Simplicity 12.5 LT Specification

Simplicity 12.5 LT Specification
GZKDJRRJDGHZ2[JZFJR
R-410A
ZH SERIES
6-1/2 - 12-1/2 Ton
60 Hertz
TABLE OF CONTENTS
General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Preceding Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Limitations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Location. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Rigging And Handling . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Ductwork . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
Condensate Drain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
Compressors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
Filters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
Power And Control Wiring. . . . . . . . . . . . . . . . . . . . . . . . . 18
Optional Electric Heat . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
Optional Gas Heat. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
Options/Accessories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
Economizer And Power Exhaust Set Point Adjustments . 34
Air Balance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48
Checking Air Quantity . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Cooling Sequence Of Operation . . . . . . . . . . . . . . . . . . . .
No Outdoor Air Options . . . . . . . . . . . . . . . . . . . . . . . . .
Cooling Operation Errors . . . . . . . . . . . . . . . . . . . . . . . .
Electric Heating Sequence Of Operations . . . . . . . . . . . .
Electric Heat Operation Errors . . . . . . . . . . . . . . . . . . . .
Gas Heating Sequence Of Operations . . . . . . . . . . . . . . .
Ignition Control Board . . . . . . . . . . . . . . . . . . . . . . . . . .
Gas Heating Operation Errors . . . . . . . . . . . . . . . . . . . .
Start-Up (Cooling) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Start-Up (Gas Heat) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Checking Gas Heat Input . . . . . . . . . . . . . . . . . . . . . . . . . . .
Charging The Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
48
52
52
52
53
54
54
55
55
55
57
57
58
60
60
LIST OF TABLES
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
ZH078-150 Unit Limitations . . . . . . . . . . . . . . . . . . . . . . .
Weights and Dimensions . . . . . . . . . . . . . . . . . . . . . . . .
ZH078-150 Unit Accessory Weights . . . . . . . . . . . . . . . .
ZH078-150 Unit Physical Dimensions . . . . . . . . . . . . . .
ZH078-150 Unit Clearances . . . . . . . . . . . . . . . . . . . . . .
Side Duct Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . .
Control Wire Sizes . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Electrical Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
ZH078-150 Physical Data . . . . . . . . . . . . . . . . . . . . . . . .
Electric Heat Minimum Supply Air . . . . . . . . . . . . . . . . . .
Gas Application Data . . . . . . . . . . . . . . . . . . . . . . . . . . .
Gas Pipe Sizing - CapacIty of Pipe . . . . . . . . . . . . . . . . .
Gas Heat Minimum Supply Air . . . . . . . . . . . . . . . . . . . .
Supply Air Limitations . . . . . . . . . . . . . . . . . . . . . . . . . . .
Altitude/Temperature Correction Factors . . . . . . . . . . . .
10
11
12
13
13
15
20
21
29
30
31
31
32
36
37
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
Unit Shipping Bracket . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Condenser Covering . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Compressor Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Predator® Component Location (ZH120 Shown) . . . . . . . 9
Unit 4 Point Load Weight . . . . . . . . . . . . . . . . . . . . . . . . 11
Unit 6 Point Load Weight . . . . . . . . . . . . . . . . . . . . . . . . 11
Center of Gravity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
ZH078-120 Physical Dimensions . . . . . . . . . . . . . . . . . . 12
ZH150 Physical Dimensions . . . . . . . . . . . . . . . . . . . . . 12
ZH078-150 Unit Bottom Duct Openings . . . . . . . . . . . . 13
ZH078-150 Unit Electrical Entry . . . . . . . . . . . . . . . . . . . 14
ZH078-120 Unit Side Duct Openings . . . . . . . . . . . . . . . 14
ZH150 Unit Side Duct Openings . . . . . . . . . . . . . . . . . . 15
ZH078-150 Unit Left Duct Opening . . . . . . . . . . . . . . . . 15
ZH078-150 Roof Curb . . . . . . . . . . . . . . . . . . . . . . . . . . 16
ZH078-150 Transition Roof Curb . . . . . . . . . . . . . . . . . . 16
Side Panels With Hole Plugs . . . . . . . . . . . . . . . . . . . . . 17
Return Downflow Plenum With Panel . . . . . . . . . . . . . . 17
Discharge Panel In Place . . . . . . . . . . . . . . . . . . . . . . . . 17
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
ZH Bottom Duct Blower Performance . . . . . . . . . . . . . . .
ZH Side Duct Blower Performance . . . . . . . . . . . . . . . . .
Indoor Blower Specifications . . . . . . . . . . . . . . . . . . . . . .
Power Exhaust Specifications . . . . . . . . . . . . . . . . . . . .
Motor Sheave Datum Diameters . . . . . . . . . . . . . . . . . .
Additional Static Resistance . . . . . . . . . . . . . . . . . . . . . .
Electric Heat Limit Setting 50” Cabinet . . . . . . . . . . . . . .
Electric Heat Limit Setting 42” Cabinet . . . . . . . . . . . . . .
Electric Heat Anticipator Setpoints . . . . . . . . . . . . . . . . .
Gas Heat Limit Control Settings . . . . . . . . . . . . . . . . . . .
Gas Heat Anticipator Setpoints . . . . . . . . . . . . . . . . . . . .
Gas Rate Cubic Feet Per Hour . . . . . . . . . . . . . . . . . . . .
Gas Heat Stages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Unit Control Board Flash Codes . . . . . . . . . . . . . . . . . . .
Ignition Control Flash Codes . . . . . . . . . . . . . . . . . . . . . .
38
43
48
48
50
51
54
54
55
56
57
58
59
60
60
LIST OF FIGURES
20 Condensate Drain . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
21 Field Wiring Disconnect - Cooling Unit With/
Without Electric Heat . . . . . . . . . . . . . . . . . . . . . . . . . . .
22 Field Wiring Disconnect - Cooling Unit With Gas Heat .
23 Electronic Thermostat Field Wiring . . . . . . . . . . . . . . . .
24 Field Wiring 24 Volt Thermostat . . . . . . . . . . . . . . . . . . .
25 Side Entry Gas Piping . . . . . . . . . . . . . . . . . . . . . . . . . .
26 Bottom Entry Gas Piping . . . . . . . . . . . . . . . . . . . . . . . .
27 Enthalpy Set Point Chart . . . . . . . . . . . . . . . . . . . . . . . .
28 Honeywell Economizer Control W7212 . . . . . . . . . . . . .
29 Belt Adjustment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
30 Altitude/Temperature Correction Factors . . . . . . . . . . . .
31 Dry Coil Delta P . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
32 Typical Flame . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
33 Typical Gas Valve . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
34 Basic Troubleshooting Flowchart . . . . . . . . . . . . . . . . . .
35 Power On Flow Chart . . . . . . . . . . . . . . . . . . . . . . . . . . .
36 Trip Failure Flow Chart . . . . . . . . . . . . . . . . . . . . . . . . .
17
19
19
20
20
31
31
35
35
36
37
49
59
59
61
61
62
164015-YIM-A-0905
164015-YIM-A-0905
General
York® Predator® units are single package air conditioners with
optional gas heating designed for outdoor installation on a
rooftop or slab and for non-residential use. These units can be
equipped with factory or field installed electric heaters for
heating applications.
These units are completely assembled on rigid, permanently
attached base rails. All piping, refrigerant charge, and electrical
wiring is factory installed and tested. The units require electric
power, gas supply (where applicable), and duct connections.
The electric heaters have nickel-chrome elements and utilize
single-point power connection.
Before performing service or maintenance operations on
unit, turn off main power switch to unit. Electrical shock
could cause personal injury. Improper installation,
adjustment, alteration, service or maintenance can
cause injury or property damage. Refer to this manual.
For assistance or additional information consult a
qualified installer, service agency or the gas supplier.
Safety Considerations
This is a safety alert symbol. When you see this symbol on
labels or in manuals, be alert to the potential for personal injury.
Understand and pay particular attention the signal words
DANGER, WARNING or CAUTION.
DANGER indicates an imminently hazardous situation, which,
if not avoided, will result in death or serious injury.
This system uses R-140A Refrigerant which operates at
higher pressures than R-22. No other refrigerant may be
used in this system. Gage sets, hoses, refrigerant
containers and recovery systems must be designed to
handle R-410A. If you are unsure, consult the equipment
manufacturer. Failure to use R-410A compatible servicing
equipment may result in property damage or injury.
WARNING indicates a potentially hazardous situation, which,
if not avoided, could result in death or serious injury.
CAUTION indicates a potentially hazardous situation, which, if
not avoided may result in minor or moderate injury. It is also
used to alert against unsafe practices and hazards involving
only property damage.
If the information in this manual is not followed exactly, a
fire or explosion may result causing property damage,
personal injury or loss of life.
Do not store or use gasoline or other flammable vapors
and liquids in the vicinity of this or any other appliance.
WHAT TO DO IF YOU SMELL GAS:
a. Do not try to light any appliance.
Improper installation may create a condition where the
operation of the product could cause personal injury or
property damage. Improper installation, adjustment,
alteration, service or maintenance can cause injury or
property damage. Refer to this manual for assistance or
for additional information, consult a qualified contractor,
installer or service agency.
This product must be installed in strict compliance with
the installation instructions and any applicable local,
state and national codes including, but not limited to
building, electrical, and mechanical codes.
b. Do not touch any electrical switch; do not use any
phone in your building.
c. Immediately call your gas supplier from a neighbor’s
phone. Follow the gas supplier’s instructions.
d. If you cannot reach your gas supplier, call the fire
department.
Installation and service must be performed by a qualified
installer, service agency or the gas supplier.
Due to system pressure, moving parts, and electrical
components, installation and servicing of air conditioning
equipment can be hazardous. Only qualified, trained service
personnel should install, repair, or service this equipment.
Untrained personnel can perform basic maintenance functions
of cleaning coils and filters and replacing filters.
Observe all precautions in the literature, labels, and tags
accompanying the equipment whenever working on air
conditioning equipment. Be sure to follow all other applicable
safety precautions and codes including ANSI Z223.1 or CSAB149.1- latest edition.
2
Unitary Products Group
164015-YIM-A-0905
Wear safety glasses and work gloves. Use quenching cloth and
have a fire extinguisher available during brazing operations.
• Gas Heat High Altitude Kit (Natural Gas)
Inspection
• –60°F Gas Heat Kit
• Gas Heat High Altitude Kit (Propane)
• Electric Heater Accessory 50” cabinet
As soon as a unit is received, it should be inspected for possible
damage during transit. If damage is evident, the extent of the
damage should be noted on the carrier’s freight bill. A separate
request for inspection by the carrier’s agent should be made in
writing.
• Electric Heater Accessory 42” cabinet
Renewal Parts
Contact your local York® parts distribution center for authorized
replacement parts.
Approvals
This product must be installed in strict compliance with
the enclosed installation instructions and any applicable
local, state and national codes including, but not limited
to, building, electrical, and mechanical codes.
The furnace and its individual shut-off valve must be
disconnected from the gas supply piping system during
any pressure testing at pressures in excess of 1/2 PSIG.
Pressures greater than 1/2 PSIG will cause gas valve
damage resulting in a hazardous condition. If it is
subjected to a pressure greater than 1/2 PSIG, the gas
valve must be replaced.
The furnace must be isolated from the gas supply piping
system by closing its individual manual shut-off valve
during any pressure testing of the gas supply piping
system at test pressures equal to or less than 1/2 PSIG
Reference
Design certified by CSA as follows:
1.
For use as a cooling only unit, cooling unit with
supplemental electric heat or a forced air furnace.
2.
For outdoor installation only.
3.
For installation on combustible material and may be
installed directly on combustible flooring or, in the U.S., on
wood flooring or Class A, Class B or Class C roof covering
materials.
4.
For use with natural gas (convertible to LP with kit).
This product must be installed in strict compliance with
the enclosed installation instructions and any applicable
local, state, and national codes including, but not limited
to, building, electrical, and mechanical codes.
Additional information is available in the following reference
forms:
• Technical Guide - ZH078-150, 036-21692-001-A-0805
• General Installation - ZH078-150, 164015-YIM-A-0905
• Pre-start & Post-start Check List - 035-18466-000
• Economizer Accessory Downflow Factory Installed
Downflow Field Installed
Horizontal Field Installed
Improper installation may create a condition where the
operation of the product could cause personal injury or
property damage.
• Motorized Outdoor Air Damper
• Manual Outdoor Air Damper (0-100%)
• Manual Outdoor Air Damper (0-35%)
• Gas Heat Propane Conversion Kit
Unitary Products Group
This system uses R-410A Refrigerant which operates at
higher pressures than R-22. No other refrigerant may be
used in this system.
3
164015-YIM-A-0905
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Unitary Products Group
164015-YIM-A-0905
Nomenclature Additional Options
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Additional Options
None
Phase Monitor
Coil Guard
Dirty Filter Switch
Phase Monitor & Coil Guard
Phase Monitor & Dirty Filter Switch
Coil Guard & Dirty Filter Switch
Phase Monitor, Coil Guard, & Dirty Filter Switch
SS Drain Pan
SS Drain Pan & Phase Monitor
SS Drain Pan & Coil Guard
SS Drain Pan & Dirty Filter Switch
SS Drain Pan, Phase Monitor, Coil Guard & Dirty Filter Switch
CPC Controller with Dirty Filter Switch & Air Proving Switch
CPC Controller, DFS, APS & Phase Monitor
CPC Controller, DFS, APS & Coil Guard
CPC Controller, DFS, APS, Phase Monitor, & Coil Guard
CPC Controller, DFS, APS & Technicoat Cond. Coil
CPC Controller, DFS, APS, Technicoat Cond. Coil, & Phase Monitor
CPC Controller, DFS, APS, Technicoat Cond. Coil, & Coil Guard
CPC Controller, DFS, APS, Technicoat Cond. Coil, Phase Monitor, & Coil Guard
CPC Controller, DFS, APS & Technicoat Evap. Coil
CPC Controller, DFS, APS, Technicoat Evap. Coil, & Phase Monitor
CPC Controller, DFS, APS, Technicoat Evap. Coil, & Coil Guard
CPC Controller, DFS, APS, Technicoat Evap. Coil, Phase Monitor, & Coil Guard
CPC Controller, DFS, APS & Technicoat Evap. & Cond Coils
CPC Controller, DFS, APS, Technicoat Evap. & Cond Coils, & Phase Monitor
CPC Controller, DFS, APS, Technicoat Evap. & Cond Coils, & Coil Guard
CPC Controller, DFS, APS, Technicoat Evap. & Cond Coils, Phase Monitor, & Coil Guard
CPC Controller, DFS, APS, SS Drain Pan
CPC Controller, DFS, APS, SS Drain Pan, Phase Monitor, & Coil Guard
CPC Controller, DFS, APS, SS Drain Pan, & Technicoat Cond Coils
CPC Controller, DFS, APS, SS Drain Pan, & Technicoat Evap Coil
CPC Controller, DFS, APS, SS Drain Pan, & Technicoat Evap and Cond Coils
CPC Controller, DFS, APS, SS Drain Pan, Phase Monitor, Coil Guard, & Technicoat Evap and Cond Coils
Johnson UNT Controller with Dirty Filter Switch & Air Proving Switch
Johnson UNT Controller, DFS, APS & Phase Monitor
Johnson UNT Controller, DFS, APS & Coil Guard
Johnson UNT Controller, DFS, APS, Phase Monitor, & Coil Guard
Johnson UNT Controller, DFS, APS & Technicoat Cond. Coil
Johnson UNT Controller, DFS, APS, Technicoat Cond. Coil, & Phase Monitor
Johnson UNT Controller, DFS, APS, Technicoat Cond. Coil, & Coil Guard
Johnson UNT Controller, DFS, APS, Technicoat Cond. Coil, Phase Monitor, & Coil Guard
Johnson UNT Controller, DFS, APS & Technicoat Evap. Coil
Johnson UNT Controller, DFS, APS, Technicoat Evap. Coil, & Phase Monitor
Johnson UNT Controller, DFS, APS, Technicoat Evap. Coil, & Coil Guard
Johnson UNT Controller, DFS, APS, Technicoat Evap. Coil, Phase Monitor, & Coil Guard
Johnson UNT Controller, DFS, APS & Technicoat Evap. & Cond Coils
Johnson UNT Controller, DFS, APS, Technicoat Evap. & Cond Coils, & Phase Monitor
Johnson UNT Controller, DFS, APS, Technicoat Evap. & Cond Coils, & Coil Guard
Johnson UNT Controller, DFS, APS, Technicoat Evap. & Cond Coils, Phase Monitor, & Coil Guard
Johnson UNT Controller, DFS, APS, SS Drain Pan
Johnson UNT Controller, DFS, APS, SS Drain Pan, Phase Monitor, & Coil Guard
Johnson UNT Controller, DFS, APS, SS Drain Pan, & Technicoat Cond Coils
Johnson UNT Controller, DFS, APS, SS Drain Pan, & Technicoat Evap Coil
Johnson UNT Controller, DFS, APS, SS Drain Pan, & Technicoat Evap and Cond Coils
Johnson UNT Controller, DFS, APS, SS Drain Pan, Phase Monitor, Coil Guard, & Technicoat Evap and Cond Coils
Unitary Products Group
5
164015-YIM-A-0905
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HK
HL
HM
HN
HP
HQ
HR
HS
HT
HU
HV
HW
HX
WA
WB
WC
WD
WE
WF
WG
WH
WJ
WK
WL
WM
WN
WP
WQ
WR
WS
WT
WU
WV
WW
WX
NA
NB
NC
ND
NE
NF
NG
NH
NJ
NK
NL
NM
NN
NP
NQ
6
Additional Options
Honeywell Excel 10 Controller with Dirty Filter Switch & Air Proving Switch
Honeywell Excel 10 Controller, DFS, APS & Phase Monitor
Honeywell Excel 10 Controller, DFS, APS & Coil Guard
Honeywell Excel 10 Controller, DFS, APS, Phase Monitor, & Coil Guard
Honeywell Excel 10 Controller, DFS, APS & Technicoat Cond. Coil
Honeywell Excel 10 Controller, DFS, APS, Technicoat Cond. Coil, & Phase Monitor
Honeywell Excel 10 Controller, DFS, APS, Technicoat Cond. Coil, & Coil Guard
Honeywell Excel 10 Controller, DFS, APS, Technicoat Cond. Coil, Phase Monitor, & Coil Guard
Honeywell Excel 10 Controller, DFS, APS & Technicoat Evap. Coil
Honeywell Excel 10 Controller, DFS, APS, Technicoat Evap. Coil, & Phase Monitor
Honeywell Excel 10 Controller, DFS, APS, Technicoat Evap. Coil, & Coil Guard
Honeywell Excel 10 Controller, DFS, APS, Technicoat Evap. Coil, Phase Monitor, & Coil Guard
Honeywell Excel 10 Controller, DFS, APS & Technicoat Evap. & Cond Coils
Honeywell Excel 10 Controller, DFS, APS, Technicoat Evap. & Cond Coils, & Phase Monitor
Honeywell Excel 10 Controller, DFS, APS, Technicoat Evap. & Cond Coils, & Coil Guard
Honeywell Excel 10 Controller, DFS, APS, Technicoat Evap. & Cond Coils, Phase Monitor, & Coil Guard
Honeywell Excel 10 Controller, DFS, APS, SS Drain Pan
Honeywell Excel 10 Controller, DFS, APS, SS Drain Pan, Phase Monitor, & Coil Guard
Honeywell Excel 10 Controller, DFS, APS, SS Drain Pan, & Technicoat Cond Coils
Honeywell Excel 10 Controller, DFS, APS, SS Drain Pan, & Technicoat Evap Coil
Honeywell Excel 10 Controller, DFS, APS, SS Drain Pan, & Technicoat Evap and Cond Coils
Honeywell Excel 10 Controller, DFS, APS, SS Drain Pan, Phase Monitor, Coil Guard, & Technicoat Evap and Cond Coils
Intelli-Comfort w/ModLINC Controller
Intelli-Comfort w/ModLINC Controller, & Phase Monitor
Intelli-Comfort w/ModLINC Controller, & Coil Guard
Intelli-Comfort w/ModLINC Controller, Phase Monitor, & Coil Guard
Intelli-Comfort w/ModLINC Controller, & Technicoat Cond. Coil
Intelli-Comfort w/ModLINC Controller, Technicoat Cond. Coil, & Phase Monitor
Intelli-Comfort w/ModLINC Controller, Technicoat Cond. Coil, & Coil Guard
Intelli-Comfort w/ModLINC Controller, Technicoat Cond. Coil, Phase Monitor, & Coil Guard
Intelli-Comfort w/ModLINC Controller, & Technicoat Evap. Coil
Intelli-Comfort w/ModLINC Controller, Technicoat Evap. Coil, & Phase Monitor
Intelli-Comfort w/ModLINC Controller, Technicoat Evap. Coil, & Coil Guard
Intelli-Comfort w/ModLINC Controller, Technicoat Evap. Coil, Phase Monitor, & Coil Guard
Intelli-Comfort w/ModLINC Controller, & Technicoat Evap. & Cond Coils
Intelli-Comfort w/ModLINC Controller, Technicoat Evap. & Cond Coils, & Phase Monitor
Intelli-Comfort w/ModLINC Controller, Technicoat Evap. & Cond Coils, & Coil Guard
Intelli-Comfort w/ModLINC Controller, Technicoat Evap. & Cond Coils, Phase Monitor, & Coil Guard
Intelli-Comfort w/ModLINC Controller, SS Drain Pan
Intelli-Comfort w/ModLINC Controller, SS Drain Pan, Phase Monitor, & Coil Guard
Intelli-Comfort w/ModLINC Controller, SS Drain Pan, & Technicoat Cond Coils
Intelli-Comfort w/ModLINC Controller, SS Drain Pan, & Technicoat Evap Coil
Intelli-Comfort w/ModLINC Controller, SS Drain Pan, & Technicoat Evap and Cond Coils
Intelli-Comfort w/ModLINC Controller, SS Drain Pan, Phase Monitor, Coil Guard, & Technicoat Evap and Cond Coils
Novar ETC-3 Controller with Dirty Filter Switch & Air Proving Switch
Novar ETC-3 Controller, DFS, APS & Phase Monitor
Novar ETC-3 Controller, DFS, APS & Coil Guard
Novar ETC-3 Controller, DFS, APS, Phase Monitor, & Coil Guard
Novar ETC-3 Controller, DFS, APS & Technicoat Cond. Coil
Novar ETC-3 Controller, DFS, APS, Technicoat Cond. Coil, & Phase Monitor
Novar ETC-3 Controller, DFS, APS, Technicoat Cond. Coil, & Coil Guard
Novar ETC-3 Controller, DFS, APS, Technicoat Cond. Coil, Phase Monitor, & Coil Guard
Novar ETC-3 Controller, DFS, APS & Technicoat Evap. Coil
Novar ETC-3 Controller, DFS, APS, Technicoat Evap. Coil, & Phase Monitor
Novar ETC-3 Controller, DFS, APS, Technicoat Evap. Coil, & Coil Guard
Novar ETC-3 Controller, DFS, APS, Technicoat Evap. Coil, Phase Monitor, & Coil Guard
Novar ETC-3 Controller, DFS, APS & Technicoat Evap. & Cond Coils
Novar ETC-3 Controller, DFS, APS, Technicoat Evap. & Cond Coils, & Phase Monitor
Novar ETC-3 Controller, DFS, APS, Technicoat Evap. & Cond Coils, & Coil Guard
Unitary Products Group
164015-YIM-A-0905
NR
NS
NT
NU
NV
NW
NX
LA
LB
LC
LD
LE
LF
LG
LH
LJ
LK
LL
LM
LN
LP
LQ
LR
LS
LT
LU
LV
LW
LX
TA
TB
TC
TD
TE
TF
TG
TH
TJ
TK
TL
TM
TN
TP
TQ
TR
TS
TT
TU
TV
TW
TX
TY
TZ
T1
T3
T4
T6
T7
T9
Additional Options
Novar ETC-3 Controller, DFS, APS, Technicoat Evap. & Cond Coils, Phase Monitor, & Coil Guard
Novar ETC-3 Controller, DFS, APS, SS Drain Pan
Novar ETC-3 Controller, DFS, APS, SS Drain Pan, Phase Monitor, & Coil Guard
Novar ETC-3 Controller, DFS, APS, SS Drain Pan, & Technicoat Cond Coils
Novar ETC-3 Controller, DFS, APS, SS Drain Pan, & Technicoat Evap Coil
Novar ETC-3, DFS, APS, SS Drain Pan, & Technicoat Evap and Cond Coils
Novar ETC-3 Controller, DFS, APS, SS Drain Pan, Phase Monitor, Coil Guard, & Technicoat Evap and Cond Coils
Simplicity Intelli-Comfort Controller
Simplicity Intelli-Comfort Controller, & Phase Monitor
Simplicity Intelli-Comfort Controller, & Coil Guard
Simplicity Intelli-Comfort Controller, Phase Monitor, & Coil Guard
Simplicity Intelli-Comfort Controller, & Technicoat Cond. Coil
Simplicity Intelli-Comfort Controller, Technicoat Cond. Coil, & Phase Monitor
Simplicity Intelli-Comfort Controller, Technicoat Cond. Coil, & Coil Guard
Simplicity Intelli-Comfort Controller, Technicoat Cond. Coil, Phase Monitor, & Coil Guard
Simplicity Intelli-Comfort Controller, & Technicoat Evap. Coil
Simplicity Intelli-Comfort Controller, Technicoat Evap. Coil, & Phase Monitor
Simplicity Intelli-Comfort Controller, Technicoat Evap. Coil, & Coil Guard
Simplicity Intelli-Comfort Controller, Technicoat Evap. Coil, Phase Monitor, & Coil Guard
Simplicity Intelli-Comfort Controller, & Technicoat Evap. & Cond Coils
Simplicity Intelli-Comfort Controller, Technicoat Evap. & Cond Coils, & Phase Monitor
Simplicity Intelli-Comfort Controller, Technicoat Evap. & Cond Coils, & Coil Guard
Simplicity Intelli-Comfort Controller, Technicoat Evap. & Cond Coils, Phase Monitor, & Coil Guard
Simplicity Intelli-Comfort Controller, SS Drain Pan
Simplicity Intelli-Comfort Controller, SS Drain Pan, Phase Monitor, & Coil Guard
Simplicity Intelli-Comfort Controller, SS Drain Pan, & Technicoat Cond Coils
Simplicity Intelli-Comfort Controller, SS Drain Pan, & Technicoat Evap Coil
Simplicity Intelli-Comfort Controller, SS Drain Pan, & Technicoat Evap and Cond Coils
Simplicity Intelli-Comfort Controller, SS Drain Pan, Phase Monitor, Coil Guard, & Technicoat Evap and Cond Coils
Technicoat Condenser Coil
Technicoat Condenser Coil & Phase Monitor
Technicoat Condenser Coil & Coil Guard
Technicoat Condenser Coil & Dirty Filter Switch
Technicoat Condenser Coil, Phase Monitor, & Coil Guard
Technicoat Condenser Coil, Phase Monitor, & Dirty Filter Switch
Technicoat Condenser Coil, Coil Guard, & Dirty Filter Switch
Technicoat Condenser Coil, Phase Monitor, Coil Guard, & Dirty Filter Switch
Technicoat Evaporator Coil
Technicoat Evaporator Coil & Phase Monitor
Technicoat Evaporator Coil & Coil Guard
Technicoat Evaporator Coil & Dirty Filter Switch
Technicoat Evaporator Coil, Phase Monitor, & Coil Guard
Technicoat Evaporator Coil, Phase Monitor, & Dirty Filter Switch
Technicoat Evaporator Coil, Coil Guard, & Dirty Filter Switch
Technicoat Evaporator Coil, Phase Monitor, Coil Guard, & Dirty Filter Switch
Technicoat Evaporator & Condenser Coils
Technicoat Evaporator & Condenser Coils & Phase Monitor
Technicoat Evaporator & Condenser Coils & Coil Guard
Technicoat Evaporator & Condenser Coils & Dirty Filter Switch
Technicoat Evaporator & Condenser Coils, Phase Monitor, & Coil Guard
Technicoat Evaporator & Condenser Coils, Phase Monitor, & Dirty Filter Switch
Technicoat Evaporator & Condenser Coils, Coil Guard, & Dirty Filter Switch
Technicoat Evaporator & Condenser Coils, Phase Monitor, Coil Guard, & Dirty Filter Switch
Technicoat Condenser & SS Drain Pan
Technicoat Condenser Coil, SS Drain Pan, Phase Monitor, Coil Guard, & Dirty Filter Switch
Technicoat Evaporator & SS Drain Pan
Technicoat Evaporator Coil, SS Drain Pan, Phase Monitor, Coil Guard, & Dirty Filter Switch
Technicoat Evaporator & Condenser Coils & SS Drain Pan
Technicoat Evaporator & Condenser Coils, SS Drain Pan, Phase Monitor, Coil Guard, & Dirty Filter Switch
Unitary Products Group
7
164015-YIM-A-0905
Installation
4.
Remove the toolless doorknobs and instruction packet
prior to installation.
Installation Safety Information
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Read these instructions before continuing this appliance
installation. This is an outdoor combination heating and cooling
unit. The installer must assure that these instructions are made
available to the consumer and with instructions to retain them
for future reference.
1.
Refer to the unit rating plate for the approved type of gas
for this product.
2.
Install this unit only in a location and position as specified
on Page 10 of these instructions.
3.
Never test for gas leaks with an open flame. Use
commercially available soap solution made specifically for
the detection of leaks when checking all connections, as
specified on Pages 8, 32, 33 and 57 of these instructions.
4.
Always install furnace to operate within the furnace's
intended temperature-rise range with the duct system and
within the allowable external static pressure range, as
specified on the unit name/rating plate, specified on
Page 59 of these instructions.
5.
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Figure 2: Condenser Covering
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This equipment is not to be used for temporary heating of
buildings or structures under construction.
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FIRE OR EXPLOSION HAZARD
Failure to follow the safety warning exactly could result
in serious injury, death or property damage.
Never test for gas leaks with an open flame. use a
commercially available soap solution made specifically
for the detection of leaks to check all connections. A fire
or explosion may result causing property damage,
personal injury or loss of life.
Figure 3: Compressor Section
Limitations
These units must be installed in accordance with the following:
In U.S.A.:
1.
Preceding Installation
1.
Remove the two screws holding the brackets in the front,
rear and compressor side fork-lift slots.
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Figure 1: Unit Shipping Bracket
2.
3.
8
Turn each bracket toward the ground and the protective
plywood covering will drop to the ground.
Remove the condenser coil external protective covering
prior to operation.
National Electrical Code, ANSI/NFPA No. 70 - Latest
Edition
2.
National Fuel Gas Code, ANSI Z223.1 - Latest Edition
3.
Gas-Fired Central Furnace Standard, ANSI Z21.47a. Latest Edition
4.
Local building codes, and
5.
Local gas utility requirements
In Canada:
1.
Canadian Electrical Code, CSA C22.1
2.
Installation Codes, CSA - B149.1.
3.
Local plumbing and waste water codes, and
4.
Other applicable local codes.
Refer to unit application data found in this document.
Unitary Products Group
164015-YIM-A-0905
After installation, gas fired units must be adjusted to obtain a
temperature rise within the range specified on the unit rating
plate.
Size of unit for proposed installation should be based on heat
loss/heat gain calculation made according to the methods of Air
Conditioning Contractors of America (ACCA).
If components are to be added to a unit to meet local codes,
they are to be installed at the dealer’s and/or customer’s
expense.
This furnace is not to be used for temporary heating of buildings
or structures under construction.
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Figure 4: Predator® Component Location (ZH120 Shown)
Unitary Products Group
9
164015-YIM-A-0905
Table 1:
ZH078-150 Unit Limitations
Unit Limitations
Size
(Tons)
078
(6.5)
090
(7.5)
102
(8.5)
120
(10)
150
(12.5)
Model
Unit Voltage
Applied Voltage
Outdoor DB Temp
Min
Max
Max (°F)
208/230-3-60
187
252
125
460-3-60
432
504
125
575-3-60
540
630
125
208/230-3-60
187
252
125
460-3-60
432
504
125
575-3-60
540
630
125
208/230-3-60
187
252
125
460-3-60
432
504
125
575-3-60
540
630
125
208/230-3-60
187
252
125
460-3-60
432
504
125
575-3-60
540
630
125
208/230-3-60
187
252
125
460-3-60
432
504
125
575-3-60
540
630
125
ZH
ZH
ZH
ZH
ZH
Location
Clearances
Use the following guidelines to select a suitable location for
these units:
All units require particular clearances for proper operation and
service. Installer must make provisions for adequate
combustion and ventilation air in accordance with section 5.3 of
Air for Combustion and Ventilation of the National Fuel Gas
Code, ANSI Z223.1 – Latest Edition (in U.S.A.), or Sections 7.2,
7.3, or 7.4 of Gas Installation Codes, CSA-B149.1 (in Canada) Latest Edition, and/or applicable provisions of the local building
codes. Refer to Table 5 for clearances required for combustible
construction, servicing, and proper unit operation.
1.
Unit is designed for outdoor installation only.
2.
Condenser coils must have an unlimited supply of air.
Where a choice of location is possible, position the unit on
either north or east side of building.
3.
Suitable for mounting on roof curb.
4.
For ground level installation, use a level concrete slab with
a minimum thickness of 4 inches. The length and width
should be at least 6 inches greater than the unit base rails.
Do not tie slab to the building foundation.
5.
Roof structures must be able to support the weight of the
unit and its options/accessories. Unit must be installed on a
solid, level roof curb or appropriate angle iron frame.
6.
Maintain level tolerance to 1/2” across the entire width and
length of unit.
Excessive exposure of this furnace to contaminated
combustion air may result in equipment damage or
personal injury. Typical contaminates include:
permanent wave solution, chlorinated waxes and
cleaners, chlorine based swimming pool chemicals,
water softening chemicals, carbon tetrachloride,
Halogen type refrigerants, cleaning solvents (e.g.
perchloroethylene), printing inks, paint removers,
varnishes, hydrochloric acid, cements and glues,
antistatic fabric softeners for clothes dryers, masonry
acid washing materials.
10
Do not permit overhanging structures or shrubs to
obstruct condenser air discharge outlet, combustion air
inlet or vent outlets.
Rigging And Handling
Exercise care when moving the unit. Do not remove any
packaging until the unit is near the place of installation. Rig the
unit by attaching chain or cable slings to the lifting holes
provided in the base rails. Spreader bars, whose length
exceeds the largest dimension across the unit, MUST be used
across the top of the unit.
If a unit is to be installed on a roof curb other than a
York® roof curb, gasketing must be applied to all
surfaces that come in contact with the unit underside.
Unitary Products Group
164015-YIM-A-0905
Before lifting, make sure the unit weight is distributed
equally on the rigging cables so it will lift evenly.
Units may be moved or lifted with a forklift. Slotted openings in
the base rails are provided for this purpose.
LENGTH OF FORKS MUST BE A MINIMUM OF 60 INCHES.
FRONT
LEFT
All panels must be secured in place when the unit is
lifted.
D
C
B
A
E
F
The condenser coils should be protected from rigging
cable damage with plywood or other suitable material.
Figure 6: Unit 6 Point Load Weight
Y
X
FRONT
LEFT
Figure 7: Center of Gravity
FRONT
LEFT
B
C
A
D
Figure 5: Unit 4 Point Load Weight
Table 2:
Weights and Dimensions
Weight (lbs.)
Center of Gravity
Size
Model
(Tons)
Shipping Operating
X
Y
078
ZH
905
900
38
23
(6.5)
090
ZH
925
920
38
23
(7.5)
102
ZH
1140
1135
38
25.5
(8.5)
120
ZH
1140
1135
38
25.5
(10)
150
ZH
1405
1400
51
25.5
(12.5)
Unitary Products Group
4 Point Load Location (lbs.)
A
B
C
D
A
6 Point Load Location (lbs.)
B
C
D
E
F
201
150
234
315
141
115
95
149
180
221
206
153
240
322
144
117
97
152
184
225
281
209
275
369
197
160
133
175
211
259
281
209
275
369
197
160
133
175
211
259
258
347
456
339
164
198
243
319
260
216
11
164015-YIM-A-0905
Table 3:
ZH078-150 Unit Accessory Weights
Unit Accessory
Economizer
Power Exhaust
Electric Heat1
Gas Heat2
Weight (lbs.)
Shipping
Operating
90
85
155
150
80
80
110
110
1. Weight given is for the maximum heater size available (54KW).
2. Weight given is for the maximum number of tube heat exchangers
available (8 tube).
Figure 8: ZH078-120 Physical Dimensions
Figure 9: ZH150 Physical Dimensions
12
Unitary Products Group
164015-YIM-A-0905
Table 4:
ZH078-150 Unit Physical Dimensions
Unit Model Number
A
42
42
50 3/4
50 3/4
50 3/4
ZH078
ZH090
ZH102
ZH120
ZH150
Detail A
B
89
89
89
89
119 1/2
Base
Pan
17-13/16
E
15 3/16
15 3/16
17 3/16
17 3/16
17 3/16
F
6 3/16
6 3/16
6 3/16
6 3/16
6 3/16
Detail B
Gas Pipe Inlet
5-1/4
Dimension (in.)
C
D
22 1/8
18 3/16
22 1/8
18 3/16
30 3/16
24 3/16
30 3/16
24 3/16
30 3/16
24 3/16
View of Wall Across from Coil
Table 5:
ZH078-150 Unit Clearances
Direction
Top1
Front
Rear
Distance (in.)
72
36
36
Direction
Right
Left
Bottom2
Distance (in.)
12
36
0
1. Units must be installed outdoors. Over hanging structure or shrubs should not obscure condenser air discharge outlet.
2. Units may be installed on combustable floors made from wood or class A, B or C roof covering materials.
Figure 10: ZH078-150 Unit Bottom Duct Openings
Unitary Products Group
13
164015-YIM-A-0905
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Figure 11: ZH078-150 Unit Electrical Entry
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Figure 12: ZH078-120 Unit Side Duct Openings
14
Unitary Products Group
164015-YIM-A-0905
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Figure 13: ZH150 Unit Side Duct Openings
Table 6:
Side Duct Dimensions
Unit Model Number
Dimension (in.)
A
B
C
D
ZH078
27 3/4
12 1/16
27 1/2
16
ZH090
27 3/4
12 1/16
27 1/2
16
ZH102
28 1/4
18 1/16
28 1/4
18 1/4
ZH120
28 1/4
18 1/16
28 1/4
18 1/4
ZH150
28 1/4
18 1/16
28 1/4
18 1/4
Figure 14: ZH078-150 Unit Left Duct Opening
Unitary Products Group
15
164015-YIM-A-0905
RIGHT
80-5/8
INSULATED DECK UNDER
CONDENSER SECTION
20
SUPPLY
20
6
RETURN
2 TYP.
30
INSULATED DECK UNDER
COMPRESSOR SECTION
50-1/2
FRONT
8 or 14
Figure 15: ZH078-150 Roof Curb
7<3
5(7851
6833/<
)5217
5,*+7
Figure 16: ZH078-150 Transition Roof Curb
Ductwork
Ductwork should be designed and sized according to the
methods in Manual D of the Air Conditioning Contractors of
America (ACCA) or as recommended by any other recognized
authority such as ASHRAE or SMACNA.
A closed return duct system should be used. This will not
preclude use of economizers or outdoor fresh air intake. The
16
supply and return air duct connections at the unit should be
made with flexible joints to minimize noise.
The supply and return air duct systems should be designed for
the CFM and static pressure requirements of the job. They
should NOT be sized to match the dimensions of the duct
connections on the unit.
Refer to Figure 10 for bottom air duct openings. Refer to
Figures 12, 13 and Table 6 for side air duct openings.
Unitary Products Group
164015-YIM-A-0905
Duct Covers
Units are shipped with the side duct openings covered and a
covering over the bottom of the unit. For bottom duct
application, no duct cover changes are necessary. For side
duct application, remove the side duct covers and install over
the bottom duct openings. The panels removed from the side
duct connections are designed to be reused by securing each
panel to its respective downflow opening. But keep in mind that
the supply panel is installed with the painted surface UP, facing
the heat exchanger, while the return panel is installed with the
painted surface DOWN, facing the downflow duct opening. The
supply panel is secured with the bracket (already in place from
the factory) and two screws. It’s a snug fit for the panel when
sliding it between the heat exchanger and unit bottom, but there
is room. The return panel is secured with four screws.
When fastening ductwork to side duct flanges on unit,
insert screws through duct flanges only. DO NOT insert
screws through casing. Outdoor ductwork must be
insulated and water-proofed.
Figure 19: Discharge Panel In Place
Condensate Drain
The side condensate drain is reversible and maybe re-oriented to
the rear of the cabinet to facilitate condensate piping. A
condensate drain connection is available through the base pan
for piping inside the roof curb. Trap the connection per Figure 20.
The trap and drain lines should be protected from freezing.
Plumbing must conform to local codes. Use a sealing compound
on male pipe threads. Install condensate drain line from the 3/4
inch NPT female connection on the unit to an open drain.
237,21$/&2,/
*8$5'
0LQLPXP
Figure 17: Side Panels With Hole Plugs
NOTE: Orientation. Panel is “insulation” side up.
Figure 20: Condensate Drain
Compressors
The scroll compressor used in this product is specifically
designed to operate with R-410A Refrigerant and cannot be
interchanged.
Figure 18: Return Downflow Plenum With Panel
This system uses R-410A Refrigerant which operates at
higher pressures than R-22. No other refrigerant may be
used in this system.
The compressor also uses a polyolester (POE oil), Mobil 3MA
POE. This oil is extremely hygroscopic, meaning it absorbs water
readily. POE oil can absorb 15 times as much water as other oils
Unitary Products Group
17
164015-YIM-A-0905
designed for HCFC and CFC refrigerants. Take all necessary
precautions to avoid exposure of the oil to the atmosphere.
Do not leave the system open to the atmosphere. Unit
damage could occur due to moisture being absorbed by
the POE oil in the system. This type of oil is highly
susceptible to moisture absorption
POE (polyolester) compressor lubricants are known to cause
long term damage to some synthetic roofing materials.
Exposure, even if immediately cleaned up, may cause
embrittlement (leading to cracking) to occur in one year
or more. When performing any service that may risk
exposure of compressor oil to the roof, take precautions
to protect roofing.
Procedures which risk oil leakage include, but are not limited to,
compressor replacement, repairing refrigerant leaks, replacing
refrigerant components such as filter drier, pressure switch,
metering device or coil.
Units are shipped with compressor mountings which are
factory-adjusted and ready for operation.
Do not loosen compressor mounting bolts.
Filters
Two-inch filters are supplied with each unit. One-inch filters may
be used with no modification to the filter racks. Filters must
always be installed ahead of evaporator coil and must be kept
clean or replaced with same size and type. Dirty filters reduce
the capacity of the unit and result in frosted coils or safety
shutdown. Refer to physical data tables, for the number and
size of filters needed for the unit. The unit should not be
operated without filters properly installed.
70 – Latest Edition (in U.S.A.), current Canadian Electrical
Code C221, and/or local ordinances. The unit must be
electrically grounded in accordance with NEC and CEC as
specified above and/or local codes.
Voltage tolerances which must be maintained at the
compressor terminals during starting and running conditions are
indicated on the unit Rating Plate and Table 1.
The internal wiring harnesses furnished with this unit are an
integral part of the design certified unit. Field alteration to
comply with electrical codes should not be required. If any of
the wire supplied with the unit must be replaced, replacement
wire must be of the type shown on the wiring diagram and the
same minimum gauge as the replaced wire.
A disconnect must be utilized for these units. Factory installed
disconnects are available. If installing a disconnect (field
supplied or York International® supplied accessory), refer to
Figure 4 for the recommended mounting location.
Avoid damage to internal components if drilling holes for
disconnect mounting.
NOTE: Since not all local codes allow the mounting of a
disconnect on the unit, please confirm compliance with
local code before mounting a disconnect on the unit.
Electrical line must be sized properly to carry the load. USE
COPPER CONDUCTORS ONLY. Each unit must be wired with
a separate branch circuit fed directly from the meter panel and
properly fused.
Refer to Figures 21, 22, 23 and 24 for typical field wiring and to
the appropriate unit wiring diagram mounted inside control
doors for control circuit and power wiring information.
When connecting electrical power and control wiring to
the unit, water-proof connectors must be used so that
water or moisture cannot be drawn into the unit during
normal operation. The above water-proofing conditions
will also apply when installing a field supplied disconnect
switch.
Power Wiring Detail
Make sure that panel latches are properly positioned on
the unit to maintain an airtight seal.
Power And Control Wiring
Units are factory wired for the voltage shown on the unit
nameplate. Refer to Electrical Data Table 8 to size power
wiring, fuses, and disconnect switch.
Power wiring is brought into the unit through the side of the unit
or the basepan inside the curb.
Field wiring to the unit, fuses, and disconnects must conform to
provisions of National Electrical Code (NEC), ANSI/NFPA No.
18
Unitary Products Group
164015-YIM-A-0905
7(50,1$/%/2&.7%
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Figure 21: Field Wiring Disconnect - Cooling Unit With/Without Electric Heat
&217$&7250
7
7
7
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Figure 22: Field Wiring Disconnect - Cooling Unit With Gas Heat
Unitary Products Group
19
164015-YIM-A-0905
Thermostat Wiring
thermostat to the unit. Refer to Table 7 for control wire sizing
and maximum length.
The thermostat should be located on an inside wall
approximately 56 inch above the floor where it will not be
subject to drafts, sun exposure or heat from electrical fixtures or
appliances. Follow the manufacturer's instructions enclosed
with thermostat for general installation procedure. Seven (7)
color-coded, insulated wires should be used to connect the
Table 7:
Wire Size
Maximum Length1
18 AWG
150 Feet
1. From the unit to the thermostat and back to the unit.
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Figure 23: Electronic Thermostat Field Wiring
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Figure 24: Field Wiring 24 Volt Thermostat
20
Unitary Products Group
164015-YIM-A-0905
Table 8: Electrical Data
ZH078-150 Standard Motor - Without Powered Convenience Outlet
Size
(Tons)
Volt
Compressors
(each)
RLA LRA
MCC
OD Fan
Motors
(each)
Supply
Blower
Motor
Pwr
Exh
Motor
Pwt
Conv
Outlet
FLA
FLA
FLA
FLA
208
12.8
95.0
20.0
1.5
6.2
5.5
0.0
230
12.8
95.0
20.0
1.5
6.2
5.5
0.0
460
6.4
45.0
10.0
0.8
3.1
2.2
0.0
575
5.4
38.0
8.5
0.6
2.4
1.8
0.0
208
14.7 115.0 23.0
1.5
8.2
5.5
0.0
230
14.7 115.0 23.0
1.5
8.2
5.5
0.0
460
7.7
50.0
12.0
0.8
4.1
2.2
0.0
575
6.4
40.0
10.0
0.6
3.6
1.8
0.0
208
16.0 120.0 25.0
3.5
8.2
5.5
0.0
230
16.0 120.0 25.0
3.5
8.2
5.5
0.0
460
8.3
60.0
13.0
1.6
4.1
2.2
0.0
575
6.7
40.0
10.5
1.3
3.6
1.8
0.0
078
(6.5)
090
(7.5)
102
(8.5)
Unitary Products Group
Electric Heat Option
MCA1
(Amps)
Model
kW
Stages
Amps
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
6.8
13.5
18.0
25.5
9.0
18.0
24.0
34.0
9.0
18.0
24.0
34.0
9.0
18.0
24.0
34.0
6.8
13.5
18.0
25.5
9.0
18.0
24.0
34.0
9.0
18.0
24.0
34.0
9.0
18.0
24.0
34.0
6.8
13.5
18.0
25.5
9.0
18.0
24.0
34.0
9.0
18.0
24.0
34.0
9.0
18.0
24.0
34.0
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
18.9
37.5
50.0
70.8
22.6
45.2
60.2
85.3
11.3
22.6
30.1
42.7
9.0
18.1
24.1
34.1
18.9
37.5
50.0
70.8
22.6
45.2
60.2
85.3
11.3
22.6
30.1
42.7
9.0
18.1
24.1
34.1
18.9
37.5
50.0
70.8
22.6
45.2
60.2
85.3
11.3
22.6
30.1
42.7
9.0
18.1
24.1
34.1
38.0
38.0
54.6
70.2
96.2
38.0
38.0
61.9
79.9
110.0
19.1
19.1
30.9
40.0
55.0
15.8
15.8
24.7
31.9
43.9
44.3
44.3
57.1
72.7
98.7
44.3
44.3
64.4
82.4
112.5
23.0
23.0
32.2
41.2
56.2
19.2
19.2
26.2
33.4
45.4
51.2
51.2
57.1
72.7
98.7
51.2
51.2
64.4
82.4
112.5
26.0
26.0
32.2
41.2
56.2
21.3
21.3
26.2
33.4
45.4
MCA1
w/Pwr
Exh
(Amps)
43.5
43.5
61.5
77.1
103.1
43.5
43.5
68.8
86.8
116.9
21.3
21.3
33.7
42.7
57.7
17.6
17.6
26.9
34.1
46.1
49.8
49.8
64.0
79.6
105.6
49.8
49.8
71.3
89.3
119.4
25.2
25.2
34.9
44.0
59.0
21.0
21.0
28.4
35.6
47.6
56.7
56.7
64.0
79.6
105.6
56.7
56.7
71.3
89.3
119.4
28.2
28.2
34.9
44.0
59.0
23.1
23.1
28.4
35.6
47.6
2
Max Fuse2/ Max Fuse3 /
Breaker3 Breaker
Size w/
Size
Pwr Exh
(Amps)
(Amps)
50
50
50
50
60
70
80
80
100
110
50
50
50
50
70
70
80
90
110
125
25
25
25
25
35
35
40
45
60
60
20
20
20
20
25
30
35
35
45
50
50
60
50
60
60
70
80
80
100
110
50
60
50
60
70
80
90
90
125
125
30
30
30
30
35
35
45
45
60
60
25
25
25
25
30
30
35
40
50
50
60
70
60
70
60
70
80
80
100
110
60
70
60
70
70
80
90
90
125
125
30
35
30
35
35
35
45
45
60
60
25
25
25
25
30
30
35
40
50
50
21
164015-YIM-A-0905
ZH078-150 Standard Motor - Without Powered Convenience Outlet (Continued)
Size
(Tons)
Volt
Compressors
(each)
RLA LRA
MCC
OD Fan
Motors
(each)
Supply
Blower
Motor
Pwr
Exh
Motor
Pwt
Conv
Outlet
FLA
FLA
FLA
FLA
208
17.9 120.0 28.0
3.5
8.2
5.5
0.0
230
17.9 120.0 28.0
3.5
8.2
5.5
0.0
460
9.6
70.0
15.0
1.6
4.1
2.2
0.0
575
7.4
53.0
11.5
1.3
3.6
1.8
0.0
208
25.0 149.0 35.0
1.5
10.9
5.5
0.0
230
25.0 149.0 35.0
1.5
10.9
5.5
0.0
460
11.8
75.0
16.5
0.8
5.3
2.2
0.0
575
8.6
54.0
12.0
0.6
4.1
1.8
0.0
120
(10)
150
(12.5)
Electric Heat Option
MCA
(Amps)
MCA1
w/Pwr
Exh
(Amps)
55.5
57.1
72.7
98.7
151.1
55.5
64.4
82.4
112.5
140.2
28.9
32.2
41.2
56.2
70.1
22.9
26.2
33.4
45.4
56.5
73.2
73.2
76.1
102.1
154.5
73.2
73.2
85.8
115.9
143.5
35.1
35.1
42.7
57.7
71.6
25.9
26.8
34.0
46.0
57.1
61.0
64.0
79.6
105.6
158.0
61.0
71.3
89.3
119.4
147.0
31.1
34.9
44.0
59.0
72.8
24.7
28.4
35.6
47.6
58.7
78.7
78.7
83.0
109.0
161.4
78.7
78.7
92.7
122.7
150.4
37.3
37.3
45.5
60.5
74.3
27.7
29.0
36.2
48.3
59.3
1
Model
kW
Stages
Amps
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
13.5
18.0
25.5
40.6
18.0
24.0
34.0
54.0
18.0
24.0
34.0
54.0
18.0
24.0
34.0
54.0
13.5
18.0
25.5
40.6
18.0
24.0
34.0
54.0
18.0
24.0
34.0
54.0
18.0
24.0
34.0
54.0
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
37.5
50.0
70.8
112.7
45.2
60.2
85.3
135.6
22.6
30.1
42.7
67.8
18.1
24.1
34.1
54.2
37.5
50.0
70.8
112.7
45.2
60.2
85.3
135.6
22.6
30.1
42.7
67.8
18.1
24.1
34.1
54.2
2
Max Fuse2/ Max Fuse3 /
Breaker3 Breaker
Size w/
Size
Pwr Exh
(Amps)
(Amps)
70
70
70
70
80
80
100
110
175
175
70
70
70
80
90
90
125
125
150
175
35
40
35
40
45
45
60
60
80
80
30
30
30
30
35
40
50
50
70
70
90
100
90
100
90
100
110
110
175
175
90
100
90
100
90
100
125
125
175
175
45
45
45
45
45
50
60
70
80
80
30
35
30
35
35
40
50
50
70
70
1. Minimum Circuit Ampacity.
2. Dual Element, Time Delay Type.
3. HACR type per NEC.
22
Unitary Products Group
164015-YIM-A-0905
ZH078-150 Alternate Motor - Without Powered Convenience Outlet
Size
(Tons)
Volt
Compressors
(each)
RLA LRA
MCC
OD Fan
Motors
(each)
Supply
Blower
Motor
Pwr
Exh
Motor
Pwt
Conv
Outlet
FLA
FLA
FLA
FLA
208
12.8
95.0
20.0
1.5
8.2
5.5
0.0
230
12.8
95.0
20.0
1.5
8.2
5.5
0.0
460
6.4
45.0
10.0
0.8
4.1
2.2
0.0
575
5.4
38.0
8.5
0.6
3.6
1.8
0.0
208
14.7 115.0 23.0
1.5
10.9
5.5
0.0
230
14.7 115.0 23.0
1.5
10.9
5.5
0.0
460
7.7
50.0
12.0
0.8
5.3
2.2
0.0
575
6.4
40.0
10.0
0.6
4.1
1.8
0.0
208
16.0 120.0 25.0
3.5
10.9
5.5
0.0
230
16.0 120.0 25.0
3.5
10.9
5.5
0.0
460
8.3
60.0
13.0
1.6
5.3
2.2
0.0
575
6.7
40.0
10.5
1.3
4.1
1.8
0.0
078
(6.5)
090
(7.5)
102
(8.5)
Unitary Products Group
Electric Heat Option
Model
kW
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
6.8
13.5
18.0
25.5
9.0
18.0
24.0
34.0
9.0
18.0
24.0
34.0
9.0
18.0
24.0
34.0
6.8
13.5
18.0
25.5
9.0
18.0
24.0
34.0
9.0
18.0
24.0
34.0
9.0
18.0
24.0
34.0
6.8
13.5
18.0
25.5
9.0
18.0
24.0
34.0
9.0
18.0
24.0
34.0
9.0
18.0
24.0
34.0
MCA1
(Amps)
MCA1
w/Pwr
Exh
(Amps)
40.0
40.0
57.1
72.7
98.7
40.0
40.0
64.4
82.4
112.5
20.1
20.1
32.2
41.2
56.2
17.0
17.0
26.2
33.4
45.4
47.0
47.0
60.5
76.1
102.1
47.0
47.0
67.8
85.8
115.9
24.2
24.2
33.7
42.7
57.7
19.7
19.7
26.8
34.0
46.0
53.9
53.9
60.5
76.1
102.1
53.9
53.9
67.8
85.8
115.9
27.2
27.2
33.7
42.7
57.7
21.8
21.8
26.8
34.0
46.0
45.5
45.5
64.0
79.6
105.6
45.5
45.5
71.3
89.3
119.4
22.3
22.3
34.9
44.0
59.0
18.8
18.8
28.4
35.6
47.6
52.5
52.5
67.3
83.0
109.0
52.5
52.5
74.6
92.7
122.7
26.4
26.4
36.4
45.5
60.5
21.5
21.5
29.0
36.2
48.3
59.4
59.4
67.3
83.0
109.0
59.4
59.4
74.6
92.7
122.7
29.4
29.4
36.4
45.5
60.5
23.6
23.6
29.0
36.2
48.3
Stages Amps
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
1
2
2
2
18.9
37.5
50.0
70.8
22.6
45.2
60.2
85.3
11.3
22.6
30.1
42.7
9.0
18.1
24.1
34.1
18.9
37.5
50.0
70.8
22.6
45.2
60.2
85.3
11.3
22.6
30.1
42.7
9.0
18.1
24.1
34.1
18.9
37.5
50.0
70.8
22.6
45.2
60.2
85.3
11.3
22.6
30.1
42.7
9.0
18.1
24.1
34.1
2
Max Fuse2/ Max Fuse3 /
Breaker
Breaker3
Size w/ Pwr
Size
Exh
(Amps)
(Amps)
50
50
50
50
60
70
80
80
100
110
50
50
50
50
70
80
90
90
125
125
25
25
25
25
35
35
45
45
60
60
20
20
20
20
30
30
35
40
50
50
60
60
60
60
70
70
80
90
110
110
60
60
60
60
70
80
90
100
125
125
30
30
30
30
35
40
45
50
60
70
25
25
25
25
30
30
35
40
50
50
60
70
60
70
70
70
80
90
110
110
60
70
60
70
70
80
90
100
125
125
35
35
35
35
35
40
45
50
60
70
25
30
25
30
30
30
35
40
50
50
23
164015-YIM-A-0905
ZH078-150 Alternate Motor - Without Powered Convenience Outlet (Continued)
Size
(Tons)
Volt
Compressors
(each)
RLA LRA
MCC
OD Fan
Motors
(each)
Supply
Blower
Motor
Pwr
Exh
Motor
Pwt
Conv
Outlet
FLA
FLA
FLA
FLA
208
17.9 120.0 28.0
3.5
10.9
5.5
0.0
230
17.9 120.0 28.0
3.5
10.9
5.5
0.0
460
9.6
70.0
15.0
1.6
5.3
2.2
0.0
575
7.4
53.0
11.5
1.3
4.1
1.8
0.0
208
25.0 149.0 35.0
1.5
16.1
5.5
0.0
230
25.0 149.0 35.0
1.5
16.1
5.5
0.0
460
11.8
75.0
16.5
0.8
8.1
2.2
0.0
575
8.6
54.0
12.0
0.6
6.0
1.8
0.0
120
(10)
150
(12.5)
Electric Heat Option
Model
kW
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
13.5
18.0
25.5
40.6
18.0
24.0
34.0
54.0
18.0
24.0
34.0
54.0
18.0
24.0
34.0
54.0
13.5
18.0
25.5
40.6
18.0
24.0
34.0
54.0
18.0
24.0
34.0
54.0
18.0
24.0
34.0
54.0
MCA
(Amps)
MCA1
w/Pwr
Exh
(Amps)
58.2
60.5
76.1
102.1
154.5
58.2
67.8
85.8
115.9
143.5
30.1
33.7
42.7
57.7
71.6
23.4
26.8
34.0
46.0
57.1
78.4
78.4
82.6
108.6
161.0
78.4
78.4
92.3
122.4
150.0
37.9
37.9
46.2
61.2
75.1
27.8
29.2
36.4
48.4
59.5
63.7
67.3
83.0
109.0
161.4
63.7
74.6
92.7
122.7
150.4
32.3
36.4
45.5
60.5
74.3
25.2
29.0
36.2
48.3
59.3
83.9
83.9
89.5
115.5
167.9
83.9
83.9
99.2
129.2
156.9
40.1
40.1
49.0
64.0
77.8
29.6
31.4
38.6
50.6
61.7
1
Stages Amps
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
37.5
50.0
70.8
112.7
45.2
60.2
85.3
135.6
22.6
30.1
42.7
67.8
18.1
24.1
34.1
54.2
37.5
50.0
70.8
112.7
45.2
60.2
85.3
135.6
22.6
30.1
42.7
67.8
18.1
24.1
34.1
54.2
2
Max Fuse2/ Max Fuse3 /
Breaker
3
Breaker
Size w/ Pwr
Size
Exh
(Amps)
(Amps)
70
80
70
80
80
90
110
110
175
175
70
80
70
80
90
100
125
125
175
175
35
40
35
40
45
50
60
70
80
80
30
30
30
30
35
40
50
50
70
70
100
100
100
100
100
100
110
125
175
175
100
100
100
100
100
100
125
150
175
175
45
50
45
50
50
50
70
70
90
90
35
35
35
35
40
40
50
60
70
70
1. Minimum Circuit Ampacity.
2. Dual Element, Time Delay Type.
3. HACR type per NEC.
24
Unitary Products Group
164015-YIM-A-0905
ZH078-150 Standard Motor - With Powered Convenience Outlet
Size
(Tons)
Volt
Compressors
(each)
RLA LRA
MCC
OD Fan
Motors
(each)
Supply
Blower
Motor
Pwr
Exh
Motor
Pwt
Conv
Outlet
FLA
FLA
FLA
FLA
208
12.8
95.0
20.0
1.5
6.2
5.5
10.0
230
12.8
95.0
20.0
1.5
6.2
5.5
10.0
460
6.4
45.0
10.0
0.8
3.1
2.2
5.0
575
5.4
38.0
8.5
0.6
2.4
1.8
4.0
208
14.7 115.0 23.0
1.5
8.2
5.5
10.0
230
14.7 115.0 23.0
1.5
8.2
5.5
10.0
460
7.7
50.0
12.0
0.8
4.1
2.2
5.0
575
6.4
40.0
10.0
0.6
3.6
1.8
4.0
208
16.0 120.0 25.0
3.5
8.2
5.5
10.0
230
16.0 120.0 25.0
3.5
8.2
5.5
10.0
460
8.3
60.0
13.0
1.6
4.1
2.2
5.0
575
6.7
40.0
10.5
1.3
3.6
1.8
4.0
078
(6.5)
090
(7.5)
102
(8.5)
Unitary Products Group
Electric Heat Option
Model
kW
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
–
6.8
13.5
18.0
25.5
–
9.0
18.0
24.0
34.0
–
9.0
18.0
24.0
34.0
–
9.0
18.0
24.0
34.0
–
6.8
13.5
18.0
25.5
–
9.0
18.0
24.0
34.0
–
9.0
18.0
24.0
34.0
–
9.0
18.0
24.0
34.0
–
6.8
13.5
18.0
25.5
–
9.0
18.0
24.0
34.0
–
9.0
18.0
24.0
34.0
–
9.0
18.0
24.0
34.0
MCA1
(Amps)
MCA1
w/Pwr
Exh
(Amps)
48.0
48.0
67.1
82.7
108.7
48.0
48.0
74.4
92.4
122.5
24.1
24.1
37.2
46.2
61.2
19.8
19.8
29.7
36.9
48.9
54.3
54.3
69.6
85.2
111.2
54.3
54.3
76.9
94.9
125.0
28.0
28.0
38.4
47.5
62.5
23.2
23.2
31.2
38.4
50.4
61.2
61.2
69.6
85.2
111.2
61.2
61.2
76.9
94.9
125.0
31.0
31.0
38.4
47.5
62.5
25.3
25.3
31.2
38.4
50.4
53.5
53.5
74.0
89.6
115.6
53.5
54.2
81.3
99.3
129.4
26.3
26.4
39.9
49.0
64.0
21.6
21.6
31.9
39.1
51.1
59.8
59.8
76.5
92.1
118.1
59.8
59.8
83.8
101.8
131.9
30.2
30.2
41.2
50.2
65.2
25.0
25.0
33.4
40.6
52.6
66.7
66.7
76.5
92.1
118.1
66.7
66.7
83.8
101.8
131.9
33.2
33.2
41.2
50.2
65.2
27.1
27.1
33.4
40.6
52.6
Stages Amps
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
18.9
37.5
50.0
70.8
–
22.6
45.2
60.2
85.3
–
11.3
22.6
30.1
42.7
–
9.0
18.1
24.1
34.1
–
18.9
37.5
50.0
70.8
–
22.6
45.2
60.2
85.3
–
11.3
22.6
30.1
42.7
–
9.0
18.1
24.1
34.1
–
18.9
37.5
50.0
70.8
–
22.6
45.2
60.2
85.3
–
11.3
22.6
30.1
42.7
–
9.0
18.1
24.1
34.1
2
Max Fuse2/ Max Fuse3 /
Breaker
Breaker3
Size w/ Pwr
Size
Exh
(Amps)
(Amps)
60
60
60
60
70
80
90
90
110
125
60
60
60
60
80
90
100
100
125
150
30
30
30
30
40
40
50
50
70
70
25
25
25
25
30
35
40
40
50
60
60
70
60
70
70
80
90
100
125
125
60
70
60
70
80
90
100
110
125
150
35
35
35
35
40
45
50
60
70
70
25
30
25
30
35
35
40
45
60
60
70
80
70
80
70
80
90
100
125
125
70
80
70
80
80
90
100
110
125
150
35
40
35
40
40
45
50
60
70
70
30
30
30
30
35
35
40
45
60
60
25
164015-YIM-A-0905
ZH078-150 Standard Motor - With Powered Convenience Outlet (Continued)
Size
(Tons)
Volt
Compressors
(each)
RLA LRA
MCC
OD Fan
Motors
(each)
Supply
Blower
Motor
Pwr
Exh
Motor
Pwt
Conv
Outlet
FLA
FLA
FLA
FLA
208
17.9 120.0 28.0
3.5
8.2
5.5
10.0
230
17.9 120.0 28.0
3.5
8.2
5.5
10.0
460
9.6
70.0
15.0
1.6
4.1
2.2
5.0
575
7.4
53.0
11.5
1.3
3.6
1.8
4.0
208
25.0 149.0 35.0
1.5
10.9
5.5
10.0
230
25.0 149.0 35.0
1.5
10.9
5.5
10.0
460
11.8
75.0
16.5
0.8
5.3
2.2
5.0
575
8.6
54.0
12.0
0.6
4.1
1.8
4.0
120
(10)
150
(12.5)
Electric Heat Option
Model
kW
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
–
13.5
18.0
25.5
40.6
–
18.0
24.0
34.0
54.0
–
18.0
24.0
34.0
54.0
–
18.0
24.0
34.0
54.0
–
13.5
18.0
25.5
40.6
–
18.0
24.0
34.0
54.0
–
18.0
24.0
34.0
54.0
–
18.0
24.0
34.0
54.0
MCA
(Amps)
MCA1
w/Pwr
Exh
(Amps)
65.5
69.6
85.2
111.2
163.6
65.5
76.9
94.9
125.0
152.7
33.9
38.4
47.5
62.5
76.3
26.9
31.2
38.4
50.4
61.5
83.2
83.2
88.6
114.6
167.0
83.2
83.2
98.3
128.4
156.0
40.1
40.1
49.0
64.0
77.8
29.9
31.8
39.0
51.0
62.1
71.0
76.5
92.1
118.1
170.5
71.0
83.8
101.8
131.9
159.5
36.1
41.2
50.2
65.2
79.1
28.7
33.4
40.6
52.6
63.7
88.7
88.7
95.5
121.5
173.9
88.7
88.7
105.2
135.2
162.9
42.3
42.7
51.7
66.7
80.6
31.7
34.0
41.2
53.3
64.3
1
Stages Amps
–
2
2
2
2
–
2
2
2
2
–
2
2
2
2
–
2
2
2
2
–
2
2
2
2
–
2
2
2
2
–
2
2
2
2
–
2
2
2
2
–
37.5
50.0
70.8
112.7
–
45.2
60.2
85.3
135.6
–
22.6
30.1
42.7
67.8
–
18.1
24.1
34.1
54.2
–
37.5
50.0
70.8
112.7
–
45.2
60.2
85.3
135.6
–
22.6
30.1
42.7
67.8
–
18.1
24.1
34.1
54.2
2
Max Fuse2/ Max Fuse3 /
Breaker
3
Breaker
Size w/ Pwr
Size
Exh
(Amps)
(Amps)
80
80
80
80
90
100
125
125
175
175
80
80
80
90
100
110
125
150
175
175
40
45
40
45
50
60
70
70
90
90
30
35
35
35
40
45
60
60
70
70
100
110
100
110
100
110
125
125
175
175
100
110
100
110
100
110
150
150
175
175
50
50
50
50
50
60
70
70
90
90
35
40
35
40
40
45
60
60
70
70
1. Minimum Circuit Ampacity.
2. Dual Element, Time Delay Type.
3. HACR type per NEC.
26
Unitary Products Group
164015-YIM-A-0905
ZH078-150 Alternate Motor - With Powered Convenience Outlet
Size
(Tons)
Volt
Compressors
(each)
RLA LRA
MCC
OD Fan
Motors
(each)
Supply
Blower
Motor
Pwr
Exh
Motor
Pwt
Conv
Outlet
FLA
FLA
FLA
FLA
208
12.8
95.0
20.0
1.5
6.2
5.5
10.0
230
12.8
95.0
20.0
1.5
6.2
5.5
10.0
460
6.4
45.0
10.0
0.8
3.1
2.2
5.0
575
5.4
38.0
8.5
0.6
2.4
1.8
4.0
208
14.7 115.0 23.0
1.5
8.2
5.5
10.0
230
14.7 115.0 23.0
1.5
8.2
5.5
10.0
460
7.7
50.0
12.0
0.8
4.1
2.2
5.0
575
6.4
40.0
10.0
0.6
3.6
1.8
4.0
208
16.0 120.0 25.0
3.5
8.2
5.5
10.0
230
16.0 120.0 25.0
3.5
8.2
5.5
10.0
460
8.3
60.0
13.0
1.6
4.1
2.2
5.0
575
6.7
40.0
10.5
1.3
3.6
1.8
4.0
078
(6.5)
090
(7.5)
102
(8.5)
Unitary Products Group
Electric Heat Option
Model
kW
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
None
E09
E18
E24
E36
–
6.8
13.5
18.0
25.5
–
9.0
18.0
24.0
34.0
–
9.0
18.0
24.0
34.0
–
9.0
18.0
24.0
34.0
–
6.8
13.5
18.0
25.5
–
9.0
18.0
24.0
34.0
–
9.0
18.0
24.0
34.0
–
9.0
18.0
24.0
34.0
–
6.8
13.5
18.0
25.5
–
9.0
18.0
24.0
34.0
–
9.0
18.0
24.0
34.0
–
9.0
18.0
24.0
34.0
MCA1
(Amps)
MCA1
w/Pwr
Exh
(Amps)
50.0
50.0
69.6
85.2
111.2
50.0
50.0
76.9
94.9
125.0
25.1
25.1
38.4
47.5
62.5
21.0
21.0
31.2
38.4
50.4
57.0
57.0
73.0
88.6
114.6
57.0
57.0
80.3
98.3
128.4
29.2
29.2
39.9
49.0
64.0
23.7
23.7
31.8
39.0
51.0
63.9
63.9
73.0
88.6
114.6
63.9
63.9
80.3
98.3
128.4
32.2
32.2
39.9
49.0
64.0
25.8
25.8
31.8
39.0
51.0
55.5
55.5
76.5
92.1
118.1
55.5
56.7
83.8
101.8
131.9
27.3
27.7
41.2
50.2
65.2
22.8
22.8
33.4
40.6
52.6
62.5
62.5
79.8
95.5
121.5
62.5
62.5
87.1
105.2
135.2
31.4
31.4
42.7
51.7
66.7
25.5
25.5
34.0
41.2
53.3
69.4
69.4
79.8
95.5
121.5
69.4
69.4
87.1
105.2
135.2
34.4
34.4
42.7
51.7
66.7
27.6
27.6
34.0
41.2
53.3
Stages Amps
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
1
2
2
2
–
18.9
37.5
50.0
70.8
–
22.6
45.2
60.2
85.3
–
11.3
22.6
30.1
42.7
–
9.0
18.1
24.1
34.1
–
18.9
37.5
50.0
70.8
–
22.6
45.2
60.2
85.3
–
11.3
22.6
30.1
42.7
–
9.0
18.1
24.1
34.1
–
18.9
37.5
50.0
70.8
–
22.6
45.2
60.2
85.3
–
11.3
22.6
30.1
42.7
–
9.0
18.1
24.1
34.1
2
Max Fuse2/ Max Fuse3 /
Breaker
Breaker3
Size w/ Pwr
Size
Exh
(Amps)
(Amps)
60
60
60
60
70
80
90
100
125
125
60
60
60
60
80
90
100
110
125
150
30
30
30
30
40
45
50
60
70
70
25
25
25
25
35
35
40
45
60
60
70
70
70
70
80
80
90
100
125
125
70
70
70
70
90
90
100
110
150
150
35
35
35
35
40
45
50
60
70
70
30
30
30
30
35
35
40
45
60
60
70
80
70
80
80
80
90
100
125
125
70
80
70
80
90
90
100
110
150
150
40
40
40
40
40
45
50
60
70
70
30
30
30
30
35
35
40
45
60
60
27
164015-YIM-A-0905
ZH078-150 Alternate Motor - With Powered Convenience Outlet (Continued)
Size
(Tons)
Volt
Compressors
(each)
RLA LRA
MCC
OD Fan
Motors
(each)
Supply
Blower
Motor
Pwr
Exh
Motor
Pwt
Conv
Outlet
FLA
FLA
FLA
FLA
208
17.9 120.0 28.0
3.5
8.2
5.5
10.0
230
17.9 120.0 28.0
3.5
8.2
5.5
10.0
460
9.6
70.0
15.0
1.6
4.1
2.2
5.0
575
7.4
53.0
11.5
1.3
3.6
1.8
4.0
208
25.0 149.0 35.0
1.5
10.9
5.5
10.0
230
25.0 149.0 35.0
1.5
10.9
5.5
10.0
460
11.8
75.0
16.5
0.8
5.3
2.2
5.0
575
8.6
54.0
12.0
0.6
4.1
1.8
4.0
120
(10)
150
(12.5)
Electric Heat Option
Model
kW
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
None
E18
E24
E36
E54
–
13.5
18.0
25.5
40.6
–
18.0
24.0
34.0
54.0
–
18.0
24.0
34.0
54.0
–
18.0
24.0
34.0
54.0
–
13.5
18.0
25.5
40.6
–
18.0
24.0
34.0
54.0
–
18.0
24.0
34.0
54.0
–
18.0
24.0
34.0
54.0
MCA
(Amps)
MCA1
w/Pwr
Exh
(Amps)
68.2
73.0
88.6
114.6
167.0
68.2
80.3
98.3
128.4
156.0
35.1
39.9
49.0
64.0
77.8
27.4
31.8
39.0
51.0
62.1
88.4
88.4
95.1
121.1
173.5
88.4
88.4
104.8
134.9
162.5
42.9
43.4
52.5
67.5
81.3
31.8
34.2
41.4
53.4
64.5
73.7
79.8
95.5
121.5
173.9
73.7
87.1
105.2
135.2
162.9
37.3
42.7
51.7
66.7
80.6
29.2
34.0
41.2
53.3
64.3
93.9
93.9
102.0
128.0
180.4
93.9
93.9
111.7
141.7
169.4
45.1
46.2
55.2
70.2
84.1
33.6
36.4
43.6
55.6
66.7
1
Stages Amps
–
2
2
2
2
–
2
2
2
2
–
2
2
2
2
–
2
2
2
2
–
2
2
2
2
–
2
2
2
2
–
2
2
2
2
–
2
2
2
2
–
37.5
50.0
70.8
112.7
–
45.2
60.2
85.3
135.6
–
22.6
30.1
42.7
67.8
–
18.1
24.1
34.1
54.2
–
37.5
50.0
70.8
112.7
–
45.2
60.2
85.3
135.6
–
22.6
30.1
42.7
67.8
–
18.1
24.1
34.1
54.2
2
Max Fuse2/ Max Fuse3 /
Breaker
3
Breaker
Size w/ Pwr
Size
Exh
(Amps)
(Amps)
80
90
80
90
90
100
125
125
175
175
80
90
90
90
100
110
150
150
175
175
40
45
40
45
50
60
70
70
90
90
30
35
35
35
40
45
60
60
70
70
110
110
110
110
110
110
125
150
175
200
110
110
110
110
110
125
150
150
175
175
50
50
50
50
60
60
70
80
90
90
40
40
40
40
45
45
60
60
70
70
1. Minimum Circuit Ampacity.
2. Dual Element, Time Delay Type.
3. HACR type per NEC.
28
Unitary Products Group
164015-YIM-A-0905
Table 9:
ZH078-150 Physical Data
Models
Component
ZH078
ZH090
ZH102
ZH120
ZH150
6.5
7.5
8.5
10
12.5
Gross Capacity @ ARI A point (Btu)
79000
93000
106000
126000
156000
ARI net capacity (Btu)
76000
90000
102000
122000
150000
EER
11.4
11.4
11.5
11.5
11.2
SEER
-
-
-
-
-
IPLV
12.7
12.4
12.4
12.1
12.7
Nominal CFM
2600
3000
3400
4000
5000
System power (KW)
6.67
7.90
8.87
10.61
13.40
R-410a
R-410a
R-410a
R-410a
R-410a
System 1
9-4
8-8
11-8
11-8
19-8
System 2
6-0
8-4
11-0
11-8
19-8
Nominal Tonnage
ARI COOLING PERFORMANCE
Refrigerant type
Refrigerant charge (lb-oz)
ARI HEATING PERFORMANCE
Heating model
10
15
10
15
10
15
15
20
15
20
Heat input (K Btu)
120
180
120
180
120
180
180
240
180
240
Heat output (K Btu)
96
144
96
144
96
144
144
192
144
192
-
-
-
-
-
-
-
-
-
-
Steady state efficiency (%)
80
80
80
80
80
80
80
80
80
80
No. burners
4
6
4
6
4
6
6
8
6
8
No. stages
2
2
2
2
2
2
2
2
2
2
20-50
35-65
15-45
30-60
10-40
25-55
20-50
35-65
10-40
25-55
Gas Limit Setting (ºF)
165
165
165
165
215
195
195
160
195
160
Gas piping connection (in.)
3/4
3/4
3/4
3/4
3/4
3/4
3/4
3/4
3/4
3/4
AFUE %
Temperature Rise Range (ºF)
DIMENSIONS (inches)
Length
89
89
89
89
Width
59
59
59
59
59
Height
42
42
50-3/4
50-3/4
50-3/4
900
920
1135
1135
1400
Scroll
Scroll
Scroll
Scroll
Scroll
OPERATING WT. (lbs.)
119-7/16
COMPRESSORS
Type
Quantity
2
2
2
2
2
50 / 100
50 / 100
50 / 100
50 / 100
50 / 100
Face area (Sq. Ft.)
23.8
23.8
29.0
29.0
47.5
Rows
2/1
2
2
2
2
20
20
20
20
15
Unit Capacity Steps (%)
CONDENSER COIL DATA
Fins per inch
Tube diameter (in.)
Circuitry Type
3/8
3/8
3/8
3/8
3/8
Split-face
Split-face
Split-face
Split-face
Split-face
13.2
EVAPORATOR COIL DATA
Face area (Sq. Ft.)
10.6
10.6
13.2
13.2
Rows
3
3
4
4
4
Fins per inch
15
15
15
15
15
Tube diameter
0.375
0.375
0.375
0.375
0.375
Circuitry Type
Split-face
Split-face
Split-face
Split-face
Split-face
TXV
TXV
TXV
TXV
TXV
Refrigerant control
Unitary Products Group
29
164015-YIM-A-0905
Table 9:
ZH078-150 Physical Data (Continued)
Models
Component
ZH078
ZH090
ZH102
ZH120
ZH150
6.5
7.5
8.5
10
12.5
2
2
2
2
4
Nominal Tonnage
CONDENSER FAN DATA
Quantity
Fan diameter (Inch)
24
24
24
24
24
Type
Prop
Prop
Prop
Prop
Prop
Drive type
Direct
Direct
Direct
Direct
Direct
No. speeds
1
1
1
1
1
Number of motors
2
2
2
2
4
1/3
1/3
3/4
3/4
1/3
Motor HP each
RPM
850
850
1110
1110
850
Nominal total CFM
6800
6800
8800
8800
14000
BELT DRIVE EVAP FAN DATA
Quantity
Fan Size (Inch)
Type
1
1
1
1
1
12 x 12
12 x 12
15 x 15
15 x 15
15 x 15
Centrifugal
Centrifugal
Centrifugal
Centrifugal
Centrifugal
Motor Sheave
1VM50
1VM50
1VM50
1VM50
1VM50
1VM50
1VM50
1VM50
1VM50
1VP56
Blower Sheave
AK74
AK66
AK69
AK64
AK89
AK74
AK84
AK74
AK74
BK77
Belt
A49
A49
A49
A49
A56
A54
A56
A54
A54
BX55
Motor HP each
1-1/2
2
2
3
2
3
2
3
3
5
RPM
1725
1725
1725
1725
1725
1725
1725
1725
1725
1725
56
56
56
56
56
56
56
56
56
184T
Frame size
FILTERS
Quantity - Size
4 - 25 x 16 x 2
4 - 25 x 16 x 2
Optional Electric Heat
The factory-installed heaters are wired for single point power
supply. Power supply need only be brought into the single point
terminal block.
4 - 25 x 20 x 2
4 - 25 x 20 x 2
4 - 25 x 20 x 2
These CSA approved heaters are located within the central
compartment of the unit with the heater elements extending in
to the supply air chamber.
Fuses are supplied, where required, by the factory. Some kW
sizes require fuses and others do not. refer to Table 10 for
minimum CFM limitations and to Table 8 for electrical data.
Table 10: Electric Heat Minimum Supply Air
Size
(Tons)
30
Model
078
(6.5)
ZH
090
(7.5)
ZH
102
(8.5)
ZH
120
(10)
ZH
150
(12.5)
ZH
Voltage
208/230-3-60
460-3-60
600-3-60
208/230-3-60
460-3-60
600-3-60
208/230-3-60
460-3-60
600-3-60
208/230-3-60
460-3-60
600-3-60
208/230-3-60
460-3-60
600-3-60
9
1950
1950
1950
2250
2250
2250
2550
2550
2550
-
Minimum Supply Air (CFM)
Heater kW
18
24
36
1950
1950
1950
1950
1950
1950
1950
1950
1950
2250
2250
2250
2250
2250
2250
2250
2250
2250
2550
2550
2550
2550
2550
2550
2550
2550
2550
3000
3000
3000
3000
3000
3000
3000
3000
3000
3750
3750
3750
3750
3750
3750
3750
3750
3750
54
3500
3000
3500
4000
3750
3750
Unitary Products Group
164015-YIM-A-0905
Optional Gas Heat
These gas-fired heaters have aluminized-steel or optional
stainless steel, tubular heat exchangers with spark ignition.
/04)/.!,
#/),
'5!2$
3(/7.
Table 11: Gas Application Data
Unit
Size
078
090
102
120
150
Opt.
10
15
10
15
10
15
15
20
15
20
Input
(MBH)
120
180
120
180
120
180
180
240
180
240
Output (MBH)
96
144
96
144
96
144
144
192
144
192
Temp Rise
(°F)
20-50
35-65
15-45
30-60
10-40
25-55
20-50
35-65
10-40
25-55
Gas Piping
Proper sizing of gas piping depends on the cubic feet per hour
of gas flow required, specific gravity of the gas and the length of
run. "National Fuel Gas Code" Z223.1 (in U.S.A.) or the current
Gas Installation Codes CSA-B149.1 (in Canada) should be
followed in all cases unless superseded by local codes or gas
utility requirements. Refer to the Pipe Sizing Table 12. The
heating value of the gas may differ with locality. The value
should be checked with the local gas utility.
NOTE: There may be a local gas utility requirement specifying
a minimum diameter for gas piping. All units require a
one-inch pipe connection at the entrance fitting.
/04)/.!,
#/),
'5!2$
3(/7.
Figure 26: Bottom Entry Gas Piping
Table 12: Gas Pipe Sizing - CapacIty of Pipe
Nominal Iron Pipe Size
Length of
Pipe (ft.)
3/4 in.
1 in.
1-1/4 in.
10
278
520
1050
20
190
350
730
30
152
285
590
40
130
245
500
50
115
215
440
60
105
195
400
70
96
180
370
80
90
170
350
90
84
160
320
100
79
150
305
NOTE: Maximum capacity of pipe in cubic feet of gas per hour
based upon a pressure drop of 0.3 inch W.C. and 0.6
specific gravity gas.
NOTE: There may be a local gas utility requirement specifying a
minimum diameter for gas piping. All units require a 3/4
inch pipe connection at the entrance fitting. Line should
not be sized smaller than the entrance fitting size.
Figure 25: Side Entry Gas Piping
Unitary Products Group
31
164015-YIM-A-0905
Table 13: Gas Heat Minimum Supply Air
Size
(Tons)
078
(6.5)
090
(7.5)
102
(8.5)
120
(10)
150
(12.5)
Supply Air (CFM)
Model
ZH
ZH
ZH
ZH
ZH
Heat Size
10
15
10
15
10
15
15
20
15
20
Gas Connection
The gas supply line can be routed within the space and roof curb,
exiting through the unit’s basepan. Refer to Figures 8 and 9 for
the gas piping inlet location. Typical supply piping arrangements
are shown in Figures 25 and 26. All pipe nipples, fittings, and the
gas cock are field supplied or may be purchased in UPG
accessory kit #1GP0405.
Cooling
Min
1950
1950
2250
2250
2550
2550
3000
3000
3750
3750
Heating
Max
3250
3250
3750
3750
4250
4250
5000
5000
6250
6250
Min
1950
1950
2250
2250
2550
2550
3000
3000
3750
3750
Max
3250
3250
3750
3750
4250
4250
5000
5000
6250
6250
6.
A 1/8-inch NPT plugged tapping, accessible for test gage
connection, must be installed immediately upstream of the
gas supply connection to the unit.
7.
After the gas connections have been completed, open the
main shut-off valve admitting normal gas pressure to the
mains. Check all joints for leaks with soap solution or other
material suitable for the purpose. NEVER USE A FLAME.
Gas piping recommendations:
1.
A drip leg and a ground joint union must be installed in the
gas piping.
2.
Where required by local codes, a manual shut-off valve
must be installed outside of the unit.
3.
Use wrought iron or steel pipe for all gas lines. Pipe dope
should be applied sparingly to male threads only.
Natural gas may contain some propane. Propane is an
excellent solvent and will quickly dissolve white lead and
most standard commercial compounds. A special pipe
dope must be used when assembling wrought iron or
steel pipe. Shellac based compounds such as Gaskolac
or Stalastic, and compounds such as Rectorseal #5,
Clydes’s or John Crane may be used.
4.
All piping should be cleaned of dirt and scale by
hammering on the outside of the pipe and blowing out
loose particles. Before initial start-up, be sure that all gas
lines external to the unit have been purged of air.
5.
The gas supply should be a separate line and installed in
accordance with all safety codes as prescribed under
“Limitations”.
32
FIRE OR EXPLOSION HAZARD
Failure to follow the safety warning exactly could result
in serious injury, death or property damage.
Never test for gas leaks with an open flame. use a
commercially available soap solution made specifically
for the detection of leaks to check all connections. A fire
or explosion may result causing property damage,
personal injury or loss of life.
The furnace and its individual shut-off valve must be
disconnected from the gas supply piping system during
any pressure testing at pressures in excess of 1/2 PSIG.
Pressures greater than 1/2 PSIG will cause gas valve
damage resulting in a hazardous condition. If it is
subjected to a pressure greater than 1/2 PSIG, the gas
valve must be replaced.
The furnace must be isolated from the gas supply piping
system by closing its individual manual shut-off valve
during any pressure testing of the gas supply piping
system at test pressures equal to or less than 1/2 PSIG.
Unitary Products Group
164015-YIM-A-0905
Threaded joints should be coated with a sealing
compound that is resistant to the action of liquefied
petroleum gases. Do not use Teflon tape.
FIRE OR EXPLOSION HAZARD
Failure to follow the safety warning exactly could result
in serious injury, death or property damage.
Never test for gas leaks with an open flame. use a
commercially available soap solution made specifically
for the detection of leaks to check all connections. A fire
or explosion may result causing property damage,
personal injury or loss of life.
Lp Units, Tanks And Piping
All gas heat units are shipped from the factory equipped for
natural gas use only. The unit may be converted in the field for
use with LP gas with accessory kit model number 1NP0442.
All LP gas equipment must conform to the safety standards of
the National Fire Protection Association.
Vent And Combustion Air
For satisfactory operation, LP gas pressure must be 10.5 inch
W.C. at the unit under full load. Maintaining proper gas
pressure depends on three main factors:
Venting slots in the heating compartment access panel remove
the need for a combustion air hood. The gas heat flue exhaust
is routed through factory installed exhaust piping with screen. If
necessary, a flue exhaust extension may be installed at the
point of installation.
1.
The vaporization rate which depends on the temperature of
the liquid and the “wetted surface” area of the container(s).
2.
The proper pressure regulation. (Two-stage regulation is
recommended).
3.
The pressure drop in the lines between regulators and
between the second stage regulator and the appliance.
Pipe size required will depend on the length of the pipe run
and the total load of all appliances.
Complete information regarding tank sizing for vaporization,
recommended regulator settings, and pipe sizing is available
from most regulator manufacturers and LP gas suppliers.
Options/Accessories
Electric Heat
Electric heaters are available as factory-installed options or
field-installed accessories. Refer to electric heat instructions for
installation. These heaters mount in the heat compartment with
the heating elements extending into the supply air chamber. All
electric heaters are fused and intended for use with single point
power supply.
Motorized Outdoor Damper
LP gas is an excellent solvent and will quickly dissolve
white lead and most standard commercial compounds. A
special pipe dope must be used when assembling
wrought iron or steel pipe for LP. Shellac base
compounds such as Gaskolac or Stalastic, and
compounds such as Rectorseal #5, Clyde’s, or John
Crane may be used.
Check all connections for leaks when piping is completed using
a soap solution. NEVER USE A FLAME.
The Motorized Outdoor Damper can be a factory installed
option or a field installed accessory. If factory installed, refer to
the instructions included with the outdoor air hood to complete
the assembly. Field installed Motorized Outdoor Damper
accessories include complete instructions for installation.
Economizer
The Economizer can be a factory installed option or a field
installed accessory. If factory installed, refer to the instructions
included with the outdoor air hood to complete the assembly.
Field installed Economizer accessories include complete
instructions for installation.
There are two Economizer options:
1. Down Flow application with barometric relief hood standard.
2.
Unitary Products Group
Horizontal Flow application that requires the purchase of a
barometric relief hood.
33
164015-YIM-A-0905
Power Exhaust
The Power Exhaust can be a factory installed option or a field
installed accessory. If factory installed, refer to the instructions
included with the outdoor air hood to complete the assembly.
Field installed Power Exhaust accessories include complete
instructions for installation.
The Power Exhaust factory installed option is for Down Flow
application only.
There are two field installed Power Exhaust accessories:
1. Down Flow application.
2.
Horizontal Flow application that requires the purchase of a
barometric relief hood.
Rain Hood
All of the hood components, including the filters, the gasketing
and the hardware for assembling, are packaged and located
between the condenser coil section and the main unit cabinet, if
the unit has factory installed options. If field installed
accessories are being installed all parts necessary for the
installation comes in the accessory.
Economizer And Power Exhaust Set Point
Adjustments
Remove the top rear access panel from the unit. Locate the
economizer control module, where the following adjustments
will be made.
Extreme care must be exercised in turning all set point,
maximum and minimum damper positioning adjustment
screws to prevent twisting them off.
Minimum Position Adjustment
• Check that the damper blades move smoothly without
binding; carefully turn the Minimum Position Adjust screw
(found on the damper control module) fully clockwise and
then set the thermostat indoor fan switch to the ON
position and then OFF or energize and de-energize
terminals “R” to “G”.
• With the thermostat set to the indoor fan ON position or
terminals “R” to “G” energized, turn the Minimum Position
Adjusting screw (located on the damper control module)
counterclockwise until the desired minimum damper
position has been attained.
Enthalpy Set Point Adjustment
• The enthalpy set point may now be set by selecting the
desired set point shown in the Enthalpy Set Point
Adjustment Figure 27. Adjust as follows:
• For a single enthalpy operation carefully turn the set point
adjusting screw (found on the damper control module) to
the "A", "B", "C" or "D" setting corresponding to the lettered
curve of the Enthalpy Set Point Adjustment Figure 28.
• For a dual enthalpy operation, carefully turn the set point
adjusting screw fully clockwise past the "D" setting.
Power Exhaust Damper Set Point (With Or Without Power
Exhaust)
• With no power exhaust option, adjust the Exhaust Air
Adjustment Screw fully clockwise. This will allow 2nd
stage cooling to operate.
• With power exhaust option, each building pressurization
requirement will be different. The point at which the power
exhaust comes on is determined by the economizer
damper position (Percent Open). The Exhaust Air
Adjustment Screw should be set at the Percent Open of
the economizer damper at which the power exhaust is
needed. It can be set from 0 to 100% damper open.
Indoor Air Quality AQ
Indoor Air Quality (indoor sensor input): Terminal AQ accepts a
+2 to +10 Vdc signal with respect to the (AQ1) terminal. When
the signal is below it's set point, the actuator is allowed to
modulate normally in accordance with the enthalpy and mixed
air sensor inputs. When the AQ signal exceeds it's set point
setting and there is no call for free cooling, the actuator is
proportionately modulated from the 2 to 10 Vdc signal, with 2
Vdc corresponding to full closed and 10 Vdc corresponding to
full open. When there is no call for free cooling, the damper
position is limited by the IAQ Max damper position setting.
When the signal exceeds it's set point (Demand Control
Ventilation Set Point) setting and there is a call for free cooling,
the actuator modulates from the minimum position to the full
open position based on the highest call from either the mixed
air sensor input or the AQ voltage input.
• Optional CO2 Space Sensor Kit Part # 2AQ04700324
• Optional CO2 Sensor Kit Part # 2AQ04700424
Replace the top rear access panel on the unit.
34
Unitary Products Group
164015-YIM-A-0905
CONTROL
CURVE
CONTROL POINT
APPROX. 0F (0C)
AT 50% RH
A
73 (23)
B
C
70 (21)
67 (19)
D
63 (17)
85 90 95 100 105 110
(29) (32) (35) (38) (41) (43)
80
(27)
75
(24)
70
(21)
65
(18)
60
(16)
55
(13)
50
(10)
45
(7)
35
(2)
A
B
C
D
40
(4)
B A
D C
35
(2)
40 45 50 55 60 65 70 75 80 85 90 95 100 105 110
(4) (7) (10) (13) (16) (18) (21) (24) (27) (29) (32) (35) (38) (41) (43)
APPROXIMATE DRY BULB TEMPERATURE - 0F (0C)
Figure 27: Enthalpy Set Point Chart
Exhaust Air
Adjustment
Screw
Exhaust Air LED
Damper Min.
Position
Screw
Indoor Air Quality
Max. Adjustment
Screw
N1
N
EXH
Set
TR
P1
P
EXH
24
Vac
HOT
T1
T
Min
Pos
IAQ
Max
Indoor Air Quality
LED
AQ1
AQ
IAQ
SO
IAQ
Min
TR1
24
Vac
COM
+
1
2
5
Indoor Air Quality
Min. Adjustment
Screw
Free Cooling LED
SO+
3
4
EF
EF1
Free
Cool
SR+
SR
B
A
C
D
Economizer Enthalpy
Set Point Adjustment
Screw
Figure 28: Honeywell Economizer Control W7212
Phasing
Predator® units are properly phased at the factory. Check for
proper compressor rotation. If the blower or compressors rotate
in the wrong direction at start-up, the electrical connection to
the unit is misphased. Change the phasing of the Field Line
Unitary Products Group
Connection at the factory or field supplied disconnect to
obtain proper rotation. (Scroll compressors operate in only one
direction. If the scroll is drawing low amperage, has similar
suction and discharge pressures, or producing a high noise
level, the scroll is misphased.)
35
164015-YIM-A-0905
Scroll compressors require proper rotation to operate
correctly. Units are properly phased at the factory. Do
not change the internal wiring to make the blower
condenser fans, or compressor rotate correctly.
Blower Rotation
Check for proper supply air blower rotation. If the blower is
rotating backwards, the line voltage at the unit point of power
connection is misphased (See ‘PHASING’).
Table 14: Supply Air Limitations
Unit Size (Ton)
Minimum
Maximum
078 (6.5)
1950
3250
090 (7.5)
2250
3750
102 (8.5)
2550
4250
120 (10)
3000
5000
150 (12.5)
3750
6250
Procedure for adjusting belt tension:
1. Loosen six nuts (top and bottom) A.
2. Adjust by turning (B).
3. Never loosen nuts (C).
4. Use belt tension checker to apply a perpendicular
force to one belt at the midpoint of the span as
shown. Deflection distance of 4mm (5/32”) is
obtained.
To determine the deflection distance from normal
position, use a straight edge from sheave to sheave as
reference line. The recommended deflection force is as
follows:
Tension new belts at the max. deflection force
recommended for the belt section. Check the belt
tension at least two times during the first 24 hours of
operation. Any retensioning should fall between the min.
and max. deflection force values.
5. After adjusting retighten nuts (A).
CFM Static Pressure and Power-Altitude and Temperature
Corrections
Belt Tension
The tension on the belt should be adjusted as shown in Figure 29.
$
$
&
1(9(5/226(1
$
The information below should be used to assist in application of
product when being applied at altitudes at or exceeding 1000
feet above sea level.
The air flow rates listed in the standard blower performance
tables are based on standard air at sea level. As the altitude or
temperature increases, the density of air decreases. In order to
use the indoor blower tables for high altitude applications,
certain corrections are necessary.
A centrifugal fan is a "constant volume" device. This means
that, if the rpm remains constant, the CFM delivered is the
same regardless of the density of the air. However, since the air
at high altitude is less dense, less static pressure will be
generated and less power will be required than a similar
application at sea level. Air density correction factors are shown
in Table 15 and Figure 30.
%
63$1/(1*7+
'()/)25&(
Figure 29: Belt Adjustment
36
Unitary Products Group
164015-YIM-A-0905
Table 15: Altitude/Temperature Correction Factors
Air
Temp.
40
50
60
70
80
90
100
0
1.060
1.039
1.019
1.000
0.982
0.964
0.946
1000
1.022
1.002
0.982
0.964
0.947
0.929
0.912
2000
0.986
0.966
0.948
0.930
0.913
0.897
0.880
3000
0.950
0.931
0.913
0.896
0.880
0.864
0.848
4000
0.916
0.898
0.880
0.864
0.848
0.833
0.817
Altitude (Ft.)
5000
0.882
0.864
0.848
0.832
0.817
0.802
0.787
6000
0.849
0.832
0.816
0.801
0.787
0.772
0.758
7000
0.818
0.802
0.787
0.772
0.758
0.744
0.730
8000
0.788
0.772
0.757
0.743
0.730
0.716
0.703
9000
0.758
0.743
0.729
0.715
0.702
0.689
0.676
10000
0.729
0.715
0.701
0.688
0.676
0.663
0.651
&RUUHFWLRQ)DFWRU
6HD/HYHO
IW
IW
IW
IW
IW
IW
IW
IW
IW
IW
$LU7HPSHUDWXUHž)
Figure 30: Altitude/Temperature Correction Factors
The examples below will assist in determining the airflow
performance of the product at altitude.
blower tables to select the blower speed and the BHP
requirement.
Example 1: What are the corrected CFM, static pressure, and
BHP at an elevation of 5,000 ft. if the blower performance data
is 6,000 CFM, 1.5 IWC and 4.0 BHP?
Solution: As in the example above, no temperature
information is given so 70°F is assumed.
Solution: At an elevation of 5,000 ft. the indoor blower will still
deliver 6,000 CFM if the rpm is unchanged. However, Table 14
must be used to determine the static pressure and BHP. Since
no temperature data is given, we will assume an air temperature
of 70°F. Table 16 shows the correction factor to be 0.832.
Corrected static pressure = 1.5 x 0.832 = 1.248 IWC
Corrected BHP = 4.0 x 0.832 = 3.328
Example 2: A system, located at 5,000 feet of elevation, is to
deliver 6,000 CFM at a static pressure of 1.5". Use the unit
Unitary Products Group
The 1.5" static pressure given is at an elevation of 5,000 ft. The
first step is to convert this static pressure to equivalent sea level
conditions.
Sea level static pressure = 1.5 / .832 = 1.80"
Enter the blower table at 6000 sCFM and static pressure of
1.8". The rpm listed will be the same rpm needed at 5,000 ft.
Suppose that the corresponding BHP listed in the table is 3.2.
This value must be corrected for elevation.
BHP at 5,000 ft. = 3.2 x .832 = 2.66
37
164015-YIM-A-0905
Table 16: ZH Bottom Duct Blower Performance
ZH078 (6.5 Ton) Standard Motor Bottom Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
CFM
3320
3020
2700
2300
1781
0 Turns
RPM W 5
1126 1650
1129 1530
1132 1380
1136 1230
1120 1010
BHP
1.77
1.64
1.48
1.32
1.08
CFM
3310
3050
2780
2450
2003
-
,
6.5 Ton STANDARD MOTOR BOTTOM DUCT BLOWER PERFORMANCE1 2
4
TURNS OPEN
1 Turns
2 Turns
3 Turns
4 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5
1079 1590 1.71 3190 1035 1410 1.51 3005 991 1230 1.32 2780 945 1070
1082 1440 1.54 2850 1038 1290 1.38 2680 992 1100 1.18 2480 946 970
1086 1320 1.42 2550 1040 1150 1.23 2320 996 980 1.05 2055 948 840
1088 1180 1.27 2160 1043 1010 1.08 1879 998 840 0.90 1500 952 700
1091 1010 1.08 1570 1047 820 0.88
-
BHP
1.15
1.04
0.90
0.75
-
5 Turns
CFM RPM W 5
2560 897 940
2200 899 840
1925 902 720
-
BHP
1.01
0.90
0.77
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total static
pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
7RQ6WDQGDUG0RWRU%RWWRP'XFW
(63 LZJ
7XUQV
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ZH078 (6.5 Ton) Alternate Motor Bottom Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
CFM
3281
3031
2765
2493
0 Turns
RPM W 5
1259 2140
1262 1970
1268 1810
1273 1700
BHP
2.30
2.11
1.94
1.82
CFM
3343
3123
2875
2595
2228
,
6.5 Ton ALTERNATE MOTOR BOTTOM DUCT BLOWER PERFORMANCE1 2
4
TURNS OPEN
1 Turns
2 Turns
3 Turns
4 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5
3426 1156 1940 2.08 3300 1108 1700 1.82 3081 1057 1500
1207 2040 2.19 3155 1160 1780 1.91 3014 1111 1590 1.71 2800 1059 1380
1212 1910 2.05 2912 1164 1650 1.77 2757 1114 1460 1.57 2514 1062 1240
1215 1760 1.89 2651 1167 1500 1.61 2449 1116 1320 1.42 2148 1065 1090
1220 1630 1.75 2300 1171 1360 1.46 2051 1120 1170 1.26 1715 1069 950
1225 1420 1.52 1916 1176 1160 1.24 1323 1126 880 0.94
-
BHP
1.61
1.48
1.33
1.17
1.02
-
CFM
2889
2600
2287
1868
-
5 Turns
RPM W5
1004 1300
1007 1170
1008 1050
1012 900
-
BHP
1.39
1.26
1.13
0.97
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total static
pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
7RQ$OWHUQDWH0RWRU%RWWRP'XFW
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38
Unitary Products Group
164015-YIM-A-0905
ZH090 (7.5 Ton) Standard Motor Bottom Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
CFM
3619
3343
3100
2846
2559
2219
0 Turns
RPM W 5
1203 2148
1204 1988
1205 1857
1205 1712
1207 1574
1209 1435
BHP
2.30
2.13
1.99
1.84
1.69
1.54
CFM
3452
3189
2944
2675
2335
1935
,
7.5 Ton STANDARD MOTOR BOTTOM DUCT BLOWER PERFORMANCE1 2
TURNS OPEN 4
1 Turns
2 Turns
3 Turns
4 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5
1156 1913 2.05 3272 1110 1696 1.82 3085 1063 1503 1.61 2932 1013 1299
1159 1781 1.91 2995 1113 1547 1.66 2798 1065 1360 1.46 2640 1014 1190
1162 1676 1.80 2746 1116 1440 1.54 2512 1068 1246 1.34 2340 1017 1067
1166 1534 1.65 2448 1118 1326 1.42 2162 1071 1098 1.18 1956 1020 934
1169 1364 1.46 2084 1119 1174 1.26 1712 1074 941 1.01
1174 1039 1.11
-
BHP
1.39
1.28
1.14
1.00
-
5 Turns
CFM RPM W 5 BHP
2742 963 1123 1.20
2421 965 1024 1.10
2084 967 918 0.98
1606 969 781 0.84
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total static
pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
7RQ6WDQGDUG0RWRU%RWWRP'XFW
(63LZJ
7XUQV
7XUQV
7XUQV
7XUQV
7XUQ
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ZH090 (7.5 Ton) Alternate Motor Bottom Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
CFM
3995
3718
3506
3290
3065
2799
2401
1940
0 Turns
RPM W 5
1299 2790
1303 2580
1305 2440
1308 2290
1312 2167
1315 1977
1320 1775
1325 1514
BHP
2.99
2.77
2.62
2.46
2.32
2.12
1.90
1.62
CFM
3765
3508
3288
3053
2795
2458
2098
-
,
7.5 Ton ALTERNATE MOTOR BOTTOM DUCT BLOWER PERFORMANCE1 2
TURNS OPEN 4
1 Turns
2 Turns
3 Turns
4 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5
1249 2420 2.60 3619 1198 2147 2.30 3399 1144 1849 1.98 3223 1092 1630
1252 2290 2.46 3353 1201 2010 2.16 3131 1147 1715 1.84 2945 1094 1525
1255 2117 2.27 3107 1203 1862 2.00 2876 1149 1603 1.72 2666 1096 1368
1258 1982 2.13 2858 1206 1712 1.84 2594 1152 1487 1.60 2334 1099 1248
1261 1844 1.98 2558 1209 1602 1.72 2259 1155 1318 1.41 1954 1101 1095
1264 1675 1.80 2223 1212 1408 1.51 1780 1159 1084 1.16
1269 1487 1.60
-
BHP
1.75
1.64
1.47
1.34
1.17
-
CFM
3002
2715
2418
2049
-
5 Turns
RPM W5
1038 1421
1039 1328
1042 1206
1044 1037
-
BHP
1.52
1.42
1.29
1.11
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total
static pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
7RQ$OWHUQDWH0RWRU%RWWRP'XFW
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7XUQV
7XUQV
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Unitary Products Group
39
164015-YIM-A-0905
ZH102 (8.5 Ton) Standard Motor Bottom Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
0 Turns
CFM RPM W 5 BHP CFM
4152
3929 928 1747 1.87 3668
3395 930 1595 1.71 3133
2842 933 1423 1.53 2580
2303 936 1242 1.33 2041
1810 939 1065 1.14
-
,
8.5 Ton STANDARD MOTOR BOTTOM DUCT BLOWER PERFORMANCE1 2
TURNS OPEN 4
1 Turns
2 Turns
3 Turns
4 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5
889 1682 1.80 3875 851 1506 1.62 3583 813 1339 1.44 3276 774 1179
890 1563 1.68 3391 852 1387 1.49 3099 814 1219 1.31 2792 775 1060
892 1411 1.51 2857 854 1235 1.33 2564 816 1068 1.15 2257 777 908
895 1239 1.33 2304 857 1063 1.14 2012 819 895 0.96
898 1058 1.14
-
5 Turns
BHP CFM RPM W 5 BHP
1.26 2953 735 1027 1.10
1.14 2469 736 908 0.97
0.97
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total static
pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
7RQ6WDQGDUG0RWRU%RWWRP'XFW
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ZH102 (8.5 Ton) Alternate Motor Bottom Duct Blower Performance
ESP 3
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
CFM
4059
3763
3472
3187
2907
0 Turns
RPM W 5
1093 3457
1098 3269
1104 3068
1112 2850
1120 2611
BHP
3.71
3.51
3.29
3.06
2.80
CFM
4031
3729
3433
3142
2857
-
,
8.5 Ton ALTERNATE MOTOR BOTTOM DUCT BLOWER PERFORMANCE1 2
TURNS OPEN 4
1 Turns
2 Turns
3 Turns
4 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5
4330 1005 3172 3.40 4019 964 2788 2.99 3717 921 2417
4018 1008 3000 3.22 3707 967 2616 2.81 3405 924 2245
1051 3224 3.46 3711 1012 2827 3.03 3400 971 2442 2.62 3098 928 2071
1055 3046 3.27 3409 1016 2648 2.84 3098 975 2263 2.43
1061 2858 3.07 3112 1022 2460 2.64
1067 2656 2.85 2822 1028 2259 2.42
1074 2439 2.62
-
BHP
2.59
2.41
2.22
-
5 Turns
CFM RPM W5 BHP
3425 877 2060 2.21
3113 880 1887 2.02
2806 884 1714 1.84
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total
static pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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40
Unitary Products Group
164015-YIM-A-0905
ZH120 (10 Ton) Standard Motor Bottom Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
1.4
0 Turns
CFM RPM W 5 BHP CFM
4355
4229 978 2067 2.22 3943
3760 980 1908 2.05 3475
3263 983 1732 1.86 2978
2765 987 1550 1.66 2480
2292 990 1370 1.47 2007
1873 993 1206 1.29
-
10 Ton STANDARD MOTOR BOTTOM DUCT BLOWER PERFORMANCE1
TURNS OPEN 4
1 Turns
2 Turns
3 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM
938 1969 2.11 4054 899 1748 1.88 3736 857 1535 1.65 3402
940 1838 1.97 3642 901 1618 1.74 3324 859 1405 1.51 2990
943 1680 1.80 3173 903 1459 1.57 2856 862 1247 1.34 2522
946 1504 1.61 2676 906 1284 1.38 2359 865 1071 1.15 2025
949 1321 1.42 2178 910 1101 1.18
953 1142 1.23
-
,2
4 Turns
RPM W 5
814 1330
816 1200
818 1041
822 865
-
BHP
1.43
1.29
1.12
0.93
-
5 Turns
CFM RPM W 5 BHP
3052 769 1132 1.21
2640 771 1002 1.08
2172 773 844 0.91
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total static
pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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ZH120 (10 Ton) Alternate Motor Bottom Duct Blower Performance
ESP 3
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
CFM
4059
3763
3472
3187
2907
0 Turns
RPM W 5
1093 3457
1098 3269
1104 3068
1112 2850
1120 2611
BHP
3.71
3.51
3.29
3.06
2.80
CFM
4031
3729
3433
3142
2857
-
,
10 Ton ALTERNATE MOTOR BOTTOM DUCT BLOWER PERFORMANCE1 2
4
TURNS OPEN
1 Turns
2 Turns
3 Turns
4 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5
4330 1005 3172 3.40 4019 964 2788 2.99 3717 921 2417
4018 1008 3000 3.22 3707 967 2616 2.81 3405 924 2245
1051 3224 3.46 3711 1012 2827 3.03 3400 971 2442 2.62 3098 928 2071
1055 3046 3.27 3409 1016 2648 2.84 3098 975 2263 2.43
1061 2858 3.07 3112 1022 2460 2.64
1067 2656 2.85 2822 1028 2259 2.42
1074 2439 2.62
-
BHP
2.59
2.41
2.22
-
5 Turns
CFM RPM W5 BHP
3425 877 2060 2.21
3113 880 1887 2.02
2806 884 1714 1.84
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total
static pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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Unitary Products Group
41
164015-YIM-A-0905
ZH150 (12.5 Ton) Standard Motor Bottom Duct Blower Performance
ESP 3
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
CFM
4059
3763
3472
3187
2907
0 Turns
RPM W 5
1093 3457
1098 3269
1104 3068
1112 2850
1120 2611
BHP
3.71
3.51
3.29
3.06
2.80
CFM
4031
3729
3433
3142
2857
-
,
12.5 Ton STANDARD MOTOR BOTTOM DUCT BLOWER PERFORMANCE1 2
TURNS OPEN 4
1 Turns
2 Turns
3 Turns
4 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5
4330 1005 3172 3.40 4019 964 2788 2.99 3717 921 2417
4018 1008 3000 3.22 3707 967 2616 2.81 3405 924 2245
1051 3224 3.46 3711 1012 2827 3.03 3400 971 2442 2.62 3098 928 2071
1055 3046 3.27 3409 1016 2648 2.84 3098 975 2263 2.43
1061 2858 3.07 3112 1022 2460 2.64
1067 2656 2.85 2822 1028 2259 2.42
1074 2439 2.62
-
BHP
2.59
2.41
2.22
-
5 Turns
CFM RPM W 5 BHP
3425 877 2060 2.21
3113 880 1887 2.02
2806 884 1714 1.84
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total static
pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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ZH150 (12.5 Ton) Alternate Motor Bottom Duct Blower Performance
ESP 3
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
2.2
CFM
5351
5062
4775
4488
4197
3898
3588
0 Turns
RPM W 5
1254 5250
1258 5049
1263 4847
1268 4639
1274 4419
1280 4181
1286 3921
BHP
5.63
5.42
5.20
4.98
4.74
4.49
4.21
CFM
5864
5546
5242
4946
4657
4370
4083
3792
3493
-
,
12.5 Ton ALTERNATE MOTOR BOTTOM DUCT BLOWER PERFORMANCE1 2
TURNS OPEN 4
1 Turns
2 Turns
3 Turns
4 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5
1204 5252 5.63 5489 1163 4675 5.02 5143 1124 4168 4.47 4827 1085 3730
1206 5022 5.39 5171 1165 4446 4.77 4825 1125 3939 4.23 4510 1087 3501
1208 4808 5.16 4866 1168 4232 4.54 4521 1128 3724 4.00 4205 1089 3287
1212 4604 4.94 4571 1172 4027 4.32 4225 1132 3520 3.78 3909 1093 3082
1216 4403 4.72 4282 1176 3827 4.11 3936 1136 3319 3.56 3620 1097 2881
1221 4201 4.51 3995 1181 3625 3.89 3650 1141 3118 3.34 3334 1102 2680
1227 3993 4.28 3708 1186 3417 3.67 3362 1147 2909 3.12
1233 3773 4.05 3416 1192 3196 3.43
1239 3536 3.79
-
BHP
4.00
3.76
3.53
3.31
3.09
2.87
-
CFM
4541
4223
3919
3623
3334
-
5 Turns
RPM W5
1047 3361
1049 3132
1051 2918
1055 2713
1059 2513
-
BHP
3.61
3.36
3.13
2.91
2.70
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total
static pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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42
Unitary Products Group
164015-YIM-A-0905
Table 17: ZH Side Duct Blower Performance
ZH078 (6.5 Ton) Standard Motor Side Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
1.4
CFM
2866
2611
2300
1918
0 Turns
RPM W 5
1117 1600
1122 1470
1126 1340
1131 1180
BHP
1.72
1.58
1.44
1.27
CFM
2974
2724
2417
2070
-
,
6.5 Ton STANDARD MOTOR SIDE DUCT BLOWER PERFORMANCE1 2
4
TURNS OPEN
1 Turns
2 Turns
3 Turns
4 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5
3278 1021 1540 1.65 3146 980 1370 1.47 2963 936 1200
3007 1025 1430 1.53 2865 982 1280 1.37 2673 939 1100
1071 1530 1.64 2749 1029 1320 1.42 2585 986 1170 1.26 2371 941 980
1075 1420 1.52 2465 1032 1220 1.31 2278 989 1050 1.13 2020 944 890
1079 1300 1.39 2133 1036 1100 1.18 1907 992 940 1.01 1542 947 760
1083 1160 1.24 1702 1040 950 1.02
-
BHP
1.29
1.18
1.05
0.95
0.82
-
5 Turns
CFM RPM W 5 BHP
2792 892 1040 1.12
2483 893 940 1.01
2154 894 850 0.91
1745 896 750 0.80
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total static
pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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ZH078 (6.5 Ton) Alternate Motor Side Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
CFM
3204
2966
2594
2391
1912
0 Turns
RPM W 5
1259 2190
1264 2070
1270 1890
1273 1740
1279 1510
BHP
2.35
2.22
2.03
1.87
1.62
CFM
3368
3139
2892
2621
2286
1909
-
,
6.5 Ton ALTERNATE MOTOR SIDE DUCT BLOWER PERFORMANCE1
4
TURNS OPEN
1 Turns
2 Turns
3 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM
3678 1102 1900 2.04 3412
3626 1152 2100 2.25 3406 1137 1830 1.96 3134
3397 1156 1970 2.11 3160 1107 1680 1.80 2879
1206 2130 2.29 3148 1159 1830 1.96 2909 1110 1560 1.67 2596
1211 1990 2.13 2891 1162 1690 1.81 2642 1113 1450 1.56 2288
1213 1840 1.97 2619 1167 1560 1.67 2316 1116 1320 1.42 1871
1217 1700 1.82 2289 1170 1420 1.52 1930 1120 1160 1.24
1221 1550 1.66 1844 1175 1240 1.33
1226 1370 1.47
-
2
4 Turns
RPM W 5
1044 1600
1046 1510
1048 1380
1050 1270
1053 1140
1056 1020
-
BHP
1.72
1.62
1.48
1.36
1.22
1.09
-
CFM
3310
3020
2734
2428
2073
-
5 Turns
RPM W5
1001 1500
1003 1390
1005 1260
1008 1150
1010 1030
-
BHP
1.61
1.49
1.35
1.23
1.10
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total static
pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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Unitary Products Group
43
164015-YIM-A-0905
ZH090 (7.5 Ton) Standard Motor Side Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
1.4
CFM
3309
3058
2809
2580
0 Turns
RPM W 5
1202 2058
1206 1899
1209 1793
1212 1701
BHP
2.21
2.04
1.92
1.82
CFM
3439
3178
2918
2645
2340
,
7.5 Ton STANDARD MOTOR SIDE DUCT BLOWER PERFORMANCE1 2
TURNS OPEN 4
1 Turns
2 Turns
3 Turns
4 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5
3721 1108 1951 2.09 3495 1053 1684 1.81 3377 1006 1520
3446 1104 1831 1.96 3239 1055 1408 1.51 3058 1008 1388
1152 1996 2.14 3198 1106 1697 1.82 2964 1057 1456 1.56 2772 1010 1268
1156 1847 1.98 2922 1109 1591 1.71 2688 1060 1336 1.43 2469 1012 1177
1159 1714 1.84 2649 1111 1453 1.56 2385 1063 1241 1.33 2108 1015 1035
1162 1595 1.71 2333 1115 1325 1.42 2002 1066 1114 1.19 1624 1017 886
1165 1455 1.56 1951 1118 1176 1.26
-
BHP
1.63
1.49
1.36
1.26
1.11
0.95
-
5 Turns
CFM RPM W 5 BHP
3124 957 1309 1.40
2825 959 1182 1.27
2523 960 1090 1.17
2177 963 975 1.05
1746 965 851 0.91
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total static
pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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ZH090 (7.5 Ton) Alternate Motor Side Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
CFM
4467
4216
4001
3804
3603
3370
3185
2928
2678
2326
0 Turns
RPM W 5
1295 3131
1299 3018
1301 2861
1304 2729
1308 2598
1310 2435
1312 2327
1315 2173
1319 2055
1354 1844
BHP
3.36
3.24
3.07
2.93
2.79
2.61
2.50
2.33
2.20
1.98
CFM
4316
4058
3825
3652
3442
3225
2970
2742
2294
-
,
7.5 Ton ALTERNATE MOTOR SIDE DUCT BLOWER PERFORMANCE1
TURNS OPEN 4
1 Turns
2 Turns
3 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM
1246 2800 3.00 4139 1195 2476 2.66 3886 1146 2178 2.34 3622
1248 2708 2.91 3882 1199 2391 2.56 3612 1147 2048 2.20 3351
1252 2534 2.72 3664 1201 2290 2.46 3369 1149 1915 2.05 3100
1254 2426 2.60 3436 1204 2097 2.25 3118 1151 1816 1.95 2827
1256 2306 2.47 3153 1207 2000 2.15 2840 1153 1644 1.76 2539
1259 2173 2.33 2898 1209 1858 1.99 2560 1155 1554 1.67 2215
1262 2049 2.20 2617 1212 1719 1.84 2216 1158 1417 1.52 1758
1266 1944 2.09 2251 1214 1555 1.67
1268 1687 1.81
-
2
4 Turns
RPM W 5
1092 1894
1095 1775
1097 1643
1099 1552
1100 1398
1103 1294
1105 1116
-
BHP
2.03
1.90
1.76
1.67
1.50
1.39
1.20
-
CFM
3413
3139
2869
2583
2259
1828
-
5 Turns
RPM W5
1037 1644
1039 1550
1041 1408
1042 1307
1045 1173
1047 1027
-
BHP
1.76
1.66
1.51
1.40
1.26
1.10
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total
static pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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44
Unitary Products Group
164015-YIM-A-0905
ZH102 (8.5 Ton) Standard Motor Side Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
1.4
0 Turns
CFM RPM W 5 BHP CFM
4667
4448 918 2117 2.27 4043
3742 922 1862 2.00 3336
3018 927 1588 1.70 2612
2342 932 1316 1.41 1937
1780 937 1073 1.15
-
,
8.5 Ton STANDARD MOTOR SIDE DUCT BLOWER PERFORMANCE1 2
TURNS OPEN 4
1 Turns
2 Turns
3 Turns
4 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5
4748 842 1941 2.08 4366 806 1702 1.83 3995 769 1479
879 2055 2.20 4273 844 1800 1.93 3891 807 1561 1.67 3520 770 1338
882 1845 1.98 3649 847 1590 1.71 3267 810 1351 1.45 2896 773 1129
887 1591 1.71 2942 851 1336 1.43 2560 814 1097 1.18 2189 778 874
891 1316 1.41 2219 856 1061 1.14 1836 819 822 0.88
897 1045 1.12 1543 861 790 0.85
-
BHP
1.59
1.44
1.21
0.94
-
5 Turns
CFM RPM W 5 BHP
3636 731 1273 1.37
3160 733 1132 1.21
2537 736 922 0.99
1830 740 668 0.72
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total static
pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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ZH102 (8.5 Ton) Alternate Motor Side Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
CFM
4996
4701
4412
4129
3852
3582
0 Turns
RPM W 5
1093 3457
1098 3269
1104 3068
1112 2850
1120 2611
1130 2348
BHP
3.71
3.51
3.29
3.06
2.80
2.52
CFM
4962
4664
4369
4080
3797
3520
-
,
8.5 Ton ALTERNATE MOTOR SIDE DUCT BLOWER PERFORMANCE1
TURNS OPEN 4
1 Turns
2 Turns
3 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM
5253 961 2963 3.18 4958
5252 1005 3172 3.40 4944 964 2788 2.99 4649
4945 1008 3000 3.22 4638 967 2616 2.81 4343
1051 3224 3.46 4642 1012 2827 3.03 4335 971 2442 2.62 4040
1055 3046 3.27 4344 1016 2648 2.84 4036 975 2263 2.43 3741
1061 2858 3.07 4049 1022 2460 2.64 3742 981 2075 2.23 3447
1067 2656 2.85 3760 1028 2259 2.42 3453 987 1874 2.01
1074 2439 2.62 3477 1035 2041 2.19
1083 2200 2.36
-
2
4 Turns
RPM W 5
918 2592
921 2417
924 2245
928 2071
933 1892
938 1704
-
BHP
2.78
2.59
2.41
2.22
2.03
1.83
-
5 Turns
CFM RPM W5 BHP
4675 874 2234 2.40
4366 877 2060 2.21
4060 880 1887 2.02
3757 884 1714 1.84
3458 888 1535 1.65
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total
static pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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Unitary Products Group
45
164015-YIM-A-0905
ZH120 (10 Ton) Standard Motor Side Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
1.4
0 Turns
CFM RPM W 5 BHP CFM
3938
3727 978 2015 2.16 3460
3215 986 1739 1.87 2948
2657 996 1463 1.57 2391
,
10 Ton STANDARD MOTOR SIDE DUCT BLOWER PERFORMANCE1 2
TURNS OPEN 4
1 Turns
2 Turns
3 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM
4659 853 1999 2.14 4309
4540 889 2131 2.29 4218 853 1847 1.98 3869
4098 892 1929 2.07 3777 856 1645 1.76 3427
933 1981 2.13 3644 896 1689 1.81 3322 860 1405 1.51 2973
939 1717 1.84 3166 902 1425 1.53 2844 866 1141 1.22 2495
947 1440 1.55 2654 910 1149 1.23 2332 874 865 0.93
958 1164 1.25
-
4 Turns
RPM W 5
818 1723
819 1570
821 1368
825 1129
831 865
-
BHP
1.85
1.68
1.47
1.21
0.93
-
5 Turns
CFM RPM W 5 BHP
3932 785 1454 1.56
3492 785 1301 1.40
3050 788 1099 1.18
2596 792 860 0.92
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total static
pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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ZH120 (10 Ton) Alternate Motor Side Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
CFM
4996
4701
4412
4129
3852
3582
0 Turns
RPM W 5
1093 3457
1098 3269
1104 3068
1112 2850
1120 2611
1130 2348
BHP
3.71
3.51
3.29
3.06
2.80
2.52
CFM
4962
4664
4369
4080
3797
3520
-
,
10 Ton ALTERNATE MOTOR SIDE DUCT BLOWER PERFORMANCE1 2
4
TURNS OPEN
1 Turns
2 Turns
3 Turns
4 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5
5253 961 2963 3.18 4958 918 2592
5252 1005 3172 3.40 4944 964 2788 2.99 4649 921 2417
4945 1008 3000 3.22 4638 967 2616 2.81 4343 924 2245
1051 3224 3.46 4642 1012 2827 3.03 4335 971 2442 2.62 4040 928 2071
1055 3046 3.27 4344 1016 2648 2.84 4036 975 2263 2.43 3741 933 1892
1061 2858 3.07 4049 1022 2460 2.64 3742 981 2075 2.23 3447 938 1704
1067 2656 2.85 3760 1028 2259 2.42 3453 987 1874 2.01
1074 2439 2.62 3477 1035 2041 2.19
1083 2200 2.36
-
BHP
2.78
2.59
2.41
2.22
2.03
1.83
-
5 Turns
CFM RPM W5 BHP
4675 874 2234 2.40
4366 877 2060 2.21
4060 880 1887 2.02
3757 884 1714 1.84
3458 888 1535 1.65
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total
static pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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46
Unitary Products Group
164015-YIM-A-0905
ZH150 (12.5 Ton) Standard Motor Side Duct Blower Performance
ESP 3
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
CFM
4996
4701
4412
4129
3852
3582
0 Turns
RPM W 5
1093 3457
1098 3269
1104 3068
1112 2850
1120 2611
1130 2348
BHP
3.71
3.51
3.29
3.06
2.80
2.52
CFM
4962
4664
4369
4080
3797
3520
-
,
12.5 Ton STANDARD MOTOR SIDE DUCT BLOWER PERFORMANCE1
4
TURNS OPEN
1 Turns
2 Turns
3 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM
5253 961 2963 3.18 4958
5252 1005 3172 3.40 4944 964 2788 2.99 4649
4945 1008 3000 3.22 4638 967 2616 2.81 4343
1051 3224 3.46 4642 1012 2827 3.03 4335 971 2442 2.62 4040
1055 3046 3.27 4344 1016 2648 2.84 4036 975 2263 2.43 3741
1061 2858 3.07 4049 1022 2460 2.64 3742 981 2075 2.23 3447
1067 2656 2.85 3760 1028 2259 2.42 3453 987 1874 2.01
1074 2439 2.62 3477 1035 2041 2.19
1083 2200 2.36
-
2
4 Turns
RPM W 5
918 2592
921 2417
924 2245
928 2071
933 1892
938 1704
-
5 Turns
CFM RPM W 5 BHP
4675 874 2234 2.40
4366 877 2060 2.21
4060 880 1887 2.02
3757 884 1714 1.84
3458 888 1535 1.65
-
BHP
2.78
2.59
2.41
2.22
2.03
1.83
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total static
pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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ZH150 (12.5 Ton) Alternate Motor Side Duct Blower Performance
ESP 3
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
2.2
2.4
2.6
CFM
6168
5897
5624
5345
5061
4769
4469
4158
3836
0 Turns
RPM W 5
1254 5250
1258 5049
1263 4847
1268 4639
1274 4419
1280 4181
1286 3921
1292 3633
1298 3312
BHP
5.63
5.42
5.20
4.98
4.74
4.49
4.21
3.90
3.55
CFM
6598
6330
6062
5794
5524
5250
4971
4687
4395
4095
-
12.5 Ton ALTERNATE MOTOR SIDE DUCT BLOWER PERFORMANCE1
TURNS OPEN 4
1 Turns
2 Turns
3 Turns
RPM W 5 BHP CFM RPM W 5 BHP CFM RPM W 5 BHP CFM
1204 5252 5.63 6249 1163 4675 5.02 5926 1124 4168 4.47 5628
1206 5022 5.39 5981 1165 4446 4.77 5658 1125 3939 4.23 5359
1208 4808 5.16 5713 1168 4232 4.54 5390 1128 3724 4.00 5092
1212 4604 4.94 5445 1172 4027 4.32 5122 1132 3520 3.78 4823
1216 4403 4.72 5175 1176 3827 4.11 4851 1136 3319 3.56 4553
1221 4201 4.51 4901 1181 3625 3.89 4578 1141 3118 3.34 4279
1227 3993 4.28 4623 1186 3417 3.67 4299 1147 2909 3.12 4001
1233 3773 4.05 4338 1192 3196 3.43 4015 1152 2689 2.88 3717
1239 3536 3.79 4047 1198 2959 3.17 3723 1158 2452 2.63
1245 3276 3.51
-
,2
4 Turns
RPM W 5
1085 3730
1087 3501
1089 3287
1093 3082
1097 2881
1102 2680
1108 2471
1114 2251
-
BHP
4.00
3.76
3.53
3.31
3.09
2.87
2.65
2.42
-
CFM
5354
5086
4819
4550
4280
4006
3728
-
5 Turns
RPM W5
1047 3361
1049 3132
1051 2918
1055 2713
1059 2513
1064 2311
1070 2103
-
BHP
3.61
3.36
3.13
2.91
2.70
2.48
2.26
-
1. Blower performance for gas heat includes maximum number of heat tubes available for each tonnage.
2. Blower performance includes two-inch throwaway filters.
3. ESP (External Static Pressure) given is that available for the supply and return air duct system. All internal resistances have been deducted from the total
static pressure of the blower.
4. “Turns Open” refers to the setting of the variable pitch motor sheave, where “0 Turns Open” is fully closed.
5. W = Watts
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Unitary Products Group
47
164015-YIM-A-0905
NOTES FOR TABLE 16 AND 17:
• ESP (External Static Pressure) given is that available for
the supply and return air duct system. All internal
resistances have been deducted from the total static
pressure of the blower.
• Blower performance includes dry coil and two-inch filters.
• Blower performance for gas heat includes the maximum
number of heat tubes available for each tonnage.
Table 18: Indoor Blower Specifications
Size
(Tons)
078
(6.5)
090
(7.5)
102
(8.5)
120
(10)
150
(12.5)
Motor
Model
ZH
ZH
ZH
ZH
ZH
HP
RPM
Eff.
SF
1-1/2
2
2
3
2
3
2
3
3
5
1725
1725
1725
1725
1725
1725
1725
1725
1725
1725
0.8
0.8
0.8
0.8
0.8
0.8
0.8
0.8
0.8
0.87
1.15
1.15
1.15
1.15
1.15
1.15
1.15
1.15
1.15
1.15
Motor Sheave
Blower Sheave
Datum Dia.
Datum Dia.
Bore (in.) Model
Bore (in.) Model
Frame
(in.)
(in.)
56
3.4 - 4.4
7/8
1VM50
7.0
1
AK74
56
3.4 - 4.4
7/8
1VM50
6.2
1
AK66
56
3.4 - 4.4
7/8
1VM50
6.5
1
AK69
56
3.4 - 4.4
7/8
1VM50
6.0
1
AK64
56
3.4 - 4.4
7/8
1VM50
8.5
1
AK89
56
3.4 - 4.4
7/8
1VM50
7.0
1
AK74
56
3.4 - 4.4
7/8
1VM50
8.0
1
AK84
56
3.4 - 4.4
7/8
1VM50
7.0
1
AK74
56
3.4 - 4.4
7/8
1VM50
7.0
1
AK74
184T
4.3 - 5.3
1-1/8
1VP56
6.7
1
BK77
Belt
A49
A49
A49
A49
A56
A54
A56
A54
A54
BX55
Table 19: Power Exhaust Specifications
Model
Voltage
2PE04703225
2PE04703246
2PE04703258
208/230-1-60
460-1-60
575-1-60
HP
3/4
3/4
3/4
Motor
RPM1
1075
1075
1050
QTY
1
1
1
LRA
7.8
3.4
2.9
Motor
FLA
5
2.2
1.5
MCA
6.3
2.8
1.9
Fuse Size
10
5
4
CFM @
0.1 ESP
3800
3800
3800
1. Motors are multi-tapped and factory wired for high speed.
Air Balance
Start the supply air blower motor. Adjust the resistances in both
the supply and the return air duct systems to balance the air
distribution throughout the conditioned space. The job
specifications may require that this balancing be done by
someone other than the equipment installer.
4.
The CFM through the unit can be determined from the
pressure drop indicated by the manometer by referring to
Figure 31. In order to obtain an accurate measurement, be
certain that the air filters are clean.
5.
To adjust Measured CFM to Required CFM, see SUPPLY
AIR DRIVE ADJUSTMENT.
6.
After readings have been obtained, remove the tubes and
replace the dot plugs.
Checking Air Quantity
Method One
1.
Remove the dot plugs from the duct panel (for location of
the dot plugs see Figures 12 and 13).
2.
Insert eight-inches of 1/4 inch metal tubing into the airflow
on both sides of the indoor coil.
NOTE: The tubes must be inserted and held in a position
perpendicular to the air flow so that velocity pressure
will not affect the static pressure readings.
3.
Use an Inclined Manometer or Magnehelic to determine
the pressure drop across a dry evaporator coil. Since the
moisture on an evaporator coil can vary greatly, measuring
the pressure drop across a wet coil under field conditions
could be inaccurate. To assure a dry coil, the compressors
should be de-activated while the test is being run.
NOTE: De-energize the compressors before taking any test
measurements to assure a dry evaporator coil.
48
Failure to properly adjust the total system air quantity
can result in extensive blower damage.
Method Two
1.
Drill two 5/16 inch holes, one in the return air duct as close
to the inlet of the unit as possible, and another in the supply
air duct as close to the outlet of the unit as possible.
2.
Using the whole drilled in step 1, insert eight inches of 1/4
inch metal tubing into the airflow of the return and supply
air ducts of the unit.
NOTE: The tubes must be inserted and held in position
perpendicular to the airflow so that velocity pressure
will not affect the static pressure readings.
Unitary Products Group
164015-YIM-A-0905
3.
Use an Inclined Manometer or Magnehelic to determine
the pressure drop across the unit. This is the External
Static Pressure (ESP). In order to obtain an accurate
measurement, be certain that the air filters are clean.
4.
Determine the number of turns the variable motor sheave
is open.
5.
Select the correct blower performance table for the unit
from Tables 16 and 17. Tables are presented for side and
downflow configuration.
6.
Determine the unit Measured CFM from the Blower
Performance Table, External Static Pressure and the
number of turns the variable motor sheave is open.
7.
To adjust Measured CFM to Required CFM, see SUPPLY
AIR DRIVE ADJUSTMENT.
8.
After reading has been obtained, remove the tubes and
seal holes.
NOTE: With the addition of field installed accessories repeat
this procedure.
Failure to properly adjust the total system air quantity
can result in extensive blower damage.
'U\&RLO'HOWD3LZJ
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=+
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=+
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Unitary Products Group
49
164015-YIM-A-0905
Supply Air Drive Adjustment
EXAMPLE
A 12.5 ton unit was selected to deliver 4,000 CFM with a 3 HP
motor, but the unit is delivering 3,800 CFM. The variable pitch
motor sheave is set at 2 turns open.
Before making any blower speed changes review the
installation for any installation errors, leaks or undesirable
systems effects that can result in loss of airflow.
Even small changes in blower speed can result in
substantial changes in static pressure and BHP. BHP
and AMP draw of the blower motor will increase by the
cube of the blower speed. Static pressure will increase
by the square of the blower speed. Only qualified
personnel should make blower speed changes, strictly
adhering to the fan laws.
Use the equation to determine the required DD for the new
motor sheave,
5HTXLUHG&)0
0HDVXUHG&)0
‡ ([LVWLQJ''
1HZ''
Use Table 20 to locate the DD nearest to 4.21 in. Close the
sheave to 1 turn open.
New BHP
= (Speed increase)3 • BHP at 3,800 CFM
At unit start-up, the measured CFM may be higher or lower than
the required CFM. To achieve the required CFM, the speed of
the drive may have adjusted by changing the datum diameter
(DD) of the variable pitch motor sheave as described below:
= (Speed increase)3 • Original BHP
= New BHP
New motor Amps
&)0
&)0
‡ LQ
LQ
Use the following tables and the DD calculated per the above
equation to adjust the motor variable pitch sheave.
= (Speed increase)3 • Amps at 3,800 CFM
= (Speed increase)3 • Original Amps
= New Amps
Table 20: Motor Sheave Datum Diameters
1VM50x7/8
(1-1/2, 2 & 3 HP Motor)
Turns Open
Datum Diameter
0
4.4
1/2
4.3
1
4.2
1-1/2
4.1
2
4.0
2-1/2
3.9
3
3.8
3-1/2
3.7
4
3.6
4-1/2
3.5
5
3.4
50
1VP56x1-1/8
(5 HP Motor)
Turns Open
Datum Diameter
1
5.3
1-1/2
5.2
2
5.1
2-1/2
5.0
3
4.9
3-1/2
4.8
4
4.7
4-1/2
4.6
5
4.5
5-1/2
4.4
6
4.3
Unitary Products Group
164015-YIM-A-0905
Table 21: Additional Static Resistance
Size
(Tons)
Model
078 (6.5)
090 (7.5)
ZH
102 (8.5)
120 (10)
150 (12.5)
ZH
CFM
Cooling Only1
Economizer2 3
1900
2100
2300
2500
2700
2900
3100
3300
3500
3700
3900
4100
4300
4500
1900
2100
2300
2500
2700
2900
3100
3300
3500
3700
3900
4100
4300
4500
4700
4900
5100
5300
5500
5700
5900
6100
6300
0.00
-0.01
-0.01
-0.02
-0.03
-0.04
-0.05
-0.06
-0.07
-0.08
-0.09
-0.09
-0.10
-0.11
0.06
0.07
0.08
0.09
0.11
0.12
0.14
0.16
0.18
0.20
0.23
0.25
0.28
0.30
0.33
0.36
0.39
0.42
0.45
0.48
0.52
0.56
0.60
0.07
0.09
0.11
0.13
0.16
0.18
0.20
0.22
0.24
0.27
0.29
0.31
0.30
0.35
0.02
0.02
0.02
0.02
0.03
0.03
0.03
0.03
0.04
0.04
0.04
0.04
0.05
0.05
0.05
0.05
0.06
0.06
0.06
0.06
0.07
0.07
0.07
95
0.05
0.06
0.07
0.08
0.09
0.10
0.12
0.13
0.15
0.17
0.19
0.21
0.23
0.25
0.05
0.06
0.07
0.08
0.09
0.10
0.12
0.13
0.15
0.17
0.19
0.21
0.23
0.25
0.28
0.30
0.33
0.35
0.38
0.41
0.44
0.47
0.50
18
0.06
0.07
0.08
0.09
0.10
0.11
0.13
0.14
0.16
0.18
0.20
0.22
0.24
0.26
0.06
0.07
0.08
0.09
0.10
0.11
0.13
0.14
0.16
0.18
0.20
0.22
0.24
0.26
0.29
0.31
0.34
0.37
0.40
0.43
0.46
0.49
0.53
Electric Heat kW2
24
0.07
0.08
0.09
0.10
0.12
0.13
0.15
0.17
0.19
0.21
0.23
0.25
0.28
0.30
0.07
0.08
0.09
0.10
0.12
0.13
0.15
0.17
0.19
0.21
0.23
0.25
0.28
0.30
0.33
0.35
0.38
0.41
0.44
0.47
0.50
0.53
0.56
36
0.08
0.09
0.10
0.11
0.13
0.14
0.16
0.18
0.20
0.22
0.24
0.26
0.29
0.31
0.08
0.09
0.10
0.11
0.13
0.14
0.16
0.18
0.20
0.22
0.24
0.26
0.29
0.31
0.34
0.37
0.40
0.43
0.46
0.49
0.53
0.56
0.59
54
0.10
0.11
0.13
0.14
0.16
0.18
0.20
0.22
0.24
0.26
0.28
0.31
0.34
0.37
0.10
0.11
0.13
0.14
0.16
0.18
0.20
0.22
0.24
0.26
0.28
0.31
0.34
0.37
0.40
0.43
0.46
0.49
0.53
0.56
0.59
0.62
0.65
1. Add these values to the available static resistance in the respective Blower Performance Tables.
2. Deduct these values from the available external static pressure shown in the respective Blower Performance Tables.
3. The pressure drop through the economizer is greater for 100% outdoor air than for 100% return air. If the resistance of the return air duct
is less than 0.25 IWG, the unit will deliver less CFM during full economizer operation.
Unitary Products Group
51
164015-YIM-A-0905
Operation
Cooling Sequence Of Operation
For the Predator® series of units, the thermostat makes a circuit
between "R" and "Y1" for the first stage of cooling.
The call is passed to the Unit Control Board (UCB), which
then determines whether the requested operation is available
and, if so, which components to energize.
For gas heating, the UCB monitors the "W1" call but does not
handle the operation of the gas furnace. An ignition control
board controls the gas heater operation. For electric heat units,
the UCB passes the call to the electric heater. In both cases,
when the "W1" call is sensed, the indoor air blower is energized
following a specified heating delay.
If at any time a call for both heating and cooling are present, the
heating operation will be performed. If operating, the cooling
system is halted as with a completion of a call for cooling.
Heating always takes priority.
Continuous Blower
By setting the room thermostat fan switch to "ON," the supply
air blower will operate continuously.
Intermittent Blower
With the room thermostat fan switch set to "AUTO" and the
system switch set to either the "AUTO" or "HEAT" settings, the
blower is energized whenever a cooling or heating operation is
requested. The blower is energized after any specified delay
associated with the operation.
When energized, the indoor blower has a minimum run time of
30 seconds. Additionally, the indoor blower has a delay of 10
seconds between operations.
No Outdoor Air Options
When the thermostat calls for the first stage of cooling, the lowvoltage control circuit from “R” to “Y1” and “G” is completed.
The UCB energizes the economizer (if installed and free cooling
is available) or the first available compressor* and the
condenser fans. For first stage cooling, compressor #1 is
energized. If compressor #1 is unavailable, compressor #2 is
energized. After completing the specified fan on delay for
cooling, the UCB will energize the blower motor.
When the thermostat calls for the second stage of cooling, the
low-voltage control circuit from “R” to “Y2” is completed. The
control board energizes the first available compressor. If free
cooling is being used for the first stage of cooling, compressor
#1 is energized. If compressor #1 is active for first stage cooling
or the first compressor is locked-out, compressor #2 is
energized. In free-cooling mode, if the call for the second stage
of cooling continues for 20 minutes, compressor #2 is
energized, provided it has not been locked-out.
If there is an initial call for both stages of cooling, the UCB will
delay energizing compressor #2 by 30 seconds in order to
avoid a power rush.
Once the thermostat has been satisfied, it will de-energize Y1
and Y2. If the compressors have satisfied their minimum run
times, the compressors and condenser fans are de-energized.
Otherwise, the unit operates each cooling system until the
minimum run times for the compressors have been completed.
Upon the final compressor de-energizing, the blower is stopped
following the elapse of the fan off delay for cooling.
* To be available, a compressor must not be locked-out due to a
high or low-pressure switch or freezestat trip and the AntiShort Cycle Delay (ASCD) must have elapsed.
Economizer With Single Enthalpy Sensor
When the room thermostat calls for "first-stage" cooling, the low
voltage control circuit from "R" to "G" and "Y1" is completed.
The UCB energizes the blower motor (if the fan switch on the
room thermostat is set in the "AUTO" position) and drives the
economizer dampers from fully closed to their minimum
position. If the enthalpy of the outdoor air is below the set point
of the enthalpy controller (previously determined), "Y1"
energizes the economizer. The dampers will modulate to
maintain a constant supply air temperature as monitored by the
discharge air sensor. If the outdoor air enthalpy is above the set
point, "Y1" energizes compressor #1.
When the thermostat calls for "second-stage" cooling, the low
voltage control circuit from "R" to "Y2" is completed. The UCB
energizes the first available compressor. If the enthalpy of the
outdoor air is below the set point of the enthalpy controller (i.e.
first stage has energized the economizer), "Y2" will energize
compressor #1. If the outdoor air is above the set point, "Y2" will
energize compressor #2.
Once the thermostat has been satisfied, it will de-energize “Y1”
and “Y2”. If the compressors have satisfied their minimum run
times, the compressors and condenser fans are de-energized.
Otherwise, the unit operates each cooling system until the
minimum run times for the compressors have been completed.
Upon the final compressor de-energizing, the blower is stopped
following the elapse of the fan off delay for cooling, and the
economizer damper goes to the closed position. If the unit is in
continues fan operation, the economizer damper goes to the
minimum position.
Economizer With Dual Enthalpy Sensors
The operation with the dual enthalpy sensors is identical to the
single sensor except that a second enthalpy sensor is mounted
in the return air. This return air sensor allows the economizer to
choose between outdoor air and return air, whichever has the
lowest enthalpy value, to provide maximum operating
efficiency.
Economizer With Power Exhaust
A unit equipped with an economizer (single or dual enthalpy)
and a power exhaust operates as specified above with one
52
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164015-YIM-A-0905
addition. The power exhaust motor is energized 45 seconds
after the actuator position exceeds the exhaust fan set point on
the economizer control. When the power exhaust is operating,
the second stage of mechanical cooling will not operate. As
always, the "R" to "G" connection provides minimum position
but does not provide power exhaust operation.
Motorized Outdoor Air Dampers
This system operation is the same as the units with no outdoor
air options with one exception. When the "R" to "G" circuit is
complete, the motorized damper drives open to a position set
by the thumbwheel on the damper motor. When the "R" to "G"
circuit is opened, the damper spring returns fully closed.
Cooling Operation Errors
Each cooling system is monitored for operation outside of the
intended parameters. Errors are handled as described below. All
system errors override minimum run times for compressors.
High-Pressure Limit Switch
During cooling operation, if a high-pressure limit switch opens,
the UCB will de-energize the associated compressor, initiate
the ASCD (Anti-short cycle delay), and, if the other compressor
is idle, stop the condenser fans. If the call for cooling is still
present at the conclusion of the ASCD, the UCB will re-energize
the halted compressor.
Should a high-pressure switch open three times within two
hours of operation, the UCB will lock-out the associated
compressor and flash a code (see Table 29). If the other
compressor is inactive, the condenser fans will be deenergized.
Low-Pressure Limit Switch
The low-pressure limit switch is not monitored during the initial
30 seconds of a cooling system's operation. For the following
30 seconds, the UCB will monitor the low-pressure switch to
ensure it closes. If the low-pressure switch fails to close after
the 30-second monitoring phase, the UCB will de-energize the
associated compressor, initiate the ASCD, and, if the other
compressor is idle, stop the condenser fans.
Once the low-pressure switch has been proven (closed during
the 30-second monitor period described above), the UCB will
monitor the low-pressure limit switch for any openings. If the
low-pressure switch opens for greater than 5 seconds, the UCB
will de-energize the associated compressor, initiate the ASCD,
and, if the other compressor is idle, stop the condenser fans.
If the call for cooling is still present at the conclusion of the
ASCD, the UCB will re-energize the halted compressor.
Should a low-pressure switch open three times within one hour
of operation, the UCB will lock-out the associated compressor
and flash a code (Table 29). If the other compressor is inactive,
the condenser fans will be de-energized.
Unitary Products Group
Freezestat
During cooling operation, if a freezestat opens, the UCB will deenergize the associated compressor, initiate the ASCD, and, if
the other compressor is idle, stop the condenser fans. If the call
for cooling is still present at the conclusion of the ASCD, the
UCB will re-energize the halted compressor.
Should a freezestat open three times within two hours of
operation, the UCB will lock-out the associated compressor and
flash a code (Table 29). If the other compressor is inactive, the
condenser fans will be de-energized.
Low Ambient Cooling
To determine when to operate in low ambient mode, the UCB
has a pair of terminals connected to a temperature-activated
switch set at 45ºF. When the low ambient switch is closed and
the thermostat is calling for cooling, the UCB will operate in the
low ambient mode.
Low ambient mode operates the compressors in this manner:
10 minutes on, 5 minutes off. The indoor blower is operated
throughout the cycle. The 5-minute off period is necessary to
defrost the indoor coil.
Low ambient mode always begins with compressor operation.
Compressor minimum run time may extend the minutes of
compressor operation. The defrost cycle will begin immediately
following the elapse of the minimum run time.
When operating in low ambient mode, the UCB will not lockout
the compressors due to a freezestat trip. However, a freezestat
trip will de-energize the associated compressor. If the call for
cooling is still present at the end of the ASCD and the freezestat
has closed, the unit will resume operation.
Safety Controls
The unit control board monitors the following inputs for each
cooling system:
1.
A suction line freezestat to protect against low evaporator
temperatures due to a low airflow or a low return air
temperature, (opens at 26 ± 5 °F and resets at 38 ± 5°F).
2.
A high-pressure switch to protect against excessive
discharge pressures due to a blocked condenser coil or a
condenser motor failure, (opens at 625 ± 25 psig).
3.
A low-pressure switch to protect against loss of refrigerant
charge, (opens at 7 ± 3 psig).
The above pressure switches are hard-soldered to the unit. The
refrigeration systems are independently monitored and
controlled. On any fault, only the associated system will be
affected by any safety/preventive action. The other refrigerant
system will continue in operation unless it is affected by the
fault as well.
The unit control board monitors the temperature limit switch of
electric heat units and the temperature limit switch and the gas
valve of gas furnace units.
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164015-YIM-A-0905
Compressor Protection
Limit Switch (Ls)
In addition to the external pressure switches, the compressors
also have inherent (internal) protection. If there is an abnormal
temperature rise in a compressor, the protector will open to shut
down the compressor. The UCB incorporates features to
minimize compressor wear and damage. An Anti-Short Cycle
Delay (ASCD) is utilized to prevent operation of a compressor
too soon after its previous run. Additionally, a minimum run time
is imposed any time a compressor is energized.
This control is located inside the heater compartment and is set
to open at the temperature indicated in the Electric Heat Limit
Setting Tables 21 and 22. It resets automatically. The limit
switch operates when a high temperature condition, caused by
inadequate supply air flow occurs, thus shutting down the
heater and energizing the blower.
Table 22: Electric Heat Limit Setting 50” Cabinet
The ASCD is initiated on unit start-up and on any compressor
reset or lock-out.
UNIT (TONS)
Flash Codes
VOLTAGE
ZH102, 120, 150
(8.5, 10, 12.5)
208/230
Reset
ZH102, 120, 150
(8.5, 10, 12.5)
480
Remove the call for cooling, by raising thermostat setting higher
than the conditioned space temperature. This resets any
pressure or freezestat flash codes.
ZH102, 120, 150
(8.5, 10, 12.5)
600
The UCB will initiate a flash code associated with errors within
the system. Refer to UNIT CONTROL BOARD FLASH CODES
Table 29.
Electric Heating Sequence Of Operations
The following sequence describes the operation of the electric
heat section.
18
24
34
54
18
24
34
54
18
24
34
54
LIMIT
SWITCH
OPENS °F
150
150
150
130
150
150
150
130
150
150
150
130
Table 23: Electric Heat Limit Setting 42” Cabinet
UNIT (TONS)
Two-stage heating:
a. Upon a call for first stage heat by the thermostat, the
heater relay (RA) will be energized. After completing the
specified fan on delay for heating, the UCB will energize
the blower motor. If the second stage of heat is required,
heater relay (RB) will be energized. After completing the
specified fan on delay for heating, the UCB will energize
the blower motor.
HEATER
kW
VOLTAGE
ZH078, 090 (6.5, 7.5)
208/230
ZH078, 090 (6.5, 7.5)
480
ZH078, 090 (6.5, 7.5)
600
b The thermostat will cycle the electric heat to satisfy the
heating requirements of the conditioned space.
Electric Heat Operation Errors
HEATER
kW
9
18
24
34
9
18
24
34
9
18
24
34
LIMIT
SWITCH
OPENS °F
135
150
165
190
135
150
165
185
135
150
150
185
Temperature Limit
Flash Codes
If the UCB senses zero volts from the high temperature limit,
the indoor blower motor is immediately energized.
This limit is monitored regardless of unit operation status, i.e.
the limit is monitored at all times.
If the temperature limit opens three times within one hour, it will
lock-on the indoor blower motor and a flash code is initiated
(See Table 29).
The UCB will initiate a flash code associated with errors within
the system. Refer to UNIT CONTROL BOARD FLASH CODES
Table 29.
Reset
Remove the call for heating by lowering the thermostat setting
lower than the conditioned space temperature.This resets any
flash codes.
Safety Controls
The UCB monitors the temperature limit switch of electric heat
units.
The control circuit includes the following safety controls:
54
Electric Heat Anticipator Setpoints
It is important that the anticipator setpoint be correct. Too high
of a setting will result in longer heat cycles and a greater
temperature swing in the conditioned space. Reducing the
Unitary Products Group
164015-YIM-A-0905
value below the correct setpoint will give shorter “ON” cycles
and may result in the lowering of the temperature within the
conditioned space. Refer to Table 23 for the required electric
heat anticipator setting.
Table 24: Electric Heat Anticipator Setpoints
SETTING, AMPS
W1
W2
0.13
0.1
Gas Heating Sequence Of Operations
When the thermostat calls for the first stage of heating, the lowvoltage control circuit from “R” to “W1” is completed. A call for
heat passes through the UCB to the Ignition Control Board
(ICB). The UCB monitors the “W1” call and acts upon any call
for heat by monitoring the Gas Valve (GV). Once voltage has
been sensed at the GV, the UCB will initiate the fan on delay for
heating, energizing the indoor blower the specified delay has
elapsed.
When the thermostat has been satisfied, heating calls are
ceased. The GV is immediately closed. The blower is deenergized after the fan off delay for heating has elapsed. The
draft motor performs a 30-second post purge.
Ignition Control Board
First Stage Of Heating
When the ICB receives a call for first stage of heating, “W1,” the
draft motor is energized. Once the draft motor has been proven,
a 30-second purge is initiated. At the end of the purge, the GV
is opened, and the spark ignitor is energized for 10 seconds.
The ICB then checks for the presence of flame. If flame is
detected, the ICB enters a flame stabilization period. If flame
was not detected, the GV closes, and a retry operation begins.
During the flame stabilization period, a loss of the flame for 2
seconds will cause the GV to close and the retry operation to
begin. After the flame stabilization period, a loss of flame for 3/4
second will cause the GV to close and the retry operation to
begin.
At the conclusion of the flame stabilization period, the ICB will
operate the gas heat in high fire for an additional 60 seconds
(for a total for 120 seconds of high fire operation). After this 60
seconds, the ICB will then use the call for the second stage of
heat to control second stage operation of the GV.
When “W1” is satisfied, both valves are closed.
Second Stage Of Heating
When the ICB receives a call for the second stage of heating,
“W2,” the ICB conducts a complete first stage ignition
sequence. If this sequence is satisfied, the second main valve
of the GV is opened.
Retry Operation
When a flame is lost or is not detected during an attempt to
achieve ignition, a retry operation occurs. A 30-second purge is
performed between ignition attempts.
If the unit fails after three ignition attempts, the furnace is
locked-out for one hour. The furnace is monitored during this
one-hour period for unsafe conditions.
Recycle Operation
When a flame is lost after the flame stabilization period, a recycle operation occurs. If the unit fails after five recycle attempts,
the furnace is locked-out for one hour.
Gas Heating Operation Errors
Lock-Out
A one-hour lockout occurs following three retries or five
recycles. During the one-hour lockout, flame detection, limit
conditions, and main valves are tested. Any improper results
will cause the appropriate action to occur. Recycling the low
voltage power cancels the lock-out.
Temperature Limit
If the UCB senses zero volts from the high temperature limit,
the indoor blower motor is immediately energized. When the
UCB again senses 24 volts from the temperature limit, the draft
motor will perform a 15-second post-purge and the indoor
blower will be de-energized following the elapse of the fan off
delay for heating.
This limit is monitored regardless of unit operation status, i.e.
this limit is monitored at all times.
If the temperature limit opens three times within one hour, it will
lock-on the indoor blower motor and flash code is initiated (See
Table 29).
Flame Sense
Flame sensing occurs at all times. If “W1” is not present and a
flame is sensed for 2 seconds, the draft motor is energized and
the GV is kept off. The ICB halts any operation until a flame is
not detected. Once the flame detection is lost, the ICB performs
a post-purge. Normal operation is allowed concurrently with the
purge (i.e. this purge can be considered the purge associated
with a call for “W1”).
If “W1” is present, a flame is sensed, but the GV is not
energized, the draft motor is energized until the flame detection
is lost. Normal operation is now allowed.
The flame detection circuitry continually tests itself. If the ICB
finds the flame detection circuitry to be faulty, the ICB will not
permit an ignition sequence and the draft motor is energized. If
this failure should occur during an ignition cycle the failure is
counted as a recycle.
When “W2” is satisfied, the second main valve is closed.
Unitary Products Group
55
164015-YIM-A-0905
Gas Valve
Table 25: Gas Heat Limit Control Settings1
The UCB and ICB continuously monitor the GV.
If the ICB senses voltage at the GV when not requested, the
ICB will energize the draft motor. The ICB will not operate the
furnace until voltage is no longer sensed at the GV. The draft
motor is stopped when voltage is not sensed at the GV.
Any time the UCB senses voltage at the GV without a call for
heat for a continuous five-minute period, the UCB will lock-on
the indoor blower and a flash code is initiated (Table 29). When
voltage is no longer sensed at the GV, the UCB will de-energize
the indoor blower following the elapse of the fan off delay for
heating.
If voltage has been sensed at the GV for at least 15 seconds
during the fan on delay for heating and GV voltage or “W1” is
lost, the indoor blower is forced on for the length of the fan off
delay for heating.
During a call for heat, if the UCB does not sense voltage at the
GV for a continuous five-minute period the UCB will initiate a
flash code (Table 29). The indoor blower motor will not be
locked-on while there is no GV voltage.
Unit
Size
ZH078
ZH090
ZH102
ZH120
ZH150
Main Limit Setting
°F
Opt.
10
15
10
15
10
15
15
20
15
20
165
165
165
165
215
195
195
160
195
160
1. Rollout = 300°F, Auxiliary Limit = 200°F.
The ICB monitors the Pressure and Rollout switches of gas
heat units.
The control circuit includes the following safety controls:
Pressure Switch (PS)
The control circuit includes the following safety controls:
Once the draft motor has reached full speed and closes the
pressure switch during a normal ignition sequence, if the
pressure sw opens for 2 seconds, the GV will be de-energized,
the ignition cycle is aborted, and the ICB flashes the
appropriate code. See Table 30 Ignition Control Flash Codes.
The draft motor is energized until the pressure switch closes or
“W1” is lost.
Limit Switch (LS)
Rollout Switch (ROS)
This control is located inside the gas heat compartment and is
set to open at the temperature indicated in the Gas Heat Limit
Control Settings Table 24. It resets automatically. The limit
switch operates when a high temperature condition, caused by
inadequate supply air flow occurs, thus shutting down the
heater and energizing the blower.
The rollout switch is wired in series with the pressure switch. As
such, the ICB cannot distinguish the rollout switch operation
from that of the pressure switch.
Safety Controls
The UCB monitors the temperature limit switch of gas heat
units.
Consequently, the control will only respond in the same manner
as outlined above under “Pressure Switch”. An open rollout will
inhibit the gas valve from actuating.
Auxiliary Limit Switch (ALS)
Internal Microprocessor Failure
This control is located inside the supply air compartment and is
set to open at the temperature indicated in the Gas Heat Limit
Control Settings Table 24. It resets manually. The limit switch
operates when a high temperature condition, caused by
inadequate supply air flow occurs, thus shutting down the
heater and energizing the blower.
The auxiliary limit switch is wired in series with the limit switch.
As such, the UCB cannot distinguish the auxiliary limit and the
gas heat limit switch operation except the auxiliary is manual
reset. Consequently, the control will respond in the same
manner as outlined above under “Limit Switch”.
If the ICB detects an internal failure, it will cease all outputs,
ignore inputs, and display the proper flash code for control
replacement. The ICB remains in this condition until replaced.
Flash Codes
The UCB will initiate a flash code associated with errors within
the system. Refer to UNIT CONTROL BOARD FLASH CODES
Table 29.
Resets
Remove the call for heating by lowering the thermostat setting
lower than the conditioned space temperature. This resets any
flash codes.
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Unitary Products Group
164015-YIM-A-0905
Gas Heat Anticipator Setpoints
Start-Up (Gas Heat)
It is important that the anticipator setpoint be correct. Too high
of a setting will result in longer heat cycles and a greater
temperature swing in the conditioned space. Reducing the
value below the correct setpoint will give shorter “ON cycles
and may result in the lowering of the temperature within the
conditioned space. Refer to Table 26 for the required gas heat
anticipator setting.
Pre-Start Check List
Table 26: Gas Heat Anticipator Setpoints
Complete the following checks before starting the unit.
1. Check the type of gas being supplied. Be sure that it is the
same as listed on the unit nameplate.
2.
Make sure that the vent outlet and combustion air inlet are
free of any debris or obstruction.
Operating Instructions
SETTING, AMPS
W1
W2
0.65
0.1
This furnace is equipped with an automatic re-ignition
system. DO NOT attempt to manually light the pilot.
Start-Up (Cooling)
Prestart Check List
After installation has been completed:
Lighting The Main Burners
1.
Turn “OFF” electric power to unit.
2.
Turn room thermostat to lowest setting.
3.
Turn gas valve counter-clockwise to “ON” position (See
Figure 33).
4.
Turn “ON” electric power to unit.
5.
If thermostat set temperature is above room temperature,
the main burners will ignite. If a second stage of heat is
called for, the main burners for second stage heat will
ignite for the second stage heat.
1.
Check the electrical supply voltage being supplied. Be sure
that it is the same as listed on the unit nameplate.
2.
Set the room thermostat to the off position.
3.
Turn unit electrical power on.
4.
Set the room thermostat fan switch to on.
5.
Check indoor blower rotation.
• If blower rotation is in the wrong direction. Refer to
Phasing Section in general information section.
Check blower drive belt tension.
Post Start Checklist
6.
Check the unit supply air (CFM).
7.
Measure evaporator fan motor's amp draw.
8.
Set the room thermostat fan switch to off.
9.
Turn unit electrical power off.
After the entire control circuit has been energized and the
heating section is operating, make the following checks:
1. Check for gas leaks in the unit piping as well as the supply
piping.
Operating Instructions
1.
Turn unit electrical power on.
FIRE OR EXPLOSION HAZARD
Failure to follow the safety warning exactly could result
in serious injury, death or property damage.
Never test for gas leaks with an open flame. use a
commercially available soap solution made specifically
for the detection of leaks to check all connections. A fire
or explosion may result causing property damage,
personal injury or loss of life.
NOTE: Prior to each cooling season, the crankcase heaters
must be energized at least 10 hours before the system
is put into operation.
2.
Set the room thermostat setting to lower than the room
temperature.
3.
First stage compressors will energize after the built-in time
delay (five minutes).
4.
The second stage of the thermostat will energize second
stage compressor if needed.
Post Start Check List
1.
Verify proper system pressures for both circuits.
2.
Measure the temperature drop across the evaporator coil.
Unitary Products Group
2.
Check for correct manifold gas pressures. (See CHECKING
GAS INPUT.)
3.
Check the supply gas pressure. It must be within the limits
shown on the rating nameplate. Supply pressure should be
checked with all gas appliances in the building at full fire. At
no time should the standby gas pressure exceed 10.5 in. or
the operating pressure drop below 4.5 in for natural gas
units. If gas pressure is outside these limits, contact the
local gas utility or propane supplier for corrective action.
57
164015-YIM-A-0905
Shut Down
1.
Set the thermostat to the lowest temperature setting.
2.
Turn “OFF” all electric power to unit.
3.
Open gas heat access panel.
4.
Turn gas valve clockwise to “OFF” position (See Figure 33).
Checking Gas Heat Input
This unit has two stages of gas heat. The first stage is 60% of
the full fire input and is considered the minimum input for the
furnace. The intended input for each furnace is shown in
Table 27. The table applies to units operating on 60 Hz power
only.
To determine the rate of gas flow (Second Stage).
1.
Turn off all other gas appliances connected to the gas
meter.
2.
Turn on the furnace and make sure the thermostat is
calling for Second stage (100% input) heat.
3.
Measure the time needed for one revolution of the hand on
the smallest dial on the meter. A typical gas meter has a 1/
2 or a 1 cubic foot test dial.
4.
Using the number of seconds it takes for one revolution of
the dial, calculate the cubic feet of gas consumed per hour.
(See example below).
5.
If necessary, adjust the high pressure regulator as
discussed in the section “Manifold Gas Pressure
Adjustment”. Be sure not to over-fire the furnace on
Second stage. If in doubt, it is better to leave the Second
stage of the furnace slightly under-fired. Repeat Steps 1-5.
To determine the rate of gas flow (First Stage)
1.
Turn off all other gas appliances connected to the gas
meter.
2.
Turn on the furnace and make sure the thermostat is
calling for first stage (60% input) heat.
3.
Even when the thermostat is calling for first stage heat, the
unit will light on second stage and will run on Second stage
for 1 minute. Allow this one-minute time period to expire
and be certain the unit is running on first stage.
4.
Measure the time needed for one revolution of the hand on
the smallest dial on the meter. A typical gas meter has a 1/
2 or a 1 cubic foot test dial.
5.
Using the number of seconds it takes for one revolution of
the dial, calculate the cubic feet of gas consumed per hour
(See example below).
6.
If necessary, adjust the low pressure regulator as
discussed in the section “Manifold Gas Pressure
Adjustment”. Be sure not to under-fire the furnace on first
stage. If in doubt, it is better to leave the first stage of the
furnace slightly over-fired (greater than 60% input). Repeat
Steps 1-6.
58
Table 27: Gas Rate Cubic Feet Per Hour
Seconds for
One Rev.
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
52
54
56
58
60
Size of Test Dial
1/2 cu. ft.
1 cu. ft.
180
360
150
300
129
257
113
225
100
200
90
180
82
164
75
150
69
138
64
129
60
120
56
113
53
106
50
100
47
95
45
90
43
86
41
82
39
78
37
75
36
72
35
69
34
67
32
64
31
62
30
60
NOTE: To find the Btu input, multiply the number of cubic feet
of gas consumed per hour by the Btu content of the gas
in your particular locality (contact your gas company for
this information as it varies widely from area to area).
EXAMPLE
By actual measurement, it takes 19 seconds for the hand on a 1
cubic foot dial to make a revolution with a 192,000 Btuh furnace
running. To determine rotations per minute, divide 60 by 19 =
3.16. To calculate rotations per hour, multiply 3.16 • 60 = 189.6.
Multiply 189.6 • 1 (0.5 if using a 1/2 cubic foot dial) = 189.6.
Multiply 189.6 • (the Btu rating of the gas). For this example,
assume the gas has a Btu rating of 1050 Btu/ft.3. The result of
199,000 Btuh is within 5% of the 192,000 Btuh rating of the
furnace.
Manifold Gas Pressure Adjustment
This gas furnace has two heat stages. Therefore, the gas valve
has two adjustment screws located under a plastic protective
cover. The second stage (100% input) adjustment screw is
adjacent to the “HI” marking on the valve and the first stage
(60% input) adjustment screw is located adjacent to the “LO”
marking on the valve (See Figure 33).
Manifold pressure adjustment procedure.
Unitary Products Group
164015-YIM-A-0905
Adjust second stage (100% input) pressure first, then adjust
first stage (60% input) pressure.
1.
Turn off all power to the unit.
2.
Using the outlet pressure port on the gas valve, connect a
manometer to monitor the manifold pressure.
3.
Remove plastic cap covering HI and LO pressure
adjustment screws.
4.
5.
6.
Before checking or changing burners, pilot or orifices, CLOSE
MAIN MANUAL SHUT-OFF VALVE AND SHUT OFF ALL
POWER TO THE UNIT.
1.
Open the union fitting just upstream of the unit gas valve
and downstream from the main manual shut-off valve in
the gas supply line.
Turn on power to the unit.
2.
Set thermostat to call for second stage heat and start
furnace.
Remove the screws holding each end of the manifold to the
manifold supports.
3.
If necessary, using a screwdriver, turn the second stage
adjustment screw (adjacent to the “HI” marking on the
valve) clockwise to increase manifold pressure or
counterclockwise to decrease manifold pressure. Be sure
not to over-fire the unit on second stage.
Disconnect wiring to the gas valves and spark igniter(s).
Remove the manifold & gas valve assembly. Orifices can
now be inspected and/or replaced.
To service burners, complete step 4.
7.
After the high manifold pressure has been checked, adjust
the thermostat to call for first stage heat.
8.
If necessary, using a screwdriver, turn the first stage
adjustment screw (adjacent to the “LO” marking on the
valve) clockwise to increase manifold pressure or
counterclockwise to decrease manifold pressure. Be sure
not to under-fire the unit on first stage.
9.
Burners/Orifices Inspection/Servicing
4.
Remove the heat shield on top of the manifold supports.
Burners are now accessible for inspection and/or
replacement.
NOTE: Reverse the above procedure to replace the
assemblies.
Make sure that burners are level and seat at the rear of the gas
orifice.
Once pressure has been checked, replace the plastic cap
covering the HI and LO pressure adjustment screws.
NOTE: When using natural gas, the manifold pressure for
second stage (100% input) should be 3.5 IWG ± 0.3.
The manifold pressure for first stage (60% input) when
using natural gas should be 1.5 IWG ± 0.3.
Table 28: Gas Heat Stages
# of Burner Tubes
4
6
8
2nd Stage Input
(100% Btuh)
120,000
180,000
240,000
1st Stage Input
(60% Btuh)
72,000
108,000
144,000
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Adjustment Of Temperature Rise
The temperature rise (the difference of temperature between the
return air and the heated air from the furnace) must lie within the
range shown on the CSA rating plate and the data in Table 11.
After the temperature rise has been determined, the CFM can
be calculated as follows:
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After about 20 minutes of operation, determine the furnace
temperature rise. Take readings of both the return air and the
heated air in the ducts (about 6 feet from the furnace) where
they will not be affected by radiant heat. Increase the blower
CFM to decrease the temperature rise; decrease the blower
CFM to increase the rise (See SUPPLY AIR DRIVE
ADJUSTMENT).
NOTE: Each gas heat exchanger size has a minimum
allowable CFM. Below this CFM, the limit will open.
Unitary Products Group
09
&
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Figure 33: Typical Gas Valve
59
164015-YIM-A-0905
Charging The Unit
All ZH units use Thermal Expansion Devices. Charge the unit to
10° subcooling.
Table 29: Unit Control Board Flash Codes
Flash Code
On Steady
Heart Beat
Troubleshooting
1 Flash
Normal Operation
Not Applicable
2 Flashes
Control waiting ASCD1
3 Flashes
HPS1 - Compressor Lock out
4 Flashes
HPS2 - Compressor Lock out
5 Flashes
LPS1 - Compressor Lock out
Troubleshooting of components may require opening
the electrical control box with the power connected to
the unit. Use extreme care when working with live
circuits! Check the unit nameplate for the correct line
voltage and set the voltmeter to the correct range before
making any connections with line terminals.
6 Flashes
LPS2 - Compressor Lock out
7 Flashes
FS1 - Compressor Lock out
8 Flashes
FS2 - Compressor Lock out
9 Flashes
Ignition Control Locked Out/
Ignition Control Failure / Limit Switch Trip / No
Jumper Plug in Heat Section
When not necessary, shut off all electric power to the
unit prior to any of the following maintenance
procedures so as to prevent personal injury.
10 Flashes
Compressors Locked Out On Low
Outdoor Air Temperature1
11 Flashes
Compressors Locked Out Because The
Economizer Is Using Free Cooling1
12 Flashes
Fan Overload Switch Trip - Not Applicable On
This Unit
13 Flashes
Compressor Held Off Due To Low Voltage1
14 Flashes
Label all wires prior to disconnection when servicing
controls. Wiring errors can cause improper and
dangerous operation which could cause injury to person
and/or damage unit components. Verify proper
operation after servicing.
Predator® Flash Codes
Various flash codes are utilized by the unit control board (UCB)
to aid troubleshooting. Flash codes are distinguished by the
short on and off cycle used (approximately 200ms on and
200ms off). To show normal operation, the control board
flashes a 1 second on, 1 second off “heartbeat” during normal
operation. This is to verify that the UCB is functioning correctly.
Do not confuse this with an error flash code. To prevent
confusion, a 1-flash, flash code is not used.
Current alarms are flashed on the UCB LED. The alarm history
can be checked by pressing and releasing the ALARMS button
on the UCB. The UCB will cycle through the last five (5) alarms,
most recent to oldest, separating each alarm flash code by
approximately 2 seconds.
In some cases, it may be necessary to “zero” the ASCD for
the compressors in order to perform troubleshooting. To
reset all ASCDs for one cycle, press and release the UCB
TEST button once.
OFF
EEPROM Storage Failure (Control Failure)
No Power or Control Failure
1. These flash codes do not represent alarms.
Table 30: Ignition Control Flash Codes
Flashes
STEADY ON
HEARTBEAT
Fault Conditions
Control Failure
Check
Control
Normal Operation
1
Not Applicable
2
Pressure Switch
Stuck Closed
Pressure Switch
3
Pressure Switch Failed
To Close
Venter Pressure Switch
Vent Blocked
4
Limit Switch Open
Main Limit
AUX Limit
5
Flame Present With Gas
Off First Stage Gas Valve
Energized With W1 Off
Second Stage Gas Valve
Energized With First
Stage
Gas Valve Off
Gas Valve
Ignition Lockout
Gas Flow
Gas Pressure
Gas Valve
Flame Sensor
No Power Or Control
Failure
24VAC or Control
6
STEADY OFF
60
Description
Control Failure - Replace Control
Unitary Products Group
164015-YIM-A-0905
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Unitary Products Group
61
164015-YIM-A-0905
Figure 36: Trip Failure Flow Chart
62
Unitary Products Group
164015-YIM-A-0905
Cooling Troubleshooting Guide
the economizer provides free cooling, following a short
delay compressor #1 will be energized unless it is locked
out. If compressor #1 is locked out, compressor #2 is
energized. Compressor #2 is always energized in place of
compressor #1 when compressor #1 is requested but
locked out.
On calls for cooling, if the compressors are operating but the
supply air blower motor does not energize after a short delay
(the room thermostat fan switch is in the “AUTO” position):
1.
Turn the thermostat fan switch to the ON position. If the
supply air blower motor does not energize, go to Step 3.
2.
If the blower motor runs with the fan switch in the ON
position but will not run after the first compressor has
energized when the fan switch is in the AUTO position,
check the room thermostat for contact between R and G in
the AUTO position during calls for cooling.
3.
4.
5.
6.
2.
If no economizer is installed or the economizer is not
opening to provide free cooling and compressor #1 does
not energize on a call for cooling, check for line voltage at
the compressor contactor, M1, and that the contactor is
pulled in. Check for loose wiring between the contactor and
the compressor.
If the supply air blower motor does not energize when the
fan switch is set to ON, check that line voltage is being
supplied to the contacts of the M3, contactor, and that the
contactor is pulled in. Check for loose wiring between the
contactor and the supply air blower motor.
3.
If M1 is pulled in and voltage is supplied at M1, lightly touch
the compressor housing. If it is hot, the compressor may be
off on inherent protection. Cancel any calls for cooling and
wait for the internal overload to reset. Test again when
cool.
If M3 is pulled in and voltage is supplied to M3, lightly touch
the supply air blower motor housing. If it is hot, the motor
may be off on internal protection. Cancel any thermostat
calls and set the fan switch to AUTO. Wait for the internal
overload to reset. Test again when cool.
4.
If M1 is not pulled in, check for 24 volts at the M1 coil. If 24
volts are present and M1 is not pulled in, replace the
contactor.
5.
Failing the above, if voltage is supplied at M1, M1 is pulled
in, and the compressor still does not operate, replace the
compressor.
6.
If 24 volts is not present at M1, check for 24 volts at the
UCB terminal, C1. If 24 volts is present, check for loose
wiring between C1 and the compressor contactor.
7.
If 24 volts is not present at the C1 terminal, check for 24
volts from the room thermostat at the UCB Y1 terminal. If
24 volts is not present from the room thermostat, check for
the following:
a. 24 volts at the thermostat Y1 terminal
b. Proper wiring between the room thermostat and the
UCB, i.e. Y1 to Y1, Y2 to Y2, and
c. Loose wiring from the room thermostat to the UCB
8.
If 24 volts is present at the UCB Y1 terminal, the
compressor may be out due to an open high-pressure
switch, low-pressure switch, or freezestat. Check for 24
volts at the HPS1, LPS1, and FS1 terminals of the UCB. If
a switch has opened, there should be a voltage potential
between the UCB terminals, e.g. if LPS1 has opened, there
will be a 24-volt potential between the LPS1 terminals.
9.
If 24 volts is present at the UCB Y1 terminal and none of
the protection switches have opened, the UCB may have
locked out the compressor for repeat trips. The UCB
should be flashing an alarm code. If not, press and release
the ALARMS button on the UCB. The UCB will flash the
last five alarms on the LED. If the compressor is locked
out, cancel any call for cooling. This will reset any
compressor lock outs.
If M3 is not pulled in, check for 24 volts at the M3 coil. If 24
volts are present at M3 but M3 is not pulled in, replace the
contactor.
Failing the above, if there is line voltage supplied at M3, M3
is pulled in, and the supply air blower motor still does not
operate, replace the motor.
7.
If 24 volts is not present at M3, check that 24 volts is
present at the UCB supply air blower motor terminal,
“FAN”. If 24 volts is present at the FAN, check for loose
wiring between the UCB and M3.
8.
If 24 volts is not present at the “FAN” terminal, check for 24
volts from the room thermostat. If 24 volts are not present
from the room thermostat, check for the following:
a. Proper operation of the room thermostat (contact
between R and G with the fan switch in the ON position
and in the AUTO position during operation calls).
b. Proper wiring between the room thermostat and the
UCB, and
c. Loose wiring from the room thermostat to the UCB
9.
If 24 volts is present at the room thermostat but not at the
UCB, check for proper wiring between the thermostat and
the UCB, i.e. that the thermostat G terminal is connected to
the G terminal of the UCB, and for loose wiring.
10. If the thermostat and UCB are properly wired, replace the
UCB.
On calls for cooling, the supply air blower motor is operating but
compressor #1 is not (the room thermostat fan switch is in the
“AUTO” position):
1.
If installed, check the position of the economizer blades. If
the blades are open, the economizer is providing free
cooling and the compressors will not immediately operate.
If both stages of cooling are requested simultaneously and
Unitary Products Group
NOTE: While the above step will reset any lockouts,
compressor #1 may be held off for the ASCD. See the
next step.
10. If 24 volts is present at the UCB Y1 terminal and none of
the switches are open and the compressor is not locked
63
164015-YIM-A-0905
out, the UCB may have the compressor in an ASCD.
Check the LED for an indication of an ASCD cycle. The
ASCD should time out within 5 minutes. Press and release
the TEST button to reset all ASCDs.
11. If 24 volts is present at the UCB Y1 terminal and the
compressor is not out due to a protective switch trip, repeat
trip lock out, or ASCD, the economizer terminals of the
UCB may be improperly wired. Check for 24 volts at the Y1
“OUT” terminal of the UCB. If 24 volts is present, trace the
wiring from Y1 “OUT” for incorrect wiring. If 24 volts is not
present at the Y1 “OUT” terminal, the UCB must be
replaced.
12. For units without economizers: If 24 volts is present at the
Y1 OUT terminal, check for 24 volts at the Y1 “ECON”
terminal. If 24 volts is not present, check for loose wiring
from the Y1 “OUT” terminal to the Mate-N-Lock plug, the
jumper in the Mate-N-Lock plug, and in the wiring from the
Mate-N-Lock plug to the Y1 “ECON” terminal.
13. For units with economizers: If 24 volts is present at the Y1
“OUT” terminal, check for 24 volts at the Y1 “ECON”
terminal. If 24 volts is not present, check for loose wiring
from the Y1 “OUT” terminal to the Mate-N-Lock plug, a
poor connection between the UCB and economizer MateN-Lock plugs, loose wiring from the Mate-N-Lock plug to
the economizer, back to the Mate-N-Lock plug, and from
the Mate-N-Lock plug to the Y1 “ECON” terminal. If nothing
is found, the economizer control may have faulted and is
failing to return the 24-volt “call” to the Y1 “ECON” terminal
even though the economizer is not providing free cooling.
To test, disconnect the Mate-N-Locks and jumper between
the WHITE and YELLOW wires of the UCB’s Mate-N-Lock
plug. If compressor #1 energizes, there is a fault in the
economizer wiring or the economizer control.
14. The UCB can be programmed to lock out compressor
operation during free cooling and in low ambient
conditions. These options are not enabled by default. Local
York distributors can test the UCB for this programming.
15. If none of the above corrected the error, test the integrity of
the UCB. Disconnect the C1 terminal wire and jumper it to
the Y1 terminal. DO NOT jump the Y1 to C1 terminals. If
the compressor engages, the UCB has faulted.
16. If none of the above correct the error, replace the UCB.
On calls for the second stage of cooling, the supply air blower
motor and compressor #1 are operating but compressor #2 is
not (the room thermostat fan switch is in the “AUTO” position):
1.
2.
64
If installed, check the position of the economizer blades. If
the blades are open, the economizer is providing free
cooling. If the second stage of cooling is requested,
following a short delay, compressor #1 will be energized
unless it is locked out. Typically, compressor #2 is
energized only during free cooling if the call for the second
stage of cooling persists for 20 minutes.
Compressor #2 will not energize simultaneously with
compressor #1 if a call for both stages of cooling is
received. The UCB delays compressor #2 by 30 seconds
to prevent a power surge. If after the delay compressor #2
does not energize on a second stage call for cooling, check
for line voltage at the compressor contactor, M2, and that
the contactor is pulled in. Check for loose wiring between
the contactor and the compressor.
3.
If M2 is pulled in and voltage is supplied at M2, lightly touch
the compressor housing. If it is hot, the compressor may be
off on inherent protection. Cancel any calls for cooling and
wait for the internal overload to reset. Test again when cool.
4.
If M2 is not pulled in, check for 24 volts at the M2 coil. If 24
volts is present and M2 is not pulled in, replace the
contactor.
5.
Failing the above, if voltage is supplied at M2, M2 is pulled
in, and the compressor still does not operate, replace the
compressor.
6.
If 24 volts is not present at M2, check for 24 volts at the
UCB terminal, C2. If 24 volts are present, check for loose
wiring between C2 and the compressor contactor.
7.
If 24 volts is not present at the C2 terminal, check for 24
volts from the room thermostat at the UCB Y2 terminal. If
24 volts is not present from the room thermostat, check for
the following:
a. 24 volts at the thermostat Y2 terminal
b. Proper wiring between the room thermostat and the
UCB, i.e. Y1 to Y1, Y2 to Y2, and
c. Loose wiring from the room thermostat to the UCB
8.
If 24 volts is present at the UCB Y2 terminal, the
compressor may be out due to an open high-pressure
switch, low-pressure switch, or freezestat. Check for 24
volts at the HPS2, LPS2, and FS2 terminals of the UCB. If
a switch has opened, there should be a voltage potential
between the UCB terminals, e.g. if LPS2 has opened, there
will be 24 volts of potential between the LPS2 terminals.
9.
If 24 volts is present at the UCB Y2 terminal and none of
the protection switches have opened, the UCB may have
locked out the compressor for repeat trips. The UCB
should be flashing a code. If not, press and release the
ALARMS button on the UCB. The UCB will flash the last
five alarms on the LED. If the compressor is locked out,
remove any call for cooling at the thermostat or by
disconnecting the thermostat wiring at the Y2 UCB
terminal. This will reset any compressor lock outs.
NOTE: While the above step will reset any lock outs,
compressor #1 will be held off for the ASCD, and
compressor #2 may be held off for a portion of the
ASCD. See the next step.
10. If 24 volts is present at the UCB Y2 terminal and none of
the switches are open and the compressor is not locked
out, the UCB may have the compressor in an ASCD.
Check the LED for an indication of an ASCD cycle. The
ASCD should time out within 5 minutes. Press and release
the TEST button to reset all ASCDs.
Unitary Products Group
164015-YIM-A-0905
11. The UCB can be programmed to lock out compressor
operation during free cooling and in low ambient
conditions. These options are not enabled by default. Local
York distributors can test the UCB for this programming.
12. If none of the above corrected the error, test the integrity of
the UCB. Disconnect the C2 terminal wire and jumper it to
the Y2 terminal. DO NOT jump the Y2 to C2 terminals. If
the compressor engages, the UCB has faulted.
13. If none of the above correct the error, replace the UCB.
On a call for cooling, the supply air blower motor and
compressor #2 are operating but compressor #1 is not (the
room thermostat fan switch is in the “AUTO” position):
1.
Compressor #2 is energized in place of compressor #1
when compressor #1 is unavailable for cooling calls. Check
the UCB for alarms indicating that compressor #1 is locked
out. Press and release the ALARMS button if the LED is
not flashing an alarm.
2.
Check for line voltage at the compressor contactor, M1,
and that the contactor is pulled in. Check for loose wiring
between the contactor and the compressor.
3.
If M1 is pulled in and voltage is supplied at M1, lightly touch
the compressor housing. If it is hot, the compressor may be
off on inherent protection. Cancel any calls for cooling and
wait for the internal overload to reset. Test again when cool.
4.
If M1 is not pulled in, check for 24 volts at the M1 coil. If 24
volts is present and M1 is not pulled in, replace the
contactor.
5.
Failing the above, if voltage is supplied at M1, M1 is pulled
in, and the compressor still does not operate, replace the
compressor.
6.
If 24 volts is not present at M1, check for 24 volts at the
UCB terminal, C1. If 24 volts is present, check for loose
wiring between C1 and the compressor contactor.
7.
If 24 volts is not present at the C1 terminal, check for 24
volts from the room thermostat at the UCB Y1 terminal. If
24 volts are not present at the UCB Y1 terminal, the UCB
may have faulted. Check for 24 volts at the Y1 ECON
terminal. If 24 volts is not present at Y1 “ECON”, the UCB
has faulted. The UCB should de-energize all compressors
on a loss of call for the first stage of cooling, i.e. a loss if 24
volts at the Y1 terminal.
8.
9.
If 24 volts are present at the UCB Y1 terminal, the
compressor may be out due to an open high-pressure
switch, low-pressure switch, or freezestat. Check for 24
volts at the HPS1, LPS1, and FS1 terminals of the UCB. If
a switch has opened, there should be a voltage potential
between the UCB terminals, e.g. if LPS1 has opened, there
will be a 24-volt potential between the LPS1 terminals.
If 24 volts is present at the UCB Y1 terminal and none of
the protection switches have opened, the UCB may have
locked out the compressor for repeat trips. The UCB
should be flashing a code. If not, press and release the
ALARMS button on the UCB. The UCB will flash the last
five alarms on the LED. If the compressor is locked out,
Unitary Products Group
remove any call for cooling. This will reset any compressor
lock outs.
NOTE: While the above step will reset any lock outs,
compressor #2 will be held off for the ASCD, and
compressor #1 may be held off for a portion of the
ASCD. See the next step.
10. If 24 volts is present at the UCB Y1 terminal and none of
the switches are open and the compressor is not locked
out, the UCB may have the compressor in an ASCD.
Check the LED for an indication of an ASCD cycle. The
ASCD should time out within 5 minutes. Press and release
the TEST button to reset all ASCDs.
11. If 24 volts is present at the UCB Y1 terminal and the
compressor is not out due to a protective switch trip, repeat
trip lock out, or ASCD, the economizer terminals of the UCB
may be improperly wired. Check for 24 volts at the Y1 “OUT”
terminal of the UCB. If 24 volts is present, trace the wiring
from Y1 “OUT” for incorrect wiring. If 24 volts is not present
at the Y1 “OUT” terminal, the UCB must be replaced.
12. For units without economizers: If 24 volts is present at the
Y1 “OUT” terminal, check for 24 volts at the Y1 “ECON”
terminal. If 24 volts is not present, check for loose wiring
from the Y1 “OUT” terminal to the Mate-N-Lock plug, the
jumper in the Mate-N-Lock plug, and in the wiring from the
Mate-N-Lock plug to the Y1 “ECON” terminal.
For units with economizers: If 24 volts is present at the Y1
“OUT” terminal, check for 24 volts at the Y1 “ECON”
terminal. If 24 volts is not present, check for loose wiring
from the Y1 “OUT” terminal to the Mate-N-Lock plug, a
poor connection between the UCB and economizer MateN-Lock plugs, loose wiring from the Mate-N-Lock plug to
the economizer, back to the Mate-N-Lock plug, and from
the Mate-N-Lock plug to the Y1 “ECON” terminal. The
economizer control may have faulted and is not returning
the 24 volts to the Y1 “ECON” terminal even though the
economizer is not providing free cooling. To test the
economizer control, disconnect the Mate-N-Locks and
jumper between the WHITE and YELLOW wires of the
UCB’s Mate-N-Lock plug.
13. The UCB can be programmed to lock out compressor
operation during free cooling and in low ambient
conditions. These options are not enabled by default. They
can be checked by local York distributors.
14. If none of the above corrected the error, test the integrity of
the UCB. Disconnect the C1 terminal wire and jumper it to
the Y1 terminal. DO NOT jump the Y1 to C1 terminals. If
the compressor engages, the UCB has faulted.
15. If none of the above correct the error, replace the UCB.
Gas Heat Troubleshooting Guide
On calls for heating, the draft motor operates and the furnace
lights but the supply air blower motor does not energize after a
short delay (the room thermostat fan switch is in “AUTO”
position).
65
164015-YIM-A-0905
On calls for heating, the supply air blower operates but the draft
motor does not (the room thermostat fan switch is in the
“AUTO” position).
The furnace may shut down on a high temperature
condition during the procedure. If this occurs, the UCB
energize the supply air blower motor until the high
temperature limit has reset. Caution should be used at
all times as the supply air blower may energize
regardless of the room thermostat fan switch position.
1.
Place the thermostat fan switch in the “ON” position. If the
supply air blower motor energizes, go to Step 9.
2.
If the supply air blower motor does not energize when the
fan switch is set to “ON,” check that line voltage is being
supplied to the contacts of the M3 contactor, and that the
contactor is pulled in. Check for loose wiring between the
contactor and the supply air blower motor.
3.
If M3 is pulled in and voltage is supplied at M3, lightly touch
the supply air blower motor housing. If it is hot, the motor
may be off on inherent protection. Cancel any thermostat
calls and set the fan switch to “AUTO”, wait for the internal
overload to reset. Test again when cool.
4.
If M3 is not pulled in, check for 24 volts at the M3 coil. If 24
volts is present at M3 but M3 is not pulled in, replace the
contactor.
5.
Failing the above, if there is line voltage supplied at M3, M3
is pulled in, and the supply air blower motor still does not
operate, replace the motor.
6.
If 24 volts is not present at M3, check that 24 volts is
present at the supply air blower motor terminal on the UCB.
If 24 volts is present at the UCB terminal, check for loose
wiring between the UCB and M3.
a. If 24 volts is not present at the UCB supply air blower
motor terminal, check for 24 volts from the room
thermostat. If 24 volts is not present from the room
thermostat, check for the following:
• Proper operation of the room thermostat (contact
between R and G with the fan switch in the “ON” position
and in the “AUTO” position during operation calls.)
• Proper wiring between the room thermostat and the
UCB, and
• Loose wiring from the room thermostat to the UCB
7.
If 24 volts is present at the room thermostat but not at the
UCB, check for proper wiring between the thermostat and
the UCB, i.e. that the thermostat G terminal is connected to
the G terminal of the UCB, and for loose wiring.
8.
If the thermostat and UCB are properly wired, replace the
UCB.
9.
If the blower motor runs with the fan switch in the “ON”
position but does not run shortly after the furnace has
ignited when the fan switch is in the “AUTO” position,
check the room thermostat for contact between R and G
during “W1” calls.
66
1.
The draft motor has inherent protection. If the motor shell is
hot to the touch, wait for the internal overload to reset.
2.
If the motor shell is cold with the room thermostat calling
for heat, check for line voltage at the motor leads. If line
voltage is present, replace the draft motor.
3.
If line voltage is not present, check for line voltage on the
ignition control at the “inducer” terminal draft motor relay
(DMR or DMC) contacts in the main control box and check
to see if the (DMR or DMC) is pulled in.
The draft motor runs but the furnace does not light and the
spark ignitor does not spark.
1.
Check for 24 volts at the spark ignitor from the ignition
control board (ICB). Check the 24-volt wiring from the ICB
to the spark ignitor. Check for 24 volts at the ICB spark
ignitor terminal.
2.
Check the ground wiring for the ICB and the gas valve is
intact and making good electrical connection. Check the
ceramic insulator on the spark ignitor for breaks or cracks.
Replace the spark ignitor if damaged.
3.
With the draft motor running, check for 24 volts at the
pressure switch terminal on the ICB. If not present, check
for 24 volts on the terminal from the pressure switch. If
present, go to step 4. If 24 volts is not present, the either
pressure or rollout switch is not closed. Or the draft motor
is not sufficiently evacuating the heat exchanger tubes or
the pressure switch has failed. Check the operation of the
pressure switch. Check the line voltage to the unit; if line
voltage is low, call the local power company. If the problem
persists, the draft motor may need replacement.
4.
If the furnace is hot, it may be out on a high temperature
limit open; wait for limit reset.
5.
If all are intact replace the ICB.
The draft motor runs and the spark ignitor sparks at the burner,
but the burner does not ignite and a gas odor is not detected at
the draft motor outlet.
1.
Check to ensure gas is being supplied to the unit. Confirm
that the gas pressure to the unit is within the proper limits
as described in the “POST START CHECKLIST”.
2.
Check the voltage at the gas valve and at the gas valve
terminals on the ICB. Check all wiring between the ICB and
the gas valve. Check to make sure the ground connections
are intact.
3.
If 24 volts is present, remove the pilot burner and the
orifice. The removal procedure is described in “BURNER/
ORIFICE INSPECTION/SERVICING.” Inspect the orifice
for obstruction. If it is clear, replace the gas valve.
Main burners light but exhibit erratic flame characteristics.
1.
Check the main burner orifices for obstruction and
alignment. The removal procedure is described in
“BURNER/ORIFICE INSPECTION/SERVICING”. Clean or
replace burner orifices and burners as needed.
Unitary Products Group
164015-YIM-A-0905
Unitary Products Group
67
Subject to change without notice. Printed in U.S.A.
Copyright © 2005 by Unitary Products Group. All rights reserved.
Unitary
Products
Group
164015-YIM-A-0905
Supersedes: Nothing
5005
York
Drive
Norman
OK
73069
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