Carrier | AQUAZONE 50PTH | Product data | Carrier AQUAZONE 50PTH Product data

Carrier AQUAZONE 50PTH Product data
Advance
Product
Data*
Aquazone™
50PTH, PTV024-070
Two-Stage Water Source Heat Pumps
with Puron® Refrigerant (R-410A)
*For units purchased on or after May 12, 2014.
2 to 6 Nominal Tons
Single-package horizontally and vertically mounted water source heat
pumps with electronic controls offer:
• Two-stage unloading scroll
compressor
• Variable speed blower motor
• Exclusive double spring and
grommet compressor isolation for
ultra-quiet operation
• Available mute package for quieter
operation
• Performance certified to ARI/ISO
13256-1
• Flexible and reliable multiple
protocol WSHP Open controller can
use BACnet*, Modbus†, N2, and
LON (with a separate card)
protocols for integrating energy
efficiency and precise unit control
(field-installed accessory)
• Hot gas reheat (HGR) available for
dehumidification capability
• Optional tin-plated copper tubing
and polymer coated aluminum fin
evaporator coil available
• Non-ozone depleting Puron
refrigerant (R-410A)
Features/Benefits
Carrier’s Aquazone two-stage
water source heat pump
(WSHP) with Puron
refrigerant (R-410A) is a high
quality, ultra-efficient solution
for all boiler/tower and
geothermal design
applications.
Operating efficiency
Carrier WSHPs are designed for quality and high performance over a lifetime of operation. Two-stage WSHP
models with Puron refrigerant offer
cooling EERs (Energy Efficiency Ra© Carrier Corporation 2014
Form 50PT-1APD
Features/Benefits (cont)
tios) to 37.0 and heating COPs (Coefficiency of Performance) to 6.5.
All efficiencies stated are in accordance
with standard conditions under ISO (International Organization for Standardization) Standard 13256-1:1998 and
provide among the highest ratings in
the industry, exceeding ASHRAE
(American Society of Heating, Refrigerant and Air-Conditioning Engineers)
90.1 Energy Standards.
High quality construction and
testing
All units are manufactured to meet
extensive quality control protocol
from start to finish through an automated control system, which provides
continuous monitoring of each unit
and performs quality control checks
as equipment progresses through the
production process. Standard construction features of the Aquazone™ units
include:
Cabinet — Standard unit fabrication
consists of heavy gage galvanized sheet
metal cabinet construction designed for
part standardization (i.e., minimal
number of parts) and modular design.
All interior surfaces are lined with 1/2
in. thick, 11/2 lb per cubic ft density,
foil faced Micromat insulation for thermal insulation and acoustical attenuation. This insulation is non-combustible, non-hydroscopic and does not
support fungal growth. Insulation
meets NFPA90A and 90B for fire protection and is certified to meet the
Greenguard Indoor Air Quality Standard for Low Emitting Products.
Compressor — Two-stage models
with Puron® refrigerant (R-410A) offer
a dual level vibration isolation system.
Noise reduction is a critical consideration of the unit design. All units have
a unique floating base. The compressor is mounted on a heavy steel plate
which rests on a high density rubber
pad on the base of the unit. In addition, compressors are mounted on rubber grommets. This double isolation is
standard in all units preventing vibration and noise transmission from the
compressor to the unit structure resulting in exceptionally quiet operation.
The compressor has thermal overload
protection and is located in an insulated compartment away from the airstream to minimize sound transmission.
Blower and motor assembly —
Large blower wheels allow the unit to
operate at lower speeds for quieter operation.
The constant-torque blower motor can
handle up to 1 in. w.g. external static
pressure making it a wise choice for
high filtration applications. The 460-v
constant torque motors do not require
a neutral wire.
Multiple speed ECM (electronically
commutated motor) motors are optional on units, allowing the user to select
the correct speed to deliver the specified airflow and the design system static pressure.
Motors are mounted on the fan housing with rubber grommets to prevent
noise and vibration transmission to the
unit and airstream.
Table of contents
Page
Features/Benefits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1-4
Model Number Nomenclature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
ARI/ISO Capacity Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
Physical Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
Options and Accessories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .9-13
Performance Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14-26
Electrical Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .27,28
Application Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .29-33
Guide Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .34-36
2
A 1-in. supply air duct-flange connection is standard, facilitating duct installation on the unit. Horizontal units are
field convertible from straight through
to an end discharge arrangement.
Refrigeration/water circuit — All
units contain sealed Puron® refrigerant
(R-410A) circuits including a highefficiency Copeland UltraTech™ twostage compressor designed for heat
pump operation, a thermostatic expansion valve for refrigerant metering,
an enhanced corrugated aluminumlanced fin and rifled copper tube
refrigerant-to-air heat exchanger, reversing valve, coaxial (tube-in-tube)
refrigerant-to-water heat exchanger,
and safety controls including a highpressure switch, low-pressure switch,
water coil low temperature sensor, and
air coil low temperature sensor.
ARI/ISO — Aquazone units have ARI
(Air-Conditioning & Refrigeration Institute)/ISO, NRTL (Nationally Recognized Testing Lab), or ETL labels and
are factory tested under normal operating conditions at nominal water flow
rates. Quality assurance is provided via
testing report cards shipped with each
unit to indicate specific unit performance under cooling and heating
modes of operation.
Quiet operation
Fan motor insulation and double isolated compressor are provided for sound
isolation, cabinets are fully insulated to
reduce noise transmission, low speed
blowers are utilized for quiet operation
through reduced outlet air velocities,
and air-to-refrigerant coils are designed
for lower airflow coil face velocities.
Puron® refrigerant (R410-A)
Puron refrigerant (R-410A) is a nonchlorine based enviromentally balanced, non-ozone depleting refrigerant. Puron refrigerant characteristics,
compared to R-22, have:
• Binary and near azeotropic mixture
of 50% R-32 and 50% R-125.
• Higher efficiencies (50 to 60%
higher operating pressures).
• Virtually no glide. Unlike other
alternative refrigerants, the two
components in Puron refrigerant
have virtually the same leak rates.
Therefore, refrigerant can be added
if necessary without recovering the
charge.
Optional evaporator coil
protection
All units come standard with a copper
coil aluminum fin evaporator coil.
These evaporator coils employ lanced
fin and rifled tubing for maximum heat
transfer. Large face areas result in lower face velocity reducing sound while
ensuring high latent heat removal for
maximum dehumidification in the cooling mode.
Optional tin electro-plated copper tubing with high-tech polymer coated aluminum fins protect the evaporator coil
from all forms of corrosive elements in
the airstream. Corrosion often results
in refrigerant leaks and eventual failure
of the air coil costing hundreds of dollars to replace. Studies have also
shown that these air coil coatings improve moisture shedding and therefore
improve a unit’s moisture removal capability resulting in a more comfortable
indoor environment. The 50PTH,
PTV units assure both maximum air
coil life and comfort.
Design flexibility
Airflow configurations for horizontal
units are available in four patterns including left or right return, and left,
right, or back discharge. Horizontal
and downflow units are field convertible from left or right discharge to back
discharge. Vertical units are available in
three airflow patterns including top
discharge with right or left return.
Standard entering water temperature is
between 50 and 100 F. Extended entering water temperature range between 25 F and 110 F offers maximum
design flexibility for all applications.
Water flow rates as low as 1.5 gpm per
ton assist with selection from a range
of various circulating pumps. Factory-
installed options are offered to meet
specific design requirements.
Safe, reliable operation
Standard safety features for the refrigerant circuit include high-pressure
switch, low-pressure sensor to detect
loss of refrigerant, and low air temperature sensor to safeguard against freezing. Equipment safety features include
water loop temperature monitoring,
voltage protection, water coil freeze
protection, and standard electronic
condensate overflow shutdown. All
safety features are tested and run at the
factory to assure proper operation of
all components and safety switches.
All components are carefully
designed and selected for endurance,
durability, and carefree day-to-day
operation.
The Aquazone™ unit is shipped to
provide internal and external equipment protection. Shipping supports
are placed under the blower housing
and compressor feet. In addition, horizontal and vertical units are both
mounted on oversized pallets with lag
bolts for sturdiness and maximum protection during transit.
Ease of installation
The Aquazone unit is packaged for
simple low cost handling, with minimal
time required for installation. All units
are pre-wired and factory charged with
refrigerant. Horizontal units are provided with factory-installed hanger isolation brackets. Vertical units are provided with an internally trapped condensate drain to reduce labor associated
with installing an external trap for each
unit. Water connections (3/4 in. diameter FPT) and condensate drains (FPT)
are anchored securely to the unit cabinet.
Simple maintenance and
serviceability
The Aquazone water source heat
pump (WSHP) units are constructed to
provide ease of maintenance. Units
allow access to the compressor section
from 2 sides and have large removable
panels for easy access. Additional panels are provided to access the blower
and control box sections.
The blower housing assembly can be
serviced without disconnecting ductwork from the dedicated blower access
panel. Blower units are provided with
permanently lubricated bearings for
worry-free performance. Blower inlet
rings allow removal of the blower
wheel without having to remove the
housing or ductwork connections.
Electrical disconnection of the blower motor and control box is easily accomplished from quick disconnects on
each component.
Easy removal of the control box
from the unit provides access to all refrigeration components.
The refrigeration circuit is easily tested and serviced through the use of
high and low pressure ports integral to
the refrigeration circuit.
Maximum control flexibility
Aquazone water source heat pumps
provide reliable control operation
using a standard microprocessor board
with flexible alternatives for many
direct digital controls (DDC) applications including the Carrier Comfort
Network® (CCN) controls and open
protocol systems.
The Aquazone™ standard unit solidstate control system, the Complete C,
provides control of the unit compressor, reversing valve, fan, safety features, and troubleshooting fault indication features. The Complete C control
system is a user friendly, low cost,
advanced WSHP control board. Many
features are field selectable to maximize flexibility in field installation. The
overall features of this standard control
system include:
75 va transformer — The transformer
assists in accommodating accessory
loads.
Anti-short cycle timer — Timer provides a minimum off time to prevent the
unit from short cycling. The 5-minute
timer energizes when the compressor is
deenergized, resulting in a 5-minute
delay before the unit can be restarted.
Random start relay — Random start
relay provides a random delay in energizing each different WSHP unit. This
option minimizes peak electrical demand
during start-up from different operating
modes or after building power outages.
High and low pressure refrigerant
protection — This protection safeguards against unreliable unit operation
and prevents refrigerant from leaking.
Condensate overflow sensor —
The electronic sensor is mounted to
the drain pan. When condensate pan
liquid reaches an unacceptable level,
unit is automatically deactivated and
placed in a lockout condition. Thirty
3
Features/Benefits (cont)
continuous seconds of overflow is recognized as a fault by the sensor.
High and low voltage protection
— Safety protection for excessive or
low voltage conditions is included.
Automatic intelligent reset — Unit
will automatically restart 5 minutes
after shutdown if the fault has cleared.
Should a fault occur 3 times sequentially, lockout will occur.
Accessory output — Twenty-four
volt output is provided to cycle a motorized water valve or damper actuator
with compressor in applications such as
variable speed pumping arrangements.
Performance monitor (PM) — This
feature monitors water temperatures to
warn when the heat pump is operating
inefficiently or beyond typical operating
range. Field selectable switch initiates a
warning code on the unit display.
Water coil freeze protection (selectable for water or antifreeze) — Field
selectable switch for water and water/
glycol solution systems initiates a fault
when temperatures exceed the selected
limit for 30 continuous seconds.
Air coil freeze protection (check
filter operation) — Field selectable
switch for assessing excessive filter
pressure drop initiates a fault when
temperatures exceed the selected limit
for 30 continuous seconds.
Alarm relay setting — Selectable
24 v or pilot duty dry contact provides
activation of a remote alarm.
* Sponsored by ASHRAE (American Society of
Heating, Refrigerating, and Air-Conditioning
Engineers).
† Registered trademark of Schneider Electric.
4
Electric heat option — The output
provided on the controller operates
two stages of emergency electric heat.
Service Test mode with diagnostic
LED (light-emitting diode) — The
Test mode allows service personnel to
check the operation of the WSHP and
control system efficiently. Upon entering Test mode, time delays are sped up,
and the Status LED will flash a code to
indicate the last fault experienced for
easy diagnosis. Based on the fault code
flashed by the status LED, system diagnostics are assisted through the use of
Carrier provided troubleshooting tables
for easy reference to typical problems.
LED visual output — An LED panel
indicates high pressure, low pressure,
low voltage, high voltage, air/water
freeze protection, condensate overflow, and control status.
Hot gas reheat — Hot gas reheat
(HGR) allows the user to control not
only space temperature, but also
humidity levels within the conditioned
space. Excessive moisture in the space
can promote mold growth leading to
damage in the structure or interior surfaces, as well as reducing the air quality
and creating an unhealthy environment.
Excess humidity may be caused by
the unit having to operate under a
widely varying load, an oversized short
cycling unit, a high percentage of unconditioned outside air being introduced into the space, a high latent load
in the space and any location where
humidity infiltration is a problem.
Typical unit control is by a wall
mounted thermostat that senses temperature in the occupied space. By utilizing a humidistat in addition to the
thermostat, we are able to monitor the
humidity levels in the space as well.
The HGR option allows cooling and
dehumidification to satisfy both the
thermostat and humidistat while preventing over-cooling of the space while
in the dehumidification mode.
Once the thermostat reaches set
point temperature and the humidity is
above set point, the unit controller will
energize the reheat valve to operate
the unit in hot gas reheat mode, first
cooling and dehumidifying, then reheating the air using hot refrigerant gas
before delivering it to the space, usually
2 to 5 F below room temperature. The
unit is operating as a dehumidifier. By
reheating the air along a constant sensible heat line, the relative humidity of
the leaving air is reduced.
The moisture removal capacity of a
specific heat pump is determined by
the unit latent capacity rating. A heat
pump’s latent capacity can be determined by reviewing the heat pump
specification data sheets. Depending
upon the entering water and air conditions, a total and sensible capacity can
be interpolated from the data shets.
Subtracting sensible capacity from total
capacity by 1069 (btu/lb of water vapor at 80° dry bulb and 67° wet bulb)
yields the amount of moisture removal
in pounds per hour.
Model number nomenclature
50PTH,PTV PREMIUM EFFICIENCY

Aquazone™ Two-Stage Water Source Heat
Pump with Puron® Refrigerant (R-410A)
024 –
036 –
048 –
060 –
070 –
Factory Installed Opons
Std MERV8 MERV13
Filter
Filter
Filter
2
3
4
5
6
None
5 Kw Electric Heat
10 Kw Electric Heat
X
A
C
Y
B
F
Z
W
R
15 Kw Electric Heat
20 Kw Electric Heat
D
E
G
T
S
H
Operating Range/Sound Option
Horizontal
Extended Range
B –
E –
N –
P –
S –
W–
Y –
Z –
Right
Left
Right
Right
Left
Left
Left
Right
End
Right (Straight)
Left (Straight)
End
End
End
Right (Straight)
Left (Straight)
Constant Torque
Constant Torque
ECM
ECM
Constant Torque
ECM
ECM
Constant Torque
Left
Right
Left
Right
Top
Top
Top
Top
ECM
ECM
Constant Torque
Constant Torque
Standard
1/2" Closed Cell Foam
–
–
–
–
Extra Quiet
J
F
Valve Option
A – 2-Way Solenoid
C – None
D – Internal Pump
Vertical
J
K
L
R
Std
A
D
A
Voltage
3 – 208/230-1-60
5 – 208/230-3-60
6 – 460-3-60
C – 208/230-1-60 with Disconnect
E – 208/230-3-60 with Disconnect
F – 460-3-60 with Disconnect
C – Standard C Microprocessor Control Package
D – Standard D Microprocessor Control Package
Refrigerant and Water Circuit Options
Standard
Hot Gas Reheat
ECM
Non-Coated Air Coil
Cu
CUNi
C
N
E
P
Duo-Guard Air Coil
Cu
CuNi
A
J
D
F
LEGEND
— Electronically Commutated Motor
514
5
ARI/ISO capacity ratings
50PTH, 50PTV FULL LOAD APPLICATIONS
WATER LOOP HEAT PUMP
COOLING 86 F
HEATING 68 F
CAPACITY
CAPACITY
EER
Btuh/W
COP
Btuh
Btuh
25,500
17.4
29,200
5.6
39,000
19.0
42,800
5.6
49,200
16.6
56,100
5.3
63,800
17.0
73,300
5.2
71,600
16.3
84,000
5.1
UNIT
SIZE
024
036
048
060
070
ARI
COP
EER
ISO
—
—
—
—
LEGEND
Air-Conditioning and Refrigeration Institute
Coefficient of Performance
Energy Efficiency Ratio
International Organization for Standardization
GROUND WATER HEAT PUMP
COOLING 59 F
HEATING 50 F
CAPACITY
CAPACITY
EER
Btuh/W
COP
Btuh
Btuh
29,000
26.5
23,500
4.9
43,300
28.0
35,900
5.1
55,300
25.3
46,300
4.7
70,200
24.4
60,300
4.6
78,700
23.1
70,000
4.5
GROUND LOOP HEAT PUMP
COOLING 77 F
HEATING 32 F
CAPACITY
CAPACITY
EER
Btuh/W
COP
Btuh
Btuh
26,600
19.9
18,000
4.1
40,800
22.3
28,400
4.3
51,300
19.3
36,900
4.0
65,100
18.9
48,000
3.9
73,700
18.5
55,300
3.8
NOTES:
1. A brine-to-air heat pump using a brine solution circulating through a subsurface
piping loop functioning as a heat source/heat sink.
2. The heat exchange loop may be placed in horizontal trenches or vertical bores,
or submerged in a body of surface water.
3. The temperature of the brine is related to the climatic conditions and may vary
from 20 F to 120 F.
4. Certified in accordance with the ARI/ISO Standard 13256-1 Certification Program, with 15% antifreeze solution.
5. Table does not reflect fan or pump power connections for ARI/ISO conditions.
50PTH, 50PTV PART LOAD APPLICATIONS
WATER LOOP HEAT PUMP
COOLING 86 F
HEATING 68 F
CAPACITY
CAPACITY
EER
Btuh/W
COP
Btuh
Btuh
18,500
18.9
21,200
6.5
29,000
22.2
31,000
6.5
36,700
18.9
40,900
6.2
47,500
18.7
53,600
5.8
55,200
17.8
64,900
5.7
UNIT
SIZE
024
036
048
060
070
ARI
COP
EER
ISO
6
—
—
—
—
LEGEND
Air-Conditioning and Refrigeration Institute
Coefficient of Performance
Energy Efficiency Ratio
International Organization for Standardization
GROUND WATER HEAT PUMP
COOLING 59 F
HEATING 50 F
CAPACITY
CAPACITY
EER
Btuh/W
COP
Btuh
Btuh
21,700
33.6
16,700
5.1
32,600
37.0
25,200
5.2
42,000
33.8
33,700
5.2
53,300
31.2
44,300
4.8
60,800
28.5
52,900
4.8
GROUND LOOP HEAT PUMP
COOLING 68 F
HEATING 41 F
CAPACITY
CAPACITY
EER
Btuh/W
COP
Btuh
Btuh
21,000
28.1
14,400
4.4
31,900
32.0
22,400
4.7
39,900
27.8
29,800
4.5
51,600
26.5
39,800
4.4
60,300
25.4
46,900
4.3
NOTES:
1. A brine-to-air heat pump using a brine solution circulating through a subsurface
piping loop functioning as a heat source/heat sink.
2. The heat exchange loop may be placed in horizontal trenches or vertical bores,
or submerged in a body of surface water.
3. The temperature of the brine is related to the climatic conditions and may vary
from 20 F to 120 F.
4. Certified in accordance with the ARI/ISO Standard 13256-1 Certification Program, with 15% antifreeze solution.
5. Table does not reflect fan or pump power connections for ARI/ISO conditions.
Physical data
PHYSICAL DATA — 50PTH, PTV 024-070 UNITS
 COMPRESSOR
UNIT 50PTH, PTV
024
036
048
060
070
114
Scroll
REFRIGERANT CHARGE VT (oz)
58
98
88
110
REFRIGERATION CHARGE HZ ONLY (oz)
64
85
77
100
114
450/3,100
450/3,100
450/3,100
450/3,100
450/3,100
CONSTANT TORQUE - FAN MOTOR/BLOWER
Fan Motor Type/Speeds
Fan Motor (Hp)
Blower Wheel Size (D x W) (in.)
0.33
10 x 8
0.75
11 x 9
Constant Torque / 5 speed
0.75
1.00
11 x 9
11 x 11
1.00
11 x 11
ECM CONST AIRFLOW - FAN MOTOR/BLOWER
Fan Motor Type/Speeds
Fan Motor (Hp)
Blower Wheel Size (D x W) (in.)
0.33
10 x 8
0.75
11 x 9
ECM Constant Air Flow
0.75
1.00
11 x 9
11 x 11
1.00
11 x 11
3/4
0.33
1
1.18
1
0.62
1
1.07
1
1.12
24 x 20
24 x 24 (1)
32 x 26
16 x 30 (2)
32 x 26
16 x 30 (2)
38 x 26
20 x 30 (2)
38 x 26
20 x 30 (2)
250
350
360
475
340
450
410
530
440
560
18 x 31.5
18 x 18 (2)
20 x 42
20 x 24 (2)
20 x 42
20 x 24 (2)
20 x 49
18 x 20 (3)
20 x 49
18 x 20 (3)
260
360
375
495
355
470
430
550
460
580
MAXIMUM WATER WORKING PRESSURE (psig/kPa)
WATER CONNECTION SIZE
FPT
Coaxial Coil Volume (gal)
VERTICAL CABINET
Air Coil
Dimensions (H x W) (in.)
Nominal size Standard Filter - 2-in. MERV11 (L x H)
Weight (lb)
Operating
Shipping
HORIZONTAL CABINET
Air Coil
Dimensions (H x W) (in.)
Nominal size Standard Filter - 2-in. MERV11 (L x H)
Weight (lb)
Operating
Shipping
LEGEND
ECM — Electronically Commutated Motor
HZ
— Horizontal
VT
— Vertical
514
7
Options and accessories
Factory-installed options
Cupronickel heat exchangers are available for higher
corrosion protection for applications such as open tower,
geothermal, etc. Consult the water quality guidelines for
proper application and selection of this option.
Sound attenuation package (mute package) is available for applications that require especially low noise levels. With this option, a double application of sound
attenuating material is applied, access panels are double
dampened with 1/2-in. thick density fiberglass insulation,
and a unique application of special dampening material is
applied to the curved portion of the blower. The mute
package in combination with standard unit noise reduction
features, as mentioned previously provides sound levels
and noise reduction to the highest degree.
Compressor blanket provides a 1/2-in. thick, closed cell
foam insulation to help aid indoor air quality (IAQ) and to
further attenuate low frequency noise from the compressor
compartment. The closed-cell foam insulation option is
available in all unit sizes. For additional sound attenuation,
an optional compressor blanket is available.
Extended range units insulate the coaxial coil to prevent
condensation, and therefore potential dripping problems,
in applications where the entering water temperature is
below the normal operating range (less than 60 F). Units
are capable of operating at a range of 25 to 110 F.
Water circuit options provide internally mounted 2.5 or
3.0 gpm per ton automatic flow regulating valves for easier
installation.
Two-way motorized control valve can be provided for
applications involving open type systems or variable speed
pumping. This valve will slowly open and close in conjunction with the compressor operation to shut off or turn on
water to the unit.
8
Hot gas reheat (HGR) allows the user to control not only
space temperature, but also humidity levels within the conditioned space. Excessive moisture in the space can promote mold growth leading to damage in the structure or
interior surfaces, as well as reducing the air quality and creating an unhealthy environment.
Typical unit control is by a wall-mounted thermostat that
senses temperature in the occupied space. By utilizing a
humidistat in addition to the thermostat, we are able to
monitor the humidity levels in the space as well. The HGR
option allows cooling and dehumidification to satisfy both
the thermostat and humidistat while preventing over cooling of the space while in the dehumidification mode.
Electronically commutated motors (ECM) provide
soft starting, maintain constant airflow over the motor
static operating range, and provide airflow adjustment on
the motor control board. The fan motor is isolated from
the housing by rubber grommets, is permanently lubricated
and has thermal overload protection.
Evaporator coil protection — Optional tin electroplated copper tubing with high-tech polymer coated aluminum fins will protect the evaporator coil from all forms of
corrosive elements in the airstream.
Field-installed accessories
WSHP Open multiple protocol controller is a proactive controller capable of communicating BACnet, Modbus, N2, and LON (with a separate card) protocols. The
controller is designed to allow users access and ability to
change and configure multiple settings and features including indoor air quality (IAQ), waterside economizer controls,
etc.
Dimensions
*
*
50PTH024-070 UNITS SUPPLY AIR CONFIGURATION - END BLOW
9
Dimensions (cont)
*
*
*
50PTH024-070 UNITS SUPPLY AIR CONFIGURATION - STRAIGHT THROUGH
10
50PTH024-070 UNITS HANGING BRACKET SPECIFICATIONS
11
12
H
B
T
U
M
ELECTRICAL
KNOCKOUTS
N
F
ELECTRICAL HEATER
KNOCKOUT*
NOTES:
1. ALL DIMENSIONS ARE WITHIN ± 0.125 INCH.
2. RETURN AND SUPPLY AIR DUCT FLANGES SHIPPED UNFOLDED.
3. ALL DIMENSIONS ARE IN INCHES.
4. SPECIFICATIONS SUBJECT TO CHANGE WITHOUT NOTICE.
* ELECTRIC HEATER IS OPTIONAL FEATURE.
** CONDENSATE DRAIN CONNECTION 3/4-IN. FPT.
C
D
E
G
A
W
LEFT HAND RETURN
V
L
WATER IN
K
J
T
U
CONDENSATE
DRAIN**
WATER OUT
V
A
W
RIGHT HAND RETURN
F
RETURN AIR
DUCT FLANGES
RETURN AIR
DUCT FLANGES
SUPPLY AIR
DUCT FLANGES
SUPPLY AIR
DUCT FLANGES
Dimensions (cont)
50PTV024-070 UNITS
50PTH,PTV 024-070 CORNER WEIGHTS
LEFT HAND EVAPORATOR
RIGHT
LEFT
FRONT*
BACK
(lbs)
(lbs)
74
68
RIGHT HAND EVAPORATOR
RIGHT
LEFT
FRONT*
BACK
(lbs)
(lbs)
74
61
RIGHT
BACK
(lbs)
61
LEFT
FRONT*
(lbs)
60
92
94
104
RIGHT
BACK
(lbs)
68
UNIT SIZE
024
TOTAL
(lbs)
283
LEFT
FRONT*
(lbs)
60
036
385
94
048
361
84
109
88
81
84
109
81
88
060
440
107
124
104
105
107
124
105
104
070
469
117
136
105
111
117
136
111
105
104
95
92
95
* Front is control box end.
LEGEND AND NOTES FOR PAGES 14-23
LEGEND
COP
EER
EWT
FOH
MBtuh
—
—
—
—
—
Coefficient of Performance
Energy Efficiency Ratio
Entering Water Temperature (F)
Feet of Heat
Btuh in Thousands
NOTES:
1. Interpolation is permissible; extrapolation is not.
2. AHRI/ISO certified conditions are 80.6 F db and 66.2 F wb in cooling and 68 F db in heating.
3. Table does not reflect fan or pump power corrections for AHRI/ISO
conditions.
4. Operation below 40 F EWT is based on a 15% antifreeze solution.
5. See Carrier WSHP Builder selection software for operating conditions other than those listed.
13
Performance data
50PTH,PTV024
650 CFM AT 0.34-in. ESP — PART LOAD
HEATING
COOLING
Entering Water Pressure Entering
Fluid
Flow Drop PSI Air Temp
Temp (F) (GPM) (FOH) (db/wb) F
75/63
0.7
3
75/63
(1.7)
80/67
85/71
1.3
50
4
75/63
(2.9)
80/67
85/71
2.6
6
75/63
(5.9)
80/67
85/71
0.7
3
75/63
(1.6)
80/67
85/71
1.2
60
4
75/63
(2.8)
80/67
85/71
2.5
6
75/63
(5.7)
80/67
85/71
0.7
3
75/63
(1.6)
80/67
85/71
1.2
70
4
75/63
(2.7)
80/67
85/71
2.4
6
75/63
(5.5)
80/67
85/71
0.6
3
75/63
(1.5)
80/67
85/71
1.1
80
4
75/63
(2.6)
80/67
85/71
2.3
6
75/63
(5.4)
80/67
85/71
0.6
3
75/63
(1.5)
80/67
85/71
1.1
85
4
75/63
(2.5)
80/67
85/71
2.3
6
75/63
(5.3)
80/67
85/71
0.6
3
75/63
(1.5)
80/67
85/71
1.1
90
4
75/63
(2.5)
80/67
85/71
2.3
6
75/63
(5.2)
80/67
85/71
0.6
3
75/63
(1.4)
80/67
85/71
1.0
100
4
75/63
(2.4)
80/67
85/71
2.2
6
75/63
(5.0)
80/67
85/71
0.6
3
75/63
(1.4)
80/67
85/71
1.0
4
110
75/63
(2.4)
80/67
85/71
2.1
6
75/63
(4.9)
80/67
14
Total
Capacity
(MBtuh)
20.0
20.0
21.3
22.7
20.4
21.8
23.2
20.8
22.2
23.7
19.0
20.3
21.6
19.4
20.7
22.0
19.8
21.1
22.5
18.0
19.2
20.4
18.3
19.6
20.9
18.7
20.0
21.3
17.0
18.1
19.3
17.3
18.5
19.7
17.6
18.9
20.1
16.4
17.5
18.7
16.8
17.9
19.1
17.1
18.3
19.5
15.9
17.0
18.1
16.2
17.3
18.5
16.5
17.7
18.9
14.8
15.8
16.9
15.1
16.2
17.2
15.4
16.5
17.6
13.7
14.7
15.7
14.0
15.0
16.0
14.2
15.3
Sensible
Capacity
(MBtuh)
15.8
15.8
16.3
16.8
16.0
16.5
16.9
16.2
16.7
17.1
15.4
15.9
16.3
15.6
16.0
16.5
15.7
16.2
16.7
15.0
15.5
16.0
15.1
15.6
16.1
15.3
15.8
16.3
14.5
15.1
15.5
14.6
15.2
15.7
14.8
15.3
15.9
14.3
14.9
15.3
14.4
15.0
15.5
14.6
15.1
15.6
14.1
14.6
15.1
14.2
14.8
15.3
14.3
14.9
15.4
13.6
14.2
14.7
13.7
14.3
14.9
13.9
14.4
15.0
13.2
13.7
14.3
13.3
13.9
14.4
13.4
14.0
Heat of
Power
Rejection Input
(MBtuh)
(kW)
22.5
0.77
22.5
0.77
23.8
0.76
25.1
0.76
22.8
0.74
24.1
0.73
25.6
0.72
23.1
0.71
24.5
0.70
26.0
0.69
21.7
0.86
23.0
0.85
24.3
0.84
22.0
0.82
23.3
0.81
24.6
0.80
22.3
0.79
23.6
0.78
25.0
0.77
21.0
0.96
22.2
0.95
23.4
0.94
21.2
0.92
22.5
0.91
23.7
0.90
21.5
0.89
22.8
0.87
24.1
0.86
20.2
1.08
21.4
1.07
22.6
1.06
20.5
1.04
21.6
1.03
22.9
1.02
20.7
1.00
21.9
0.99
23.1
0.97
19.9
1.14
21.0
1.13
22.2
1.13
20.1
1.10
21.2
1.09
22.4
1.08
20.3
1.06
21.5
1.05
22.7
1.03
19.5
1.21
20.7
1.20
21.8
1.20
19.7
1.17
20.9
1.16
22.0
1.15
20.0
1.13
21.1
1.12
22.3
1.10
18.9
1.36
19.9
1.36
21.0
1.35
19.0
1.32
20.1
1.31
21.2
1.30
19.2
1.28
20.3
1.26
21.5
1.25
18.3
1.53
19.3
1.53
20.3
1.52
18.4
1.48
19.4
1.48
20.5
1.47
18.5
1.44
19.6
1.43
EER
25.8
25.8
27.8
30.0
27.4
29.7
32.1
29.1
31.5
34.3
22.1
23.9
25.7
23.5
25.4
27.4
25.0
27.0
29.3
18.7
20.2
21.6
19.8
21.5
23.2
21.1
22.9
24.7
15.8
16.9
18.2
16.7
18.0
19.4
17.6
19.1
20.7
14.4
15.4
16.6
15.2
16.4
17.6
16.1
17.4
18.8
13.1
14.1
15.1
13.8
14.9
16.1
14.6
15.8
17.1
10.9
11.6
12.5
11.4
12.3
13.2
12.0
13.0
14.0
9.0
9.6
10.3
9.4
10.1
10.8
9.8
10.6
Entering Pressure Entering
Total
Heat of
Power
Fluid Temp Drop PSI Air Temp Capacity Absorption Input COP
(F)
(FOH)
(F)
(MBtuh)
(MBtuh)
(kW)
60
12.8
9.6
1.01
3.7
0.8
70
12.4
8.9
1.13
3.2
(1.8)
80
12.1
8.1
1.26
2.8
60
13.1
10.0
1.01
3.8
1.3
30
70
12.7
9.2
1.13
3.3
(3.1)
80
12.3
8.4
1.27
2.9
60
13.5
10.4
1.02
3.9
2.8
70
13.1
9.5
1.14
3.4
(6.4)
80
12.6
8.7
1.27
2.9
60
14.8
11.6
1.03
4.2
0.8
70
14.3
10.7
1.15
3.7
(1.8)
80
13.9
9.9
1.28
3.2
60
15.2
12.0
1.03
4.3
1.3
40
70
14.9
11.2
1.15
3.8
(3.0)
80
14.3
10.3
1.28
3.3
60
15.7
12.5
1.03
4.5
2.7
70
15.4
11.6
1.15
3.9
(6.1)
80
14.7
10.7
1.29
3.4
60
16.9
13.6
1.04
4.8
0.7
70
16.4
12.7
1.16
4.2
(1.7)
80
16.0
11.8
1.30
3.6
60
17.4
14.2
1.04
4.9
1.2
50
70
16.9
13.2
1.16
4.3
(2.9)
80
16.5
12.3
1.30
3.7
60
18.1
14.8
1.04
5.1
2.6
70
17.4
13.7
1.16
4.4
(5.9)
80
16.9
12.7
1.30
3.8
60
19.0
15.8
1.04
5.4
0.7
70
18.5
14.8
1.17
4.7
(1.6)
80
18.0
13.8
1.31
4.0
60
19.7
16.4
1.04
5.6
1.2
60
70
19.1
15.4
1.17
4.8
(2.8)
80
18.6
14.4
1.31
4.2
60
20.4
17.1
1.04
5.8
2.5
70
19.7
16.0
1.17
4.9
(5.7)
80
19.1
14.9
1.31
4.3
60
21.3
18.0
1.04
6.0
0.7
70
20.7
16.9
1.17
5.2
(1.6)
80
20.1
15.9
1.32
4.5
60
22.0
18.7
1.04
6.2
1.2
70
70
21.3
17.6
1.17
5.3
(2.7)
80
20.7
16.5
1.32
4.6
60
22.8
19.5
1.04
6.5
2.4
70
22.1
18.3
1.17
5.6
(5.5)
80
21.4
17.1
1.32
4.7
60
23.5
20.3
1.03
6.7
0.7
70
22.9
19.2
1.17
5.8
(1.5)
80
22.3
18.0
1.32
5.0
60
24.4
21.1
1.03
7.0
1.1
80
70
23.6
19.9
1.16
6.0
(2.6)
80
22.9
18.7
1.32
5.1
60
25.3
22.1
1.03
7.2
2.3
70
24.4
20.8
1.16
6.2
(5.4)
80
23.7
19.5
1.32
5.3
Operation Not Recommended
50PTH,PTV024
825 CFM AT 0.23-in. ESP — FULL LOAD
HEATING
COOLING
Entering Water Pressure Entering
Fluid
Flow Drop PSI Air Temp
Temp (F) (GPM) (FOH) (db/wb) F
75/63
0.7
3
80/67
(1.7)
85/71
75/63
1.3
50
4
80/67
(2.9)
85/71
75/63
2.6
6
80/67
(5.9)
85/71
75/63
0.7
3
80/67
(1.6)
85/71
75/63
1.2
60
4
80/67
(2.8)
85/71
75/63
2.5
6
80/67
(5.7)
85/71
75/63
0.7
3
80/67
(1.6)
85/71
75/63
1.2
70
4
80/67
(2.7)
85/71
75/63
2.4
6
80/67
(5.5)
85/71
75/63
0.6
3
80/67
(1.5)
85/71
75/63
1.1
80
4
80/67
(2.6)
85/71
75/63
2.3
6
80/67
(5.4)
85/71
75/63
0.6
3
80/67
(1.5)
85/71
75/63
1.1
85
4
80/67
(2.5)
85/71
75/63
2.3
6
80/67
(5.3)
85/71
75/63
0.6
3
80/67
(1.5)
85/71
75/63
1.1
4
90
80/67
(2.5)
85/71
75/63
2.3
6
80/67
(5.2)
85/71
75/63
0.6
3
80/67
(1.4)
85/71
75/63
1.0
100
4
80/67
(2.4)
85/71
75/63
2.2
6
80/67
(5.0)
85/71
75/63
0.6
3
80/67
(1.4)
85/71
75/63
1.0
4
110
80/67
(2.4)
85/71
75/63
2.1
6
80/67
(4.9)
85/71
Total
Capacity
(MBtuh)
27.1
28.9
30.7
27.8
29.6
31.5
28.5
30.4
32.4
25.9
27.5
29.3
26.6
28.2
30.1
27.2
29.0
30.9
24.6
26.2
27.9
25.2
26.9
28.6
25.9
27.6
29.5
23.4
24.9
26.4
23.9
25.5
27.2
24.5
26.2
28.0
22.7
24.1
25.7
23.3
24.8
26.4
23.9
25.4
27.2
22.0
23.5
24.9
22.5
24.0
25.7
23.2
24.7
26.4
20.7
22.1
23.6
21.2
22.7
24.1
21.7
23.2
24.8
19.4
20.7
22.1
19.9
21.3
22.7
20.4
21.8
23.3
Sensible
Capacity
(MBtuh)
20.7
21.2
21.8
21.0
21.6
22.1
21.3
21.9
22.4
20.2
20.8
21.3
20.4
21.1
21.6
20.7
21.3
22.0
19.7
20.2
20.8
19.9
20.5
21.1
20.1
20.8
21.3
19.1
19.7
20.3
19.3
20.0
20.5
19.6
20.3
20.8
18.8
19.5
20.1
19.0
19.7
20.3
19.3
20.0
20.5
18.5
19.2
19.8
18.8
19.4
20.0
19.0
19.6
20.3
18.0
18.7
19.3
18.2
18.9
19.5
18.4
19.1
19.7
17.5
18.2
18.8
17.6
18.3
19.0
17.8
18.6
19.2
Heat of
Power
Rejection Input
(MBtuh)
(kW)
31.3
1.27
33.1
1.29
35.0
1.30
31.8
1.20
33.6
1.22
35.6
1.24
32.3
1.14
34.2
1.15
36.3
1.16
30.4
1.38
32.1
1.40
34.0
1.41
30.9
1.32
32.6
1.34
34.5
1.35
31.4
1.26
33.2
1.27
35.2
1.28
29.4
1.49
31.1
1.51
32.9
1.53
29.9
1.44
31.6
1.45
33.4
1.46
30.4
1.38
32.1
1.39
34.1
1.40
28.5
1.62
30.1
1.64
31.8
1.66
29.0
1.56
30.6
1.58
32.4
1.59
29.4
1.50
31.1
1.52
32.9
1.52
28.0
1.69
29.6
1.71
31.3
1.73
28.5
1.63
30.1
1.65
31.8
1.66
28.9
1.57
30.5
1.58
32.4
1.59
27.7
1.77
29.2
1.79
30.7
1.80
28.0
1.71
29.5
1.72
31.3
1.73
28.4
1.64
30.0
1.66
31.7
1.66
26.8
1.93
28.3
1.95
29.8
1.97
27.1
1.87
28.7
1.88
30.2
1.89
27.4
1.80
29.0
1.81
30.7
1.82
26.1
2.12
27.5
2.14
28.9
2.16
26.4
2.06
27.8
2.07
29.3
2.08
26.6
1.99
28.1
1.99
29.7
2.00
EER
21.4
22.5
23.6
23.1
24.3
25.5
25.1
26.5
27.9
18.8
19.7
20.8
20.2
21.1
22.4
21.6
22.8
24.2
16.5
17.3
18.3
17.6
18.5
19.6
18.8
19.9
21.1
14.4
15.2
16.0
15.3
16.2
17.1
16.3
17.3
18.4
13.4
14.1
14.9
14.3
15.1
16.0
15.2
16.1
17.1
12.5
13.2
13.9
13.2
14.0
14.9
14.1
14.9
15.9
10.7
11.4
12.0
11.4
12.1
12.8
12.1
12.8
13.7
9.2
9.7
10.3
9.7
10.3
11.0
10.3
11.0
11.7
Entering Pressure Entering
Total
Heat of
Power
Fluid Temp Drop PSI Air Temp Capacity Absorption Input COP
(F)
(FOH)
(F)
(MBtuh)
(MBtuh)
(kW)
60
18.1
13.5
1.38
3.8
0.8
70
17.6
12.6
1.52
3.4
(1.8)
80
17.4
11.7
1.67
3.0
60
18.6
14.1
1.39
3.9
1.3
30
70
18.2
13.1
1.53
3.5
(3.1)
80
17.8
12.2
1.68
3.1
60
19.3
14.7
1.41
4.0
2.8
70
18.8
13.7
1.55
3.6
(6.4)
80
18.4
12.7
1.69
3.2
60
20.4
15.7
1.43
4.2
0.8
70
20.0
14.8
1.57
3.7
(1.8)
80
19.6
13.9
1.72
3.3
60
21.2
16.5
1.44
4.3
1.3
40
70
20.7
15.5
1.58
3.8
(3.0)
80
20.2
14.5
1.74
3.4
60
22.0
17.3
1.46
4.4
2.7
70
21.5
16.2
1.60
3.9
(6.1)
80
20.9
15.1
1.75
3.5
60
23.1
18.2
1.48
4.6
0.7
70
22.5
17.2
1.62
4.1
(1.7)
80
22.1
16.1
1.78
3.6
60
24.0
19.0
1.50
4.7
1.2
50
70
23.4
18.0
1.64
4.2
(2.9)
80
22.9
16.8
1.80
3.7
60
25.2
20.0
1.52
4.8
2.6
70
24.4
18.9
1.66
4.3
(5.9)
80
23.8
17.7
1.82
3.8
60
25.9
20.8
1.54
4.9
0.7
70
25.3
19.8
1.68
4.4
(1.6)
80
24.9
18.6
1.83
4.0
60
27.0
21.8
1.55
5.1
1.2
60
70
26.3
20.8
1.69
4.5
(2.8)
80
25.8
19.5
1.85
4.1
60
28.2
23.1
1.58
5.2
2.5
70
27.5
21.8
1.72
4.7
(5.7)
80
26.8
20.5
1.87
4.2
60
28.8
23.6
1.59
5.3
0.7
70
28.2
22.5
1.73
4.8
(1.6)
80
27.6
21.3
1.89
4.3
60
30.4
24.8
1.61
5.5
1.2
70
70
29.3
23.6
1.75
4.9
(2.7)
80
29.0
22.2
1.91
4.4
60
31.6
26.2
1.63
5.7
2.4
70
30.7
24.9
1.77
5.1
(5.5)
80
30.2
23.4
1.93
4.6
60
32.2
26.5
1.64
5.8
0.7
70
31.1
25.3
1.78
5.1
(1.5)
80
30.8
23.9
1.94
4.6
60
33.7
27.9
1.66
5.9
1.1
80
70
32.5
26.6
1.81
5.3
(2.6)
80
31.7
25.2
1.97
4.7
60
35.0
29.5
1.69
6.1
2.3
70
34.0
28.0
1.83
5.4
(5.4)
80
33.4
26.3
2.00
4.9
Operation Not Recommended
15
Performance data (cont)
50PTH,PTV036
800 CFM AT 0.58-in. ESP — PART LOAD
HEATING
COOLING
Entering Water Pressure Entering
Fluid
Flow Drop PSI Air Temp
Temp (F) (GPM) (FOH) (db/wb) F
75/63
1.4
4.5
80/67
(3.2)
85/71
75/63
2.3
50
6.0
80/67
(5.4)
85/71
75/63
4.8
9.0
80/67
(11.1)
85/71
75/63
1.3
4.5
80/67
(3.1)
85/71
75/63
2.3
60
6.0
80/67
(5.2)
85/71
75/63
4.6
9.0
80/67
(10.7)
85/71
75/63
1.3
4.5
80/67
(3.0)
85/71
75/63
2.2
70
6.0
80/67
(5.0)
85/71
75/63
4.5
9.0
80/67
(10.4)
85/71
75/63
1.3
4.5
80/67
(2.9)
85/71
75/63
2.1
80
6.0
80/67
(4.8)
85/71
75/63
4.4
9.0
80/67
(10.1)
85/71
75/63
1.2
4.5
80/67
(2.8)
85/71
75/63
2.1
85
6.0
80/67
(4.8)
85/71
75/63
4.3
9.0
80/67
(9.9)
85/71
75/63
1.2
4.5
80/67
(2.8)
85/71
75/63
2.0
90
6.0
80/67
(4.7)
85/71
75/63
4.2
9.0
80/67
(9.7)
85/71
75/63
1.2
4.5
80/67
(2.7)
85/71
75/63
2.0
100
6.0
80/67
(4.6)
85/71
75/63
4.1
9.0
80/67
(9.5)
85/71
75/63
1.1
4.5
80/67
(2.6)
85/71
75/63
1.9
6.0
110
80/67
(4.4)
85/71
75/63
4.0
9.0
80/67
(9.2)
85/71
16
Total
Capacity
(MBtuh)
29.9
32.0
34.2
30.4
32.5
34.8
30.8
33.1
35.4
28.5
30.5
32.7
29.0
31.1
33.3
29.4
31.6
33.9
27.1
29.1
31.1
27.5
29.6
31.7
27.9
30.0
32.3
25.7
27.5
29.5
26.1
28.0
30.1
26.5
28.4
30.5
24.9
26.8
28.7
25.3
27.2
29.2
25.7
27.6
29.7
24.1
26.0
27.9
24.5
26.4
28.4
24.9
26.8
28.8
22.7
24.4
26.2
23.0
24.8
26.6
23.3
25.1
27.1
21.1
22.8
24.5
21.4
23.1
24.9
21.8
23.5
25.3
Sensible
Capacity
(MBtuh)
21.8
22.4
23.0
22.0
22.7
23.3
22.2
22.8
23.5
21.2
21.9
22.4
21.4
22.1
22.6
21.6
22.3
22.9
20.6
21.2
21.9
20.8
21.4
22.1
21.0
21.6
22.2
19.9
20.7
21.3
20.1
20.8
21.4
20.3
21.0
21.7
19.7
20.3
21.0
19.8
20.5
21.2
19.9
20.7
21.3
19.3
20.1
20.7
19.5
20.2
20.8
19.6
20.3
21.0
18.7
19.4
20.0
18.9
19.5
20.3
19.0
19.7
20.4
18.1
18.8
19.5
18.2
19.0
19.6
18.3
19.1
19.7
Heat of
Power
Rejection Input
(MBtuh)
(kW)
33.2
1.01
35.3
1.00
37.5
0.98
33.6
0.99
35.7
0.97
38.0
0.95
34.0
0.96
36.2
0.94
38.5
0.92
32.1
1.11
34.1
1.10
36.3
1.08
32.4
1.07
34.5
1.06
36.7
1.04
32.8
1.04
34.9
1.02
37.2
1.00
31.0
1.23
33.0
1.22
35.0
1.21
31.3
1.19
33.4
1.18
35.5
1.16
31.7
1.16
33.7
1.14
35.9
1.12
30.1
1.39
31.9
1.38
33.9
1.37
30.3
1.35
32.3
1.33
34.3
1.32
30.6
1.30
32.6
1.29
34.6
1.27
29.6
1.48
31.5
1.47
33.4
1.47
29.9
1.43
31.7
1.42
33.7
1.41
30.1
1.39
32.0
1.37
34.1
1.35
29.1
1.58
30.9
1.57
32.8
1.57
29.3
1.53
31.3
1.52
33.2
1.51
29.6
1.48
31.5
1.47
33.5
1.45
28.3
1.80
30.0
1.79
31.9
1.79
28.5
1.74
30.3
1.73
32.1
1.72
28.7
1.69
30.4
1.68
32.4
1.67
27.5
2.04
29.2
2.04
30.9
2.03
27.7
1.99
29.4
1.98
31.1
1.97
27.8
1.94
29.5
1.92
31.4
1.91
EER
29.6
32.1
34.9
30.9
33.6
36.7
32.0
35.1
38.5
25.7
27.9
30.3
27.0
29.4
32.0
28.2
30.9
33.9
22.0
23.8
25.7
23.1
25.1
27.2
24.2
26.4
28.9
18.5
19.9
21.5
19.4
21.0
22.8
20.4
22.1
24.1
16.8
18.2
19.6
17.7
19.2
20.8
18.5
20.1
21.9
15.3
16.6
17.8
16.0
17.4
18.9
16.8
18.3
19.9
12.7
13.6
14.7
13.2
14.3
15.5
13.8
14.9
16.3
10.3
11.2
12.1
10.8
11.7
12.6
11.3
12.2
13.2
Entering Pressure Entering
Total
Heat of
Power
Fluid Temp Drop PSI Air Temp Capacity Absorption Input COP
(F)
(FOH)
(F)
(MBtuh)
(MBtuh)
(kW)
60
18.4
13.6
1.46
3.7
1.5
70
17.9
12.5
1.65
3.2
(3.4)
80
17.7
11.4
1.87
2.8
60
18.8
14.0
1.47
3.8
2.5
30
70
18.3
12.9
1.65
3.2
(5.7)
80
18.0
11.7
1.87
2.8
60
19.3
14.5
1.47
3.8
5.2
70
18.9
13.4
1.66
3.3
(11.9)
80
18.3
12.4
1.87
2.9
60
21.3
16.4
1.48
4.2
1.4
70
20.8
15.3
1.67
3.6
(3.3)
80
20.3
14.1
1.89
3.1
60
21.9
17.0
1.49
4.3
2.4
40
70
21.3
15.8
1.67
3.7
(5.5)
80
20.8
14.5
1.89
3.2
60
22.5
17.6
1.49
4.4
5.0
70
21.9
16.3
1.68
3.8
(11.5)
80
21.4
15.1
1.90
3.3
60
24.4
19.4
1.50
4.8
1.4
70
23.8
18.1
1.69
4.1
(3.2)
80
23.5
16.8
1.92
3.6
60
25.1
20.1
1.51
4.9
2.3
50
70
24.4
18.8
1.70
4.2
(5.4)
80
23.9
17.5
1.92
3.6
60
25.9
20.9
1.51
5.0
4.8
70
25.1
19.5
1.70
4.3
(11.1)
80
24.6
18.1
1.93
3.7
60
27.6
22.6
1.52
5.3
1.3
70
26.9
21.2
1.72
4.6
(3.1)
80
26.3
19.6
1.95
4.0
60
28.4
23.4
1.52
5.5
2.2
60
70
27.7
22.0
1.73
4.7
(5.2)
80
27.0
20.5
1.95
4.0
60
29.4
24.4
1.53
5.6
4.6
70
28.5
22.8
1.73
4.8
(10.7)
80
28.0
21.1
1.97
4.2
60
30.9
25.9
1.54
5.9
1.3
70
30.0
24.2
1.74
5.0
(3.0)
80
29.7
22.7
1.99
4.4
60
31.9
26.9
1.54
6.1
2.2
70
70
31.0
25.3
1.75
5.2
(5.0)
80
30.3
23.6
1.99
4.5
60
33.0
28.0
1.54
6.3
4.5
70
32.0
26.3
1.76
5.3
(10.4)
80
31.2
24.4
2.00
4.6
60
34.4
28.7
1.55
6.5
1.2
70
33.2
27.5
1.77
5.5
(2.9)
80
32.8
25.8
2.02
4.8
60
35.4
30.5
1.55
6.7
2.1
80
70
34.4
28.6
1.78
5.7
(4.8)
80
33.8
26.4
2.03
4.9
60
36.7
31.8
1.56
6.9
4.4
70
35.6
29.9
1.79
5.8
(10.1)
80
35.0
27.6
2.04
5.0
Operation Not Recommended
50PTH,PTV036
1,100 CFM AT 0.25-in. ESP — FULL LOAD
HEATING
COOLING
Entering Water Pressure Entering
Fluid
Flow Drop PSI Air Temp
Temp (F) (GPM) (FOH) (db/wb) F
75/63
1.4
4.5
80/67
(3.2)
85/71
75/63
2.3
50
6.0
80/67
(5.4)
85/71
75/63
4.8
9.0
80/67
(11.1)
85/71
75/63
1.3
4.5
80/67
(3.1)
85/71
75/63
2.3
60
6.0
80/67
(5.2)
85/71
75/63
4.6
9.0
80/67
(10.7)
85/71
75/63
1.3
4.5
80/67
(3.0)
85/71
75/63
2.2
70
6.0
80/67
(5.0)
85/71
75/63
4.5
9.0
80/67
(10.4)
85/71
75/63
1.3
4.5
80/67
(2.9)
85/71
75/63
2.1
80
6.0
80/67
(4.8)
85/71
75/63
4.4
9.0
80/67
(10.1)
85/71
75/63
1.2
4.5
80/67
(2.8)
85/71
75/63
2.1
85
6.0
80/67
(4.8)
85/71
75/63
4.3
9.0
80/67
(9.9)
85/71
75/63
1.2
4.5
80/67
(2.8)
85/71
75/63
2.0
6.0
90
80/67
(4.7)
85/71
75/63
4.2
9.0
80/67
(9.7)
85/71
75/63
1.2
4.5
80/67
(2.7)
85/71
75/63
2.0
100
6.0
80/67
(4.6)
85/71
75/63
4.1
9.0
80/67
(9.5)
85/71
75/63
1.1
4.5
80/67
(2.6)
85/71
75/63
1.9
6.0
110
80/67
(4.4)
85/71
75/63
4.0
9.0
80/67
(9.2)
85/71
Total
Capacity
(MBtuh)
40.9
43.6
46.4
41.6
44.4
47.4
42.4
45.3
48.3
39.2
41.8
44.6
40.0
42.6
45.5
40.7
43.5
46.4
37.5
40.0
42.6
38.2
40.8
43.5
38.9
41.6
44.5
35.7
38.1
40.7
36.5
38.9
41.6
37.1
39.6
42.5
34.8
37.2
39.8
35.5
38.0
40.5
36.1
38.6
41.4
34.0
36.3
38.8
34.6
37.0
39.5
35.2
37.7
40.4
32.1
34.4
36.7
32.7
35.0
37.4
33.3
35.7
38.1
30.3
32.4
34.7
30.8
33.1
35.4
31.5
33.7
36.1
Sensible
Capacity
(MBtuh)
29.9
30.6
31.4
30.2
31.0
31.7
30.6
31.4
32.1
29.1
30.0
30.7
29.4
30.3
31.1
29.8
30.5
31.4
28.4
29.1
30.0
28.7
29.5
30.4
29.0
29.8
30.6
27.7
28.5
29.3
27.9
28.8
29.6
28.2
29.1
29.8
27.3
28.1
28.8
27.6
28.4
29.2
27.7
28.7
29.5
26.8
27.7
28.5
27.2
28.1
28.9
27.4
28.2
29.1
26.1
26.9
27.9
26.3
27.3
28.1
26.6
27.5
28.4
25.3
26.3
27.1
25.5
26.5
27.3
25.8
26.7
27.6
Heat of
Power
Rejection Input
(MBtuh)
(kW)
46.4
1.69
49.3
1.74
52.3
1.78
47.0
1.64
50.0
1.69
53.1
1.73
47.7
1.60
50.7
1.64
54.0
1.69
45.2
1.82
47.9
1.86
50.8
1.89
45.7
1.76
48.5
1.79
51.5
1.83
46.3
1.71
49.3
1.74
52.3
1.78
43.9
1.97
46.6
2.01
49.3
2.04
44.4
1.91
47.2
1.94
50.0
1.96
44.9
1.85
47.8
1.87
50.8
1.90
42.7
2.16
45.2
2.19
47.9
2.22
43.2
2.09
45.7
2.11
48.5
2.13
43.6
2.02
46.3
2.04
49.2
2.06
42.1
2.27
44.6
2.29
47.3
2.32
42.5
2.19
45.2
2.21
47.8
2.23
43.0
2.12
45.6
2.14
48.4
2.15
41.6
2.38
44.1
2.41
46.6
2.43
42.0
2.30
44.5
2.32
47.1
2.34
42.3
2.23
45.0
2.25
47.7
2.26
40.5
2.63
43.0
2.66
45.3
2.68
40.9
2.55
43.3
2.57
45.8
2.58
41.2
2.47
43.7
2.48
46.2
2.49
39.7
2.92
41.9
2.94
44.3
2.96
39.9
2.84
42.2
2.85
44.6
2.86
40.2
2.74
42.6
2.75
45.0
2.77
EER
24.2
25.1
26.1
25.3
26.4
27.4
26.6
27.6
28.7
21.6
22.5
23.6
22.7
23.8
24.9
23.9
25.0
26.2
19.0
19.9
20.9
20.1
21.1
22.2
21.1
22.2
23.4
16.5
17.4
18.4
17.5
18.5
19.5
18.4
19.5
20.7
15.4
16.2
17.2
16.2
17.2
18.2
17.0
18.1
19.3
14.3
15.1
16.0
15.1
16.0
16.9
15.8
16.8
17.9
12.2
13.0
13.7
12.8
13.7
14.5
13.5
14.4
15.3
10.4
11.0
11.7
10.9
11.6
12.4
11.5
12.3
13.1
Entering Pressure Entering
Total
Heat of
Power
Fluid Temp Drop PSI Air Temp Capacity Absorption Input COP
(F)
(FOH)
(F)
(MBtuh)
(MBtuh)
(kW)
60
25.9
19.5
1.93
3.9
1.5
70
25.6
18.3
2.15
3.5
(3.4)
80
25.6
17.1
2.40
3.1
60
26.8
20.2
1.95
4.0
2.5
30
70
26.3
19.0
2.17
3.5
(5.7)
80
26.3
17.7
2.42
3.2
60
27.7
21.1
1.97
4.1
5.2
70
27.2
19.8
2.19
3.6
(11.9)
80
27.1
18.3
2.44
3.3
60
29.6
22.9
2.01
4.3
1.4
70
29.1
21.6
2.23
3.8
(3.3)
80
28.7
20.3
2.48
3.4
60
30.7
23.9
2.03
4.4
2.4
40
70
30.1
22.5
2.25
3.9
(5.5)
80
29.5
21.1
2.50
3.4
60
31.9
25.0
2.05
4.5
5.0
70
31.1
23.5
2.28
4.0
(11.5)
80
30.5
22.0
2.53
3.5
60
33.6
26.6
2.09
4.7
1.4
70
32.9
25.1
2.32
4.2
(3.2)
80
32.8
23.5
2.57
3.7
60
34.9
27.8
2.12
4.8
2.3
50
70
34.1
26.2
2.34
4.3
(5.4)
80
34.1
24.5
2.60
3.8
60
36.3
29.1
2.15
4.9
4.8
70
35.4
27.5
2.37
4.4
(11.1)
80
35.3
25.5
2.62
3.9
60
37.8
30.5
2.18
5.1
1.3
70
37.0
28.9
2.40
4.5
(3.1)
80
36.3
27.3
2.65
4.0
60
39.3
31.9
2.21
5.2
2.2
60
70
38.4
30.2
2.43
4.6
(5.2)
80
37.6
28.5
2.68
4.1
60
41.0
33.5
2.25
5.3
4.6
70
40.0
31.7
2.46
4.8
(10.7)
80
39.0
29.8
2.71
4.2
60
42.2
34.6
2.27
5.4
1.3
70
41.2
32.8
2.49
4.8
(3.0)
80
40.4
31.1
2.75
4.3
60
44.0
36.2
2.31
5.6
2.2
70
70
42.9
34.4
2.53
5.0
(5.0)
80
41.9
32.5
2.78
4.4
60
46.0
38.1
2.36
5.7
4.5
70
44.7
36.1
2.57
5.1
(10.4)
80
43.5
34.0
2.82
4.5
60
46.7
38.8
2.37
5.8
1.2
70
46.0
36.8
2.59
5.2
(2.9)
80
44.6
35.0
2.85
4.6
60
48.8
40.7
2.42
5.9
2.1
80
70
47.5
38.6
2.64
5.3
(4.8)
80
46.4
36.6
2.89
4.7
60
51.1
42.8
2.48
6.0
4.4
70
49.6
40.6
2.69
5.4
(10.1)
80
48.2
38.3
2.94
4.8
Operation Not Recommended
17
Performance data (cont)
50PTH,PTV048
1,300 CFM AT 0.27-in. ESP — PART LOAD
HEATING
COOLING
Entering Water Pressure Entering
Fluid
Flow Drop PSI Air Temp
Temp (F) (GPM) (FOH) (db/wb) F
75/63
1.1
6
80/67
(2.6)
85/71
75/63
1.9
50
8
80/67
(4.4)
85/71
75/63
3.9
12
80/67
(9.1)
85/71
75/63
1.1
6
80/67
(2.5)
85/71
75/63
1.9
60
8
80/67
(4.3)
85/71
75/63
3.8
12
80/67
(8.8)
85/71
75/63
1.1
6
80/67
(2.5)
85/71
75/63
1.8
70
8
80/67
(4.1)
85/71
75/63
3.7
12
80/67
(8.6)
85/71
75/63
1.0
6
80/67
(2.4)
85/71
75/63
1.7
80
8
80/67
(4.0)
85/71
75/63
3.6
12
80/67
(8.3)
85/71
75/63
1.0
6
80/67
(2.3)
85/71
75/63
1.7
85
8
80/67
(3.9)
85/71
75/63
3.5
12
80/67
(8.1)
85/71
75/63
1.0
6
80/67
(2.3)
85/71
75/63
1.7
90
8
80/67
(3.9)
85/71
75/63
3.5
12
80/67
(8.0)
85/71
75/63
1.0
6
80/67
(2.2)
85/71
75/63
1.6
100
8
80/67
(3.8)
85/71
75/63
3.4
12
80/67
(7.8)
85/71
75/63
1.0
6
80/67
(2.2)
85/71
75/63
1.6
8
110
80/67
(3.6)
85/71
75/63
3.3
12
80/67
(7.6)
85/71
18
Total
Capacity
(MBtuh)
39.8
42.6
45.3
40.7
43.6
46.4
41.7
44.6
47.6
37.7
40.3
43.0
38.5
41.2
44.0
39.4
42.2
45.2
35.5
38.0
40.6
36.3
38.9
41.5
37.1
39.7
42.6
33.2
35.6
38.2
33.9
36.4
39.0
34.7
37.3
40.0
32.1
34.5
37.0
32.8
35.3
37.8
33.5
36.0
38.7
31.0
33.3
35.7
31.7
34.0
36.6
32.3
34.9
37.5
28.8
31.0
33.3
29.4
31.6
34.0
30.0
32.4
34.8
26.6
28.7
30.5
27.1
29.3
31.5
27.7
29.9
32.2
Sensible
Capacity
(MBtuh)
31.6
32.6
33.5
32.0
33.0
34.0
32.4
33.4
34.3
30.6
31.7
32.6
31.1
32.1
33.1
31.4
32.5
33.4
29.7
30.9
31.8
30.0
31.2
32.2
30.4
31.6
32.5
28.9
30.0
31.0
29.2
30.3
31.4
29.5
30.6
31.7
28.4
29.5
30.6
28.7
29.8
30.8
29.0
30.2
31.3
28.0
29.1
30.2
28.2
29.4
30.4
28.5
29.6
30.7
27.0
28.3
29.4
27.3
28.5
29.7
27.6
28.7
29.9
26.2
27.4
28.5
26.4
27.7
28.8
26.6
27.9
29.1
Heat of
Power
Rejection Input
(MBtuh)
(kW)
44.5
1.43
47.2
1.41
49.9
1.39
45.2
1.36
47.9
1.33
50.7
1.30
45.9
1.28
48.7
1.24
51.7
1.21
43.0
1.63
45.5
1.61
48.2
1.58
43.5
1.55
46.2
1.52
48.9
1.49
44.2
1.47
46.9
1.44
49.8
1.40
41.4
1.85
43.8
1.82
46.5
1.80
41.9
1.77
44.5
1.74
47.1
1.71
42.5
1.69
45.1
1.65
47.9
1.62
39.8
2.09
42.2
2.07
44.8
2.05
40.3
2.01
42.8
1.98
45.3
1.95
40.8
1.92
43.4
1.89
46.0
1.86
39.2
2.22
41.5
2.20
44.0
2.18
39.6
2.13
42.0
2.11
44.5
2.08
40.0
2.05
42.5
2.02
45.1
1.99
38.4
2.35
40.7
2.34
43.1
2.32
38.9
2.27
41.2
2.25
43.7
2.22
39.3
2.19
41.7
2.16
44.3
2.12
37.1
2.64
39.3
2.63
41.6
2.61
37.4
2.56
39.7
2.54
42.0
2.52
37.8
2.48
40.2
2.45
42.5
2.42
35.9
2.96
38.0
2.95
39.9
2.94
36.1
2.88
38.3
2.86
40.5
2.84
36.5
2.80
38.7
2.77
41.0
2.74
EER
27.8
30.2
32.7
30.0
32.8
35.8
32.6
35.8
39.4
23.1
25.1
27.1
24.8
27.0
29.5
26.8
29.4
32.2
19.2
20.8
22.5
20.5
22.4
24.3
22.0
24.0
26.3
15.9
17.2
18.7
16.9
18.4
20.0
18.0
19.7
21.5
14.5
15.7
17.0
15.4
16.7
18.1
16.3
17.8
19.5
13.2
14.2
15.4
14.0
15.1
16.5
14.8
16.2
17.7
10.9
11.8
12.7
11.5
12.4
13.5
12.1
13.2
14.4
9.0
9.7
10.4
9.4
10.2
11.1
9.9
10.8
11.7
Entering Pressure Entering
Total
Heat of
Power
Fluid Temp Drop PSI Air Temp Capacity Absorption Input COP
(F)
(FOH)
(F)
(MBtuh)
(MBtuh)
(kW)
60
25.7
19.3
1.95
3.9
1.2
70
24.8
17.7
2.18
3.3
(2.8)
80
24.0
16.0
2.44
2.9
60
26.4
20.0
1.95
4.0
2.0
30
70
25.5
18.3
2.18
3.4
(4.7)
80
24.6
16.6
2.44
3.0
60
27.2
20.8
1.95
4.1
4.2
70
26.2
19.0
2.18
3.5
(9.8)
80
25.2
17.2
2.45
3.0
60
29.3
22.9
1.96
4.4
1.2
70
28.4
21.1
2.20
3.8
(2.7)
80
27.6
19.4
2.47
3.3
60
30.2
23.8
1.96
4.5
2.0
40
70
29.2
21.9
2.20
3.9
(4.6)
80
28.3
20.1
2.47
3.4
60
31.2
24.7
1.96
4.7
4.1
70
30.1
22.8
2.21
4.0
(9.5)
80
29.1
20.9
2.48
3.4
60
33.3
26.8
1.97
5.0
1.1
70
32.3
24.9
2.22
4.3
(2.6)
80
31.4
23.1
2.50
3.7
60
34.4
27.9
1.97
5.1
1.9
50
70
33.3
25.9
2.22
4.4
(4.4)
80
32.4
23.9
2.50
3.8
60
35.6
29.1
1.97
5.3
4.0
70
34.4
27.0
2.23
4.5
(9.1)
80
33.4
24.9
2.50
3.9
60
37.5
31.0
1.98
5.5
1.1
70
36.5
29.0
2.23
4.8
(2.5)
80
35.5
27.1
2.51
4.1
60
38.9
32.3
1.98
5.8
1.8
60
70
37.7
30.2
2.24
4.9
(4.3)
80
36.6
28.2
2.52
4.3
60
40.3
33.8
1.98
6.0
3.8
70
39.0
31.6
2.24
5.1
(8.8)
80
37.8
29.4
2.52
4.4
60
42.0
35.5
1.98
6.2
1.1
70
40.9
33.4
2.24
5.3
(2.5)
80
39.8
31.3
2.53
4.6
60
43.6
37.1
1.98
6.4
1.8
70
70
42.3
34.8
2.25
5.5
(4.1)
80
41.1
32.6
2.54
4.8
60
45.3
38.8
1.98
6.7
3.7
70
43.9
36.4
2.25
5.7
(8.6)
80
42.5
34.0
2.54
4.9
60
46.7
40.2
1.98
6.9
1.0
70
45.5
38.0
2.25
5.9
(2.4)
80
44.3
35.8
2.55
5.1
60
48.5
42.0
1.98
7.2
1.7
80
70
47.1
39.6
2.26
6.1
(4.0)
80
45.8
37.2
2.55
5.3
60
50.5
44.0
1.98
7.5
3.6
70
48.9
41.5
2.26
6.3
(8.3)
80
47.4
38.9
2.56
5.4
Operation Not Recommended
50PTH,PTV048
1,600 CFM AT 0.60-in. ESP — FULL LOAD
HEATING
COOLING
Entering Water Pressure Entering
Fluid
Flow Drop PSI Air Temp
Temp (F) (GPM) (FOH) (db/wb) F
75/63
1.1
6
80/67
(2.6)
85/71
75/63
1.9
50
8
80/67
(4.4)
85/71
75/63
3.9
12
80/67
(9.1)
85/71
75/63
1.1
6
80/67
(2.5)
85/71
75/63
1.9
60
8
80/67
(4.3)
85/71
75/63
3.8
12
80/67
(8.8)
85/71
75/63
1.1
6
80/67
(2.5)
85/71
75/63
1.8
70
8
80/67
(4.1)
85/71
75/63
3.7
12
80/67
(8.6)
85/71
75/63
1.0
6
80/67
(2.4)
85/71
75/63
1.7
80
8
80/67
(4.0)
85/71
75/63
3.6
12
80/67
(8.3)
85/71
75/63
1.0
6
80/67
(2.3)
85/71
75/63
1.7
85
8
80/67
(3.9)
85/71
75/63
3.5
12
80/67
(8.1)
85/71
75/63
1.0
6
80/67
(2.3)
85/71
75/63
1.7
8
90
80/67
(3.9)
85/71
75/63
3.5
12
80/67
(8.0)
85/71
75/63
1.0
6
80/67
(2.2)
85/71
75/63
1.6
100
8
80/67
(3.8)
85/71
75/63
3.4
12
80/67
(7.8)
85/71
75/63
1.0
6
80/67
(2.2)
85/71
75/63
1.6
8
110
80/67
(3.6)
85/71
75/63
3.3
12
80/67
(7.6)
85/71
Total
Capacity
(MBtuh)
52.4
55.8
59.4
53.7
57.2
61.0
55.0
58.8
62.7
50.0
53.4
56.9
51.3
54.8
58.4
52.6
56.3
59.9
47.7
50.9
54.3
48.9
52.2
55.6
50.1
53.6
57.2
45.2
48.3
51.6
46.4
49.6
53.0
47.5
50.9
54.4
44.0
47.0
50.2
45.1
48.2
51.6
46.3
49.6
53.0
42.7
45.7
48.8
43.8
46.8
50.1
44.9
48.2
51.6
40.2
43.1
45.9
41.2
44.2
47.2
42.2
45.3
48.6
37.6
40.3
42.9
38.5
41.3
44.1
39.5
42.5
45.4
Sensible
Capacity
(MBtuh)
40.1
41.4
42.3
40.7
41.9
42.9
41.3
42.4
43.6
39.2
40.4
41.4
39.7
40.8
42.0
40.3
41.4
42.7
38.2
39.4
40.4
38.6
39.9
41.1
39.1
40.5
41.7
37.1
38.4
39.5
37.5
38.8
40.0
38.1
39.4
40.6
36.5
37.9
39.0
37.1
38.4
39.5
37.5
38.8
40.0
36.1
37.4
38.5
36.4
37.9
39.0
37.0
38.3
39.5
35.1
36.3
37.7
35.5
36.7
38.0
35.9
37.3
38.4
34.0
35.3
36.7
34.4
35.8
37.1
34.8
36.1
37.5
Heat of
Power
Rejection Input
(MBtuh)
(kW)
60.5
2.47
64.0
2.50
67.7
2.53
61.4
2.36
65.0
2.38
68.9
2.40
62.4
2.24
66.3
2.25
70.2
2.26
58.8
2.69
62.2
2.71
65.9
2.74
59.6
2.57
63.3
2.59
67.0
2.61
60.6
2.45
64.4
2.46
68.1
2.47
57.1
2.93
60.5
2.95
64.0
2.98
58.0
2.81
61.5
2.83
64.9
2.84
58.9
2.68
62.4
2.69
66.1
2.70
55.5
3.20
58.8
3.23
62.2
3.26
56.3
3.07
59.7
3.09
63.1
3.11
57.0
2.94
60.5
2.95
64.1
2.96
54.8
3.35
57.9
3.38
61.3
3.42
55.4
3.22
58.7
3.24
62.2
3.26
56.3
3.09
59.6
3.10
63.2
3.11
54.0
3.52
57.1
3.55
60.4
3.59
54.7
3.38
57.8
3.40
61.3
3.43
55.3
3.24
58.7
3.25
62.2
3.27
52.7
3.88
55.7
3.92
58.7
3.96
53.2
3.73
56.3
3.76
59.5
3.79
53.7
3.59
56.9
3.60
60.3
3.62
51.4
4.31
54.3
4.35
57.1
4.40
51.8
4.15
54.7
4.17
57.7
4.21
52.3
3.99
55.4
4.01
58.4
4.02
EER
21.2
22.3
23.5
22.8
24.1
25.5
24.6
26.1
27.7
18.6
19.7
20.8
20.0
21.2
22.4
21.5
22.9
24.2
16.3
17.2
18.2
17.4
18.5
19.6
18.7
19.9
21.2
14.1
14.9
15.8
15.1
16.0
17.0
16.1
17.2
18.4
13.1
13.9
14.7
14.0
14.9
15.8
15.0
16.0
17.0
12.1
12.9
13.6
13.0
13.8
14.6
13.9
14.8
15.8
10.4
11.0
11.6
11.0
11.8
12.5
11.8
12.6
13.4
8.7
9.3
9.8
9.3
9.9
10.5
9.9
10.6
11.3
Entering Pressure Entering
Total
Heat of
Power
Fluid Temp Drop PSI Air Temp Capacity Absorption Input COP
(F)
(FOH)
(F)
(MBtuh)
(MBtuh)
(kW)
60
34.5
25.7
2.67
3.8
1.2
70
34.0
24.2
2.98
3.3
(2.8)
80
34.2
22.4
3.32
3.0
60
35.8
26.9
2.70
3.9
2.0
30
70
35.4
25.1
3.01
3.4
(4.7)
80
34.9
23.4
3.34
3.1
60
37.3
28.2
2.73
4.0
4.2
70
36.7
26.3
3.04
3.5
(9.8)
80
36.6
24.3
3.37
3.2
60
39.5
30.3
2.79
4.2
1.2
70
38.8
28.6
3.09
3.7
(2.7)
80
39.0
26.6
3.42
3.3
60
41.5
31.4
2.82
4.3
2.0
40
70
40.3
30.0
3.12
3.8
(4.6)
80
40.3
27.8
3.45
3.4
60
42.9
33.3
2.86
4.4
4.1
70
42.0
31.4
3.15
3.9
(9.5)
80
41.1
29.4
3.48
3.5
60
44.9
35.0
2.90
4.5
1.1
70
44.7
33.1
3.20
4.1
(2.6)
80
44.0
31.3
3.52
3.7
60
47.3
36.7
2.94
4.7
1.9
50
70
46.4
34.7
3.23
4.2
(4.4)
80
45.7
32.7
3.56
3.8
60
49.0
39.0
2.98
4.8
4.0
70
47.9
36.7
3.27
4.3
(9.1)
80
47.5
34.3
3.60
3.9
60
50.6
40.4
3.01
4.9
1.1
70
49.6
38.4
3.31
4.4
(2.5)
80
48.8
36.4
3.64
3.9
60
53.4
42.4
3.05
5.1
1.8
60
70
52.3
40.2
3.35
4.6
(4.3)
80
51.3
37.9
3.68
4.1
60
55.4
45.0
3.09
5.2
3.8
70
54.0
42.6
3.39
4.7
(8.8)
80
52.8
40.1
3.73
4.1
60
56.5
46.0
3.11
5.3
1.1
70
55.4
43.8
3.42
4.7
(2.5)
80
54.5
41.6
3.77
4.2
60
59.1
48.4
3.16
5.5
1.8
70
70
57.8
46.0
3.47
4.9
(4.1)
80
58.4
42.8
3.82
4.5
60
62.1
51.4
3.21
5.7
3.7
70
60.5
48.7
3.52
5.0
(8.6)
80
59.1
46.0
3.88
4.5
60
62.6
52.1
3.22
5.7
1.0
70
61.4
49.5
3.54
5.1
(2.4)
80
60.2
47.0
3.90
4.5
60
65.6
55.0
3.27
5.9
1.7
80
70
64.1
52.0
3.59
5.2
(4.0)
80
62.8
49.3
3.96
4.6
60
69.0
58.0
3.33
6.1
3.6
70
67.2
54.9
3.66
5.4
(8.3)
80
65.8
51.4
4.03
4.8
Operation Not Recommended
19
Performance data (cont)
50PTH,PTV060
1,600 CFM AT 0.60-in. ESP — PART LOAD
HEATING
COOLING
Entering Water Pressure Entering
Fluid
Flow Drop PSI Air Temp
Temp (F) (GPM) (FOH) (db/wb) F
75/63
1.2
7.5
80/67
(2.8)
85/71
75/63
2.0
50
10.0
80/67
(4.7)
85/71
75/63
4.2
15.0
80/67
(9.7)
85/71
75/63
1.1
7.5
80/67
(2.6)
85/71
75/63
1.9
60
10.0
80/67
(4.4)
85/71
75/63
3.9
15.0
80/67
(9.1)
85/71
75/63
1.1
7.5
80/67
(2.6)
85/71
75/63
1.9
70
10.0
80/67
(4.4)
85/71
75/63
3.9
15.0
80/67
(9.1)
85/71
75/63
1.1
7.5
80/67
(2.5)
85/71
75/63
1.8
80
10.0
80/67
(4.2)
85/71
75/63
3.8
15.0
80/67
(8.8)
85/71
75/63
1.1
7.5
80/67
(2.5)
85/71
75/63
1.8
85
10.0
80/67
(4.2)
85/71
75/63
3.7
15.0
80/67
(8.5)
85/71
75/63
1.0
7.5
80/67
(2.4)
85/71
75/63
1.8
90
10.0
80/67
(4.1)
85/71
75/63
3.7
15.0
80/67
(8.5)
85/71
75/63
1.0
7.5
80/67
(2.4)
85/71
75/63
1.7
100
10.0
80/67
(4.0)
85/71
75/63
3.6
15.0
80/67
(8.3)
85/71
75/63
1.0
7.5
80/67
(2.3)
85/71
75/63
1.7
10.0
110
80/67
(3.9)
85/71
75/63
3.5
15.0
80/67
(8.0)
85/71
20
Total
Capacity
(MBtuh)
51.0
54.5
58.0
52.1
55.7
59.3
53.2
56.8
60.7
48.3
51.7
55.1
49.3
52.8
56.2
50.4
53.8
57.6
45.5
48.6
52.1
46.4
49.8
53.2
47.4
50.8
54.3
42.6
45.7
48.9
43.5
46.7
49.9
44.3
47.7
51.2
41.1
44.2
47.4
42.0
45.2
48.4
42.9
46.1
49.5
39.7
42.7
45.8
40.5
43.6
46.8
41.4
44.5
47.8
36.9
39.7
42.6
37.6
40.5
43.4
38.4
41.3
44.5
34.0
36.6
39.4
34.6
37.4
40.3
35.3
38.2
41.1
Sensible
Capacity
(MBtuh)
39.7
40.9
42.1
40.2
41.4
42.5
40.6
41.9
42.9
38.5
39.7
40.9
38.9
40.2
41.4
39.3
40.7
41.8
37.3
38.7
39.8
37.8
39.0
40.2
38.2
39.5
40.8
36.1
37.5
38.8
36.4
37.8
39.2
36.9
38.3
39.5
35.6
36.9
38.2
35.9
37.2
38.5
36.2
37.6
38.9
35.0
36.3
37.6
35.2
36.7
38.1
35.5
37.0
38.5
33.8
35.3
36.6
34.1
35.6
37.0
34.3
35.9
37.2
32.7
34.2
35.7
33.0
34.5
35.9
33.2
34.6
36.2
Heat of
Power
Rejection Input
(MBtuh)
(kW)
57.1
1.85
60.5
1.83
63.9
1.79
57.9
1.77
61.4
1.74
64.9
1.70
58.8
1.69
62.3
1.65
66.1
1.61
55.0
2.08
58.4
2.05
61.8
2.02
55.8
2.00
59.2
1.96
62.6
1.93
56.6
1.91
60.0
1.87
63.7
1.83
53.1
2.34
56.2
2.31
59.5
2.29
53.7
2.25
57.0
2.22
60.4
2.18
54.4
2.16
57.7
2.12
61.2
2.08
51.1
2.64
54.2
2.61
57.2
2.58
51.7
2.55
54.8
2.51
58.0
2.47
52.2
2.45
55.5
2.41
58.9
2.37
50.1
2.80
53.2
2.77
56.3
2.75
50.6
2.71
53.8
2.67
57.0
2.64
51.3
2.61
54.4
2.57
57.7
2.53
49.2
2.97
52.2
2.94
55.2
2.92
49.7
2.88
52.7
2.84
55.8
2.81
50.3
2.78
53.4
2.74
56.5
2.70
47.5
3.32
50.3
3.30
53.2
3.29
47.9
3.23
50.7
3.21
53.7
3.18
48.4
3.14
51.2
3.11
54.4
3.07
45.8
3.72
48.5
3.71
51.3
3.68
46.1
3.63
48.9
3.60
51.8
3.58
46.5
3.54
49.4
3.50
52.2
3.47
EER
27.5
29.8
32.3
29.4
32.0
34.8
31.4
34.3
37.7
23.2
25.2
27.2
24.7
26.9
29.2
26.4
28.8
31.5
19.4
21.0
22.8
20.6
22.4
24.4
21.9
23.9
26.1
16.1
17.5
18.9
17.1
18.6
20.2
18.1
19.8
21.6
14.7
15.9
17.3
15.5
16.9
18.3
16.4
17.9
19.6
13.4
14.5
15.7
14.1
15.3
16.7
14.9
16.2
17.7
11.1
12.0
13.0
11.6
12.6
13.6
12.2
13.3
14.5
9.1
9.9
10.7
9.5
10.4
11.3
10.0
10.9
11.8
Entering Pressure Entering
Total
Heat of
Power
Fluid Temp Drop PSI Air Temp Capacity Absorption Input COP
(F)
(FOH)
(F)
(MBtuh)
(MBtuh)
(kW)
60
33.6
25.2
2.56
3.8
1.3
70
32.4
22.8
2.85
3.3
(3.0)
80
31.2
20.6
3.17
2.9
60
34.5
26.0
2.57
3.9
2.2
30
70
33.1
23.8
2.86
3.4
(5.0)
80
31.9
21.4
3.18
2.9
60
35.5
27.0
2.57
4.0
4.5
70
34.4
24.3
2.87
3.5
(10.4)
80
32.7
22.2
3.19
3.0
60
38.4
29.8
2.59
4.3
1.3
70
37.1
27.5
2.89
3.8
(2.9)
80
35.8
25.2
3.22
3.3
60
39.5
31.0
2.60
4.5
2.1
40
70
38.1
28.6
2.90
3.9
(4.9)
80
36.7
26.2
3.23
3.3
60
40.8
32.2
2.61
4.6
4.4
70
39.2
29.6
2.91
4.0
(10.9)
80
38.0
27.0
3.24
3.4
60
43.6
34.9
2.62
4.9
1.2
70
42.2
32.4
2.93
4.2
(2.8)
80
41.0
29.9
3.26
3.7
60
45.0
36.3
2.63
5.0
2.0
50
70
43.5
33.6
2.93
4.3
(4.7)
80
42.0
31.3
3.27
3.8
60
46.5
38.0
2.63
5.2
4.2
70
45.4
34.8
2.94
4.5
(9.7)
80
43.4
32.1
3.28
3.9
60
49.1
40.4
2.64
5.5
1.2
70
47.6
37.8
2.96
4.7
(2.7)
80
46.3
35.0
3.30
4.1
60
51.2
41.8
2.64
5.7
2.0
60
70
49.6
39.0
2.96
4.9
(4.5)
80
47.7
36.3
3.31
4.2
60
52.6
44.1
2.65
5.8
4.1
70
51.3
40.6
2.97
5.1
(9.4)
80
49.1
38.4
3.32
4.3
60
55.4
45.9
2.65
6.1
1.1
70
53.8
43.1
2.98
5.3
(2.6)
80
51.7
40.7
3.34
4.5
60
57.3
47.8
2.66
6.3
1.9
70
70
55.5
44.9
2.99
5.5
(4.4)
80
53.5
41.8
3.35
4.7
60
59.5
49.9
2.66
6.6
3.9
70
57.5
46.7
2.99
5.6
(9.1)
80
55.7
43.5
3.36
4.9
60
61.3
51.9
2.66
6.8
1.1
70
59.6
48.9
3.00
5.8
(2.5)
80
57.4
46.2
3.37
5.0
60
63.6
54.1
2.66
7.0
1.8
80
70
61.1
51.3
3.00
6.0
(4.2)
80
59.4
47.6
3.38
5.2
60
66.0
56.5
2.66
7.3
3.8
70
63.8
53.0
3.01
6.2
(8.8)
80
61.8
49.6
3.38
5.4
Operation Not Recommended
50PTH,PTV060
2,000 CFM AT 0.60-in. ESP — FULL LOAD
HEATING
COOLING
Entering Water Pressure Entering
Fluid
Flow Drop PSI Air Temp
Temp (F) (GPM) (FOH) (db/wb) F
75/63
1.2
7.5
80/67
(2.8)
85/71
75/63
2.0
50
10.0
80/67
(4.7)
85/71
75/63
4.2
15.0
80/67
(9.7)
85/71
75/63
1.1
7.5
80/67
(2.6)
85/71
75/63
1.9
60
10.0
80/67
(4.4)
85/71
75/63
3.9
15.0
80/67
(9.1)
85/71
75/63
1.1
7.5
80/67
(2.6)
85/71
75/63
1.9
70
10.0
80/67
(4.4)
85/71
75/63
3.9
15.0
80/67
(9.1)
85/71
75/63
1.1
7.5
80/67
(2.5)
85/71
75/63
1.8
80
10.0
80/67
(4.2)
85/71
75/63
3.8
15.0
80/67
(8.8)
85/71
75/63
1.1
7.5
80/67
(2.5)
85/71
75/63
1.8
85
10.0
80/67
(4.2)
85/71
75/63
3.7
15.0
80/67
(8.5)
85/71
75/63
1.0
7.5
80/67
(2.4)
85/71
75/63
1.8
90
10.0
80/67
(4.1)
85/71
75/63
3.7
15.0
80/67
(8.5)
85/71
75/63
1.0
7.5
80/67
(2.4)
85/71
75/63
1.7
100
10.0
80/67
(4.0)
85/71
75/63
3.6
15.0
80/67
(8.3)
85/71
75/63
1.0
7.5
80/67
(2.3)
85/71
75/63
1.7
10.0
110
80/67
(3.9)
85/71
75/63
3.5
15.0
80/67
(8.0)
85/71
Total
Capacity
(MBtuh)
66.6
71.0
75.5
68.0
72.5
77.3
69.5
74.1
79.2
63.9
68.1
72.4
65.3
69.6
74.3
66.6
71.3
76.0
61.0
65.1
69.3
62.3
66.6
71.1
63.7
68.1
72.6
58.1
62.1
66.0
59.3
63.4
67.6
60.7
64.9
69.3
56.6
60.5
64.4
57.9
61.8
66.0
59.0
63.1
67.6
55.1
58.9
62.7
56.3
60.1
64.3
57.4
61.5
65.7
52.0
55.6
59.2
53.1
56.8
60.7
54.2
58.0
62.2
48.9
52.2
55.6
49.9
53.4
57.0
50.9
54.5
58.3
Sensible
Capacity
(MBtuh)
50.5
52.0
53.4
51.1
52.7
54.1
51.8
53.3
54.6
49.4
51.0
52.3
50.0
51.6
52.8
50.6
52.0
53.5
48.2
49.8
51.2
48.8
50.4
51.6
49.2
50.8
52.4
47.0
48.4
50.0
47.5
49.1
50.6
47.9
49.5
51.0
46.4
47.8
49.4
46.8
48.5
49.8
47.4
49.0
50.4
45.7
47.4
48.8
46.1
47.9
49.2
46.7
48.4
49.9
44.5
46.1
47.6
44.9
46.6
48.0
45.4
47.1
48.4
43.2
44.9
46.4
43.6
45.3
46.9
43.8
45.7
47.3
Heat of
Power
Rejection Input
(MBtuh)
(kW)
77.1
3.15
81.7
3.21
86.4
3.27
78.1
3.04
82.8
3.09
87.8
3.15
79.2
2.93
84.1
2.98
89.4
3.04
75.1
3.40
79.4
3.45
84.0
3.50
76.1
3.27
80.6
3.32
85.5
3.37
77.0
3.15
81.9
3.20
86.8
3.24
73.0
3.67
77.3
3.72
81.7
3.78
73.9
3.54
78.4
3.58
83.1
3.63
75.0
3.42
79.5
3.45
84.2
3.49
71.1
4.00
75.4
4.05
79.5
4.10
71.9
3.86
76.2
3.89
80.6
3.93
72.9
3.72
77.3
3.75
81.8
3.78
70.2
4.18
74.4
4.23
78.4
4.27
71.1
4.04
75.1
4.07
79.6
4.11
71.7
3.89
76.0
3.92
80.6
3.95
69.3
4.37
73.3
4.42
77.3
4.47
70.1
4.23
74.1
4.26
78.4
4.30
70.7
4.08
74.9
4.10
79.3
4.13
67.6
4.80
71.4
4.85
75.2
4.89
68.2
4.65
72.1
4.68
76.2
4.72
68.8
4.50
72.8
4.52
77.1
4.55
66.1
5.30
69.6
5.34
73.2
5.39
66.5
5.13
70.2
5.17
74.0
5.20
67.2
4.99
70.8
5.00
74.7
5.02
EER
21.1
22.1
23.1
22.4
23.4
24.5
23.7
24.9
26.1
18.8
19.8
20.7
19.9
21.0
22.0
21.1
22.3
23.4
16.6
17.5
18.4
17.6
18.6
19.6
18.6
19.7
20.8
14.5
15.3
16.1
15.4
16.3
17.2
16.3
17.3
18.3
13.5
14.3
15.1
14.3
15.2
16.1
15.1
16.1
17.1
12.6
13.3
14.0
13.3
14.1
15.0
14.1
15.0
15.9
10.8
11.5
12.1
11.4
12.1
12.9
12.0
12.8
13.7
9.2
9.8
10.3
9.7
10.3
11.0
10.2
10.9
11.6
Entering Pressure Entering
Total
Heat of
Power
Fluid Temp Drop PSI Air Temp Capacity Absorption Input COP
(F)
(FOH)
(F)
(MBtuh)
(MBtuh)
(kW)
60
46.3
33.6
3.51
3.9
1.3
70
45.8
31.6
3.87
3.5
(3.0)
80
45.2
29.7
4.25
3.1
60
47.3
35.4
3.54
3.9
2.2
30
70
47.2
32.8
3.90
3.6
(5.0)
80
45.8
31.2
4.28
3.1
60
49.1
36.7
3.57
4.0
4.5
70
48.0
34.8
3.93
3.6
(10.4)
80
48.0
31.9
4.31
3.3
60
52.6
39.2
3.63
4.2
1.3
70
52.9
36.5
3.99
3.9
(2.9)
80
52.2
34.5
4.38
3.5
60
54.5
40.9
3.67
4.4
2.1
40
70
53.6
38.7
4.02
3.9
(4.9)
80
52.8
36.5
4.42
3.5
60
56.0
43.2
3.71
4.4
4.4
70
54.8
40.8
4.06
4.0
(10.9)
80
54.6
38.0
4.46
3.6
60
58.8
45.8
3.76
4.6
1.2
70
57.8
43.5
4.12
4.1
(2.8)
80
56.9
41.2
4.52
3.7
60
61.0
48.5
3.81
4.7
2.0
50
70
60.6
45.2
4.17
4.3
(4.7)
80
59.6
42.7
4.57
3.8
60
63.6
50.5
3.86
4.8
4.2
70
63.1
47.2
4.22
4.4
(9.7)
80
61.8
44.5
4.62
3.9
60
67.6
51.7
3.90
5.1
1.2
70
66.5
49.2
4.27
4.6
(2.7)
80
63.7
48.1
4.69
4.0
60
69.4
54.8
3.96
5.1
2.0
60
70
68.0
52.1
4.33
4.6
(4.5)
80
68.0
48.2
4.74
4.2
60
71.8
58.1
4.02
5.2
4.1
70
70.1
55.1
4.39
4.7
(9.4)
80
69.5
51.5
4.80
4.2
60
74.2
59.4
4.06
5.4
1.1
70
72.8
56.6
4.43
4.8
(2.6)
80
71.6
53.8
4.85
4.3
60
77.5
62.3
4.12
5.5
1.9
70
70
77.0
58.1
4.50
5.0
(4.4)
80
75.6
55.0
4.92
4.5
60
80.4
66.2
4.20
5.6
3.9
70
78.4
62.7
4.58
5.0
(9.1)
80
76.8
59.4
5.00
4.5
60
82.1
66.8
4.22
5.7
1.1
70
80.5
63.7
4.61
5.1
(2.5)
80
79.0
60.5
5.04
4.6
60
85.9
70.1
4.31
5.8
1.8
80
70
84.0
66.7
4.69
5.3
(4.2)
80
82.2
63.3
5.12
4.7
60
89.3
74.5
4.40
5.9
3.8
70
87.1
71.6
4.79
5.3
(8.8)
80
85.7
66.2
5.22
4.8
Operation Not Recommended
21
Performance data (cont)
50PTH,PTV070
1,850 CFM AT 0.60-in. ESP — PART LOAD
HEATING
COOLING
Entering Water Pressure Entering
Fluid
Flow Drop PSI Air Temp
Temp (F) (GPM) (FOH) (db/wb) F
75/63
0.9
9
80/67
(2.1)
85/71
75/63
1.5
50
12
80/67
(3.5)
85/71
75/63
3.2
18
80/67
(7.3)
85/71
75/63
0.9
9
80/67
(2.0)
85/71
75/63
1.5
60
12
80/67
(3.4)
85/71
75/63
3.1
18
80/67
(7.1)
85/71
75/63
0.9
9
80/67
(2.0)
85/71
75/63
1.4
70
12
80/67
(3.3)
85/71
75/63
3.0
18
80/67
(6.9)
85/71
75/63
0.8
9
80/67
(1.9)
85/71
75/63
1.4
80
12
80/67
(3.2)
85/71
75/63
2.9
18
80/67
(6.6)
85/71
75/63
0.8
9
80/67
(1.9)
85/71
75/63
1.3
85
12
80/67
(3.1)
85/71
75/63
2.8
18
80/67
(6.5)
85/71
75/63
0.8
9
80/67
(1.8)
85/71
75/63
1.3
90
12
80/67
(3.1)
85/71
75/63
2.8
18
80/67
(6.4)
85/71
75/63
0.8
9
80/67
(1.8)
85/71
75/63
1.3
100
12
80/67
(3.0)
85/71
75/63
2.7
18
80/67
(6.2)
85/71
75/63
0.7
9
80/67
(1.7)
85/71
75/63
1.3
12
110
80/67
(2.9)
85/71
75/63
2.6
18
80/67
(6.1)
85/71
22
Total
Capacity
(MBtuh)
58.8
62.6
66.6
59.9
63.9
68.2
61.1
65.3
69.6
56.0
59.7
63.6
57.1
61.1
65.1
58.3
62.3
66.4
53.2
56.8
60.7
54.3
58.1
62.0
55.4
59.2
63.2
50.4
53.8
57.4
51.3
54.9
58.6
52.4
56.1
59.9
48.9
52.2
55.9
49.9
53.3
57.1
50.8
54.5
58.2
47.5
50.7
54.2
48.3
51.8
55.4
49.3
52.9
56.5
44.4
47.6
51.0
45.3
48.6
52.0
46.1
49.5
53.1
41.2
44.5
47.7
42.2
45.4
48.8
42.9
46.2
49.8
Sensible
Capacity
(MBtuh)
45.7
47.1
48.4
46.2
47.7
48.8
46.7
48.1
49.4
44.6
46.0
47.4
45.0
46.4
47.7
45.5
47.0
48.4
43.4
44.9
46.1
43.7
45.2
46.6
44.2
45.8
47.2
42.1
43.7
45.1
42.6
44.2
45.6
43.0
44.5
46.0
41.5
43.1
44.4
41.9
43.6
44.9
42.4
43.9
45.4
40.9
42.6
44.0
41.4
42.8
44.3
41.7
43.3
44.8
39.7
41.4
43.0
40.1
41.6
43.3
40.5
42.1
43.7
38.6
40.3
41.9
38.8
40.6
42.2
39.2
40.9
42.5
Heat of
Power
Rejection Input
(MBtuh)
(kW)
66.3
2.28
70.1
2.27
74.1
2.27
67.1
2.18
71.0
2.16
75.3
2.15
68.0
2.07
72.1
2.05
76.4
2.02
64.3
2.54
68.1
2.54
72.0
2.54
65.1
2.43
69.0
2.42
73.1
2.41
65.9
2.33
69.9
2.30
74.0
2.28
62.4
2.84
66.1
2.84
70.0
2.85
63.2
2.73
67.0
2.72
70.9
2.71
63.9
2.61
67.7
2.60
71.7
2.58
60.7
3.18
64.1
3.18
67.8
3.19
61.2
3.06
64.8
3.06
68.6
3.05
61.9
2.94
65.7
2.93
69.4
2.91
59.8
3.37
63.2
3.37
66.9
3.38
60.3
3.24
63.8
3.24
67.6
3.24
60.9
3.12
64.6
3.11
68.3
3.10
58.9
3.56
62.2
3.57
65.8
3.58
59.4
3.44
62.9
3.44
66.6
3.44
60.0
3.31
63.6
3.30
67.2
3.29
57.3
3.99
60.5
4.00
63.9
3.99
57.7
3.87
61.1
3.87
64.5
3.85
58.1
3.74
61.5
3.73
65.1
3.71
55.6
4.47
58.9
4.46
62.1
4.45
56.2
4.35
59.4
4.33
62.7
4.31
56.5
4.22
59.8
4.19
63.3
4.17
EER
25.7
27.5
29.4
27.5
29.5
31.8
29.4
31.9
34.4
22.0
23.5
25.0
23.4
25.2
27.0
25.1
27.0
29.1
18.7
20.0
21.3
19.9
21.3
22.8
21.2
22.8
24.5
15.8
16.9
18.0
16.8
18.0
19.2
17.8
19.2
20.6
14.5
15.5
16.5
15.4
16.4
17.6
16.3
17.5
18.8
13.3
14.2
15.1
14.0
15.1
16.1
14.9
16.0
17.2
11.1
11.9
12.8
11.7
12.6
13.5
12.3
13.3
14.3
9.2
10.0
10.7
9.7
10.5
11.3
10.2
11.0
11.9
Entering Pressure Entering
Total
Heat of
Power
Fluid Temp Drop PSI Air Temp Capacity Absorption Input COP
(F)
(FOH)
(F)
(MBtuh)
(MBtuh)
(kW)
60
39.9
29.3
3.05
3.8
1.0
70
39.5
26.9
3.39
3.4
(2.3)
80
38.8
25.8
3.78
3.0
60
41.5
25.9
3.05
4.0
1.6
30
70
40.3
29.6
3.40
3.5
(3.8)
80
39.3
23.9
3.78
3.0
60
41.7
33.0
3.07
4.0
3.4
70
41.1
29.1
3.41
3.5
(7.9)
80
40.0
27.3
3.80
3.1
60
45.1
35.0
3.09
4.3
0.9
70
45.4
23.5
3.41
3.9
(2.2)
80
41.0
36.0
3.82
3.1
60
46.8
36.0
3.10
4.4
1.6
40
70
46.3
27.9
3.44
4.0
(3.7)
80
45.2
29.5
3.84
3.5
60
49.2
32.8
3.11
4.6
3.3
70
46.4
35.5
3.46
3.9
(7.6)
80
46.3
32.4
3.85
3.5
60
51.3
41.1
3.13
4.8
0.9
70
50.1
38.8
3.49
4.2
(2.1)
80
50.1
36.3
3.89
3.8
60
53.3
42.5
3.14
5.0
1.5
50
70
53.6
29.9
3.48
4.5
(3.5)
80
52.0
29.2
3.88
3.9
60
56.6
36.6
3.14
5.3
3.2
70
54.9
35.8
3.51
4.6
(7.3)
80
51.4
40.1
3.92
3.8
60
58.2
47.3
3.17
5.4
0.9
70
56.8
44.6
3.54
4.7
(2.0)
80
55.8
41.9
3.95
4.1
60
60.4
49.3
3.19
5.6
1.5
60
70
59.1
46.8
3.56
4.9
(3.4)
80
53.4
55.4
3.97
3.9
60
64.5
36.4
3.17
6.0
3.1
70
62.5
39.4
3.56
5.1
(7.1)
80
59.8
40.5
3.98
4.4
60
65.2
54.3
3.22
5.9
0.9
70
63.7
51.4
3.61
5.2
(2.0)
80
63.7
49.9
4.05
4.6
60
67.6
57.3
3.24
6.1
1.4
70
70
66.5
53.6
3.63
5.4
(3.3)
80
65.9
51.7
4.07
4.7
60
73.6
39.7
3.21
6.7
3.0
70
70.6
41.8
3.62
5.7
(6.9)
80
64.7
64.5
4.09
4.6
60
72.6
61.5
3.27
6.5
0.8
70
70.9
58.1
3.67
5.7
(1.9)
80
69.3
55.1
4.11
4.9
60
75.6
64.2
3.29
6.7
1.4
80
70
73.7
60.7
3.70
5.8
(3.2)
80
60.8
93.6
4.14
4.3
60
79.3
67.6
3.32
7.0
2.9
70
77.5
63.6
3.73
6.1
(6.6)
80
77.0
40.6
4.11
5.5
Operation Not Recommended
50PTH,PTV070
2,350 CFM AT 0.60-in. ESP — FULL LOAD
HEATING
COOLING
Entering Water Pressure Entering
Fluid
Flow Drop PSI Air Temp
Temp (F) (GPM) (FOH) (db/wb) F
75/63
0.9
9
80/67
(2.1)
85/71
75/63
1.5
50
12
80/67
(3.5)
85/71
75/63
3.2
18
80/67
(7.3)
85/71
75/63
0.9
9
80/67
(2.0)
85/71
75/63
1.5
60
12
80/67
(3.4)
85/71
75/63
3.1
18
80/67
(7.1)
85/71
75/63
0.9
9
80/67
(2.0)
85/71
75/63
1.4
70
12
80/67
(3.3)
85/71
75/63
3.0
18
80/67
(6.9)
85/71
75/63
0.8
9
80/67
(1.9)
85/71
75/63
1.4
80
12
80/67
(3.2)
85/71
75/63
2.9
18
80/67
(6.6)
85/71
75/63
0.8
9
80/67
(1.9)
85/71
75/63
1.3
85
12
80/67
(3.1)
85/71
75/63
2.8
18
80/67
(6.5)
85/71
75/63
0.8
9
80/67
(1.8)
85/71
75/63
1.3
90
12
80/67
(3.1)
85/71
75/63
2.8
18
80/67
(6.4)
85/71
75/63
0.8
9
80/67
(1.8)
85/71
75/63
1.3
100
12
80/67
(3.0)
85/71
75/63
2.7
18
80/67
(6.2)
85/71
75/63
0.7
9
80/67
(1.7)
85/71
75/63
1.3
12
110
80/67
(2.9)
85/71
75/63
2.6
18
80/67
(6.1)
85/71
Total
Capacity
(MBtuh)
74.5
79.5
84.7
76.2
81.5
86.8
78.0
83.5
89.2
71.4
76.4
81.5
73.0
78.1
83.3
74.8
80.1
85.6
68.3
72.9
77.8
69.7
74.8
79.9
71.4
76.4
81.9
65.0
69.6
73.9
66.5
71.2
76.1
67.9
72.9
77.9
63.5
67.7
72.2
64.9
69.4
74.2
66.2
71.1
75.9
61.8
65.9
70.4
63.3
67.3
72.1
64.5
69.0
74.1
58.2
62.6
66.6
59.5
63.9
68.2
61.0
65.3
69.9
54.9
58.7
62.6
56.0
60.1
64.3
57.4
61.5
65.9
Sensible
Capacity
(MBtuh)
56.1
58.0
59.6
56.8
58.4
60.4
57.6
59.2
60.9
54.9
56.4
58.0
55.6
57.4
59.1
56.0
57.8
59.5
53.3
55.4
57.1
54.2
55.7
57.4
54.9
56.8
58.1
52.3
53.7
56.4
52.5
54.4
56.0
53.4
55.0
57.2
51.3
53.4
55.2
51.9
53.6
55.4
52.7
54.3
56.4
50.9
53.1
54.4
51.1
53.9
55.1
52.0
53.9
55.3
50.1
51.3
53.3
50.5
52.0
54.0
50.6
52.5
54.3
48.3
50.1
52.1
49.0
50.6
52.3
49.0
51.1
52.7
Heat of
Power
Rejection Input
(MBtuh)
(kW)
86.7
3.68
91.9
3.73
97.3
3.79
87.9
3.53
93.4
3.57
98.9
3.62
89.2
3.37
94.9
3.41
100.8
3.45
84.5
3.98
89.7
4.03
95.0
4.07
85.6
3.82
90.8
3.86
96.3
3.90
86.9
3.67
92.4
3.69
98.1
3.73
82.5
4.31
87.2
4.34
92.3
4.39
83.4
4.14
88.6
4.18
93.8
4.21
84.5
3.98
89.7
4.00
95.3
4.03
80.3
4.66
85.0
4.71
89.5
4.75
81.3
4.51
86.1
4.54
91.2
4.57
82.1
4.34
87.3
4.36
92.4
4.38
79.4
4.86
83.8
4.90
88.5
4.95
80.3
4.69
85.0
4.73
89.9
4.76
81.0
4.53
86.0
4.55
91.0
4.57
78.3
5.06
82.6
5.10
87.4
5.16
79.3
4.90
83.5
4.92
88.4
4.97
79.9
4.73
84.7
4.75
89.8
4.78
76.2
5.51
80.8
5.56
85.0
5.61
76.9
5.33
81.5
5.37
85.9
5.41
77.9
5.17
82.4
5.19
87.0
5.21
74.7
6.05
78.7
6.10
82.7
6.14
75.1
5.86
79.4
5.89
83.7
5.93
75.9
5.68
80.1
5.70
84.7
5.72
EER
20.2
21.3
22.4
21.6
22.8
24.0
23.1
24.5
25.9
18.0
19.0
20.0
19.1
20.2
21.4
20.4
21.7
23.0
15.9
16.8
17.7
16.8
17.9
19.0
17.9
19.1
20.3
13.9
14.8
15.6
14.8
15.7
16.7
15.7
16.7
17.8
13.1
13.8
14.6
13.8
14.7
15.6
14.6
15.6
16.6
12.2
12.9
13.6
12.9
13.7
14.5
13.6
14.5
15.5
10.6
11.2
11.9
11.2
11.9
12.6
11.8
12.6
13.4
9.1
9.6
10.2
9.5
10.2
10.8
10.1
10.8
11.5
Entering Pressure Entering
Total
Heat of
Power
Fluid Temp Drop PSI Air Temp Capacity Absorption Input COP
(F)
(FOH)
(F)
(MBtuh)
(MBtuh)
(kW)
60
52.5
38.1
4.16
3.7
1.0
70
51.6
35.9
4.56
3.3
(2.3)
80
51.9
33.7
4.99
3.0
60
54.0
39.4
4.20
3.8
1.6
30
70
54.0
37.3
4.59
3.4
(3.8)
80
52.9
34.2
5.02
3.1
60
55.8
41.6
4.23
3.9
3.4
70
55.3
38.1
4.63
3.5
(7.9)
80
54.4
37.2
5.07
3.1
60
59.7
44.6
4.29
4.1
0.9
70
59.0
42.5
4.70
3.7
(2.2)
80
57.8
40.1
5.14
3.3
60
61.6
46.5
4.33
4.2
1.6
40
70
60.7
44.3
4.74
3.8
(3.7)
80
59.8
42.1
5.19
3.4
60
64.2
49.1
4.38
4.3
3.3
70
63.0
47.1
4.79
3.9
(7.6)
80
61.5
43.6
5.23
3.4
60
67.2
52.0
4.43
4.4
0.9
70
66.4
49.8
4.85
4.0
(2.1)
80
65.8
47.6
5.31
3.6
60
70.4
54.6
4.48
4.6
1.5
50
70
68.2
51.4
4.89
4.1
(3.5)
80
68.9
48.7
5.36
3.8
60
73.2
57.9
4.54
4.7
3.2
70
72.6
54.0
4.96
4.3
(7.3)
80
70.3
51.9
5.42
3.8
60
75.6
59.6
4.58
4.8
0.9
70
74.5
57.0
5.01
4.4
(2.0)
80
73.6
54.4
5.49
3.9
60
79.3
63.0
4.65
5.0
1.5
60
70
77.9
60.0
5.08
4.5
(3.4)
80
76.0
56.7
5.55
4.0
60
82.7
66.8
4.73
5.1
3.1
70
78.9
61.3
5.12
4.5
(7.1)
80
79.4
60.0
5.62
4.1
60
84.6
68.0
4.75
5.2
0.9
70
82.6
64.6
5.18
4.7
(2.0)
80
81.8
61.7
5.67
4.2
60
88.5
72.1
4.84
5.4
1.4
70
70
86.9
69.1
5.27
4.8
(3.3)
80
85.4
65.1
5.75
4.4
60
93.3
76.1
4.93
5.6
3.0
70
91.2
72.3
5.36
5.0
(6.9)
80
89.3
68.4
5.84
4.5
60
93.8
76.6
4.94
5.6
0.8
70
92.1
73.3
5.38
5.0
(1.9)
80
90.6
69.9
5.87
4.5
60
98.4
80.9
5.03
5.7
1.4
80
70
96.4
77.2
5.47
5.2
(3.2)
80
94.5
73.9
5.96
4.6
60
103.7
85.8
5.14
5.9
2.9
70
101.4
81.8
5.57
5.3
(6.6)
80
99.1
77.2
6.06
4.8
Operation Not Recommended
23
Performance data (cont)
ANTIFREEZE CORRECTION TABLE
ANTIFREEZE
TYPE
ANTIFREEZE %
Total Capacity
1.000
0.997
0.994
0.990
0.983
0.997
0.996
0.994
0.998
0.996
0.992
0.986
0.997
0.995
0.992
0.988
0.985
0
5
10
15
25
5
10
15
5
10
15
25
5
10
15
25
30
Propylene
Glycol
Methanol
Ethanol
Ethylene Glycol
COOLING
HEATING
EWT 90 F
EWT 30 F
Sensible Capacity
1.000
0.997
0.994
0.990
0.983
0.997
0.996
0.994
0.998
0.996
0.992
0.986
0.997
0.995
0.992
0.988
0.985
kW
1.000
1.004
1.006
1.009
1.016
1.003
1.005
1.008
1.002
1.004
1.006
1.009
1.003
1.004
1.005
1.009
1.012
Heating Capacity
1.000
0.989
0.986
0.978
0.960
0.990
0.979
0.970
0.981
0.960
0.944
0.917
0.993
0.986
0.980
0.970
0.965
WPD
CORRECTION
FACTOR
EWT 30 F
1.000
1.060
1.125
1.190
1.300
1.060
1.100
1.140
1.160
1.230
1.280
1.400
1.060
1.120
1.190
1.330
1.400
kW
1.000
0.997
0.995
0.988
0.979
0.997
0.993
0.990
0.994
0.988
0.983
0.974
0.998
0.996
0.993
0.990
0.987
LEGEND
EWT — Entering Water Temperature
WPD — Water Pressure Differential
CONSTANT TORQUE MOTOR BLOWER PERFORMANCE DATA
50PTH,
PTV
UNITS
024
036
048
060
070
FAN
SPEED
5
4
3
2
1
5
4
3
2
1
5
4
3
2
1
5
4
3
2
1
5
4
3
2
1
RATED
AIRFLOW
(Cfm)
950
825
725
650
500
1300
1100
950
800
750
1800
1600
1400
1300
1100
2200
2000
1800
1600
1400
2500
2350
2100
1850
1600
LEGEND
— — Operation Not Recommended
24
0.10
1,154
0.20
1,117
0.30
1,077
0.40
1,034
AIRFLOW (Cfm)
External Static Pressure (in. wg)
0.50
0.60
0.70
0.80
988
938
886
830
1,072
976
906
829
1,506
1,425
1,354
1,294
1,213
1,950
1,774
1,565
1,506
1,425
2,476
2,170
1,942
1,766
1,561
2,723
2,566
2,256
2,004
1,766
1,018
920
844
750
1,469
1,326
1,233
1,157
1,084
1,912
1,738
1,526
1,469
1,326
2,403
2,135
1,914
1,729
1,520
2,671
2,529
2,230
1,975
1,728
966
867
785
676
1,430
1,250
1,138
1,041
976
1,880
1,703
1,493
1,430
1,250
2,338
2,100
1,886
1,693
1,483
2,622
2,489
2,202
1,945
1,693
915
815
730
610
1,390
1,191
1,063
946
886
1,852
1,669
1,463
1,390
1,191
2,283
2,066
1,858
1,660
1,451
2,578
2,446
2,171
1,915
1,660
866
766
678
551
1,347
1,143
1,002
866
812
1,826
1,635
1,432
1,347
1,143
2,237
2,033
1,829
1,629
1,423
2,537
2,399
2,137
1,883
1,629
FACTORY
SETTING
FL
PL/Fan Only
FL
PL/Fan Only
FL
PL/Fan Only
FL
PL/Fan Only
FL
PL/Fan Only
818
719
630
498
1,300
1,100
950
800
750
1,800
1,600
1,400
1,300
1,100
2,200
2,000
1,800
1,600
1,400
2,500
2,350
2,100
1,850
1,600
772
674
585
451
1,249
1,056
901
744
698
1,771
1,562
1,363
1,249
1,056
2,172
1,968
1,770
1,573
1,381
2,467
2,298
2,060
1,816
1,573
727
631
544
412
1,193
1,006
850
696
653
1,737
1,521
1,319
1,193
1,006
2,153
1,937
1,741
1,548
1,366
2,437
2,242
2,017
1,781
1,548
0.90
—
—
—
—
—
1.00
—
—
—
—
—
1,130
942
791
653
612
1,695
1,475
1,265
1,130
942
2,142
1,907
1,710
1,526
1,356
2,412
2,184
1,971
1,745
1,526
1,061
860
719
611
573
1,644
1,423
1,199
1,061
860
2,141
1,877
1,680
1,505
1,350
2,390
2,122
1,922
1,708
1,505
1.10
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
1.20
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
2,149
1,848
1,649
1,487
1,349
2,372
2,057
1,871
1,669
1,486
2,166
1,819
1,617
1,470
1,352
2,358
1,990
1,816
1,630
1,470
ECM CONSTANT CFM MOTOR BLOWER PERFORMANCE DATA
50PTH,
PTV
UNITS
024
PART
LOAD
024
FULL
LOAD
036
PART
LOAD
036
FULL
LOAD
048
PART
LOAD
048
FULL
LOAD
060
PART
LOAD
060
FULL
LOAD
070
PART
LOAD
070
FULL
LOAD
0.30
AIRFLOW (Cfm)
External Static Pressure (in. wg)
0.40
0.50
0.60
0.70
0.80
0.90
1.00
725
725
725
725
725
725
—
—
650
650
650
650
650
650
650
—
—
500
500
500
500
500
500
500
500
—
—
A
950
950
950
950
950
950
950
950
—
—
Normal
A
825
825
825
825
825
825
825
825
—
—
+
A
725
725
725
725
725
725
725
725
—
—
High
725
950
A
950
950
950
950
950
950
950
950
950
950
Med
800
Normal
A
800
800
800
800
800
800
800
800
800
800
Low
+
A
750
750
750
750
750
750
750
750
750
750
High
750
1300
A
1,300
1,300
1,300
1,300
1,300
1,300
1,300
1,300
1,300
1,300
Med
1100
Normal
A
1,100
1,100
1,100
1,100
1,100
1,100
1,100
1,100
1,100
1,100
Low
+
A
950
950
950
950
950
950
950
950
950
950
High
950
1400
A
1,400
1,400
1,400
1,400
1,400
1,400
1,400
1,400
1,400
1,400
Med
1300
Normal
A
1,300
1,300
1,300
1,300
1,300
1,300
1,300
1,300
1,300
1,300
Low
+
A
1,100
1,100
1,100
1,100
1,100
1,100
1,100
1,100
1,100
1,100
High
1100
1800
A
1,800
1,800
1,800
1,800
1,800
1,800
1,800
1,800
1,800
1,800
Med
1600
Normal
A
1,600
1,600
1,600
1,600
1,600
1,600
1,600
1,600
1,600
1,600
Low
+
A
1,400
1,400
1,400
1,400
1,400
1,400
1,400
1,400
1,400
1,400
High
1400
1800
A
1,800
1,800
1,800
1,800
1,800
1,800
1,800
1,800
1,800
1,800
Med
1600
Normal
A
1,600
1,600
1,600
1,600
1,600
1,600
1,600
1,600
1,600
1,600
Low
1400
2200
+
A
1,400
1,400
1,400
1,400
1,400
1,400
1,400
1,400
1,400
1,400
A
2,200
2,200
2,200
2,200
2,200
2,200
2,200
2,200
2,200
2,200
Med
2000
Normal
A
2,000
2,000
2,000
2,000
2,000
2,000
2,000
2,000
2,000
2,000
Low
+
A
1,800
1,800
1,800
1,800
1,800
1,800
1,800
1,800
1,800
1,800
High
18000
2100
A
2,100
2,100
2,100
2,100
2,100
2,100
2,100
2,100
2,100
2,100
Med
1850
Normal
A
1,850
1,850
1,850
1,850
1,850
1,850
1,850
1,850
1,850
1,850
Low
+
A
1,600
1,600
1,600
1,600
1,600
1,600
1,600
1,600
1,600
1,600
High
1600
2500
A
2,500
2,500
2,500
2,500
2,500
2,500
2,500
2,500
2,500
2,500
Med
2350
Normal
A
2,350
2,350
2,350
2,350
2,350
2,350
2,350
2,350
2,350
2,350
Low
2100
-
A
2,100
2,100
2,100
2,100
2,100
2,100
2,100
2,100
2,100
2,100
FAN
SPEED
RATED
AIRFLOW
(Cfm)
ADJUSTMENT
TAP
0.10
0.20
High
725
+
A
725
725
Med
650
Normal
A
650
Low
+
A
High
500
950
Med
825
Low
High
LEGEND
— — Operation Not Recommended
25
Performance data (cont)
50PTH,PTV SOUND DATA
Octave Band Sound Power Levels dB, re 10-12 Watts
Center Frequency - Hz
UNIT SIZE
Casing
Radiated
024
Ducted
Discharge
Casing
Radiated
036
Ducted
Discharge
Casing
Radiated
048
Ducted
Discharge
Casing
Radiated
060
Ducted
Discharge
Casing
Radiated
070
Ducted
Discharge
26
Load
Cooling Part
Cooling Full
Heating Part
Heating Full
FAN Only
Cooling Part
Cooling Full
Heating Part
Heating Full
FAN Only
Cooling Part
Cooling Full
Heating Part
Heating Full
FAN Only
Cooling Part
Cooling Full
Heating Part
Heating Full
FAN Only
Cooling Part
Cooling Full
Heating Part
Heating Full
FAN Only
Cooling Part
Cooling Full
Heating Part
Heating Full
FAN Only
Cooling Part
Cooling Full
Heating Part
Heating Full
FAN Only
Cooling Part
Cooling Full
Heating Part
Heating Full
FAN Only
Cooling Part
Cooling Full
Heating Part
Heating Full
FAN Only
Cooling Part
Cooling Full
Heating Part
Heating Full
FAN Only
63
125
250
500
1000
2000
4000
8000
79
80
74
74
73
75
76
77
77
75
75
75
74
73
66
78
89
79
80
79
75
77
77
76
69
82
88
81
83
86
82
79
76
82
71
89
94
88
94
87
82
80
75
77
73
92
97
92
96
93
66
63
66
65
61
67
68
67
70
67
61
65
60
66
53
65
71
65
68
66
69
75
69
75
56
70
75
69
74
70
66
72
67
74
60
73
79
74
79
73
68
72
71
74
63
78
83
79
82
79
60
60
59
61
56
60
62
60
62
60
53
55
52
57
48
56
59
56
59
56
56
60
58
69
56
59
64
60
64
60
58
62
62
63
57
63
68
63
68
63
61
63
63
64
61
67
72
68
73
68
54
54
54
53
51
67
68
65
68
66
50
52
50
51
45
61
63
61
63
61
52
53
52
53
49
63
67
64
67
63
55
58
57
58
53
67
70
67
70
67
57
59
59
60
55
69
72
70
73
70
53
54
52
54
48
63
65
63
65
63
45
49
44
48
42
59
62
59
62
59
50
53
51
53
48
63
66
63
66
62
51
55
52
56
49
63
68
64
68
64
52
54
52
55
51
68
73
69
74
69
44
47
43
45
43
59
61
58
61
59
39
43
38
42
36
55
59
56
59
55
43
48
43
47
43
59
64
60
64
60
45
49
47
49
44
61
66
61
66
62
49
51
48
50
49
66
70
66
70
66
38
40
38
39
38
56
58
56
59
56
34
41
33
39
29
53
57
53
58
53
36
40
35
39
35
58
62
58
63
58
42
47
47
46
39
60
66
60
66
60
44
46
44
45
44
64
69
64
69
64
31
37
31
34
30
49
52
49
53
49
31
40
30
36
24
46
51
46
52
46
32
36
31
34
27
52
58
53
58
52
37
42
47
42
29
54
61
54
61
54
36
39
40
37
42
59
64
59
64
59
A weighted A weighted
overall
overall
(dBA)
(dBA)
ARIARI260:2011
260:2001
(50 Hz(100 Hz10 kHz)
10 kHz)
59
58
59
58
58
57
58
58
54
53
68
63
70
67
67
63
70
67
67
63
53
52
56
55
53
52
56
55
48
47
64
63
68
67
64
63
67
67
64
63
57
57
62
61
58
57
63
63
53
52
67
67
72
71
68
67
71
71
68
67
59
57
62
61
60
60
63
62
55
55
70
69
75
74
70
70
75
74
70
70
61
59
62
61
61
61
63
63
58
58
74
73
78
77
74
74
79
78
74
74
Electrical data
50PTH,PTV BLOWER MOTOR ELECTRICAL DATA
UNIT SIZE
50PT024
50PT036
50PT048
50PT060
50PT070
FLA
HACR
LRA
MAX
MIN
RLA
—
—
—
—
—
—
COMPRESSOR
RATED
VOLTAGE
v-ph-Hz
VOLTAGE
MIN/MAX
8733902168
8733801381
8733801385
8733801392
8733902169
8733801382
8733801386
8733903844
8733902170
8733801387
8733801393
8733902171
8733801388
8733801394
8733902172
8733801389
8733801395
208/230-1-60
265/277-1-60
208/230-3-60
460-3-60
208/230-1-60
265/277-1-60
208/230-3-60
460-3-60
208/230-1-60
208/230-3-60
460-3-60
208/230-1-60
208/230-3-60
460-3-60
208/230-1-60
208/230-3-60
460-3-60
197/253
—
197/253
—
197/253
—
197/253
197/253
197/253
197/253
197/253
197/253
197/253
-
COMPRESSOR
QTY
RLA
LRA
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
11.7
9.1
6.5
3.5
15.3
13.0
11.6
5.7
21.2
14.0
6.4
27.1
16.5
7.2
29.7
17.6
8.5
58.3
54.0
55.4
28.0
83.0
72.0
73.0
38.0
104.0
83.1
41.0
152.9
110.0
52.0
179.2
136.0
66.1
TOTAL UNIT CONST TORQUE TOTAL UNIT ECM CONST AIR FLOW
MOTOR (STANDARD)
MOTOR (OPTION)
MIN CIRCUIT MAX FUSE/
MIN CIRCUIT MAX FUSE/
FLA
FLA
AMPS
HACR
AMPS
HACR
2.8
17.4
25
2.8
17.4
25
2.6
14.0
20
2.6
14.0
20
2.8
10.9
15
2.8
10.9
15
2.1
6.4
15
2.6
6.9
15
6.0
25.1
35
6.8
25.9
35
4.9
21.2
30
5.5
21.8
35
6.0
20.5
30
6.8
21.3
30
3.2
10.4
15
5.5
12.6
15
6.0
32.4
50
6.8
33.2
50
6.0
23.5
35
6.8
24.3
35
3.2
11.3
15
5.5
13.5
15
7.6
41.5
60
9.1
43.0
70
7.6
28.3
40
9.1
29.8
45
4.0
13.1
20
6.9
16.0
20
7.6
44.7
70
9.1
46.2
70
7.6
29.6
45
9.1
31.1
45
4.0
14.6
20
6.9
17.5
25
LEGEND
Full Load Amps
Heating, Air Conditioning and Refrigeration
Locked Rotor Amps
Maximum
Minimum
Rated Load Amps
50PTH,PTV UNITS WITH EH OPTION - CONSTANT TORQUE MOTOR ELECTRICAL DATA
UNIT SIZE EH RATED kW
024
036
048
060
070
EH
FLA
MCA
MOP
—
—
—
—
STAGE
HEATER WATTS
4.8
4.8
9.6
4.8
9.6
1
1
1
1
1
240
4,800
4,800
9,600
4,800
9,600
208
3,600
3,600
7,200
3,600
7,200
14.4
2
14,400
10,800
4.8
9.6
1
1
4,800
9,600
3,600
7,200
14.4
2
14,400
10,800
19.2
2
19,200
14,000
4.8
9.6
1
1
4,800
9,600
3,600
7,200
14.4
2
14,400
10,800
19.2
2
19,200
14,000
HEATER AMPS MOTOR FLA CIRCUIT
240
208
FUSES
(A)
20.0
17.3
2.8
—
20.0
17.3
6.0
—
40.0
34.6
6.0
—
20.0
17.3
6.0
—
40.0
34.6
6.0
—
F1/F2
60.0
51.9
6.0
F3/F4
20.0
17.3
7.6
—
40.0
34.6
7.6
—
F1/F2
60.0
51.9
7.6
F3/F4
F1/F2
80.0
69.2
7.6
F3/F4
20.0
17.3
7.6
—
40.0
34.6
7.6
—
F1/F2
60.0
51.9
7.6
F3/F4
F1/F2
80.0
69.2
7.6
F3/F4
MOP
MCA
240
28.5
32.5
57.5
32.5
57.5
208
25.1
29.1
50.8
29.1
50.8
240
30
35
60
35
60
208
30
30
60
30
60
82.5
72.4
90
80
34.5
59.5
31.1
52.8
35
60
35
60
84.5
74.4
90
80
109.5
96.0
110
100
34.5
52.8
31.1
52.8
35
60
35
60
84.5
74.4
90
80
109.5
96.0
110
100
LEGEND
Electric Heat
Full Load Amps
Minimum Circuit Amps
Maximum Overcurrent Protection
27
Electrical data (cont)
50PTH,PTV UNITS WITH ELECTRIC HEAT OPTION - CONSTANT AIRFLOW ECM MOTOR ELECTRICAL DATA
UNIT SIZE EH RATED kW
024
036
048
060
070
EH
FLA
MCA
MOP
28
—
—
—
—
STAGE
HEATER WATTS
4.8
4.8
9.6
4.8
9.6
1
1
1
1
1
240
4,800
4,800
9,600
4,800
9,600
14.4
2
14,400
10,800
4.8
9.6
1
1
4,800
9,600
3,600
7,200
14.4
2
14,400
10,800
19.2
2
19,200
14,000
4.8
9.6
1
1
4,800
9,600
3,600
7,200
14.4
2
14,400
10,800
19.2
2
19,200
14,000
LEGEND
Electric Heat
Full Load Amps
Minimum Circuit Amps
Maximum Overcurrent Protection
208
3,600
3,600
7,200
3,600
7,200
HEATER AMPS MOTOR FLA CIRCUIT
240
208
FUSES
(A)
20.0
17.3
2.8
—
20.0
17.3
6.8
—
40.0
34.6
6.8
—
20.0
17.3
6.8
—
40.0
34.6
6.8
—
6.8
F1/F2
60.0
51.9
6.8
F3/F4
20.0
17.3
9.1
—
40.0
34.6
9.1
—
F1/F2
60.0
51.9
9.1
F3/F4
F1/F2
80.0
69.2
9.1
F3/F4
20.0
17.3
9.1
—
40.0
34.6
9.1
—
F1/F2
60.0
51.9
9.1
F3/F4
F1/F2
80.0
69.2
9.1
F3/F4
MOP
MCA
240
28.5
33.5
58.5
33.5
58.5
208
25.1
30.1
51.8
30.1
51.8
240
30
35
60
35
60
208
30
35
60
35
60
83.5
73.4
90
80
36.4
61.4
33.0
54.6
40
70
35
60
86.4
76.3
90
80
111.4
97.9
125
100
36.4
61.4
33.0
54.6
40
70
35
60
86.4
76.3
90
80
111.4
97.9
125
100
Application data
Aquazone™ water source heat pump products are available
in a flexible, efficient array of models, which can be used in
all types of water loop, ground water, and ground loop systems. Utilize Aquazone products to provide optimal energy
efficient solutions and adapt to the most challenging design
requirements.
• Water Source Heat Pump Efficiency/Operational Cost
Comparison chart
• system variations such as a system without a boiler, variable pumping, and variable air volume (VAV) for interior
use
AQUAZONE PRODUCT GUIDE
To utilize Aquazone units in ground water applications, extended range should be specified. This will provide factoryinstalled insulation on the coaxial coil to prevent condensate from dripping when entering water temperatures are
below 60 F. In addition, the copper coaxial coil installed on
the Aquazone units may not be suitable for all water conditions. Refer to the Water Conditioning section for proper
coaxial coil material selection.
Surface water system — This system is typically located
near a lake or pond. In this application, the loop can be
submerged in a series of coils beneath the water surface.
The number of coils required depends on system load and
design. This application requires minimum piping and
excavation.
Open loop system — This system is used where ground
water is plentiful. In this application, ground water is
pumped through supply piping from the well to the building.
The water is then pumped back into the ground through a
discharge well as it leaves the building. An additional heat
exchanger is usually installed between the building water
piping system and the ground water piping system. This design limits the amount of piping and excavation required.
Aquazone units are provided with a standard TXV (thermostatic expansion valve) and are rated to extremely low
temperatures to self-adjust the refrigeration circuit, therefore water regulating valves are not required on open loop
systems. To conserve water on this type of system, a slow
opening/closing solenoid valve is recommended.
50 SERIES
50HQP,VQP
TYPE
SIZE (tons)
Large Capacity
6-20 (HQP)
6-30 (VQP)
50PC
Compact
1/ -6
2
50PS
Premium
Efficiency
1/ -6
2
High Efficiency
Console
3/ -11/
4
2
Premium
Efficiency
2-6
50PEC
50PT
50PSW
Water-to-Water
3-28
APPLICATION
Environmentally sound unit with Puron®
refrigerant (R-410A) designed to handle
large zoned areas for all geothermal and
boiler/tower applications.
Compact WSHP with Puron refrigerant
(R-410A) for boiler/tower, ground water, or
ground loop systems.
Premium, ultra efficient unit with Puron
refrigerant (R-410A) for new boiler/tower,
ground water, or ground loop systems.
Efficient console unit with Puron refrigerant
(R-410A) and attractive design for finished
interior, under-window installations.
Premium, ultra efficient 2-stage unit with
Puron refrigerant (R-410A) for new boiler/
tower, ground water, or ground loop
systems.
Efficient unit with Puron refrigerant
(R-410A) serves as an alternative to preheat or cool air. Unit can be used as a
stand-alone or supplemental boiler/chiller
in most hydronic heating applications. Also
conditions process fluids, lubricants, and
refrigerants.
Water loop system
Water loop (or boiler/tower) system applications typically
include a number of units plumbed to a common piping
system. For optimal performance, this system should be
designed between 2.25 and 3 gpm per ton of cooling
capacity. The system is comprised of highly efficient packaged reverse cycle heat pump units interconnected by a
water loop. The water circuit serves as both a sink and
source for heat absorption and rejection and is designed
for entering water temperatures between 60 F and 90 F.
Within this temperature range units can heat or cool as required from the same water source. Transferring heat from
warm to cold spaces in the building, whenever they coexist, conserves energy rather than creating new heat.
Refer to the Carrier Water Source Heat Pump System Design Guide for assistance with the design of water
loop systems. The guide includes a practical approach
for the latest and most current design recommendations
including:
• product application, including horizontal, vertical, console, rooftop and water-to-water applications
• ventilation methods and system design, including
energy recovery
• acoustical considerations for different product types
• addressing indoor air quality (IAQ) issues such as condensate removal and humidity control
• air distribution design including diffuser selection/
layout and ductwork design
• hydronic system design including pipe sizing/layout and
boiler/tower sizing
• control configurations such as standalone, DDC (direct
digital control), DCV (demand controlled ventilation),
and VVT® (variable volume and temperature) controls
Ground water systems
Ground loop systems
There are many commonly specified designs for ground
loop applications. Typical designs include vertical loops
and horizontal loops. In some applications, water is piped
from the ground or lake directly to the water source heat
pump. Piping is limited to the amount of pipe required to
get the water from the source to the unit.
NOTE: When utilizing Aquazone water source heat pumps
in ground loop systems, refer to design considerations in
the ground water system section.
Horizontal ground loop — This system is used when
adequate space is available and trenching can be easily accomplished. A series of parallel pipes are laid out in trenches 3 to 6 ft below the ground surface, and then back-filled.
Often, multiple pipes are used to maximize the heat transfer capability of each trench. The amount of pipe and the
size of the ground loop field are based on ground conditions, heating, and cooling requirements of the application
and system design.
Vertical ground loop — This system is used in vertical
borehole applications. This design is well suited for retrofit
applications when space is limited or where landscaping is
already complete and minimum disruption of the site is desired. The vertical ground loop system contains a single
29
Application data (cont)
loop of pipe inserted into a hole. The hole is back-filled and
grouted after the pipe is inserted. The completed loop is
concealed below ground. The number of loops required depends on ground conditions, heating and cooling requirements, and the depth of each hole.
Hybrid systems — In some applications, it may be beneficial to incorporate a cooling tower into the ground loop
system to reduce the overall cost. A hybrid system discards
excess heat into the air and increases the cooling performance of the ground loop.
Condensate drainage
Venting — Condensate lines should be properly vented to
prevent fan pressure from causing water to hang up in the
piping. Condensate lines should be pitched to assure full
drainage of condensate under all load conditions. Chemical
treatment should be provided to remove algae in the condensate pans and drains in geographical areas that are
conducive to algae growth.
Trapping — Condensate trapping is essential on every
water source heat pump unit. A trap is provided to prevent
the backflow of moisture from the condensate pan and into
the fan intake or downstream into the mechanical system.
The water seal or the length of the trap depends on the
positive or negative pressure on the drain pan. As a rule of
thumb, the water seal should be sized for 1 in. for every 1
in. of negative pressure on the unit. The water seal is the
distance from the bottom of the unit condensate piping
connection to the bottom of the condensate drain line runout piping. Therefore, the trap size should be double the
water seal dimension.
Horizontal units — Horizontal units should be sloped toward the drain at a 1/4 in. per foot pitch. If it is not possible
to meet the pitch requirement, a condensate pump should
be designed and installed at the unit to pump condensate
to a building drain. Horizontal units are not internally
trapped; therefore an external trap is necessary. Each unit
must be installed with its own individual trap and means to
flush or blow out the condensate drain. The design of a
common trap or vent for multiple units is not acceptable.
30
The condensate piping system should not be designed with
a pipe size smaller than the drain connection pipe size.
Vertical units — Vertical units utilize a condensate hose
inside the cabinet that acts as a trapping loop, therefore an
external trap is not necessary. Each unit must be installed
with its own vent and means to flush or blow out the
condensate drain lines. Do not install a common trap or
vent on vertical units.
Water conditioning
In some applications, maintaining proper water quality
may require the use of higher corrosion protection for
the water-to-refrigerant heat exchanger. Water quality varies from location to location and is unique for each job.
Water characteristics such as pH value, alkalinity, hardness, and specific conductance are of importance when
considering any WSHP application. Water typically includes impurities and hardness that must be removed. The
required treatment will depend on the water quality as
well as type of system. Water problems fall into three main
categories:
1. Scale formation caused by hard water reduces the
heat transfer rate and increases the water pressure
drop through the heat exchanger. As water is heated,
minerals and salts are precipitated from a solution
and deposited on the inside surface of the pipe or
tube.
2. Corrosion is caused by absorption of gases from the
air coupled with water on exposed metal. Corrosion
is also common in salt-water areas.
3. Organic growths such as algae can reduce the heat
transfer rate by forming an insulating coating on the
inside tube surface. Algae can also promote corrosion
by pitting.
NOTE: In most commercial water loop applications,
Aquazone WSHP units use copper water-to-refrigerant
heat exchanger. Units can also be equipped with a cupronickel heat exchanger for applications where water is outside the standard contaminant limits for a copper heat
exchanger.
WATER QUALITY GUIDELINES
CONDITION
HX MATERIAL*
CLOSED
RECIRCULATING†
OPEN LOOP AND RECIRCULATING WELL**
Scaling Potential — Primary Measurement
Above the given limits, scaling is likely to occur. Scaling indexes should be calculated using the limits below.
pH/Calcium
All
N/A
pH < 7.5 and Ca Hardness, <100 ppm
Hardness Method
Index Limits for Probable Scaling Situations (Operation outside these limits is not recommended.)
Scaling indexes should be calculated at 150 F for direct use and at 90 F for indirect HX use. A monitoring plan should be implemented.
Ryznar Stability Index
6.0 - 7.5
All
N/A
If >7.5 minimize steel pipe use.
Langelier Saturation Index
–0.5 to +0.5
All
N/A
If <–0.5 minimize steel pipe use.
Based upon 150 F direct well, 85 F indirect well HX.
Iron Fouling
Iron Fe2+ (Ferrous)
<0.2 ppm (Ferrous)
All
N/A
(Bacterial Iron Potential)
If Fe2+ (ferrous) >0.2 ppm with pH 6 - 8, O2<5 ppm check for iron bacteria.
Iron Fouling
<0.5 ppm of Oxygen
All
N/A
Above this level deposition will occur.
Corrosion Prevention††
pH
6 - 8.5
6 - 8.5
All
Monitor/treat as needed.
Minimize steel pipe below 7 and no open tanks with pH <8.
<0.5 ppm
Hydrogen Sulfide (H2S)
At H2S>0.2 ppm, avoid use of copper and cupronickel piping or HXs.
All
N/A
Rotten egg smell appears at 0.5 ppm level.
Copper alloy (bronze or brass) cast components are okay to <0.5 ppm.
Ammonia Ion as Hydroxide,
<0.5 ppm
Chloride, Nitrate and Sulfate
All
N/A
Compounds
Maximum Chloride Levels
Maximum allowable at maximum water temperature.
50 F (10 C)
75 F (24 C)
100 F (38 C)
Copper
N/A
<20 ppm
NR
NR
Cupronickel
N/A
<150 ppm
NR
NR
304 SS
N/A
<400 ppm
<250 ppm
<150 ppm
316 SS
N/A
<1000 ppm
<550 ppm
<375 ppm
Titanium
N/A
>1000 ppm
>550 ppm
>375 ppm
Erosion and Clogging
Particulate Size and Erosion
<10 ppm of particles and a
maximum velocity of 6 fps. <10 ppm (<1 ppm “sandfree” for reinjection) of particles and a maximum
All
velocity of 6 fps. Filtered for maximum 800 micron size. Any particulate that
Filtered for maximum
is not removed can potentially clog components.
800 micron size.
Brackish
Use cupronickel heat exchanger when concentrations of calcium or
All
N/A
sodium chloride are greater than 125 ppm are present. (Seawater is
approximately 25,000 ppm.)
HX
N/A
NR
SS
LEGEND
— Heat Exchanger
— Design Limits Not Applicable Considering Recirculating
Potable Water
— Application Not Recommended
— Stainless Steel
*Heat exchanger materials considered are copper, cupronickel, 304 SS
(stainless steel), 316 SS, titanium.
†Closed recirculating system is identified by a closed pressurized piping
system.
**Recirculating open wells should observe the open recirculating design
considerations.
††If the concentration of these corrosives exceeds the maximum allowable
level, then the potential for serious corrosion problems exists.
Sulfides in the water quickly oxidize when exposed to air, requiring that no
agitation occur as the sample is taken. Unless tested immediately at the
site, the sample will require stabilization with a few drops of one Molar
zinc acetate solution, allowing accurate sulfide determination up to
24 hours after sampling. A low pH and high alkalinity cause system problems, even when both values are within ranges shown. The term pH refers
to the acidity, basicity, or neutrality of the water supply. Below 7.0, the
water is considered to be acidic. Above 7.0, water is considered to be
basic. Neutral water registers a pH of 7.0.
To convert ppm to grains per gallon, divide by 17. Hardness in mg/l is
equivalent to ppm.
31
Application data (cont)
Acoustical design
Sound power levels represent the sound as it is produced
by the source, the WSHP unit, with no regard to attenuation between the source and the space. Acoustical design
goals are necessary to provide criteria for occupied spaces
where people can be comfortable and communicate effectively over the background noise of the air-conditioning
system and other background noise sources.
Acoustical design goals are desirable sound pressure levels within a given conditioned space and are represented
by noise criteria (NC) curves. Noise criteria curve levels represent a peak over a full spectrum of frequencies. A high
value in a low frequency band has the same effect on NC
level as a lower value in a high frequency band. It is important that sound levels be balanced over the entire spectrum
relative to the NC curve. The lower the NC criteria curve,
the more stringent the room acoustical design must be to
meet the design goals.
It is important to know how to convert NC levels from
the unit ratings in terms of sound power (Lw). This conversion depends on the specifics of the acoustical environment of the installation.
The resulting calculations are compared to the NC curve
selected for the area to assess the acoustical design.
Some of the factors that affect conversion of sound
power to sound pressure and consequent NC level include:
• type of acoustical ceiling
• use of metal or flex duct
• absorption in the occupied space
• location in the occupied space
• open or closed layout plan
• use of open or ducted returns
• orientation of unit to occupant
• use of lined or unlined duct
WSHP sound control
The analysis of the projected sound level in the conditioned
space caused by a WSHP unit located in a ceiling plenum is
quite involved. The key is to have good sound power ratings (Lw) in dB on the equipment to determine the sound
attenuation effect of the ductwork, ceiling and room. In
combination with utilizing standard Aquazone™ equipment
attenuating features or the advanced mute package features, suggestions for horizontal and vertical unit sound design are provided to design around the WSHP units.
Horizontal units
Use the following guidelines for layout of Aquazone horizontal units to minimize noise:
1. Obtain sound power ratings in accordance with latest
standards from manufacturers to select quietest
equipment.
2. Do not locate units over a space with a required NC
of 40 or less. Instead, locate units above less sensitive
noise areas such as above or in equipment rooms,
utility closets, restrooms, storage rooms, or above
corridors.
3. Provide at least 10 feet between WSHP units to avoid
the additive effect of two noise sources.
32
4. Provide an acoustical pad underneath the WSHP unit
in applications where the unit must be mounted
above noise sensitive areas such as private offices or
conference rooms. The pad attenuates radiated noise.
Be sure the pad has an area at least twice that of the
WSHP footprint.
5. Maximize the installed height above the suspended
ceiling.
6. Be sure the WSHP unit is located at least 6 feet away
from any ceiling return grille to prevent line-of-sight
casing noise from reaching the space below.
7. Suspend the WSHP unit from the ceiling with hangers that utilize spring or neoprene type isolators to
reduce vibration transmission.
8. Utilize flexible electrical connections to the WSHP
unit. DO NOT USE NOT RIGID CONNECTIONS.
9. Utilize flexible loop water and condensate piping connections to the WSHP unit.
10. Use a canvas duct connector to connect the WSHP
discharge to the downstream duct system. This
reduces vibration-induced noise.
11. Provide acoustic interior lining for the first 20 feet of
discharge duct, or until the first elbow is reached. The
elbow prevents line-of-site sound transmission in the
discharge duct.
12. Provide turning vanes in ductwork elbows and tees to
reduce air turbulence.
13. Size the sheet metal supply duct with velocities no
greater than 1000 fpm.
14. Ensure ductwork is rigid.
15. Use round duct whenever possible to further reduce
noise.
16. Allow at least 3 equivalent duct diameters of straight
duct upstream and downstream of the unit before
allowing any fittings, transitions, etc.
17. Seal all penetrations around duct entering the space.
18. Provide a 4-ft run-out duct made of flexible material
to connect a diffuser to the supply trunk duct. The
flex duct provides an “attenuating end-effect” and
reduces duct-transmitted sound before it reaches the
space. Typically a 6 dB sound reduction can be
accomplished with the use of flex duct.
19. Locate the run-out duct balancing damper as far away
from the outlet diffuser as possible. Locating the
balancing damper at the trunk duct exit is the best
location.
20. If return air is drawn through a ceiling plenum, provide an acoustically lined return duct elbow or “L”
shaped boot at the WSHP to eliminate line-of-sight
noise into the ceiling cavity and possibly through ceiling return air grilles. Face the elbow or boot away
from the nearest adjacent WSHP unit to prevent additive noise.
21. Do not hang suspended ceiling from the ductwork.
Vertical units
All guidelines established for horizontal units also apply for
vertical units. In addition, since vertical units tend to be installed in small equipment rooms or closets, the following
guidelines apply:
1. Mount the unit on a pad made of high-density sound
absorbing material such as rubber or cork. Extend the
pad beyond the WSHP unit footprint by at least
6 inches in each direction.
2. Since the unit returns airflow through a grille
mounted in a closet door, provide a sound barrier or
some other modification of the closet to prevent lineof-sight noise into the space.
3. Follow good duct design practice in sizing and locating the connection of the WSHP discharge to the
supply duct system. Use an elbow with turning vanes
and bent in the direction of the fan rotation to minimize turbulence. Make any duct transitions as smooth
and as gradual as possible to minimize turbulence and
loss of fan static pressure.
Solenoid valves
In applications using variable flow pumping, solenoid
valves can be field-installed and operated from the control
board in the Aquazone™ WSHP unit.
Freeze protection
Applications where systems are exposed to outdoor
temperatures below freezing (32 F) must be protected from
freezing. The most common method of protecting water
systems from freezing is adding glycol concentrations into
the water. Design care should be used when selecting both
the type and concentrations of glycol utilized due to the
following:
• Equipment and performance may suffer with high concentrations of glycol and other antifreeze solutions.
• Loss of piping pressure may increase greatly, resulting
in higher pumping costs.
• Higher viscosity of the mixture may cause excess corrosion and wear on the entire system.
• Acidity of the water may be greatly increased, promoting corrosion.
• Glycol promotes galvanic corrosion in systems of dissimilar metals. The result is corrosion of one metal by
the other, causing leaks.
Hot gas reheat
Hot gas reheat (HGR) allows the user to not only control
space temperature, but also humidity levels within the conditioned space. Excessive moisture in the space can pro-
mote mold growth leading to damage in the structure or interior surfaces, as well as reducing the air quality and creating an unhealthy environment.
Possible causes of excess humidity could be a byproduct
of the unit having to operate under a widely varying load,
an oversized short cycling unit, a high percentage of unconditioned outside air being introduced into the space, a
high latent load in the space or any location where humidity infiltration is a problem.
Typical unit control is by a wall mounted thermostat that
senses temperature in the occupied space. By utilizing a
humidistat in addition to the thermostat, part load units
with hot gas reheat are able to control the humidity levels
in the space as well. The hot gas reheat option allows cooling and dehumidification to satisfy both the thermostat and
humidistat while preventing over-cooling of the space while
in the dehumidification mode.
Once the thermostat reaches set point temperature, and
is above humidity set point, the unit controller will energize
the reheat valve operating the unit in hot gas reheat mode,
first cooling and dehumidifying, then reheating the air (using hot refrigerant gas) before delivering it to the space,
usually 2° to 5° F below room temperature. The unit operates like a dehumidifier by reheating the air along a constant sensible heat line, while the relative humidity of the
leaving air is reduced. This option offers significant energy
savings over reheating air with electric heating coils.
The moisture removal capacity of a specific heat pump is
determined by the unit latent capacity rating. A heat
pump’s latent capacity can be determined by reviewing the
heat pump specification data sheets. Depending upon the
entering water and air conditions, a total and sensible capacity can be interpolated from the data sheets. Subtracting sensible capacity from total capacity yields latent capacity. Dividing the latent capacity by 1069 converts the
amount of moisture removal from Btuh to lb/hr.
A hot gas reheat valve and a reheat coil are included in
the refrigerant circuit. The refrigerant circuits in the cooling and heating modes are identical to a standard heat
pump. In the reheat mode, the compressor discharge gas
is diverted through the reheat valve to the reheat coil which
is located downstream of the cooling coil. The superheated
refrigerant gas reheats the air leaving the cooling coil. The
hot refrigerant gas then passes though the water to refrigerant coil where it is condensed to a liquid. From this point
the rest of the cooling cycle is completed as in a regular
heat pump. There are check valves to prevent refrigerant
flow into the reheat coil during standard cooling/heating
cycles.
33
Guide specifications
architect must approve all changes 10 days
prior to bid.
2. All units shall have stainless steel drain pans to
comply with this project’s IAQ (indoor air quality) requirements. No exceptions shall be
allowed.
3. All water source heat pumps shall be fabricated
from sheet metal finished with G90 galvanized
steel. All interior surfaces shall be lined with
1/ in. thick, multi-density acoustic insulation.
2
All insulation must meet NFPA 90A and be certified to meet the GREENGUARD Indoor Air
Quality Standard for Low Emitting Products.
One blower access panel and two compressor
compartment access panels shall be removable
with supply and return air ductwork in place.
4. Unit shall have a floating base pan consisting of
a 1/2 in. (12 mm) thick high density rubber pad
between the compressor base plate and the unit
base pan to prevent transmission of vibration to
the structure.
5. All units shall have a factory installed four sided
filter rack capable of accepting either one or
two inch filters. Units shall have a 1-in. thick
throwaway type glass fiber filter as standard.
The filter rack shall incorporate a 1-in. duct
flange. The contractor shall purchase one spare
set of filters and replace factory-shipped filters
upon completion of start-up.
6. Cabinets shall have separate holes and knockouts for entrance of line voltage and low voltage
control wiring. Supply and return water connections shall be brass FPT fittings and shall be
securely mounted flush to the cabinet allowing
for connection to a flexible hose without the use
of a back-up wrench. Water connections which
protrude through the cabinet shall not be
allowed.
7. Hanging brackets shall be provided as standard
for horizontal units.
8. All units shall have condensate overflow switch,
Air-Coil and Water-Coil Freeze sensor as standard.
C. Access Panels:
All units (horizontal and vertical) must have a minimum of three access panels for serviceability of
compressor compartment. Units having only one
access panel to compressor, heat exchangers,
expansion device, or refrigerant piping shall not be
acceptable.
D. Insulation:
Standard cabinet panel insulation must meet NFPA
90A requirements, air erosion and mold growth limits of UL-181, stringent fungal resistance test per
ASTM C1071 and ASTM G21, and shall meet zero
level bacteria growth per ASTM G22. Unit insulation must meet these stringent requirements or
unit(s) will not be accepted.
Two-Stage Water Source Heat Pumps with
Puron® Refrigerant (R-410A)
HVAC Guide Specifications
Size Range: 18,500 to 78,700 Btuh
Cooling Capacity
14,400 to 84,000 Btuh
Heating Capacity
Carrier Model Number: 50PTH, 50PTV
Part 1 — General
1.01 SYSTEM DESCRIPTION
A. Single-package horizontally and vertically mounted
water source heat pump with Puron refrigerant
(R-410A) and electronic controls.
B. Equipment shall be completely assembled, piped
and internally wired. Capacities and characteristics
as listed in the schedule and the guide specifications
that follow.
1.02 QUALITY ASSURANCE
A. All equipment listed in this section must be rated and
certified in accordance with ARI/ISO, latest edition,
and ETL listed to UL standard 1995. The units shall
have ARI/ISO and ETL labels.
B. All units shall be factory tested in all operating modes
and safety switch operation shall be verified. Quality
control system shall automatically perform via computer: triple leak check, pressure tests, evacuate and
accurately charge system, perform detailed heating
and cooling mode tests, and quality cross check all
operational and test conditions to pass/fail data base.
NOTE: If unit fails on any cross check, system shall
not allow unit to ship.
C. Serial numbers will be recorded by factory and furnished to contractor on report card for ease of unit
warranty status. Units shall be prewired and precharged in factory.
Part 2 — Product
2.01 EQUIPMENT
A. General:
Units shall be supplied completely factory built for

an entering water temperature range from 25 to
110 F as standard. Equivalent units from other manufacturers can be proposed provided approval to bid
is given 10 days prior to bid closing.
B. Basic Construction
1. Units shall have the air flow arrangement as
shown on the plans. If units with these arrangements are not used, the contractor supplying
the water source heat pumps is responsible for
any extra costs incurred by other trades and
must submit detailed mechanical drawings
showing ductwork requirements and changes or
relocation of any other mechanical or electrical
system. If other arrangements make servicing
difficult the contractor must provide access panels and clear routes to ease service. The
34
514
E. Factory-Installed Wiring:
All factory-installed wiring passing through factory
knockouts and openings shall be protected from
sheet metal edges at openings by plastic ferrules.
F. Unit Removal:
Contractor must ensure that units can be easily
removed for servicing and coordinate locations of
electrical conduit and lights with the electrical
contractor.
G. Compressor:
1. Compressor section interior surfaces shall be
lined with 1/2 in. thick, dual density, 13/4 lb per
cu. ft acoustic type fiberglass insulation. Airhandling section interior surfaces shall be lined
with 1/2 in. thick, single density, 13/4 lb per cu.
ft foil-backed fiber insulation for ease of cleaning.
2. Insulation placement shall be designed in a
manner that will eliminate any exposed edges
to prevent the introduction of glass fibers into
the airstream. Units without foil-backed insulation in the air-handling section will not be
accepted.
3. The compressor shall have a dual level vibration
isolation system.
4. The compressor will be mounted on computerselected vibration isolation springs to a large
heavy gage compressor mounting tray plate,
which is then isolated from the cabinet base
with rubber grommets for maximized vibration
attenuation.
5. Compressor shall be located in an insulated
compartment away from airstream to minimize
sound transmission.
6. Compressor shall have thermal overload
protection.
7. The heat pumps shall be fabricated from heavy
gage G90 galvanized steel with powder coat
paint finish. Both sides of the steel shall be
painted for added protection.
8. All units must have an insulated panel separating the fan compartment from the compressor
compartment.
9. Units with the compressor in the airstream are
not acceptable.
H. Fan and Motor Assembly:
1. Blower shall have inlet rings to allow removal of
wheel and motor from one side without removing housing.
2. Units shall have a direct-drive centrifugal fan.
The fan motor shall be a factory preprogrammed high efficiency constant torque type.
3. The fan motor shall be isolated from the housing by rubber grommets.
4. The fan and motor assembly must be capable of
overcoming the external static pressures as
shown on the schedule. External static pressure
rating of the unit shall be based on a wet coil.
Ratings based on a dry coil shall NOT be
acceptable.
5. All units shall have removable blower inlet ring
as standard for ease of service and maintenance.
I. Refrigerant Circuit:
1. Units shall use R-410A refrigerant. All units
shall have a factory sealed and fully charged
refrigerant circuit with the following components:
2. Two stage hermetic compressor specifically
designed for heat pump operation and shall be
internally protected with thermal overload protection and mounted on rubber vibration isolators.
3. Bi-directional refrigerant metering thermal
expansion valves. Finned tube refrigerant to air
heat exchanger not exceeding 14 fins per inch.
Refrigerant to air heat exchangers shall utilize
enhanced aluminum fins and rifled copper tube
construction rated to withstand 600 psig refrigerant working pressure. All air coils shall have
non-ferrous aluminum end plates.
4. Reversing valve. Reversing valves shall be four
way solenoid activated refrigerant valves which
shall fail to the heating operation should the
solenoid fail to function. Reversing valves which
fail to the cooling operation shall not be
allowed.
5. Coaxial (tube in tube) refrigerant to water heat
exchanger. Refrigerant to water heat exchangers shall be insulated and with copper inner
water tube and steel outer refrigerant tube
design rated to withstand 600 psig working
refrigerant pressure and 400 psig working
water pressure. Shell and tube style refrigerant
to water heat exchangers shall be treated as
pressure vessels and shall require refrigerant
pressure relief valves piped to the exterior of
the building. The contractor supplying the
water source heat pumps with shell and tube
heat exchangers shall be responsible for any
additional installation costs. Brazed plate water
to refrigerant heat exchangers shall require
additional centrifugal separators added to the
supply water piping at each unit. Each separator shall have an automated clean out valve
piped to a waste line. The contractor supplying
water source heat pumps with brazed plate heat
exchangers shall be responsible for any additional costs.
6. Safety controls including both a high pressure
and low pressure switch. Temperature sensors
shall not replace these safety switches.
7. Access fittings shall be factory installed on high
and low pressure refrigerant lines to facilitate
field service.
35
Guide specifications (cont)
8. Activation of any safety device shall prevent
compressor operation via a lockout circuit. The
lockout circuit shall be reset at the thermostat
or at the contractor supplied disconnect switch.
Units which may be reset at the disconnect
switch only shall not be acceptable.
J. Thermostatic Expansion Valve:
1. Expansion valves shall be dual port balanced
types with external equalizer for optimum
refrigerant metering.
2. Units shall be designed and tested for operating
ranges of entering water temperatures from
25 to 110 F.
3. Reversing valve shall be four-way solenoid activated refrigerant valve, which shall default to
heating mode should the solenoid fail to function. If the reversing valve solenoid defaults to
cooling mode, an additional low temperature
thermostat must be provided to prevent overcooling an already cold room.
K. Controls and Safeties:
1. Electrical:
A control box shall be located within the unit
and shall contain a transformer, controls for the
compressor, reversing valve and fan motor
operation and shall have a terminal block for
low voltage field wiring connections. The transformer shall be rated for a minimum 75 va. All
units shall be nameplated for use with time
delay fuses or HACR (Heating, Air-Conditioning, and Refrigeration) circuit breakers. Unit
controls shall be 24 volts.
2. Solid-State Safety Circuit
All units shall have a solid-state UPM (unit protection module) safety control circuit with the
following features:
a. Anti-short cycle time delay on compressor
operation.
b. Random start on power up mode.
c. Brown out/surge/power interruption protection.
d. Low pressure switch 120 second bypass
timer.
e. Shutdown on the following fault indications:
1) High or low refrigerant pressure safety
switches inputs.
2) Freeze sensors shall monitor refrigerant
temperature to the water coil in the
heating mode and refrigerant coil in the
cooling mode.
3) Condensate sensor input.
f. Alarm output which closes for selectable dry
contact closure or 24 vac remote fault indication.
g. Alarm output selectable for constant output
for general alarm notification, or pulse output
for annunciation of the specific fault alarm.
36
h. Selectable reset of unit at thermostat or disconnect.
i. Automatic intelligent reset. Unit shall automatically reset after a safety shut down and
restart after the anti-short cycle timer and random start timer expire. Should a fault reoccur within 60 minutes after reset, then a
permanent lockout will occur. Reset attempts
shall be selectable for either 2 or 4 tries. A
condensate overflow will place the unit in an
immediate hard lockout.
j. Ability to defeat time delays for servicing.
k. A light emitting diode (LED) to indicate safety
alarms. The LED shall annunciate the following alarms:
1) High refrigerant pressure,
2) Low refrigerant pressure,
3) Low refrigerant temperature to the
water coil in the heating operation,
4) High level of condensate in the drain
pan,
5) Brown out/surge/ power interruption.
l. The LED will display each fault condition as
soon as the fault occurs. If a permanent lockout occurs, then the fault LED will display the
type of fault until the unit is reset.
m. UL listed, CUL listed, and RFI, ESD, and
transient protected.
3. Deluxe D Controls:
Optional electronic Deluxe D control shall have
all the features of the Complete C control with
the following additional features:
a. 75 va transformer.
b. Single grounded wire to initiate night setback,
or emergency shutdown.
c. Boilerless system control can switch automatically to electric heat at low loop water
temperature.
d. Selection of boilerless changeover temperature set point.
Units not having automatic low sensible heat
ratio cooling will not be accepted; as an alternate, a hot gas reheat coil may be provided with
control system for automatic activation.
L. Piping:
1. Supply and return water connections shall be
copper FPT fittings and shall be securely
mounted flush to the cabinet corner post allowing for connection to a flexible hose without the
use of a back-up wrench.
2. All water connections and electrical knockouts
must be in the compressor compartment corner
post so as to not interfere with the serviceability
of unit. Contractor shall be responsible for any
extra costs involved in the installation of units
that do not have this feature.
Carrier Corporation • Syracuse, New York 13221
514
4-14
Manufacturer reserves the right to discontinue, or change at any time, specifications or designs without notice and without incurring obligations.
Pg 40
Catalog No. 04-52500097-01
Printed in U.S.A.
Form 50PT-1APD
Replaces: NEW
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