York Eco R 407c User Manual

FORM 100.50-EG1 (201)  
Packaged Rooftop  
Air Conditioning Units  
00406VIP  
R-407C OPTIMIZED  
50 THROUGH 65 TONS  
FORM 100.50-EG1  
PAGE  
FIGURES  
1
2
3
4
5
6
7
8
Packaged Rooftop Air Conditioning Unit .................................................. 4  
Single-Point Power Supply Wiring .......................................................... 31  
Single-Point Power Supply Wiring with Non-Fused Disconnect ............. 32  
Dual-Point Power Supply Wiring ............................................................ 33  
Field Control Wiring ............................................................................... 34  
General Arrangement Drawing – Bottom Return, Bottom Supply ........... 35  
General Arrangement Drawing – Rear Return, Left or Right Supply ...... 36  
Curb Layout Drawing.............................................................................. 37  
NOMENCLATURE  
BASIC MODEL NUMBER  
1 2 3 4  
BASE PRODUCT TYPE  
5 6 7  
NOMINAL CAPACITY  
8 9  
10  
11 12  
13 14  
DUCT LOCATIONS  
15 16  
DESIGN SPECIAL  
APPLICATION REFRIGERANT VOLTAGE  
Y
0
0
0
0
5
5
6
6
0: 50-ton  
5: 55-ton  
0: 60-ton  
5: 65-ton  
B : R-407C  
1
2
4
5
7
8
6
8
B
L
R
A
: 200 / 3 / 60  
: 230 / 3 / 60  
: 460 / 3 / 60  
: 575 / 3 / 60  
: Rev. Level A  
: Std. Product  
: Special  
: YORK  
: Packaged  
Rooftop  
: Air-Cooled  
: Bottom Supply  
: Left Supply  
: Right Supply  
: Bottom Return  
: Front Return  
: Side Return  
P
S
X
A
B
F
S
L
: Scroll  
: Cooling Only  
C
: Constant Volume  
: VAV, VFD  
: VAV, VFD w/ Manual Bypass  
C
V
B
YORK INTERNATIONAL  
3
Introduction  
00406VIP  
FIG. 1 PACKAGED ROOFTOP AIR CONDITIONING UNIT  
FEATURES/BENEFITS  
in two directions conforming to ASHRAE 62n, this  
drain pan swiftly minimizes any condensate within  
the unit. Best of all, the drain pan is accessible for  
periodic cleaning required by IAQ standards.  
Ecological and Economical Design  
• First packaged RTU with 407C optimized design  
Smart ventilation – YORK maintains the leader-  
ship role in IAQ products with adaptive ventilation  
control. The OptiLogicTM controls provide continu-  
ous monitoring of air quality and take action by open-  
ing the outside air dampers, bringing in the right  
amount of fresh air before air impurities reach un-  
comfortable or even dangerous levels.  
Cooling and Heating – Superior operating perfor-  
mance provides lower operating costs. Smaller  
steps of cooling capacity provide tighter control of  
building environment and occupant comfort while  
optimizing energy efficiency.  
Indoor Air Quality (IAQ) – Outside air economiz-  
ers provide energy savings in free cooling mode,  
and can provide a healthier and more comfortable  
building environment by introducing fresh outside air  
into the building as needed. Indoor Air Quality (IAQ)  
requirements for building ventilation and comfort are  
controlled through the microprocessor control panel.  
Optional air flow measurement provides an accu-  
rate means of tracking air quality and alerting the  
occupants or building owner to unhealthy situations.  
Air flow measurement – Precise measurement  
of ventilation air flow is possible using an air flow  
measurement station which can be installed in the  
economizer section. Proper ventilation air flow is  
required to ensure sufficient fresh air is in the build-  
ing. A myriad of air flow measurement options are  
available from minimum air flow to high-accuracy  
full air flow capabilities. The complete system is  
designed as an integrated component of the  
OptiLogicTM control system to ensure optimum sys-  
tem performance.  
High-Efficiency Motors – High-efficiency motors are  
available for optimum energy efficiency. All motors  
used on the eco2 packaged rooftop air conditioner  
meet U.S. EPACT 1992 minimum requirements.  
Double-wall construction – Rigid double-wall  
construction throughout provides ease of clean-  
ing and protects against insulation fiber entrain-  
ment in the breathable air. Double-wall construc-  
tion also helps improve the acoustical character-  
istics of the air handling unit.  
Indoor Air Quality (IAQ)  
Double-sloped stainless steel drain pan – This  
double-sloped inclined stainless steel drain pan fa-  
cilitates removal of evaporator condensate. Sloped  
YORK INTERNATIONAL  
4
FORM 100.50-EG1  
Enhanced filtration The Eco2 unit gives design-  
ers the flexibility to meet various IAQ requirements  
with a full range of rigid and throwaway filters at  
various efficiency levels.  
Serviceability  
OptiLogicTM fully-integrated factory-packaged  
controls are standard on every unit and include a  
display unit with a 4x20 character LCD display.  
OptiLogicTM continually monitors all control setpoints  
and configurations. If a unit or control component,  
or sensor fails, the controller notifies the user of a  
problem. If desired, YORK service can provide re-  
mote monitoring and automatically schedule a ser-  
vice technician to make the repair and maintain your  
comfort.  
Reliable Scroll Compressor Technology  
Reliable, efficient, trouble-free operation is the true mea-  
sure of a packaged rooftop’s value. That’s why YORK  
Eco2 Packaged Rooftop Air Conditioners use estab-  
lished scroll-compressor technology to deliver depend-  
able, economical performance in a wide range of appli-  
cations. With the Eco2 Packaged Rooftop, you get the  
latest generation of compressor enhancements added  
to the scroll’s inherent strengths. The simplicity of a  
hermetic scroll compressor allows the use of fewer  
moving parts to minimize breakdown. YORK also em-  
ploys the latest sealing technology to avoid metal-to-  
metal contact. Axial sealing is accomplished with float-  
ing tip seals, while radial sealing utilizes a microcushion  
of oil. The result: a maintenance-free compressor pro-  
viding minimum wear and maximum runtime.  
Access doors full-sized access doors provide  
easy access into the unit for routine maintenance  
and inspection.  
Suction & discharge service valves oversized  
service valves to provide isolation and quick recla-  
mation and charging of system refrigerant are avail-  
able to minimize downtime and simplify the service  
and repair task.  
VFD Fan Motor Control with Manual Bypass –  
Optional manual VFD bypass reduces time required  
for troubleshooting, commissioning and system  
balancing.  
A scroll compressor operates with two scroll members—  
a fixed scroll and an identical orbiting scroll turned 180  
degrees, like two hands curled and interlocked together.  
As the orbiting scroll oscillates against the fixed scroll,  
it traps and compresses suction gas inside involute  
pockets. As the orbiting scroll moves, the gas is com-  
pressed into the central area, where it is discharged as  
compressed gas. High efficiency is achieved through a  
precisely controlled orbit and the use of advanced scroll  
geometry. There is no wasted motion. All rotating parts  
are statically and dynamically balanced to ensure opti-  
mal performance over the long haul.  
Convenience Outlet for maintenance tasks re-  
quiring power tools, an optional 110V GFCI power  
supply can power lights, drills or any other power  
hand tool needed.  
Filter Maintenance Alarm An optional filter main-  
tenance alarm indicates when a filter becomes dirty  
and requires replacement or cleaning.  
Install with Ease and Safety  
Balanced components and precision machining also  
ensure that smooth compression occurs in all involute  
pockets simultaneously. When compression forces are  
equally distributed over the entire scroll surface, equal  
forces in opposing directions cancel one another, mini-  
mizing any imbalance. Consequently, compression is  
smooth, continuous, and quiet. Vibration isolators on  
each compressor handle normal vibration. For extra  
quiet operation, acoustic sound blankets for each com-  
pressor are available as options.  
Factory run-tested Each unit is subjected to a  
series of quality assurance checks as well as an  
automated quality control process before being run-  
tested. Fans and drives are balanced at the factory  
during testing. The factory run-test ensures safe,  
proper operation when the unit is installed and re-  
duces installation and commissioning time.  
Single-point power connection Single-point  
power connection reduces installation time by pro-  
viding a single point for incoming power, including  
YORK INTERNATIONAL  
5
Introduction  
the optional convenience outlet. All incoming power  
is connected in one location, reducing the cost of  
field-supplied and installed power wiring.  
on all systems offering higher rooftop cooling ca-  
pacity than competitive units.  
Hot Gas Bypass Optional on constant volume units,  
hot gas bypass reduces the cycling of compressors  
which helps prolong the life of the equipment.  
Factory-mounted and wired controls All con-  
trol points within the unit are factory-installed, wired  
and tested. The OptiLogicTM controls can commu-  
nicate with BACNet IP.  
Supply Air Openings Side supply connections  
are available on select configurations, offering more  
flexibility for duct layout and improving sound trans-  
mission characteristics.  
Non-fused disconnect A factory-installed non-  
fused disconnect switch simplifies unit installation  
and serviceability by reducing installed labor costs.  
The disconnect switch is interlocked with the power  
cabinet ensuring that all power to the unit has been  
disconnected before servicing.  
Compressor Sound Blankets For applications  
in sound-sensitive areas, compressor sound blan-  
kets are available to reduce sound emitted from  
the rooftop unit.  
Fan Spring Isolators One-inch spring isolation  
is used to prevent vibration transmission from the  
rooftop unit’s supply fan to the building. Two-inch  
spring isolation is also available.  
Design Flexibility  
Low Ambient Operation Head-pressure control  
is accomplished via a VFD motor controller rather  
than an inefficient and noisy condenser fan damper.  
By varying the speed of the condenser fan, better  
control and quieter operation is obtained during the  
colder months. Low ambient controls are available  
Harsh Environments A variety of coil coating and  
materials are available as well as hail guards to pro-  
tect coils from weather damage. Seismic and hurri-  
cane duty curbs and fan restraints are available.  
YORK INTERNATIONAL  
6
FORM 100.50-EG1  
Physical Data  
TABLE 1 PHYSICAL DATA  
MODEL SIZE  
50  
55  
60  
65  
GENERAL DATA  
Length (Inches)  
Width (Inches)  
336  
92  
336  
92  
336  
92  
336  
92  
Height (Inches)  
82  
82  
82  
82  
Operating Weights (Lbs.) (base unit, no options)  
Cooling Only (Rigging & Refrigerant)  
Rigging Weights (Lbs.) (base unit, no options)  
Cooling Only  
8,080  
8,010  
8,290  
8,210  
8,530  
8,440  
8,740  
8,640  
Option Weights (Lbs.)  
Power Exhaust (Blower, motor, fan skid & mod damper)  
Power Exhaust (Blower, motor, fan skid, VFD & baro damper)  
100% AMS (Measurement Station & Mounting)  
25/75% AMS (Measurement Station & Mounting)  
Min. AMS (Measurement Station & Mounting)  
Barometric only  
647  
654  
110  
130  
40  
647  
654  
110  
130  
40  
647  
654  
110  
130  
40  
647  
654  
110  
130  
40  
36  
36  
36  
36  
Condenser Hail Guard  
32  
32  
32  
32  
Copper Condenser Coils  
Copper Evaporator Coils  
Roof Curb Weights (Lbs.)  
14" Full Perimeter Roof Curb  
14" Open Condenser Roof Curb  
Compressor Data  
617  
262  
617  
320  
793  
400  
793  
500  
787  
555  
787  
555  
787  
555  
787  
555  
Quantity / Size (Nominal Tons )  
Type  
4/13  
Scroll  
4/13  
Scroll  
4/15  
Scroll  
4/15  
Scroll  
Capacity Steps (%)  
25, 50, 75, 100 25, 50, 75, 100 25, 50, 75, 100 25, 50, 75, 100  
Supply Fan and Drive  
Quantity  
Type  
1
FC  
1
FC  
1
FC  
1
FC  
Size  
25-22  
25-22  
25-22  
25-22  
Motor Size Range (min. to max. HP)  
Air Flow Range (min. to max. cfm)  
Static Pressure Range (min. to max. ESP)  
Exhaust Fan  
7.5-40  
10000-22500  
0-4"  
7.5-40  
12000-24000  
0-4"  
7.5-40  
14000-27000  
0-4"  
7.5-40  
14000-27000  
0-4"  
Quantity  
Type  
2
FC  
2
FC  
2
FC  
2
FC  
Size  
15-15  
5-20  
0-20000  
0-1"  
15-15  
5-20  
0-20000  
0-1"  
15-15  
5-20  
0-20000  
0-1"  
15-15  
5-20  
0-20000  
0-1"  
Motor Size Range (min. to max. HP)  
Air Flow Range (min. to max. cfm)  
Static Pressure Range (min. to max. ESP)  
Evaporator Coil  
Size (square feet)  
48.8  
3/8  
48.8  
4/8  
48.8  
4/12  
48.8  
5/10  
Number of rows/fins per inch  
Tube Diameter/Surface  
Condenser Coil (Aluminum Fins)  
Size (square feet)  
1/2"/enhanced 1/2"/enhanced 1/2"/enhanced 1/2"/enhanced  
121.3  
3/14  
3/8"  
121.3  
3/14  
3/8"  
121.3  
3/18  
3/8"  
121.3  
3/18  
3/8"  
Number of rows/fins per inch  
Tube Diameter  
Condenser Coil (Copper Fins Opt)  
Size (square feet)  
121.3  
3/14  
3/8"  
121.3  
3/14  
3/8"  
121.3  
3/18  
3/8"  
121.3  
3/18  
3/8"  
Number of rows/fins per inch  
Tube Diameter  
YORK INTERNATIONAL  
7
Physical Data (continued)  
TABLE 1 PHYSICAL DATA (Cont’d)  
MODEL SIZE  
50  
55  
60  
65  
GENERAL DATA  
Condenser Fans  
Quantity  
4
4
4
4
Type  
Diameter (inches)  
Prop.  
36  
Prop.  
36  
Prop.  
36  
Prop.  
36  
Filters 2" throwaway  
Quantity  
Size (length x width) (in.)  
Total Filter Face Area (square feet)  
Filters 2" cleanable  
Quantity  
Size (length x width) (in.)  
Total Filter Face Area (square feet)  
Filters 2" pleated (30% efficient)  
Quantity  
8
12  
25x16 25x20 25x16 25x20 25x16 25x20 25x16 25x20  
63.9 63.9 63.9 63.9  
8
12  
8
12  
8
12  
8
12  
25x16 25x20 25x16 25x20 25x16 25x20 25x16 25x20  
63.9 63.9 63.9 63.9  
8
12  
8
12  
8
12  
8
12  
8
12  
8
12  
8
12  
Size (length x width) (in.)  
Total Filter Face Area (square feet)  
Filters 12" rigid 65%, 2" 30% prefilter  
Quantity  
25x16 25x20 25x16 25x20 25x16 25x20 25x16 25x20  
63.9  
4
63.9  
4
63.9  
4
63.9  
4
1
9
1
9
1
9
1
9
Size (length x width) (in.)  
Total Filter Face Area (square feet)  
Filters 12" rigid 95%, 2" 30% prefilter  
Quantity  
16x20 25x16 25x20 16x20 25x16 25x20 16x20 25x16 25x20 16x20 25x16 25x20  
44.6  
4
44.6  
4
44.6  
4
44.6  
4
1
9
1
9
1
9
1
9
Size (length x width) (in.)  
Total Filter Face Area (square feet)  
Filters 2" carbon (30% efficient)  
Quantity  
16x20 25x16 25x20 16x20 25x16 25x20 16x20 25x16 25x20 16x20 25x16 25x200  
44.6  
44.6  
12  
44.6  
44.6  
8
12  
8
8
12  
8
12  
Size (length x width) (in.)  
Total Filter Face Area (square feet)  
Refrigerant  
25x16 25x20 25x16 25x20 25x16 25x20 25x16 25x20  
63.9  
63.9  
63.9  
63.9  
HFC-407C  
HFC-407C  
HFC-407C  
HFC-407C  
Minimum OA Temp. for Mech. Clg. (°F)  
Low Ambient Option Min. OA Temp. (°F)  
45  
0
45  
0
45  
0
45  
0
YORK INTERNATIONAL  
8
FORM 100.50-EG1  
Application Data  
LOCATION  
Spreader bars must be used to prevent damage to the  
unit casing. All lifting lugs must be used when lifting the  
rooftop unit.  
Of the many factors that can affect the acoustical char-  
acteristics of a rooftop installation, one of the most im-  
portant is the unit location. Ideally, the rooftop unit should  
be installed away from sound-sensitive areas, such as  
conference rooms, auditoriums and executive offices.  
Possible locations could be above storage areas, hall-  
ways, mechanical or utility rooms, or bathrooms.  
Care must be taken to keep the unit in the upright posi-  
tion during rigging and to prevent damage to the water-  
tight seams in the unit casing. Avoid unnecessary jar-  
ring or rough handling.  
Ground Level Locations  
The eco2 air conditioning units are designed for out-  
door installation. When selecting a site for installation,  
be guided by the following conditions:  
It is important that the units be installed on a substan-  
tial base that will not settle, causing strain on the refrig-  
erant lines and sheet metal and resulting in possible  
leaks. A one-piece concrete slab with footers extended  
below the frost line is highly recommended. Addition-  
ally, the slab should not be tied to the main building  
foundation as noises may be transmitted into the build-  
ing structure.  
• Unit must be installed on a level surface.  
• For the outdoor location of the unit, select a place  
having a minimum sun exposure and an adequate  
supply of fresh air for the condenser.  
For ground level installations, precautions should be  
taken to protect the unit from tampering by, or injury to,  
unauthorized persons. Erecting a fence around the unit  
is another common practice.  
• Also avoid locations beneath windows or between  
structures.  
• Optional condenser coil protection should be used  
for seashore locations or other harsh environments.  
• The unit should be installed on a roof that is struc-  
turally strong enough to support the weight of the  
unit with a minimum of deflection. Extreme caution  
should be taken when the unit is mounted on a wood  
structured roof. It is recommended that the unit(s)  
be installed not more than 15 feet from a main sup-  
port beam to provide proper structural support and  
to minimize the transmission of sound and vibra-  
tion. Ideally, the center of gravity should be located  
over a structural support or building column.  
ECONOMIZER  
The economizer section is used for ventilation of the  
conditioned space to maintain indoor air quality, and  
also to reduce energy consumption by using outdoor  
air cooling in lieu of mechanical cooling. If outdoor air  
is appropriate for cooling, but not sufficient for the cool-  
ing demand, mechanical cooling will stage on as nec-  
essary until the cooling load is met.  
Comparative enthalpy operation is the most accurate and  
efficient means of economizer operation. The OptiLogicTM  
control monitors the return and outside air energy con-  
tent, and selects the lower of the two for operation.  
• Location of unit(s) should also be away from build-  
ing flue stacks or exhaust ventilators to prevent pos-  
sible reintroduction of contaminated air through the  
outside air intakes.  
• Be sure the supporting structures will not obstruct  
the duct, gas or wiring connections.  
VAV SUPPLY AIR PRESSURE CONTROL  
• Proper service clearance space of 6-feet around  
the perimeter of the unit and 12-feet to any adja-  
cent units is required to eliminate cross contami-  
nation of exhaust and outdoor air, and for mainte-  
nance tasks such as coil pull and cleaning. No ob-  
structions should be above the condensing unit  
section.  
Traditional packaged rooftop systems use inlet guide  
vanes (IGVs) for duct static pressure control. These con-  
trol supply duct pressure by modulating dampers (intro-  
ducing losses and inefficiencies) on the intlet of the fan,  
open and closed. Variable frequency drives (VFDs) of-  
fer superior fan speed control and quieter, energy effi-  
cient operation.  
RIGGING  
IGV inefficiency can be compared to the operation of a  
car. Modulating air flow with an IGV is like pressing on  
the gas to drive the car, but modulating the speed of the  
car by simultaneously pressing on the brake. VFD modu-  
lation is speed modulation by using just the gas pedal.  
Proper rigging and handling of the equipment is man-  
datory during unloading and setting it into position to  
retain warranty status.  
YORK INTERNATIONAL  
9
Application Data (continued)  
For VAV applications, the YORK eco2 unit uses a VFD  
to modulate fan speed and maintain a constant duct  
static pressure. VFDs offer superior control over the  
operation of the unit at part load, and offer the addi-  
tional benefits of quieter and more efficient operation  
when compared to IGV.  
BUILDING EXHAUST SYSTEMS  
Building exhaust systems are often necessary when  
economizers are used to bring in outdoor air. Without  
proper building exhaust, the building may become over-  
pressurized. The exhaust system maintains the proper  
building pressure by expelling the appropriate amount  
of air from the building. Exhaust systems are typically  
designed to exhaust approximately 10% less air than  
what is entering the building. This provides a slight posi-  
tive pressure on the building.  
HARSH ENVIRONMENTS CONDENSER AND  
EVAPORATOR COIL PROTECTION  
For harsh environmental conditions such as seashore  
applications, YORK offers three types of coil protec-  
tion: copper fin material, black fin and Technicoat coat-  
ings. YORK recommends that for corrosive environ-  
ments that copper fins be used to protect the evapora-  
tor and/or condenser coils. In areas where chemicals  
that can corrode copper are present, such as ammo-  
nia, YORK recommends that the black fin or Technicoat  
coating be used for maximum protection.  
100% modulating exhaust with building static  
pressure sensing and control  
The 100% exhaust system can be configured with ei-  
ther control actuated dampers or VFDs for modulating  
control. The unit controller monitors the building pres-  
sure using a differential pressure transducer and main-  
tains the required building static pressure by modulat-  
ing the exhaust control. If the building has other means  
of exhaust or building pressure is not important, on/off  
or barometric control may be used.  
Copper Fin Condenser Coil  
Copper fins can be used instead of aluminum for addi-  
tional corrosion protection, however it is not suitable  
for areas that are subject to acid rain or exposed to  
ammonia.  
100% modulating exhaust with fan on/off control  
The 100% exhaust system can be configured for on/off  
operation eliminating the expense of the damper ac-  
tuators or VFDs. This exhaust system can be controlled  
by either the outside air damper position, or a building  
static pressure sensor.  
Pre-Coated Condenser Fins  
Black fin coating (yellow fin for evaporator fins) is pre-  
coated application epoxy on aluminum fin stock to guard  
from corrosive agents and insulate against galvanic po-  
tential. It is used for mild seashore or industrial loca-  
tions. This can provide corrosion resistance comparable  
to copper fin coils in typical seashore locations.  
Barometric exhaust  
Barometric exhaust can be used when smaller amounts  
of air at low static pressure variations within the build-  
ing or other means of building exhaust are employed.  
Barometric exhaust is commonly used where there are  
only small fluctuations in building pressure or where  
building static pressure control is not necessary.  
Post-Coated Condenser Fins  
Technicoat (a post-coated application of epoxy) can be  
used for seashore and other corrosive applications with  
the exception of strong alkalides, oxidizers, wet bro-  
mide, chlorine and fluorine in concentrations greater  
than 100 ppm.  
ROOF CURB  
Optional 14-inch full-perimeter or open condenser roof  
curbs can be provided if necessary for mounting to  
the building roof. These curbs come disassembled and  
require installation in the field. For bottom supply and  
return duct openings, the curbs have matching con-  
nections to ease installation. A pipe chase that  
matches the rooftop unit is also included in the curb  
footprint for through-the-curb utility connections.  
Any of the above suitable options should be selected  
based on the particular project design parameters and  
related environmental factors. The application should  
be further reviewed and approved by the consulting en-  
gineer or owner based on their knowledge of the job  
site conditions.  
YORK INTERNATIONAL  
10  
FORM 100.50-EG1  
The curb should be located according to the location  
recommendations above, and properly sealed to pre-  
vent moisture and air leakage into and out of the duct  
system. Flexible collars should be used when connect-  
ing the duct work to prevent unit noise transmission  
and vibration into the building.  
and the unit requires a modulating economizer, 2-inch  
pleated filters, bottom supply and bottom return air open-  
ings and is constant volume.  
Select Unit:  
1. Determine the internal static pressure drop of the  
cabinet by referencing Table 8.  
Duct work should be supported independently of the  
unit.  
Wet evaporator coil  
0.54  
0.14  
0.13  
0.10  
0.24  
0.31  
Bottom supply opening  
Bottom return opening  
2-inch pleated filters  
Economizer openings  
Modulating economizer dampers  
ACOUSTICAL CONSIDERATIONS  
The eco2 unit is designed for lower sound levels than  
competitive units by using flexible fan connections, fan  
spring isolators, double-wall construction, and lower  
speed and horsepower fans. For VAV applications,  
VFDs are used instead of inlet guide vanes. Additional  
sound attenuation can be obtained using compressor  
sound blankets and field-supplied sound attenuators  
when necessary.  
Total 1.46 IWG  
2. Determine the total static pressure by adding the  
internal to the external static pressure.  
TSP = 1.46 IWG + 2.25 IWG  
= 3.71 IWG total static pressure  
Even with these equipment design features, the acous-  
tical characteristics of the entire installation must never  
be overlooked. Additional steps for the acoustical char-  
acteristics of a rooftop installation should be addressed  
during the design phase of a project to avoid costly al-  
terations after the installation of the equipment. During  
the design phase of a project, the designing engineer  
should consider, at a minimum, the impact of the equip-  
ment location, rooftop installation, building structure,  
and duct work.  
3. Determine the BHP of the supply fan from Table 6  
using the supply air flow and total static pressure.  
From the table, we interpolate to get 15.1 BHP. As-  
suming a drive loss of 3% and a motor efficiency of  
90%, we can calculate the heat rejection of the sup-  
ply fan motor as:  
(2545 x 15.1)/(0.90 x (1-0.03)) = 44.0 mbh  
Required Cooling Capacities:  
Total = 600 + 44.0 = 644 mbh  
Sensible = 450 + 44.0 = 494 mbh  
4. Required total and sensible capacities are 644 mbh  
and 494 mbh, respectively. Using the Cooling Per-  
formance Data starting with Tables 2, locate the  
table with the correct ambient air temperature. Next,  
trace the 83°F entering air dry bulb temperature to  
match the 17,500 cfm and 67°F entering wet bulb  
temperature condition. The resulting conditions are,  
from the table, 645 mbh total cooling capacity and  
497 mbh sensible cooling capacity. Thus, a 50-ton  
unit is selected.  
SELECTION PROCEDURE  
Given:  
Required total cooling capacity of 600 mbh and sen-  
sible cooling capacity of 450 mbh with evaporator en-  
tering air conditions of 83°F dry bulb and 67°F wet bulb.  
Design ambient temperature is 95°F dry bulb. Supply  
air requirements are 17500 cfm of air at 2.25 IWG ex-  
ternal static pressure. Power supply is 460V/3ph/60Hz  
YORK INTERNATIONAL  
11  
Cooling Performance Data 50 Ton Model  
TABLE 2 COOLING PERFORMANCE DATA 50 TON MODEL  
85° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
ENTERING  
90  
86  
83  
80  
77  
74  
CFM  
WB (°F)  
72  
CAP  
700  
653  
640  
711  
665  
654  
729  
684  
680  
749  
705  
710  
758  
715  
715  
SHC  
477  
548  
640  
500  
581  
654  
536  
634  
680  
576  
695  
710  
595  
715  
715  
CAP  
700  
646  
608  
708  
656  
625  
721  
672  
652  
736  
689  
682  
742  
697  
696  
SHC  
431  
500  
608  
445  
523  
625  
467  
558  
652  
492  
597  
682  
504  
616  
610  
CAP  
695  
635  
590  
705  
647  
606  
719  
666  
632  
736  
686  
661  
743  
696  
674  
SHC  
387  
454  
583  
399  
474  
606  
418  
505  
625  
439  
540  
661  
449  
557  
549  
CAP  
692  
637  
582  
701  
647  
594  
715  
663  
612  
732  
680  
633  
739  
689  
643  
SHC  
353  
416  
562  
360  
431  
547  
370  
454  
550  
382  
479  
582  
388  
492  
486  
CAP  
691  
632  
569  
699  
643  
583  
712  
660  
606  
726  
679  
631  
732  
688  
643  
SHC  
311  
377  
514  
316  
388  
498  
324  
406  
497  
333  
425  
523  
338  
435  
429  
CAP  
SHC  
10000  
67  
626  
574  
343  
455  
62  
72  
14000  
17500  
20000  
22500  
67  
637  
585  
349  
439  
62  
72  
67  
653  
603  
359  
438  
62  
72  
67  
672  
622  
370  
467  
62  
72  
67  
680  
631  
376  
370  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
95° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
83 80  
ENTERING  
90  
86  
77  
74  
CFM  
WB (°F)  
72  
CAP  
673  
628  
618  
684  
642  
635  
701  
665  
661  
720  
691  
691  
729  
703  
704  
SHC  
468  
536  
618  
491  
569  
635  
526  
625  
661  
565  
691  
691  
584  
703  
704  
CAP  
673  
630  
590  
682  
638  
607  
696  
651  
634  
712  
665  
663  
720  
672  
675  
SHC  
416  
494  
590  
432  
515  
607  
458  
547  
634  
486  
582  
663  
500  
599  
658  
CAP  
669  
615  
569  
678  
627  
586  
693  
645  
612  
709  
665  
641  
717  
674  
655  
SHC  
375  
445  
513  
388  
465  
541  
407  
497  
587  
429  
532  
641  
439  
549  
629  
CAP  
667  
616  
571  
676  
625  
580  
690  
640  
594  
705  
656  
609  
712  
664  
617  
SHC  
340  
404  
481  
348  
419  
500  
360  
443  
531  
373  
470  
565  
380  
483  
556  
CAP  
664  
609  
562  
673  
619  
572  
686  
635  
588  
701  
653  
606  
708  
661  
614  
SHC  
301  
383  
435  
306  
382  
453  
315  
382  
481  
325  
382  
511  
329  
382  
488  
CAP  
SHC  
10000  
67  
605  
562  
331  
390  
62  
72  
14000  
17500  
20000  
22500  
67  
615  
571  
338  
407  
62  
72  
67  
630  
586  
348  
433  
62  
72  
67  
647  
602  
360  
462  
62  
72  
67  
655  
610  
366  
447  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
YORK INTERNATIONAL  
12  
FORM 100.50-EG1  
TABLE 2 COOLING PERFORMANCE DATA 50 TON MODEL (CONTD)  
105° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
83 80 77  
ENTERING  
90  
86  
74  
CFM  
WB (°F)  
72  
CAP  
649  
590  
597  
658  
609  
614  
673  
638  
641  
689  
670  
670  
696  
686  
684  
SHC  
464  
513  
597  
483  
550  
614  
512  
607  
641  
545  
670  
670  
560  
695  
684  
CAP  
650  
596  
573  
658  
608  
589  
670  
625  
614  
684  
645  
642  
690  
654  
655  
SHC  
409  
478  
573  
424  
501  
589  
447  
537  
614  
472  
577  
642  
485  
596  
655  
CAP  
645  
589  
536  
653  
600  
556  
667  
618  
587  
682  
638  
621  
690  
647  
637  
SHC  
365  
434  
498  
378  
454  
527  
397  
485  
571  
419  
520  
621  
430  
537  
644  
CAP  
644  
591  
549  
651  
600  
557  
663  
615  
570  
677  
631  
584  
683  
639  
591  
SHC  
330  
390  
460  
338  
406  
483  
350  
432  
520  
364  
461  
561  
371  
475  
580  
CAP  
644  
593  
544  
650  
601  
553  
661  
613  
567  
672  
626  
582  
678  
632  
590  
SHC  
290  
354  
429  
295  
366  
446  
303  
384  
472  
311  
404  
500  
315  
414  
514  
CAP  
SHC  
10000  
67  
589  
542  
318  
384  
62  
72  
14000  
17500  
20000  
22500  
67  
597  
550  
326  
397  
62  
72  
67  
609  
563  
337  
419  
62  
72  
67  
623  
576  
350  
443  
62  
72  
67  
629  
583  
356  
455  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
115° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
83 80 77  
ENTERING  
90  
86  
74  
CFM  
WB (°F)  
72  
CAP  
563  
494  
498  
592  
548  
550  
608  
577  
578  
625  
609  
609  
633  
624  
624  
SHC  
368  
424  
498  
432  
509  
550  
465  
555  
578  
503  
609  
609  
520  
624  
624  
CAP  
562  
524  
501  
588  
545  
533  
603  
557  
550  
618  
570  
568  
626  
576  
577  
SHC  
318  
387  
501  
370  
449  
533  
397  
481  
550  
427  
517  
568  
441  
534  
577  
CAP  
567  
514  
442  
589  
541  
498  
600  
555  
527  
613  
571  
560  
619  
579  
575  
SHC  
286  
349  
424  
325  
406  
488  
346  
435  
522  
368  
468  
560  
379  
484  
578  
CAP  
558  
515  
458  
585  
539  
494  
600  
552  
513  
616  
566  
534  
623  
572  
544  
SHC  
258  
313  
349  
286  
359  
434  
300  
383  
478  
316  
410  
528  
324  
423  
548  
CAP  
563  
514  
467  
583  
536  
491  
594  
548  
504  
606  
562  
518  
611  
568  
525  
SHC  
233  
281  
343  
246  
317  
395  
253  
336  
422  
261  
357  
452  
265  
367  
467  
CAP  
SHC  
10000  
67  
518  
467  
254  
306  
62  
72  
14000  
17500  
20000  
22500  
67  
537  
489  
276  
349  
62  
72  
67  
547  
500  
288  
371  
62  
72  
67  
558  
513  
301  
396  
62  
72  
67  
563  
520  
307  
408  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
YORK INTERNATIONAL  
13  
Cooling Performance Data 55 Ton Model  
TABLE 3 COOLING PERFORMANCE DATA 55 TON MODEL  
85° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
ENTERING  
90  
86  
83  
80  
77  
74  
CFM  
WB (°F)  
72  
CAP  
732  
677  
660  
743  
693  
680  
767  
728  
725  
781  
750  
750  
786  
758  
760  
SHC  
488  
564  
648  
512  
598  
661  
564  
677  
701  
592  
713  
713  
604  
720  
720  
CAP  
704  
651  
616  
712  
661  
634  
731  
684  
673  
741  
695  
694  
746  
701  
701  
SHC  
437  
511  
616  
452  
535  
634  
485  
586  
673  
502  
613  
613  
510  
625  
602  
CAP  
700  
641  
598  
709  
653  
615  
731  
680  
652  
742  
694  
672  
747  
701  
681  
SHC  
393  
463  
598  
405  
484  
587  
433  
530  
652  
448  
554  
554  
454  
565  
534  
CAP  
696  
642  
588  
706  
652  
600  
727  
675  
627  
738  
688  
642  
743  
693  
648  
SHC  
356  
423  
564  
363  
438  
531  
378  
472  
572  
387  
490  
490  
390  
497  
473  
CAP  
695  
637  
576  
703  
649  
591  
722  
673  
624  
731  
687  
641  
736  
692  
649  
SHC  
313  
382  
515  
319  
394  
481  
331  
419  
515  
337  
433  
433  
340  
439  
416  
CAP  
SHC  
12000  
67  
631  
579  
346  
456  
62  
72  
16000  
19250  
22000  
24000  
67  
642  
591  
353  
421  
62  
72  
67  
666  
616  
367  
458  
62  
72  
67  
679  
630  
375  
375  
62  
72  
67  
685  
636  
378  
357  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
95° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
83 80  
ENTERING  
90  
86  
77  
74  
CFM  
WB (°F)  
72  
CAP  
706  
651  
641  
716  
668  
661  
738  
707  
705  
751  
728  
730  
756  
737  
740  
SHC  
479  
554  
626  
502  
585  
644  
554  
671  
682  
581  
701  
703  
593  
709  
709  
CAP  
678  
634  
598  
687  
643  
616  
708  
661  
654  
719  
671  
675  
723  
675  
675  
SHC  
424  
504  
598  
441  
525  
616  
478  
572  
654  
497  
597  
675  
506  
607  
607  
CAP  
673  
621  
577  
683  
633  
594  
704  
659  
633  
715  
673  
653  
720  
678  
662  
SHC  
381  
454  
527  
394  
476  
554  
422  
521  
625  
438  
546  
653  
444  
556  
556  
CAP  
671  
621  
575  
680  
630  
585  
700  
651  
605  
711  
663  
616  
715  
667  
620  
SHC  
344  
411  
490  
352  
427  
511  
369  
462  
555  
379  
481  
578  
383  
489  
489  
CAP  
668  
613  
567  
677  
624  
577  
696  
647  
600  
707  
660  
613  
711  
665  
618  
SHC  
303  
382  
444  
309  
382  
462  
322  
382  
502  
328  
382  
524  
331  
382  
382  
CAP  
SHC  
12000  
67  
610  
566  
334  
398  
62  
72  
16000  
19250  
22000  
24000  
67  
620  
576  
341  
415  
62  
72  
67  
642  
598  
357  
453  
62  
72  
67  
654  
609  
365  
473  
62  
72  
67  
659  
614  
369  
369  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
YORK INTERNATIONAL  
14  
FORM 100.50-EG1  
TABLE 3 COOLING PERFORMANCE DATA 55 TON MODEL (CONTD)  
105° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
ENTERING  
90  
86  
83  
80  
77  
74  
CFM  
WB (°F)  
72  
CAP  
642  
593  
592  
661  
619  
618  
701  
679  
679  
723  
711  
711  
733  
724  
725  
SHC  
473  
531  
605  
493  
569  
623  
535  
651  
661  
558  
696  
682  
567  
693  
691  
CAP  
654  
602  
581  
662  
613  
598  
679  
639  
634  
689  
653  
653  
693  
659  
661  
SHC  
416  
489  
581  
432  
513  
598  
465  
565  
634  
483  
593  
653  
490  
605  
661  
CAP  
649  
594  
546  
658  
606  
566  
678  
632  
611  
689  
645  
635  
693  
651  
645  
SHC  
371  
443  
512  
384  
464  
542  
413  
510  
606  
428  
534  
641  
435  
545  
656  
CAP  
647  
595  
553  
655  
605  
561  
673  
626  
580  
682  
637  
590  
686  
642  
594  
SHC  
334  
397  
471  
342  
415  
496  
360  
452  
549  
370  
473  
577  
374  
481  
590  
CAP  
647  
597  
549  
654  
605  
558  
669  
622  
578  
677  
631  
588  
681  
635  
593  
SHC  
292  
359  
437  
297  
372  
454  
308  
398  
492  
314  
412  
512  
317  
418  
521  
CAP  
SHC  
12000  
67  
593  
546  
322  
390  
62  
72  
16000  
19250  
22000  
24000  
67  
601  
554  
330  
405  
62  
72  
67  
619  
572  
346  
436  
62  
72  
67  
628  
582  
355  
453  
62  
72  
67  
632  
586  
359  
460  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
115° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
83 80 77  
ENTERING  
90  
86  
74  
CFM  
WB (°F)  
72  
CAP  
657  
606  
598  
665  
623  
617  
682  
660  
659  
692  
680  
682  
696  
689  
692  
SHC  
460  
535  
581  
482  
562  
600  
529  
632  
639  
554  
660  
660  
565  
668  
669  
CAP  
624  
579  
557  
633  
588  
572  
653  
606  
602  
663  
617  
616  
668  
621  
622  
SHC  
400  
477  
567  
417  
498  
578  
455  
544  
602  
476  
568  
614  
484  
578  
620  
CAP  
618  
571  
528  
627  
582  
547  
647  
605  
589  
658  
617  
611  
663  
622  
621  
SHC  
357  
435  
517  
371  
454  
539  
399  
496  
587  
414  
518  
613  
421  
527  
624  
CAP  
613  
566  
519  
623  
577  
534  
645  
599  
565  
657  
611  
582  
662  
617  
589  
SHC  
321  
390  
458  
330  
406  
487  
350  
440  
551  
360  
458  
585  
365  
466  
589  
CAP  
610  
563  
517  
619  
573  
528  
640  
595  
552  
651  
607  
565  
656  
613  
570  
SHC  
284  
350  
425  
288  
362  
443  
297  
388  
481  
302  
402  
501  
304  
408  
510  
CAP  
SHC  
12000  
67  
559  
512  
312  
381  
62  
72  
16000  
19250  
22000  
24000  
67  
570  
523  
319  
395  
62  
72  
67  
592  
547  
335  
426  
62  
72  
67  
603  
559  
343  
443  
62  
72  
67  
608  
565  
347  
450  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
YORK INTERNATIONAL  
15  
Cooling Performance Data 60 Ton Model  
TABLE 4 COOLING PERFORMANCE DATA 60 TON MODEL  
85° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
ENTERING  
90  
86  
83  
80  
77  
74  
CFM  
WB (°F)  
72  
CAP  
804  
736  
689  
846  
795  
771  
867  
824  
813  
888  
854  
854  
897  
867  
873  
SHC  
495  
586  
689  
609  
720  
771  
666  
787  
813  
722  
854  
854  
748  
867  
873  
CAP  
804  
728  
663  
840  
773  
740  
858  
795  
779  
876  
818  
817  
884  
828  
835  
SHC  
461  
522  
663  
538  
632  
740  
576  
687  
779  
614  
742  
817  
632  
767  
835  
CAP  
801  
729  
658  
837  
771  
725  
855  
792  
759  
872  
814  
792  
880  
823  
808  
SHC  
277  
339  
442  
410  
504  
617  
477  
587  
705  
544  
670  
792  
574  
708  
817  
CAP  
798  
727  
656  
833  
769  
704  
851  
790  
728  
868  
810  
752  
876  
820  
763  
SHC  
383  
440  
543  
426  
519  
630  
448  
558  
673  
470  
598  
716  
480  
616  
736  
CAP  
792  
725  
647  
827  
767  
700  
845  
787  
726  
862  
808  
752  
870  
818  
764  
SHC  
344  
408  
493  
372  
468  
572  
386  
498  
611  
401  
528  
651  
407  
541  
669  
CAP  
SHC  
14000  
67  
723  
654  
377  
424  
62  
72  
18000  
21000  
24000  
27000  
67  
761  
699  
415  
502  
62  
72  
67  
780  
722  
434  
541  
62  
72  
67  
799  
744  
453  
580  
62  
72  
67  
808  
755  
461  
598  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
95° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
83 80  
ENTERING  
90  
86  
77  
74  
CFM  
WB (°F)  
72  
CAP  
773  
723  
671  
814  
775  
750  
834  
802  
789  
854  
828  
828  
864  
840  
846  
SHC  
491  
527  
671  
599  
678  
750  
652  
753  
789  
706  
828  
828  
730  
863  
846  
CAP  
771  
692  
645  
808  
752  
719  
827  
783  
756  
846  
813  
793  
854  
827  
810  
SHC  
442  
464  
645  
524  
570  
719  
565  
623  
756  
607  
675  
793  
626  
699  
810  
CAP  
769  
703  
631  
804  
745  
699  
822  
766  
732  
840  
788  
766  
848  
797  
782  
SHC  
336  
397  
474  
434  
529  
620  
482  
594  
693  
531  
660  
766  
553  
691  
788  
CAP  
769  
703  
642  
802  
742  
684  
819  
761  
706  
835  
780  
727  
843  
789  
737  
SHC  
368  
432  
505  
414  
508  
604  
438  
546  
653  
461  
584  
703  
471  
601  
726  
CAP  
763  
699  
655  
797  
736  
682  
814  
755  
696  
831  
774  
709  
838  
782  
716  
SHC  
331  
437  
416  
361  
455  
550  
376  
463  
616  
391  
472  
683  
397  
476  
714  
CAP  
SHC  
14000  
67  
696  
673  
363  
318  
62  
72  
18000  
21000  
24000  
27000  
67  
732  
681  
402  
494  
62  
72  
67  
751  
685  
421  
582  
62  
72  
67  
769  
689  
441  
670  
62  
72  
67  
778  
690  
450  
710  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
YORK INTERNATIONAL  
16  
FORM 100.50-EG1  
TABLE 4 COOLING PERFORMANCE DATA 60 TON MODEL (CONTD)  
105° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
83 80 77  
ENTERING  
90  
86  
74  
CFM  
WB (°F)  
72  
CAP  
753  
690  
652  
782  
745  
726  
797  
773  
763  
811  
801  
800  
818  
814  
817  
SHC  
500  
469  
652  
588  
635  
726  
633  
718  
763  
677  
801  
800  
697  
839  
817  
CAP  
744  
676  
627  
778  
718  
697  
794  
739  
732  
811  
761  
767  
818  
771  
783  
SHC  
438  
304  
627  
514  
508  
697  
551  
610  
732  
589  
712  
767  
606  
759  
783  
CAP  
741  
672  
587  
774  
713  
664  
790  
734  
702  
806  
754  
741  
814  
764  
758  
SHC  
392  
458  
554  
457  
550  
648  
490  
597  
694  
522  
643  
741  
537  
664  
759  
CAP  
741  
681  
616  
771  
715  
658  
787  
732  
679  
802  
750  
700  
809  
757  
710  
SHC  
357  
416  
489  
403  
494  
589  
425  
533  
639  
448  
572  
690  
459  
589  
709  
CAP  
737  
681  
632  
767  
711  
655  
782  
727  
667  
798  
742  
679  
804  
749  
684  
SHC  
319  
384  
454  
347  
442  
536  
361  
471  
576  
375  
500  
617  
382  
514  
636  
CAP  
SHC  
14000  
67  
678  
624  
350  
412  
62  
72  
18000  
21000  
24000  
27000  
67  
708  
655  
389  
480  
62  
72  
67  
723  
670  
409  
515  
62  
72  
67  
738  
686  
428  
549  
62  
72  
67  
744  
693  
437  
565  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
115° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
83 80 77  
ENTERING  
90  
86  
74  
CFM  
WB (°F)  
72  
CAP  
726  
629  
626  
749  
700  
699  
760  
736  
735  
772  
772  
772  
777  
788  
788  
SHC  
485  
574  
626  
572  
673  
699  
615  
722  
735  
658  
772  
772  
678  
788  
788  
CAP  
711  
647  
607  
742  
688  
666  
758  
708  
695  
774  
728  
724  
781  
737  
737  
SHC  
413  
512  
622  
496  
603  
673  
538  
648  
698  
580  
693  
724  
599  
714  
735  
CAP  
702  
647  
562  
736  
683  
639  
754  
701  
677  
771  
718  
715  
779  
727  
732  
SHC  
376  
447  
543  
440  
537  
629  
473  
582  
672  
505  
627  
715  
520  
647  
733  
CAP  
698  
643  
561  
732  
680  
625  
749  
699  
657  
766  
717  
690  
773  
726  
704  
SHC  
345  
411  
467  
389  
484  
578  
411  
521  
634  
433  
558  
690  
443  
574  
706  
CAP  
689  
635  
582  
726  
673  
620  
744  
692  
640  
763  
711  
659  
771  
719  
668  
SHC  
309  
370  
447  
335  
429  
524  
349  
458  
563  
362  
487  
602  
368  
501  
619  
CAP  
SHC  
14000  
67  
633  
574  
338  
404  
62  
72  
18000  
21000  
24000  
27000  
67  
669  
617  
376  
472  
62  
72  
67  
687  
638  
395  
505  
62  
72  
67  
706  
659  
414  
539  
62  
72  
67  
714  
669  
423  
555  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
YORK INTERNATIONAL  
17  
Cooling Performance Data 65 Ton Model  
TABLE 5 COOLING PERFORMANCE DATA 65 TON MODEL  
85° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
ENTERING  
90  
86  
83  
80  
77  
74  
CFM  
WB (°F)  
72  
CAP  
840  
785  
754  
853  
802  
779  
876  
827  
821  
899  
862  
862  
909  
878  
878  
SHC  
584  
669  
754  
615  
713  
779  
668  
788  
821  
721  
862  
862  
745  
878  
878  
CAP  
839  
774  
724  
851  
788  
748  
871  
810  
787  
892  
833  
827  
901  
843  
843  
SHC  
516  
605  
724  
540  
638  
748  
582  
694  
787  
623  
750  
827  
642  
776  
765  
CAP  
836  
771  
695  
848  
784  
719  
868  
806  
760  
888  
828  
801  
898  
838  
820  
SHC  
467  
554  
640  
486  
582  
676  
518  
630  
739  
550  
678  
801  
564  
700  
686  
CAP  
833  
772  
710  
844  
784  
723  
864  
804  
745  
884  
824  
767  
893  
833  
777  
SHC  
418  
502  
589  
431  
525  
620  
454  
563  
674  
477  
601  
727  
488  
619  
604  
CAP  
828  
768  
707  
840  
780  
719  
859  
800  
741  
878  
820  
762  
887  
829  
772  
SHC  
368  
456  
542  
377  
473  
568  
392  
502  
612  
407  
531  
656  
413  
544  
530  
CAP  
SHC  
14000  
67  
764  
706  
406  
492  
62  
72  
18000  
21000  
24000  
27000  
67  
776  
717  
418  
513  
62  
72  
67  
796  
737  
439  
548  
62  
72  
67  
815  
757  
460  
584  
62  
72  
67  
824  
766  
469  
455  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
95° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
83 80  
ENTERING  
90  
86  
77  
74  
CFM  
WB (°F)  
72  
CAP  
810  
767  
733  
822  
782  
756  
844  
800  
797  
866  
837  
837  
875  
854  
854  
SHC  
572  
658  
733  
603  
699  
756  
656  
768  
797  
709  
837  
837  
733  
854  
854  
CAP  
808  
747  
704  
820  
759  
726  
839  
781  
764  
858  
802  
802  
867  
812  
812  
SHC  
504  
593  
704  
528  
625  
726  
569  
681  
764  
610  
737  
802  
629  
762  
753  
CAP  
806  
743  
676  
817  
756  
699  
836  
777  
737  
855  
798  
776  
863  
807  
794  
SHC  
454  
542  
631  
473  
570  
664  
505  
618  
720  
537  
665  
776  
552  
687  
674  
CAP  
802  
744  
686  
813  
755  
697  
832  
774  
717  
850  
793  
737  
859  
801  
746  
SHC  
405  
491  
581  
419  
513  
610  
442  
551  
661  
464  
589  
712  
475  
606  
592  
CAP  
798  
740  
682  
809  
751  
694  
827  
770  
714  
844  
788  
734  
852  
797  
743  
SHC  
357  
443  
530  
365  
460  
556  
380  
489  
600  
394  
519  
644  
401  
532  
518  
CAP  
SHC  
14000  
67  
737  
680  
393  
477  
62  
72  
18000  
21000  
24000  
27000  
67  
748  
691  
406  
500  
62  
72  
67  
766  
710  
426  
538  
62  
72  
67  
784  
729  
447  
577  
62  
72  
67  
792  
738  
456  
441  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
YORK INTERNATIONAL  
18  
FORM 100.50-EG1  
TABLE 5 COOLING PERFORMANCE DATA 65 TON MODEL (CONTD)  
105° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
83 80 77  
ENTERING  
90  
86  
74  
CFM  
WB (°F)  
72  
CAP  
780  
737  
710  
792  
753  
732  
812  
771  
771  
831  
809  
809  
840  
826  
826  
SHC  
560  
646  
710  
591  
683  
732  
643  
746  
771  
696  
809  
809  
720  
826  
826  
CAP  
777  
717  
682  
788  
730  
703  
805  
752  
739  
822  
774  
774  
830  
784  
791  
SHC  
493  
581  
682  
516  
613  
703  
555  
668  
739  
595  
722  
774  
613  
747  
791  
CAP  
774  
714  
650  
785  
726  
672  
802  
746  
711  
820  
766  
750  
828  
775  
767  
SHC  
442  
529  
621  
461  
556  
650  
493  
604  
700  
524  
651  
750  
539  
673  
772  
CAP  
771  
714  
658  
781  
725  
669  
798  
744  
689  
816  
762  
709  
823  
770  
718  
SHC  
393  
476  
565  
406  
499  
595  
429  
538  
647  
452  
576  
698  
462  
594  
721  
CAP  
768  
711  
655  
777  
721  
666  
794  
738  
685  
810  
756  
704  
817  
763  
712  
SHC  
342  
430  
516  
351  
447  
542  
365  
476  
586  
379  
505  
630  
386  
518  
650  
CAP  
SHC  
14000  
67  
708  
653  
381  
466  
62  
72  
18000  
21000  
24000  
27000  
67  
718  
663  
393  
486  
62  
72  
67  
734  
681  
413  
522  
62  
72  
67  
751  
699  
433  
558  
62  
72  
67  
759  
707  
442  
574  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
115° AIR ON CONDENSER COIL  
CAPACITY (MBH) AT ENTERING DRY BULB (°F)  
83 80 77  
ENTERING  
90  
86  
74  
CFM  
WB (°F)  
72  
CAP  
748  
708  
681  
759  
724  
704  
776  
741  
741  
794  
779  
779  
802  
796  
796  
SHC  
548  
639  
681  
578  
671  
704  
629  
725  
741  
680  
779  
779  
703  
796  
796  
CAP  
744  
690  
664  
754  
700  
679  
771  
716  
706  
789  
732  
732  
797  
740  
740  
SHC  
478  
570  
664  
502  
599  
679  
543  
650  
706  
584  
700  
732  
603  
723  
717  
CAP  
742  
686  
621  
752  
696  
644  
768  
714  
682  
784  
732  
721  
791  
740  
738  
SHC  
429  
517  
608  
448  
544  
634  
479  
591  
678  
511  
637  
721  
525  
658  
648  
CAP  
738  
684  
625  
748  
694  
642  
766  
711  
669  
784  
728  
697  
792  
736  
710  
SHC  
378  
463  
550  
392  
486  
583  
415  
523  
640  
438  
561  
697  
449  
578  
563  
CAP  
735  
681  
628  
744  
690  
638  
759  
706  
655  
774  
722  
672  
781  
729  
680  
SHC  
330  
417  
503  
338  
434  
528  
352  
462  
571  
366  
491  
615  
372  
504  
490  
CAP  
SHC  
14000  
67  
678  
625  
368  
452  
62  
72  
18000  
21000  
24000  
27000  
67  
687  
635  
380  
473  
62  
72  
67  
703  
651  
400  
508  
62  
72  
67  
718  
668  
419  
543  
62  
72  
67  
725  
676  
428  
414  
62  
* Rated performance is at sea level. Cooling capacities are gross cooling capacity.  
YORK INTERNATIONAL  
19  
Fan Performance  
TABLE 6 50 THROUGH 65 TON SUPPLY FAN DATA  
TOTAL STATIC PRESSURE (inches of water column)  
1.00 1.50 2.00 2.50  
RPM RPM RPM RPM  
CFM  
STD. AIR  
10000  
12000  
14000  
16000  
17500  
18000  
19250  
20000  
21000  
22000  
22500  
24000  
26000  
27000  
0.50  
RPM  
3.00  
RPM  
HP  
1.7  
HP  
2.5  
HP  
3.3  
HP  
HP  
––  
HP  
249  
269  
290  
312  
329  
334  
348  
357  
370  
383  
387  
398  
417  
429  
321  
335  
352  
371  
386  
391  
404  
412  
423  
434  
440  
458  
478  
490  
382  
392  
405  
421  
435  
439  
451  
458  
468  
478  
484  
500  
520  
533  
––  
––  
––  
––  
2.5  
3.4  
4.4  
443  
454  
467  
478  
482  
493  
499  
510  
520  
524  
537  
559  
572  
5.3  
493  
497  
510  
519  
522  
532  
538  
547  
555  
560  
574  
593  
602  
6.4  
––  
3.6  
4.7  
5.8  
6.9  
8.0  
540  
549  
558  
561  
570  
575  
583  
591  
595  
607  
626  
638  
9.1  
5.1  
6.3  
7.5  
8.7  
10.0  
11.7  
12.3  
14.0  
15.1  
16.7  
18.3  
19.2  
22.1  
26.3  
28.6  
11.2  
13.1  
13.8  
15.5  
16.6  
18.3  
20.0  
20.9  
23.8  
28.3  
30.9  
6.3  
7.7  
9.0  
10.4  
10.9  
12.5  
13.5  
15.1  
16.7  
17.6  
20.2  
24.4  
26.8  
6.8  
8.2  
9.6  
8.1  
9.6  
11.1  
12.1  
13.5  
15.0  
15.8  
18.4  
22.3  
24.6  
8.9  
10.5  
11.9  
13.3  
14.1  
16.6  
20.2  
22.3  
10.1  
11.4  
12.0  
13.9  
16.8  
18.6  
TABLE 6 50 THROUGH 65 TON SUPPLY FAN DATA (CONTD)  
TOTAL STATIC PRESSURE (inches of water column)  
4.00 4.50 5.00 5.50  
RPM RPM RPM RPM  
CFM  
STD. AIR  
10000  
12000  
14000  
16000  
17500  
18000  
19250  
20000  
21000  
22000  
22500  
24000  
26000  
27000  
3.50  
RPM  
6.00  
HP  
––  
HP  
––  
HP  
––  
HP  
––  
HP  
––  
RPM  
––  
HP  
––  
––  
––  
––  
––  
––  
––  
––  
––  
––  
––  
––  
––  
––  
––  
––  
––  
––  
585  
587  
595  
597  
605  
609  
617  
624  
628  
640  
656  
665  
10.5  
12.5  
14.5  
15.2  
17.1  
18.2  
19.9  
21.7  
22.7  
25.7  
30.2  
32.7  
––  
––  
––  
––  
––  
––  
––  
––  
––  
––  
622  
629  
631  
638  
642  
649  
655  
659  
671  
687  
693  
13.8  
15.9  
16.6  
18.6  
19.8  
21.6  
23.4  
24.4  
27.5  
32.2  
34.6  
663  
664  
664  
670  
674  
681  
688  
691  
700  
716  
723  
15.4  
17.3  
18.0  
20.1  
21.4  
23.3  
25.3  
26.3  
29.4  
34.2  
36.8  
700  
697  
696  
702  
705  
710  
715  
719  
729  
742  
751  
17.0  
18.8  
19.5  
21.6  
22.9  
24.9  
26.9  
28.0  
31.4  
36.1  
38.9  
––  
––  
––  
––  
549  
732  
734  
735  
740  
744  
748  
759  
769  
778  
15.9  
21.2  
23.3  
24.5  
26.6  
28.6  
29.8  
33.4  
38.2  
41.0  
575  
766  
765  
764  
769  
773  
776  
783  
798  
802  
17.3  
23.0  
25.0  
26.1  
28.2  
30.4  
31.5  
35.1  
40.5  
43.1  
YORK INTERNATIONAL  
20  
FORM 100.50-EG1  
TABLE 7 50 THROUGH 65 TON EXHAUST FAN DATA  
TOTAL STATIC PRESSURE (inches of water column)  
1.00 1.50 2.00 2.50  
RPM RPM RPM RPM  
––  
CFM  
STD. AIR  
10000  
12000  
14000  
16000  
18000  
20000  
0.50  
RPM  
3.00  
RPM  
HP  
HP  
HP  
–––  
6.87  
HP  
––  
––  
HP  
––  
––  
HP  
––  
––  
––  
674  
713  
762  
819  
3.30  
4.84  
6.84  
9.36  
801  
823  
858  
4.18  
––  
––  
––  
––  
––  
––  
––  
5.82 929  
7.98 952  
9.12 1043 10.32 1132 11.62  
904 10.73 988 12.04 1070 13.33 1150 14.69 1229 16.10  
879 12.42 957 14.04 1032 15.56 1107 17.02 1179 18.48  
943 16.18 1014 18.04 –– –– –– –– –– ––  
––  
––  
––  
––  
YORK INTERNATIONAL  
21  
Fan Performance (continued)  
TABLE 8 COMPONENT STATIC PRESSURE DROPS (INCHES OF WATER COLUMN)  
FILTERS  
2" 2"  
THROW- CLEAN- PLEAT-  
EVAPORATOR  
COILS  
SUPPLY  
RETURN AIR  
OPENING  
AIR FLOW  
2"  
SIZE  
50  
2"  
OPENING  
CFM STD. AIR  
CARBON  
WET  
DRY  
BOTTOM LEFT RIGHT BOTTOM REAR SIDES AWAY  
ABLE  
ED  
10000  
12000  
14000  
16000  
17500  
18000  
20000  
21000  
22000  
22500  
12000  
14000  
16000  
18000  
19250  
20000  
22000  
24000  
14000  
16000  
18000  
20000  
21000  
22000  
24000  
26000  
27000  
14000  
16000  
18000  
20000  
21000  
22000  
24000  
26000  
27000  
0.22  
0.30  
0.38  
0.47  
0.54  
0.57  
0.67  
0.72  
0.78  
0.80  
0.30  
0.38  
0.47  
0.57  
0.63  
0.67  
0.78  
0.89  
0.38  
0.47  
0.57  
0.67  
0.72  
0.78  
0.89  
1.01  
1.07  
0.38  
0.47  
0.57  
0.67  
0.72  
0.78  
0.89  
1.01  
1.07  
0.15  
0.21  
0.27  
0.35  
0.41  
0.44  
0.53  
0.58  
0.63  
0.66  
0.21  
0.27  
0.35  
0.44  
0.49  
0.53  
0.63  
0.74  
0.27  
0.35  
0.44  
0.53  
0.58  
0.63  
0.74  
0.86  
0.92  
0.27  
0.35  
0.44  
0.53  
0.58  
0.63  
0.74  
0.86  
0.92  
0.04  
0.06  
0.09  
0.11  
0.14  
0.14  
0.18  
0.20  
0.21  
0.22  
0.06  
0.09  
0.11  
0.14  
0.16  
0.18  
0.21  
0.25  
0.09  
0.11  
0.14  
0.18  
0.20  
0.21  
0.25  
0.30  
0.32  
0.09  
0.11  
0.14  
0.18  
0.20  
0.21  
0.25  
0.30  
0.32  
0.08 0.08  
0.11 0.11  
0.15 0.15  
0.20 0.20  
0.24 0.24  
0.25 0.25  
0.31 0.31  
0.35 0.35  
0.38 0.38  
0.40 0.40  
0.11 0.11  
0.15 0.15  
0.20 0.20  
0.25 0.25  
0.29 0.29  
0.31 0.31  
0.38 0.38  
0.45 0.45  
0.15 0.15  
0.20 0.20  
0.25 0.25  
0.31 0.31  
0.35 0.35  
0.38 0.38  
0.45 0.45  
0.53 0.53  
0.57 0.57  
0.15 0.15  
0.20 0.20  
0.25 0.25  
0.31 0.31  
0.35 0.35  
0.38 0.38  
0.45 0.45  
0.53 0.53  
0.57 0.57  
0.04  
0.06  
0.08  
0.11  
0.13  
0.13  
0.17  
0.18  
0.20  
0.21  
0.06  
0.08  
0.11  
0.13  
0.15  
0.17  
0.20  
0.24  
0.08  
0.11  
0.13  
0.17  
0.18  
0.20  
0.24  
0.28  
0.30  
0.08  
0.11  
0.13  
0.17  
0.18  
0.20  
0.24  
0.28  
0.30  
0.06 0.04  
0.09 0.06  
0.12 0.09  
0.15 0.11  
0.18 0.14  
0.19 0.14  
0.24 0.18  
0.26 0.20  
0.29 0.21  
0.30 0.22  
0.09 0.06  
0.12 0.09  
0.15 0.11  
0.19 0.14  
0.22 0.16  
0.24 0.18  
0.29 0.21  
0.34 0.25  
0.12 0.09  
0.15 0.11  
0.19 0.14  
0.24 0.18  
0.26 0.20  
0.29 0.21  
0.34 0.25  
0.40 0.30  
0.43 0.32  
0.12 0.09  
0.15 0.11  
0.19 0.14  
0.24 0.18  
0.26 0.20  
0.29 0.21  
0.34 0.25  
0.40 0.30  
0.43 0.32  
0.05  
0.07  
0.09  
0.11  
0.12  
0.13  
0.15  
0.16  
0.17  
0.17  
0.07  
0.09  
0.11  
0.13  
0.14  
0.15  
0.17  
0.19  
0.09  
0.11  
0.13  
0.15  
0.16  
0.17  
0.19  
0.21  
0.23  
0.09  
0.11  
0.13  
0.15  
0.16  
0.17  
0.19  
0.21  
0.23  
0.01  
0.02  
0.03  
0.04  
0.05  
0.05  
0.06  
0.07  
0.08  
0.08  
0.02  
0.03  
0.04  
0.05  
0.06  
0.06  
0.08  
0.09  
0.03  
0.04  
0.05  
0.06  
0.07  
0.08  
0.09  
0.11  
0.12  
0.03  
0.04  
0.05  
0.06  
0.07  
0.08  
0.09  
0.11  
0.12  
0.04  
0.06  
0.07  
0.09  
0.10  
0.10  
0.12  
0.13  
0.14  
0.15  
0.06  
0.07  
0.09  
0.10  
0.12  
0.12  
0.14  
0.16  
0.07  
0.09  
0.10  
0.12  
0.13  
0.14  
0.16  
0.19  
0.20  
0.07  
0.09  
0.10  
0.12  
0.13  
0.14  
0.16  
0.19  
0.20  
0.08  
0.11  
0.14  
0.16  
0.19  
0.19  
0.22  
0.24  
0.26  
0.26  
0.11  
0.14  
0.16  
0.19  
0.21  
0.22  
0.26  
0.29  
0.14  
0.16  
0.19  
0.22  
0.24  
0.26  
0.29  
0.32  
0.34  
0.14  
0.16  
0.19  
0.22  
0.24  
0.26  
0.29  
0.32  
0.34  
55  
60  
65  
For Aluminum Fins Only  
*
YORK INTERNATIONAL  
22  
FORM 100.50-EG1  
FILTERS  
ECONOMIZER DAMPERS  
ECONOMIZER  
FRESH AIR  
OPENINGS  
RIGID FILTER  
RACK NO.  
MEDIA  
POWERED  
EXHAUST  
12" RIGID  
65%*  
12" RIGID  
95%*  
MANUAL OR  
0 - 100%  
2-POSITION MODULATION  
0.05  
0.07  
0.09  
0.11  
0.12  
0.13  
0.15  
0.16  
0.17  
0.17  
0.07  
0.09  
0.11  
0.13  
0.14  
0.15  
0.17  
0.19  
0.09  
0.11  
0.13  
0.15  
0.16  
0.17  
0.19  
0.21  
0.23  
0.09  
0.11  
0.13  
0.15  
0.16  
0.17  
0.19  
0.21  
0.23  
0.21  
0.28  
0.34  
0.42  
0.47  
0.49  
0.58  
0.62  
0.66  
0.68  
0.28  
0.34  
0.42  
0.49  
0.54  
0.58  
0.66  
0.75  
0.34  
0.42  
0.49  
0.58  
0.62  
0.66  
0.75  
0.84  
0.89  
0.34  
0.42  
0.49  
0.58  
0.62  
0.66  
0.75  
0.84  
0.89  
0.30  
0.38  
0.46  
0.55  
0.62  
0.65  
0.74  
0.79  
0.84  
0.87  
0.38  
0.46  
0.55  
0.65  
0.71  
0.74  
0.84  
0.95  
0.46  
0.55  
0.65  
0.74  
0.79  
0.84  
0.95  
1.06  
1.11  
0.46  
0.55  
0.65  
0.74  
0.79  
0.84  
0.95  
1.06  
1.11  
0.07  
0.11  
0.15  
0.20  
0.24  
0.25  
0.31  
0.35  
0.38  
0.40  
0.11  
0.15  
0.20  
0.25  
0.29  
0.31  
0.38  
0.46  
0.15  
0.20  
0.25  
0.31  
0.35  
0.38  
0.46  
0.55  
0.59  
0.15  
0.20  
0.25  
0.31  
0.35  
0.38  
0.46  
0.55  
0.59  
0.05  
0.08  
0.11  
0.14  
0.17  
0.18  
0.22  
0.24  
0.27  
0.28  
0.08  
0.11  
0.14  
0.18  
0.20  
0.22  
0.27  
0.32  
0.11  
0.14  
0.18  
0.22  
0.24  
0.27  
0.32  
0.37  
0.40  
0.11  
0.14  
0.18  
0.22  
0.24  
0.27  
0.32  
0.37  
0.40  
0.11  
0.16  
0.21  
0.26  
0.31  
0.32  
0.39  
0.42  
0.46  
0.48  
0.16  
0.21  
0.26  
0.32  
0.36  
0.39  
0.46  
0.54  
0.21  
0.26  
0.32  
0.39  
0.42  
0.46  
0.54  
0.62  
0.67  
0.21  
0.26  
0.32  
0.39  
0.42  
0.46  
0.54  
0.62  
0.67  
0.08  
0.11  
0.15  
0.20  
0.24  
0.25  
0.31  
0.34  
0.37  
0.39  
0.11  
0.15  
0.20  
0.25  
0.29  
0.31  
0.37  
0.45  
0.15  
0.20  
0.25  
0.31  
0.34  
0.37  
0.45  
0.52  
0.56  
0.15  
0.20  
0.25  
0.31  
0.34  
0.37  
0.45  
0.52  
0.56  
YORK INTERNATIONAL  
23  
Electrical Data  
ELECTRICAL SERVICE SIZING  
In order to use the electrical service required for the  
cooling only Eco2 rooftop, use the appropriate calcula-  
tions listed below from U.L. 1995. Based on the operat-  
ing mode and configuration of the rooftop, the calcula-  
tions will yield different MCA (minimum circuit ampac-  
ity), and MOP (maximum overcurrent protection).  
LOAD3 is the current of the electric heaters zero  
for cooling only units.  
LOAD4 is the sum of any remaining currents  
greater than or equal to 1.0 amp  
Use the following calculations to determine MCA  
and MOP for units supplied with a single-point power  
connection:  
Using the following load definitions and calculations,  
determine the correct electrical sizing for your unit. All  
concurrent load conditions must be considered in the  
calculations, and you must use the highest value for  
any combination of loads.  
MCA = (1.25 x LOAD1) + LOAD2 + LOAD4  
MOP = (2.25 x LOAD1) + LOAD2 + LOAD4  
Load Definitions:  
If the MOP does not equal a standard current rating of  
an overcurrent protective device, then the marked maxi-  
mum rating is to be the next lower standard rating. How-  
ever, if the device selected for MOP is less than the  
MCA, then select the lowest standard maximum fuse  
size greater than or equal to the MCA.  
LOAD1 is the current of the largest motor com-  
pressor or fan motor.  
LOAD2 is the sum of the remaining motor currents  
that may run concurrently with LOAD1 (i.e., exhaust  
fan motor).  
TABLE 9 COMPRESSORS  
COMPRESSOR  
NOMINAL VOLTAGE  
QUANTITY  
208V  
230V  
RLA*  
460V  
575V  
LRA*  
PER  
MODEL  
MODEL  
UNIT  
RLA*  
54.0  
54.0  
62.3  
62.3  
LRA*  
265.0  
265.0  
380.0  
380.0  
LRA*  
265.0  
265.0  
380.0  
380.0  
RLA*  
24.2  
24.2  
27.9  
27.9  
LRA*  
135.0  
135.0  
175.0  
175.0  
RLA*  
19.4  
19.4  
22.3  
22.3  
50  
55  
60  
65  
4
4
4
4
SZ160  
SZ160  
SZ185  
SZ185  
48.8  
48.8  
56.3  
56.3  
120.0  
120.0  
140.0  
140.0  
* Values shown are per compressor  
YORK INTERNATIONAL  
24  
FORM 100.50-EG1  
TABLE 10 SUPPLY AND EXHAUST FAN MOTOR (ODP OR TEFC)  
High Efficiency Premium Efficiency  
NOMINAL VOLTAGE  
NOMINAL VOLTAGE  
MOTOR  
HP  
208V  
230V  
FLA  
13.4  
21.6  
28.4  
39.0  
50.0  
60.0  
76.0  
95.6  
460V  
FLA  
6.7  
575V  
FLA  
5.3  
MOTOR  
HP  
208V  
FLA  
14.9  
22.5  
29.2  
41.5  
55.0  
71.0  
85.5  
109.0  
230V  
FLA  
13.6  
20.0  
25.8  
36.0  
48.0  
61.0  
74.0  
96.0  
460V  
FLA  
6.8  
575V  
FLA  
5.5  
FLA  
14.0  
22.2  
28.5  
44.8  
61.0  
74.0  
87.0  
113.0  
5.0  
5.0  
7.5  
10.8  
14.2  
19.5  
25.0  
30.0  
38.0  
47.8  
8.2  
7.5  
10.0  
12.9  
18.0  
24.0  
30.5  
37.0  
48.0  
7.9  
10.0  
15.0  
20.0  
25.0  
30.0  
40.0  
11.4  
16.0  
20.0  
24.2  
30.3  
38.0  
10.0  
15.0  
20.0  
25.0  
30.0  
40.0  
10.3  
14.5  
19.3  
24.5  
30.0  
38.0  
TABLE 11 CONDENSER FAN MOTORS / EACH  
TABLE 12 CONTROLS AND CONVENIENCE  
OUTLET  
NOMINAL VOLTAGE  
NOMINAL VOLTAGE  
NOMINAL  
208V  
FLA  
7.5  
230V  
FLA  
6.8  
460V  
FLA  
3.4  
575V  
FLA  
2.7  
208V 230V 460V 575V  
DESCRIPTION  
TONS  
50  
AMPS AMPS AMPS AMPS  
Control Transformer  
Convenience Outlet  
3.6  
9.6  
3.3  
8.7  
1.6  
4.3  
3.3  
3.5  
55  
7.5  
6.8  
3.4  
2.7  
60  
7.5  
6.8  
3.4  
2.7  
65  
7.5  
6.8  
3.4  
2.7  
YORK INTERNATIONAL  
25  
Controls  
CONTROL SEQUENCES FOR ALL UNITS  
GENERAL  
ECONOMIZER OPERATION  
The control system for the YORK eco2 Packaged Roof-  
top Unit is fully self-contained and based around an  
OptiLogicrooftop unit controller. To aid in unit setup,  
maintenance, and operation, the OptiLogicrooftop  
unit controller is equipped with a user interface that is  
based around a 4 line x 20 character backlit LCD dis-  
play. The LCD displays plain language text in a menu-  
driven format to facilitate use. In addition to the display,  
the OptiLogicuser interface is also equipped with an  
LED indicator light, which will warn of any abnormal  
operation of the equipment or communication failures.  
The unit can be equipped with one of three types of  
optional economizers, dry bulb, single enthalpy, or com-  
parative enthalpy. When the unit controller determines  
that Outside Air is suitable for economizing, the unit  
controller will control the outside air damper(s) open to  
provide economizer cooling. If economizer cooling alone  
is insufficient for the cooling load, the unit controller  
shall stage up compressors, one at a time, to meet  
demand.  
The control logic for the three types of economizers is  
as follows:  
For the maximum in system flexibility, the YORK ECO2  
Packaged Rooftop Unit can be operated by either a  
typical 7-wire thermostat (2 cool / 2 heat), a space tem-  
perature sensor, or stand-alone (VAV only). Note, a field  
wiring terminal block is provided to facilitate unit setup  
and installation.  
Dry Bulb Economizer  
The dry bulb economizer is the default economizer con-  
trol scheme. With the dry bulb economizer, the unit con-  
troller monitors the Outside Air temperature only and  
compares it to a reference temperature setting. Outside  
Air is deemed suitable for economizing when the Out-  
side Air temperature is determined to be less than the  
reference temperature setting. This method of econo-  
mizing is effective, but is prone to some changeover in-  
efficiencies due to the fact that this method is based on  
sensible temperatures only and does not take Outside  
Air moisture content into consideration.  
In lieu of the hard-wired control options, the OptiLogic™  
rooftop unit controller can be connected to and oper-  
ated by a Building Automation System (BAS). If re-  
quired, the OptiLogicrooftop unit controller can be  
equipped with an optional BACNet IP communication  
card, which allows communication, via Ethernet, to a  
BACNet IP based BAS.  
Single Enthalpy Economizer  
UNOCCUPIED / OCCUPIED SWITCHING  
With the optional single enthalpy economizer, the unit  
controller monitors the Outside Air enthalpy in addition  
to the Outside Air temperature and compares it to a  
reference enthalpy setting and a reference tempera-  
ture setting. Outside Air is deemed suitable for econo-  
mizing when the Outside Air enthalpy is determined to  
be less than the reference enthalpy setting and the Out-  
side Air temperature is less than the reference tem-  
perature setting. This method of economizing allows  
the reference temperature setting to be set higher than  
the DB Economizer and is consequently a more effi-  
cient packaged rooftop economizer.  
Depending on application, the unit can be indexed be-  
tween unoccupied and occupied modes of operation  
by one of three methods, hard-wired input, internal time  
clock, or BAS. A contact-closure input is provided for  
hard-wiring to an external indexing device such as a  
central time clock, thermostat with built in scheduling,  
or a manual switch. The unit controller is also equipped  
with a built in 7-day time clock which can be used, in  
lieu of the contact closure input, to switch the unit be-  
tween Unoccupied and Occupied modes of operation.  
The internal time clock is fully configurable via the user  
interface and includes Holiday scheduling. In addition  
to the hard-wired input or the internal time clock, the  
unit can also be indexed between unoccupied and oc-  
cupied modes of operation via a BAS command.  
Comparative Enthalpy Economizer  
With the optional comparative enthalpy economizer, the  
unit controller monitors and compares the Outside Air  
and Return Air enthalpies in addition to comparing the  
Outside Air temperature to the reference temperature  
setting. Outside Air is deemed suitable for economiz-  
ing when the Outside Air enthalpy is determined to be  
Note a unit operated from a space sensor can be  
equipped to temporarily override an unoccupied mode  
of operation. This Unoccupied Override feature is fully  
configurable via the OptiLogicuser interface.  
YORK INTERNATIONAL  
26  
FORM 100.50-EG1  
less than the Return Air enthalpy and the Outside Air  
temperature is less than the reference temperature set-  
ting. This method of economizing is the most accurate  
and provides the highest degree of energy efficiency  
for a packaged rooftop economizer.  
Demand Ventilation  
If an optional CO2 sensor is connected to the unit, the  
unit controller can reset the minimum OA damper  
position(s) or minimum flow rate based on demand.  
The unit controller shall monitor the CO2 level within the  
building. If the CO2 level rises above the CO2 setpoint,  
the controller will temporarily increase the Minimum OA  
Damper Position or Minimum OA flow rate to increase  
ventilation. If the CO2 level drops below the CO2 set-  
point, the controller will decrease the Minimum OA  
Damper Position or Minimum OA flow rate to decrease  
ventilation.  
VENTILATION CONTROL SEQUENCES  
Minimum OA Damper Position (CV Units)  
When the unit goes into the Occupied mode of opera-  
tion, the unit controller shall open the Outside Air  
Damper to a fixed minimum position. The damper shall  
remain at this position as long as the unit is in the occu-  
pied mode. The minimum position may be overridden  
more open by the unit controller when Outside Air con-  
ditions are suitable for economizing.  
Demand Ventilation shall remain active as long as the  
unit is in the Occupied mode of operation.  
Minimum OA Damper Position (VAV Units)  
EXHAUST CONTROL SEQUENCES  
Barometric  
With Variable Air Volume units, there are two Minimum  
OA Damper Positions, one when the unit is at full speed  
and the second when the unit is at approximately half  
speed. These two points allow the control to linearly  
reset the position of the OA damper in response to fan  
speed.  
The optional barometric exhaust system consists of a  
lightweight barometric relief damper installed on the end  
of the unit in the Return Air section. As more outside air  
is introduced into the controlled zone due to Econo-  
mizer and Ventilation control sequences, the pressure  
inside the building rises. This increase in building pres-  
sure forces the barometric relief damper open to allow  
exhaust air to escape. Because this type of exhaust  
system is not powered, it is limited to small amounts of  
exhaust.  
When the unit goes into the Occupied mode of opera-  
tion, the unit controller shall monitor the speed of the  
supply fan and open the Outside Air damper to a calcu-  
lated minimum position based on the fan speed. This  
minimum position shall vary as the speed of the fan  
changes. The damper shall remain at this calculated  
position as long as the unit is in the occupied mode.  
The minimum position may be overridden more open  
by the unit controller when Outside Air conditions are  
suitable for economizing.  
Powered Fixed Volume Exhaust Based on  
Outside Air Damper Position  
This optional fixed volume powered exhaust system  
consists of a fixed speed fan that is controlled ON and  
OFF based on the position of the Outside Air Damper.  
During operation, when the Outside Air Damper opens  
to a selected turn-on point, the Exhaust Fan is cycled  
ON. The fan remains on as long as the Outside Air  
damper is above a selected turn-off point. If the Out-  
side Air Damper closes to the selected turn-off point,  
the Exhaust Fan is cycled OFF. The turn-on and turn-  
off points are user selectable from the OptiLogicUser  
Interface panel.  
Air Measurement Stations  
When the unit is equipped with an air measurement  
station, the unit controller shall control the Outside Air  
damper to a measured flow rate through the Air Mea-  
surement Station.  
When the unit goes into the Occupied mode of opera-  
tion, the unit controller shall control the Outside Air  
damper to maintain the Minimum AirFlow Setpoint  
through the Air Measurement Station. The unit control-  
ler shall control the Outside Air damper to this flow rate  
as long as the unit is in the Occupied mode. The Out-  
side Air damper may be overridden more open by the  
unit controller when Outside Air conditions are suitable  
for economizing.  
Powered Fixed Volume Exhaust Based on  
Building Pressure  
This optional fixed volume powered exhaust system  
consists of a fixed speed fan that is controlled ON and  
OFF based on the pressure inside the building. During  
YORK INTERNATIONAL  
27  
Controls (continued)  
operation, the pressure within the building in monitored  
by the OptiLogiccontroller. If the pressure rises to or  
above a selected turn-on pressure, the Exhaust Fan is  
cycled ON. The fan shall remain on as long as the pres-  
sure within the building remains above a selected turn-  
off pressure. If the building pressure falls to or below  
the selected turn-off pressure, the Exhaust Fan is cycled  
OFF. The turn-on and turn-off pressure setpoints are  
user selectable from the OptiLogicUser Interface.  
For these applications, the unit can be equipped with  
optional Low Ambient controls. For optional Low Ambi-  
ent operation, the OptiLogiccontroller monitors the  
refrigeration system discharge pressure and controls  
the speed of the condenser fans. If the discharge pres-  
sure falls, the speeds of the condenser fans are re-  
duced to maintain acceptable condensing pressures in  
the refrigeration system. With the optional Low Ambi-  
ent controls, mechanical cooling is allowed down to  
Outside Air temperatures of 0°F.  
Powered Variable Volume Exhaust-Discharge  
Damper Controlled  
SMOKE PURGE SEQUENCES  
General  
This optional variable volume powered exhaust system  
consists of a fixed speed fan configured with a propor-  
tionally controlled discharge damper. The OptiLogic™  
controller monitors the pressure inside the building and  
controls the Exhaust Damper and the Exhaust Fan. If  
the Building Pressure rises, the Exhaust Damper is pro-  
portionally controlled open and the Exhaust Fan is con-  
trolled ON. If the Building Pressure falls, the Exhaust  
Damper is proportionally controlled closed and the Ex-  
haust Fan is controlled OFF. The position of the Ex-  
haust Damper in which the Exhaust Fan is controlled  
ON and OFF as well as the Building Pressure setpoint  
is user selectable from the OptiLogicUser Interface.  
As a convenience, for when buildings catch fire or the  
building is inundated with smoke or fumes from manu-  
facturing processes, etc., the OptiLogiccontrol sys-  
tem provides one of five ventilation override control se-  
quences for building purge. The five selectable purge  
sequences are, Shutdown, Pressurization, Exhaust,  
Purge and Purge with duct pressure control. Note, when  
any of the purge sequences are activated, cooling and  
heating modes are disabled. A contact closure is pro-  
vided which indexes the OptiLogiccontroller into the  
selected purge sequence.  
Powered Variable Volume Exhaust-VFD  
Controlled  
Shutdown  
When this purge sequence is selected and activated,  
the supply and exhaust fans are controlled OFF and  
the Outside Air damper is overridden closed. This idle  
state is maintained until the purge input is deactivated  
and the unit returns to normal operation.  
This optional variable volume powered exhaust system  
consist of an Exhaust Fan driven by a Variable Fre-  
quency Drive (VFD), which is controlled by the  
OptiLogiccontroller. The OptiLogiccontroller moni-  
tors the pressure within the building. As the pressure  
rises, the VFD is controlled to increase Exhaust Fan  
speed. As the pressure falls, the VFD is controlled to  
decrease Exhaust Fan speed. The Building Pressure  
Setpoint is user selectable from the OptiLogicUser  
Interface.  
Pressurization  
When this purge sequence is selected and activated,  
the exhaust fan is controlled OFF and the Supply Fan  
is controlled ON. The Outside Air damper is opened  
full and the Return Air Damper is closed full. If the unit  
is a VAV unit, the VAV boxes are also driven full open to  
prevent duct over-pressurization. This mode is main-  
tained until the smoke purge input is deactivated and  
the unit returns to normal operation.  
LOW AMBIENT OPERATION  
The OptiLogiccontroller continuously monitors the  
outside air temperature to determine if mechanical cool-  
ing should be allowed. As a safety, if the Outside Air  
temperature falls to or below the Low Ambient Lockout  
temperature, mechanical cooling is prevented from op-  
erating. For units with economizers, the Low Ambient  
Lockout temperature is typically low enough that me-  
chanical cooling will rarely be required. However, for  
some applications mechanical cooling is required when  
the Outside Air temperature is lower than the Low Am-  
bient Lockout temperature.  
Exhaust  
When this purge sequence is selected and activated,  
the Supply Fan is controlled OFF and the Exhaust Fan  
is controlled ON (Exhaust Damper driven full open).  
This mode is maintained until the smoke purge input is  
deactivated and the unit returns to normal operation.  
YORK INTERNATIONAL  
28  
FORM 100.50-EG1  
Purge  
When a Cooling Stage 1 call (Y1) is received, and the  
unit is equipped with an economizer, the OptiLogic™  
controller will check the Outside Air conditions to de-  
termine if conditions are suitable for economizing and  
modulate the outside air damper and or stage up com-  
pressors as required to maintain the VAV High Supply  
Air Temperature Setpoint. This setpoint is user select-  
able at the OptiLogicUser Interface. The OptiLogic™  
controller will control to this setpoint as long as Cooling  
Stage 1 (Y1) remains active.  
When this purge sequence is selected and activated,  
the Supply Fan is controlled ON and the Exhaust Fan  
is controlled ON. The Outside Air damper is opened  
full and the Return Air damper is closed full. If the unit  
is a VAV unit, the VAV boxes are also driven full open to  
prevent duct over-pressurization. This mode is main-  
tained until the smoke purge input is deactivated and  
the unit returns to normal operation.  
Purge With Duct Pressure Control (VAV Only)  
When a Cooling Stage 2 call (Y2) is received, and the  
unit is equipped with an economizer, the OptiLogic™  
controller will check the Outside Air conditions to de-  
termine if conditions are suitable for economizing and  
modulate the outside air damper and or stage up com-  
pressors as required to maintain the VAV Low Supply  
Air Temperature Setpoint. This setpoint is user select-  
able at the OptiLogicUser Interface. The OptiLogic™  
controller will control to this setpoint as long as Cooling  
Stage 2 (Y2) remains active.  
When this purge sequence is selected and activated,  
the Supply Fan is cycled ON and controlled to maintain  
the duct static pressure setpoint. The Exhaust Fan is  
also controlled ON (Exhaust Damper driven full open)  
and the Outside Air Damper is driven full open. This  
mode is maintained until the smoke purge input is de-  
activated and the unit returns to normal operation.  
VAV SPECIFIC SEQUENCES  
Supply fan operation  
The VAV High SAT Setpoint is always greater than the  
VAV Low SAT Setpoint and because of this essentially  
makes this control sequence a Supply Air Tempera-  
ture Reset algorithm based on Zone Temperature.  
For VAV units, the supply fan is controlled ON and OFF  
based on the occupancy state or the G input from a  
Thermostat (Unit must be configured for Thermostat  
operation to respond to the G input). When the unit  
goes into the Occupied mode of operation (or Gis  
called) the Supply Fan will be controlled ON. The  
OptiLogiccontroller will monitor the static pressure  
within the supply duct system and control the speed of  
the supply fan to maintain a specified Duct Static Pres-  
sure setpoint. A Variable Frequency Drive (VFD) is used  
on all VAV units to vary the speed of the supply fan.  
Note, the use of a VFD in lieu of inlet guide vanes pro-  
vides for higher energy efficiency for the unit by elimi-  
nating the losses (air pressure drop) typical of inlet guide  
vane systems.  
Zone Sensor Control  
When a VAV unit is configured for Zone Sensor opera-  
tion, the OptiLogiccontroller will monitor a reference  
Zone Temperature and command the Supply Fan to  
start when the unit goes into the Occupied mode.  
If the zone temperature is above the VAV Setpoint for  
SAT Reset, the OptiLogiccontroller will modulate the  
outside air damper (Economizer available and condi-  
tions suitable) and/or stage compressors up and down,  
as required, to maintain the VAV High Supply Air Tem-  
perature Setpoint.  
If the zone temperature is below or falls below the VAV  
Setpoint for SAT Reset, the OptiLogiccontroller will  
modulate the Outside Air Damper (Economizer avail-  
able and conditions suitable) and/or stage compres-  
sors up and down, as required, to maintain the VAV  
Low Supply Air Temperature Setpoint.  
COOLING OPERATION  
Thermostat Control  
When a VAV unit is configured for thermostat opera-  
tion, the OptiLogiccontroller will command the Sup-  
ply Fan to start when the unit goes into the Occupied  
mode or a thermostat Gsignal is received by the con-  
trol. With no thermostat calls for cooling, the unit shall  
remain idle with the Supply Fan operating as required.  
As with thermostat operation, this sequence is also a  
Supply Air Temperature Reset algorithm based on Zone  
Temperature.  
YORK INTERNATIONAL  
29  
Controls (continued)  
Stand Alone Control  
SAT setpoint. If conditions are not suitable for econo-  
mizing or not equipped with an economizer, the control  
will stage up 50% of the compressors. This shall be  
maintained until Stage 1 is deactivated or Stage 2 is  
called.  
If the unit is not configured for Thermostat or Zone Sen-  
sor operation, the unit will operate in Stand Alone Mode.  
In Stand Alone Mode, the OptiLogicController will  
monitor only the Occupied/Unoccupied state. When the  
unit is commanded into the Occupied Mode of opera-  
tion, the OptiLogicController will start the Supply Fan.  
If the unit is equipped with an Economizer, the Control-  
ler will check to see if Outside Air conditions are suit-  
able for Economizing. The controller will then use Out-  
side Air (when available and suitable) and/or stage com-  
pressors up and down, as required, to maintain the VAV  
Low SAT Setpoint.  
Stage 2 (Y2) Call  
If Y2 is called and the unit is equipped with an econo-  
mizer, the control will check to see if the Outside Air is  
suitable for economizing. If conditions are suitable for  
economizing, the control will control the economizer and  
stage up compressors, as required, to maintain a LOW  
SAT setpoint. If conditions are not suitable for econo-  
mizing or not equipped with an economizer, the control  
will stage up 100% of the compressors. This shall be  
maintained until Stage 2 is deactivated.  
CV SPECIFIC SEQUENCES  
Zone Sensor Control  
Cooling Operation  
Thermostat Control  
If a zone sensor controls the unit, the OptiLogiccon-  
troller shall maintain all zone temperature setpoints.  
These setpoints are user selectable at the OptiLogic™  
User Interface.  
If a 7-wire thermostat (2 Cool/2Heat) controls the unit,  
all zone temperature setpoint control is maintained at  
the thermostat. With this operation, the unit remains  
idle until it receives a stage call from the Thermostat. If  
Gis called from the thermostat, the Supply Fan will  
start and all occupied functions (if equipped), i.e. venti-  
lation, economizer, etc. will be allowed to operate.  
When a zone sensor is used for control, the OptiLogic™  
unit controller will monitor the temperature within the  
space and control the unit accordingly. A closed-loop  
staging algorithm is used to stage compressors up and  
down as required to maintain the desired zone tempera-  
ture setpoint. If the unit is equipped with an economizer,  
Outside Air conditions are continuously monitored by the  
control to determine if conditions are suitable for econo-  
mizing. If conditions are suitable for economizing, the  
OptiLogiccontroller will modulate the Outside Air  
damper in addition to staging compressors up and down  
to maintain the zone temperature setpoint.  
Stage 1 (Y1) Call  
If Y1 is called and the unit is equipped with an econo-  
mizer, the control will check to see if the Outside Air is  
suitable for economizing. If conditions are suitable for  
economizing, the control will control the economizer and  
stage up compressors, as required, to maintain a high  
YORK INTERNATIONAL  
30  
FORM 100.50-EG1  
Power Wiring  
SINGLE-POINT POWER SUPPLY WIRING  
Electrical / Controls Box  
Power Side  
Control Side  
TB1  
Wiring Terminal  
Block  
LD06414  
Line 1  
Line 2  
Line 3  
Field Power  
Supply  
Earth  
Ground  
NOTES:  
1. All field wiring must be provided through a field-supplied fused disconnect switch to the unit terminals (or optional molded  
disconnect switch).  
2. All electrical wiring must be made in accordance with all N.E.C. and/or local code requirements.  
3. Minimum Circuit Ampacity (MCA) is based on U.L. Standard 1995, Section 36.14 (N.E.C. Section 440.34).  
4. Maximum Dual Element Fuse size is based on U.L. Standard 1995, Section 36.15 (N.E.C. Section 440.22)  
5. Use copper conductors only.  
6. On units with an optional disconnect switch, the supplied disconnect switch is a Disconnecting Meansas defined in the N.E.C. Section  
100, and is intended for isolating the unit from the available power supply to perform maintenance and troubleshooting. This disconnect  
switch is not intended to be a Load Break Device.  
FIG. 2 SINGLE-POINT POWER SUPPLY WIRING  
YORK INTERNATIONAL  
31  
Power Wiring (continued)  
SINGLE-POINT POWER SUPPLY WIRING  
WITH NON-FUSED DISCONNECT  
Electrical / Controls Box  
Power Side  
Control Side  
Molded  
Case  
Disconnect  
Switch  
Wiring Terminal  
Block  
LD06415  
Line 1  
Line 2  
Line 3  
Field Power  
Supply  
Earth  
Ground  
NOTES:  
1. All field wiring must be provided through a field-supplied fused disconnect switch to the unit terminals (or optional molded  
disconnect switch).  
2. All electrical wiring must be made in accordance with all N.E.C. and/or local code requirements.  
3. Minimum Circuit Ampacity (MCA) is based on U.L. Standard 1995, Section 36.14 (N.E.C. Section 440.34).  
4. Maximum Dual Element Fuse size is based on U.L. Standard 1995, Section 36.15 (N.E.C. Section 440.22)  
5. Use copper conductors only.  
6. On units with an optional disconnect switch, the supplied disconnect switch is a Disconnecting Meansas defined in the N.E.C. Section  
100, and is intended for isolating the unit from the available power supply to perform maintenance and troubleshooting. This disconnect  
switch is not intended to be a Load Break Device.  
FIG. 3 SINGLE-POINT POWER SUPPLY WIRING WITH NON-FUSED DISCONNECT  
YORK INTERNATIONAL  
32  
FORM 100.50-EG1  
DUAL-POINT POWER SUPPLY WIRING  
Electrical / Controls Box  
Power Side  
Control Side  
TB2  
TB1  
Wiring Terminal  
Block  
LD06416  
Line 1  
Line 2  
Line 3  
Field Power  
Supply #2  
Earth  
Ground  
Line 1  
Line 2  
Line 3  
Field Power  
Supply #1  
Earth  
Ground  
NOTES:  
1. All field wiring must be provided through a field-supplied fused disconnect switch to the unit terminals (or optional molded  
disconnect switch).  
2. All electrical wiring must be made in accordance with all N.E.C. and/or local code requirements.  
3. Minimum Circuit Ampacity (MCA) is based on U.L. Standard 1995, Section 36.14 (N.E.C. Section 440.34).  
4. Maximum Dual Element Fuse size is based on U.L. Standard 1995, Section 36.15 (N.E.C. Section 440.22)  
5. Use copper conductors only.  
6. On units with an optional disconnect switch, the supplied disconnect switch is a Disconnecting Meansas defined in the N.E.C. Section  
100, and is intended for isolating the unit from the available power supply to perform maintenance and troubleshooting. This disconnect  
switch is not intended to be a Load Break Device.  
FIG. 4 DUAL-POINT POWER SUPPLY WIRING  
YORK INTERNATIONAL  
33  
Field Control Wiring  
Wiring Notes:  
1. Wiring shown indicates typical wiring.  
2. All wiring is Class 2, low voltage.  
3. Maximum power available from the 24 VAC  
terminal is 40 VA.  
4. Use shielded wire where shown.  
1
2
3
4
5
6
7
8
9 10 11 12  
14 15 16 17 18 19 20 21  
13  
7 Wire Thermostat  
COMMON  
R (24VAC)  
Y1 (Cool Stage 1)  
Y2 (Cool Stage 2)  
G (Fan)  
Space Sensor  
* Use Shielded Wire  
* Use Shielded Wire  
1K Nickel  
Signal  
Common  
RTD Sensor  
Signal  
1.5K Adjust  
Common  
Potentiometer  
CO2 Sensor  
* Use Shielded Wire  
Signal  
0-5V Output  
Common  
Note, 24VAC switch voltage must be  
sourced from the unit. Use of another  
power source external of the unit may  
cause equipment damage.  
Closed = Occupied  
Open = Unoccupied  
Occupied /  
Unoccupied Input  
Closed = Shutdown  
Open = Normal  
Shutdown Input  
Closed = Smoke Purge  
Open = Normal  
Smoke Purge Input  
24 VAC Signal  
VAV Heat  
Relay Output  
Common  
Note: VAV Heat Relay  
output shall be used to  
command the VAV boxes  
to open full.  
LD06158  
FIG. 5 FIELD CONTROL WIRING  
YORK INTERNATIONAL  
34  
GeneralArrangementDrawing  
TOP VIEW  
SUPPLY OPENING  
RETURN OPENING  
53"  
106-7/16"  
40"  
5-3/4"  
SECTION DESCRIPTIONS  
31-7/8"  
36-7/8"  
35-3/4"  
EE = Economizer  
FE = Fan Exhaust  
MB = Mixing Box  
CONTROL PANEL DETAIL  
_F = Filter Segment  
CC = Cooling Coils  
FS = Supply Fan  
DP = Discharge Plenum  
CO = Condenser Section  
CP = Control Panel  
I R  
A
F
L
OW  
10'  
CP  
CO  
72"  
FRONT  
72"  
SIDE  
72"  
REAR  
72"  
SIDE  
1-1/2" FPT  
FRONT VIEW  
16-1/16"  
REAR VIEW  
COUPLING  
DRAIN CONN.  
179"  
SIDE VIEW  
(LEFT SIDE)  
(LEFT SIDE)  
7-3/16"  
24-5/16"  
236-1/16"  
95-1/4"  
(SEE NOTE 6)  
344"  
92-3/16"  
1-9/16"  
140-3/4"  
379-9/16"  
NOTES:  
1. 10' CLEARANCE MINIMAL OVER THE TOP OF THE CONDENSING UNIT.  
2. ONLY ONE ADJACENT WALL CAN EXCEED UNIT HEIGHT.  
3. 12' CLEARANCE REQUIRED TO ADJACENT UNITS.  
4. 8' SERVICE ACCESS RECOMMENDED ON ONE SIDE.  
5. ECONOMIZER AND EXHAUST HOODS, WHERE APPLICABLE, ARE FOLDED  
INSIDE UNIT FOR SHIPMENT.  
6. DIM. IS TO OUTSIDE OF LIFTING LUGS  
FIG. 6 GENERAL ARRANGEMENT DRAWING  
LD06417  
GeneralArrangementDrawing  
NOTES:  
1. 10' CLEARANCE MINIMAL OVER THE TOP OF THE CONDENSING UNIT.  
2. ONLY ONE ADJACENT WALL CAN EXCEED UNIT HEIGHT.  
3. 12' CLEARANCE REQUIRED TO ADJACENT UNITS.  
4. 8' SERVICE ACCESS RECOMMENDED ON ONE SIDE.  
5. ECONOMIZER AND EXHAUST HOODS, WHERE APPLICABLE, ARE FOLDED  
INSIDE UNIT FOR SHIPMENT.  
TOP VIEW  
53"  
31-7/8"  
36-7/8"  
CONTROL PANEL DETAIL  
SECTION DESCRIPTIONS  
EE = Economizer  
FE = Fan Exhaust  
MB = Mixing Box  
_F = Filter Segment  
CC = Cooling Coils  
FS = Supply Fan  
DP = Discharge Plenum  
CO = Condenser Section  
CP = Control Panel  
SUPPLY  
OPENING  
I
A
RETURN  
OPENING  
C
(continued)  
FRONT VIEW  
EE  
FE  
16-1/16"  
24-5/16"  
95-1/4"  
(SEE NOTE 6)  
117-7/16"  
28-1/2"  
140-3/4"  
REAR VIEW  
79-1/8"  
SIDE VIEW  
(LEFT SIDE)  
6-1/2"  
LD06418  
FIG. 7 GENERAL ARRANGEMENT DRAWING  
CurbLayoutDrawing  
87"  
RETURN  
237"  
339"  
35-3/4"  
71-3/5"  
52"  
Y
SUPPL  
53-3/4"  
40"  
NOTES:  
1. CURB, NAILER & GASKET ONLY, FURNISHED BY YORK. ALL  
OTHER PARTS ARE FURNISHED AND INSTALLED "BY OTHERS".  
2. ROOF CURB SHIPPED IN PIECES FOR FIELD ASSEMBLY.  
3. ROOF CURB MUST BE INSTALLED SQUARE AND LEVEL.  
4. CURB MATERIAL IS 14 GAUGE GALVANIZED, NOT PAINTED.  
5. CURB INSULATED WITH 1.5"-3# INSULATION.  
LD06419  
FIG. 8 CURB LAYOUT DRAWING  
Guide Specifications  
GENERAL  
doors shall be a minimum of 18 gauge on the exterior  
surfaces, and 20 gauge on the interior. Interior floor  
panels shall be 18 gauge.  
Units shall be designed for outdoor rooftop installation  
on a roof curb. Units shall be rated according to ARI  
360. Units shall be shipped in a single package, fully  
charged with HFC-407C refrigerant. The manufactur-  
ing facility shall be registered under ISO 9001 Quality  
Standards for Manufacturing. All units shall be com-  
pletely factory assembled and run tested.  
All serviceable sections shall have hinged access doors  
with latches on both sides of the unit. All access doors  
shall be constructed of 20-gauge steel on the outside,  
with 24 gauge on the inside. Each door shall seal against  
PVC gaskets to prevent air and water leakage.  
Units shall be ETL listed and be tested according to UL  
1995. Tags and decals to aid in the service or indicate  
caution areas shall be provided. Installation, operation  
and maintenance manuals shall be supplied with each  
unit.  
The roof shall be double wall, with 18 gauge on the  
external surface and 24 gauge on the interior. The roof  
shall be formed with a 45 degree drip lipoverhanging  
the side walls to prevent precipitation drainage from  
streaming down the side of the unit. Roof sections shall  
be connected together via integral channels fastened  
with screws and sealed with gasketing. Each fastened  
seam shall be further protected by a sheet metal chan-  
nel covering the full length of the gasket surface, mak-  
ing a completely water tight seal.  
Units shall be capable of providing mechanical cooling  
down to 45° F (0°F with a low ambient kit). Unit shall be  
capable of starting and running at 120° F. Unit electric  
and gas connections shall be either through the curb or  
the side of the unit.  
SUPPLY AIR SYSTEM  
Supply Air Fan  
CONSTRUCTION  
Base  
Fans shall be centrifugal type, statically and dynami-  
cally balanced in the factory. Fan wheels shall be de-  
signed for continuous operation at the maximum rate  
of fan speed and motor HP. Fans shall be double-width,  
double-inlet with forward curved blades.  
The base rail shall be constructed of 12 gauge galva-  
nized steel, extending the full perimeter of the unit. All  
components shall be supported from the base, and the  
base shall include integral lifting lugs. The unit base  
rail shall overhang the roof curb for water runoff and  
shall have a fabricated recess with a continuous flat  
surface to seat on the roof curb gasket, providing a  
positive, weather tight seal between the unit and the  
curb.  
The fan and motor assembly shall be mounted on a  
common base to allow consistent belt tension with no  
relative motion between the fan and motor shafts. The  
entire assembly shall be isolated from the unit base  
with 1" deflection springs. The fan discharge shall be  
connected to the cabinet through a reinforced neoprene  
flexible connection to eliminate vibration transmission  
from the fan to the unit casing.  
Casing  
The unit cabinet shall be double wall construction to  
provide both maximum resistance to bacterial growth  
in the air stream and superior structural integrity. All  
sheet metal shall be G90 mill galvanized sheet metal,  
formed and reinforced to provide a rigid assembly. Cabi-  
net shall be coated with baked on powder paint which,  
when subject to ASTM B117, 500 hour, 5% salt spray  
test, yields minimum ASTM 1654 rating of 6. The unit  
shall be insulated with 1-1/2,1 pound fiberglass insu-  
lation between the two sheet metal skins. Insulation shall  
meet NFPA-90A regulations for smoke and flame  
spread ratings. Single-wall units, or foil-faced insula-  
tion in the air stream shall be not acceptable.  
BEARINGS AND DRIVES  
Bearings shall be self-aligning pillow-block re-greasable  
ball bearings with an average life expectancy L10 of  
40,000 hours. Grease fittings shall be accessible  
through access doors.  
Fan motors shall be NEMA designed, Standard effi-  
ciency ball bearing type with electrical characteristics  
and horsepower as specified. Motors shall be 1750  
RPM, open drip proof type. The motor shall be located  
within the unit on an adjustable, heavy steel base.  
The cabinet corner post and the intermediate side sup-  
ports shall be a minimum of 16-gauge steel. All access  
YORK INTERNATIONAL  
38  
FORM 100.50-EG1  
densate drain opening shall be flush with the bottom of  
the drain pan to allow complete drainage. Coils in ex-  
cess of 48high shall have an intermediate drain pan,  
extending the entire width of the coil to provide better  
water drainage.  
All fan motor drives shall be selected for a minimum  
service factor of 1.2 and have fixed pitched sheaves.  
AIR FILTERING SYSTEM  
All filter holding frames shall be of heavy-duty construc-  
tion designed for industrial applications. All filters shall  
be either side accessible via access doors on both sides  
of the filter section.  
Compressors  
Compressors shall be hermetic, scroll-type, including  
tip seals to provide efficient axial sealing while prevent-  
ing scroll tip to base contact, controlled orbit design for  
radial sealing to incorporate minimum flank-to-flank con-  
tact for long service life, refrigerant cooled motors, large  
suction side free volume and oil sump to provide liquid  
handling capability, annular discharge check valve and  
reverse vent assembly to provide low pressure drop,  
silent shutdown and reverse rotation protection, initial  
oil charge, oil level sight glass, vibration isolator mounts  
for compressors, and brazed-type connections for fully  
hermetic refrigerant circuits.  
All filter media shall be Class II listed under UL Stan-  
dard 900. Filter efficiencies shall be rated in accordance  
with ASHRAE Standard 52-76  
Two-inch throwaway filters in an angled filter rack shall  
be standard. On units with rigid filters, two-inch prefilters  
shall be installed upstream of the rigid filters.  
AIR INLET SYSTEM  
General  
Condenser Coils  
Condenser coils shall have 3/8seamless copper tubes,  
arranged in staggered rows, mechanically expanded into  
aluminum fins. Coils shall be protected from hail dam-  
age with a Vconfiguration, with individual flat coils ro-  
tated from the vertical plane for each condensing circuit.  
A factory installed outside air rain hood permanently  
attached to the cabinet to prevent windblown precipita-  
tion from entering the unit shall cover inlet openings.  
The rain hoods on the sides of the unit shall be rotated  
into the cabinet and secured for shipment so that upon  
installation they need only be rotated upwards and  
screwed into place. The outside air hood shall contain  
a removable and cleanable filter.  
Condenser Fans and Motors  
Condenser fans shall be direct drive, propeller type,  
discharging vertically. Condenser fan motors shall be  
3-phase, totally enclosed air over (TEAO). Thermal  
overload protection shall be provided for each con-  
denser fan motor.  
All damper assemblies shall be of low leak design.  
Damper blades shall be fabricated from a minimum of  
16 gauge galvanized steel.  
Refrigerant Piping  
REFRIGERATION SYSTEM  
All interconnecting piping between refrigeration com-  
ponents shall be copper tubing with brazed joints.  
Units shall have four compressors for maximum load-  
matching capability. Each refrigerant circuit shall be  
controlled with a thermal expansion valve for maximum  
control at low load conditions.  
Each refrigerant circuit shall be equipped with liquid line  
filter drier, and moisture indicating sight glass. Each  
circuit shall also have both high and low pressure  
switches installed on either side of the compressor and  
include access fittings for replacement of the pressure  
switches without removing charge.  
Evaporator Coils  
Evaporator coils shall be direct expansion. Coil tubes  
shall be 3/8OD copper, with internally enhanced tubes.  
Fins shall be enhanced aluminum mechanically ex-  
panded to bond with the copper tubes. Coil casing shall  
be fabricated from heavy gauge galvanized steel.  
Polyurethane sleeves shall protect all small diameter  
distributor tubing to the evaporator coil to prevent the  
tubes from copper-to-copper contact during shipment  
or operation.  
A stainless steel double-sloped drain pan shall be pro-  
vided under the entire width of the evaporator coil, in-  
cluding all return bends. The main drain pan shall be  
sloped a total of 1/4per foot towards the drainage point  
according to ASHRAE 62 guidelines. Main drain pan  
shall be accessible and cleanable in the field. The con-  
POWER SUPPLY  
Unit power supply shall be 460V 3-phase 60Hz (208,  
230 and 575V optional) single-point power connections  
with terminal block connections.  
YORK INTERNATIONAL  
39  
Guide Specifications (continued)  
CONTROLS  
ACCESSORIES AND OPTIONS  
A factory-mounted unit controller with a 4x20 character  
alphanumeric display and user keypad shall be included  
as standard. The controller and keypad shall be housed  
inside the low-voltage compartment of the control/power  
panel. On units with supply or exhaust VFDs, the VFD  
keypads shall be located inside the same panel as the  
unit controller and interface keypad. Control operating  
data, setpoints, unit setup, configuration, service and  
history shall all be accessible via a single key. A sys-  
tem alarm LED shall indicate failures to the operator  
with more detail provide in the menu screens. The user  
interface shall function with a simple menu-driven dis-  
play for easy access to unit data with integral time clock  
for weekly and holiday scheduling. The unit keypad  
shall include password protection to prevent unautho-  
rized access and tampering with unit setpoints and con-  
figuration.  
Full perimeter and partial perimeter roof curbs - 14”  
high roof curb with wood nailer. Roof curb covers the  
entire perimeter of the unit (full curb) or that portion of  
the unit that has airflow (partial curb).  
Supply Fan VFD Manual Bypass provides full air-  
flow in the event of a VFD failure.  
Power Supply Connections single-point power with  
manual disconnect, and dual-point power wiring options  
are available for various applications.  
Supply air setpoint reset by outside air or space air  
temperature - Allows VAV supply air setpoint to float  
upward (saving energy) if the outdoor air temperature  
or the space temperature is sufficiently low.  
A single terminal strip shall be provided for all thermo-  
stat and customer hard-wired field connections.  
Supply Fan Isolation the entire supply fan assem-  
bly shall be isolated from the unit base with 2" deflec-  
tion springs.  
Unit controls shall be completely factory packaged and  
compatible with a room thermostat. Constant volume  
units shall operate with a two (2) cool/two (2) heat ther-  
mostat. Staging decisions shall be based upon the de-  
viation of space temperature from set point and the rate  
of change of the space temperature.  
Supply and Exhaust Fan Motors high efficiency  
ODP, and standard and high efficiency TEFC motors  
are available all meeting the Energy Policy Act of 1992  
(EPACT).  
VAV units shall operate with a sensor in the supply air  
stream for cooling operation. Staging decisions shall  
be based upon the deviation of supply air temperature  
from set point and the rate of change of the supply air  
temperature.  
Low Ambient Operation a low ambient kit is avail-  
able to control compressor head pressure via VFD con-  
denser fan speed control. Head pressure control is  
accomplished by monitoring head pressure with suc-  
tion and discharge line pressure transducers rather than  
less accurate temperature control.  
Controllers shall have the following safeties (both VAV  
and CV):  
ECONOMIZERS  
High and low pressure cut-outs (one each refriger-  
ant circuit)  
Minimum on time for compressors  
Manual Damper Economizer economizer is avail-  
able with a manual damper adjustable between 0-25  
percent.  
Delay between compressor stages  
Anti-short cycle delays (minimum off time) for com-  
pressors and supply fan  
Two-Position Damper Economizer economizer is  
available with a two-position damper with the open po-  
sition adjustable between 0-25 percent. The operation  
of the two-position economizer shall be based on oc-  
cupancy; occupied is open, unoccupied is closed.  
Cooling lockout at 40° F; 0° F if equipped for low  
ambient operation  
Air flow proving switch requiring proper air flow for  
cooling operation  
YORK INTERNATIONAL  
40  
FORM 100.50-EG1  
Modulating Damper Economizer economizer is  
available with a modulating damper arrangements.  
Modulating damper economizers shall have outdoor air  
and return air dampers that are interlocked and posi-  
tioned by fully modulating, solid state damper actua-  
tors. The actuators shall be spring loaded so that the  
outside air damper will close when power to the unit is  
interrupted. The operation of the modulating economizer  
shall be fully integrated into the cooling control system.  
The modulating economizer control shall be via a dry  
bulb sensor, single or dual enthalpy sensors.  
EVAPORATOR COIL PROTECTION  
Copper Fins provided in lieu of aluminum fins.  
Pre-Coated Fins an epoxy-coated aluminum fin stock  
to guard from corrosive agents and insulate against gal-  
vanic potential. Used for mild seashore or industrial  
locations.  
CONDENSER COIL PROTECTION  
Copper Fins provided in lieu of aluminum fins.  
Airflow Measurement airflow measurement is avail-  
able for the Modulating Damper Economizer option  
listed above. Three options exist for airflow measure-  
ment; minimum airflow and 100% air flow. Minimum  
airflow measures airflow between 0 and the minimum  
ventilation airflow up to 25% outside air. 100% airflow  
measurement measures air flow from 0-100% of the  
outside airflow.  
Pre-Coated Fins an epoxy-coated aluminum fin stock  
to guard from corrosive agents and insulate against gal-  
vanic potential. Used for mild seashore or industrial  
locations.  
Post-Coated Fins Technicoat coil-coating process  
used on condenser coils for seashore and other corro-  
sive applications (with the exception of strong alkalis,  
oxidizers, wet bromide, chlorine and fluorine in concen-  
trations greater than 100ppm).  
RELIEF SYSTEM  
Barometric Relief - building air exhaust shall be ac-  
complished through barometric relief dampers installed  
in the return air plenum. The dampers will open relative  
to the building pressure.  
Hot Gas Bypass (Optional on Constant Volume;  
Standard on VAV) permits continuous, stable opera-  
tion at capacities below the minimum step of unloading  
by introducing an artificial load on the evaporator.  
Exhaust Air Fans - two (2) forward curved centrifugal  
fans shall be installed in the return air plenum for posi-  
tive power exhaust. Fan impellers shall be on a com-  
mon shaft, driven by a single motor. The fans, motors  
and drives shall be of the same quality and design as  
specified for the supply air fan, except the fans shall be  
Class I. Exhaust control options are on/off, modulating  
discharge damper, or VFD fan speed control. On units  
with non-modulating exhaust a barometric relief damper  
is included to prevent outside air from entering in the  
off cycle. Fans shall cycle on and off with building pres-  
sure. On units with modulating exhaust and two posi-  
tion control based on building pressure, a field-installed  
static pressure sensor mounted in the conditioned  
space or return air duct is required for damper and VFD  
modulation.  
BACNet Communications Card for BAS commu-  
nications, a BACNet card is available with Ethernet  
connection.  
Compressor Sound Blankets compressor acoustic  
sound blankets for sound sensitive applications.  
CO2 Sensors carbon dioxide sensors for occupied  
space that operate demand ventilation control opening  
outside air dampers to ventilate building.  
Suction and Discharge Pressure Transducers moni-  
tor and readout of suction and discharge pressures.  
YORK INTERNATIONAL  
41  
NOTES  
YORK INTERNATIONAL  
42  
FORM 100.50-EG1  
NOTES  
YORK INTERNATIONAL  
43  
Proud Sponsor  
of the 2002  
U.S. Olympic Team  
36USC380  
Tele. 800-861-1001  
P.O. Box 1592, York, Pennsylvania USA 17405-1592  
Copyright © by York International Corporation 2001  
Subject to change without notice. Printed in USA  
ALL RIGHTS RESERVED  
Form 100.50-EG1 (201)  
New Release  

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