User manual_SmartVFD Compact

User manual_SmartVFD Compact
Ho
Honeywell
User Manual
SmartVFD Compact
Variable Frequency Drives
for Constant and Variable
Torque Applications
62-0312-03
Honeywell
1
User’s Manual
Index
1. SAFETY .........................................................................................4
1.1 Warnings ...............................................................................4
1.2 Safety instructions .................................................................6
1.3 Grounding and Ground fault protection .................................6
1.4 Before running the motor .......................................................7
2. RECEIPT OF DELIVERY ...............................................................8
2.1 Type designation code .........................................................8
2.2 Storage ..................................................................................9
2.3 Maintenance ..........................................................................9
2.4 Warranty ................................................................................9
3. TECHNICAL DATA ........................................................................10
3.1 SmartVFD Compact technical data .......................................10
3.2 Power ratings ........................................................................11
3.2.1 SmartVFD Compact - Mains voltage 208 - 240 V .......11
3.2.2 SmartVFD Compact - Mains voltage 380 - 480 V .......11
3.2.3 SmartVFD Compact - Mains voltage 230 V, 3~ ..........12
3.2.4 SmartVFD Compact - Mains voltage 115 V, 1~ ..........12
3.2.5 SmartVFD Compact - Mains voltage 575 V, 3~ ..........13
4. INSTALLATION .............................................................................14
4.1 Mechanical installation ..........................................................14
4.1.1 SmartVFD Compact dimensions .................................15
4.1.2 Cooling ........................................................................16
4.1.3 EMC levels ..................................................................16
4.1.4 Changing the EMC protection class from H or L to T .17
4.2 Cabling and connections .......................................................18
4.2.1 Power cabling .............................................................18
4.2.2 Control cabling ............................................................19
4.2.3 Cable and fuse specifications .....................................21
4.2.4 General cabling rules ..................................................22
4.2.5 Stripping lengths of motor and mains cables ..............23
4.2.6 Cable installation and the UL standards .....................23
4.2.7 Cable and motor insulation checks .............................23
5. COMMISSIONING ..........................................................................25
5.1 Commissioning steps of SmartVFD Compact .......................25
6. FAULT TRACING ..........................................................................27
7. SMARTVFD COMPACT APPLICATION INTERFACE .................30
7.1 Introduction ............................................................................30
2
Honeywell
7.2 Control I/O .............................................................................32
8. CONTROL PANEL .........................................................................34
8.1 General ..................................................................................34
8.2 Display ...................................................................................34
8.3 Keypad ..................................................................................35
8.4 Navigation on the SmartVFD Compact control panel ............36
8.4.1 Main menu ...................................................................36
8.4.2 Reference menu ..........................................................37
8.4.3 Monitoring menu ..........................................................38
8.4.4 Parameter menu ..........................................................40
8.4.5 Fault history menu .......................................................41
9. GENERAL PURPOSE APPLICATION PARAMETERS ................43
9.1 Quick setup parameters (Virtual menu, shows when par.
13.1 = 1) ........................................................................................44
9.2 Motor settings (Control panel: Menu PAR -> P1) ..................46
9.3 Start/stop setup (Control panel: Menu PAR -> P2) ................47
9.4 Frequency references (Control panel: Menu PAR -> P3) ......47
9.5 Ramps and brakes setup (Control panel: Menu PAR -> P4) 48
9.6 Digital inputs (Control panel: Menu PAR -> P5) ....................48
9.7 Analogue inputs (Control panel: Menu PAR -> P6) ...............50
9.8 Digital and analogue outputs (Control panel: Menu PAR > P7) ............................................................................................50
9.9 Protections (Control panel: Menu PAR -> P9) .......................52
9.10 Autorestart parameters (Control panel: Menu PAR ->
P10 ) ..........................................................................................53
9.11 PI control parameters (Control panel: Menu PAR -> P12) ..54
9.12 Easy usage menu (Control panel: Menu PAR -> P0) .........55
9.13 System parameters .............................................................55
10. PARAMETER DESCRIPTIONS ...................................................57
10.1 Motor settings (Control panel: Menu PAR -> P1) ................57
10.2 Start/Stop setup (Control panel: Menu PAR -> P2) .............60
10.3 Frequency references (Control panel: Menu PAR -> P3) ....62
10.4 Ramps & brakes setup (Control panel: Menu PAR -> P4) ..62
10.5 Digital inputs (Control panel: Menu PAR -> P5) ..................65
10.6 Analoque inputs (Control panel: Menu PAR -> P6) .............66
10.7 Digital and analoque outputs (Control panel: Menu PAR
-> P7) ..........................................................................................67
10.8 Motor thermal protection (parameters 9.7 - 9.10) ................67
10.9 Autorestart parameters (Control panel: Menu PAR ->
P10) ...........................................................................................69
10.10 PI control parameters (Control panel: Menu PAR -> P12) 70
Honeywell
3
10.11 Easy usage menu (Control panel: Menu PAR -> P9) ........71
10.12 Fieldbus parameters (Control panel: Menu PAR -> S2) ....73
10.12.1 Modbus process data ..............................................74
1
4
Safety
Honeywell
1. SAFETY
ONLY A COMPETENT ELECTRICIAN IS ALLOWED TO
CARRY OUT THE ELECTRICAL INSTALLATION!
This manual contains clearly marked cautions and warnings which are intended for
your personal safety and to avoid any unintentional damage to the product or connected appliances.
Please read the information included in cautions and warnings carefully:
= Dangerous voltage
Risk of death or severe injury
= General warning
Risk of damage to the product or
connected appliances
1.1 WARNINGS
1
2
3
4
5
The components of the power unit of the frequency converter
are live when SmartVFD Compact is connected to mains potential. Coming into contact with this voltage is extremely dangerous
and may cause death or severe injury. The control unit is isolated from the mains potential.
The motor terminals U, V, W (T1, T2, T3) and the possible brake
resistor terminals -/+ are live when SmartVFD Compact is connected to mains, even if the motor is not running.
The control I/O-terminals are isolated from the mains potential.
However, the relay output terminals may have a dangerous control voltage present even when SmartVFD Compact is disconnected from mains.
The ground leakage current of SmartVFD Compact frequency
converters exceeds 3.5mA AC. According to standard EN618005-1, a reinforced protective ground connection must be ensured.
If the frequency converter is used as a part of a machine, the
machine manufacturer is responsible for providing the machine
with a main switch (EN 60204-1).
Safety
Honeywell
6
7
5
If SmartVFD Compact is disconnected from mains while running
the motor, it remains live if the motor is energized by the process. In this case the motor functions as a generator feeding
energy to the frequency converter.
After disconnecting the frequency converter from the mains, wait
until the fan stops and the indicators on the display go out. Wait
5 more minutes before doing any work on SmartVFD Compact
connections.
1
1
6
Safety
Honeywell
1.2 SAFETY INSTRUCTIONS
1
The SmartVFD Compact frequency converter has been designed
for fixed installations only.
2
Do not perform any measurements when the frequency converter
is connected to the mains.
3
Do not perform any voltage withstand tests on any part of SmartVFD Compact. The product safety is fully tested at factory.
4
Prior to measurements on the motor or the motor cable, disconnect the motor cable from the frequency converter.
5
Do not open the cover of SmartVFD Compact. Static voltage discharge from your fingers may damage the components. Opening
the cover may also damage the device. If the cover of SmartVFD
Compact is opened, warranty becomes void.
1.3 GROUNDING AND GROUND FAULT PROTECTION
The SmartVFD Compact frequency converter must always be grounded with an
grounding conductor connected to the grounding terminal. See figure below:
•
The ground fault protection inside the frequency converter protects
only the converter itself against ground faults.
•
If fault current protective switches are used they must be tested
with the drive with ground fault currents that are possible to arise in
fault situations.
Honeywell
Safety
1.4 BEFORE RUNNING THE MOTOR
Checklist:
Before starting the motor, check that the motor is mounted
properly and ensure that the machine connected to the motor
allows the motor to be started.
Set the maximum motor speed (frequency) according to the
motor and the machine connected to it.
Before reversing the motor shaft rotation direction make sure
that this can be done safely.
Make sure that no power correction capacitors are connected
to the motor cable.
7
1
8
Receipt of Delivery
Honeywell
2. RECEIPT OF DELIVERY
After unpacking the product, check that no signs of transport damages are to be
found on the product and that the delivery is complete (compare the type designation
of the product to the code below).
Should the drive have been damaged during the shipping, please contact primarily
the cargo insurance company or the carrier.
If the delivery does not correspond to your order, contact the supplier immediately.
2.1
TYPE DESIGNATION CODE
Figure 2.1: SmartVFD Compact type designation code
2
Honeywell
Receipt of Delivery
9
2.2 STORAGE
If the frequency converter is to be kept in store before use make sure that the ambient
conditions are acceptable:
Storing temperature -40 °F(-40 °C)…+70 °F(21 °C)
Relative humidity < 95%, no condensation
2.3
MAINTENANCE
In normal operating conditions, SmartVFD Compact frequency converters are maintenance-free.
2.4
WARRANTY
Only manufacturing defects are covered by the warranty. The manufacturer assumes no responsibility for damages caused during or resulting from transport, receipt of the delivery, installation, commissioning or use.
The manufacturer shall in no event and under no circumstances be held responsible
for damages and failures resulting from misuse, wrong installation, unacceptable
ambient temperature, dust, corrosive substances or operation outside the rated
specifications. Neither can the manufacturer be held responsible for consequential
damages.
Variable frequency drive devices (VFD) and accessories: new products for thiry-six
(36) months and factory refurbished drives for twelve (12) months from date of installation when start-up and commissioning is performed by Honeywell VFD Authorized and trained personnel. All VFD warranty return products must have
priorauthorization (Form No. 87-0284) and be returned only to the VFD Service Center in Chattanooga, TN.
2
3
10
Technical Data
Honeywell
3. TECHNICAL DATA
3.1 SMARTVFD COMPACT TECHNICAL DATA
Frame
Dimensions
and weight
0 - Uin
Continuous rated current IN at ambient temperature max. 122 ºF (+50 ºC), overload 1.5 x IN max.
1min/10min
14 °F (-10 °C) (no frost)…122 °F (+50 °C): rated
loadability IN
Storage temperature
Relative humidity
Enclosure class
Immunity
Emissions
Standards
Certificates
and
manufacturer’s
declarations of
conformity
Weight (lb)
Output voltage
Altitude
EMC
D (in)
Output current
Ambient operating
temperature
Ambient
conditions
W (in)
6.1
2.6
3.9
1.2
7.7
3.5
4.0
1.5
10.3
3.9
4.3
2.18
SmartVFD Compact (400V) cannot be used with
corner grounded networks
Supply
network
Motor
connection
H (in)
MI1
MI2
MI3
-40 °F (-40 °C)…+158 °F (+70 °C)
0…95% RH, non-condensing, non-corrosive, no
dripping water
100% load capacity (no derating) up to 3280 ft.
1% derating for each 328 ft above 3280 ft; max.
6560 ft
IP20 (open Chassis), option: NEMA 1
Complies with EN50082-1, -2, EN61800-3
230V : Complies with EMC category C2 (Honeywell level H); With an internal RFI filter
400V: Complies with EMC category C2 (Honeywell level H): With an internal RFI filter
Both: No EMC emission protection (Honeywell
level N): Without RFI filter
For EMC: EN61800-3,
For safety: UL508C, EN61800-5-1
For safety: CB, CE, UL, cUL,
For EMC: CE, CB, c-tick
(see unit nameplate for more detailed approvals)
Table 3.1 : SmartVFD Compact technical data
Technical Data
Honeywell
11
3.2 POWER RATINGS
3.2.1 SmartVFD Compact - Mains voltage 208 - 240 V
Mains voltage 208-240 V, 50/60 Hz, 1~ series
Product code
HVFDCD1B0003xxx
HVFDCD1B0005xxx
HVFDCD1B0007xxx
HVFDCD1B0010xxx
HVFDCD1B0015xxx
HVFDCD1B0020xxx
HVFDCD1B0030xxx
Rated loadability
100% contin.
current IN [ A ]
150% overload
current [ A ]
Motor
shaft
power
P
[ HP ]
1.7
2.4
2.8
3.7
4.8
7.0
9.6
2.6
3.6
4.2
5.6
7.2
10.5
14.4
0.25
0.5
0.75
1
1.5
2
3
Nominal
input
current
[A]
Mechanical
size and
weight (lb)
4.2
5.7
6.6
8.3
11.2
14.1
15.8
MI1 1.2
MI1 1.2
MI1 1.2
MI2 1.5
MI2 1.5
MI2 1.5
MI3, 2.18
Table 3.2 : SmartVFD Compact power ratings, 208 - 240 V
3.2.2 SmartVFD Compact - Mains voltage 380 - 480 V
Mains voltage 380-480 V, 50/60 Hz, 3~ series
Product code
HVFDCD3C0005xxx
HVFDCD3C0007xxx
HVFDCD3C0010xxx
HVFDCD3C0015xxx
HVFDCD3C0020xxx
HVFDCD3C0030xxx
HVFDCD3C0040xxx
HVFDCD3C0050xxx
HVFDCD3C0075xxx
Rated loadability
Motor shaft
power
100%
continuous
current
IN [ A ]
150%
overload
current
[A]
380-480V
supply
P[ HP ]
1.3
1.9
2.4
3.3
4.3
5.6
7.6
9.0
12.0
2.0
2.9
3.6
5.0
6.5
8.4
11.4
13.5
18.0
0.5
0.75
1
1.5
2
3
4
5
7.5
Table 3.3 : SmartVFD Compact power ratings, 380 - 480 V
Nomina Mechanical
l input
size and
current weight (lb)
[A]
2.2
2.8
3.2
4.0
5.6
7.3
9.6
11.5
14.9
MI1 1.2
MI1 1.2
MI1 1.2
MI2 1.5
MI2 1.5
MI2 1.5
MI3, 2.18
MI3, 2.18
MI3, 2.18
3
3
12
Technical Data
Honeywell
3.2.3 SmartVFD Compact - Mains voltage 230 V, 3~
Mains voltage 208-240 V, 50/60 Hz, 3~ series
Product code
HVFDCD3B0003xxx
HVFDCD3B0005xxx
HVFDCD3B0007xxx
HVFDCD3B0010xxx
HVFDCD3B0015xxx
HVFDCD3B0020xxx
HVFDCD3B0030xxx
Rated loadability
Motor shaft
power
100% contin.
current
IN [ A ]
150%
overload
current [ A ]
P[ HP ]
1.7
2.4
2.8
3.7
4.8
7.0
11
2.6
3.6
4.2
5.6
7.2
10.5
16.5
0.33
0.5
0.75
1
1.5
2
3
Nomina Mechanical
l input
size and
current weight (lb)
[A]
2.7
3.5
3.8
4.3
6.8
8.4
13.4
MI1 1.2
MI1 1.2
MI1 1.2
MI2 1.5
MI2 1.5
MI2 1.5
MI3 2.18
Table 3.4 : SmartVFD Compact power ratings 208 - 240 V, 3~
3.2.4 SmartVFD Compact - Mains voltage 115 V, 1~
Mains voltage 115 V, 50/60 Hz, 1~ series
Product code
HVFDCD1A0003xxx
HVFDCD1A0005xxx
HVFDCD1A0007xxx
HVFDCD1A0010xxx
HVFDCD1A0015xxx
Rated loadability
Motor shaft
power
100%
continuous
current
IN [ A ]
150%
overload
current
[A]
380-480V
supply
P[ HP ]
1.7
2.4
2.8
3.7
4.8
2.6
3.6
4.2
5.6
7.2
0.33
0.5
0.75
1
1.5
Table 3.5 : SmartVFD Compact power ratings 115 V, 1~
Note! The output voltage of the 115 V drives is 230 V.
Nomina Mechanical
l input
size and
current weight (lb)
[A]
9.2
11.6
12.4
15
16.5
MI2 1.5
MI2 1.5
MI2 1.5
MI2 1.5
MI3 2.18
Technical Data
Honeywell
13
3.2.5 SmartVFD Compact - Mains voltage 575 V, 3~
Mains voltage 575 V, 50/60 Hz, 3~ series
Product code
Rated loadability
100% contin.
current
IN [ A ]
HVFDCD3D0010xxx
HVFDCD3D0020xxx
HVFDCD3D0030xxx
HVFDCD3D0055xxx
HVFDCD3D0075xxx
HVFDCD3D0100xxx
1.7
2.7
3.9
6.1
9
11
150%
overload
current
[A]
2.6
4.1
5.9
9.2
13.5
16.5
Motor shaft
power
P[ HP ]
1
2
3
5.4
7.5
10
Nomina Mechanical
l input
size and
current weight (lb)
[A]
2
3.6
5
7.6
10.4
14.1
MI3 2.18
MI3 2.18
MI3 2.18
MI3 2.18
MI3 2.18
MI3 2.18
Table 3.6 : SmartVFD Compact power ratings 575 V, 3~
Note 1: The input currents are calculated values with 100 kVA line transformer supply.
Note 2: The mechanical dimensions of the units are given in Chapter 4.1.1.
3
14
Installation
Honeywell
4. INSTALLATION
4.1 MECHANICAL INSTALLATION
There are two possible ways to mount the SmartVFD Compact to the wall - either
screw or DIN-rail mounting. The mounting dimensions are given on the back of the
drive and on the following page.
MI1
MI2-3
=M 5
=M 4
Figure 4.1: Screw mounting
1
Figure 4.2: DIN-rail mounting
4
2
Installation
Honeywell
15
4.1.1 SmartVFD Compact dimensions
W2
D2
W3
H1
H2
H3
Honeywell
D1
W1
Figure 4.3: SmartVFD Compact dimensions, MI1-MI3
Type
H1
H2
MI1
MI2
MI3
6.
7.7
10.
5.8.4.6.5.2.9
0.3
6.7
3.5
0.2
4
0.3
7.2
2.5
9.
9..9.0.2.3.3
H3
W1
W2
W3
D1
D2
Table 4.1 : SmartVFD Compact dimensions in inches
4
16
Installation
Honeywell
4.1.2 Cooling
Forced air flow cooling is used in all SmartVFD Compact drives.
Enough free space must be left above and below the frequency converter to ensure
sufficient air circulation and cooling. The required dimensions for free space are given in the table below:
Type
MI1
MI2
MI3
Dimensions (inch)
A
3.9
3.9
3.9
A
B
2.0
2.0
2.0
Table 4.2 : Dimensions required for cooling
Type
Cooling air required (CFM)
MI1
MI2
MI3
5.89
5.89
17.7
Honeywell
B
Table 4.3 : Required cooling air
mk6.fh11
4.1.3 EMC levels
SmartVFD Compact frequency converters are divided into five classes according to
the level of electromagnetic disturbances emitted, the requirements of a power system network and the installation environment (see below). The EMC class of each
product is defined in the type designation code.
Category C1: Frequency converters of this class comply with the requirements of
category C1 of the product standard EN 61800-3 (2004). Category C1 ensures the
best EMC characteristics and it includes converters the rated voltage of which is less
than 1000V and which are intended for use in the 1st environment. NOTE: The requirements of class C are fulfilled only as far as the conducted emissions are concerned.
Category C2: Frequency converters of this class comply with the requirements of
category C2 of the product standard EN 61800-3 (2004). Category C2 includes converters in fixed installations and the rated voltage of which is less than 1000V. The
class H frequency converters can be used both in the 1st and the 2nd environment.
Category C3: Frequency converters of this class comply with the requirements of
category C3 of the product standard EN 61800-3 (2004). Cateory C3 includes converters the rated voltage of which is less than 1000V and which are intended for use
in the second environment only.
4
Honeywell
Installation
17
Category C4: The drives of this class do not provide EMC emission protection.
These kinds of drives are mounted in enclosures. NOTE: An external EMC filter is
usually required to fulfil the EMC emission requirements.
Category C4 for IT networks: Frequency converters of this class fulfil the product
standard EN 61800-3 (2004) if intended to be used in IT systems. In IT systems, the
networks are isolated from ground, or connected to ground through high impedance
to achieve a low leakage current. NOTE: if converters are used with other supplies,
no EMC requirements are complied with.
Environments in product standard EN 61800-3 (2004)
First environment: Environment that includes domestic premises. It also includes
establishments directly connected without intermediate transformers to a low-voltage
power supply network which supplies buildings used for domestic purposes.
NOTE: houses, apartments, commercial premises or offices in a residential building
are examples of first environment locations.
Second environment: Environment that includes all establishments other than
those directly connected to a low-voltage power supply network which supplies buildings used for domestic purposes.
NOTE: industrial areas, technical areas of any building fed from a dedicated transformer are examples of second environment locations.
4.1.4 Changing the EMC protection class from H or L to T
The EMC protection class of SmartVFD Compact frequency converters can be
changed from class H or L to class T by removing the EMC-capacitor disconnecting screw, see figure below.
Note! Do not attempt to change the EMC level back to class H or L. Even if the procedure above is reversed, the frequency converter will no longer fulfil the EMC requirements of class H/L!
4
18
Installation
Honeywell
4.2 CABLING AND CONNECTIONS
4.2.1 Power cabling
Note! Tightening torque for power cables is 4 - 5 in-lbs.
3~ (400V)
Motor out
1~ (230V)
Strip the
plastic cable
coating for
360° grounding
MOTOR
MAINS
Figure 4.4: SmartVFD Compact power connections, MI1
3~ (400V)
1~ (230V)
External brake
resistor (400V)
Motor out
L1 L2/N L3 R+ R- U/T1 V/T2 W/T3
Strip the
plastic
cable
coating
for 360°
grounding
MAINS
BRAKE
RESISTOR
MOTOR
Figure 4.5: SmartVFD Compact power connections, MI2 - MI3
4
Installation
Honeywell
19
4.2.2 Control cabling
Attach the support
AFTER installing
the power cables
Honeywell
Attach this plate
BEFORE installing
the power cables
Figure 4.6: Mount the PE- plate and API cable support
4
20
Installation
Honeywell
Figure 4.7: Open the cover
Control cable
tightening
torque: 3 in-lbs
Strip the plastic
cable coating for
360°earthing
Figure 4.8: Install the control cables. See Chapter 7.2
4
Installation
Honeywell
21
4.2.3 Cable and fuse specifications
Use cables with heat resistance of at least 158 °F (+70 °C). The cables and the fuses
must be sized according to the tables below. Installation of cables according to UL
regulations is presented in Chapter 4.2.6.
The fuses also function as cable overload protection.
These instructions apply only to cases with one motor and one cable connection from
the frequency converter to the motor. In any other case, ask the factory for more information.
EMC class
Mains cable types
Motor cable types
Control cable types
Level H
1
3
4
Level L
1
2
4
Level N
1
1
4
Table 4.4 : Cable types required to meet standards. EMC levels are described in
Chapter 4.1.3.
Cable type
Description
1
Power cable intended for fixed installation and the specific
mains voltage. Shielded cable not required.
(NKCABLES/MCMK or similar recommended)
2
Power cable equipped with concentric protection wire and
intended for the specific mains voltage.
(NKCABLES /MCMK or similar recommended).
3
Power cable equipped with compact low-impedance shield and
intended for the specific mains voltage.
(NKCABLES /MCCMK, SAB/ÖZCUY-J or similar recommended).
*360º grounding of both motor and FC connection required to meet the
standard
4
Screened cable equipped with compact low-impedance shield
(NKCABLES /Jamak, SAB/ÖZCuY-O or similar).
Table 4.5 : Cable type descriptions
Frame
MI1
MI2
MI3
Type
IN
[A]
P25 - P75 1,7-3,7
1P1 - 1P5 4,8-7,0
2P2
11
Terminal cable size (min/max)
Fus
Mains cable
Main
Ground Control
Relay
e
Cu [AWG] terminal terminal terminal terminal
[A]
10
20
32
2*15+15
2*13+13
2*9+9
[AWG]
[AWG]
[AWG]
[AWG]
15-11
15-11
15-9
15-11
15-11
15-9
20-15
20-15
20-15
20-15
20-15
20-15
Table 4.6 : Cable and fuse sizes for SmartVFD Compact, 208 - 240V
4
22
Installation
Frame
Type
IN
[A]
Fuse
[A]
MI1
MI2
MI3
P37 - 1P1
1P5 - 2P2
3P0 - 5P5
1,9-3,3
4,3-5,6
7,6 - 12
6
10
20
Honeywell
Terminal cable size (min/max)
Mains
Main
Ground Control
Relay
cable
Cu [AWG] terminal terminal terminal terminal
3*15+15
3*15+15
3*13+13
[AWG]
[AWG]
[AWG]
[AWG]
15-11
15-11
15-9
15-11
15-11
15-9
20-15
20-15
20-15
20-15
20-15
20-15
Table 4.7 : Cable and fuse sizes for SmartVFD Compact, 380 - 480V
Note! To fulfil standard EN61800-5-1, the protective conductor should be at least
AWG 7 Cu or AWG 5 Al. Another possibility is to use an additional protective conductor of at least the same size as the original one.
4.2.4 General cabling rules
4
1
Before starting the installation, check that none of the components of
the frequency converter is live.
2
Place the motor cables sufficiently far from other cables:
• Avoid placing the motor cables in long parallel lines with other
cables
• If the motor cable runs in parallel with other cables, the minimum
distance between the motor cable and other cables is 11.8
inches.
• The given distance also applies between the motor cables and
signal cables of other systems.
• The maximum length of the motor cables is 100 feet.
• The motor cables should cross other cables at an angle of 90
degrees.
3
If cable insulation checks are needed, see Chapter 4.2.7.
4
Connecting the cables:
• Strip the motor and mains cables as advised in Figure 4.9.
• Connect the mains, motor and control cables into their respective
terminals, see Figures 4.4 - 4.8.
• Note the tightening torques of power cables and control cables
given in page 18 and page 20.
• For information on cable installation according to UL regulations
see Chapter 4.2.6 .
• Make sure that the control cable wires do not come in contact with
the electronic components of the unit
• If an external brake resistor (option) is used, connect its cable to
the appropriate terminal.
• Check the connection of the ground cable to the motor and the
frequency converter terminals marked with
• Connect the separate shield of the motor cable to the ground
plate of the frequency converter, motor and the supply centre
Installation
Honeywell
23
4.2.5 Stripping lengths of motor and mains cables
Ground conductor
0.3 in
0.3 in
1.4 in
0.8 in
Figure 4.9: Stripping of cables
Note! Strip also the plastic cover of the cables for 360 degree grounding. See Figures 4.4, 4.5 and 4.8.
4.2.6 Cable installation and the UL standards
To meet the UL (Underwriters Laboratories) regulations, a UL-approved copper cable with a minimum heat-resistance of 140/167 °F (+60/75 °C) must be used.
4.2.7 Cable and motor insulation checks
These checks can be performed as follows if motor or cable insulations are suspected to be faulty.
1. Motor cable insulation checks
Disconnect the motor cable from terminals U/T1, V/T2 and W/T3 of the frequency
converter and from the motor. Measure the insulation resistance of the motor cable
between each phase conductor as well as between each phase conductor and the
protective ground conductor.
The insulation resistance must be >1MOhm.
2. Mains cable insulation checks
Disconnect the mains cable from terminals L1, L2/N and L3 of the frequency converter and from the mains. Measure the insulation resistance of the mains cable between
each phase conductor as well as between each phase conductor and the protective
ground conductor.The insulation resistance must be >1MOhm.
4
24
Installation
Honeywell
3. Motor insulation checks
Disconnect the motor cable from the motor and open the bridging connections in the
motor connection box. Measure the insulation resistance of each motor winding. The
measurement voltage must equal at least the motor nominal voltage but not exceed
1000 V. The insulation resistance must be >1MOhm.
4
Commissioning
Honeywell
25
5. COMMISSIONING
Before commissioning, note the warnings and instructions listed in
Chapter 1!
5.1 COMMISSIONING STEPS OF SMARTVFD COMPACT
1
2
Read carefully the safety instructions in Chapter 1 and follow them.
After the installation, make sure that:
• both the frequency converter and the motor are grounded
• the mains and motor cables comply with the requirements given
in Chapter 4.2.3
• the control cables are located as far as possible from the power
cables (see Chapter , step 2) and the shields of the shielded
cables are connected to protective ground
3
Check the quality and quantity of cooling air (Chapter 4.1.2)
4
Check that all Start/Stop switches connected to the I/O terminals are in
Stop-position.
5
Connect the frequency converter to mains
Note: The following steps are valid if you have API Full or API Limited Application Interface in your SmartVFD Compact.
6
Set the parameters of group 1 according to the requirements of your
application. At least the following parameters should be set:
• motor nominal voltage (par. 1.1)
• motor nominal frequency (par. 1.2)
• motor nominal speed (par. 1.3)
• motor nominal current (par. 1.4)
You will find the values needed for the parameters on the motor rating
plate
5
5
26
Commissioning
Honeywell
Perform test run without motor. Perform either Test A or Test B:
7
A) Control from the I/O terminals:
• Turn the Start/Stop switch to ON position.
• Change the frequency reference (potentiometer)
• Check in the Monitoring Menu that the value of Output frequency
changes according to the change of frequency reference.
• Turn the Start/Stop switch to OFF position
B) Control from the keypad:
• Select the keypad as the control place with par. 2.1. You can also
move to keypad control by pressing the navigation wheel for 5
seconds.
• Push the Start button on the keypad
• Check in the Monitoring Menu that the value of Output frequency
changes according to the change of frequency reference
• Push the Stop button on the keypad
8
Run the no-load tests without the motor being connected to the process,
if possible. If this is not possible, secure the safety of each test prior to
running it. Inform your co-workers of the tests.
• Switch off the supply voltage and wait up until the drive has
stopped.
• Connect the motor cable to the motor and to the motor cable terminals of the frequency converter.
• See to that all Start/Stop switches are in Stop positions.
• Switch the mains ON
• Repeat test 7A or 7B
9
Connect the motor to the process (if the no-load test was run without the
motor being connected)
• Before running the tests, make sure that this can be done safely.
• Inform your co-workers of the tests.
• Repeat test 7A or 7B.
Honeywell
Fault Tracing
27
6. FAULT TRACING
Note: The fault codes listed in this chapter are visible if the Application Interface has
a display, like e.g. in API FULL or API LIMITED or if a personal computer has been
connected to the drive
When a fault is detected by the frequency converter control electronics, the drive is
stopped and the symbol F together with the ordinal number of the fault and the fault
code appear on the display in the following format, e.g:
F1 02
Fault code (02 = overvoltage)
Fault ordinal number (F1 = latest fault)
The fault can be reset by pressing the Stop button on the control keypad or via the I/
O terminal or fieldbus. The faults with time labels are stored in the Fault history menu
which can be browsed. The different fault codes, their causes and correcting actions
are presented in the table below.
Fault
code
1
2
3
Fault name
Possible cause
Correcting actions
Overcurrent
Frequency converter has
detected too high a current
(>4*IN) in the motor cable:
• sudden heavy load increase
• short circuit in motor cables
• unsuitable motor
Overvoltage
The DC-link voltage has
exceeded the internal safety
limit:
Increase the deceleration
• too short a deceleration time time (P.4.3)
• high overvoltage spikes in
mains
Ground fault
Current measurement has
detected extra leakage current at
Check motor cables and
start:
motor
• insulation failure in cables
or motor
Check loading.
Check motor size.
Check cables.
Table 6.1 : Fault codes
6
28
Fault Tracing
Fault
code
Fault name
8
System fault
• component failure
• faulty operation
Correcting actions
Reset the fault and
restart.
Should the fault re-occur,
contact the distributor
near to you
The DC-link voltage has
exceeded the internal safety
limit:
• most probable cause: too
low a supply voltage
• frequency converter internal
fault
• Power outages
In case of temporary supply voltage break reset
the fault and restart the
frequency converter.
Check the supply voltage.
If it is adequate, an internal failure has occurred.
Contact the distributor
near to you
Frequency converter
undertemperature
IGBT switch temperature is
under 14 °F(-10 °C)
Check the ambient temperature
14
Frequency converter
overtemperature
IGBT switch temperature is over
248 °F (120 °C). Overtemperature warning is issued when the
IGBT switch temperature
exceeds 230 °F (110 °C).
Check that the cooling air
flow is not blocked.
Check the ambient temperature.
Make sure that the
switching frequency is not
too high in relation to
ambient temperature and
motor load.
15
Motor stalled
Motor stall protection has tripped Check motor
16
Motor overtemperature
Motor overheating has been
Decrease the motor load.
detected by frequency converter If no motor overload
motor temperature model. Motor exists, check the temperis overloaded
ature model parameters.
22
EEPROM checksum
fault
Parameter save fault
• faulty operation
• component failure
25
Microcontroller watchdog fault
34
Internal bus communication
9
13
Undervoltage
Table 6.1 : Fault codes
6
Possible cause
Honeywell
• faulty operation
• component failure
Contact the distributor
near to you
Reset the fault and
restart.
Should the fault re-occur,
contact the distributor
near to you.
Should the fault re-occur,
Ambient interference or defective
contact the distributor
hardware
near to you.
Honeywell
Fault
code
Fault name
Fault Tracing
Possible cause
35
Application fault
Application does not function
50
Analogue input Iin <
4mA (selected signal
range 4 to 20 mA)
Current at the analogue input is
< 4mA
• control cable is broken or
loose
• signal source has failed
51
External fault
53
Fieldbus fault
Digital input fault. Digital input
has been programmed as external fault input and this input is
active.
29
Correcting actions
Contact the distributor
near to you
Check the current loop
circuitry
Check the programming
and the device indicated
by the external fault information. Check also the
cabling of this device.
Check installation.
The data connection between
If installation is correct
the fieldbus Master and the fieldcontact the nearest Honbus of the drive broken
eywell distributor.
Table 6.1 : Fault codes
6
7
30
API
Honeywell
7. SMARTVFD COMPACT APPLICATION INTERFACE
7.1 INTRODUCTION
There are three versions of Application Interfaces (API) available for the SmartVFD
Compact drive:
API Full
API Limited
API RS-485 (Modbus
RTU)
6 Digital inputs
3 Digital inputs
1 Digital input
2 Analogue inputs
1 Analogue input
1 Relay output
1 Analogue output
1 Relay output
RS-485 Interface
1 Digital output
RS-485 Interface
2 Relay outputs
RS-485 Interface
Table 7.1 : Available Application Interfaces
This section provides you with a description of the I/O-signals for these versions and
instructions for using the SmartVFD Compact general purpose application.
The frequency reference can be selected from the analogue inputs, fieldbus, preset
speeds or keypad.
Basic properties:
• Digital inputs DI1…DI6 are freely programmable. The user can
assign a single input to many functions
• Digital-, relay- and analogue outputs are freely programmable
• Analogue input 1 can be programmed as current or voltage input in API Limited version
Special features in all API versions:
• Programmable Start/Stop and Reverse signal logic
• Reference scaling
• Programmable start and stop functions
• DC-brake at start and stop
• Programmable U/f curve
• Adjustable switching frequency
• Autorestart function after fault
• Protections and supervisions (all fully programmable; off, warning, fault):
Honeywell
API
• Current signal input fault
• External fault
• Undervoltage fault
• Ground fault
• Motor thermal, stall and underload protection
• Fieldbus communication
Special features in API Full and API Limited:
• 8 preset speeds
• Analogue input range selection, signal scaling and filtering
• PI-controller
31
7
7
32
API
7.2 CONTROL I/O
Honeywell
API FULL
Signal
Terminal
1 +10Vre Ref. voltage out
Analog signal in 1
2 AI1
Factory preset
Freq. reference P)
Description
Maximum load 10 mA
0 - +10 V Ri = 200 k
Ω
(min)
3
6
GND
24Vout
I/O signal ground
24V output for DI's
± 20 %, max. load 50
mA
mA
7
8
GND
DI1
I/O signal ground
Digital input 1
Start forward P)
9
10
A
B
4
DI2
Digital input 2
Start reverse P)
DI3
Digital input 3
A
B
AI2
RS485 signal A
RS485 signal B
Analog signal in 2
Preset speed B0 P)
FB Communication
FB Communication
PI actual value P)
0(4) - 20 mA, Ri = 200
5
13
14
15
16
18
GND
GND
DI4
I/O signal ground
I/O signal ground
Digital input 4
Preset speed B1P)
0 - +30 V Ri = 12 k
DI5
Digital input 5
Fault reset P)
DI6
Digital input 6
Disable PI contr. P)
AO
20 DO
22 RO 11
23 RO 12
24 RO 21
25 RO 22
26 RO 23
Output frequency P)
Digital signal out
Relay out 1
Active = READY P)
Active = RUN P)
Relay out 2 Active = FAULT P)
Ω
0 - +30 V Ri = 12 k min
Ω
Ω (min)
Ω
0(4) - 20 mA, RL = 500
Open collector, max. load
48V/50mA
Max. switching load:
250Vac/2A or 250Vdc/
0.4A
Max. switching load:
250Vac/2A or 250Vdc/
0.4A
Table 7.2 : SmartVFD Compact General purpose application default I/O configuration
and connections for API FULL version
P) = Programmable function, see parameter lists and descriptions, chapters 9 and 10.
API
Honeywell
33
API LIMITED
Signal
Terminal
1 +10Vre Ref. voltage out
Analog signal in 1
2 AI1
3
6
GND
24Vout
Factory preset
Freq. reference P)
I/O signal ground
24V output for DI's
Description
Maximum load 10 mA
0 - +10 V Ri = 200 k
Ω
± 20 %, max. load 50
mA
7
8
GND
DI1
I/O signal ground
Digital input 1
Start forward P)
9
10
A
B
24
25
DI2
Digital input 2
Start reverse P)
DI3
Digital input 3
A
B
RO 21
RO 22
RS485 signal A
RS485 signal B
Relay out 2
Preset speed B0 P)
FB Communication
FB Communication
ACTIVE (Relay
opened) = FAULT P)
Ω
0 - +30 V Ri = 12 k min
Max. switching load:
250Vac/2A or 250Vdc/
0.4A
Table 7.3 : SmartVFD Compact General purpose application default I/O configuration
and connections for API LIMITED version
P) = Programmable function, parameter lists and descriptions, chapters 9 and 10.
API RS-485
Terminal
3 GND
6 24Vout
Signal
I/O signal ground
24V output for DI's
Factory preset
Description
± 20 %, max. load 50
mA
7
8
GND
DI1
I/O signal ground
Digital input 1
A
B
24
25
A
B
RO 21
RO 22
RS485 signal A
RS485 signal B
Relay out 2
1 = Start forward
FB Communication
FB Communication
ACTIVE (Relay
opened) = FAULT P)
Ω
0 - +30 V Ri = 12 k min
Max. switching load:
250Vac/2A or 250Vdc/
0.4A
Table 7.4 : SmartVFD Compact General purpose application default I/O configuration
and connections for API RS-485 version
P) = Programmable function, parameter lists and descriptions, chapters 9 and 10.
7
34
Control Panel
Honeywell
8. CONTROL PANEL
8.1 GENERAL
The SmartVFD Compact API Full and API Limited versions have similar control panels. The panel is integrated to the drive consisting of corresponding application card
and an overlay on the drive cover with status display and button clarifications.
The Control panel consists of an LCD display with backlight and a keypad including
a navigation wheel, a green START button and a red STOP button (see Figure 8.1).
8.2 DISPLAY
The display includes 14-segment and 7-segment blocks, arrowheads and clear text
unit symbols. The arrowheads, when visible, indicate some information about the
drive, which is printed in clear text on the overlay (numbers 1…14 in the figure below). The arrowheads are grouped in 3 groups with the following meanings and English overlay texts (see Figure 8.1):
Group 1 - 5; Drive status
1= Drive is ready to start (READY)
2= Drive is running (RUN)
3= Drive has stopped (STOP)
4= Alarm condition is active (ALARM)
5= Drive has stopped due to a fault (FAULT)
Group 6 - 10; Control selections
6= Motor is rotating forward (FWD)
7= Motor is rotating reverse (REV)
8= I/O terminal block is the selected control place (I/O)
9= Keypad is the selected control place (KEYPAD)
10= Fieldbus is the selected control place (BUS)
Group 11 - 14; Navigation main menu
11= Reference main menu (REF)
12= Monitoring main menu (MON)
13= Parameter main menu (PAR)
14= Fault history main menu (FLT)
8
Honeywell
Control Panel
35
Figure 8.1: SmartVFD Compact Control panel
8.3 KEYPAD
The keypad section of the control panel consists of a navigation wheel and START
and STOP buttons (see Figure 8.1). The navigation wheel is used for navigating on
the panel display, but it also works as a reference potentiometer when KEYPAD has
been selected as the control place of the drive. The wheel has two separate functions;
- rotating the wheel e.g. for changing parameter value (12 steps / round)
- pressing the wheel e.g. for accepting the new value.
The drive stops always, regardless of the selected control place, by pressing the keypad STOP button. The drive starts by pressing the keypad START button, but only
if the selected control place is KEYPAD.
8
36
Control Panel
Honeywell
8.4 NAVIGATION ON THE SMARTVFD COMPACT CONTROL PANEL
This chapter provides you with information on navigating the menus on SmartVFD
Compact and editing the values of the parameters.
8.4.1 Main menu
The menu structure of SmartVFD Compact control software consists of a main menu
and several submenus. Navigation in the main menu is shown below:
REFERENCE
REF
MENU
Displays the
MON
keypad reference
value
PAR
regardless of
FLT
the selected
control place.
READY RUN STOP ALARM FAULT
READY RUN STOP ALARM FAULT
REF
MON
PAR
PUSH
Hz
FWD
REV
I/O KEYPAD
Hz
FLT
FWD
BUS
REV
I/O
KEYPAD
BUS
ROTATE
READY RUN STOP ALARM FAULT
READY RUN STOP ALARM FAULT
MONITORING
MENU
In this menu
you can
browse the
monitoring
values.
REF
REF
MON
MON
PAR
PAR
PUSH
FLT
FWD
REV
I/O
KEYPAD
FLT
FWD
BUS
REV
I/O
KEYPAD
BUS
ROTATE
READY RUN STOP ALARM FAULT
PARAMETER
MENU
In this menu
you can
browse and
edit the
parameters.
READY RUN STOP ALARM FAULT
REF
REF
MON
MON
PAR
PAR
FLT
PUSH
FWD
REV
I/O KEYPAD
FLT
BUS
FWD
REV
I/O KEYPAD
BUS
ROTATE
READY RUN STOP ALARM FAULT
FAULT MENU
Here you will
be able
to browse
through the
faults occurred.
READY RUN STOP ALARM FAULT
REF
REF
MON
MON
PAR
PAR
PUSH
FLT
FWD
REV
I/O KEYPAD
BUS
FLT
FWD
Figure 8.2: The main menu of SmartVFD compact
8
REV
I/O KEYPAD
BUS
Control Panel
Honeywell
37
8.4.2 Reference menu
READY RUN STOP ALARM FAULT
REF
MON
PAR
Hz
FLT
FWD
REV
Push to enter
edit mode
I/O
KEYPAD
Change
value
BUS
Push to
confirm
Figure 8.3: Reference menu display
Move to the reference menu with the navigation wheel (see Figure 8.2). The reference value can be changed with the navigation wheel as shown in Figure 8.3. The
reference value follows the rotation continuously (= without separate new value
acceptance) .
8
38
Control Panel
Honeywell
8.4.3 Monitoring menu
Alternates
in the display
READY
RUN STOP ALARM FAULT
REF
MON
PAR
Hz
FLT
FWD
REV
I/O
KEYPAD
BUS
Browse
M1.1 - M1.20
Figure 8.4: Monitoring menu display
Monitoring values mean actual values of measured signals as well as statuses of
some control settings. They are visible in API Full and Limited display, but they cannot be edited. The monitoring values are listed in Table 8.1.
Pushing the navigation wheel once in this menu takes the user to the next level,
where the monitoring value, e.g. M1.11 and value are visible (see Figure 8.2). The
monitoring values can be browsed by rolling the navigation wheel clockwise, as
shown in Figure 8.4.
Code
Monitoring signal
Unit
ID
Description
M1.1
Output frequency
Hz
1
Frequency to the motor
M1.2
Frequency reference
Hz
25
M1.3
Motor shaft speed
rpm
2
M1.4
Motor current
A
3
Measured motor current
M1.5
Motor torque
%
4
Calculated actual/nominal
torque of the motor
M1.6
Motor power
%
5
Calculated actual/nominal
power of the motor
Table 8.1 : SmartVFD Compact monitoring signals
8
Calculated motor speed
Honeywell
Code
Monitoring signal
M1.7
Motor voltage
Control Panel
Unit
ID
Description
V
6
Motor voltage
M1.8
DC-link voltage
V
7
Measured DC-link voltage
M1.9
Unit temperature
C
°
8
Heat sink temperature
M1.10
Motor temperature
C
°
M1.11
Analogue input 1
%
13
AI1 value
M1.12
Analogue input 2
%
14
AI2 value ONLY IN API FULL!
M1.13
Analogue output
%
26
AO1 ONLY IN API FULL!
M1.14
DI1, DI2, DI3
15
Digital input statuses
M1.15
DI4, DI5, DI6
16
Digital input statuses
ONLY IN API FULL!
M1.16
RO1, (also RO2, DO in
API FULL)
17
Relay/digital output statuses
39
Calculated motor temperature
M1.17
PI setpoint
%
20
In percent of the maximum process reference
M1.18
PI feedback
%
21
In percent of the maximum
actual value
M1.19
PI error value
%
22
In percent of the maximum error
value
M1.20
PI Output
%
23
In percent of the maximum output value
Table 8.1 : SmartVFD Compact monitoring signals
8
40
Control Panel
Honeywell
8.4.4 Parameter menu
In Parameter menu only the Quick setup parameter list is shown by default. By giving
the right value to the parameter 13.1 it is possible to open other advanced parameter
groups. The parameter lists and descriptions can be found in chapters 9 and 10.
The following figure shows the parameter menu view:
Alternates
in the display
READY
RUN STOP ALARM FAULT
REF
MON
PAR
Hz
FLT
FWD
Browse
P1.1 ->
REV
I/O
Push to enter
edit mode
Figure 8.5: Parameter menu
8
KEYPAD
BUS
Change
value
Push to
confirm
Control Panel
Honeywell
41
8.4.5 Fault history menu
READY RUN STOP ALARM FAULT
READY RUN STOP ALARM FAULT
REF
REF
ON
MON
AR
PAR
FLT
FLT
FWD
REV
I/O KEYPAD
BUS
Push
FWD
REV
I/O KEYPAD
BUS
Browse
faults 1-9
READY RUN STOP ALARM FAULT
READY RUN STOP ALARM FAULT
REF
REF
MON
MON
PAR
PAR
FLT
FWD
REV
I/O
KEYPAD
BUS
Push
FLT
FWD
REV
I/O
KEYPAD
BUS
Browse
for hours (H),
minutes (M)
and seconds (S)
Figure 8.6: Fault history menu
In Fault history menu you can browse through 9 latest faults (see Figure 8.6). If a fault
is active, the relevant fault number (e.g. F1 02) alternates in the display with main
menu. When you browse between the faults, the fault codes of active faults are blinking. The active faults can be reset by pressing the STOP button for 1 second. If the
fault cannot be reset, the blinking continues. It is possible to navigate in the menu
structure also when there are active faults present, but the display returns automatically to the fault menu if buttons or navigation wheel are not pressed or navigation is
not rotated. The operating hour, minute and second values at the fault instant are
shown in the value menu (operating hours = displayed reading x 1000 h).
8
42
Control Panel
Note! The whole fault history can be
cleared by pressing STOP button for 5
sec time when the drive is stopped and
Fault history menu is selected in the
display.
See Chapter 6 in for fault descriptions
8
Honeywell
Honeywell
Parameters
43
9. GENERAL PURPOSE APPLICATION PARAMETERS
On the next pages you can find the lists of parameters within the respective parameter groups. The parameter descriptions are given in Chapter 10.
NOTE: Parameters can only be changed when drive is in stop mode!
Explanations:
Code:
Location indication on the keypad; Shows the operator the present
Monitoring value number or Parameter number
Parameter: Name of monitoring value or parameter
Min:
Minimum value of parameter
Max:
Maximum value of parameter
Unit:
Unit of parameter value; given if available
Default:
Factory preset value
ID:
ID number of the parameter (used with fieldbus control)
More information on this parameter available in chapter 10: ‘Parame
ter descriptions’ click on the parameter name.
9
9
44
Parameters
Honeywell
9.1 QUICK SETUP PARAMETERS (VIRTUAL MENU, SHOWS WHEN PAR.
13.1 = 1)
Code
Parameter
Min
Max
Unit
Default
ID
Note
P1.1
Motor nominal
voltage
180
500
V
230
400
110
Check rating plate on the
motor
P1.2
Motor nom. frequency
30
320
Hz
60.00
111
Check rating plate on the
motor
P1.3
Motor nominal
speed
300
2000
0
rpm
1440
112
Default applies for a 4pole motor.
P1.4
Motor nominal
current
0.2 x
INunit
1.5 x
INunit
A
INunit
113
Check rating plate on the
motor
P1.5
Motor cos
ϕ
0.30
1.00
0.85
120
Check rating plate on the
motor
P1.7
Current limit
0.2 x
INunit
2x
INunit
1.5 x
INunit
107
P1.15
Torque boost
0
1
0
109
0 = Not used
1 = Used
P2.1
Control place
1
3
1
125
1 = I/O terminal
2 = Keypad
3 = Fieldbus
P2.2
Start function
0
1
0
505
0 = Ramp 1 = Flying start
P2.3
Stop function
0
1
0
506
0 = Coasting 1 = Ramp
A
P3.1
Min frequency
0.00
P3.2
Hz
0.00
101
P3.2
Max frequency
P3.1
320
Hz
50.00
102
P3.3
I/O reference
0
4
P3.4
Preset speed 0
0.00
P3.2
P3.5
Preset speed 1
0.00
P3.6
Preset speed 2
P3.7
P4.2
0 = Preset Speeds (0-7)
1 = Keypad Reference
2 = Fieldbus Reference
3
117
Hz
5.00
124
Activated by digital
inputs
P3.2
Hz
10.00
105
Activated by digital
inputs
0.00
P3.2
Hz
15.00
106
Activated by digital
inputs
Preset speed 3
0.00
P3.2
Hz
20.00
126
Activated by digital
inputs
Acceleration time
0.1
3000
s
1.0
103
Acceleration time from 0
Hz to maximum frequency
3 = AI1 (API FULL &
LIMITED)
4 = AI2 (API FULL)
Table 9.1: Quick setup parameters
Parameters
Honeywell
45
Code
Parameter
Min
Max
Unit
Default
ID
Note
P4.3
Deceleration time
0.1
3000
s
1.0
104
Deceleration time from
maximum frequency to 0
Hz.
P6.1
AI1 Signal range
0
3
0
379
API FULL and LIMITED:
0 = Voltage 0…10 V
1 = Voltage 2…10 V
API LIMITED ONLY:
2 = Current 0…20 mA
3 = Current 4…20 mA
NOTE: When using API
LIMITED, select the voltage/current range also
with the dip switch
P6.5
AI2 Signal range
(API Full only)
2
3
3
390
2 = Current 0…20 mA
3 = Current 4…20 mA
P10.4
Automatic restart
0
1
0
731
0 = Not used 1 = Used
P13.1
Parameter
conceal
0
1
1
115
0 = All parameters visible
1 = Only quick setup
parameter group visible
Table 9.1: Quick setup parameters
9
9
46
Parameters
Honeywell
9.2 MOTOR SETTINGS (CONTROL PANEL: MENU PAR -> P1)
Code
Parameter
Min
Max
Unit Default
ID
Note
P1.1
Motor nominal volt180
age
500
V
230
400
110
Check rating plate on
the motor
P1.2
Motor nominal frequency
30
320
Hz
50.00
111
Check rating plate on
the motor
P1.3
Motor nominal
speed
300
2000
0
rpm
1440
112
Default applies for a 4pole motor.
P1.4
Motor nominal current
0.2 x
INunit
1.5 x
INunit
A
INunit
113
Check rating plate on
the motor
P1.5
Motor cos
ϕ
0.30
1.00
0.85
120
Check rating plate on
the motor
P1.7
Current limit
0.2 x
INunit
2x
INunit
1.5 x
INunit
107
P1.8
Motor control mode 0
1
0
600
0 = Frequency control
1 = Speed control
P1.9
U/f ratio selection
0
2
0
108
0 = Linear
1 = Squared
2 = Programmable
P1.10
Field weakening
point
30.0
0
320
Hz
50.00
602
P1.11
Voltage at field
weakening point
10.0
0
200
%
100.00
603
P1.12
U/f curve midpoint
frequency
0.00
P1.10 Hz
25.00
604
P1.13
U/f curve midpoint
voltage
0.00
P1.11 %
50.00
605
% of Nominal voltage of
the motor
P1.14
Output voltage at
zero frequency
0.00
40.00
0.00
606
% of Nominal voltage of
the motor
P1.15
Torque boost
0
1
0
109
0 = Not used
1 = Used
P1.16
Switching frequency
1.5
16.0
6.0
601
P1.17
Brake chopper
0
2
0
504
A
%
kHz
Table 9.2: Motor settings
NOTE! These parameters are shown, when P13.1 = 0.
% of Nominal voltage of
the motor
0=Disabled
1=Used in Run state
2=Used in Run and Stop
state
Parameters
Honeywell
47
9.3 START/STOP SETUP (CONTROL PANEL: MENU PAR -> P2)
Code
Parameter
Min
Max
Default
ID
P2.1
Control place
1
3
1
1 = I/O terminal
125 2 = Keypad
3 = Fieldbus
P2.2
Start function
0
1
0
505
0 = Ramp
1 = Flying start
P2.3
Stop function
0
1
0
506
0 = Coasting
1 = Ramp
P2.4
Start/Stop
logic
0
DI1
DI2
0 Start Fwd Start reverse
1 Start
Reverse
300
2 Start Pulse Stop Pulse
3 Start Fwd Start Rv
REAF
REAF
0
Unit
3
Note
Table 9.3: Start/stop setup
9.4 FREQUENCY REFERENCES (CONTROL PANEL: MENU PAR -> P3)
Code
Parameter
Min
Max
Unit
Default
ID
P3.1
Min frequency
0.00
P3.2
Hz
0.00
101
P3.2
Max frequency
P3.1
320
Hz
50.00
102
P3.3
I/O reference
0
4
P3.4
Preset speed 0
0.00
P3.2
P3.5
Preset speed 1
0.00
P3.2
P3.6
Preset speed 2
0.00
P3.7
Preset speed 3
P3.8
Note
0 = Preset Speeds (0-7)
1 = Keypad Reference
2 = Fieldbus Reference
3
117
Hz
5.00
124 Activated by digital inputs
Hz
10.00
105 Activated by digital inputs
P3.2
Hz
15.00
106 Activated by digital inputs
0.00
P3.2
Hz
20.00
126 Activated by digital inputs
Preset speed 4
0.00
P3.2
Hz
25.00
127 Activated by digital inputs
P3.9
Preset speed 5
0.00
P3.2
Hz
30.00
128 Activated by digital inputs
P3.10
Preset speed 6
0.00
P3.2
Hz
40.00
129 Activated by digital inputs
P3.11
Preset speed 7
0.00
P3.2
Hz
50.00
130 Activated by digital inputs
Table 9.4: Frequency references
NOTE! These parameters are shown, when P13.1 = 0.
3 = AI1 (API FULL &
LIMITED)
4 = AI2 (API FULL)
9
9
48
Parameters
Honeywell
9.5 RAMPS AND BRAKES SETUP (CONTROL PANEL: MENU PAR -> P4)
Code
P4.1
Parameter
Min
Max
Default
s
0.0
ID
Note
500
0 = Linear
>0 = S-curve ramp time
0.0
P4.2
Acceleration time
0.1
3000
s
1.0
103
P4.3
Deceleration time 0.1
3000
s
1.0
104
P4.4
DC braking current
Unit
dep.
Unit
dep.
A
Varies
507
P4.5
DC braking time
at start
0.00
600.00 s
0
516
P4.6
Frequency to start
DC braking during 0.10
ramp stop
10.00
1.50
515
P4.7
DC braking time
at stop
600.00 s
0
508
0.00
10.0
Unit
Ramp shape
Hz
0 = DC brake is off at
start
0 = DC brake is off at
stop
Table 9.5: Motor control parameters
9.6 DIGITAL INPUTS (CONTROL PANEL: MENU PAR -> P5)
Code
Parameter
Min
Max
Unit
Default
ID
Note
0 = Not used
1 = DI1
P5.1
Start signal 1
0
6
1
403
2 = DI2 Only in API
FULL & LIMITED
3 = DI3
4 = DI4 Only in API
FULL
5 = DI5
6 = DI6
P5.2
Start signal 2
0
6
2
404
As parameter 5.1
P5.3
Reverse
0
6
0
412
As parameter 5.1
P5.4
Ext. fault Close
0
6
0
405
As parameter 5.1
P5.5
Ext. fault Open
0
6
0
406
As parameter 5.1
P5.6
Fault reset
0
6
5
414
As parameter 5.1
P5.7
Run enable
0
6
0
407
As parameter 5.1
P5.8
Preset speed B0
0
6
3
419
As parameter 5.1
P5.9
Preset speed B1
0
6
4
420
As parameter 5.1
Table 9.6: Digital inputs
Parameters
Honeywell
Code
Parameter
Min
Max
Default
ID
Note
P5.10
Preset speed B2
0
6
0
421
As parameter 5.1
P5.11
Disable PI
0
6
6
102
0
As parameter 5.1
Table 9.6: Digital inputs
Unit
49
9
9
50
Parameters
Honeywell
9.7 ANALOGUE INPUTS (CONTROL PANEL: MENU PAR -> P6)
Code Parameter
Min
Max
Unit
Default
ID
Note
Only in API FULL & LIMITED
P6.1
0
API FULL and LIMITED:
0 = Voltage 0…10 V
1 = Voltage 2…10 V
API LIMITED ONLY:
379 2 = Current 0…20 mA
3 = Current 4…20 mA
NOTE: When using API
LIMITED, select the
voltage/current range
also with the dip switch
AI1 Signal range
0
3
P6.2
AI1 filter time
0.0
10.0
0.1
378 0 = no filtering
P6.3
AI1 Custom min
-100.0 100.0 %
0.0
380 0.0 = no min scaling
P6.4
AI1 Custom max
-100.0 100.0 %
100.0
381 100.0 = no max scaling
s
Only in API FULL
P6.5
3
2
3
P6.6
AI2 filter time
0.0
10.0
0.1
389 0 = no filtering
P6.7
AI2 Custom min
-100.0 100.0 %
0.0
391 0.0 = no min scaling
P6.8
AI2 Custom max
-100.0 100.0 %
100.0
392 100.0 = no max scaling
s
390
2 = Current 0…20 mA
3 = Current 4…20 mA
AI2 signal range
Table 9.7: Analoque inputs
9.8 DIGITAL AND ANALOGUE OUTPUTS (CONTROL PANEL: MENU PAR > P7)
Code Parameter
Min
Max
Unit
Default
ID
Selections
Only in API FULL
P7.1
Relay output 1
content
0
8
In all API versions
Table 9.8: Digital and analogue outputs
2
0 = Not used
1 = Ready
2 = Run
3 = Fault
4 = Fault Inverted
313
5 = Warning
6 = Reversed
7 = At Speed
8 = Motor Regulator
Active
Parameters
Honeywell
Code Parameter
Min
Max
P7.2
Relay output 2
content
0
8
P7.3
Digital output 1
content
0
8
Unit
51
Default
ID
3
314 As parameter 7.1
Selections
Only in API FULL
1
312 As parameter 7.1
P7.4
Analogue output
function
0
4
1
0 = Not in use
1 = Output freq. (0-fmax)
2 = Output current (0307 InMotor)
3 = Torque (0-Nominal
torque)
4 = PI controller output
P7.5
Analogue output
minimum
0
1
1
310
Table 9.8: Digital and analogue outputs
0 = 0 mA
1= 4 mA
9
9
52
Parameters
Honeywell
9.9 PROTECTIONS (CONTROL PANEL: MENU PAR -> P9)
Code
Parameter
Default
ID
P9.1
Response to 4mA
0
reference fault
Min
2
Max
Unit
1
700
P9.2
Response to
under voltage
fault
0
2
2
727
P9.3
Ground fault protection
0
2
2
P9.4
Stall protection
0
2
0
0 = No response
703 1 = Warning
2 = Fault, stop acc. to
709 P2.3
P9.5
Underload protec0
tion
2
0
713
P9.6
Reserved
0
704
P9.7
Thermal protection of the motor
P9.8
Motor ambient
temperature
P9.9
Motor cooling fac0,0
tor at zero speed
150.0 %
40.0
706
P9.10
Motor thermal
time constant
200
45
707
0
-20
1
2
100
Fahre40
heit (C)
min
Table 9.9: Protections
NOTE! These parameters are shown, when P13.1 = 0.
705
Note
Parameters
Honeywell
53
9.10 AUTORESTART PARAMETERS (CONTROL PANEL: MENU PAR ->
P10 )
Code
Parameter
P10.1 Wait time
Min
Max
Unit
0.10
10.00 s
Default
ID
Note
0.50
Delay before automatic
717 restart after a fault has disappeared
P10.2 Trial time
0.00
60.00 s
30.00
Defines the time before the
frequency converter tries to
718 automatically restart the
motor after the fault has disappeared
P10.3 Start function
0
2
0
0 = Ramp
719 1 = Flying start
2 = According to P4.2
P10.4 Automatic restart
0
1
0
731
Table 9.10: Autorestart parameters
NOTE! These parameters are shown, when P13.1 = 0.
0 = Disabled
1 = Enabled
9
9
54
Parameters
Honeywell
9.11 PI CONTROL PARAMETERS (CONTROL PANEL: MENU PAR -> P12)
Code
Parameter
Min
P12.1 PI activation
0
P12.2 PI controller gain
Max
Unit
2
Default
0
0.0
1000
100.0
118
P12.3
PI controller Itime
0.00
320.0 s
10.00
119
P12.4
Keypad PI reference
0.0
100.0 %
0.0
167
P12.5 Setpoint source
0
%
ID
163
3
0
332
Note
0 = Not used
1 = PI for motor control
2 = PI for external use
0 = Keypad PI reference,
P12.4
1 = Fieldbus
2 = AI1 Only in API FULL
& LIMITED
3 = AI2 Only in API FULL
0= Fieldbus
P12.6 Feedback source 0
2
2
334
1 = AI1 Only in API FULL
& LIMITED
2 = AI2 Only in API FULL
Feedback minimum
0.0
100.0 %
0.0
336
0 = No minimum scaling
Feedback maxiP12.8
mum
0.0
100.0 %
100.0
337
100,0 = No maximum scaling
1
0
340
0=No inversion (Feedback<Setpoint->Increase
PI Output)
1=Inverted (Feedback<Setpoint->Decrease PI Output)
P12.7
P12.9
Error value inver0
sion
Table 9.11: PI control parameters
NOTE! These parameters are shown, when P13.1 = 0.
Parameters
Honeywell
55
9.12 EASY USAGE MENU (CONTROL PANEL: MENU PAR -> P0)
Code Parameter
Min
Max
Parameter
P13.1
conceal
0
1
P13.2 Drive setup
0
Unit
3
Default
ID
Note
1
0 = All parameters visible
115 1 = Only quick setup
parameter group visible
0
0 = Basic
1 = Pump drive
2 = Fan drive
540
3 = Conveyor drive (HP)
NOTE! Visible only duriing Startup wizard
Table 9.12: Easy usage menu parameters
9.13 SYSTEM PARAMETERS
Code
Parameter
Min
Max
Default
Note
Software information (MENU PAR -> S1)
S1.1
Software package
S1.2
Power SW version
S1.3
API SW version
S1.4
API Firmware interface
S1.5
Application ID
S1.6
Application revision
S1.7
System load
RS485 information (MENU PAR -> S2)
Format: xx.yyy
xx = 0 - 64 (Number of error
messages)
yyy = 0 - 999 (Number of
correct messages)
S2.1
Communication status
S2.2
Fieldbus protocol
0
1
0
S2.3
Slave address
1
255
1
0 = FB disabled 1= Modbus
S2.4
Baud rate
0
5
5
0=300, 1=600, 2=1200,
3=2400, 4=4800, 5=9600,
S2.5
Number of stop bits
0
1
1
0=1, 1=2
S2.6
Parity type
0
0
0
0= None (locked)
S2.7
Communication time-out
0
255
10
0= Not used, 1= 1 second,
2= 2 seconds, etc.
Table 9.13: System parameters
9
9
56
Parameters
Code
Parameter
S2.8
Reset communication status
Min
Max
Default
Honeywell
Note
1= Resets par. S2.1
Total counters (MENU PAR -> S3)
S3.1
MWh counter
S3.2
Power on days
S3.3
Power on hours
User settings (MENU PAR -> S4)
S4.1
Display contrast
0
15
7
Adjusts the display contrast
S4.2
Restore factory defaults
0
1
0
1= Restores factory defaults
for all parameters
Table 9.13: System parameters
NOTE! These parameters are shown, when P13.1 = 0.
Honeywell
Parameter Descriptions
57
10. PARAMETER DESCRIPTIONS
On the next pages you can find the descriptions of certain parameters. The descriptions have been arranged according to parameter group and number.
10.1 MOTOR SETTINGS (CONTROL PANEL: MENU PAR -> P1)
1.8
MOTOR CONTROL MODE
With this parameter the user can select the motor control mode. The selections are:
0 = Frequency control:
The I/O terminal, keypad and fieldbus references are frequency references and the frequency converter controls the output frequency (output frequency resolution = 0.01 Hz)
1 = Speed control:
The I/O terminal, keypad and fieldbus references are speed references
and the frequency converter controls the motor speed.
1.9
U/F RATIO SELECTION
There are three selections for this parameter:
0 = Linear:
The voltage of the motor changes linearly with the frequency in the
constant flux area from 0 Hz to the field weakening point where the
nominal voltage is supplied to the motor. Linear U/f ratio should be
used in constant torque applications. See Figure 10.1.
This default setting should be used if there is no special need for another setting.
1 = Squared:
The voltage of the motor changes following a squared curve form with
the frequency in the area from 0 Hz to the field weakening point where
the nominal voltage is also supplied to the motor. The motor runs under magnetised below the field weakening point and produces less
torque, power losses and electromechaniqal noise. Squared U/f ratio
can be used in applications where torque demand of the load is proportional to the square of the speed, e.g in centrifugal fans and pumps
10
58
Parameter Descriptions
Honeywell
U[V]
Un
par.1.11 Default: Nominal
Field weakening
point
voltage of the motor
Linear
Squared
Default: Nominal
frequency of the
motor
par. 1.14
f[Hz]
par.1.10
Figure 10.1: Linear and squared change of motor voltage
2 = Programmable U/f curve:
The U/f curve can be programmed with three different points. Programmable U/f curve can be used if the other settings do not satisfy the
needs of the application
U[V]
Un
Par 1.11
Default: Nominal
voltage of the motor
Par. 1.13
(Def. 50%)
Default: Nominal
frequency of the
motor
f[Hz]
Par. 1.14
(Def. 0.0%)
Par. 1.12
(Def. 10%)
Figure 10.2: Programmable U/f curve
10
Field weakening
point
Par. 1.10
Honeywell
Parameter Descriptions
59
1.10
FIELD WEAKENING POINT
The field weakening point is the output frequency at which the output voltage
reaches the value set with par. 1.11.
1.11
VOLTAGE AT FIELD WEAKENING POINT
Above the frequency at the field weakening point, the output voltage remains
at the value set with this parameter. Below the frequency at the field weakening point, the output voltage depends on the setting of the U/f curve parameters. See parameters 1.9 - 1.14 and Figures 10.1 and 10.2.
When the parameters 1.1 and 1.2 (nominal voltage and nominal frequency of
the motor) are set, the parameters 1.10 and 1.11 are automatically given the
corresponding values. If you need different values for the field weakening point
and the voltage, change these parameters after setting the parameters 1.1
and 1.2.
1.12
U/F CURVE, MIDDLE POINT FREQUENCY
If the programmable U/f curve has been selected with the parameter 1.9, this
parameter defines the middle point frequency of the curve. See Figure 10.2.
1.13
U/F CURVE, MIDDLE POINT VOLTAGE
If the programmable U/f curve has been selected with the parameter 1.9, this
parameter defines the middle point voltage of the curve. See Figure 10.2.
1.14
OUTPUT VOLTAGE AT ZERO FREQUENCY
This parameter defines the zero frequency voltage of the curve. See Figures
10.1 and 10.2.
1.15
TORQUE BOOST
The voltage to the motor changes automatically with high load torque which
makes the motor produce sufficient torque to start and run at low frequencies.
The voltage increase depends on the motor type and power. Automatic torque
boost can be used in applications with high load torque, e.g. in conveyors.
0 = Disabled
1 = Enabled
Note: In high torque - low speed applications - it is likely that the motor will
overheat. If the motor has to run a prolonged time under these conditions, special attention must be paid to cooling the motor. Use external cooling for the
motor if the temperature tends to rise too high.
1.16
SWITCHING FREQUENCY
Motor noise can be minimised using a high switching frequency. Increasing
the switching frequency reduces the capacity of the frequency converter unit.
10
60
Parameter Descriptions
Honeywell
Switching frequency for SmartVFD Compact: 1.5…16 kHz.
1.17
BRAKE CHOPPER
Note! An internal brake chopper is installed in three phase supply MI2 and MI3
size drives
0 = No brake chopper used
1 = Brake chopper used in Run state
2 = Used in Run and Stop state
When the frequency converter is decelerating the motor, the energy stored to
the inertia of the motor and the load are fed into an external brake resistor, if
the brake chopper has been activated. This enables the frequency converter
to decelerate the load with a torque equal to that of acceleration (provided that
the correct brake resistor has been selected). See separate Brake resistor installation manual.
10.2 START/STOP SETUP (CONTROL PANEL: MENU PAR -> P2)
2.1
CONTROL PLACE
With this parameter, the user can select the active control place. The selections are:
1 = I/O terminal
2 = Keypad
3 = Fieldbus
Note: Local/Remote control mode can be toggled by pressing the navigation
wheel for 5 seconds. P2.1 will have no effect in local mode.
Local = Keypad is the control place
Remote = P2.1 defines the control place
2.2
START FUNCTION
The user can select two start functions for SmartVFD Compact with this parameter:
0 = Ramp start
The frequency converter starts from 0 Hz and accelerates to the set
frequency reference within the set acceleration time (P4.2). (Load inertia or starting friction may cause prolonged acceleration times).
10
Honeywell
Parameter Descriptions
61
1 = Flying start
The frequency converter is able to start also a running motor by applying a small torque to motor and searching for the frequency corresponding to the speed the motor is running at. The searching starts
from the maximum frequency towards the actual frequency until the
correct value is detected. Thereafter, the output frequency will be increased/decreased to the set reference value according to the set acceleration/deceleration parameters.
Use this mode if the motor is rotating when the start command is given.
With the flying start, it is possible to ride through short mains voltage
interruptions
2.3
STOP FUNCTION
Two stop functions can be selected in this application:
0 = Coasting
The motor coasts to a halt without control from the frequency converter
after the Stop command.
1 = Ramp stop
After the Stop command, the speed of the motor is decelerated according to the set deceleration parameters.
If the regenerated energy is high it may be necessary to use an external braking resistor for to be able to decelerate the motor in acceptable
time.
2.4
START/STOP LOGIC
With this parameter the user can select the start/stop logic.
0 = DI1 = Start forward
DI2 = Start reverse (API FULL & LIMITED)
1 = DI1 = Start
DI2 = Reverse (API FULL & LIMITED)
2 = DI1 = Start pulse
DI2 = Stop pulse (API FULL & LIMITED)
3 = DI1 = Start forward, rising edge after fault
DI2 = Start reverse, rising edge after fault (API FULL & LIMITED)
10
62
Parameter Descriptions
Honeywell
10.3 FREQUENCY REFERENCES (CONTROL PANEL: MENU PAR -> P3)
3.3
I/O REFERENCE
Defines the selected frequency reference source when the drive is controlled
from the I/O terminal.
0 = Preset speed 0 - 7
1 = Keypad reference
2 = Reference from Fieldbus (FBSpeedReference)
3 = AI1 reference (terminals 2 and 3, e.g. potentiometer)
4 = AI2 reference (terminal 4 and 5, e.g. transducer)
3.4 - 3.11 PRESET SPEEDS 0 - 7
These parameters can be used to determine frequency references that are applied when appropriate combinations of digital inputs are activated. Preset
speeds can be activated from digital inputs despite of the active control place.
Parameter values are automatically limited between the minimum and maximum frequencies. (par. 3.1, 3.2).
Speed
Preset
speed B2
Preset
speed B1
Preset
speed B0
If P3.3 = 0,
Preset speed 0
Preset speed 1
x
Preset speed 2
x
Preset speed 3
x
Preset speed 4
x
Preset speed 5
x
Preset speed 6
x
x
Preset speed 7
x
x
x
x
x
Table 10.1: Preset speeds 1 - 7
10.4 RAMPS & BRAKES SETUP (CONTROL PANEL: MENU PAR -> P4)
4.1
10
RAMP SHAPE
The start and end of the acceleration and deceleration ramp can be smoothed
with this parameter. Setting value 0 gives a linear ramp shape which causes
acceleration and deceleration to act immediately to the changes in the reference signal.
Parameter Descriptions
Honeywell
63
Setting value 0.1…10 seconds for this parameter produces an S-shaped acceleration/deceleration. The acceleration and deceleration times are determined with parameters 4.2 and 4.3.
[Hz]
P4.2, 4.3
P4.1
P4.1
[t]
Figure 10.3: S-shaped acceleration/deceleration
4.5
DC BRAKING TIME AT START
DC-brake is activated when the start command is given. This parameter defines the time before the brake is released. After the brake is released, the output frequency increases according to the set start function by par. 2.2.
Output
frequency
t
Par 4.5
RUN
STOP
Figure 10.4: DC braking time at start
4.6
FREQUENCY TO START DC BRAKING DURING RAMP STOP
The output frequency at which the DC-braking is applied. See Figure 10.6.
10
64
Parameter Descriptions
4.7
Honeywell
DC BRAKING TIME AT STOP
Determines if braking is ON or OFF and the braking time of the DC-brake
when the motor is stopping. The function of the DC-brake depends on the stop
function, par. 2.3.
0 = DC brake is not in use
>0 = DC brake is in use and its function depends on the Stop function,
(par. 2.3). The DC braking time is determined with this parameter.
Par. 2.3 = 0 (Stop function = Coasting):
After the stop command, the motor coasts to a stop without control from the
frequency converter.
With the DC injection, the motor can be electrically stopped in the shortest
possible time, without using an optional external braking resistor.
The braking time is scaled by the frequency when the DC-braking starts. If the
frequency is greater than the nominal frequency of the motor, the set value of
parameter 4.7 determines the braking time. When the frequency is 10% of the
nominal, the braking time is 10% of the set value of parameter 4.7.
fout
fn
fout
fn
Output frequency
Motor speed
Output frequency
0,1 x fn
DC-braking ON
Motor speed
DC-braking ON
t
t
t = 0,1 x par. 4.7
t = 1 x par. 4.7
RUN
RUN
STOP
STOP
Figure 10.5: DC-braking time when Stop mode = Coasting
Par. 2.3 = 1 (Stop function = Ramp):
After the Stop command, the speed of the motor is reduced according to the
set deceleration parameters, if the inertia of of the motor and load allows that,
to the speed defined with parameter 4.6, where the DC-braking starts.
10
Parameter Descriptions
Honeywell
65
The braking time is defined with parameter 4.7. If high inertia exists, it is recommended to use an external braking resistor for faster deceleration. See Figure 10.6.
fout
Motor speed
Output frequency
DC-braking
Par. 4.6
t
t = par. 4.7
RUN
STOP
Figure 10.6: DC-braking time when Stop mode = Ramp
10.5 DIGITAL INPUTS (CONTROL PANEL: MENU PAR -> P5)
5.1
5.2
5.3
5.4
5.5
5.6
5.7
5.8
5.9
5.10
5.11
START SIGNAL 1
START SIGNAL 2
REVERSE
EXTERNAL FAULT (CLOSE)
EXTERNAL FAULT (OPEN)
FAULT RESET
RUN ENABLE
PRESET SPEED B0
PRESET SPEED B1
PRESET SPEED B2
DISABLE PI
The selections for these parameters are:
0 = Not used
1 = DI1
2 = DI2 (API FULL & LIMITED)
3 = DI3 (API FULL & LIMITED)
4 = DI4 (API FULL)
5 = DI5 (API FULL)
6 = DI6 (API FULL)
10
66
Parameter Descriptions
Honeywell
10.6 ANALOQUE INPUTS (CONTROL PANEL: MENU PAR -> P6)
6.2
6.6
AI1 SIGNAL FILTER TIME (ONLY IN API FULL & LIMITED)
AI2 SIGNAL FILTER TIME (ONLY IN API FULL)
This parameter, given a value greater than 0, activates the function that filters
out disturbances from the incoming analogue signal.
Long filtering time makes the regulation response slower. See Figure 10.7.
%
Unfiltered signal
100%
Filtered signal
63%
t [s]
Par. 6.2
Par. 6.6
Figure 10.7: AI1 and AI2 signal filtering
10
Parameter Descriptions
Honeywell
67
10.7 DIGITAL AND ANALOQUE OUTPUTS (CONTROL PANEL: MENU PAR
-> P7)
7.1
7.2
7.3
RELAY OUTPUT 1 FUNCTION
RELAY OUTPUT 2 FUNCTION (ONLY IN API FULL)
DIGITAL OUTPUT 1 FUNCTION (ONLY IN API FULL)
Setting
0 = Not used
Signal content
Not in operation
1 = Ready
The frequency converter is ready to operate
2 = Run
The frequency converter operates (motor is
running)
3 = Fault
A fault trip has occurred
4 = Fault inverted
5 = Alarm
A fault trip has not occurred
An alarm has occurred
6 = Reversed
The reverse command has been selected
7 = At speed
The output frequency has reached the set
reference
8 = Motor regulator
activated
One of the limit regulators (e.g. current limit,
voltage limit) is activated
Table 10.2: Output signals via RO1, RO2 and DO1
10.8 MOTOR THERMAL PROTECTION (PARAMETERS 9.7 - 9.10)
The motor thermal protection is to protect the motor from overheating. The Honeywell drive is capable of supplying higher than nominal current to the motor. If the load
requires this high current there is a risk that the motor will be thermally overloaded.
This is the case especially at low frequencies. At low frequencies the cooling effect
of the motor is reduced as well as its capacity. If the motor is equipped with an external fan the load reduction at low speeds is small.
The motor thermal protection is based on a calculated model and it uses the output
current of the drive to determine the load on the motor.
The motor thermal protection can be adjusted with parameters. The thermal current
IT specifies the load current above which the motor is overloaded. This current limit
is a function of the output frequency.
CAUTION! The calculated model
does not protect the motor if the
airflow to the motor is reduced by
blocked air intake grill
10
68
Parameter Descriptions
Honeywell
9.7
THERMAL PROTECTION OF THE MOTOR
0 = No response
1 = Warning
2 = Fault, stop mode after fault according to parameter 2.3
If tripping is selected the drive will stop and activate the fault stage. Deactivating the protection, i.e. setting parameter to 0, will reset the thermal model of
the motor to 0%.
9.8
MOTOR AMBIENT TEMPERATURE
When the motor ambient temperature must be taken into consideration, it is
recommended to set a value for this parameter. The value can be set between
-4 °F (-20 °C) and 212 °F (100 °C).
9.9
MOTOR COOLING FACTOR AT ZERO SPEED
The cooling power can be set between 0-150.0% x cooling power at nominal
frequency. See Figure 10.8.
P
cooling
Overload area
100%
IT
par.9.9=40%
0
fn
f
Figure 10.8: Motor cooling power
9.10
MOTOR THERMAL TIME CONSTANT
This time can be set between 1 and 200 minutes.
This is the thermal time constant of the motor. The bigger the motor, the bigger
the time constant. The time constant is the time within which the calculated
thermal model has reached 63% of its final value.
The motor thermal time is specific to the motor design and it varies between
different motor manufacturers.
10
Parameter Descriptions
Honeywell
69
If the motor's t6-time (t6 is the time in seconds the motor can safely operate at
six times the rated current) is known (given by the motor manufacturer) the
time constant parameter can be set basing on it. As a rule of thumb, the motor
thermal time constant in minutes equals to 2xt6. If the drive is in stop state the
time constant is internally increased to three times the set parameter value.
See also Figure 10.9.
Motor temperature
Trip area
105%
Motor
current
Fault/warning
par. 9.7
I/IT
Time constant T*)
Motor temperature Q = (I/IT)2 x (1-e-t/T)
Time
*) Changes by motor size and
adjusted with parameter 9.10
Figure 10.9: Motor temperature calculation
10.9 AUTORESTART PARAMETERS (CONTROL PANEL: MENU PAR ->
P10)
10.2
AUTOMATIC RESTART, TRIAL TIME
The Automatic restart function restarts the frequency converter when the
faults have disappeared and the waiting time has elapsed.
The time count starts from the first autorestart. If the number of faults occurring
during the trial time exceeds three, the fault state becomes active. Otherwise
the fault is cleared after the trial time has elapsed and the next fault starts the
trial time count again. See Figure 10.10.
If a single fault remains during the trial time, a fault state is true.
10
70
Parameter Descriptions
Wait t ime
par.10.1
Wait time
par.10.1
Honeywell
Wait time
par.10.1
Fault trigger
Motor stop signal
Restart 1
Restart 2
Motor start signal
Supervision
Trial time
par.10.2
Fault active
RESET/
Fault reset
Autoreset function: (Trials = 2)
Figure 10.10: Automatic restart
10.10 PI CONTROL PARAMETERS (CONTROL PANEL: MENU PAR -> P12)
12.2
PI CONTROLLER GAIN
This parameter defines the gain of the PI controller. If the value of the parameter is set to 100% a change of 10% in the error value causes the controller
output to change by 10%.
12.3
PI CONTROLLER I-TIME
This parameter defines the integration time of the PI controller. If this parameter is set to 1,00 second the controller output is changed by a value corresponding to the output caused from the gain every second. (Gain*Error)/s.
12.7
12.8
10
FEEDBACK MINIMUM
FEEDBACK MAXIMUM
Parameter Descriptions
Honeywell
71
Controller
feedback (%)
par. 12.8
par. 12.7
0V
0mA
Custom min
par. 6.3/6.7
Custom max
par.6.4/6.8
10V
20mA
Analoque input
with custom
min and max
scaling (%)
Figure 10.11: Feedback minimum and maximum
10.11 EASY USAGE MENU (CONTROL PANEL: MENU PAR -> P9)
13.2 DRIVE SETUP
With this parameter you can easily set up your drive for four different applications.
Note! This parameter is only visible when the Startup Wizard is active. The
startup wizard will start in first power-up. It can also be started as follows. See
the figures below.
NOTE! Running the startup wizard
will always return all parameter
settings to their factory defaults!
10
72
Parameter Descriptions
Honeywell
Alternates
in the display
READY RUN STOP A LARM FAULT
READY RUN STOP ALARM FAULT
REF
REF
MON
MON
PA R
PAR
FLT
FLT
1
Press STOP
for 5 seconds
in main menu
4
PERFORM THE SAME
PROCEDURE FOR PAR. 1.4,
MOTOR NOMINAL CURRENT
PAR
rp m
2 Push to enter edit mode
5
FLT
3 Select motor
nominal speed
and push
to confirm.
PERFORM DRIVE SETUP,
PAR. 13.2, SEE NEXT PAGE
Figure 10.12: Startup wizard
10
READY R UN STOP ALARM FAULT
REF
MON
Parameter Descriptions
Honeywell
READY RUN STOP A LARM FAULT
READY RUN STOP ALARM FAULT
READY R UN STOP ALARM FAULT
REF
REF
REF
MON
MON
MON
PA R
PAR
PAR
FLT
FLT
FLT
1
Startup wizard
shows par 13.2
number.
2
Push to enter
edit mode.
73
3
Select between
0 - 3, see below!
Selections:
P1.1 P1.2 P1.7 P1.15 P2.1 P2.2 P2.3 P3.1 P3.2 P3.3 P4.2 P4.3
1,1 * 0=
INMOT Not
used
0=
1,1 *
Not
INMOT used
0 = Basic
400
V*
50
Hz
1 = Pump drive
400
V*
50
Hz
2 = Fan drive
400
V*
50
Hz
1,1 *
400
V*
50
Hz
1,5 *
3 = Conveyor
drive
0=
Not
INMOT used
1=
INMOT Used
I/O
0=
0=
0
Ramp Coast. Hz
50
Hz
I/O
0=
1=
20
Ramp Ramp Hz
50
Hz
I/O
0=
0= 20
Ramp Coast. Hz
50
Hz
I/O
0=
0=
0
Ramp Coast. Hz
50
Hz
0=
3s
Ai1
0-10V
0=
Ai1
5s
0-10V
0=
Ai1 20 s
0-10V
0=
1s
Ai1
0-10V
3s
5s
20 s
1s
*In drives of 208V...230V
this value is 230V
Parameters
affected:
P1.1 Motor Un (V)
P1.2 Motor fn (H z)
P1.7 Current limit (A)
P1.15 Torque boost
P2.1 Control place
P2.2 Start function
READY RUN
P2.3 Stop function
P3.1 Min frequency
P3.2 Max frequency
P3.3 I/O reference
P4.2 Acc. time (s)
P4.3 Dec time (s)
STOP ALARM FAULT
REF
MON
PAR
FLT
4
Push to
confirm
drive setup
Figure 10.13: Drive setup
10.12 FIELDBUS PARAMETERS (CONTROL PANEL: MENU PAR -> S2)
The built-in Modbus connection of SmartVFD Compact supports the following function codes:
- 03 Read Holding Registers
10
74
Parameter Descriptions
Honeywell
- 04 Read Input Registers
- 06 Preset Single Registers
10.12.1 Modbus process data
Process data is an address area for fieldbus control. Fieldbus control is active when
the value of parameter 2.1 (Control place) is 3 (=fieldbus). The contents of the process data has been determined in the application. The following tables present the
process data contents in the GP Application.
Table 10.3: Output process data:
ID
Modbus register
Name
Scale
Type
2101
32101, 42101
FB Status Word
-
Binary coded
2102
32102, 42102
FB General Status Word
-
Binary coded
2103
32103, 42103
FB Actual Speed
0,01
%
2104
32104, 42104
Motor freq.
0,01
+/- Hz
2105
32105, 42105
Motor speed
1
+/- Rpm
2106
32106, 42106
Motor current
0,01
A
2107
32107, 42107
Motor torque
0,1
+/- % (of nominal)
2108
32108, 42108
Motor power
0,1
+/- % (of nominal)
2109
32109, 42109
Motor voltage
0,1
V
2110
32110, 42110
DC voltage
1
V
2111
32111, 42111
Active fault
-
Fault code
Table 10.4: Input process data:
10
ID
Modbus register
Name
Scale
Type
2001
32001, 42001
FB Control Word
-
Binary coded
2002
32002, 42002
FB General Control Word
-
Binary coded
2003
32003, 42003
FB Speed Reference
0,01
%
2004
32004, 42004
PI Control Reference
0,01
%
2005
32005, 42005
PI Actual value
0,01
%
2006
32006, 42006
-
-
-
2007
32007, 42007
-
-
-
2008
32008, 42008
-
-
-
2009
32009, 42009
-
-
-
2010
32010, 42010
-
-
-
2011
32011, 42011
-
-
-
Parameter Descriptions
Honeywell
75
Table 10.5: Status Word:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
-
-
-
-
-
-
-
-
-
Z
AREF
W
FLT
DIR
RUN
RDY
Information about the status of the device and messages is indicated in the Status
word. The Status word is composed of 16 bits the meanings of which are described
in the table below:
Table 10.6: Actual speed:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
MSB
0
LSB
This is actual speed of the frequency converter. The scaling is -10000...10000. In the
application, the value is scaled in percentage of the frequency area between set minimum and maximum frequency.
Table 10.7: Control word:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
-
-
-
-
-
-
-
-
-
-
-
-
-
RST
DIR
RUN
In Honeywell applications, the three first bits of the control word are used to control
the frequency converter. However, you can customise the content of the control word
for your own applications because the control word is sent to the frequency converter
as such.
Table 10.8: Speed reference:
15
MSB
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
LSB
This is the Reference 1 to the frequency converter. Used normally as Speed reference. The allowed scaling is 0...10000. In the application, the value is scaled in percentage of the frequency area between the set minimum and maximum frequencies.
10
76
Parameter Descriptions
Honeywell
Table 10.9: Bit definitions:
Bit
Description
Value = 0
10
Value = 1
RUN
Stop
Run
DIR
Clockwise
Counter-clockwise
RST
Rising edge of this bit will reset active fault
RDY
Drive not ready
Drive ready
FLT
No fault
Fault active
W
No warning
Warning active
AREF
Ramping
Speed reference reached
Z
-
Drive is running at zero speed
62-0269-02.fm Page 24 Tuesday, October 14, 2008 6:55 AM
COMPACT VARIABLE FREQUENCY DRIVE (DPD00128A)
Automation and Control Solutions
Honeywell International Inc.
Honeywell Limited-Honeywell Limitée
1985 Douglas Drive North
35 Dynamic Drive
Golden Valley, MN 55422
Toronto, Ontario M1V 4Z9
customer.honeywell.com
® U.S. Registered Trademark
© 2011 Honeywell International Inc.
62-0312—03 T.D. Rev. 01-11
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