• Body Material: C-PVC
• Body length: 207mm
• Enclosure: IP68
• Power supply: 10-30 VDC regulated
• Max Working pressure/Working
Temperature:
- 10bar (145psi) @ 25°C (77°F)
- 6bar (87psi) @ 50°C (122°F)
• Process connection: 1 ½” male NPT
Standards & Approvals
• Manufactured under ISO 9001
• Manufactured under ISO 14001
• CE
• RoHS Compliant
• GOST R
CONDUCTIVITY SENSORS
DIMENSIONS
1 Cable:3 mt (9 ft.)
2 1 ½” male NPT
3 C-PVC coating
WWW.FLSNET.IT
107
ORDERING DATA
C6.30 Inductive Conductivity Transmitters
Description /Name
Applications/
Operative Range
Cell Constant
Connection
Installation
Weight
(gr.)
C6.30.01
C-PVC Inductive
Conductivity Transmitter
with Temperature Sensor
included
0-10 mS
-
3 mt
1 1/2" NPT
male threaded
550
C6.30.02
C-PVC Inductive
Conductivity Transmitter
with Temperature Sensor
included
0-100 mS
-
3 mt
1 1/2" NPT
male threaded
550
C6.30.03
C-PVC Inductive
Conductivity Transmitter
with Temperature Sensor
included
0-1000 mS
-
3 mt
1 1/2" NPT
male threaded
550
Part No.
108
INSTALLATION
& OPERATING GUIDELINES
FOR CONDUCTIVITY SENSORS
INSTALLATION GUIDELINES
In line
In line installation is available for all conductivity sensor families.
It’s possible to perform 2 different types of in-line installation: vertically on
a straight pipeline using a proper T fitting or through the side of a T fitting.
The first installation should be performed mounting upside down (or at
least at 45°) as this condition help to prevent air entrapment.
The second installation type is preferred since this configuration reduces
the probability of entrapped air bubbles and provides the best continous
sampling of the fluid.
Pay attention that the electrodes of the sensor are completely dipped into
a representative solution (not in a dead volume).
Conductivity sensors can work properly in any direction.
Submersible
Submersible installation is available for C150/C200 sensor family.
Sensor should be installed near tank outlet away from addition areas in order
to measure a representative solution.
OPERATING GUIDELINES
Care & Cleaning
All conductivity sensors can be cleaned with a gentle detergent.
C150/C200 sensor families can be cleaned using a 5% HCl solution also.
Do not sand or abrade the electrodes surface as abrasion changes the
surface area and will cause erroneous readings.
Anyway every solution compatible with electrodes material and sensor
body material can be used.
Calibration
Calibration is fundamental to achieve a good accuracy and a reliable
measurement.
The frequency of calibration is a function of the sensor and the solutions
that conductivity sensor has to measure.
Moreover this frequency is correlated to how much critical the
measurement is.
Pay attention that air bubbles are not present during calibration since
such condition could cause a erroneous readings.
As temperature affects strongly conductivity measurement, pay attention
on:
•reference temperature (it should be the same for monitor and for
calibration solution)
•temperature compensation: if it’s activated User should use conductivity
value of calibration solution at reference temperature; if it’s not activated
User should refer to conductivity value of calibration solution at calibration
solution temperature.
•temperature compensation factor: check if it’s proper for calibration/
measured solution.
110
INSTALLATION FITTINGS
FOR FLOW SENSORS
AND ANALYTICAL ELECTRODES
STANDARD INSERTION
INSTALLATION
INSTALLATION ON PVC PIPES
ISO Metric PVC Tee Fittings (female ends for solvent welding)
DN/
Size
d/R
O-ring
Body
TFIV20B
15
20
EPDM
TFIV25B
20
25
EPDM
TFIV32B
25
32
TFIV40B
32
40
TFIV50B
40
TFIV20D
15
Part No.
E
Flow
Sensor
Lenght
73
53
L0
F&A
8
62
L0
F&A
22
81
71
L0
F&A
26
84
84
L0
F&A
137
31
82.5
98
L0
F&A
81
16
73
53
L0
F&A
H
Z
L
B
UPVC
113
UPVC
126
81
16
88
19
EPDM
UPVC
EPDM
UPVC
139.5
95.5
170
118
50
EPDM
UPVC
199
20
FPM
UPVC
113
Suitable
for (*)
TFIV25D
20
25
FPM
UPVC
126
88
19
8
62
L0
F&A
TFIV32D
25
32
FPM
UPVC
139.5
95.5
22
81
71
L0
F&A
TFIV40D
32
40
FPM
UPVC
170
118
26
84
84
L0
F&A
TFIV50D
40
50
FPM
UPVC
199
137
31
82.5
98
L0
F&A
ISO Metric Clamp Saddles
DN/
Size
d/R
O-ring
Body
Insert
H
E
h
Drilling
Hole
Flow
Sensor
Lenght
Suitable
for (*)
SVIC063BVC
50
63
EPDM
UPVC
C-PVC
105
116
86.7
35
L0
F&A
SVIC075BVC
65
75
EPDM
UPVC
C-PVC
105
134
90.8
35
L0
F&A
SVIC090BVC
80
90
EPDM
UPVC
C-PVC
105
152
95.9
40
L0
F&A
SVIC110BVC
100
110
EPDM
UPVC
C-PVC
105
176
102.8
40
L0
F&A
SVIC125BVC
110
125
EPDM
UPVC
C-PVC
112
190
137.9
40
L1
F
SVIC140BVC
125
140
EPDM
UPVC
C-PVC
114
214
143.1
40
L1
F
SVIC160BVC
150
160
EPDM
UPVC
C-PVC
120
238
149.9
40
L1
F
SVIC200BVC
180
200
EPDM
UPVC
C-PVC
133
300
163.7
40
L1
F
SVIC225BVC
200
225
EPDM
UPVC
C-PVC
125
333
172.3
40
L1
F
SVIC063DVC
50
63
FPM
UPVC
C-PVC
105
116
86.7
35
L0
F&A
F&A
SVIC075DVC
65
75
FPM
UPVC
C-PVC
105
134
90.8
35
L0
SVIC090DVC
80
90
FPM
UPVC
C-PVC
105
152
95.9
40
L0
F&A
SVIC110DVC
100
110
FPM
UPVC
C-PVC
105
176
102.8
40
L0
F&A
SVIC125DVC
110
125
FPM
UPVC
C-PVC
112
190
137.9
40
L1
F
SVIC140DVC
125
140
FPM
UPVC
C-PVC
114
214
143.1
40
L1
F
SVIC160DVC
150
160
FPM
UPVC
C-PVC
120
238
149.9
40
L1
F
SVIC200DVC
180
200
FPM
UPVC
C-PVC
133
300
163.7
40
L1
F
SVIC225DVC
200
225
FPM
UPVC
C-PVC
125
333
172.3
40
L1
F
SMIC250IVC*
225
250
NBR
PP
C-PVC
79
324
203.5
40
L0
F
SMIC280IVC*
250
280
NBR
PP
C-PVC
88
385
212.2
40
L1
F
SMIC315IVC*
280
315
NBR
PP
C-PVC
88
385
220.1
40
L1
F
* For IP68 sensors or compact monitors only
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
WWW.FLSNET.IT
113
INSTALLATION FITTINGS
Part No.
INSTALLATION ON PVC PIPES
BSP Female Threaded PVC Tee Fittings (parallel threaded female ends)
DN/
Size
d/R
O-ring
Body
TFFV20B
15
1/2"
EPDM
TFFV25B
20
3/4"
EPDM
TFFV32B
25
1"
EPDM
Part No.
L
B
E
Flow
Sensor
Lenght
Suitable
for (*)
88.5
15
73
53
L0
F&A
94.9
16.3
80
62
L0
F&A
107.8
19.1
81
71
L0
F&A
H
Z
UPVC
118.5
UPVC
127.5
UPVC
146
TFFV40B
32
1 1/4"
EPDM
UPVC
177
134.2
21.4
84
84
L0
F&A
TFFV50B
40
1 1/2"
EPDM
UPVC
191
148.2
21.4
82.5
98
L0
F&A
TFFV20D
15
1/2"
FPM
UPVC
118.5
88.5
15
73
53
L0
F&A
TFFV25D
20
3/4"
FPM
UPVC
127.5
94.9
16.3
80
62
L0
F&A
TFFV32D
25
1"
FPM
UPVC
146
107.8
19.1
81
71
L0
F&A
TFFV40D
32
1 1/4"
FPM
UPVC
177
134.2
21.4
84
84
L0
F&A
TFFV50D
40
1 1/2"
FPM
UPVC
191
148.2
21.4
82.5
98
L0
F&A
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
114
INSTALLATION ON PVC PIPES
BS Solvent Welding PVC Tee Fittings (female ends for solvent welding)
DN/
Size
d/R
O-ring
Body
TFLV20B
15
1/2"
EPDM
UPVC
TFLV25B
20
3/4"
EPDM
UPVC
TFLV32B
25
1"
EPDM
UPVC
TFLV40B
32
1 1/4"
EPDM
UPVC
TFLV50B
40
1 1/2"
EPDM
UPVC
Part No.
H
E
Flow
Sensor
Lenght
73
53
L0
F&A
80
62
L0
F&A
71
L0
F&A
84
L0
F&A
82.5
98
L0
F&A
F&A
Z
L
B
113
8
16.5
126
88
19
139.5
94.5
22.5
81
17
118
26
84
199
139
30
Suitable
for (*)
TFLV20D
15
1/2"
FPM
UPVC
113
8
16.5
73
53
L0
TFLV25D
20
3/4"
FPM
UPVC
126
88
19
80
62
L0
F&A
TFLV32D
25
1"
FPM
UPVC
139.5
94.5
22.5
81
71
L0
F&A
TFLV40D
32
1 1/4"
FPM
UPVC
17
118
26
84
84
L0
F&A
TFLV50D
40
1 1/2"
FPM
UPVC
199
139
30
82.5
98
L0
F&A
BS Clamp Saddles
h
Drilling
Hole
Flow
Sensor
Lenght
Suitable
for (*)
105
116
85.3
35
L0
F&A
105
152
95.0
40
L0
F&A
C-PVC
105
176
103.5
40
L0
F&A
UPVC
C-PVC
120
238
151.7
40
L1
F
EPDM
UPVC
C-PVC
125
333
169.8
40
L1
F
2"
FPM
UPVC
C-PVC
105
116
85.3
35
L0
F&A
80
3"
FPM
UPVC
C-PVC
105
152
95.0
40
L0
F&A
100
4"
FPM
UPVC
C-PVC
105
176
103.5
40
L0
F&A
150
6"
FPM
UPVC
C-PVC
120
238
151.7
40
L1
F
200
8"
FPM
UPVC
C-PVC
125
333
169.8
40
L1
F
DN/
Size
d/R
O-ring
Body
Insert
H
SVLC2.0BVM
50
2"
EPDM
UPVC
C-PVC
SVLC3.0BVM
80
3"
EPDM
UPVC
C-PVC
SVLC4.0BVM
100
4"
EPDM
UPVC
SVLC6.0BVM
150
6"
EPDM
SVLC8.0BVM
200
8"
SVLC2.0DVM
50
SVLC3.0DVM
SVLC4.0DVM
SVLC6.0DVM
SVLC8.0DVM
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
WWW.FLSNET.IT
115
INSTALLATION FITTINGS
E
Part No.
INSTALLATION ON PVC PIPES
ASTM SCH. 80 PVC Tee Fittings (female ends for solvent welding)
DN/
Size
d/R
O-ring
Body
H
Z
L
B
E
Flow
Sensor
Lenght
Suitable
for (*)
TFAV20B
15
1/2"
EPDM
UPVC
4.92"
3.15"
0.89"
2.87"
2.09"
L0
F&A
TFAV25B
20
3/4"
EPDM
UPVC
5.51"
3.50"
1.00"
3.15"
2.44"
L0
F&A
TFAV32B
25
1"
EPDM
UPVC
6.04"
3.78"
1.13"
3.19"
2.80"
L0
F&A
TFAV40B
32
1 1/4"
EPDM
UPVC
7.34"
4.80"
1.26"
3.31"
3.31"
L0
F&A
TFAV50B
40
1 1/2"
EPDM
UPVC
8.15"
5.39"
1.38"
3.25"
3.86"
L0
F&A
TFAV20D
15
1/2"
FPM
UPVC
4.92"
3.15"
0.89"
2.87"
2.09"
L0
F&A
TFAV25D
20
3/4"
FPM
UPVC
5.51"
3.50"
1.00"
3.15"
2.44"
L0
F&A
TFAV32D
25
1"
FPM
UPVC
6.04"
3.78"
1.13"
3.19"
2.80"
L0
F&A
TFAV40D
32
1 1/4"
FPM
UPVC
7.34"
4.80"
1.26"
3.31"
3.31"
L0
F&A
TFAV50D
40
1 1/2"
FPM
UPVC
8.15"
5.39"
1.38"
3.25"
3.86"
L0
F&A
Part No.
NPT Female Threaded PVC Tee Fittings (NPT threaded female ends)
DN/
Size
d/R
O-ring
Body
H
Z
L
B
E
Flow
Sensor
Lenght
Suitable
for (*)
TFNV20B
15
1/2"
EPDM
UPVC
4.67"
3.26"
0.70"
2.87"
2.09"
L0
F&A
TFNV25B
20
3/4"
EPDM
UPVC
5.02"
3.60"
0.71"
3.15"
2.44"
L0
F&A
TFNV32B
25
1"
EPDM
UPVC
5.75"
3.97"
0.89"
3.19"
2.80"
L0
F&A
TFNV40B
32
1 1/4"
EPDM
UPVC
6.97"
5.12"
0.93"
3.31"
3.31"
L0
F&A
TFNV50B
40
1 1/2"
EPDM
UPVC
7.52"
5.28"
1.12"
3.25"
3.86"
L0
F&A
TFNV20D
15
1/2"
FPM
UPVC
4.67"
3.26"
0.70"
2.87"
2.09"
L0
F&A
TFNV25D
20
3/4"
FPM
UPVC
5.02"
3.60"
0.71"
3.15"
2.44"
L0
F&A
TFNV32D
25
1"
FPM
UPVC
5.75"
3.97"
0.89"
3.19"
2.80"
L0
F&A
TFNV40D
32
1 1/4"
FPM
UPVC
6.97"
5.12"
0.93"
3.31"
3.31"
L0
F&A
TFNV50D
40
1 1/2"
FPM
UPVC
7.52"
5.28"
1.12"
3.25"
3.86"
L0
F&A
Part No.
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
116
INSTALLATION ON PVC PIPES
ASTM Clamp Saddles
d/R
O-ring
Body
Insert
H
E
h
Drilling
Hole
Flow
Sensor
Lenght
Suitable
for (*)
50
2"
EPDM
UPVC
C-PVC
4.13"
4.57"
3.3"
1.38"
L0
F&A
65
2 1/2"
EPDM
UPVC
C-PVC
4.13"
5.28"
3.4"
1.38"
L0
F&A
SVAC3.0BVM
80
3"
EPDM
UPVC
C-PVC
4.13"
5.98"
3.6"
1.57"
L0
F&A
SVAC4.0BVM
100
4"
EPDM
UPVC
C-PVC
4.13"
6.93"
4.0"
1.57"
L0
F&A
SVAC5.0BVM
125
5"
EPDM
UPVC
C-PVC
4.49"
8.43"
5.6"
1.57"
L1
F
SVAC6.0BVM
150
6"
EPDM
UPVC
C-PVC
4.72"
9.37"
5.9"
1.57"
L1
F
SVAC8.0BVM
200
8"
EPDM
UPVC
C-PVC
4.92"
13.11"
6.6"
1.57"
L1
F
SVAC2.0DVM
50
2"
FPM
UPVC
C-PVC
4.13"
4.57"
3.3"
1.38"
L0
F&A
SVAC2.5DVM
65
2 1/2"
FPM
UPVC
C-PVC
4.13"
5.28"
3.4"
1.38"
L0
F&A
SVAC3.0DVM
80
3"
FPM
UPVC
C-PVC
4.13"
5.98"
3.6"
1.57"
L0
F&A
SVAC4.0DVM
100
4"
FPM
UPVC
C-PVC
4.13"
6.93"
4.0"
1.57"
L0
F&A
SVAC5.0DVM
125
5"
FPM
UPVC
C-PVC
4.49"
8.43"
5.6"
1.57"
L1
F
SVAC6.0DVM
150
6"
FPM
UPVC
C-PVC
4.72"
9.37"
5.9"
1.57"
L1
F
SVAC8.0DVM
200
8"
FPM
UPVC
C-PVC
4.92"
13.11"
6.6"
1.57"
L1
F
Suitable
for (*)
Part No.
DN/
Size
SVAC2.0BVM
SVAC2.5BVM
INSTALLATION ON PVCC PIPES
d/R
O-ring
Body
TFIC20B
15
20
EPDM
TFIC25B
20
25
EPDM
Part No.
H
Z
C-PVC
113
81
C-PVC
126
88
B
E
Flow
Sensor
Lenght
16
73
53
L0
F&A
19
80
62
L0
F&A
L
TFIC32B
25
32
EPDM
C-PVC
139.5
95.5
22
81
71
L0
F&A
TFIC40B
32
40
EPDM
C-PVC
170
118
26
84
84
L0
F&A
F&A
TFIC50B
40
50
EPDM
C-PVC
199
137
31
82.5
98
L0
TFIC20D
15
20
FPM
C-PVC
113
81
16
73
53
L0
F&A
TFIC25D
20
25
FPM
C-PVC
126
88
19
80
62
L0
F&A
TFIC32D
25
32
FPM
C-PVC
139.5
95.5
22
81
71
L0
F&A
TFIC40D
32
40
FPM
C-PVC
170
118
26
84
84
L0
F&A
TFIC50D
40
50
FPM
C-PVC
199
137
31
82.5
98
L0
F&A
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
WWW.FLSNET.IT
117
INSTALLATION FITTINGS
ISO Metric C-PVC Tee Fittings (female ends for solvent welding)
DN/
Size
INSTALLATION ON PVCC PIPES
ISO Metric Clamp Saddles
Part No.
DN/
Size
d/R
O-ring
Body
Insert
H
E
h
Drilling
Hole
Flow
Sensor
Lenght
Suitable
for (*)
SVIC063BVC
50
63
EPDM
UPVC
C-PVC
105
116
86.7
35
L0
F&A
SVIC075BVC
65
75
EPDM
UPVC
C-PVC
105
134
90.8
35
L0
F&A
SVIC090BVC
80
90
EPDM
UPVC
C-PVC
105
152
95.9
40
L0
F&A
SVIC110BVC
100
110
EPDM
UPVC
C-PVC
105
176
102.8
40
L0
F&A
SVIC125BVC
110
125
EPDM
UPVC
C-PVC
112
190
137.9
40
L1
F
SVIC140BVC
125
140
EPDM
UPVC
C-PVC
114
214
143.1
40
L1
F
SVIC160BVC
150
160
EPDM
UPVC
C-PVC
120
238
149.9
40
L1
F
SVIC200BVC
180
200
EPDM
UPVC
C-PVC
133
300
163.7
40
L1
F
SVIC225BVC
200
225
EPDM
UPVC
C-PVC
125
333
172.3
40
L1
F
SVIC063DVC
50
63
FPM
UPVC
C-PVC
105
116
86.7
35
L0
F&A
F&A
SVIC075DVC
65
75
FPM
UPVC
C-PVC
105
134
90.8
35
L0
SVIC090DVC
80
90
FPM
UPVC
C-PVC
105
152
95.9
40
L0
F&A
SVIC110DVC
100
110
FPM
UPVC
C-PVC
105
176
102.8
40
L0
F&A
SVIC125DVC
110
125
FPM
UPVC
C-PVC
112
190
137.9
40
L1
F
SVIC140DVC
125
140
FPM
UPVC
C-PVC
114
214
143.1
40
L1
F
SVIC160DVC
150
160
FPM
UPVC
C-PVC
120
238
149.9
40
L1
F
SVIC200DVC
180
200
FPM
UPVC
C-PVC
133
300
163.7
40
L1
F
SVIC225DVC
200
225
FPM
UPVC
C-PVC
125
333
172.3
40
L1
F
SMIC250IVC*
225
250
NBR
PP
C-PVC
79
324
203.5
40
L0
F
SMIC280IVC*
250
280
NBR
PP
C-PVC
88
385
212.2
40
L1
F
SMIC315IVC*
280
315
NBR
PP
C-PVC
88
385
220.1
40
L1
F
* For IP68 sensors or compact monitors only
118
INSTALLATION ON PP PIPES
ISO Metric PP Tee Fittings (female ends for socket welding)
H
Z
L
B
E
Flow
Sensor
Lenght
Suitable
for (*)
PP
111
73
14.5
73
53
L0
F&A
PP
120.5
80
16
80
62
L0
F&A
EPDM
PP
133.5
81
18
81
71
L0
F&A
40
EPDM
PP
163.5
84
20.5
84
84
L0
F&A
40
50
EPDM
PP
195
82.5
23.5
82.5
98
L0
F&A
15
20
FPM
PP
111
73
14.5
73
53
L0
F&A
DN/
Size
d/R
O-ring
Body
TFIM20B
15
20
EPDM
TFIM25B
20
25
EPDM
TFIM32B
25
32
TFIM40B
32
TFIM50B
TFIM20D
Part No.
TFIM25D
20
25
FPM
PP
120.5
80
16
80
62
L0
F&A
TFIM32D
25
32
FPM
PP
133.5
81
18
81
71
L0
F&A
TFIM40D
32
40
FPM
PP
163.5
84
20.5
84
84
L0
F&A
TFIM50D
40
50
FPM
PP
195
82.5
23.5
82.5
98
L0
F&A
BSP Female Threaded PP Tee Fittings (parallel threaded female ends)
B
E
Flow
Sensor
Lenght
Suitable
for (*)
83
15
73
53
L0
F&A
93.4
16.3
80
62
L0
F&A
101.3
19.1
81
71
L0
F&A
17
127.2
21.4
84
84
L0
F&A
PP
199
156.2
21.4
82.5
98
L0
F&A
FPM
PP
113
83
15
73
53
L0
F&A
3/4"
FPM
PP
126
93.4
16.3
80
62
L0
F&A
1"
FPM
PP
139.5
101.3
19.1
81
71
L0
F&A
32
1 1/4"
FPM
PP
17
127.2
21.4
84
84
L0
F&A
40
1 1/2"
FPM
PP
199
156.2
21.4
82.5
98
L0
F&A
d/R
O-ring
Body
TFFM20B
15
1/2"
EPDM
PP
113
TFFM25B
20
3/4"
EPDM
PP
126
TFFM32B
25
1"
EPDM
PP
139.5
TFFM40B
32
1 1/4"
EPDM
PP
TFFM50B
40
1 1/2"
EPDM
TFFM20D
15
1/2"
TFFM25D
20
TFFM32D
25
TFFM40D
TFFM50D
H
Z
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
WWW.FLSNET.IT
119
INSTALLATION FITTINGS
L
DN/
Size
Part No.
INSTALLATION ON PP PIPES
ISO metric Clamp Saddles
Part No.
DN/
Size
d/R
O-ring
Body
Insert
H
E
h
Drilling
Hole
Flow
Sensor
Lenght
Suitable
for (*)
SVIC063BME
50
63
EPDM
UPVC
C-PVC **
105
116
84.3
35
L0
F&A
SVIC075BME
65
75
EPDM
UPVC
C-PVC **
105
134
88.
35
L0
F&A
SVIC090BME
80
90
EPDM
UPVC
C-PVC **
105
152
92.6
4
L0
F&A
SVIC110BME
100
110
EPDM
UPVC
C-PVC **
105
176
98.8
40
L0
F&A
SVIC125BME
110
125
EPDM
UPVC
C-PVC **
112
190
133.3
40
L1
F
SVIC140BME
125
140
EPDM
UPVC
C-PVC **
114
214
138.0
40
L1
F
SVIC160BME
150
160
EPDM
UPVC
C-PVC **
120
238
144.1
40
L1
F
SVIC200BME
180
200
EPDM
UPVC
C-PVC **
133
300
156.4
40
L1
F
SVIC225BME
200
225
EPDM
UPVC
C-PVC **
125
333
164.1
40
L1
F
SVIC063DME
50
63
FPM
UPVC
C-PVC **
105
116
84.3
35
L0
F&A
SVIC075DME
65
75
FPM
UPVC
C-PVC **
105
134
88.
35
L0
F&A
SVIC090DME
80
90
FPM
UPVC
C-PVC **
105
152
92.6
4
L0
F&A
SVIC110DME
100
110
FPM
UPVC
C-PVC **
105
176
98.8
40
L0
F&A
SVIC125DME
110
125
FPM
UPVC
C-PVC **
112
190
133.3
40
L1
F
SVIC140DME
125
140
FPM
UPVC
C-PVC **
114
214
138.0
40
L1
F
SVIC160DME
150
160
FPM
UPVC
C-PVC **
120
238
144.1
40
L1
F
SVIC200DME
180
200
FPM
UPVC
C-PVC **
133
300
156.4
40
L1
F
SVIC225DME
200
225
FPM
UPVC
C-PVC **
125
333
164.1
40
L1
F
SMIC250IME*
225
250
NBR
PP
C-PVC **
79
324
189.9
40
L0
F
SMIC280IME*
250
280
NBR
PP
C-PVC **
88
385
200.2
40
L1
F
SMIC315IME*
300
315
NBR
PP
C-PVC **
88
385
209.3
40
L1
F
* For IP68 sensors or compact monitors only
** PVDF insert available on request
NPT Female Threaded PP Tee Fittings (NPT threaded female ends)
DN/
Size
d/R
O-ring
Body
H
Z
L
B
E
Flow
Sensor
Lenght
Suitable
for (*)
TFNM20B
15
1/2"
EPDM
PP
4.45"
3.05"
0.70"
2.87"
2.09"
L0
F&A
TFNM25B
20
3/4"
EPDM
PP
4.96"
3.54"
0.71"
3.15"
2.44"
L0
F&A
TFNM32B
25
1"
EPDM
PP
5.49"
3.71"
0.89"
3.19"
2.80"
L0
F&A
TFNM40B
32
1 1/4"
EPDM
PP
6.69"
4.84"
0.93"
3.31"
3.31"
L0
F&A
TFNM50B
40
1 1/2"
EPDM
PP
7.83"
5.59"
1.12"
3.25"
3.86"
L0
F&A
TFNM20D
15
1/2"
FPM
PP
4.45"
3.05"
0.70"
2.87"
2.09"
L0
F&A
TFNM25D
20
3/4"
FPM
PP
4.96"
3.54"
0.71"
3.15"
2.44"
L0
F&A
TFNM32D
25
1"
FPM
PP
5.49"
3.71"
0.89"
3.19"
2.80"
L0
F&A
Part No.
TFNM40D
32
1 1/4"
FPM
PP
6.69"
4.84"
0.93"
3.31"
3.31"
L0
F&A
TFNM50D
40
1 1/2"
FPM
PP
7.83"
5.59"
1.12"
3.25"
3.86"
L0
F&A
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
120
INSTALLATION ON PP PIPES
ASTM Clamp Saddles
d/R
O-ring
Body
Insert
H
E
h
Drilling
Hole
Flow
Sensor
Lenght
Suitable
for (*)
50
2"
EPDM
UPVC
C-PVC**
4.13"
4.57"
3.29"
1.38"
L0
F&A
65
2 1/2"
EPDM
UPVC
C-PVC**
4.13"
5.28"
3.43"
1.38"
L0
F&A
SVAC3.0BVM
80
3"
EPDM
UPVC
C-PVC**
4.13"
5.98"
3.65"
1.57"
L0
F&A
SVAC4.0BVM
100
4"
EPDM
UPVC
C-PVC**
4.13"
6.93"
4.00"
1.57"
L0
F&A
SVAC5.0BVM
125
5"
EPDM
UPVC
C-PVC**
4.49"
8.43"
5.55"
1.57"
L1
F
SVAC6.0BVM
150
6"
EPDM
UPVC
C-PVC**
4.72"
9.37"
5.91"
1.57"
L1
F
SVAC8.0BVM
200
8"
EPDM
UPVC
C-PVC**
4.92"
13.11"
6.61"
1.57"
L1
F
SVAC2.0DVM
50
2"
FPM
UPVC
C-PVC**
4.13"
4.57"
3.29"
1.38"
L0
F&A
SVAC2.5DVM
65
2 1/2"
FPM
UPVC
C-PVC**
4.13"
5.28"
3.43"
1.38"
L0
F&A
SVAC3.0DVM
80
3"
FPM
UPVC
C-PVC**
4.13"
5.98"
3.65"
1.57"
L0
F&A
SVAC4.0DVM
100
4"
FPM
UPVC
C-PVC**
4.13"
6.93"
4.00"
1.57"
L0
F&A
SVAC5.0DVM
125
5"
FPM
UPVC
C-PVC**
4.49"
8.43"
5.55"
1.57"
L1
F
SVAC6.0DVM
150
6"
FPM
UPVC
C-PVC**
4.72"
9.37"
5.91"
1.57"
L1
F
SVAC8.0DVM
200
8"
FPM
UPVC
C-PVC**
4.92"
13.11"
6.61"
1.57"
L1
F
Part No.
DN/
Size
SVAC2.0BVM
SVAC2.5BVM
** PVDF insert available on request
INSTALLATION FITTINGS
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
WWW.FLSNET.IT
121
INSTALLATION ON PVDF PIPES
ISO Metric PVDF Tee Fittings (female ends tor socket welding)
DN/
Size
d/R
O-ring
Body
TFIF20B
15
20
EPDM
PVDF
TFIF25B
20
25
EPDM
PVDF
Part No.
H
B
E
Flow
Sensor
Lenght
Suitable
for (*)
Z
L
111
82
14.5
73
53
L0
F&A
120.5
88.5
16
80
62
L0
F&A
TFIF32B
25
32
EPDM
PVDF
133.5
97
18
81
71
L0
F&A
TFIF40B
32
40
EPDM
PVDF
161.5
120.5
20.5
84
84
L0
F&A
F&A
TFIF50B
40
50
EPDM
PVDF
193.5
146.5
23.5
82.5
98
L0
TFIF20D
15
20
FPM
PVDF
111
82
14.5
73
53
L0
F&A
TFIF25D
20
25
FPM
PVDF
120.5
88.5
16
80
62
L0
F&A
TFIF32D
25
32
FPM
PVDF
133.5
97
18
81
71
L0
F&A
TFIF40D
32
40
FPM
PVDF
161.5
120.5
20.5
84
84
L0
F&A
TFIF50D
40
50
FPM
PVDF
193.5
146.5
23.5
82.5
98
L0
F&A
ISO Metric Clamp Saddles
Part No.
DN/
Size
d/R
O-ring
Body
Insert
H
E
h
Drilling
Hole
Flow
Sensor
Lenght
Suitable
for (*)
SVIF063BF
50
63
EPDM
UPVC
PVDF
105
116
87.2
35
L0
F&A
SVIF075BF
65
75
EPDM
UPVC
PVDF
105
134
91.5
35
L0
F&A
SVIF090BF
80
90
EPDM
UPVC
PVDF
105
152
96.8
40
L0
F&A
SVIF110BF
100
110
EPDM
UPVC
PVDF
105
176
104.0
40
L0
F&A
SVIF125BF
110
125
EPDM
UPVC
PVDF
112
190
139.3
40
L1
F
SVIF140BF
125
140
EPDM
UPVC
PVDF
114
214
144.6
40
L1
F
SVIF160BF
150
160
EPDM
UPVC
PVDF
120
238
151.8
40
L1
F
SVIF200BF
180
200
EPDM
UPVC
PVDF
133
300
165.9
40
L1
F
SVIF225BF
200
225
EPDM
UPVC
PVDF
125
333
174.9
40
L1
F
SVIF063DF
50
63
FPM
UPVC
PVDF
105
116
87.2
35
L0
F&A
F&A
SVIF075DF
65
75
FPM
UPVC
PVDF
105
134
91.5
35
L0
SVIF090DF
80
90
FPM
UPVC
PVDF
105
152
96.8
40
L0
F&A
SVIF110DF
100
110
FPM
UPVC
PVDF
105
176
104.0
40
L0
F&A
SVIF125DF
110
125
FPM
UPVC
PVDF
112
190
139.3
40
L1
F
SVIF140DF
125
140
FPM
UPVC
PVDF
114
214
144.6
40
L1
F
SVIF160DF
150
160
FPM
UPVC
PVDF
120
238
151.8
40
L1
F
SVIF200DF
180
200
FPM
UPVC
PVDF
133
300
165.9
40
L1
F
SVIF225DF
200
225
FPM
UPVC
PVDF
125
333
174.9
40
L1
F
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
122
INSTALLATION ON PE PIPES
ISO Metric PVC Tee Fittings (PE end connectors for electrotusion or butt welding)
Part No.
DN/
Size
d/R
O-ring
Body
H
Z
L
B
E
Flow
Sensor
Lenght
Suitable
for (*)
F&A
TFIV20BE
15
20
EPDM
UPVC
183
73
55
73
53
L0
TFIV25BE
20
25
EPDM
UPVC
223
83
70
80
62
L0
F&A
TFIV32BE
25
32
EPDM
UPVC
237
89
74
81
71
L0
F&A
F&A
TFIV40BE
32
40
EPDM
UPVC
266
110
78
84
84
L0
TFIV50BE
40
50
EPDM
UPVC
295
127
84
82.5
98
L0
F&A
TFIV20DE
15
20
FPM
UPVC
183
73
55
73
53
L0
F&A
TFIV25DE
20
25
FPM
UPVC
223
83
70
80
62
L0
F&A
TFIV32DE
25
32
FPM
UPVC
237
89
74
81
71
L0
F&A
TFIV40DE
32
40
FPM
UPVC
266
110
78
84
84
L0
F&A
TFIV50DE
40
50
FPM
UPVC
295
127
84
82.5
98
L0
F&A
ISO Metric Clamp Saddles
DN/
Size
d/R
O-ring
Body
Insert
H
E
h
Drilling
Hole
Flow
Sensor
Lenght
Suitable
for (*)
SVIC063BME
50
63
EPDM
UPVC
C-PVC
105
116
84.3
35
L0
F&A
SVIC075BME
65
75
EPDM
UPVC
C-PVC
105
134
88.
35
L0
F&A
SVIC090BME
80
90
EPDM
UPVC
C-PVC
105
152
92.6
4
L0
F&A
SVIC110BME
100
110
EPDM
UPVC
C-PVC
105
176
98.8
40
L0
F&A
SVIC125BME
110
125
EPDM
UPVC
C-PVC
112
190
133.3
40
L1
F
SVIC140BME
125
140
EPDM
UPVC
C-PVC
114
214
138.0
40
L1
F
F
SVIC160BME
150
160
EPDM
UPVC
C-PVC
120
238
144.1
40
L1
SVIC200BME
180
200
EPDM
UPVC
C-PVC
133
300
156.4
40
L1
F
SVIC225BME
200
225
EPDM
UPVC
C-PVC
125
333
164.1
40
L1
F
SVIC063DME
50
63
FPM
UPVC
C-PVC
105
116
84.3
35
L0
F&A
SVIC075DME
65
75
FPM
UPVC
C-PVC
105
134
88.
35
L0
F&A
SVIC090DME
80
90
FPM
UPVC
C-PVC
105
152
92.6
4
L0
F&A
SVIC110DME
100
110
FPM
UPVC
C-PVC
105
176
98.8
40
L0
F&A
SVIC125DME
110
125
FPM
UPVC
C-PVC
112
190
133.3
40
L1
F
SVIC140DME
125
140
FPM
UPVC
C-PVC
114
214
138.0
40
L1
F
SVIC160DME
150
160
FPM
UPVC
C-PVC
120
238
144.1
40
L1
F
SVIC200DME
180
200
FPM
UPVC
C-PVC
133
300
156.4
40
L1
F
SVIC225DME
200
225
FPM
UPVC
C-PVC
125
333
164.1
40
L1
F
SMIC250IME*
225
250
NBR
PP
C-PVC
79
324
189.9
40
L0
F
SMIC280IME*
250
280
NBR
PP
C-PVC
88
385
200.2
40
L1
F
SMIC315IME*
300
315
NBR
PP
C-PVC
88
385
209.3
40
L1
F
* For IP68 sensors or compact monitors only
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
WWW.FLSNET.IT
123
INSTALLATION FITTINGS
Part No.
INSTALLATION ON METAL PIPES
BSP Female Threaded 316 SS Tee Fittings
Part No.
DN/
Size
d/R
O-ring
Body
H
Z
L
B
Flow
Sensor
Lenght
E
Suitable
for (*)
TFFX20
15
1/2"
-
316 SS
85
-
16
73
42
L0
F&A
TFFX25
20
3/4"
-
316 SS
95
-
20
81.2
42
L0
F&A
TFFX32
25
1"
-
316 SS
105
-
22.5
81.2
42
L0
F&A
TFFX40
32
1 1/4"
-
316 SS
12
-
20.5
83.8
54
L0
F&A
Drilling
Hole
Flow
Sensor
Lenght
Strap-on Saddles
Part No.
DN/
Size
O.D.
min.
O.D.
max
Parallel
Thread
(GAS)
O-ring
Body
Insert
h
Suitable
for (*)
SZIC080I*
80
88
104
1 1/4”
EPDM
Cast iron + SS
C-PVC
153
40
L0
F
SZIC100I*
100
112
126
1 1/4”
EPDM
Cast iron + SS
C-PVC
160
40
L0
F
SZIC125I*
125
140
154
1 1/4”
EPDM
Cast iron + SS
C-PVC
170
40
L0
F
SZIC150I*
150
168
184
1 1/4”
EPDM
Cast iron + SS
C-PVC
180
40
L0
F
SZIC200I*
218
234
244
1 1/4”
EPDM
Cast iron + SS
C-PVC
228
40
L1
F
SZIC250I*
272
286
295
1 1/4”
EPDM
Cast iron + SS
C-PVC
247
40
L1
F
SZIC300I*
322
344
354
1 1/4”
EPDM
Cast iron + SS
C-PVC
266
40
L1
F
SZIC350I*
356
384
414
1 1/4”
EPDM
Cast iron + SS
C-PVC
305
40
L1
F
SZIC400I*
425
458
472
1 1/4”
EPDM
Cast iron + SS
C-PVC
324
40
L1
F
SZIC450I*
475
516
534
1 1/4”
EPDM
Cast iron + SS
C-PVC
343
40
L1
F
(*) For IP68 sensors or compact monitors only
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
124
INSTALLATION ON METAL PIPES
316L SS Weld on Adapters
Part No.
DN/Size
d/R
Parallel
Thread
(GAS)
Body
L
D1
D2
Drilling
Hole
Flow
Sensor
Lenght
Suitable
for (*)
WAIXL0
40
-
1 1/4”
316L SS
68.5
33,9
34
34
L0
F&A
WAIXL0
50
-
1 1/4”
316L SS
68.5
33,9
44
44
L0
F&A
WAIXL0
60
-
1 1/4”
316L SS
68.5
33,9
44
44
L0
F&A
WAIXL0
65
-
1 1/4”
316L SS
68.5
33,9
44
44
L0
F&A
WAIXL0
80
-
1 1/4”
316L SS
68.5
33,9
44
44
L0
F&A
WAIXL0
100
-
1 1/4”
316L SS
68.5
33,9
44
44
L0
F&A
F&A
WAIXL0
110
-
1 1/4”
316L SS
68.5
33,9
44
44
L0
WAIXL0
125
-
1 1/4”
316L SS
68.5
33,9
44
44
L0
F
WAIXL0
150
-
1 1/4”
316L SS
68.5
33,9
44
44
L0
F
WAIXL0
175
-
1 1/4”
316L SS
68.5
33,9
44
44
L0
F
WAIXL0
200
-
1 1/4”
316L SS
68.5
33,9
44
44
L0
F
WAIXL0
225
-
1 1/4”
316L SS
68.5
33,9
44
44
L1
F
WAIXL1
250
-
1 1/4”
316L SS
98.5
33,9
44
44
L1
F
WAIXL1
300
-
1 1/4”
316L SS
98.5
33,9
44
44
L1
F
WAIXL1
350
-
1 1/4”
316L SS
98.5
33,9
44
44
L1
F
WAIXL1
400
-
1 1/4”
316L SS
98.5
33,9
44
44
L1
F
WAIXL1
450
-
1 1/4”
316L SS
98.5
33,9
44
44
L1
F
WAIXL1
500
-
1 1/4”
316L SS
98.5
33,9
44
44
L1
F
WAIXL1
600
-
1 1/4”
316L SS
98.5
33,9
44
44
L1
F
INSTALLATION FITTINGS
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
WWW.FLSNET.IT
125
INSTALLATION FITTINGS FOR FLS F3.10
ISO Metric PVC Tee Fittings (female ends for solvent welding)
Z
L
B
E
Flow
Sensor
Lenght
Suitable
for (*)
43
11
16
27
27
-
F
52
14
19
30
33
-
F
UPVC
61,5
17,5
22
33,5
41
-
F
-
UPVC
74
22
26
38
50
-
F
-
UPVC
89
27
31
43
61
-
F
Part No.
DN/
Size
d/R
O-ring
Body
H
TMIV20MF
15
20
-
UPVC
TMIV25MF
20
25
-
UPVC
TMIV32MF
25
32
-
TMIV40MF
32
40
TMIV50MF
40
50
ISO Metric BRASS Tee Fitting (1 1/4” male threaded ends)
Part No.
DN/
Size
d/R
O-ring
Body
H
Z
L
B
E
Flow
Sensor
Lenght
Suitable
for (*)
TMFODN23
23
1 1/4"
-
BRASS
74,2
46,2
14
28
50
-
F
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
126
INSTALLATION FITTINGS FOR FLS F3.20
316L SS Weld-on Adapters
Part No.
DN/Size
d/R
Parallel
Thread
(GAS)
Body
L
D1
D2
Drilling
Hole
Flow
Sensor
Lenght
Suitable
for (*)
WAIXHP
40
-
1 1/4”
316L SS
68,5
34
42,8
34
L0
F
WAIXHP
50
-
1 1/4”
316L SS
68,5
34
42,8
43
L0
F
WAIXHP
60
-
1 1/4”
316L SS
68,5
34
42,8
43
L0
F
WAIXHP
65
-
1 1/4”
316L SS
68,5
34
42,8
43
L0
F
WAIXHP
80
-
1 1/4”
316L SS
68,5
34
42,8
43
L0
F
WAIXHP
100
-
1 1/4”
316L SS
68,5
34
42,8
43
L0
F
WAIXHP
110
-
1 1/4”
316L SS
68,5
34
42,8
43
L0
F
WAIXHP
125
-
1 1/4”
316L SS
68,5
34
42,8
43
L0
F
WAIXHP
150
-
1 1/4”
316L SS
68,5
34
42,8
43
L0
F
WAIXHP
175
-
1 1/4”
316L SS
68,5
34
42,8
43
L0
F
WAIXHP
200
-
1 1/4”
316L SS
68,5
34
42,8
43
L0
F
INSTALLATION FITTINGS
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
WWW.FLSNET.IT
127
HOT TAP INSERTION INSTALLATION
INSTALLATION ON METAL AND PLASTIC PIPES
Strap-on Saddles ***
Part No.
DN/
Size
O.D.
min.
O.D.
max
Parallel
Thread
(GAS)
O-ring
Body
Insert
h
Drilling
Hole
Flow
Sensor
Lenght
Suitable
for (*)
SZIC080IHT
80
88
104
2.00"
EPDM
Cast iron + SS
-
160
min 32
-
F
SZIC100IHT
100
112
126
2.00"
EPDM
Cast iron + SS
-
170
min 32
-
F
SZIC125IHT
125
140
154
2.00"
EPDM
Cast iron + SS
-
172
min 32
-
F
SZIC150IHT
150
168
184
2.00"
EPDM
Cast iron + SS
-
172
min 32
-
F
SZIC200IHT
200
218
234
2.00"
EPDM
Cast iron + SS
-
177
min 32
-
F
SZIC250IHT
250
272
286
2.00"
EPDM
Cast iron + SS
-
175
min 32
-
F
SZIC300IHT
300
322
344
2.00"
EPDM
Cast iron + SS
-
178
min 32
-
F
SZIC350IHT
350
356
384
2.00"
EPDM
Cast iron + SS
-
178
min 32
-
F
SZIC400IHT
400
425
458
2.00"
EPDM
Cast iron + SS
-
171
min 32
-
F
SZIC450IHT
450
475
516
2.00"
EPDM
Cast iron + SS
-
180
min 32
-
F
*** Bigger sizes available on request
Part No.
DN/Size
d/R
Body
L
D1
D2
Drilling
Hole
Flow
Sensor
Lenght
Suitable
for (*)
WAIXHT
350
-
2.00"
316L SS
40
-
75
min 32
-
F
WAIXHT
400
-
2.00"
316L SS
40
-
75
min 32
-
F
WAIXHT
450
-
2.00"
316L SS
40
-
75
min 32
-
F
WAIXHT
500
-
2.00"
316L SS
40
-
75
min 32
-
F
WAIXHT
600
-
2.00"
316L SS
40
-
75
min 32
-
F
WAIXHT
700
-
2.00"
316L SS
40
-
75
min 32
-
F
WAIXHT
800
-
2.00"
316L SS
40
-
75
min 32
-
F
WAIXHT
900
-
2.00"
316L SS
40
-
75
min 32
-
F
(*) Suitable for: F= Flow sensors; A= Analytical electrodes
WWW.FLSNET.IT
129
INSTALLATION FITTINGS
316L SS Weld-on Adapters
Parallel
Thread
(GAS)
SPECIFIC ADAPTERS FOR ANALYTICAL
ELECTRODES INSTALLATION
ADAPTERS FOR IN-LINE, SUBMERSIBLE AND WET-TAP INSTALLATION
In-line
Description
Suitable for
Weight
(gr.)
SS
1/2” male Electrode Gland
C300
300
TCONIV32E
PVCU
T fitting d32 DN25
C150-200
500
TCONIV40E
PVCU
T fitting d40 DN32
C150-200
550
TCONIV50E
PVCU
T fitting d50 DN40
C150-200
600
TCONIC32E
PVCC
T fitting d32 DN25
C150-200
500
TCONIC40E
PVCC
T fitting d40 DN32
C150-200
550
TCONIC50E
PVCC
T fitting d50 DN40
C150-200
600
TPHIV32E
PVCU
T fitting d32 DN25
PH/ORP.200 (excluded
PH223CD; ORP223CD)
500
TPHIV40E
PVCU
T fitting d40 DN32
PH/ORP.200 (excluded
PH223CD; ORP223CD)
550
TPHIV50E
PVCU
T fitting d50 DN40
PH/ORP.200 (excluded
PH223CD; ORP223CD)
600
TPHIC32E
PVCC
T fitting d32 DN25
PH/ORP.200 (excluded
PH223CD; ORP223CD)
500
TPHIC40E
PVCC
T fitting d40 DN32
PH/ORP.200 (excluded
PH223CD; ORP223CD)
550
TPHIC50E
PVCC
T fitting d50 DN40
PH/ORP.200 (excluded
PH223CD; ORP223CD)
600
TPHIC32C
PVCC
T fitting d32 DN25
PH660-ORP660
500
TPHIC40C
PVCC
T fitting d40 DN32
PH660-ORP660
550
TPHIC50C
PVCC
T fitting d50 DN40
PH660-ORP660
600
EG66P
PVCC
3/4" male Electrode Gland
PH660-ORP660
45
MK660
PVCC
Installation KIT (adapter + yellow cap) for FLS fittings
up to DN100 (4")
PH660-ORP660
165
MK150200
PVCC
Installation KIT (EG50P, adapter, yellow cap) for FLS
fittings up to DN100 (4")
PH200C, ORP200C,
C150.1 TC
GEG135SE
PP
gland electrode for PG13.5 electrode with electrode
head protection 1 1/4" G.M.
PH430CD; ORP430CD;
PH435CD
500
PVCU
Yellow Electrode Cap for FLS fittings up to DN100 (4")
PH223CD; ORP223CD
60
EG12SS
F3.SP2.4
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131
INSTALLATION FITTINGS
Body
Part No.
ADAPTERS FOR IN-LINE, SUBMERSIBLE AND WET-TAP INSTALLATION
In-line / Submersible
Body
Description
Suitable for
Weight
(gr.)
PVCU
gland electrode for PG13.5 electrode or o 12mm body
1/2" G.M.
PH-ORP.400
70
EG50P
PP
1/2" male Electrode Gland
PH-ORP.200 (excluded
PH223CD; ORP223CD),
C150-200, T970278; T970196
45
EG75P
PP
3/4" male Electrode Gland
PH-ORP.200 (excluded
PH223CD; ORP223CD),
C150-200, T970278; T970196
45
EG135FS
PVDF/FPM
short gland electrode for PG13.5 electrode 1/2”
PH-ORP430; PH435CD
40
EG135FL
PVDF/FPM
long gland electrode for PG13.5 electrode 1/2”
PH-ORP430; PH435CD
65
Description
Suitable for
Weight
(gr.)
Double socket 20x1/2" (pipe customer supplied)
PH200C-ORP200C (with
EG50P), PH222CDORP222CD (with CN653),
(GEG135), PH650-ORP650
(with CN653), C150-200 (with
EG50P)
30
Double socket 20x1/2" (pipe customer supplied)
PH200C-ORP200C (with
EG50P), PH222CDORP222CD (with CN653),
PH650-ORP650 (with
CN653), C150-200 (with
EG50P)
30
Part No.
GEG135
Submersible
Part No.
MIFV20X05
MIMC20X05
Body
PVCU
PVCC
Hot tap or horizontal
Part No.
WT675
WT675 TC1
132
Body
Description
Suitable for
Weight
(gr.)
PVCC
Electrode gland for hot tap installation: max insertion
300mm (12")
PH655-ORP655
700
PVCC,SS
Electrode gland for hot tap installation with TC: max
insertion 300mm (12")
PH655-ORP655
880
SPARE PARTS AND ACCESSORIES
FOR MONITORS, FLOW SENSORS
AND ANALYTICAL ELECTRODES
SPARE PARTS
MONITOR SPARE PARTS
Spare Parts for monitors
Part No.
M9.SP4.1
Name
Description
Weight
(gr.)
PG 11
PG 11 complete cable gland (2 o-rings and cap)
12
M9.LN1
Locking nut
Plastic locking nut for M9.02, M9.20 and M9.00
24
M9.SN1
Fixing snails
2 plastic fixing snails for panel installation of all FLS Monitors (except for M9.02, M9.20 and M9.00)
16
M9.SP7
Replacement battery
3,6 V Lithium Thionyl Chloride battery (only for M9.20)
60
FLOW SENSORS SPARE PARTS
Spare Parts for F3.00
Part No.
F3.SP1
Name
Description
Weight
(gr.)
30
4 pole Cable Plug
Cable Plug according to DIN 43650
F3.SP2.1
Sensor Cap
Black Sensor Cap, for Hall version
42
F3.SP2.2
Sensor Cap
Red Sensor Cap, for Coil version
42
F3.SP2.4
Sensor Cap
Yellow Sensor Cap, for push-pull version
42
F3.SP2.6
Sensor Cap
SS AISI 316 Sensor Cap, for SS Hall and Coil versions
205
F3.SP3.1
O-Rings
EPDM Sensor body O-rings
4
F3.SP3.2
O-Rings
FPM Sensor body O-rings
4
F3.SP4.2
Rotor KIT
ECTFE (Halar®) rotor with Machined Ceramic Shaft and Bearings
8
F3.SP4.3
Rotor KIT
ECTFE (Halar®) rotor with SS Shaft
8
F3.SP5.1
Sensor Plug
C-PVC Sensor Plug
140
F3.SP5.2
Sensor Plug
PVDF Sensor Plug
150
F3.SP5.3
Sensor Plug
Stainless Steel Sensor Plug
470
Electrical cable
Cable (per meter), 22AWG, 3 cond.
28
F3.SP6
Spare Parts for F3.20
Part No.
F3.SP4.3
F3.SP8
Weight
(gr.)
Name
Description
Rotor KIT
ECTFE (Halar) rotor with SS shaft
8
Seal and screws kit
SS screws + graphite gasket
70
Part No.
F6.KC1
Name
Description
Weight
(gr.)
Compact mounting kit
Plastic adapter with compact cap and locking nut
137
M9.SP4.1
PG 11
PG 11 complete cable gland (2 o-rings and cap)
12
F3.SP3.1
O-Rings
EPDM Sensor body O-Rings
4
F3.SP3.2
O-Rings
FPM Sensor body O-Rings
4
Electronic device
Electronic device with 4-20 mA output and freq./volumetric pulse output for paddlewheel flow
sensor
180
USB Cable
USB cable dedicated to FLS products, 1,5 meter long
60
F6.30.
SP1.S
M9.KUSB
Spare Parts for F3.10
Part No.
Name
Description
Weight
(gr.)
F3.SP2.7
Sensor Cap
Gray Sensor Cap
10
F3.SP3.3
O-Rings
EPDM Sensor body O-rings
2
F3.SP3.4
O-Rings
FPM Sensor body O-rings
2
F3.SP11
Rotor KIT
PVC rotor with AISI 316L Shaft
2
WWW.FLSNET.IT
135
SPARE PARTS & ACCESSORIES
Spare Parts for F6.30
FLOW SENSORS SPARE PARTS
Spare Parts for F3.05
Part No.
F3.SP1
Name
Description
Weight
(gr.)
4 pole Cable Plug
Cable Plug according to DlN 43650
30
F3.SP2.1
Sensor Cap
Black Sensor Cap for Hall version
42
F3.SP3.1
O-Rings
EPDM Sensor body O-rings
4
F3.SP3.2
O-Rings
FPM Sensor body O-rings
4
F3.SP4.2
Rotor KlT
ECTFE (Halar®) rotor with Machined Ceramic Shaft and Bearings
8
F3.SP5.1
Sensor Plug
C-PVC Sensor Plug
140
F3.SP5.2
Sensor Plug
PVDF Sensor Plug
150
F3.SP5.3
Sensor Plug
Stainless Steel Sensor Plug
470
Spare Parts for F6.60
Part No.
F6.KC1
Name
Description
Weight
(gr.)
Compact mounting kit
Plastic adapter with compact cap and locking nut
137
M9.SP4.1
PG 11
PG 11 complete cable gland (2 o-rings and cap)
12
F3.SP3.1
O-Rings
EPDM Sensor body O-Rings
4
F3.SP3.2
O-Rings
FPM Sensor body O-Rings
4
Electronic device
Magmeter electronic device with 4-20 mA output and freq./volumetric pulse output for bidirectional sensor
180
F6.60M.
SP09
Magmeter bidirectional flow sensor
316L SS/PVDF body - EDPM O-Rings - L0 length
330
F3.60M.
SP10
Magmeter bidirectional flow sensor
316L SS/PVDF body - FPM O-Rings - L0 length
330
F3.60M.
SP11
Magmeter bidirectional flow sensor
316L SS/PVDF body - EDPM O-Rings - L1 length
400
F3.60M.
SP12
Magmeter bidirectional flow sensor
316L SS/PVDF body - FPM O-Rings - L1 length
400
F3.60M.
SP13
Magmeter bidirectional flow sensor
CuNi/PVDF body - EPDM O-Ring - L0 lenght
330
F3.60M.
SP14
Magmeter bidirectional flow sensor
CuNi/PVDF body - FPM O-Ring - L0 lenght
330
F3.60M.
SP15
Magmeter bidirectional flow sensor
CuNi/PVDF body - EPDM O-Ring - L1 lenght
400
F3.60M.
SP16
Magmeter bidirectional flow sensor
CuNi/PVDF body - FPM O-Ring - L1 lenght
400
F3.60M.
SP17
Magmeter bidirectional flow sensor
AISI 316L/PEEK body - FPM O-Ring - L0 lenght
330
F3.60M.
SP18
Magmeter bidirectional flow sensor
AISI 316L/PEEK body - FPM O-Ring - L1 lenght
400
USB Cable
USB cable dedicated to FLS products, 1,5 meter long
60
F6.60.
SP1.S
M9.KUSB
Spare Parts for F6.61
Part No.
F6.KC1
M9.SP4.1
Name
Description
Weight
(gr.)
Magmeter Compact
mounting kit
Plastic adapter with compact cap and locking nut
137
PG 11
PG 11 complete cable gland (2 o-rings and cap)
12
F1.SP3
Isolation Valve
2" Brass Ball Valve
1800
F1.SP6
2" to 1 1/4" Reduction
Zinc Plated Steel 2" BS male to 1 1/4" BS female
405
F1.SP7
2" to 1 1/4" Reduction
Zinc Plated Steel 2" NPT male to 1 1/4" BS female reduction
405
F6.60M.
SP1.S
Electronic device
Magmeter electronic device with 4-20mA output and freq. Output /volumetric pulse output
180
F3.61M.
SP01
Magmeter flow sensor
for Hot Tap installation
304 SS/PVDF body
1000
USB Cable
USB cable dedicated to FLS products, 1,5 meter long
60
M9.KUSB
136
FLOW SENSORS SPARE PARTS
Spare Parts for F111
Part No.
Name
Weight
(gr.)
Description
F3.SP4
Rotor KlT
ECTFE (Halar®) rotor with Ceramic Shaft and Bearings
8
F3.SP9
Turbine KlT
PVDF Turbine with ceramic shaft and bearings + fixing bushings
10
F1.SP1.01
Hall Paddlewheel
Sensor Body
Stainless Steel Hall Paddlewheel Flow Sensor
1000
F1.SP1.02
Hall Paddlewheel
Sensor Body
Brass Hall Paddlewheel Flow Sensor
1000
F1.SP1.HT
Hall Turbine Sensor
Body
Stainless Steel MONO-DIRECTIONAL Hall Effect TURBINE Sensor Body
1000
F1.SP1.BD
Bi-directional Turbine
Sensor Body
Stainless Steel BI-DIRECTIONAL Hall Effect TURBINE Sensor Body
1000
F1.SP2.01
Coil Paddlewheel
Sensor Body
Stainless Steel Coil Effect Paddlewheel Sensor Body
1000
F1.SP2.02
Coil Paddlewheel
Sensor Body
Brass Coil Effect Paddlewheel Sensor Body
1000
F1.SP3
lsolation Valve
2" Brass Ball Valve
1800
F1.SP6
Reduction 2" to 1 1/4"
Reduction 2" BS male to 1 1/4" BS female
405
F1.SP7
Reduction 2" to 1 1/4"
Reduction 2" NPT male to 1 1/4" BS female
405
F3.SP6
Electrical Cable
Cable (per meter), 22AWG, 3 cond.
28
SPARE PARTS & ACCESSORIES
WWW.FLSNET.IT
137
ACCESSORIES
MONITOR ACCESSORIES
Accessories for monitors
Name
Description
Weight
(gr.)
F6.KC1
Compact mounting kit
Plastic adapter with compact cap and locking nut
(for M9.02, M9.20 and M9.00 only)
137
M9.KW1
Wall mounting kit
144x144mm plastic box for wall installation of all panel mounting monitors
600
M9.KW2
Wall mounting kit with
power supply
144x144mm plastic box for wall installation of all panel mounting monitors
and 110/230VAC to 24 VDC power supply included
900
M9.KUSB
USB Cable
USB cable dedicated to FLS products, 1,5 meter long
60
Part No.
ANALYTICAL ELECTRODES ACCESSORIES
Accessories for pH/ORP electrodes
Description
Weight
(gr.)
CN653
5m Universal cable
assembly
Cable for PH222 CD, PH223 CD, ORP222 CD, ORP223 CD, PH-ORP.600
300
CN65310M
10m Universal cable
assembly
Cable for PH222 CD, PH223 CD, ORP222 CD, ORP223 CD, PH-ORP.600
400
CN65315M
15m Universal cable
assembly
Cable for PH222 CD, PH223 CD, ORP222 CD, ORP223 CD, PH-ORP.600
500
CN653TC1
5m Submersible
cable assembly
with Temperature
compensation (PT 100)
Cable for PH222 CD, PH223 CD, PH650CD, PH650CD HF, PH650CD DA,
PH650CD LC
350
CE5S7
5m Cable assembly
Cable for PH435 CD PH430 CD ORP430CD
300
CE10S7
10m Cable assembly
Cable for PH435 CD PH430 CD ORP430CD
400
CE15S7
15m Cable assembly
Cable for PH435 CD PH430 CD ORP430CD
500
B104
pH buffer
Buffer pH 4,01
450
B107
pH buffer
Buffer pH 7,00
450
B110
pH buffer
Buffer pH 10,00
450
B3KCL
pH buffer
3KCl solution
500
ORP buffer
Buffer 475mV
450
B475
Accessories for Conductivity Sensors
Name
Description
Weight
(gr.)
T970278
5m PT100 Temperature
Epoxy body Sensor
2 wire PT100 Temperature Sensor with epoxy body
200
T970196
5m PT100 Temperature
Epoxy body Sensor
2 wire PT100 Temperature Sensor with epoxy body (no metal in contact)
200
B0018
Conductivity buffer
Calibration solution for low conductivity (18 microsiemens)
450
B1417
Conductivity buffer
Calibration solution for conductivity (1417 microsiemens)
450
Part No.
WWW.FLSNET.IT
139
SPARE PARTS & ACCESSORIES
Name
Part No.
TECHNICAL INFORMATION
ABOUT FLOW AND ANALYTICAL
MEASUREMENT
FLOW MEASUREMENT
FLOW MEASUREMENT
Insertion technology is based on fluid speed meters, properly installed in a
cylindrical straight pipe, and used to measure the local flow velocity Vm to
calculate the average velocity Va and the volumetric flow rate Qv.
These flow sensors are theoretically supported by fluid-dynamic laws
applicable to any circular cross section pipe when some physical
conditions (fully developed turbulent flow) are respected.
Those laws state the relationship between the measured local flow velocity
and the average flow velocity (UNI 10727; ISO 7145).
The relationship between average velocity Va and measured velocity is
usually expressed through the “Profile Factor”:
Fp = Va / Vm
Using the above mentioned factor:
Qv = Va * ID² / 4 = Fp * Vm * ID² / 4
ID = pipe inside diameter
Two different positions are suitable for the flow velocity measuring point:
1. Critical position: the velocity sensor is inserted in a peculiar point where
the local velocity correspond to the average velocity (12% of Internal
Diameter):
Va = Vm >>> Fp = 1.
2. Central position: the velocity sensor is placed exactly in the centre of the
pipe cross section. The local velocity correspond to the maximum velocity:
Vm = Vmax >>> Fp < 1.
143
TECHNICAL INFORMATION
WWW.FLSNET.IT
Fully Developed
Turbulent Flow
All velocity based flow sensors provide an accurate and reliable indication
only when they are measuring a fully developed turbulent flow.
Fully developed turbulent flow occurs in every Newtonian fluid when the
Reynolds Number is greater than 4500.
Fully developed turbulent flow can be more difficult to achieve with high
viscosity liquids, low flow rates or large pipes. Quite often a reduction of
the pipe size to increase the local flow velocity is enough to produce a
proper Reynolds Number:
Re = V x ID x Sg / µ
where:
V = flow velocity in m/s
ID = pipe inside diameter in meter
Sg = Specific Gravity in Kg/m3
µ = Dynamic Viscosity in Pa*s
(1 Pa*s = 10³ cP)
or, converting flow velocity in flow rate:
Re = 1.2732 x Qv x Sg / µ x ID
where:
Qv = flow rate in l/s
Sg = Specific Gravity in Kg/m3
µ = Dynamic Viscosity in Pa*s
(1 Pa*s = 10³ cP)
ID = pipe inside diameter in meter
Re = 3162.76 x Qv x Sg / µ x ID
where:
Qv = flow rate in gpm
Sg = Specific Gravity in Kg/m3
µ = Dynamic Viscosity in centipoises
(1 Pa*s = 10³ cP)
ID = pipe inside diameter in inches
144
FLOW SENSORS OPERATING PRINCIPLE
Insertion flow sensor
Paddlewheel sensor
This flow sensor consists of a transducer (hall effect for powered system
and coil for battery powered system) and a ECTFE five-blade (four blades
for F3.10) open cell paddlewheel fixed on a ceramic shaft (SS in case
of F3.10, F3.20 and SS version of F3.00). Shaft is orthogonal to the
flow direction. The paddlewheel is equipped with a permanent magnet
integrated into each blade. As the magnet passes close to the transducer
a pulse is generated. When liquid flows into the pipe, the paddlewheel is
set in rotation producing a square wave output signal. The frequency is
proportional to the flow velocity. The sensor is installed into the pipe using
a wide range of insertion type fittings supplied by FLS.
Turbine sensor
This flow sensor consists of a transducer and a ECTFE eight-blade
turbine on a ceramic shaft. Shaft is parallel to the flow direction and
sensor is able to recognize both flow directions. The propeller is equipped
with a permanent magnet integrated into each blade. As the magnet
passes close to the transducer a pulse is generated. When liquid flows
into the pipe, the turbine is set in rotation producing a square wave output
signal. The frequency is proportional to the flow velocity. The sensor is
installed into the pipe using a wide range of insertion type fittings supplied
by FLS.
F3.05 Flow Switch
F3.05 is a flow switch based on a paddlewheel sensor from mechanical
point of view.
This means that a trasducer is present as well as a five-blade open
cell paddlewheel. Also in this case, rotor is equipped with a permanent
magnet integrated into each blade. As the magnet passes close to the
transducer an output pulse is generated. That pulse is monitored by a
missing signal circuit that trips an internal relay when the pulse frequency
drops below the factory preset frequency of 0.15 m/s (0.5 ft/s). The switch
is installed into the pipe using a wide range of insertion type fittings
supplied by FLS.
Magmeter sensor
Magmeter sensor is based on Faraday’s law since a voltage is induced in
an electrical conductor when it moves in a magnetic field. A coil mounted
into sensor body generates a magnetic field perpendicular to the flow
direction. The magnetic field and the flow velocity induce a voltage
between the electrodes. The voltage is directly proportional to the flow
velocity.
The voltage is converted into a flow proportional 4-20mA output signal or
frequency output signal.
In-line flow sensor
F3.80 Oval Gear sensor
This in-line sensor body contains two oval gears set into rotation by a
flowing fluid. The two gears are meshed at 90° to define a fixed fluid
volume pumped out every rotation.
Two permanent magnets are positioned into each gear and a hall effect
sensor detects the magnetic field generating a square wave signal output
with frequency proportional to the number of fluid volumes pumped out.
WWW.FLSNET.IT
145
TECHNICAL INFORMATION
ULF sensor
This in-line flow sensor consists of a transducer and a five-blade
paddlewheel (four-blade paddlewheel for ULF0X.X.0). The paddlewheel
is equipped with a permanent magnet integrated into each blade. As the
magnet passes close to the transducer a pulse is generated. When liquid
flows into the sensor body, the paddlewheel is set in rotation producing a
square wave output signal. The generated frequency is proportional to the
flow velocity.
VELOCITY/FLOW RATE CONVERSION TABLES
Velocity [m/s] = (Flow Rate [l/s] x 1273.2) / ID2
Flow Rate [l/s] = (Velocity [m/s] x ID2) / 1273.2
Velocity
D
[mm]
ft/sec
0,16
0,33
0,5
0,7
1,6
2,6
3,3
6,6
9,8
13,1
16,4
20
23
26,2
m/s
0,05
0,1
0,15
0,2
0,5
0,8
1
2
3
4
5
6
7
8
DN
Flow Rate l/s
[mm]
20
15
0,01
0,02
0,03
0,04
0,09
0,14
0,18
0,35
0,53
0,71
0,88
1,06
1,24
1,41
25
20
0,02
0,03
0,05
0,06
0,16
0,25
0,31
0,63
0,94
1,26
1,57
1,89
2,20
2,51
32
25
0,02
0,05
0,07
0,10
0,25
0,39
0,49
0,98
1,47
1,96
2,45
2,95
3,44
3,93
40
32
0,04
0,08
0,12
0,16
0,40
0,64
0,80
1,61
2,41
3,22
4,02
4,83
5,63
6,43
50
40
0,06
0,13
0,19
0,25
0,63
1,01
1,26
2,51
3,77
5,03
6,28
7,54
8,80
10,05
63
50
0,10
0,20
0,29
0,39
0,98
1,57
1,96
3,93
5,89
7,85
9,82
11,78
13,74
15,71
75
65
0,17
0,33
0,50
0,66
1,66
2,65
3,32
6,64
9,96
13,27
16,59
19,91
23,23
26,55
90
80
0,25
0,50
0,75
1,01
2,51
4,02
5,03
10,05
15,08
20,11
25,13
30,16
35,19
40,21
110
100
0,39
0,79
1,18
1,57
3,93
6,28
7,85
15,71
23,56
31,42
39,27
47,13
54,98
62,83
125
110
0,48
0,95
1,43
1,90
4,75
7,60
9,50
19,01
28,51
38,01
47,52
57,02
66,53
76,03
140
125
0,61
1,23
1,84
2,45
6,14
9,82
12,27
25,54
36,82
49,09
61,36
73,63
85,91
98,18
160
150
0,88
1,77
2,65
3,53
8,84
14,14
17,67
35,34
53,02
70,69
88,36
106,03
123,70
141,38
200
180
1,27
2,54
3,82
5,09
12,72
20,36
25,45
50,90
76,34
101,79
127,24
152,69
178,13
203,58
225
200
1,57
3,14
4,71
6,28
15,71
25,13
31,42
62,83
94,25
125,67
157,08
188,50
219,92
251,34
250
225
1,99
3,98
5,96
7,95
19,88
31,81
39,76
79,52
119,29
159,05
198,81
238,57
278,33
318,10
280
250
2,45
4,91
7,36
9,82
25,54
39,27
49,09
98,18
147,27
196,36
245,44
294,53
343,62
392,71
315
280
3,08
6,16
9,24
12,32
30,79
49,26
61,58
123,15
184,73
246,31
307,89
369,46
431,04
492,62
Velocity [m/s] = (Flow Rate [l/min] x 21.16) / ID2
Flow Rate [l/min] = (Velocity [m/s] x ID2) / 21.16
Velocity
D
[mm]
ft/sec
0,16
0,33
0,5
0,7
1,6
2,6
3,3
6,6
9,8
13,1
16,4
20
23
26,2
m/s
0,05
0,1
0,15
0,2
0,5
0,8
1
2
3
4
5
6
7
8
DN
Flow Rate l/min
[mm]
20
15
0,5
1,1
1,6
2,1
5,3
8,5
10,6
21,3
31,9
42,5
53,2
63,8
74,4
85,1
25
20
0,9
1,9
2,8
3,8
9,5
15,1
18,9
37,8
56,7
75,6
94,5
113,4
132,3
151,2
32
25
1,5
3,0
4,4
5,9
14,8
23,6
29,5
59,1
88,6
118,1
147,7
177,2
206,8
236,3
40
32
2,4
4,8
7,3
9,7
24,2
38,7
48,4
96,8
145,2
193,6
242,0
290,4
338,8
387,1
50
40
3,8
7,6
11,3
15,1
37,8
60,5
75,6
151,2
226,8
302,5
378,1
453,7
529,3
604,9
63
50
5,9
11,8
17,7
23,6
59,1
94,5
118,1
236,3
354,4
472,6
590,7
708,9
827,0
945,2
75
65
10,0
20,0
30,0
39,9
99,8
159,7
199,7
399,3
599,0
798,7
998,3
1198,0
1397,7
1597,4
90
80
15,1
30,2
45,4
60,5
151,2
242,0
302,5
604,9
907,4
1209,8
1512,3
1.814,7
2117,2
2419,7
3780,7
110
100
23,6
47,3
70,9
94,5
236,3
378,1
472,6
945,2
1417,8
1890,4
2362,9
2835,5
3308,1
125
110
28,6
57,2
85,8
114,4
285,9
457,5
571,8
1143,7
1715,5
2287,3
2859,2
3431,0
4002,8
4574,7
140
125
36,9
73,8
110,8
147,7
369,2
590,7
738,4
1476,8
2215,3
2953,7
3692,1
4430,5
5169,0
5907,4
160
150
53,2
106,3
159,5
212,7
531,7
850,7
1063,3
2126,7
3190,0
4253,3
5316,6
6380,0
7443,3
8506,6
200
180
76,6
153,1
229,7
306,2
765,6
1225,0
1531,2
3062,4
4593,6
6124,8
7656,0
9187,1
10718,3
12249,5
225
200
94,5
189,0
283,6
378,1
945,2
1512,3
1890,4
3780,7
5671,1
7561,4
9451,8
11342,2
13232,5
15122,9
250
225
119,6
239,2
358,9
478,5
1196,2
1914,0
2392,5
4785,0
7177,5
9569,9
11962,4
14354,9
16747,4
19139,9
280
250
147,7
295,4
443,1
590,7
1476,8
2362,9
2953,7
5907,4
8861,1
11814,7
14768,4
17722,1
20675,8
23629,5
315
280
185,3
370,5
555,8
741,0
1852,6
2964,1
3705,1
7410,2
11115,3
14820,4
18525,5
22230,6
25935,7
29640,8
146
VELOCITY/FLOW RATE CONVERSION TABLES
Velocity [m/s] = (Flow Rate [l/h] x 0.35344) /
ID2
Flow Rate [l/h] = (Velocity [m/s] x ID2) / 0.35344
Velocity
D
ft/sec
0,16
0,33
0,5
0,7
1,6
3,3
6,6
9,8
13,1
16,4
20
23
26,2
m/s
0,05
0,1
0,15
0,2
0,5
1
2
3
4
5
6
7
8
5093
DN
Flow Rate l/h
[mm]
[mm]
20
15
32
64
95
127
318
637
1273
1910
2546
3183
3820
4456
25
20
57
113
170
226
566
1132
2263
3395
4527
5659
6790
7922
9054
32
25
88
177
265
354
884
1768
3537
5305
7073
8842
10610
12378
14147
40
32
145
290
435
579
1449
2897
5794
8692
11589
14486
17383
20281
23178
50
40
226
453
679
905
2263
4527
9054
13581
18108
22635
27162
31689
36215
63
50
354
707
1061
1415
3537
7073
14147
21220
28293
35367
42440
49513
56587
75
65
598
1195
1793
2391
5977
11954
23908
35862
47816
59770
71724
83678
95632
90
80
905
1811
2716
3622
9054
18108
36215
54323
72431
90539
108646
126754
144862
110
100
1415
2829
4244
5659
14147
28293
56587
84880
113173
141467
169760
198053
226347
125
110
1712
3423
5135
6847
17117
34235
68470
102705
136940
171175
205410
239645
273880
140
125
2210
4421
6631
8842
22104
44208
88417
132625
176833
221042
265250
309458
353667
160
150
3183
6366
9549
12732
31830
63660
127320
190980
254640
318300
381960
445620
509280
200
180
4584
9167
13751
18334
45835
91670
183341
275011
366682
458352
550023
641693
733364
225
200
2659
11317
16976
22635
56587
113173
226347
339520
452694
565867
679040
792214
905387
250
225
7162
14324
21485
28647
71618
143235
286470
429705
572940
716175
859410
1002645
1145880
280
250
8842
17683
26525
35367
88417
176833
353667
530500
707334
884167
1061000
1237834
1414667
315
280
11091
22182
33273
44364
110910
221820
443640
665459
887279
1109099
1330919
1552739
1774559
Velocity [m/s] = (Flow Rate [l/h] x 0.35344) / ID2
Flow Rate [l/h] = (Velocity [m/s] x ID2) / 0.35344
Velocity
D
[mm]
ft/sec
0,16
0,33
0,5
0,7
1,6
2,6
3,3
6,6
9,8
13,1
16,4
20
23
26,2
m/s
0,05
0,1
0,15
0,2
0,5
0,8
1
2
3
4
5
6
7
8
DN
Flow Rate m3/h
[mm]
20
15
0,03
0,06
0,10
0,13
0,32
0,51
0,64
1,27
1,91
2,55
3,18
3,82
4,46
5,09
25
20
0,06
0,11
0,17
0,23
0,57
0,91
1,13
2,26
3,40
4,53
5,66
6,79
7,92
9,05
32
25
0,09
0,18
0,27
0,35
0,88
1,41
1,77
3,54
5,31
7,07
8,84
10,61
12,38
14,15
40
32
0,14
0,29
0,43
0,58
1,45
2,32
2,90
5,79
8,69
11,59
14,49
17,38
20,28
23,18
50
40
0,23
0,45
0,68
0,91
2,26
3,62
4,53
9,05
13,58
18,11
22,63
27,16
31,69
36,22
63
50
0,35
0,71
1,06
1,41
3,54
5,66
7,07
14,15
21,22
28,29
35,57
42,44
49,51
56,59
75
65
0,60
1,20
1,79
2,39
5,98
9,56
11,95
23,91
35,86
47,82
59,77
71,72
83,68
95,63
90
80
0,91
1,81
2,72
3,62
9,05
14,49
18,11
36,22
54,32
72,43
90,54
108,65
126,75
144,86
110
100
1,41
2,83
4,24
5,66
14,15
22,63
28,29
56,59
84,88
113,17
141,47
169,76
198,05
226,35
125
110
1,71
3,42
5,14
6,85
17,12
27,39
34,23
68,47
102,70
136,94
171,17
205,41
239,64
273,88
140
125
2,21
4,42
6,63
8,84
22,10
35,37
44,21
88,42
132,63
176,83
221,04
265,25
309,46
353,67
160
150
3,18
6,37
9,55
12,73
31,83
50,93
63,66
127,32
190,98
254,64
318,30
381,96
445,62
509,28
180
4,58
9,17
13,75
18,33
45,84
73,34
91,67
183,34
275,01
366,68
458,35
550,02
641,69
733,36
200
5,66
11,32
16,98
22,63
56,59
90,54
113,17
226,35
339,52
452,69
565,87
679,04
792,21
905,39
250
225
7,16
14,32
21,49
28,65
71,62
114,59
143,24
286,47
429,71
572,94
716,18
859,41
1002,65
1145,88
280
250
8,84
17,68
26,53
35,37
88,42
141,47
176,83
353,67
530,50
707,33
884,17
1061,00
1237,83
1414,67
315
280
11,09
22,18
33,27
44,36
110,91
177,46
221,82
443,64
665,46
887,28
1109,10
1330,92
1552,74
1774,56
WWW.FLSNET.IT
147
TECHNICAL INFORMATION
200
225
VELOCITY/FLOW RATE CONVERSION TABLES
Velocity [f/s] = (Flow Rate [gpm] x 0.4085) / ID2
Flow Rate [gpm] = (Velocity [f/s] x ID2) / 0.4085
Velocity
D
[inch]
ft/sec
0,16
0,33
0,5
0,7
1,6
2,6
3,3
6,6
9,8
13,1
16,4
20
23
26,2
m/s
0,05
0,1
0,15
0,2
0,5
0,8
1
2
3
4
5
6
7
8
DN
Flow Rate US-gpm
[mm]
1/2
15
0,14
0,28
0,42
0,56
1,40
2,25
2,81
5,62
8,43
11,24
14,05
16,85
19,66
22,47
3/4
20
0,25
0,50
0,75
1,00
2,50
4,00
4,99
9,99
14,98
19,98
24,97
29,96
34,96
39,95
1
25
0,39
0,78
1,17
1,56
3,90
6,24
7,80
15,61
23,41
31,21
39,01
46,82
54,62
62,42
1 1/4
32
0,64
1,28
1,92
2,56
6,39
10,23
12,78
25,57
38,35
51,14
63,92
76,70
89,49
102,27
1 1/2
40
1,00
2,00
3,00
4,00
9,99
15,98
19,98
39,95
59,93
79,90
99,88
119,85
139,83
159,80
2
50
1,56
3,12
4,68
6,24
15,61
24,97
31,21
64,42
93,63
124,85
156,06
187,27
218,48
249,69
2 1/2
65
2,64
5,27
7,91
10,55
26,37
42,20
52,75
105,49
158,24
210,99
263,74
316,48
369,23
421,98
3
80
4,00
7,99
11,99
15,98
39,95
63,92
79,90
159,80
239,70
319,60
399,50
479,41
559,31
639,21
4
100
6,24
12,48
18,73
24,97
62,42
99,88
124,85
249,69
374,54
499,38
624,23
749,07
873,92
998,76
5
125
9,75
19,51
29,26
39,01
97,54
156,06
195,07
390,14
585,21
780,28
975,35
1170,42
1365,49
1560,56
6
150
14,05
28,09
42,14
56,18
140,45
224,72
280,90
561,80
842,70
1123,61
1404,51
1685,41
1966,31
2247,21
8
200
24,97
49,94
74,91
99,88
249,69
399,50
499,38
998,76
1498,14
1997,52
2496,90
2996,28
3495,66
3995,04
10
225
31,60
63,20
94,80
126,41
316,01
505,62
632,03
1264,06
1896,08
2528,11
3160,14
3792,17
4424,20
5056,23
12
300
48,94
97,88
146,82
195,76
489,39
783,03
978,79
1957,57
2936,36
3915,14
4893,93
5872,71
6851,50
7830,28
VELOCITY/FLOW RATE CONVERSION TABLES
To convert
VOLUME
LENGTH
Multiply by
fl. oz. (U.S.)
128
cubic inch
231
cubic ft.
134
liter
3.785
cubic meter
000.379
lmp. gallon
833
pound
833
lmperial Gallon
U.S. gallon
12
Cubic Foot
U.S. gallon
748
Cubic meter
00.283
Liter
U.S. gallon
2.642
Cubic meter
cubic ft.
35.314
lnch
U.S. gallon
2.642
centimeter
25.400
Foot
meter
3.048
Yard
meter
9.144
Mile
kilometer
16.093
WEIGHT
Ounce
Pound
gram
gram
283.495
45.359
FLOW RATE
US gallon per minute (gpm)
liter per second
0.063
US gallon per minute (gpm)
cubic meter per hr.
227
UK gallon per minute (gpm)
cubic meter per hr.
273
Atmosphere
bar
10.133
PRESSURE
TEMPERATURE
148
US Gallon
Into
Psi [lb/inch2]
bar
00.689
Pascal [Newton/m2]
bar
10-5
MegaPascal
bar
10
Kelvin [°K]
Fahrenheit [°F]
celsius [°C]
celsius [°C]
°C = °K - 273
°C = (°F - 32) x 5/9
ANALYTICAL MEASUREMENT
PH MEASUREMENT
Definition
pH is defined as the negative logarithm of the hydrogen ion activity, aH+,
in a solution.
So:
pH = - log(aH+)
pH Measuring technology
pH is measured using a setup with two electrodes: the measuring
electrode and the reference electrode. These two electrodes are often
combined into one which is defined as a “combined electrode”. All pH
electrodes supplied by FLS are “combined”.
When the two electrodes are immersed in a solution, a small galvanic cell
is established.
The potential developed is dependent on both electrodes.
The measured voltage can be expressed by the Nernst equation in the
following way:
E = Emeas - Eref = E0 - (2,303RT/F)pH
where
E = Measured voltage
Emeas = Voltage of measuring electrode
Eref = Voltage of reference electrode
E0= standard electrode potential
R = Gas Constant
T = Absolute Temperature
F = Faraday’s constant
Then, it means that relationship between pH and E is linear correlated to
the temperature.
The value of the slope at 25°C is 59,18 mV/pH. It is around 54 mV/pH at
5°C and around 62mV/pH at 40°C. At 100°C slope increases till around
74mV/pH.
pH technical terms
Calibration
Determination of offset and slope of a pH system.
In order to evaluate both electrode features calibration has to be
performed for two pH points.
A calibration on sample solution can be done in order to consider chemical
species which can affect pH measurement.
Calibration solution (Buffers)
A solution at known pH value which is used to calibrate the pH system.
Calibration solutions are affected by temperature.
The temperature dependency of the buffers is well known.
Following the dependency of buffers supplied by FLS:
150
°C
°F
pH buffer solution
4,01
pH buffer
solution 7,00
pH buffer solution
10,00
0
32
4,01
7,12
10,31
5
41
4,00
7,09
10,24
10
50
4,00
7,06
10,17
15
59
4,00
7,04
10,11
20
68
4,00
7,02
10,05
25
77
4,01
7,00
10,00
30
86
4,01
6,99
9,95
35
95
4,02
6,98
9,92
40
104
4,03
6,97
9,88
45
113
4,04
6,97
9,85
pH technical terms
Reference temperature
pH readings are often referenced to a specific temperature, usually 25°C,
for comparative purposes.
Automatic temperature compensation
Algorithms for automatic conversion of sample pH to a reference
temperature.
This function considers the variation of pH slope with temperature.
pH electrode operating principle
The pH electrode is a very high-impedance galvanic cell in which the
potential developed between the pH half-cell and the reference half-cell is
the sum of various potentials. Figure A shows a typical glass combination
pH electrode in which the pH half-cell and the reference half-cell are
combined into a single design.
Ideally, all of the potentials are constant, except for one generated on the
outer hydrated gel layer that depends on the pH of the sample according
to the Nernst equation.
Real electrodes differ from an ideal electrode due to various factors,
including:
1) manufacturing tolerances,
2) electrode aging,
3) electrode conditioning and cleaning.
All pH meters allow for calibration or standardization of the electrode
to compensate for the above effects. A standard calibration involves
measuring the response of the electrode in two pH buffer solutions with
well known pH values and creating a linear map of the electrode response
to these two points. This results in offset and slope correction factors,
where the offset is the mV rending at pH 7 and the slope is the change in
mV response per pH unit, usually expressed in mV/pH is a percentage of
the ideal slope of the electrode (59.16 mV/pH at 25 °C).
151
TECHNICAL INFORMATION
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ORP MEASUREMENT
Definition
Oxidation-Reduction Potential (O.R.P.) is a measurement of the tendency
of a solution to oxidize or to reduce what can be in contact with it.
A oxidant solution is a liquid which tends to gain electrons oxidizing what is
in contact reducing itself.
A reductant solution is a liquid which tends to lose electrons reducing what
is in contact oxidizing itself.
ORP Measuring technology
ORP electrode produces a voltage as well as pH electrode. In this case,
measurement is not affected by hydrogen ions only, but it’s affected by all
chemical species which can give or receive electrons.
Although ORP is affected by temperature and in principle it follows Nernst
equation, it’s difficult to compensate measurement as usually it’s unknown
how many electrons are involved into Redox reactions (in case ORP
measurement is used to monitor a reaction only it’s possible to determine
main involved semi reaction and so it could be possible to do it).
Also in ORP measurement, it’s used a setup with two electrodes: the
measuring electrode and the reference electrode. These two electrodes
are often combined into one which is defined as a “combined electrode”.
All ORP electrodes supplied by FLS are “combined”.
When the two electrodes are immersed in a solution, a small galvanic cell
is established.
The potential developed is dependent on both electrodes and usually it
moves from -1000mV up to +1000mV.
Although it’s a no-specific measurement, it can be very useful to monitor
and control activity of specific compounds. Applications that use ORP for
monitoring and controlling oxidation-reduction reactions include cyanide
destruction, dechlorination, nitrite and hydrosulfite oxidation, chromate
reduction, hypochlorite bleach production, and chlorine and chlorine
dioxide scrubber monitoring using bisulfite. Concentration measurement
with ORP is problematic, but ORP can be used in some cases for leak
detection to evaluate the presence of an oxidant or reductant.
Finally, ORP is measured, in some instances, for the control of biological
growth. The principle behind these applications is that a minimum ORP
value will successfully destroy microorganisms. This approach has been
used in the chlorination of swimming pools and cooling towers. It should
be noted that both of these applications also include pH control.
ORP technical terms
152
Calibration
Determination of offset of a ORP system.
The slope of ORP electrode is less variable than pH electrode since the
ORP sensors are made of noble (more or less non-reactive) metals such
as Platinum (suggested for strong oxidants contained chlorides and in
general for Redox titration), Gold (preferred for strong acid solution and
in presence of iron and chrome) or rarely Silver and do not change very
much with use. Response times of these sensors depends on the surface
area, size and construction, and how clean the sensor is.
For most ORP applications, the absolute accuracy is less important than
the speed and relative changes measured in the system. Many procedures
and specifications call for target ORP values with tolerances of ±25 mV,
or ±50 mV, or they specify changes in ORP such as a 400 mV drop in
the value with a target end point value. Since ORP has a variety of uses
with methods that have their own specialized target readings or reading
changes that are based on experience, we can not elaborate on these
in detail. It is sufficient to say the precision required for pH and other
electrochemical measurements typically does not apply for ORP, and so
calibration for ORP electrodes and meters is not so common.
ORP technical terms
Calibration solution
A solution at known ORP value which is used to check the ORP system.
In principle, as explained previously, the absolute ORP value is not so
important and then the use of a ORP calibration solution can applied just
for checking purpose.
The main use of a calibration solution or a ORP reference solution is just
to simplify comparison purpose.
In other words, a offset evaluation can be necessary in case of electrode
replacement when the new probe measures a different value comparing
to the former electrode and so a calibration can be necessary to align the
new value to the former one.
If for example, a method calls for a target value of 410 mV which was
defined with your previous electrode and instrument, the new electrode
with the same instrument may read 425 mV in the same liquid. Using the
calibration or, more properly, the offset adjustment, this 15 mV difference
can be eliminated avoiding confusion. Then when the other readings
occur, they can be comparable easily with those from the old electrode.
ORP electrode operating
principle
The principle of ORP measurement is the use of an inert metal electrode
(platinum, sometimes gold, rarely silver), which, due to its low resistance,
will give up electrons to an oxidant or accept electrons from a reductant.
The ORP electrode will continue to accept or give up electrons until it
develops a potential, due to the build-up charge, which is equal to the
ORP of the solution. The typical accuracy of an ORP measurement is ±5
mV. Also ORP electrode needs a reference electrode which is typically the
same silver-silver chloride electrode used with pH measurement.
CONDUCTIVITY MEASUREMENT
Conductivity is the ability of a solution to pass an electric current. In
solutions the current is carried by cations and anions.
The solution capability to conduct electricity depends on a number of
factors:
• Concentration
• Mobility of ions
• Valence of ions
• Temperature
All substances have a different level of conductivity. In aqueous solutions
the level of ionic strength varies from the low conductivity of ultrapure
water to the high conductivity of concentrated chemical samples.
Conductivity measuring
technology
Conductivity may be measured by applying an alternating electrical current
(I) to two electrodes immersed in a solution and measuring the resulting
voltage (V). During this process, cations migrate to the negative electrode
while anions to the positive electrode and the solution acts as an electrical
conductor.
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TECHNICAL INFORMATION
Definition
Conductivity technical
terms
Resistance
The resistance of the solution (R) can be calculated using Ohm’s law
(V = R x I).
R = V/I
where:
V = voltage (volts)
I = current (amperes)
R = resistance of the solution (ohms)
Conductance
Conductance (G) is defined as the reciprocal of the electrical resistance
(R) of a solution between two electrodes.
G = 1/R
The conductivity meter in fact measures the conductance, and displays the
reading converted into conductivity.
Cell constant
This is the ratio of the distance (d) between the electrodes to the area (a)
of the electrodes.
K = d/a
K = cell constant (cm-1)
a = effective area of the electrodes (cm2)
d = distance between the electrodes (cm)
Conductivity
Electricity is the flow of electrons. This indicates that ions in solution will
conduct electricity. Conductivity is the ability of a solution to pass current.
The conductivity reading of a sample will change with temperature.
C= G x K
C= conductivity (S/cm)
G = conductance (S), where G = 1/R
K = cell constant (cm-1)
Resistivity
This is the reciprocal of the conductivity value and is measured in ohm•cm.
It is generally limited to the measurement of pure water, the conductivity of
which is very low.
Calibration
Determination of the cell constant required to convert conductance
readings into conductivity results.
Standard solution
A solution of known conductivity that is used to calibrate the conductivity
system.
Reference temperature
Conductivity readings are often referenced to a specific temperature,
typically 18°C, 20°C or 25°C, for comparative purposes.
Automatic temperature compensation
Algorithms for automatic conversion of sample conductivity to a reference
temperature.
Temperature compensation factor
Factor used for automatic compensation. Usually is considered as a %
/°C.
For UPW application, on FLS instrumentation, is available a special
correlation based on ASTM D1125-19.
Total Dissolved Solids (TDS)
This is the measure of the total concentration of ionic species of a sample.
It is relative to the standard solution used to calibrate the instrument or to
the salt solution to which user has decided to refer.
154
Conductivity technical
terms
Conductivity operating
principle
TDS factor
Conductivity readings are converted to TDS readings by multiplication
with a known mathematical factor. The factor depends on the reference
compound (usually a salt) used to prepare the standard or on the
reference material considered. For example: seawater contains a lot of
different salts but mainly NaCl, so user could refer just to it.
Following few examples of factor:
Reference salts
Conversion factor range
NaCl
0,47-0,50
KCl
0,50-0,57
442
(40%NaSO4+40%NaHCO3+20%NaCl)
0,65-0,85
2-electrodes conductivity sensor
A 2-electrodes conductivity sensor is made up of an insulating material
with 2 electrodes embedded. Electrodes can be made in platinum,
graphite, stainless steel or other metallic materials. These metal contacts
work as sensing elements and are placed at a fixed distance apart to
make contact with a solution whose conductivity is to be determined.
The distance between the sensing elements, as well as the surface
area of the metallic piece, determine the electrode cell constant, defined
as relationship distance/area. The cell constant is a critical parameter
affecting the conductance value produced by the cell and handled by the
electronic circuit.
A cell constant of 1.0 will produce a conductance reading approximately
equal to the solution conductivity. For solutions of low conductivity, the
sensing electrodes can be placed closer reducing the distance between
them and producing cell constants of 0.1 or 0.01. This will raise the
conductance reading by a factor of 10 to 100 to offset the low solution
conductivity and give a better signal to the conductivity meter. On the other
hand, the sensing electrodes can be placed farther to create cell constants
of 10 for measurement of high conductive solutions. This also produces a
conductance acceptable to the meter by reducing the conductance reading
by a factor of 10.
In order to produce a measuring signal acceptable to the conductivity
meter, it is highly important that the user choose a conductivity electrode
with a cell constant appropriate for his sample. The table below lists the
optimum conductivity range for cells with different cell constants.
Optimum Conductivity Range
0.01
0.055 - 20 μS/cm
0.1
0.5 - 200 μS/cm
1.0
0.01 - 2 mS/cm
10.0
1 - 200 mS/cm
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TECHNICAL INFORMATION
Cell Constant
Conductivity technical
terms
156
Inductive toroidal conductivity instrument
The inductive toroidal conductivity sensor is made up of two high-grade
toroids (coils) which are incorporated concentrically and adjacent to
one another in a non-conductive body. The primary coil is excited with
a sinusoidal alternating voltage creating a changing magnetic field. This
changing magnetic field causes the ions in the solution to move through
the center of the toroid. This ion motion is equivalent to an AC current
flowing through the center of the toroid. The AC current produces an AC
current in the sensing coil that is proportional to the conductivity of the
solution. Ideally the signal in the sensing coil should be due to the ion
motion only and not due to the changing magnetic field created by the
primary coil. For this reason good magnetic shielding is needed between
the coils.
NOTES
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NOTES
158
NOTES
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Cod. LEFLSCAT 10/2015 Rev.1
FIP Formatura Iniezione Polimeri
Loc. Pian di Parata, 16015 Casella Genova Italy
Tel. +39 010 9621.1
Fax +39 010 9621.209
info.fip@aliaxis.com
www.fipnet.com - www.flsnet.it
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