maverick ii commercial packaged rooftop...

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Catalog 250-8Maverick™ IICommercial Packaged Rooftop Systems

Heating & CoolingModels MPS 015F–017F, 020G–026G and 030F–050F15 to 75 TonsR-410A Refrigerant

2 Daikin CAT 250-8

Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3

The HVAC Solution for Low Rise Buildings . . . . . . . 3

MPS 015–050 Features and Options . . . . . . . . . . . . 4

MPS 015–050 Units with Energy Recovery Wheel Features and Options . . . . . . . . . . . . . . . . . . . . . . . . 6

MPS 062–075 Features and Options . . . . . . . . . . . . 8

Features and Benefits . . . . . . . . . . . . . . . . . . . . . . . . 10

Why Choose Daikin Rooftop Systems? . . . . . . . . . . . .10

Unit Construction . . . . . . . . . . . . . . . . . . . . . . . . . . . 11

MicroTech III Unit Controls . . . . . . . . . . . . . . . . . . . . 15

Superior Performance and Easy Integration . . . . . . 15

Application Considerations . . . . . . . . . . . . . . . . . . . 21

General Rooftop Applications . . . . . . . . . . . . . . . . . 21

Unit Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26

Achieving Optimal Performance . . . . . . . . . . . . . . . 26

Physical Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28

Unit Capacity and Physical Data . . . . . . . . . . . . . . . 28

Performance Data . . . . . . . . . . . . . . . . . . . . . . . . . . . 32

Cooling Capacity . . . . . . . . . . . . . . . . . . . . . . . . . . . 32

MPS 015 to 062 Ton ARI Correction Multipliers . . . 38

Electric Heating Capacity . . . . . . . . . . . . . . . . . . . . 38

Hot Water Heating Capacity . . . . . . . . . . . . . . . . . . 38

Gas Heating Capacity . . . . . . . . . . . . . . . . . . . . . . . 39

Pressure Drops . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

Hot Water Low/High Heat Curves . . . . . . . . . . . . . . 42

Hot Water Pressure Drop Curves . . . . . . . . . . . . . . 47

Supply Fan Performance . . . . . . . . . . . . . . . . . . . . . 49

Exhaust Fan Performance . . . . . . . . . . . . . . . . . . . . 54

Exhaust Fan Performance . . . . . . . . . . . . . . . . . . . . 55

Dimensional Data . . . . . . . . . . . . . . . . . . . . . . . . . . . 56

MPS 015–020 Unit Dimensions . . . . . . . . . . . . . . . 56

MPS 015–020 Roof Curb Dimensions . . . . . . . . . . 59

MPS 015–020 with Energy Recovery Wheel Unit Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . 60

MPS 015–020 Units with Energy Recovery Wheel Roof Curb Dimensions . . . . . . . . . . . . . . . . . . . . . . 62



MPS 026–035 with Energy Recovery Wheel Unit Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . 67




MPS 040–050 Units with Energy Recovery Wheel Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76


MPS 062 Unit and Curb Dimensions . . . . . . . . . . . 79

MPS 070–075 Unit and Curb Dimensions . . . . . . . 80

MPS 062–075 Additional Curb Dimensions . . . . . . 81

MPS 062–075 Section Dimensions . . . . . . . . . . . . 82

MPS 062–075 Knockout Dimensions . . . . . . . . . . 84

Weight Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85

MPS 015–050 Unit and Curb Weights . . . . . . . . . . 85

MPS 015–050 Weight Distribution Percentage . . . 86

MPS 062–075 Unit Weights . . . . . . . . . . . . . . . . . . 87

6-Row Coil and HGRH Coil Weights . . . . . . . . . . . 87

Fan Motor Weights . . . . . . . . . . . . . . . . . . . . . . . . . 87

Roof Curb Weights . . . . . . . . . . . . . . . . . . . . . . . . . 87

Electrical Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88

Power Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88

Engineering Guide Specification . . . . . . . . . . . . . . 92

Part 1: General . . . . . . . . . . . . . . . . . . . . . . . . . . . . 92

Part 2: Products . . . . . . . . . . . . . . . . . . . . . . . . . . . 92

Introduction
Introduction
The HVAC Solution for Low Rise Buildings• Non-ozone depleting R-410A refrigerant.

• Variable air volume (VAV) or constant volume (CV)operation.

• EER meets ASHRAE 90.1 2010 (except the 75 ton unit).

• Durable, double wall construction with access doors on bothsides.

• Gas heat option with staged or modulating control.

• Economizer with 80% to 100% exhaust.

• Building pressure control with a VFD.

• Factory integrated and commissioned MicroTech® III DDCcontrol system.

• Daikin's Open ChoicesTM feature provides building automation system integration using BACnet® MS/TP, BACnet IP, or LonTalk® communication protocol options.

• Hinged access doors on both sides of the unit.

• Stainless steel sloped drain pan.

• 2" prefilters with option for 4" secondary filter on sizes 15–50, and 12" secondary filters on sizes 62–75.

• Airfoil fans provide non-overloading operation, better fanefficiency, and less noise.

• Energy recovery wheel with unitary construction and single-point power connection.

Agency Listed

Nomenclature (MPS 015–050)

Nomenclature (MPS 062–075)

MEA265-07-E

M P S – 015 – F G

Daikin Packaged System

Heat mediumY = None (cooling only)G = Natural gasE = Electric heatW = Hot water heat

Nominal capacity (tons) Design vintageF - 15, 17, 30, 35, 40, 50G - 20, 26

M P S – 062 – F L A

Daikin Packaged System

Heat mediumY = None (cooling only) A = Natural gasE = Electric heat W = Hot water

Design vintage

Nominal capacity (tons)Cooling coil sizeL = Large face area S = Small face area

Daikin CAT 250-8 3

Introduction

MPS 015–050 Features and Options

Hinged access doors• On both sides of unit of every

section for easy access to allcomponents

• Easy open quarter-turn latches

• Double-wall constructionprotects insulation duringmaintenance

Stainless steel, double-sloped drain pan

• Prevents corrosion

• Avoids standing water for highIAQ

Airfoil plenum fan• Energy efficient and quiet

• 1" seismic spring isolators forsuperior vibration control

• Class II construction

• Premium efficiency motor isstandard

Low leak outside air dampers • 4 cfm/ft2 to meet ASHRAE

Standard 90.1-2010

• Double-wall blades

• Blade edge and jamb seals

Exhaust fans with building pressure control

• Provide better buildingenvelope airflow controlwhich increasesbuilding operationefficiency

2"/4" combination filter rack• Provides more flexibility to meet

building filtration requirements

• 2" MERV 7 filters shipped with unit,owner preference thereafter

Economizer • DCV control for efficient VAV

operation

• CO2 control for building IAQ

MicroTech® III unit controller• Open Choices™ feature provides

interoperability with BACnet or LonMarkcommunications for easy integration intoyour building automation system of choice

• Outdoor air and humidity control logicmaintains minimum fresh air intake andoptimum humidity levels

4 Daikin CAT 250-8

Introduction

R-410A refrigerant• No ozone depletion potential or

phase-out date

• Greater than 10.0 EER, meetsASHRAE 90.1-2010 energy requirements

• Dual refrigerant circuits provideredundancy for high unit reliability

Scroll compressors• Provide maximum dependability,

efficiency, and quiet operation

• 2-5 stages of capacity control forefficient DAT control

Microchannel condenser coils

• Proven technologyfrom the automotive industry

• Suited for R-410A highoperating pressures

• All aluminum designfor minimal corrosion between fins, tubes, and header

Gas heat• Tubular heat exchanger for

maximum heat transfer

• Four-stage capacity control

• Optional 4-to-1 modulationcontrol on low heat

• Optional 8-to-1 modulationcontrol on high heat

Durable construction• Pre-painted exterior cabinet panels pass 750-hour

ASTM B 117 Salt Spray Test for durability

• Weather-resistant construction with capped seamsand sloped top panels

• Double-wall construction protects R-4 insulationand provides wipe-clean surface

Optional electric heat• 4-stage control

• Operational safeties

• High-limit temperature switch

• Single point power

Optional hot water heat• Low and high capacity options

• DDC control ready with 0–10volt wiring harness

• Vestibule for field installedcontrol valve package

Daikin CAT 250-8 5

6 Daikin CAT 250-8

Introduction

MPS 015–050 Units with Energy Recovery Wheel Features and Options

Hinged access doors

• On both sides of unit for easyaccess to all components

• Easy open, quarter-turn latches


2" Combination filter rack

• Provides more flexibility to meetbuilding filtration requirements

• 2" MERV 7 filters shipped withunit, owner preference at building occupancy


• Provide better buildingoperations, highercustomer satisfaction

MicroTech® III unit controller• Open Choices™ feature provides

interoperability with BACnet orLonWorks communications for easyintegration into your buildingautomation system of choice

• Outdoor air and humidity controllogic maintains minimum fresh airintake and optimum humidity levels

Optional energy recovery wheel

• Meets ASHRAE Standard90.1-2010

• Factory installed


• 2" MERV 7 filters to minimizewheel cleaning andmaintenance

Durable construction

• Pre-painted exterior cabinet panelspass 750-hour ASTM B 117 SaltSpray Test for durability

• Double-wall construction protectsinsulation and provides wipe-cleansurface

Daikin CAT 250-8 7

Introduction

R-410A refrigerant

• No ozone depletionpotential or phase-outdate

• EER per ASHRAE 90.12010

• Dual refrigerant circuitsprovide redundancy forhigh unit reliability

Scroll compressors

• Provide maximum dependability,efficiency andquiet operation


• Proven technology from the automotiveindustry

• Suited for R-410A

• All aluminum design

• Minimal corrosion between fins, tubes andheader

• LEED® credit for enhanced refrigerationmanagement

Gas heat

• Tubular heat exchanger

• Aluminized steel or optionalstainless steel tubes

• Staged or modulating control– 4:1 on low heat– 8:1 on high heat

Optional electric heat

• 4-stage control



• Single point power connection


• DDC control ready with 0–10volt wiring harness for watercontrol valve

• Vestibule for field installedcontrol valve package

Airfoil plenum fan

• Energy efficient and quiet

• 1" seismic spring isolators for superiorvibration control

• Premium efficiency motor is standard

• Vibration transmissibility of less than 5%

Introduction

MPS 062–075 Features and Options

Hinged access doors• On both sides of unit of every

section for easy access to allcomponents

• Easy open, single point latch


Stainless steel, double-sloped drain pan

• Prevents corrosion

• Avoids standing water for highIAQ

Airfoil plenum fan (DWDI shown)

• Energy efficient and quiet

• 2" seismic spring isolators forsuperior vibration control

• Class II construction

• Premium efficiency motor isstandard

Low leak outside air dampers

• Double-wall blades

• Blade edge and jamb seals


• Provide better buildingenvelope airflow controlwhich increases buildingoperation efficiency

Cartridge filters with prefilters• 2", 30% MERV 7 angular (shown)

• 6", 60% MERV 11

• 12", 90% MERV 14

Economizer • DCV control for efficient VAV

operation

MicroTech III™ unit controller• Open Choices™ feature provides

interoperability with BACnet orLonMark communications for easyintegration into your buildingautomation system of choice

• Outdoor air and humidity control logicmaintains minimum fresh air intakeand optimum humidity levels

8 Daikin CAT 250-8

Introduction

R-410A refrigerant• No ozone depletion potential or phase-out date

• Meets ASHRAE 90.1-2010 energyrequirements (except the 75)

• Dual refrigerant circuits provide redundancy forhigh unit reliability

Scroll compressors• Provide maximum dependability,

efficiency, and quiet operation

• 4-6 stages of capacity control forefficient DAT control

• Discharge unit liquid lineisolation valves standard


• Proven technologyfrom the automotiveindustry

• Suited for R-410A highoperating pressures

• All aluminum design

• Minimal corrosionbetween fins, tubes,and header

Gas heat• Drum and tube heat exchanger

for maximum heat transfer

• 3-to-1 modulation control onlow heat

• Stainless steel heat exchanger

Durable construction• Pre-painted exterior cabinet panels pass 750-hour

ASTM B 117 Salt Spray Test for durability

• Weather-resistant construction with capped seamsand sloped top panels

• Double-wall construction protects R-6.5 insulationand provides wipe-clean surface

Optional electric heat• DDC with 4-stage control





Daikin CAT 250-8 9

Features and Benefits
Why Choose Daikin Rooftop Systems?

Maverick II rooftop systems are the HVAC solution for low rise building projects. Available with cooling capacities from 15 to 75 tons and energy efficiencies of 10.0 EER and higher.

Maverick II systems are built to perform, with features and options that provide for lower installed costs, high energy efficiency, good indoor air quality, quiet operation, low cost maintenance and service, and longevity. Completed systems are factory tested and shipped with a cETLus Safety Listing.

High Efficiencies and Competitively Priced

Daikin offers a complete line of R-410A rooftop systems that meet the efficiencies of ASHRAE 90.1.

Daikin R-410A rooftop systems use all-aluminum, microchannel condenser coils, which help reduce galvanic corrosion, making them more resistant to corrosion in any environment. However, if the unit is located in a corrosive environment, such as near the sea coast or industrial fumes, then optional coated condenser coils are required.

Figure 1: Microchannel Condenser Coils

Easy, Low Cost Installation, Maintenanceand Service

Maverick II units arrive at the job site as a complete package, including fully tested controls. This eliminates the need for expensive field assembly, refrigerant piping, and control installation. Hinged access doors on both sides of the unit put all components within easy reach for maintenance and service personnel. This promotes regular maintenance for peak system performance.

MicroTech III controls are easily accessed for equipment diagnostics and adjustments via a keypad/display on the unit. Our Open Choices feature provides interoperability with building automation systems (BAS), including those using the BACnet and LonTalk communication protocols. The result is easy access to all unit operating data from a central control station.

Figure 2: MPS 015–050 Example

Flat aluminum tubes with many small flow channels increase fluid-to-tube heat transfer and reduce refrigerant charge requirements.

Aluminum fins brazed between adjoining tubes

protect the fins from surface damage, which can inhibit cooling

10 Daikin CAT 250-8


Unit Construction• Nominal unit cooling capacities from 15 to 75 tons.

• Pre-painted exterior surfaces that withstand a minimum 750hour salt spray test per ASTM B117.

• Double-wall hinged access doors on both sides of the unit.

• Heavy-gauge, galvanized steel unit base with a formedrecess to seat on roof curb gasket and provide positiveweather-tight seal.

• Rigging brackets integral to the unit base.

• Double-wall construction to protect the insulation, enhanceperformance, and satisfy IAQ requirements.

• Fully insulated base and condenser fans.

Controls• Integrated advanced MicroTech III DDC controls with unit-

mounted interface featuring a 4-line, 20-character English display for fast equipment diagnostics and adjustments, providing the best possible comfort to the space while saving energy and money.

• Controls factory installed and commissioned prior toshipment for fast start-up.

• Open Choices feature allows interoperability with a BAS,including those using BACnet and LonTalk communication protocols for integrating into Building Automation Services.

Figure 3: MicroTech III Unit Controller

Variable Air Volume Control• Factory mounted energy saving variable frequency drive

(VFD) fan speed control.

• All VFDs are factory installed and tested.

• To manage building static pressure, the exhaust fans have anoption for being controlled by a VFD.

• MicroTech III controls provide advanced duct and buildingstatic pressure control and equipment diagnostics capability.

Figure 4: Variable Frequency Drives

Electrical• Units are completely wired and tested at the factory to

provide faster commissioning and start-up.

• Wiring complies with NEC requirements and all applicableUL standards.

• All units have a minimum short circuit current rating of10,000 amps.

• For ease of use, wiring and electrical components arenumber coded and labeled according to the electrical diagram.

• Units have a 115 V GFI convenience receptacle. Theindependent power supply for the receptacle is field supplied.

• An optional unit powered 20 amp 115 V conveniencereceptacle, complete with factory mounted transformer, disconnect switch, and primary and secondary overload protection, eliminates the need to pull a separate 115 V power source.

• Supply air fan, compressor, and condenser fan motorsbranch circuits have individual short circuit protection.

• A single point power connection with power block isstandard.

• The optional unit-mounted disconnect includes a servicehandle on the exterior of the unit.

• Electrical power feeds inside the perimeter roof curbthrough factory provided knockouts located in the bottom of the main control panel.

Daikin CAT 250-8 11


Figure 5: Control Panel Section (MPS 015–050)

Supply Fan Section• Airfoil blade fans provide superior energy performance and

quiet operation.

• Class II construction.

• Concentric locking bearing.

• Minimum, standard 1" seismic spring isolation reducesnoise transmission into the space.

• Each fan assembly is dynamically trimmed balanced at thefactory.

Figure 6: Fan Section (MPS 015–050)

• A neoprene gasket isolates the fan housing and eliminatesvibration transmission to the fan bulkhead.

• Solid steel fan shafts rotate in 200,000 hour regreasablepillow block ball bearings, providing years of reliableoperation.

• All fan and motor assemblies are isolated from the main uniton 1" deflection spring mounts (2" deflection on 62–75 tonunits).

• All fan drives have fixed pitch sheaves as standard.

Gas Heat Option• Natural gas heating is provided with modular heat

exchangers.

• Optional stainless steel heat exchanger (standard on 62–75ton units) and optional modulating gas heat with turndowns as high as 8:1, save energy and supply greater comfort to the space.

• All gas burners exceed ASHRAE Standard 90.1 efficiencyrequirement of 78% for low fire and 80% for high fire.

• Gas burners are UL listed with the complete furnaceassembly cETLus listed.

• All burner assemblies are factory tested and adjusted prior toshipment.

Figure 7: Gas Heat Section (MPS 015–050)

Figure 8: Gas Heat (MPS 062–075)

12 Daikin CAT 250-8


• 15–50 ton unit heat exchangers are air induced draft tubulardesign with in-shot burner manifolds.

• Low heat option has one module with two stages of heat-ing capacity.

• High heat option has two modules with four stages ofheating capacity control.

• 62–75 ton unit heat exchangers are a forced draft drum andtube design.

• Fuel lines may be conveniently routed through the curb orthe burner vestibule.

• Heating control is fully integrated into the unit's MicroTechIII control system.

• Optional field installed LP kits are available for stagedheating control only.

Energy Recovery Wheel• Optional energy recovery wheel for increase efficiency for

conditioning minimum outdoor air.

• Unitary design for installation/rigging cost savings.

• Single point power connection for decreased installationcost

• Slide-out wheel cassette & track for easy maintenance andcleaning.

• Bypass dampers for increased efficiency during economizeroperation.

• Integrated unit control for control coordination betweenrooftop unit and wheel that controls the wheel speed.

• Leaving wheel temperature sensors for wheel operationmonitoring.

• Integrated unit control with optimum leaving wheeltemperature control to prevent over-heating the outdoor air.

• Defrost options including ON/OFF control, Start/Stop andVFD speed modulation.

Electric Heat Option• Low, medium, and high kW furnace options for matching

the requirements of any project.

• 4 stages of DDC control.

• Single point power connection eliminates the need to pullmultiple power connections.

• Operational safeties.

• High-limit temperature switch.

• Individual coil fusing.

Figure 9: Electric Heat Section

Hot Water Heat Option• 1 and 2-row, low and high output options.

• Fully cased coil.

• Factory installed coil vent and drain.

• Piping vestibule for field installed piping control package.

• DDC control ready with 0–10 volt wiring harness.

• Optional valve package on size 62–75.

Modulating Hot Gas Reheat Option• All aluminum coil construction eliminates corrosion and

provides better heat transfer.

• Controls leaving air temperature and leaving air dew point.

• Low volume microchannel coil eliminates the need forrefrigerant receivers

• By over-cooling the conditioned air, excessive humidity isreduced to prevent mold growth and sick building syndrome

• Modulating control provides precise temperature reheatcontrol to keep conditioned space better satisfied

Outside Air Options

Maverick II units are available with a 0% to 30% outdoor air damper or a 0% to 100% economizer.

0% to 30% Outside Air Option

• Includes return air plenum and 0% to 30% outside air intakehood with motorized dampers to minimize leakage duringoff cycles.

• Damper is field adjusted to a fixed open position that iseasily set using the MicroTech III keypad, allowing for abalance between IAQ and energy savings.

Daikin CAT 250-8 13


0% to 100% Economizer Option

• A fully functional modulating economizer takes advantageof free cooling days.

• Includes return air plenum with back or bottom opening,exhaust air relief dampers and low leak economizer dampersto minimize leakage during off cycles.

• Economizer control is fully integrated into the unit'sMicroTech III control system and features spring-returnactuator, adjustable minimum outside air set point andadjustable changeover.

• Dry bulb economizer changeover control is standard.Optional comparative enthalpy control provides the mosteconomical amount of outside air for “free” cooling.

• Barometric relief dampers are standard for exhaust control.

0% to 100% Outdoor Air (OA) Option

• Unit can be equipped with a 100% OA damper.

• Damper is fully modulating for field adjustment to requiredair flow at the installation site.

• Damper is actuated to minimize leakage during off cycles.

Prop Exhaust Fans

• MicroTech III controls provide staged capacity control asstandard.

• MicroTech III controls can provide an optional VFD controlfor building static pressure control. The building pressuretransducer is included in the control panel.

• Building static pressure control is important in minimizingexfiltration, energy consumption, and preventing moldgrowth.

Condensing Section• Open design permits unrestricted condenser airflow, access

to compressors, and refrigeration components and piping.

• Condenser coil hail protection is integral with the design.

• High efficiency scroll compressors.

Figure 10: Condensing Section (MPS 015–050)

• Each refrigerant circuit is furnished with an accessiblesightglass, filter drier, high pressure switch, low pressureswitch, and expansion valve.

• All units feature dual refrigeration circuits for redundancyand efficient capacity control.

• Vertical air discharge minimizes condenser fan noise.

• Three-phase condenser fan motors eliminate reverse rotationfailures.

• A vandal protection screen is standard on 15–50 ton unitsand optional on 62–75 ton units.

Cooling Coil/Drain Pan Section• Evaporator coils with enhanced copper tubing and

aluminum fins, provide high efficiencies at full and part loadoperating conditions.

• All evaporator coils feature interlaced circuiting to keep thefull face of the coil active and eliminate air temperaturestratification, allowing the cooling coil maximum humiditycontrol.

• Construction will include stainless steel drain pans toeliminate corrosion.

• Drain pan is sloped 1/8"/ft per the requirements ofASHRAE, eliminating standing water and preventingbacteria growth.

Filter Section• Combination 2" – 4" filter tracks are provided for 15–50 ton

units. Single or combination tracks may be used for thebuilding's filtration needs.

• 62–75 ton units are available with 2", 30% MERV 6 angularfilters, 6", 60% MERV 11 cartridge filters, or 12", 90%MERV 14 filters. MERV 11 and MERV 14 filters alsoinclude MERV 6 prefilters.

• Multiple access doors allow easy filter changes from eitherside of the unit.

Roof Curbs• Constructed in accordance with NRCA guidelines with 12-

gauge galvanized steel.

• Fits inside the unit base. 15–50 ton units use a full perimetercurb. 62–75 ton units use an air handler curb with an islandrail for the condensing unit.

• Gasket seals between the curb and the unit.

14 Daikin CAT 250-8

MicroTech III Unit Controls
Superior Performance and Easy Integration

Each Maverick II rooftop unit is equipped with a complete MicroTech III unit control system that is pre-engineered and factory tested prior to shipment. Its features include:

• Stable, efficient temperature and static pressure control.

• Comprehensive diagnostics.

• Alarm monitoring.

• Alarm-specific component shutdown if critical equipmentconditions occur.

The MicroTech III control system comes standard with a user interface, providing system operators with superior access to temperatures, pressures, operating states, alarm messages, control parameters, and schedules. All messages display in English text. Password protection is included to protect against unauthorized or accidental set point or parameter changes.

MicroTech III control system components include:

• DDC controller with keypad/display user interface.

• Ductwork or building pressure transducers.

• Unit-mounted temperature sensors.

• Field installed zone temperature sensor packages.

• Enthalpy sensors/controllers.

• Field installed CO2 sensors.

Open Choices™ Feature

MicroTech III unit control systems are factory configured for either stand-alone operation or for incorporation into an independent building automation systems (BAS) through Daikin's Open Choices feature. This feature provides building automation system integration using BACnet MS/TP, BACnet IP, or LonTalk communication protocol options.

BACnet communications conform to the BACnet Standard, ANSI/ASHRAE Standard 135-2004, and are supported by a protocol implementation conformance statement (PICS).

LonTalk communications are in accordance with either the Discharge Air Controller (DAC) or Space Comfort Controller (SCC) profiles and are LONMARK 3.4 certified.

The building automation system can interact with one or more rooftop unit controllers in any of the following ways:

• Sets the unit’s operating and occupancy modes.

• Monitors all controller inputs, outputs, set points,parameters, and alarms.

• Sets controller set points and parameters.

• Clears alarms.

• Resets the cooling discharge air temperature set points (VAVunits).

• Resets the duct static pressure set point (VAV units).

• Sets the heat/cool changeover temperature.

• Sets the representative zone temperature (CAV-ZTC units).

DDC Unit Controller

The DDC controller contains a microprocessor that is preprogrammed with the software necessary to control the unit. This can keep schedules, set points and parameters from being lost, even during a 48-hour power outage. The microprocessor board processes system input data and then determines and controls output responses.

Daikin CAT 250-8 15


Communication Modules

Field installed communication modules provide the means to configure MicroTech III unit controls for interoperability with an independent BAS using Daikin's innovative Open Choices feature. Communication modules are available to support BACnet MS/TP, BACnet/IP, LONMARK AND DAIKIN DIII communication protocols.

Figure 11: VRV/DOAS System

Keypad/Display

The keypad/display provides a user interface with the main controller and has easy-to-use keys and control knob used for navigation and entering changes. The display is a 4-line by 20-character format with clear English display messages. All operating conditions, system alarms, control parameters and schedules can be monitored from the keypad/display. If the correct password has been entered, any adjustable parameter or schedule can be modified from the keypad.

Figure 12: Keypad/Display Interface

DIII-Net Gateway

Maverick™ II DOAS

DIII-Net Integration Points Occupancy (Start/Stop) Alarm Notification DAT - Setpoint DAT - Measured Fan speed Adjust Set DIII-Net Address

Daikin Intelligent Touch Controller

DOAS with DIII Communications

DIII Expansion Module

Outdoor VRV

DIII Communications

RS 232 Communications

Indoor VRV Units

Up to 64 with Room Controllers Up to 10

DIII Communications

Indoor VRV Units

Up to 64 with Room Controllers Up to 10

The Daikin MPS can be directly connected to a Daikin, VRV, DIII network. A DIII gateway communication card is shipped loose for field installation on the MicroTech® III board.

Outdoor VRV

VRV System

New Factory Mounted Hardware

16 Daikin CAT 250-8


Unit Sensors

Temperature and Enthalpy Sensors

The return, discharge, and outside air temperature sensors are factory installed. The zone temperature sensor package can be ordered as a field installed option.

Zone Temperature Sensors

Two optional zone temperature sensors are available:

1 Zone sensor with tenant override.

2 Zone sensor with tenant override and remote set point adjustment.

Timed tenant override is a standard MicroTech III control feature.

Zone sensors are required for the controller's space reset of supply air set point and night setback features. All zone sensors are field installed with field wiring terminated at the unit controller.

The optional comparative enthalpy control economizer package is provided with the enthalpy sensor for the return air and outside air factory installed.

Static Pressure Transducers

When the Daikin Packaged System is ordered with the VAV option, the duct static pressure transducer is factory installed as standard. The units can also have an exhaust fan option. The exhaust fans on VAV units are controlled by the building static pressure control package. The exhaust fans on CAV units are controlled by either the building static pressure control package as mentioned above, or they are controlled by the DDC program based on the outside air damper position. The static pressure transducers are factory installed when building static pressure control is ordered. The installation and routing of the field-supplied sampling tubes is done at the time of the unit installation.

Stand-Alone Controller Features

MicroTech III rooftop unit controls include all of the essential features required to make them capable of independent and stand-alone operation.

Auto/Manual Operation Selection

Automatic or manual operation can be controlled at the keypad. The keypad provides a variety of occupancy and auto/manual control mode selections available to the operator:

Cooling and Heating Lockout Control

All unit controls include separate keypad-programmable set points for locking out mechanical cooling and heating. Mechanical cooling is locked out when the outdoor temperature is below the cooling lockout set point. Heating is locked out when the outdoor temperature is above the heating lockout set point. This feature can save energy cost by eliminating unnecessary heating and cooling during periods when the outdoor air temperature is mild.

Night/Unoccupied Setback

When one of the zone temperature sensors is connected to the unit controller, night setback heating control and night setback cooling control are available. Separate, keypad-programmable, night heating and night cooling set points are used to start the unit when necessary. After the unit starts, night setback control is similar to normal occupied control except that the minimum outside air damper position is set to zero. If the outside air is suitable for free cooling, it is used during night setback operation.

Internal Time Clock

An internal time clock is included in the MicroTech III unit controller. Current date and time can be quickly and easily set at the user interface keypad.

Internal Schedule

Seven daily schedules and holiday schedules can be entered at the keypad of all unit controllers. For each of these eight schedules, one start and one stop time can be entered. Up to 16 holiday periods of any duration can be designated. The unit will automatically run according to the holiday schedule on the holiday dates.

In lieu of its internal schedule, the unit can be operated according to a network schedule from a BAS.

External Time Clock or Tenant Override Input

An input is supplied that can be used to accept a field wired start/stop signal from a remote source. An external time clock, a tenant override switch, or both may be connected. Whenever the external circuit is closed, the controller overrides the internal schedule (if activated) and places the unit into the occupied mode.

If the internal schedule or a BAS network schedule is used, field wiring is not required.

Occupancy Modes Control Modes

Auto Off ManualOccupied Auto or Heat/Cool

Unoccupied Cool Only

Bypass (tenant override)Heat Only

Fan Only

Daikin CAT 250-8 17


Timed Tenant Override

Off-hour operation flexibility is a must in today's office environments and the stand-alone MicroTech III controls handle it with ease. When unit operation is desired during unoccupied hours the tenant override button on either of the optional zone sensor packages is pressed to initiate the override operation. The unit then starts and runs in the occupied mode for a keypad-adjustable length of time (up to five hours). If the button is pressed again while the unit is operating, the timer resets to the full time allowance without interrupting unit operation. Tenant override operation can also be initiated by a BAS.

Remote Set Point Adjustment Options

All constant air volume-zone temperature control (CAV-ZTC) unit controllers include an input that can be used to remotely adjust the zone cooling and heating set points. To use this feature, wire the optional zone sensor package with set point adjustment to the controller. The remote set point adjustment feature can be enabled or disabled from the keypad at any time. When enabled, the remote set point adjustment is available even if the return temperature is selected to be the control temperature.

The building automation system (BAS) can also remotely adjust the unit's setpoints.

Standard Control Options

MicroTech controls offer two basic control configurations; (1) variable air volume with discharge temperature control (VAV-DTC) or (2) constant air volume with zone temperature control (CAV-ZTC).

All control configurations use sophisticated state change control logic to provide stable, reliable and efficient control. When combined with MicroTech's many available control capabilities–both factory installed and keypad programmable–these basic configurations can be customized to meet the requirements of the most demanding applications.

Configuration 1: Variable Air Volume with Discharge Temperature Control (VAV-DTC)

MicroTech VAV-DTC controls provide discharge air temperature control along with duct static pressure control. The operator can enter the desired cooling set point and VAV parameters at the keypad.

Configuration 2: Constant Air Volume with Zone Temperature Control (CAV-ZTC)

MicroTech CAV-ZTC controls provide the sophisticated and flexible zone temperature control that is only possible with DDC systems. Zone temperature sensors are available with or without a remote set point adjustment. With the remote adjustment model, the space set point can be set at the keypad or at the zone sensor package. (Even if a zone sensor is connected, remote set point adjustment can be enabled or disabled as desired at the keypad.)

Control Temperature

The Control Temperature for VAV-DTC or CAV-ZTC determines whether the unit supplies heating, cooling, or neither. It also determines the amount of heating or cooling required to satisfy the load. Its source can be selected at the keypad from among the following selections:

• Zone temperature sensor.

• Return temperature sensor.

Supply Air Reset

By automatically varying the discharge air temperature to suit a building's cooling or heating needs, supply air temperature reset can increase the energy efficiency of VAV systems. MicroTech controllers offer a variety of different reset strategies that can be selected at the keypad. Because they are keypad-programmable, reset strategies can be changed or eliminated as desired. Separate strategies can be selected for both cooling and heating. If reset is not desired, a fixed discharge cooling or heating set point can be entered.

The following reset methods are available:

• Space temperature.

• Return temperature.

• Outdoor air temperature.

• Supply airflow (VAV, cooling set point only).

• External 0–10 V (dc) or 0–20 mA signal.

• Network communication.

For all temperature reset methods, the minimum and maximum cooling and heating set points are keypad programmable along with the corresponding minimum and maximum space, return or outdoor air temperature parameters. For the supply airflow method, the discharge set point will be reset as the supply fan modulates between 30% (adjustable) and 100% (adjustable). For the external method, the discharge set point will be reset as the voltage or current signal varies over its entire range. For units in a BAS network, the discharge set points are reset via the communication signal.

Compressor Control

Compressor Staging

Compressor staging is controlled directly by the control temperature. When the control temperature is warmer than the cooling set point, cooling is staged up; when the control temperature is cooler than the cooling set point, cooling is staged down. However, a stage change can only occur when the control temperature is outside the dead band. Staging is constrained by an inter-stage delay timer (five minute default setting) and minimum and maximum discharge air temperature limits (all keypad programmable). These constraints protect the compressors from short cycling while eliminating temperature variations near the diffusers.

18 Daikin CAT 250-8


Project Ahead Algorithm

Because of the inherent thermal inertia in a building, zone temperature control applications can cause overshoot during warm-up or cool-down periods, MicroTech features a “Project Ahead” control algorithm. “Project Ahead” calculates the rate at which the control temperature is changing and reduces the unit's cooling or heating output as the zone temperature nears its set point, essentially eliminating overshoot.

Energy Recovery Control

The energy recovery wheel option has integrated control with the units DDC controller. Temperature sensors are mounted at the wheel to coordinate its operation with the rooftop unit. The outdoor air temperature, leaving wheel temperature, return air temperature, and exhaust air temperature are connected to the rooftop unit controller. These temperatures are also available as BACnet variables for the BAS integration option. The operational performance of the wheel and unit is maximized with this integrated control. The benefit of the integrated control is that it will montior the leaving wheel temperature and prevent the wheel operation from overheating the outdoor air, which will force the building into the cooling mode of operation and consume more energy.

Frost control can be provided by a number of options. The standard offering for frost protection is to stop the wheel when a frost condition is encountered. The second option is to have the start-stop-jog control to prevent the wheel from reaching a frost condition. The third option for frost control is VFD proportional control. The speed of the wheel is varied to prevent the wheel from entering a frost condition. This option maximizes the amount of energy savings and also prevents the frost condition.

Supply Fan Control

Duct Static Pressure Control

On all VAV-DTC units, duct static pressure control is maintained by a control algorithm which provides precise control of the supply fan variable frequency drive. The keypad programmable set point can be set between 0.20" wc and 2.00" wc.

Economizer Control

Economizer Changeover Selection

On units equipped with an economizer, there are two methods of determining whether the outdoor air is suitable for free cooling.

• The standard offering uses an internal dry bulb changeoverstrategy: the unit controller compares the outdoor air dry-bulb temperature to a keypad-programmable set point.

• The optional second method is a comparative enthalpycontrol. It uses a solid state device that compares the outdoor

air ambient enthalpy to the return air enthalpy. When the outdoor air enthalpy is lower than the return air enthalpy, the unit will change to economizer operation.

Minimum Ventilation Air Volume Control

Consistently maintaining the minimum outdoor air requirements of ASHRAE Standard 62 has been a long-standing control challenge for VAV systems. As supply air fan volumes were reduced, the volume of air introduced through a fixed-position, minimum outdoor air damper was also reduced, compromising indoor air quality. To meet this challenge, MicroTech controls feature user-selected control methods for maintaining outdoor air volume.

MicroTech controls have a keypad-selected control function that automatically adjusts outdoor air damper position in response to changes in supply air fan volume. Regardless of supply air volume, this strategy maintains a nearly constant outdoor air volume at all times.

The outdoor air damper position can also be controlled by the following:

• The MicroTech controller can accept an external 0–10 V(dc) or a 0–20 mA signal from a control device or from a CO2 sensor.

• The MicroTech controller can accept a BAS network signalfor the minimum position.

• A fixed minimum damper position can be keypadprogrammed. This selection may be acceptable when ventilation requirements are met through other sources.

During cold ambient conditions where the mixed air temperature of the minimum outdoor air and the return air can become too low, MicroTech controls maintain the minimum discharge temperature set point by controlling the unit's heating system.

Exhaust Fan Control

Building Static Pressure Control

Any constant or variable air volume Maverick unit with an optional variable volume exhaust fan can be provided with direct building static pressure control capability. The building static pressure is measured and processed by the unit DDC controller. The controller provides precise control of the exhaust fan's variable speed drive to maintain the space pressure set point. The range of the keypad-programmable set point is between –0.25 and +0.25" wc.

Field Output Signals

All MicroTech controls include two solid-state relay outputs that are available for field connection to any suitable device: a remote alarm output and a fan operation output. These outputs are used to signal field equipment of unit status.

Daikin CAT 250-8 19


Remote Alarm Output

The remote alarm output can be used to operate a 24 V relay to provide a remote alarm signal to a light, audible alarm, or other device when an alarm condition exists at the unit.

Fan Operation Output

The fan operation output is used to operate a 24 V relay to control field equipment that depends on fan operation, such as field-installed isolation dampers or VAV boxes. To allow actuators enough time to stroke, the fan operation output is energized three minutes before the fan starts. It then remains energized until thirty seconds after the unit airflow switch senses no airflow. The fan operation output is on whenever the unit airflow switch senses airflow.

Alarm Management and Control

MicroTech unit controllers are capable of sophisticated alarm management and controlled response functions. Each alarm is prioritized, indicated, and responded to with the appropriate action. The current alarm (up to four alarms, arranged by alarm priority), each with a time and date stamp, can be displayed at the user interface.

Alarm Priority

The various alarms that can occur are prioritized according to the severity of the problem. Three alarm categories are used: (1) Faults, (2) Problems, and (3) Warnings.

1 Faults are the highest priority alarms. If a fault condition occurs, the complete unit is shut down until the alarm

condition is gone and the fault is manually cleared at the keypad. A fault example is a “Fan Fail” alarm.

2 Problems are the next lower priority to faults. If a problem occurs, the complete unit does not shut down, but its operation is modified to compensate for the alarm condition. A problem automatically clears when the alarm condition that caused it is gone. “Lo Pres-Ckt1” is an example of a problem where only the affected compressor is shut down.

3 Warnings are the lowest priority alarms. No control action is taken when a warning occurs; it is simply indicated to alert the operator that the alarm condition needs attention. To remind the operator to read warnings, they must be manually cleared. “Dirty Filter” indication is an example of a warning.

Table 1: MicroTech Alarm Summary

Alarm name Fault Problem Warning

Emergency Off XControl T Fail XDisch Sensor XDuct Hi Limit X

Hi Return Tmp XHi Disch Tmp XLo Disch Tmp X

Fan Fail XOAT Sensor X

Space Sensor XReturn Sensor XHi Pres-Ckt1 XHi Pres-Ckt2 XLo Pres-Ckt1 XLo Pres-Ckt2 X

Dirty Filter X

20 Daikin CAT 250-8

Application Considerations
General Rooftop Applications

Units are intended for use in normal heating, ventilating, and air conditioning applications. Consult your local Daikin sales representative for applications involving operation at high ambient temperatures, high altitudes, non-cataloged voltages, and for job specific unit selections that fall outside of the range of the catalog tables.

For proper operation, units should be rigged in accordance with instructions stated in IM 842. Fire dampers, if required, must be installed in the ductwork according to local or state codes. No space is allowed for these dampers in the unit. Follow factory check, test and start procedures explicitly to achieve satisfactory start-up and operation (see IM 842).

Most rooftop applications take advantage of the significant energy savings provided with economizer operation. When an economizer system is used, mechanical refrigeration is typically not required below an ambient temperature of 50°F. Standard MPS refrigeration systems are designed to operate in ambient temperatures down to 20°F for 15–50 ton units or 45°F for 62–75 ton units.

Unit Location

The structural engineer must verify that the roof has adequate strength and ability to minimize deflection. Take extreme caution when using a wooden roof structure.

Unit condenser coils should be located to avoid contact with any heated exhaust air.. If the unit is located in a corrosive environment, such as near the sea coast or industrial fumes, then, optional coated condenser coils are required.

Allow sufficient space around the unit for maintenance/service clearance. Refer to Figure 13 for recommended clearances. Consult your Daikin sales representative if available clearances do not meet minimum recommendations. Where code considerations, such as the NEC, require extended clearances, they take precedence.

Service Clearance

Allow recommended service clearances as shown in Figure 13. Provide a roof walkway along the sides of the unit for service and access to controls and components. Contact your Daikin sales representative for service requirements less than those recommended.

Figure 13: MPS 015–075 Service Clearances (030 Shown)

Daikin CAT 250-8 21


Curb Installation

The roof curb is field assembled and must be installed level (within 1/16" per foot side to side). A sub-base has to be constructed by the contractor in applications involving pitched roofs. Gaskets are furnished and must be installed between the unit and curb. For proper installation, follow NRCA guidelines. Typical curb installation is illustrated in Figure 52, page 66 and Figure 61, page 75. In applications requiring post and rail installation, an I-beam securely mounted on multiple posts should support the unit on each side. In addition the insulation on the underside of the unit should also be protected from the elements.

Applications in geographic areas subjected to seismic or hurricane conditions must meet code requirements for fastening the unit to the curb and the curb to the building structure.

Acoustical Considerations

Good acoustical design is critical for any installation and should start at the earliest stages in the design process. Common sound paths for rooftop equipment must be addressed are:

• Radiated sound through the bottom of the unit (air handlingsection and condensing section) and into the space.

• Radiated sound to the property line.

• Structure-borne vibration from the unit to the building.

• Airborne sound through the supply air duct.

• Airborne sound through the return air duct.

Locating rooftop equipment away from sound sensitive areas is critical and the most cost effective means of avoiding sound problems. If possible, rooftop equipment should always be located over less sensitive areas such as corridors, toilet facilities or auxiliary spaces and away from office areas, conference rooms and classrooms.

Some basic guidelines for good acoustical performance are:

• Provide proper structural support under all areas of the unit.

• Always locate the unit's center of gravity close to a mainsupport to minimize roof deflection.

• Use a concrete deck or pad when a unit has to be locatedover an occupied space where good acoustics are essential.

• Only the supply and return air ducts should penetrate theacoustical material and decking within the curb perimeter,and the openings must be sealed once the duct is installed.

• Don't overlook the return air path. Never leave a clear “lineof sight” into a return or exhaust fan; always include someduct work (acoustically lined tee) at the return inlet.

• Place an acoustical material in the area directly beneath thecondensing section.

• Select acoustical material that discourages microbial growth.

• Minimize system static pressure losses to reduce fan soundgeneration.

• Design duct systems to minimize turbulence.

• Account for low frequency duct breakout in system design.Route the first 20 ft. of rectangular duct over non-sensitiveareas and avoid large duct aspect ratios. Consider round oroval duct to reduce breakout.

There are many sound sources in rooftop systems. Fans, compressors, condenser fans, duct take-offs, etc., all generate sound. For guidelines on reducing sound generation in the duct system, refer to the ASHRAE Applications Handbook.

Contact your local Daikin sales representative for equipment supply, return and radiated sound power data specific to your application.

Ductwork Considerations

A well-designed duct system is required to allow the rooftop equipment to provide rated performance and to minimize system resistance and sound generation. Duct connections to and from units should allow straight, smooth airflow transitions. Avoid any abrupt change in duct size and sharp turns in the fan discharge. Avoid turns opposed to wheel rotation since they generate air turbulence and result in unwanted sound. If 90° turns are necessary, use turning vanes. Refer to the ASHRAE Applications Handbook for specific guidelines relevant to rooftop equipment.

Return Duct

The return path is the most often overlooked. A section of return duct is required to avoid a “line of sight” to the return air opening and to provide attenuation of return air sound. Install an insulated tee with a maximum duct velocity of 1000 to 1200 feet per minute. Extend the duct 15 feet to provide adequate attenuation.

Supply Duct

Insulate supply air ductwork for at least the first 20 feet from the unit. Consider the use of round or oval ductwork, as it significantly reduces low frequency breakout noise near the equipment. If rectangular duct is used, keep the aspect ratio of the duct as low as possible. The large flat surfaces associated with high aspect ratios increase low frequency breakout to the space and can generate noise, such as “oil canning.” The maximum recommended supply duct velocity is 1800 to 2000 feet per minute.

Duct High Limit

A Daikin Packaged System with VAV control includes a duct high limit switch as a standard feature that is of particular importance when fast acting, normally closed boxes are used.

Vibration Isolation

Make duct attachments to the unit with a flexible connection.

22 Daikin CAT 250-8


Economizer and Exhaust Fan Application

Rooftop economizer applications usually require exhaust fans to properly control building pressure and maintain minimum ventilation.

The air balancer must adjust the outdoor air damper to provide minimum ventilation settings.

The EAF is normally off during non-economizer operation. During these minimum outdoor air conditions, the system essentially acts like a supply fan only system.

Smoke and Fire Protection

Due to the wide variation in building design and ambient operating conditions into which our units are applied, we do not represent or warrant that our products are fit and sufficient for smoke, fume, and fire control purposes. The owner and a fully qualified building designer are responsible for meeting all local and NFPA building code requirements with respect to smoke, fume, and fire control.

The unit's control panel has a terminal block that a supply air and return air smoke detector can be wired to. An optional return air smoke detector is offered. Any other smoke detector, its installation, and the wiring to the unit controller are all field supplied.

Variable Air Volume Application

MPS units are available with variable speed drives to provide variable air volume (VAV) control as shown in Figure 14.

Daikin MPS variable air volume systems (VAV) employ the concept of varying the air quantity to a space at a constant temperature, thereby balancing the heat gains or losses and maintaining the desired room temperature. This ability to reduce supply air quantities not only provides substantial fan energy savings at partial load conditions, but it also minimizes equipment sizing.

Variable volume systems offer the following advantages:

• Lower system first cost by using system diversity to reduceequipment and duct sizes.

• Lower operating costs by reducing fan energy demands,especially at part load conditions.

• Acoustical sound performance is reduced at the lowerairflows.

Figure 14: Variable Air Volume (VAV) Control

In placing a duct static pressure sensor, locate a pressure tap near the end of the main duct trunk. Adjust the static pressure set point so that at minimum airflow all of the terminals receive the minimum static pressure required plus any downstream resistance. Locate the static pressure sensor tap in the ductwork in an area free from turbulence effects and at least ten duct diameters downstream and several duct diameters upstream from any major interference, including branch takeoffs.

Fan Isolation

All Daikin MPS systems feature internally isolated fans. All supply fans are statically and dynamically balanced in the factory. 15–50 ton unit springs have 1" deflection and 62–75 ton unit springs have 2" deflection. Flexible isolation is provided as standard between the fan and bulkhead to prevent hard contact and vibration transmission.

When using an isolation curb, consult with the curb manufacturer to confirm no resonant vibration situation can occur between the fan and roof curb.

Normally, 15–50 ton unit springs are left in the tied down position. Optional rubber and shear isolators should be ordered for 62–75 ton units.

Daikin CAT 250-8 23


Fan Operating Range

The acceptable system operating range of the Daikin rooftop is determined by all of the following characteristics. Each of these limiting factors must be considered for proper performance and component design life:

• Unstable fan operation.

• Maximum fan rpm.

• Maximum cabinet static pressure.

• Maximum face velocity (cooling coil is most important).

• Minimum furnace velocity.

• Turndown capability on VAV applications.

• Compressor operating pressures.

Indoor Fan and Motor Heat

The indoor fan and motor electrical consumption is a sensible cooling load approximately equal to 2.8 MBh per bhp (depending slightly on motor efficiency). The fan and motor temperature rise is equal to Btuh/(1.08 × cfm) and is typically about 3°F.

Altitude Adjustments

Fan Curve Performance

Fan curve performance is based on 70°F air temperature and sea level elevation. Selections at any other conditions require adjustment for air densities listed in Table 2. Higher elevations generally require more rpm to provide a given static pressure but less bhp due to the decrease in air density.

Example:

Assume 12,000 cfm is required at 2.0" TSP. The elevation is 5000 ft. and 70°F average air temperature is selected. A 24" SWSI airfoil fan is selected.

1 The density adjustment factor for 5000 ft. and 70°F is 0.83.

2 TSP must be adjusted as follows: 2.0" / 0.83 = 2.4".

3 Locate 12,000 cfm and 2.4 on the fan curve. Rpm = 1700 and bhp = 9.

4 Consumed fan power at design = 9 bph × 0.83 = 7.5 bhp.

Condenser Performance

Altitudes greater than sea level require a derate in condenser and cooling performance that can be estimated as follows:

For altitudes up to 6000 feet:

• Cooling capacity decrease factor (all sizes) = 0.5% per 1000feet.

• Compressor kW increase factor = 0.6% per 1000 feet.

For altitudes above 6000 feet, consult the factory. The actual derate varies with each individual unit and design conditions. Your local Daikin representative can provide exact performance data.

Furnace Performance

Gas heat performance data is based on standard 70°F air temperature and zero feet altitude (sea level).

For altitudes between 2000 to 6000 feet, the gas burner must be derated 4% for every 1000 feet of altitude.

Example:

A 400 MBh furnace at an altitude of 3000 feet is derated (0.04 × 3 = 0.12). At 400 MBh input (400 × 0.12 MBh), the actual input is (400 - 48 = 352 MBh) at 3000 feet.

For altitudes above 6000 feet, consult the factory.

System Operating Limits

Daikin MPS systems are designed to operate over an extensive operating range. However, for proper system operation some limits do apply.

To help prevent moisture blow-off, design guidelines have been established for cooling coil selection. Based on laboratory testing, average coil face velocities should not exceed 600 ft./min. For applications outside of these limits, consult your Daikin sales representative.

In addition to maximum face velocity limitations, minimum velocity guidelines must also be followed. In order to maintain proper refrigeration performance, the minimum coil face velocity is 175 ft./min. When selecting a variable air volume unit, it is necessary to design the system such that the 175 ft./min. limit is maintained at light load conditions.

Table 2: Temperature and Altitude Conversion Factors

Air temp (°F)

Altitude (feet)

0 1000 2000 3000 4000 5000 6000 7000 8000

-20 1.20 1.16 1.12 1.08 1.04 1.00 0.97 0.93 0.89

0 1.15 1.10 1.08 1.02 0.99 0.95 0.92 0.88 0.85

20 1.11 1.06 1.02 .098 0.95 0.92 0.88 0.85 0.82

40 1.06 1.02 0.98 0.94 0.91 0.88 0.84 0.81 0.78

60 1.02 0.98 0.94 0.91 0.88 0.85 0.81 0.79 0.76

70 1.00 0.96 0.93 0.89 0.86 0.83 0.80 0.77 0.74

80 0.98 0.94 0.91 0.88 0.84 0.81 0.78 0.75 0.72

100 0.94 0.91 0.88 0.84 0.81 0.78 0.75 0.72 0.70

120 0.92 0.88 0.85 0.81 0.78 0.76 0.72 0.70 0.67

140 0.89 0.85 0.82 0.79 0.76 0.73 0.70 0.78 0.65

Table 2: Temperature and Altitude Conversion Factors

Air temp (°F)

Altitude (feet)

0 1000 2000 3000 4000 5000 6000 7000 8000

24 Daikin CAT 250-8


Condensate Drainage

Provide all drain pans with a properly sized p-trap to allow free drainage of coil condensate. For trap sizing, follow instruction given in IM 842. Run all traps and drain lines full size from the threaded unit connection to the roof drain.

Zone Sensor Placement

Placement of the zone temperature sensor is critical for proper and economical operation of the heating and cooling system. It is generally recommended that the space sensor be located on an inside wall (3 to 5 feet from an outside wall) in a space having a floor area of at least 400 square feet. Do not locate the sensor below the outlet of a supply diffuser, in the direct rays of the sun, on a wall adjacent to an unheated or abnormally warm room (boiler or incinerator room), or near any heat producing equipment. Where zone sensor placement is a problem, all zone control systems, as standard, have the capability to use a return air sensor for heating and cooling.

Unit Wiring

All units require three phase, 60 Hz, 208, 230, 460, or 575 volt power supply. All units include branch circuits and short circuit protection and are available with a power block or non-fused disconnect switch. Each unit is provided with a 115 V convenience outlet. Per the NEC, this circuit must be fed independent of the main unit power supply.

All wiring must be installed in accordance with the National Electric Code (NEC) and local codes.

Winter Shipment

Flat bed shipment in winter can expose units to harsh road chemicals. Since equipment size and configuration precludes covering during transit, wash units free of these chemicals as soon as possible to help prevent corrosion.

Coil Freeze Protection

When applying roof-mounted equipment in areas that experience subfreezing conditions, coil freeze protection measures must be provided. Subfreezing temperatures can adversely affect water and steam coils during controlled or uncontrolled unit shutdowns and even during unit operation. Daikin economizer dampers are arranged to direct the outside and return air streams toward each other, however, there may not always be a uniform unit temperature profile under all load and ambient temperatures. Some temperature stratification will occur, particularly at low ambient temperatures and the associated reduced airflow inherent with VAV systems.

Glycol is strongly recommended as a positive means of freeze protection for water coils. No control sequence can prevent coil freezing in the event of a power failure or equipment malfunction. During those periods, glycol is the only positive means of freeze protection. When selecting water coils, specify glycol to account for performance differences.

Freeze protection control strategies must be designed to keep unit cabinet temperatures from exceeding 150°F during a unit shutdown. Temperatures in excess of 150°F may exceed the design limits of motors, electrical components, gaskets, etc. potentially leading to premature failure of components.

Daikin CAT 250-8 25

Unit Selection
Unit Selection
Achieving Optimal Performance

Achieving the optimal performance of a rooftop system requires both accurate system design and proper equipment selection. Factors that control the unit selection include applicable codes, ventilation and air filtration requirements, heating and cooling loads, acceptable temperature differentials, and installation limitations.

The Daikin SelectTools™ software selection program allows your local Daikin sales representative to provide you with fast, accurate and complete selection of Daikin MPS units. You also can select your unit through reference to physical, performance, dimensional, and unit weight data included in this catalog.

To properly select unit equipment:

1 Select unit size and cooling coil.

2 Select heating coils and equipment.

3 Select fans and motors.

Below are examples that illustrate the equations and catalog references used in the unit selection process.

Selecting Unit Size to SatisfySummer Design

Unit size is based on coil face area and cooling capacity requirements. Supply air capacity and maximum face velocity constraints should serve as a guide for selecting coil dimensions and cabinet size.

Based on the given data in Table 3, the appropriate coil face area may be determined as follows:

Note: Unit data is based on standard air conditions of 70°F at sea level. Refer to Application Considerations‚ page 21 for temperature/altitude conversion factors for nonstandard conditions.

Referring to Physical Data‚ page 28, the 29.4 square foot coil of the MPS 040A unit satisfies the required face velocity.

Using the Performance Data‚ page 32, the unit selection is an MPS 040A. Unit performance equals 457,000 Btu/hr. total, 350,000 Btu/hr. Sensible.

Once the initial unit selection is made, determine the actual supply fan heat rise and check and verify the selection for net capacity and supply air temperature.

Selecting the Unit Heating System

Heating equipment and coils can be specified directly from figures and tables incorporated in Hot Water Heating Capacity‚ page 38.

Calculating Total Heating Load

From the data given in Table 3, the outdoor air load is (1.085 × 2800)(70 – 10) / 1000 = 182 MBh and supply fan heat is 46 MBh.

Total heat load = 315 MBh + 182 MBh – 46 MBh = 451 MBh

Table 3: Selection Example

A constant volume system with DX cooling and natural gas heat is required to meet the following criteria:

Supply air volume = 14,000 cfmReturn air volume = 11,200 cfm

Minimum outside air volume = 2800 cfmMaximum face velocity = 550 fpm

Supply ductwork external SP = 1.50-in. w.g.Return ductwork external SP = 0.50-in. w.g.

Altitude = Sea levelEconomizer = Required

30% throw-away filters = RequiredVoltage = 460 V/60 Hz/3 Ph

Natural gas heat = RequiredDouble-wall construction = Required

Summer design: Mixed air temperature = 80°F/67°F

Total sensible load = 345,000 Btu/hrTotal load = 450,000 Btu/hr

Space supply air temperature = 60°FAmbient conditions = 95°F/76°F

Est. supply fan sensible heat rise =(included in above sensible load)

3°F

Winter design: Return air temperature = 70°F

Ambient temperature = 10°FSpace heating load = 315,000 Btu/hr

Minimum facearea

= supply air volume/max. face velocity

= 14,000 cfm/550 fpm= 25.5 square feet

Supply air dry bulb =80°F – 350 MBh/(1.085 × 14,000 cfm) = 57.0°F

Total heating load =space heating load + outdoor air load –supply fan heat

26 Daikin CAT 250-8

Unit Selection

Selecting Fans and Motors

Fan and motor selections are based on total static pressure drop and design airflow. Total static pressure includes internal air pressure drops of unit components and external air pressure drops in supply and return ducts. Refer to Pressure Drops‚ page 40 for internal pressure drops of unit components.

When selecting unit fans and motors, use the fan curves provided in Figure 32, page 51 and Figure 33, page 51.

Select the motor size most closely above the application brake horsepower. (Example: For an application brake horsepower of 7 bhp, select a 7.5 hp motor). An oversized motor (large horsepower to load ratio) can greatly increase electric consumption due to the reduction in motor performance.

Exhaust Fan and Motor

Exhaust fans must be sized for maximum exhaust cfm and return duct ESP at those conditions. See Hot Water Pressure Drop Curves‚ page 47 for more information.

Supply Fan and Motor

Since the system in Table 3 includes a return fan, the return duct static pressure drop is not added to the supply fan pressure drop. Therefore, the total static pressure for the supply fan in Table 3 is as follows:

Entering the MPS 040A fan curve at 14,000 cfm and 3.16-in. w.g., the required fan motor size is 15 hp operating at 1325rpm. Fan brake horsepower is 12.9 horsepower.

The total fan and motor heat for the supply fan is as follows:

Additional Weights When Selecting Motors

Table 4 and Table 5 lists additional weights when selecting a motor and exhaust fan. See Unit Capacity and Physical Data‚ page 28 for base unit weights, capacities and physical data.

Note: See Table 46, page 87 for additional weights on 62–75 ton units.

Supply Power Wiring for Units WithoutElectric Heat

Sizing supply power wire for a unit is based on the circuit with the largest amperage draw. All electrical equipment is wired to a central panel for single or optional multipower connections. Refer to Electrical Data‚ page 88 for FLA and RLA ratings of equipment. Determination of Minimum Circuit Ampacity (MCA) for a 460 V unit with standard condenser fans and R-410A is as follows:

Fans and Cooling

Therefore,

Note: In the above example, the selected power supply wire is based on 90 amperes.

Internal pressure drops:0–100% economizer, with RAF = 0.17-in. w.g.

30% filters = 0.13-in. w.g.Evaporative coil = 0.61-in. w.g.

Total internal pressure drop = 1.16-in. w.g.

External pressure drops:Supply duct = 1.50-in. w.g.Return duct = 0.50-in. w.g.

Total external pressure drop = 2.00-in. w.g.

Total static pressure = internal drops + external drops= 1.16 + 2.00= 3.16-in. w.g.

(12.9) bhp × 2.8 MBh/bhp = 36 MBh

Table 4: Additional Weights When Selecting Motors/Exhaust Fans (015–020 units)

HPAdditional Motor

Weight (lbs)Unit tons

Additional Exhaust Fan Weight (lbs)

1 0 15 1501.5 9 17 1502 9 20 1503 325 43

Table 5: Additional Weights When Selecting Motors/Exhaust Fans (026–050 units)

HPAdditional Motor

Weight (lbs)Unit tons

Additional Exhaust Fan Weight (lbs)

7.5 0 26 15010 25 30 15015 125 35 15020 175 40 20025 225 50 20030 275

MCA = 1.25 × (RLA or FLA of largest motor) + FLA of all other loads

Example: FLA/RLA

Compressor 1, 2, 3 = 16.5, 16.5, 14 ampsCondenser fan motors, (3) 1 hp = 2 amps ea.

Supply fan motor, 15 hp = 17.7 ampsControls = 1 amps

MCA = (1.25 × 17.7) + 16.5 + 16.5 + 14.0 + (3 × 2) + 1= 76 amps

Daikin CAT 250-8 27

Physical Data
Physical Data
Unit Capacity and Physical Data

Note: 1 Piping connections are given with a male outside diameter dimension, brazed connection.2 Heating output is for standard conditions at sea level.3 AHRI performance, see Table 22, “MPS 015–062 Multipliers,” on page 38

Table 6: MPS 015–026

ModelMPS

015 017 020 026Cooling PerformanceGross cooling capacity (tons) 16.0 18.5 22.4 25.3Nominal airflow (cfm) 6000 7000 8000 10,000Maximum EER3 11.0 11.0 10.0 10.8Maximum IEER (CAV-VAV)3 11.3-11.5 11.3-11.9 11.2 12.8Gas Heating PerformanceLow heat MBH (input/output)2 240/192 240/192 240/192 300/240Number of stages (low heat) 2 2 2 2Turndown (low heat)2 4:1 4:1 4:1 4:1Gas connection pipe size/qty (low heat)1 3/4"/1 3/4"/1 3/4"/1 3/4"/1High heat MBH (input/output)2 480/384 480/384 480/384 600/480Number of stages (high heat) 4 4 4 4Turndown (high heat) 8:1 8:1 8:1 8:1Steady state efficiency 80% 80% 80% 80%Hot Water Heating PerformanceFace area (sq ft) 12.2 12.2 12.25 19.25Rows/FPI (low heat) 1/11 1/11 1/14 1/14Coil model (low heat) 5WB 5WB 5WB 5WBConnection sizes/type (low heat) ODM Sweat ODM Sweat ODM Sweat ODM SweatRows/FPI (high heat) 2/12 2/12 2/9 210Coil model (high heat) 5WB 5WB 5WS 5WSConnection sizes/type (high heat) ODM Sweat ODM Sweat ODM Sweat ODM SweatElectric Heating PerformanceNumber of stages 4 4 4 4kW (low/medium/high heat) 18/36/54 18/36/54 36/54/72 54/72/90CompressorsType/number Scroll/2 Scroll/2 Scroll/3 Scroll/3Number of stages 2 2 4 4Evaporator CoilsRows/FPI 4/14 4/14 6/13 4/12Face area (sq ft) 18.2 18.2 18.2 25.4Capacity control TXV TXV TXV TXVHot Gas ReheatCoil type Microchannel Microchannel Microchannel MicrochannelControl type Modulating Modulating Modulating ModulatingFace area (sq ft) 14.1 14.1 14.1 19.9Minimum temperature rise 20° 20° 20° 20°Condenser CoilsFin type Enhanced Enhanced Enhanced EnhancedFPI 18 18 18 18Face area (sq ft) 36.2 36.2 36.2 41.2Outdoor FansType Propeller Propeller Propeller PropellerNumber - diameter 2 - 26" 2 - 26" 2 - 26" 3 - 26"Drive type/number of speeds Direct/1 Direct/1 Direct/1 Direct/1Indoor FansType AF - SWSI AF - SWSI AF - SWSI AF - SWSINumber - diameter 1 - 18" 1 - 20" 1 - 22" 1 - 24"Drive type Fixed sheave Fixed sheave Fixed sheave Fixed sheaveIsolation 1" spring 1" spring 1" spring 1" springNumber of motors 1 1 1 1Motor hp range 1.5 - 10 1.5 - 10 2 - 15 5 - 20Motor nominal rpm 1800 1800 1800 1800Motor efficiency Premium Premium Premium PremiumFiltersType 2", MERV 7Area (sq ft) 24 24 24 32Qty. - size 6 - 24" x 24" 6 - 24" x 24" 6 - 24" x 24" 8 - 24" x 24"

28 Daikin CAT 250-8

Physical Data



ModelMPS

030 035 040 050Cooling PerformanceGross cooling capacity (tons) 30.0 34.0 40.0 50.0Nominal airflow (cfm) 12,000 14,000 16,000 20,000Maximum EER3 10.3 10.0 10.2 10.0Maximum IEER (CAV-VAV)3 12.4-13.0 11.9-12.3 12.0-12.6 11.6-12.2Gas Heating PerformanceLow heat MBH (input/output)2 300/240 300/240 400/320 400/320Number of stages (low heat) 2 2 2 2Turndown (low heat) 4:1 4:1 4:1 4:1Gas connection pipe size/qty (low heat)1 3/4"/1 3/4"/1 3/4"/1 3/4"/1High heat MBH (input/output)2 600/480 600/480 800/640 800/640Number of stages (high heat) 4 4 4 4Turndown (high heat) 8:1 8:1 8:1 8:1Steady state efficiency 80% 80% 80% 80%Hot Water Heating PerformanceFace area (sq ft) 19.25 19.25 19.25 19.25Rows/FPI (low heat) 1/12 1/12 1/11 1/11Coil model (low heat) 5WB 5WB 5WH 5WHConnection sizes/type (low heat) ODM Sweat ODM Sweat ODM Sweat ODM SweatRows/FPI (high heat) 2/10 2/10 2/13 2/13Coil model (high heat) 5WS 5WS 5WS 5WSConnection sizes/type (high heat) ODM Sweat ODM Sweat ODM Sweat ODM SweatElectric Heating PerformanceNumber of stages 4 4 4 4kW (low/medium/high heat) 54/72/90 54/72/90 72/90/108 72/90/108CompressorsType/number Scroll/3 Scroll/3 Scroll/4 Scroll/4Number of stages 5 5 5 5Evaporator CoilsRows/FPI 4/12 4/12 4/12 4/12Face area (sq ft) 25.4 25.4 35.7 35.7Capacity control TXV TXV TXV TXVHot Gas Reheat CoilsCoil type Microchannel Microchannel Microchannel MicrochannelControl type Modulating Modulating Modulating ModulatingFace area (sq ft) 19.9 19.9 26.8 26.8Minimum temperature rise 20° 20° 20° 20°Condenser CoilsFin type Enhanced Enhanced Enhanced EnhancedFPI 18 18 18 18Face area (sq ft) 41.2 41.2 74.7 74.7Outdoor FansType Propeller Propeller Propeller PropellerNumber - diameter 3 - 26" 3 - 26" 4 - 26" 4 - 26"Drive type/number of speeds Direct/1 Direct/1 Direct/1 Direct/1Indoor FansType AF - SWSI AF - SWSI AF - SWSI AF - SWSINumber - diameter 1 - 24" 1 - 24" 1 - 30" 1 - 30"Drive type Fixed sheave Fixed sheave Fixed sheave Fixed sheaveIsolation 1" spring 1" spring 1" spring 1" springNumber of motors 1 1 1 1Motor hp range 5 - 20 5 - 20 7-1/2 - 30 7-1/2 - 30Motor nominal rpm 1800 1800 1800 1800Motor efficiency Premium Premium Premium PremiumFiltersType 2", MERV 7Area (sq ft) 32 32 44 44Qty. - size 8 - 24" x 24" 8 – 24" x 24" 8 – 24" x 24"/4 – 18" x 24" 8 – 24" x 24"/4 – 18" x 24"

Daikin CAT 250-8 29

Physical Data



ModelMPS

062 070 075

Cooling PerformanceNominal gross cooling capacity (tons) 62.0 70.0 75.0Nominal airflow (cfm) 24,000 26,000 28,000Maximum EER (standard coil/large coil)3 10.0/10.1 9.7 9.4Maximum IEER (standard coil/large coil)3 12.2/12.3 13.6 12.9Gas Heating PerformanceLow heat MBH (input/output)2 500/400 500/400 500/400Gas connection pipe size/qty (low heat)1 1"/1 1"/1 1"/1Medium heat MBH (input/output)2 600/480 600/480 800/640Gas connection pipe size/qty (medium heat)1 1 1/4"/1 1 1/4"/1 1 1/4"/1High heat MBH (input/output)2 980/790 980/790 980/790Number of stages - all furnaces Mod Mod ModTurndown - all furnaces 3:1 3:1 3:1Steady state efficiency - all furnaces 80% 80% 80%Hot Water Heating PerformanceFace area (sq ft) 29.7 29.7 29.7Type–rows (standard / high capacity) 5WH–1 / 5WS–2 5WH–1 / 5WS–2 5WH–1 / 5WS–2FPI 9 9 9Electric Heating PerformanceNumber of stages 4 4 4kW (low/medium/high heat) 100/120/160 100/120/160 100/120/160CompressorsType/number Scroll/4 Scroll/6 Scroll/6Number of stages 4 6 6Evaporator CoilsRows/FPI 5/10 5/10 5/10Face area (sq ft) 39.5 or 47.1 47.1 47.1Capacity control TXV TXV TXVCondenser CoilsFin type Enhanced Enhanced EnhancedFPI 18 18 18Face area (sq ft) 32.1 × 2 37.3 × 2 37.3 × 2Outdoor FansType Propeller Propeller PropellerNumber - diameter 6 - 26" 6 - 26" 8 - 26"Drive type/number of speeds Direct/1 Direct/1 Direct/1Indoor FansSWSI AF 1 - 44"DWDI AF 1 - 30" or 1 - 33"Drive type Fixed sheaveIsolation 2" springNumber of motors 1Motor hp range 5 - 40Motor nominal rpm 1800Motor efficiency PremiumFilters

Qty. - type / sq. ft.Merv 7 angular (7) 16 × 20 and (21) 16 × 25 / 73 sq. ft.

6" Merv 11 or 12" Merv 14(4) 12 × 24 and (8) 24 × 24 / 40 sq. ft. standard air flow

(8) 12 × 24 and (8) 24 × 24 / 48 sq. ft. high air flow

30 Daikin CAT 250-8

Physical Data

Table 9: MPS Refrigerant Charge Table

Size (ton) EvaporatorCircuit 1 Circuit 1 with HGRH Circuit 2

lbs. kg. lbs. kg. lbs. kg.

15 F4-row 9.0 4.1 17.3 7.8 9.0 4.16-row 10.4 4.7 18.7 8.4 10.4 4.7

17 F4-row 9.0 4.1 17.3 7.8 10.0 4.56-row 10.4 4.7 18.7 8.4 11.5 5.2

20 G 6-row 12.7 5.8 21.0 9.6 14.4 6.6

26 G4-row 18.5 8.4 30.0 13.6 10.0 4.56-row 21.5 9.8 33.0 15.0 11.5 5.2

30 F4-row 19.0 8.6 30.7 13.9 10.2 4.66-row 21.9 9.9 33.6 15.2 11.7 5.3

35 F4-row 19.0 8.6 30.7 13.9 10.5 4.86-row 21.9 9.9 33.6 15.2 12.1 5.5

40 F4-row 23.0 10.4 40.0 18.1 23.5 10.76-row 26.5 12.0 43.5 19.7 27.0 12.3

50 F4-row 23.0 10.4 40.0 18.1 23.5 10.76-row 26.5 12.0 43.5 19.7 27.0 12.3

Daikin CAT 250-8 31

Performance Data
Performance Data
Cooling CapacityTable 10: MPS 015 Cooling Capacities (4 Row Coil)

CFMEntering Air

Temperature (°F)Ambient Air Temperature (°F)

85° 95° 105° 115°

DB WB THC SHC kW THC SHC kW THC SHC kW THC SHC kW

6000

7561 183 163 10.8 175 159 12.1 166 155 13.5 157 151 15.067 203 122 10.8 192 118 12.1 182 114 13.6 172 111 15.173 - - - 214 77 12.2 203 73 13.6 191 69 15.1

8061 189 189 10.8 182 182 12.1 174 174 13.5 166 166 15.167 203 155 10.8 193 151 12.1 183 147 13.6 173 144 15.173 - - - - - - 202 106 13.6 191 102 15.1

8561 201 201 10.8 193 193 12.1 185 185 13.5 176 176 15.167 205 188 10.9 196 184 12.1 186 179 13.6 177 173 15.173 - - - 213 142 12.2 202 139 13.6 191 135 15.1

5250

7561 179 152 10.8 171 148 12.1 162 144 13.5 154 140 15.067 199 115 10.8 189 112 12.1 179 108 13.5 170 104 15.173 - - - 210 75 12.2 199 71 13.6 188 68 15.1

8061 183 179 10.8 175 173 12.1 167 167 13.5 160 160 15.067 199 144 10.8 189 141 12.1 180 137 13.5 170 133 15.173 - - - - - - 100 100 13.6 188 96 15.1

8561 192 192 10.8 185 185 12.1 177 177 13.5 169 169 15.167 200 173 10.8 191 170 112.1 181 166 13.5 172 162 15.173 - - - 210 133 12.2 199 129 13.6 188 125 15.1

4125

7561 171 133 10.8 163 130 12.1 156 126 13.4 147 122 15.067 - - - 181 101 12.1 173 97 13.5 164 94 15.073 - - - 203 72 12.2 193 69 13.6 182 65 15.1

8061 172 156 10.8 165 153 12.1 157 149 13.5 149 145 15.067 191 128 10.8 182 124 12.1 173 120 13.5 164 117 15.073 - - - - - - - - - - - -

8561 177 176 10.8 170 170 12.1 164 164 13.5 157 157 15.067 191 150 10.8 182 147 12.1 174 143 13.5 164 139 15.173 - - - - - - - - - - - -

Note: THC = Total Heat Capacity (gross), SHC = Sensible Heat Capacity (gross), kW = Total compressor kW

Cooling capacities are for standard conditions at sea level.

Note: THC = Total Heat Capacity (gross), SHC = Sensible Heat Capacity (gross), kW = Total compressor kWCooling capacities are for standard conditions at sea level.

Table 11: MPS 017 Cooling Capacities (4 Row Coil)

CFMEntering Air


85° 95° 105° 115°


7000

7561 211 188 12.9 202 184 14.3 192 179 15.9 182 174 17.667 232 141 13.1 221 136 14.5 210 132 16.1 199 128 17.873 257 92 13.3 - - - - - - - - -

8061 218 218 13.0 210 210 14.4 202 202 16.0 192 192 17.767 232 179 13.1 222 175 14.5 211 170 16.1 200 166 17.873 257 130 13.3 - - - - - - - - -

8561 231 231 13.1 223 223 14.5 214 214 16.1 204 204 17.967 236 217 13.1 226 212 14.6 215 207 16.1 204 201 17.973 257 169 13.3 - - - - - - - - -

6125

7561 206 175 12.8 197 171 14.3 188 167 15.8 178 162 17.667 228 133 13.1 217 129 14.5 207 125 16.0 196 120 17.873 252 90 13.3 242 86 14.7 - - - - - -

8061 210 207 12.9 203 201 14.3 194 194 15.9 185 185 17.667 228 167 13.1 218 163 14.5 207 158 16.0 196 154 17.873 253 124 13.3 241 120 14.7 - - - - - -

8561 222 222 13.0 214 214 14.4 206 206 16.0 196 196 17.867 230 200 13.1 220 196 14.5 210 192 16.1 199 187 17.873 253 157 13.3 241 153 14.7 - - - - - -

4812

7561 197 154 12.7 189 150 14.2 180 146 15.7 170 142 17.567 219 121 13.0 209 117 14.4 200 113 16.0 189 108 17.773 244 87 13.2 233 83 14.6 222 79 16.2 210 75 18.0

8061 199 181 12.8 191 177 14.2 182 173 15.7 173 168 17.567 219 147 13.0 210 143 14.4 200 139 16.0 189 135 17.773 243 113 13.2 233 109 14.6 222 105 16.2 210 101 18.0

8561 204 204 12.8 197 197 14.2 190 190 15.8 182 182 17.667 220 174 13.0 211 170 14.4 201 166 16.0 190 162 17.773 244 140 13.2 233 136 14.6 222 132 16.2 210 128 18.0

32 Daikin CAT 250-8

Performance Data




UintData

Entering Air Temperature (°F)

Ambient Air Temperature (°F)

85° 95° 105° 115°


8000 cfm6 row12 fpi

7561 255 222 17.8 243 217 19.9 230 211 22.2 214 204 24.867 282 168 18.3 268 162 20.4 252 156 22.7 237 150 25.373 311 112 18.8 296 107 20.9 278 101 23.2 261 95 25.9

8061 260 261 17.9 249 252 20.0 238 240 22.3 224 226 25.067 282 211 18.3 268 205 20.4 252 199 22.7 237 193 25.373 311 155 18.8 295 150 20.9 278 144 23.2 260 138 25.9

8561 275 277 18.1 263 266 20.2 250 253 22.6 238 240 25.367 283 254 18.3 269 248 20.4 254 242 22.7 239 234 25.473 310 198 18.9 295 193 20.9 278 187 23.3 260 181 25.9

7000 cfm6 row12 fpi

7561 249 207 17.7 238 201 19.8 224 195 22.1 210 188 24.767 276 159 18.2 263 153 20.3 248 147 22.6 232 141 25.273 306 110 18.7 290 104 20.8 275 99 23.1 257 93 25.8

8061 251 244 17.7 240 237 19.8 228 229 22.1 216 219 24.867 275 196 18.2 262 191 20.3 248 185 22.6 232 178 25.273 306 148 18.7 290 142 20.8 274 136 23.1 256 130 25.8

8561 262 265 17.9 252 255 20.0 241 243 22.4 228 230 25.167 276 234 18.2 263 228 20.3 249 222 22.6 233 217 25.273 305 185 18.7 289 179 20.8 274 174 23.1 256 169 25.8

5500 cfm6 row12 fpi

7561 238 182 17.5 226 177 19.5 214 172 21.8 201 165 24.467 264 145 18.0 252 139 20.0 239 133 22.3 223 127 25.073 293 106 18.5 279 101 20.6 264 95 22.9 248 89 25.5

8061 239 213 17.5 227 207 19.5 215 201 21.8 202 195 24.567 264 174 18.0 251 169 20.0 238 164 22.4 223 157 25.073 293 135 18.5 278 130 20.6 264 124 22.9 247 119 25.5

8561 241 240 17.6 231 233 19.6 221 223 22.0 210 213 24.667 264 204 18.0 251 199 20.0 238 193 22.4 223 187 25.073 292 166 18.5 278 160 20.6 263 155 22.9 247 148 25.6


UintData

Entering Air Temperature (°F)

Ambient Air Temperature (°F)

85° 95° 105° 115°


6875 cfm

4 row12 fpi

7563 269 194 17.9 257 188 19.8 244 182 22.0 229 175 24.367 288 162 18.0 275 157 20.0 261 151 22.1 245 145 24.471 309 131 18.1 295 126 20.1 280 120 22.2 264 144 24.5

8063 269 229 17.9 257 224 19.8 244 218 22.0 229 211 24.367 288 199 18.0 275 194 20.0 261 187 22.1 245 181 24.471 309 167 18.1 294 161 20.1 279 156 22.2 263 150 24.6

8563 271 265 17.9 260 258 19.9 148 251 22.0 236 239 24.367 288 235 18.0 275 229 20.0 262 224 22.1 246 218 24.471 308 204 18.1 294 198 20.1 279 193 22.2 263 187 24.6

8750 cfm

4 row12 fpi

7563 281 218 18.0 226 212 19.9 253 205 22.0 237 198 24.467 300 179 18.1 286 173 20.0 270 166 22.2 254 161 24.571 322 139 18.2 — — — — — — — — —

8063 283 262 18.0 268 257 19.9 255 250 22.1 241 241 24.467 300 225 18.1 303 219 20.0 270 213 22.2 254 206 24.571 321 186 18.2 — — — — — — — — —

8563 291 295 18.0 280 284 20.0 267 271 22.1 254 258 24.567 302 270 18.1 287 264 20.1 272 258 22.2 257 251 24.571 321 231 18.2 — — — — — — — — —

10000 cfm

4 row12 fpi

7563 287 232 18.0 272 226 20.0 257 221 22.1 242 214 24.467 306 189 18.1 290 183 20.1 275 177 22.2 258 170 24.571 — — — — — — — — — — — —

8063 289 283 18.0 276 274 20.0 262 264 22.1 248 252 24.467 306 189 18.1 290 183 20.1 275 177 22.2 258 170 24.571 — — — — — — — — — — — —

8563 303 307 18.1 290 294 20.1 278 282 22.2 — — —67 308 291 18.1 293 285 20.1 279 277 22.2 — — —71 — — — — — — — — — — — —

Daikin CAT 250-8 33

Performance Data




CFMEntering Air


85° 95° 105° 115°


12,000

7561 360 318 22.7 343 311 25.0 326 302 27.7 307 291 30.967 398 239 23.3 379 232 25.7 359 224 28.3 337 216 31.573 441 158 24.0 420 151 26.4 397 143 29.0 373 135 32.2

8061 368 221 22.8 353 353 25.2 338 338 27.9 321 321 31.267 398 303 23.3 379 295 25.7 359 288 28.4 337 279 31.573 440 221 24.0 420 214 26.4 397 207 29.0 373 199 32.2

8561 388 388 23.2 374 374 25.6 357 357 28.3 340 340 31.567 399 364 23.4 381 356 25.7 362 345 28.4 343 333 31.673 439 285 24.0 419 278 26.4 396 270 29.0 372 262 32.2

10,500

7561 352 297 22.6 336 290 24.9 319 282 27.6 301 273 30.867 390 226 23.2 372 219 25.5 352 211 28.2 331 331 31.473 433 154 23.9 413 147 26.2 391 140 28.9 367 132 32.0

8061 356 346 22.6 342 336 25.0 326 325 27.7 310 310 30.967 390 283 23.2 373 276 25.5 353 268 28.2 332 260 31.473 432 210 23.9 412 260 26.2 389 252 28.9 366 244 32.0

8561 373 373 22.9 359 359 25.3 344 344 28.1 327 327 31.367 391 338 23.2 373 331 25.5 354 323 28.2 334 313 31.473 432 267 23.9 412 260 26.2 389 252 28.9 366 244 32.0

8250

7561 336 263 22.3 322 256 24.6 306 248 27.3 288 240 30.567 373 206 22.9 357 199 25.3 340 192 28.0 320 184 31.273 416 148 23.6 397 141 26.0 377 134 28.7 355 126 31.8

8061 337 307 22.3 323 300 24.6 307 291 27.4 291 281 30.667 373 251 22.9 357 244 25.3 339 237 28.0 320 229 31.173 415 193 23.6 397 186 26.0 377 179 28.6 355 171 31.8

8561 344 343 22.4 331 331 24.8 318 318 27.6 304 304 30.867 374 296 22.9 358 289 25.3 340 281 28.0 320 273 31.173 415 238 23.6 396 231 26.0 376 224 28.7 354 216 31.8


CFMEntering Air


85° 95° 105° 115°


14,000

7561 397 359 25.5 378 350 28.2 358 340 31.2 336 329 34.867 438 267 26.3 417 259 28.9 394 251 31.9 370 242 35.573 484 173 27.1 461 166 29.7 435 157 32.8 408 149 36.3

8061 408 408 25.8 392 392 28.5 374 374 31.6 355 355 35.267 438 341 26.3 417 332 28.9 394 324 31.9 370 314 35.573 484 247 27.1 460 239 29.7 435 231 32.8 408 222 36.3

8561 431 431 26.2 414 414 28.9 396 396 32.0 376 376 35.667 440 412 26.3 419 402 29.0 398 392 32.0 376 376 35.673 483 320 27.1 460 313 29.8 435 304 32.8 407 295 36.3

12,250

7561 389 335 25.4 371 327 28.0 351 318 31.1 330 308 34.767 429 253 26.2 409 245 28.8 388 236 31.8 364 228 35.473 476 170 27.0 453 162 29.6 429 154 32.6 403 145 36.2

8061 393 393 25.5 378 378 28.2 361 361 31.3 343 343 35.067 430 318 26.2 410 310 28.8 388 301 31.3 343 343 35.073 476 235 27.0 453 227 29.6 429 219 32.6 402 210 36.2

8561 415 415 25.9 399 399 28.6 382 382 31.7 363 363 35.467 430 382 26.2 411 374 28.8 389 364 31.8 366 354 35.473 475 299 27.0 452 292 29.6 428 283 32.6 402 275 36.2

9625

7561 373 296 25.1 357 288 27.7 338 280 30.8 318 271 34.467 413 230 25.9 395 222 28.5 674 214 31.6 352 205 35.273 459 163 26.7 438 156 29.3 415 148 32.4 390 139 35.9

8061 373 347 25.1 358 339 27.8 340 330 30.9 321 320 34.567 413 282 25.9 395 274 28.5 374 266 31.6 353 257 35.273 458 215 26.7 438 208 29.3 415 199 32.4 390 191 35.9

8561 384 384 25.3 370 370 28.0 355 355 31.2 338 338 34.967 414 334 25.8 395 326 28.5 375 318 31.5 352 309 35.273 458 267 26.7 437 259 29.3 414 251 32.3 389 242 35.9

34 Daikin CAT 250-8

Performance Data




CFMEntering Air


85° 95° 105° 115°


16,000

7561 442 404 27.7 421 394 30.6 399 382 33.9 377 367 37.767 487 300 28.5 464 292 31.3 440 283 34.6 412 273 38.473 539 194 29.4 513 185 32.2 485 176 35.4 455 166 39.2

8061 456 456 28.0 438 438 30.9 419 419 34.2 397 397 38.167 487 384 28.5 465 376 31.3 439 366 34.6 413 355 38.473 538 278 29.4 512 269 32.2 485 260 35.4 455 250 39.2

8561 482 482 28.4 463 463 31.3 443 443 34.6 421 421 38.567 490 463 28.6 470 451 31.4 446 436 34.7 421 419 38.673 537 361 29.4 512 353 32.2 484 344 35.4 454 334 39.2

14,000

7561 432 377 27.6 413 368 30.4 392 358 33.7 368 347 37.667 478 284 28.4 456 275 31.2 432 266 34.4 406 257 38.373 530 189 29.2 505 181 32.0 478 172 35.3 449 162 39.1

8061 440 437 27.7 422 422 30.6 404 404 33.9 384 384 37.967 479 359 28.4 457 350 31.2 432 341 34.5 406 330 38.373 529 263 29.2 505 255 32.0 478 246 35.3 449 236 39.1

8561 464 464 28.1 447 447 31.0 428 428 34.4 406 406 38.367 480 431 28.4 458 422 31.2 435 411 34.5 411 396 38.473 529 338 29.2 504 329 32.0 477 320 35.3 448 310 39.1

11,000

7561 415 333 27.2 397 325 30.1 377 316 33.4 355 306 37.367 460 258 28.1 439 250 30.9 417 241 34.2 393 231 38.073 511 182 28.9 488 174 31.7 463 165 35.0 436 155 38.8

8061 416 391 27.3 399 381 30.1 380 369 33.5 360 355 37.467 460 318 28.0 440 309 30.9 417 300 34.2 393 290 38.073 511 241 28.9 488 233 31.7 463 224 35.0 435 215 38.8

8561 430 430 27.5 414 414 30.4 397 397 33.8 379 379 37.867 460 377 28.0 440 368 30.9 418 359 34.2 393 349 38.073 510 300 28.9 487 292 31.7 461 283 35.0 434 274 38.8


CFMEntering Air


85° 95° 105° 115°


20,000

7561 568 512 38.0 540 499 42.0 512 486 46.6 480 470 52.067 625 381 39.2 595 370 43.1 563 358 47.6 528 345 53.073 691 248 40.5 657 236 44.4 621 224 48.9 582 212 54.2

8061 583 583 38.4 560 560 42.4 534 534 47.1 506 506 52.667 626 486 39.2 596 475 43.1 563 462 47.7 528 448 53.073 691 352 40.5 657 341 44.4 620 329 48.9 581 316 54.2

8561 616 616 39.1 592 592 43.1 566 566 47.7 537 537 53.267 628 587 39.3 599 574 43.2 567 559 47.8 537 537 53.273 689 457 40.5 656 446 44.4 620 434 48.9 580 421 54.3

17,500

7561 557 479 37.8 531 467 41.7 502 453 46.3 470 439 51.867 614 361 39.0 585 349 42.9 553 337 47.5 520 325 52.873 680 242 40.2 647 231 44.2 612 219 48.7 574 207 54.0

8061 563 562 37.9 540 540 42.0 516 516 46.7 490 490 52.267 615 454 39.0 585 443 42.9 554 430 47.5 519 417 52.873 679 335 40.2 647 324 44.2 611 312 48.7 573 299 54.0

8561 593 593 38.6 570 570 42.6 545 545 47.3 518 518 52.867 615 545 39.0 587 533 43.0 556 520 47.5 523 506 52.973 678 427 40.2 644 416 44.2 610 404 48.7 572 392 54.1

13,750

7561 534 423 37.3 510 412 41.3 483 400 45.9 455 387 51.467 591 329 38.5 564 318 42.5 534 306 47.1 502 293 52.573 656 233 39.8 625 222 43.7 592 211 48.3 556 198 53.7

8061 534 496 37.3 511 485 41.3 486 472 46.0 458 456 51.567 591 403 38.5 564 392 42.5 534 380 47.1 503 367 52.573 655 307 39.8 625 296 43.7 592 285 48.3 556 272 53.7

8561 549 549 37.7 529 529 41.7 507 507 46.5 482 482 52.167 592 477 38.5 565 466 42.5 534 453 47.1 503 441 52.573 654 381 39.7 624 370 43.7 591 358 48.3 555 346 53.6

Daikin CAT 250-8 35

Performance Data



Table 18: MPS 062 Standard Airflow Cooling Capacities

CFMEntering Air


85° 95° 105°

DB WB THC SHC kW THC SHC kW THC SHC kW

18,000

7563 651 479 47.1 622 466 52.7 591 454 59.267 703 401 48.3 671 388 53.9 639 375 60.571 758 320 49.6 725 308 55.3 690 296 61.9

8063 652 575 47.2 624 563 52.8 595 549 59.367 703 497 48.3 672 484 54.0 638 471 60.571 757 513 49.7 723 500 55.3 688 487 61.9

8563 663 663 47.4 641 641 53.1 616 616 59.867 703 592 48.3 672 579 54.0 640 566 60.571 757 513 49.7 723 500 55.3 688 487 61.9

21,000

7563 667 518 47.5 638 506 53.1 607 493 59.667 721 427 48.7 689 415 54.3 655 402 60.971 777 334 50.1 743 322 55.8 707 310 62.4

8063 673 628 47.6 644 614 53.3 613 600 59.867 720 538 48.8 688 525 54.4 654 513 61.071 777 446 50.1 742 433 55.7 706 420 62.3

8563 701 701 48.2 674 674 54.0 648 648 60.767 723 648 48.8 692 635 54.5 659 621 61.171 775 557 50.1 741 544 55.8 705 531 62.4

23,700

7563 681 553 48.2 651 540 53.4 617 526 59.967 734 450 48.8 701 437 54.6 665 424 61.271 791 346 50.1 756 334 56.1 717 321 62.7

8063 689 671 47.8 660 655 53.7 631 631 60.367 733 574 49.0 701 562 54.7 665 548 61.371 790 471 50.5 754 459 56.1 716 446 62.7

8563 727 727 48.9 701 701 54.6 672 672 61.467 739 696 49.2 708 682 54.9 674 665 61.571 789 596 50.5 754 583 56.1 716 569 62.7

Table 19: MPS 062 High Airflow Cooling Capacities

CFMEntering Air


85° 95° 105°


21,000

7563 680 525 47.8 651 513 53.4 616 499 59.967 733 433 49.0 701 420 54.6 666 407 61.271 792 340 50.5 757 327 56.1 719 315 62.8

8063 684 636 47.9 655 622 53.5 624 609 60.167 733 545 49.1 700 532 54.7 665 518 61.371 790 452 50.5 756 439 56.2 717 426 62.8

8563 711 711 48.5 686 686 54.3 659 659 61.067 737 658 49.2 706 644 54.8 671 630 61.471 791 564 50.5 757 552 56.1 718 538 62.8

24,000

7563 696 564 48.2 662 551 53.8 629 536 60.367 748 459 49.4 714 446 55.0 678 433 61.671 806 481 50.9 769 468 56.6 – – –

8063 704 687 48.4 672 669 54.0 644 644 60.767 748 586 49.5 714 573 55.1 678 560 61.671 806 481 50.9 769 468 56.6 – – –

8563 743 743 49.3 716 716 55.0 687 687 61.867 755 711 49.6 721 697 55.3 688 680 61.971 808 609 50.9 771 596 56.5 – – –

27,000

7563 707 601 48.5 674 587 54.0 640 572 60.667 760 485 49.8 725 471 55.4 688 458 61.971 819 367 51.2 – – – – – –

8063 722 722 48.8 695 695 54.5 666 666 61.267 760 626 49.8 726 613 55.4 689 599 62.071 820 510 51.3

8563 769 769 49.9 741 741 55.7 711 711 62.567 772 760 50.1 740 740 55.8 709 709 62.671 820 652 51.3 – – – – – –

36 Daikin CAT 250-8

Performance Data




CFMEntering Air


85° 95° 105°


22,000

7563 784 586 57.6 743 568 64.7 697 548 73.167 838 484 58.8 794 467 66.0 746 448 74.471 896 381 60.1 849 364 67.5 796 465 75.9

8063 788 705 57.6 746 687 64.8 702 667 73.267 838 604 58.8 794 586 66.1 747 568 74.571 894 500 60.1 847 484 67.5 796 465 75.9

8563 804 804 57.9 770 770 65.4 732 732 74.067 839 723 58.8 796 705 66.2 749 686 74.671 894 621 60.2 847 603 67.6 796 585 75.9

26,000

7563 803 637 58.0 761 619 65.2 714 599 73.667 857 518 59.2 812 501 66.5 762 482 74.971 915 399 60.6 867 382 68.0 814 364 76.4

8063 809 774 58.1 768 753 65.4 725 725 73.867 858 659 59.3 813 641 66.6 763 622 75.071 915 539 60.6 866 522 68.0 813 504 76.4

8563 845 845 58.9 808 808 66.4 767 767 75.067 861 796 59.4 819 778 66.8 769 755 75.271 913 679 60.7 865 662 68.1 812 643 76.4

30,000

7563 819 687 58.3 774 668 65.6 726 648 73.967 873 552 59.6 826 535 66.9 775 516 75.271 930 415 61.0 880 399 68.4 - - -

8063 831 830 58.6 793 793 66.0 751 751 74.567 874 712 59.7 827 694 67.0 776 674 75.371 929 576 61.0 879 559 68.4 - - -

8563 877 877 59.7 838 838 67.2 795 795 75.867 881 862 59.9 836 835 67.3 793 793 75.971 928 735 61.1 879 718 68.5 - - -


CFMEntering Air


85° 95° 105°


22,000

7563 851 615 65.0 809 597 72.8 765 577 81.767 910 513 66.3 865 495 74.2 817 476 83.271 970 409 67.9 922 391 75.8 872 372 84.8

8063 853 735 65.0 811 716 72.8 768 697 81.867 909 632 66.3 864 614 74.2 817 596 83.271 969 528 67.9 922 511 75.8 871 492 84.8

8563 861 850 65.2 822 822 73.2 787 787 82.367 910 752 66.4 866 734 74.3 819 715 83.371 968 648 67.9 921 630 75.8 871 612 84.9

26,000

7563 873 667 65.5 831 649 73.3 785 629 82.267 932 547 66.9 885 529 74.8 836 510 83.771 994 426 68.5 944 409 76.4 891 390 85.4

8063 878 806 65.6 835 786 73.4 789 765 82.467 930 687 66.9 885 670 74.8 836 650 83.771 992 566 68.5 942 549 76.4 890 530 85.4

8563 903 903 66.2 866 866 74.2 826 826 83.467 935 827 67.1 889 808 75.0 840 788 84.071 991 707 68.6 942 689 76.5 890 671 85.5

30,000

7563 891 717 65.9 847 699 73.7 799 679 82.667 949 581 67.4 901 563 75.2 850 544 84.271 1011 443 69.0 958 425 76.9 904 407 85.9

8063 899 871 66.1 855 847 74.0 813 813 83.067 949 741 67.4 901 723 75.3 850 703 84.371 1008 604 69.0 957 586 76.9 903 567 85.8

8563 940 940 67.1 900 900 75.2 858 858 84.467 954 897 67.6 907 875 75.5 858 851 84.671 1009 764 69.0 958 746 77.0 905 727 86.0

Daikin CAT 250-8 37

Performance Data

MPS 015 to 062 Ton AHRI Correction Multipliers

Electric Heating Capacity

Note: * Temperature rise is calculated at nominal cfm

Hot Water Heating Capacity

Note: * Temperature rise is calculated at nominal cfm. Water temperature drop = 20°

Table 22: MPS 015–062 Multipliers

Option% Multiplier

Capacity EER IEER

Gas (high) 100 99 99Gas (low) 100 99 99HW (high) 100 99 99HW (low) 100 99 99Electric 100 99 99

Economizer 100 99 99VFD 100 99 99

Table 23: MPS 015–075 Electric Heating Capacities

UnitNomcfm

StagesLow Heat Medium Heat High Heat

kW MBhDelta

T*Min. cfm

kW MBhDelta

T*Min. cfm

kW MBhDelta

T*Min. cfm

015 6000 4 18 61 9.3 950 36 123 18.6 1900 72 246 37.2 3800017 6800 4 18 61 8.2 950 36 123 16.4 1900 72 246 32.8 3800020 8000 4 36 123 14.1 1900 54 184 21.1 2900 72 246 28.2 3800026 10,000 4 54 184 16.9 2900 72 246 25.5 3800 90 307 31.4 4800030 12,000 4 54 184 14.2 2900 72 246 19.0 3800 90 307 23.7 4800035 14,000 4 54 184 12.2 2900 72 246 16.3 3800 90 307 20.3 4800040 16,000 4 72 246 14.2 3800 90 307 17.8 4800 108 369 21.3 5700050 20,000 4 72 246 11.4 3800 90 307 14.2 4800 108 369 17.1 5700062 24,000 4 100 342 13.1 14,000 160 546 21.0 14,000 200 684 26.3 14,000070 26,000 4 100 342 12.1 14,000 160 546 19.6 14,000 200 684 24.2 14,000075 28,000 4 100 342 11.3 14,000 160 546 18.0 14,000 200 684 22.5 14,000

Table 24: MPS 015–050 Hot Water Heating Capacities

UnitNomcfm

Low Heat High Heat

MBhDelta

T*GPM

Min. cfm

Inlet dia.

MBhDelta

T*GPM

Min. cfm

Inlet dia.

015 6000 145 22.4 25.9 1850 1.5 270 41.7 25.9 1850 1.5017 6800 158 21.5 30.2 1850 1.5 302 41.1 32.0 1850 1.5020 8000 233 26.6 26.6 1850 1.5 415 40.7 40.0 1850 1.5026 10,000 312 28.6 32.8 2900 1.5 640 58.5 63.0 2900 2.5030 12,000 297 22.8 29.0 2900 1.5 553 42.5 57.2 2900 2.5035 14,000 315 20.7 30.5 2900 1.5 614 40.4 60.8 2900 2.5040 16,000 389 22.4 34.0 2900 1.5 758 43.7 69.5 2900 2.5050 20,000 446 20.6 43.4 2900 1.5 878 40.5 87.0 2900 2.5

38 Daikin CAT 250-8

Performance Data

Gas Heating Capacity

Note: 1 Modulating gas heat only.2 Modulating gas heat not available with propane.3 See Table 7, page 29 and Table 8, page 30 for connection sizes.4 Stainless steelheat exchanger only in 100% OA configuration only.

Table 25: MPS 015–075 Gas Heating Capacities

Data

Unit Size

015–020 015–020 026–035 026–035 040–050 040–050 062, 070, 075

Low Heat

High Heat

Low Heat

High Heat

Low Heat

High Heat

Low Heat

Medium Heat

High Heat

Heating Input (MBh) 240 480 300 600 400 800 500 800 988Heating Output (MBh) 192 384 240 480 320 640 400 640 790Steady State Efficiency 80% 80% 80% 80% 80% 80% 80% 80% 80%Number of Stages 2 4 2 4 2 4 Mod Mod Mod

Turndown1 4:1 8:1 4:1 8:1 4:1 8:1 3:1 3:1 3:1

Minimum Airflow 2960 5920 3700 7400 4900 9800 6000 9600 12,000Maximum Temperature Rise

60°F 60/100°F4 60°F 60/85°F4 60°F 60/85°F4 61°F 61°F 61°F

Gas Main PressureNatural Gas (in. wc)Staged Heat

7-14 7-14 7-14 7-14 7-14 7-14 — — —

Natural Gas (in. wc)Modulating Heat

10-14 10-14 10-14 10-14 10-14 10-14 7-13.5 7-13.5 7.5-13.5

Liquid Propane (in. wc) 12-14 12-14 12-14 12-14 12-14 12-14 7-13.5 7-13.5 7.5-13.5Connection Pipe sz/qty 3/4"/1 3/4"/2 3/4"/1 3/4"/2 3/4"/1 3/4"/2 1"/1 1-1/4"/1 1-1/4"/1Manifold PressureNatural Gas (per gas valve)Stage 1 (in. wc) 1.2 1.2 1.2 1.2 1.2 1.2 N/A N/A N/AStage 2 (in. wc) 3.2 3.2 3.2 3.2 3.2 3.2 N/A N/A N/A

Modulating Low fire2 0.4 0.4 0.4 0.4 0.4 0.4 N/A N/A N/A

Propane3

Stage 1 (in. wc) 2.3 2.3 2.3 2.3 2.3 2.3 N/A N/A N/AStage 2 (in. wc) 10.0 10.0 10.0 10.0 10.0 10.0 N/A N/A N/A

Daikin CAT 250-8 39

Performance Data

Pressure DropsTable 26: Component Pressure Drops—MPS 015–050

Component UnitUnit Airflow (CFM)

4000 6000 8000 10,000 12,000 14,000 16,000 18,000 20,000

Economizer/RA/OA

015–017 0.01 0.02 0.03 - - - - - -020 0.01 0.02 0.03 0.05 - - - - -

026–035 - 0.01 0.02 0.04 0.06 0.08 - - -040–050 - - 0.01 0.02 0.03 0.04 0.05 0.06 0.08

Filter

015–017 0.04 0.09 0.16 - - - - - -020 0.04 0.09 0.16 0.25 - - - - -

026–035 0.02 0.04 0.07 0.11 0.16 0.21 - - -040 - 0.02 0.05 0.08 0.12 0.16 0.21 - -050 - - 0.04 0.06 0.08 0.11 0.15 0.19 0.23

Cooling Coil

015–017 0.08 0.17 0.31 - - - - - -020 0.08 0.17 0.31 0.50 - - - - -

026–035 - 0.09 0.15 0.24 0.34 0.47 - - -040 - - 0.14 0.22 0.32 0.45 0.58 - -050 - - 0.10 0.15 0.21 0.29 0.38 0.48 0.59

Hot Gas Reheat015–020 0.06 0.11 0.17 0.23 - - - - -026–035 - 0.07 0.10 0.14 0.19 0.23 - - -040–050 - - 0.07 0.09 0.12 0.15 0.18 0.22 0.25

Table 27: Gas Heat Pressure Drops—MPS 015–050

Unit Heat TypeUnit Airflow (CFM)

4000 6000 8000 10,000 12,000 14,000 16,000 18,000 20,000

015–017Low (240MBH) 0.08 0.19 0.33 - - - - - -High (480 MBH) 0.14 0.31 0.55 - - - - - -

020Low (240MBH) - 0.19 0.33 0.52 0.74 - - - -High (480 MBH) - 0.31 0.55 0.86 1.24 - - - -

026–035Low (300MBH) - - 0.10 0.16 0.23 0.31 - - -High (600 MBH) - - 0.18 0.28 0.41 0.56 - - -

040–050Low (400 MBH) - - 0.04 0.07 0.10 0.14 0.18 0.23 0.28High (800 MBH) - - 0.11 0.18 0.26 0.35 0.46 0.58 0.71

Table 28: High Temperature Furnace Airside Pressure Drops

Unit 4000 6000 8000 10,000 12,000 14,000

015 - 017 0.14 0.31 - - - -020 0.14 0.31 0.55 - - -

026 - 035 0.13 0.29 0.53 0.83 - -040 - 050 - 0.26 0.45 0.69 0.98 1.32

Table 29: Hot Water Pressure Drops—MPS 015–050

Unit Heat TypeUnit Airflow (CFM)

4000 6000 8000 10,000 12,000 14,000 16,000 18,000 20,000

015–017015–017 Low (1 row) 0.09 0.17 0.27 - - - - - -015–017 High (2 row) 0.17 0.34 0.68 - - - - - -

020020–025 Low (1 row) - 0.20 0.32 0.52 - - - - -020–025 High (2 row) - 0.28 0.46 0.98 - - - - -

026–035030–035 Low (1 row) - - 0.14 0.20 0.27 0.35 - - -030–035 High (2 row) - - 0.23 0.33 0.46 0.59 - - -

040–050040–050 Low (1 row) - - - 0.19 0.26 0.34 0.42 0.51 0.61040–050 High (2 row) - - - 0.40 0.54 0.69 0.86 1.05 1.25

Table 30: Electric Heat Pressure Drops—MPS 015–050

UnitUnit Airflow (CFM)

4000 6000 8000 10,000 12,000 14,000 16,000 18,000 20,000

015–017 0.05 0.11 0.20 - - - - - -

020 0.05 0.11 0.20 0.31 - - - - -026–035 - 0.05 0.10 0.15 0.22 0.30 0.39 - -040–050 - - 0.05 0.08 0.11 0.15 0.19 0.24 0.30

40 Daikin CAT 250-8

Performance Data

Note: 1Pressure drop is based on 30% of listed airflow.2DX coil pressure drops are based on wet coils. Standard air flow coil not applicable on sizes 070E-075E.

Table 31: Component Pressure Drops—MPS 062–075

ComponentAirflow (cfm)

14,000 16,000 18,000 20,000 22,000 24,000 26,000 28,000 30,000

Outdoor/return

air options1

0–30% outside air hood w/damper 0.06 0.08 0.10 0.12 0.15 0.18 0.21 0.24 0.28100% outside air hood w/damper 0.01 0.02 0.02 0.03 0.03 0.04 0.05 0.05 0.060–100% economizer, w/o RAF 0.08 0.10 0.13 0.16 0.19 0.23 0.27 0.31 0.36

Filter options

30% pleated 0.08 0.10 0.12 0.14 0.16 0.18 0.20 0.25 0.27Prefilter, standard flow 0.17 0.20 0.24 0.28 0.32 0.37 0.41 - -Prefilter, medium flow 0.13 0.15 0.18 0.21 0.25 0.28 0.32 0.35 0.3965% cartridge, standard flow 0.27 0.34 0.41 0.49 0.57 0.66 0.76 - -65% cartridge, medium flow 0.20 0.25 0.31 0.36 0.43 0.49 0.56 0.63 0.7195% cartridge, standard flow 0.38 0.46 0.55 0.64 0.74 0.84 0.95 - -95% cartridge, medium flow 0.29 0.35 0.42 0.49 0.56 0.64 0.72 0.81 0.89

Cooling options2 DX, standard airflow, 5-row, 10 fpi 0.41 0.50 0.59 0.69 0.79 0.89 - - -DX, high airflow, 5-row, 10 fpi - 0.38 0.45 0.52 0.60 0.68 0.79 0.88 0.98

Heating optionsHot water, 1-row 0.12 0.15 0.19 0.22 0.26 0.30 0.35 0.39 0.44Hot water, 2-row 0.24 0.30 0.37 0.44 0.52 0.61 0.69 0.78 0.88Electric heat 0.07 0.10 0.12 0.15 0.18 0.22 0.25 0.29 0.34

FurnaceLow heat 0.10 0.13 0.17 0.21 0.25 0.30 0.35 0.41 0.47Medium heat 0.21 0.12 0.16 0.20 0.24 0.28 0.33 0.38 0.44High heat 0.10 0.12 0.16 0.20 0.24 0.28 0.33 0.38 0.44

Table 32: Pressure Drop—Standard Airflow Energy Wheel

CabinetWheel

Diameter1,000 2,000 3,000 4,000 5,000 6,000 7,000

15 - 20 46 0.30 0.60 0.89 — — — —26 - 35 52 0.18 0.33 0.48 0.62 0.76 — —40 - 50 64 0.15 0.30 0.45 0.60 0.75 0.90 1.32

Table 33: Pressure Drop—High Airflow Energy Wheel

CabinetWheel

Diameter2,000 3,000 4,000 5,000 6,000 7,000 8,000 9,000 10,000 11,000

15 - 20 52 0.33 0.48 0.62 0.76 — — — — — —26 - 35 64 0.30 0.45 0.60 0.75 0.90 1.05 1.20 — — —40 - 50 74 0.18 0.27 0.34 0.42 0.50 0.57 0.65 0.72 0.79 0.87

Table 34: Pressure Drop—Standard Airflow Energy Wheel Filter

Cabinet 1,000 2,000 3,000 4,000 5,000 6,000 7,000

15 - 20 0.01 0.01 0.02 0.03 — — —26 - 35 0.01 0.03 0.08 0.14 0.22 — —40 - 50 0.01 0.02 0.03 0.06 0.10 0.14 0.19

Table 35: Pressure Drop—High Airflow Energy Wheel Filter

Cabinet 2,000 3,000 4,000 5,000 6,000 7,000 8,000 9,000 10,000 11,000

15 - 20 0.03 0.08 0.14 0.22 0.31 0.42 0.55 0.70 0.87 1.0526 - 35 0.02 0.04 0.08 0.12 0.18 0.24 0.31 0.40 0.49 0.5940 - 50 0.01 0.02 0.03 0.05 0.08 0.11 0.14 0.18 0.22 0.26

Table 36: Pressure Drop—Energy Wheel Back Draft Damper

Cabinet 2,000 3,000 4,000 5,000 6,000 7,000 8,000 9,000 10,000 11,000

15 - 20 0.01 0.03 0.04 0.07 0.09 0.12 0.16 0.20 0.24 0.2926 - 35 0.01 0.03 0.04 0.07 0.09 0.12 0.16 0.20 0.24 0.2940 - 50 0.01 0.01 0.02 0.04 0.05 0.07 0.09 0.11 0.14 0.17

Daikin CAT 250-8 41

Performance Data

Hot Water Low/High Heat Curves

Figure 15: MPS 015–017 Low Heat

Figure 16: MPS 015–017 High Heat

4000

cfm

5000

cfm

6000

cfm

7000

cfm

8000

cfm

9000

cfm

1000

0 cf

m

10

15

20

25

30

35

160 180 200 220 240 260

Capacity (MBH)

Wat

er F

low

Rat

e (g

pm

)

4000

cfm

4500

cfm

5000

cfm

5500

cfm

6000

cfm

6500

cfm

7000

cfm

15

20

25

30

35

40

45

50

250 275 300 325 350 375

Capacity (MBH)

Wat

er F

low

Rat

e (g

pm

)

42 Daikin CAT 250-8

Performance Data

Figure 17: MPS 020 Low Heat

Figure 18: MPS 020 High Heat

4000

cfm

5000

cfm

6000

cfm

7000

cfm

8000

cfm

9000

cfm

1000

0 cf

m

10

15

20

25

30

35

160 180 200 220 240 260 280

Capacity (MBH)

Wat

er F

low

Rat

e (g

pm

)

4000

cfm

5000

cfm

6000

cfm

7000

cfm

8000

cfm

9000

cfm

1000

0 c

fm

15

20

25

30

35

40

45

50

225 275 325 375 425 475

Capacity (MBH)

Wa

ter

Flo

w R

ate

(g

pm

)

Daikin CAT 250-8 43

Performance Data



6000

cfm

7000

cfm

8000

cfm

9000

cfm

1000

0 cf

m

1100

0 cf

m

1200

0 cf

m

1300

0 cf

m

1400

0 cf

m

15

20

25

30

35

40

220 240 260 280 300 320 340 360

Capacity (MBH)

Wat

er F

low

Rat

e (g

pm

)

60

00

cfm

70

00

cfm

80

00

cfm

90

00

cfm

10

00

0 c

fm

11

00

0 c

fm

12

00

0 c

fm

13

00

0 c

fm

14

00

0 c

fm

20

25

30

35

40

45

50

55

60

400 450 500 550 600 650 700 750 800

Capacity (MBH)

Wa

ter

Flo

w R

ate

(g

pm

)

44 Daikin CAT 250-8

Performance Data



1100

0 cf

m

1200

0 cf

m

1300

0 cf

m

1400

0 cf

m

1500

0 cf

m

1600

0 cf

m

1700

0 cf

m

1800

0 cf

m

1900

0 cf

m20

000

cfm

20

25

30

35

40

45

50

55

60

65

350 375 400 425 450 475 500 525 550 575 600

Capacity (MBH)

Wat

er F

low

Rat

e (g

pm

)

11

00

0 c

fm

12

00

0 c

fm

13

00

0 c

fm

14

00

0 c

fm

15

00

0 c

fm

16

00

0 c

fm

17

00

0 c

fm

18

00

0 c

fm19

000

cfm

2000

0 cfm

40

60

80

100

120

700 750 800 850 900 950 1,000 1,050 1,100 1,150 1,200

Capacity (MBH)

Wa

ter

Flo

w R

ate

(g

pm

)

Daikin CAT 250-8 45

Performance Data

Figure 23: MPS 062–075 Standard Heat


Capacity (MBh)

Wat

er fl

ow r

ate

(gpm

)

Capacity (MBh)

Wat

er fl

ow r

ate

(gpm

)

46 Daikin CAT 250-8

Performance Data

Hot Water Pressure Drop Curves

Figure 25: MPS 015–017 Pressure Drop

Figure 26: MPS 020 Pressure Drop

0

2

4

6

8

10

10 15 20 25 30 35 40 45 50

Water Flow Rate (GPM)

Pre

ssu

re D

rop

(ft

. hea

d)

High Capacity Coil

Low Capacity Coi

0

2

4

6

8

10

10 15 20 25 30 35 40 45 50

Water Flow Rate (GPM)

Pre

ssu

re D

rop

(ft

. h

ead

)

High Capacity Coil

Low Capacity Coil

Daikin CAT 250-8 47

Performance Data



0

1

2

3

4

5

6

7

8

9

10

10 20 30 40 50 60

Water Fow Rate (gpm)

Pre

ssu

re D

rop

(ft

hd

)

High Capacity Coil

Low Capacity Coil

0

2

4

6

8

10

12

14

25 50 75 100 125

Water Flow Rate (gpm)

Pre

ssu

re D

rop

(ft

hd

)

High Capacity Coil

Low Capacity Coil

48 Daikin CAT 250-8

Supply Fan Performance
Figure 29: 18" SWSI Airfoil Supply Fan

Table 37: Supply Fan Matrix

Cabinet Standard 100% Outdoor AirEnergy Recovery with

Economizer

15 ton 18" 15" 18"17 ton 20" 15" 20"20 ton 22" 18" 22"26 ton 24" 18" 24"30 ton 24" 20" 24"35 ton 24" 20" 24"40 ton 30" 24" 30"50 ton 30" 24" 30"

Daikin CAT 250-8 49




2100 RPM

1900 RPM

1700 RPM

1500 RPM

1300 RPM

1100 RPM

900 RPM

1.5 BHP 2.0 BHP3.0 BHP

5.0 BHP

7.5 BHP

0.0

1.0

2.0

3.0

4.0

5.0

6.0

0 1000 2000 3000 4000 5000 6000 7000 8000 9000 10000 11000 12000

Airflow (CFM)

Stat

ic P

ress

ure

(In H

2)

1900

2100

1700

1500

1300

1100

900

15 BHP

10.0 BHP

7.5 BHP

5.0 BHP

3.0 BHP2.0 BHP

1.5 BHP

50 Daikin CAT 250-8




1800

1600

1400

1200

3.0 HP 5.0 HP

7.5 HP

10.0 HP

15.0 HP

20.0 HP

Daikin CAT 250-8 51


Figure 34: MPS 062–075 40-in. Standard Fan, SWSI Airfoil Supply Fan, Cooling Only or Hot Water

Note: Maximum allowable static pressure at fan bulkhead is 5.0 in. (i.e., supply duct ESP cannot exceed 5.0 in).

Figure 35: MPS 062–075 44-in. Large Fan, SWSI Airfoil Supply Fan, Cooling Only or Hot Water


Airflow - cfm

0 2000 4000 6000 8000 10000120001400016000180002000022000240002600028000300003200034000

Sta

tic P

ress

ure

- in

. w.g

.

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

500

600

700

800

900

1000

1100

3.0

5.0

7.5

10.0

15.0

20.0

25.0

30.0

40.0 BHP

1200 RPM

1150

Airflow - cfm

0 2000 4000 6000 8000 10000 12000 14000 16000 18000 20000 22000 24000 26000 28000 30000 32000 34000

Sta

tic P

ress

ure

- in

. w.g

.

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

500

600

700

800

900 1000 RPM

3.0

5.0

7.5

10.0

15.0

20.0

25.0

30.0

40.0BHP

400

52 Daikin CAT 250-8


Figure 36: MPS 062–075 30-in. Standard Fan, DWDI Airfoil Supply Fan


Figure 37: MPS 062–075 Large Fan, 33-in. Standard Fan, DWDI Airfoil Supply Fan, Gas or Electric Heat


Daikin CAT 250-8 53

Exhaust Fan Performance
Figure 38: 18" Energy Recovery SWSI Air Foil Exhaust Fan Curve

Figure 39: 22" Energy Recovery SWSI Air Foil Exhaust Fan Curve

1.0 HP1.5 HP

2.0 HP

3.0 HP

5.0 HP

0.5HP0.00

1.00

2.00

3.00

4.00

0 1000 2000 3000 4000 5000 6000

Airflow (CFM)

Stat

ic P

ress

ure

(In H

2O)

800

1000

1200

1400

1600

1800

2050

800

1000

1200

1400

1600

1800

5.0 HP

2050

17501600

1400

1200

1000

800

600

2.0 HP3.0 HP

5.0 HP

1.0 HP1.5 HP

0.00

1.00

2.00

3.00

4.00

0 1000 2000 3000 4000 5000 6000 7000 8000 9000 10000

Airflow (CFM)

Stat

ic P

ress

ure

(In H

2O)

1400

1200

1000

800

600

50

54 Daikin CAT 250-8

Figure 40: Energy Recovery Dual SWSI Air Foil Dual 18" Exhaust Fan Curve

Figure 41: Energy Recovery Dual SWSI Air Foil Dual 22" Exhaust Fan Curve

2050 RPM

1800

1600

1400

1200

1000

800

1.5 HP 2.0 HP3.0 HP

5.0 HP

7.5 HP

1.0 HP0.00

1.00

2.00

3.00

4.00

0 2000 4000 6000 8000 10000 12000

Airflow (CFM)

Stat

ic P

ress

ure

(In H

2O)

1800

1600

1400

1200

1000

800

0 RPM

HP

1750 RPM1600

1400

1200

1000

800

600

2.0 HP

3.0 HP

5.0 HP

7.5 HP 10.0 HP

15.0 HP

1.5 HP0.00

1.00

2.00

3.00

4.00

0 2000 4000 6000 8000 10000 12000 14000 16000 18000 20000

Airflow (CFM)

Stat

ic P

ress

ure

(In H

2O)

1400

1200

1000

800

600

0 RPM

5.0 HP

Daikin CAT 250-8 55

Dimensional Data
Dimensional Data
MPS 015–020 Unit Dimensions

Figure 42: MPS 015–020 Cooling/Electric Heating Unit

56 Daikin CAT 250-8

Dimensional Data

Figure 43: MPS 015–020 Cooling/Hot Water Heating Unit

Daikin CAT 250-8 57

Dimensional Data

Figure 44: MPS 015–020 Cooling/Gas Heating Unit

58 Daikin CAT 250-8

Dimensional Data

MPS 015–020 Roof Curb Dimensions

Figure 45: MPS 015–020 Cooling/Heating Curb

Daikin CAT 250-8 59

Dimensional Data

MPS 015–020 with Energy Recovery Wheel Unit Dimensions

Figure 46: MPS 015–020 Cooling Only

Plan View

Return Opening

Supply Opening

A

A �

� A

Condensate Drain

63.02 (1600.7)

74.0 (1879.6)

235.63 (5984.2)

38.6 (980.4)

18.4 (467.4)

63.25 (1606.6)

47.5 (1206.5)

59.7 (1516.4)

37.73 (958.3) TYP (4)

7.36 (186.9)

90.07 (2287.8)

113.41 (2880.6)

137.4 (3489.9)

153.27 (3893.1)

23.25 (590.6) 21.0

(533.4)5.38

(136.7)5.38

(136.7)108.58

(2757.9)

Ener

gy R

ecov

ery

Whe

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Ret

urn

Air

Coi

l & F

ilter

Con

trol

Pan

el

Ret

urn

Air

Supp

ly A

ir

A

Deck Channel (4 Locations) Base Channel

Detail A-A

3.0 (76.2)

2.75 (69.9)

4.5 (114.3)

60 Daikin CAT 250-8

Dimensional Data

Figure 47: MPS 015–020 Gas Heat

63.02 (1600.7)

74.0 (1879.6) 235.63

(5985.0)38.6

(980.4)

18.4 (467.4)

63.25 (1606.6)

47.5 (1206.5)

176.29 (4477.8)

5.0" UP(127)

Gas Line Connection

Plan View

59.7 (1516.4)

37.73 (958.3) TYP (4)

7.36 (186.9)

90.07 (2287.8)

113.41 (2880.6)

137.4 (3489.9)

153.27 (3893.1)

23.25 (590.6) 21.0

(533.4)5.38

(136.7)5.38

(136.7)

A

A �

� A

Return Opening

Supply Opening

108.58 (2757.9) Condensate Drain

Ener

gy R

ecov

ery

Whe

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Ret

urn

Air

Coi

l & F

ilter

Con

trol

Pan

el

Ret

urn

Air

Supp

ly A

ir

A


Detail A-A

3.0 (76.2)

4.5 (114.3)

2.75 (69.9)

Daikin CAT 250-8 61

Dimensional Data

MPS 015–020 Units with Energy Recovery Wheel Roof Curb Dimensions

Figure 48: MPS 015–020 Roof Curb

Plan View

Optional Hot Water Chase

Ret

urn

Air

Ope

ning

Supp

ly A

ir O

peni

ng

54.2 (1377.0)

23.5 (597.0)

2.0 (51.0)

2.0 (51.0)

12.0 (305.0)

1.25 (32.0) TYP

2.0 (51.0)

1.25 (32.0)

63.75 (1619.0)

Inside Curb

47.88 (1216.0)

147.9 (3757.0)

21.25 (540.0)

225.39 (5725.0)

Inside Curb

147.9 (3757.0)

117.59 (2987.0)

Ø.88 Knockout (4) Ø3.00 Knockout (2)

1.0 (26.0)

0.38 (9.7)

23.86 (606.0)

1.0 (26.0)

2.0 (51.0)

2.0 (51.0)

Knockout Detail

3.63 (92.2)

See Knockout Detail

3.75 (95.0)3.63

(92.2)

Curb Cross Section

1

2

3

4

5

67

8

9

1 Unit Base

2 Curb Gasketing

3 2×4 Nailer Strip

4 Galvanized Curb

5 Cant Strip (not furnished)

67 Rigid Insulation (not furnished)

8 Counter Flashing (not furnished)

9 Ductwork (not furnished)

62 Daikin CAT 250-8

Dimensional Data



Daikin CAT 250-8 63

Dimensional Data


64 Daikin CAT 250-8

Dimensional Data


Daikin CAT 250-8 65

Dimensional Data



23.50[597 mm]

2.00[51 mm]

2.00[51 mm] 21.25

[540 mm]

71.38[1813 mm]

15.87[403 mm]

87.25[2216 mm]

(INSIDE CURB)

1.25[32 mm] TYP

3.63[92.2 mm]

3.63[92.2 mm]

93.70[2380 mm]

171.18 (INSIDE CURB)[4348 mm]

63.69[1610 mm]

2.00[51 mm]

2.00[51 mm]

1.00[26 mm]

1.00[26 mm]

2.00[51 mm]

0.38[9.7 mm]

3.75[95 mm]

PLAN VIEW

23.86[606 mm]

CURB CROSS SECTION

KNOCKOUT DETAIL

F

HOT WATERONLY

CHASE

1.00[25 mm]

19.00[483 mm]

66 Daikin CAT 250-8

Dimensional Data

MPS 026–035 with Energy Recovery Wheel Unit Dimensions

Figure 53: MPS 026–035 Cooling Only, Standard Diameter Energy Recovery Wheel

A �

� A

Plan View

Return Opening

Supply Opening

A

Condensate Drain

63.02 (1600.7)

97.5 (2476.5)

235.6 (5984.2)

38.6 (980.4)

18.4 (467.4)

86.75 (2203.5)

71.0 (1803.4)

59.7 (1516.4)

37.73 (958.3) TYP (4)

7.36 (186.9)

90.07 (2287.8)

113.41 (2880.6)

137.4 (3489.9)

153.27 (3893.1)

23.25 (590.6) 21.0

(533.4)5.38

(136.7)5.38

(136.7)108.58

(2757.9)

Ener

gy R

ecov

ery

Whe

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Ret

urn

Air

Coi

l & F

ilter

Con

trol

Pan

el

Ret

urn

Air

Supp

ly A

ir

A


Detail A-A

3.0 (76.2)

2.75 (69.9)4.5

(114.3)

Daikin CAT 250-8 67

Dimensional Data

Figure 54: MPS 026–035 Cooling Only, Large Diameter Energy Recovery Wheel

Plan View

Return Opening

Supply Opening

A

A �

� A

Condensate Drain

74.8 (1899.9)

97.5 (2476.5)

235.6 (5984.2)50.36

(1279.1)

18.4 (467.4)

86.75 (2203.5)

71.0 (1803.4)

59.7 (1516.4)

37.73 (958.3) TYP (4)

7.36 (186.9)

90.07 (2287.8)

113.41 (2880.6)

137.4 (3489.9)

153.27 (3893.1)

23.25 (590.6) 21.0

(533.4)5.38

(136.7)5.38

(136.7)108.58

(2757.9)

Ener

gy R

ecov

ery

Whe

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Ret

urn

Air

Coi

l & F

ilter

Con

trol

Pan

el

Ret

urn

Air

Supp

ly A

ir

A


Detail A-A

3.0 (76.2)

2.75 (69.9)4.5

(114.3)

68 Daikin CAT 250-8

Dimensional Data

Figure 55: MPS 026–035 Gas Heat, Standard Diameter Energy Recovery Wheel

63.02 (1600.7)

97.5 (2476.5)

235.6 (5984.2)

38.6 (980.4)

18.4 (467.4)

86.75 (2203.5)

71.0 (1803.4)

176.29 (4477.8)

5.0" UP(127)

Gas Line Connection

Plan View

59.7 (1516.4)

37.73 (958.3) TYP (4)

7.36 (186.9)

90.07 (2287.8)

113.41 (2880.6)

137.4 (3489.9)

153.27 (3893.1)

23.25 (590.6)

21.0 (533.4)

5.38 (136.7)

5.38 (136.7)

A

A �

� A

Return Opening

Supply Opening


Ener

gy R

ecov

ery

Whe

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Ret

urn

Air

Coi

l & F

ilter

Con

trol

Pan

el

Ret

urn

Air

Supp

ly A

ir

A


Detail A-A

3.0 (76.2)

2.75 (69.9)

4.5 (114.3)

Daikin CAT 250-8 69

Dimensional Data

Figure 56: MPS 026–035 Gas Heat, Large Diameter Energy Recovery Wheel

74.8 (1899.9)

97.5 (2476.5)

235.6 (5984.2)

50.36 (1279.1)

18.4 (467.4)

86.75 (2203.5)

71.0 (1803.4)

176.29 (4477.8)

5.0" UP(127)

Gas Line Connection

Plan View

Return Opening

Supply Opening

59.7 (1516.4)

37.73 (958.3) TYP (4)

7.36 (186.9)

90.07 (2287.8)

113.41 (2880.6)

137.4 (3489.9)

153.27 (3893.1)

23.25 (590.6) 21.0

(533.4)5.38

(136.7)5.38

(136.7)

A

A �

� A


Ener

gy R

ecov

ery

Whe

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Ret

urn

Air

Coi

l & F

ilter

Con

trol

Pan

el

Ret

urn

Air

Supp

ly A

ir

A


Detail A-A

3.0 (76.2)

2.75 (69.9)4.5

(114.3)

70 Daikin CAT 250-8

Dimensional Data



Plan View


Ret

urn

Air

Ope

ning

Supp

ly A

ir O

peni

ng

54.2 (1377.0)

23.5 (597.0)

21.25 (540.0)

2.0 (51.0)

2.0 (51.0)

12.0 (305.0)

1.25 (32.0) TYP

2.0 (51.0)

147.9 (3757.0)

1.25 (32.0)

87.25 (2216.0)

Inside Curb

71.38 (1813.0)

225.39 (5725.0)

Inside Curb

147.9 (3757.0)

117.59 (2987.0)


1.0 (26.0)

23.86 (606.0)

1.0 (26.0)

2.0 (51.0)

2.0 (51.0)

Knockout Detail

3.63 (92.2)

See Knockout Detail

3.75 (95.0)

0.38 (9.7)

3.63 (92.2)

Curb Cross Section

1

2

3

4

5

67

8

9

1 Unit Base

2 Curb Gasketing

3 2×4 Nailer Strip

4 Galvanized Curb





Daikin CAT 250-8 71

Dimensional Data



72 Daikin CAT 250-8

Dimensional Data


Daikin CAT 250-8 73

Dimensional Data


74 Daikin CAT 250-8

Dimensional Data



CURB CROSS SECTION

2.00[51 mm]

2.00[51 mm]

30.63[778 mm]

87.25[2216 mm]

(INSIDE CURB)

2.00[51 mm]

1.25 TYP[32 mm]

69.39[1763 mm]

105.45[2678 mm]

208.57 (INSIDE CURB)[5298 mm]

71.38[1813 mm]

15.87[403 mm]

28.25[718 mm]

2.00[51 mm]

2.00[51 mm]

1.00[25 mm]

3.75[95 mm]

28.92[735 mm]

PLAN VIEW

F

1.00[25 mm]

26.00[660 mm]

HOT WATERONLY

CHASE

3.63[92.2 mm]

3.63[92.2 mm]

0.38[9.7 mm]

Daikin CAT 250-8 75

Dimensional Data

MPS 040–050 Units with Energy Recovery Wheel Dimensions

Figure 62: MPS 040–050 Cooling Only

Plan View

Return Opening

Supply Opening

A

Condensate Drain

A �

� A

84.8 (2153.9)

97.5 (2476.5)

273.15 (6938.0)

46.22 (1173.9)

27.09 (688.1)

86.75 (2203.5)

71.0 (1803.4)

59.71 (1516.6)

36.78 (934.2) TYP (4)

7.36 (186.9)

96.41 (2448.8)

119.93 (3046.2)

147.68 (3751.1)

165.08 (4193.0)

30.25 (768.3) 28.0

(711.2)5.38

(136.7)5.38

(136.7)114.83

(2916.6)

Ener

gy R

ecov

ery

Whe

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Ret

urn

Air

Coi

l & F

ilter

Con

trol

Pan

el

Ret

urn

Air

Supp

ly A

ir

A


Detail A-A

3.0 (76.2)

2.75 (69.9)4.5

(114.3)

76 Daikin CAT 250-8

Dimensional Data

Figure 63: MPS 040–050 Gas Heat

A �

� A

Plan View

Return Opening

Supply Opening

A

Condensate Drain

193.8 (4922.5)

5.0" UP (127)

Gas Line Connection

84.8 (2153.9)

97.5 (2476.5)

273.15 (6938.0)46.22

(1173.9)

27.09 (688.1)

86.75 (2203.5)

71.0 (1803.4)

59.7 (1516.4)

36.78 (934.2) TYP (4)

7.36 (186.9)

96.41 (2448.8)

119.93 (3046.2)

147.68 (3751.1)

165.08 (4193.0)

30.25 (768.3) 28.0

(711.2)5.38

(136.7)5.38

(136.7)114.83

(2916.6)

Ener

gy R

ecov

ery

Whe

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Dec

k C

hann

el

Ret

urn

Air

Coi

l & F

ilter

Con

trol

Pan

el

Ret

urn

Air

Supp

ly A

ir

A


Detail A-A

3.0 (76.2)

2.75 (69.9)4.5

(114.3)

Daikin CAT 250-8 77

Dimensional Data



Plan View


Ret

urn

Air

Ope

ning

Supp

ly A

ir O

peni

ng

54.2 (1377.0)

2.0 (51.0)

2.0 (51.0)

12.0 (305.0)

1.25 (32.0) TYP

2.0 (51.0)

1.25 (32.0)

87.25 (2216.0)

Inside Curb

71.38 (1813.0)

84.83 (2155.0)

159.65 (4055.0)

28.25 (718.0)

36.44 (925.0)

123.59 (3139.0)

159.65 (4055.0)

262.77 (6674.0)

Inside Curb


1.0 (26.0)

23.86 (606.0)

1.0 (26.0)

2.0 (51.0)

2.0 (51.0)

Knockout Detail

3.63 (92.2)

See Knockout Detail

3.75 (95.0)

0.38 (9.7)

3.63 (92.2)

Curb Cross Section

1

2

3

4

5

67

8

9

1 Unit Base

2 Curb Gasketing

3 2×4 Nailer Strip

4 Galvanized Curb





78 Daikin CAT 250-8

Dimensional Data

MPS 062 Unit and Curb DimensionsNote: Exact length varies with options (refer to MPS 062–075 Additional Curb Dimensions‚ page 81).

Figure 65: Longest MPS 062 Cooling/Gas or Electric Heating Unit

Figure 66: Shortest MPS 062 Cooling Only Unit

Daikin CAT 250-8 79

Dimensional Data

MPS 070–075 Unit and Curb DimensionsNote: Exact length varies with options (refer to MPS 062–075 Additional Curb Dimensions‚ page 81).

Figure 67: Longest MPS 070–075 Cooling/Gas or Electric Heating Unit

Figure 68: Shortest MPS 070–075 Cooling Only Unit

80 Daikin CAT 250-8

Dimensional Data

MPS 062–075 Additional Curb Dimensions

Figure 69: Curb Cross Section

Figure 70: Curb Cross Section

Figure 71: Roof Curb Dimensions

4.5

14.4

Curb gasketing

2×4 nailer strip

Ductsupport

Counterflashing*

Galvanizedcurb

Roofing material*Cant strip*

Flashing*

Unit base

*Not furnished

Curb gasketing

Rigid insulation*

*Not furnished

9.816

4.6

3.2

4.3

2 × 4 nailer stripCant strip*

14.4

Galvanized curb

Roofingmaterial*Roofingmaterial*

Flashing*

Unit base

Duct support

Curb gasketing

Galvanized curb

Counterflashing*

Rigid insulation*

Rigidinsulation*

Cantstrip*

87 RA OPENING

381.5

B

B2

4A B

81

28

100

8

7.5

5.0

5.0

AA

SA OPENING

(Unit length minus 6.4")

Note:Curb must beinstalled level.

1.5

1.56.86.86.8

B = 61 for size 62 ton unitB = 74 for size 70-75 ton units

Daikin CAT 250-8 81

Dimensional Data

MPS 062–075 Section Dimensions

Figure 72: MPS 062–075 Gas or Electric Heat Section Dimensions

Example: MPS 062

For a custom certified drawing of your specific requirements, consult your local Daikin sales representative.

72

30” Dia

SupplyAir Fan

Mandatory

Air-cooledCondenser

106(Does not affect

curb length)

Air-cooledCondenser

83(Does not affect

curb length)

Air-cooledCondensing

Unit

48

DischargePlenum

DischargePlenum

Mandatory

48

(39.5 sq. ft.)

24

(47.1 sq. ft.)

DX CoilMandatory

48

30%Outside Air

Economizer

72

Outdoor/Return AirMandatory

Electric

Gas

48

48

HeatMandatory

Angular

24

Cartridge(40 sq. ft.)

24

Cartridge(48 sq. ft.)

FilterMandatory

Econ w/ Prop. Exh.Fans, Bottom or

Back Ret.

72

Position A Position B Position D Position F Position G Position K Position M

Size 62

Size 70-75

N/A on Size 70-75

96

33” Dia

Section description Length (in.)

Bottom return economizer with exhaust air fan = 72

Angular filters = 24

Standard size cooling coil = 24

Supply fan = 72

Gas heat = 48

Discharge plenum = 48

Air cooled condensing unit = 83

Total air handler length = 288

Total unit length (including condensing unit) = 371

82 Daikin CAT 250-8

Dimensional Data

Figure 73: MPS 062–075 Cooling Only or Hot Water Section Dimensions

30% OA

48 in.

Economizer

72 in.

TA/30

24 in.

65/9540 ft2

24 in.

65/9548 ft2

48 in.

40.1 ft2

24 in.

47.4 ft2

48 in.

S&HW

48 in.

44 in. Dia

72 in. 83 in.

106 in.

Exhaust/ReturnAir Filter DX Coil Optional

HeatSupply Air

FanAir-Cooled

Condensing Unit

Econ w/ Prop. Exh.Fans, Bottom orBack Ret. Fans

72

Size 62

Size 70-75

N/A on Size 70-75

(Does not affectcurb length)

(Does not affectcurb length)

Daikin CAT 250-8 83

Dimensional Data

MPS 062–075 Knockout Dimensions

Figure 74: Main Control Panel/Discharge Plenum Knockouts

Figure 75: Main Control Panel/Discharge Plenum Knockout Detail

Figure 76: Gas Heat/Heat Section

17.7

3.0 dia. K.O.(qty = 3)

0.9 dia. K.O.(qty = 4)

11.9

12.9

15.3

6.6

18.7

22.3

24.3

7.6

8.8

Reference fromleaving air end of section

5.112.1

3.4

4.84.6

2.0

9.7

2.1 3.1 4.3

0.9 diameter K.O. (quantity = 4)

3.0 diameter K.O. (quantity = 3)

Recommended p iping entrance (through the curb)

BA

C

D

A B C D

8.6 6.0 4.2 4.0

84 Daikin CAT 250-8

Weight Data
Weight Data
MPS 015–050 Unit and Curb Weights

The following tables detail overall unit weight. Figure 77 details weight distribution percentages and loading point locations..

.

Table 38: Unit Base Weights

Unit (Tons) Total Weight (lbs)

015 2655017 2705020 3610026 3610030 3610035 3660040 4685050 4985

Table 39: Unit Curb Weights

Unit (tons) Curb Height (inches) Total Weight (lbs)

Standard Unit

015–03514" 34124" 504

040–05014" 46124" 706

Unit with Energy Wheel

015–03514" 45824" 674

040–05014" 61924" 908

Table 40: Heat Section Weights

Unit (tons)Weights (lbs)

High Gas Heat Low Gas Heat Electric Heat Hot Water Heat

015 200 100 120 195017 200 100 120 195020 200 100 120 195

026, 030 270 135 270 291035 270 135 270 291040 350 175 350 307050 350 175 350 307

Table 41: Energy Recovery Section Weights

Unit Weight (lbs.)

015–020 1200026–035 1540040–050 1800

Daikin CAT 250-8 85

Weight Data

Figure 77: Weight Distribution Locations and % of Total Load (MPS 030–035 Example)

Figure 78: Weight Distribution Locations and % of Total Load (MPS 050 Example)

Note: Loading points G & H are only on the 040–050 units and not on the 015–035 units with energy recovery feature.

MPS 015–050 Weight Distribution Percentage

The following table details unit weights for the MPS 015–050 ton units.

Table 42: Weight Distribution Locations (see Figure 77)

Unit (Tons)Distance

L1 L2 L3

015–035 Ton Unit 35.5 62.0 52.0040–050 Ton Unit 40.0 69.0 89.0

Table 43: Curb Weights

Unit (Tons) / Curb Height

Weight (lbs)without ERW with ERW

015–035 / 14" Curb 341 458015–035 / 24" Curb 501 674040–050 / 14" Curb 481 619040–050 / 24" Curb 708 908

Table 44: Weight Distribution Locations (see Figure 78)

Unit (Tons)Distance

L1 L2 L3 L4

040/050 Ton Unit 42.2 66.6 58.3 60.9

L1

L2

L3

L4

B

A CE

G

D

FH

Table 45: Weight Distribution

Unit

Point

Percent of total

A B C D E F G H

015–050 without Energy Wheel 11% 11% 20% 24% 16% 18% N/A N/A015–035 with Energy Wheel 13% 12% 20% 21% 17% 17% N/A N/A040–050 with Energy Wheel 12% 12% 13% 13% 12% 12% 13% 13%

86 Daikin CAT 250-8

Weight Data

MPS 062–075 Unit Weights

The following table details unit weights for the MPS 062–075 ton units. \

Note: Basic unt consists of return air plenum, angular filter section, supply air fan section without fan or motor, cooling section without coil, and condensing unit.

6-Row Coil and HGRH Coil Weights

Fan Motor Weights

Roof Curb Weights

Calculate the weight of the unit curb using the following equations:

Note: Curb length does not include condenser length.

Additional Weights1 For bottom return opening, add 91 lbs.

2 For bottom discharge opening, add 78 lbs.

3 Cross supports:– For curb length greater than 288 in., add 30 lbs.

Example: MPS 070E with Gas Heat

Note: For structural purposes, consider roof curb weight.

Table 46: MPS 062 to 075 (lbs.)

Components 062E 070E 075E

Unit configurationMPS, basic unit* 5460 5720 5895Outdoor/return air optionsReturn air plenum Included in basic unit0–30% O.A. hood 222 222 222 0–100% economizer 1065 1065 1065 Filter options30% pleated 4 4 4 65% cartridge—standard flow 57 57 57 —Medium flow 538 538 538 95% cartridge—standard flow 67 67 67 —Medium flow 550 550 550 Supply air fan assemblyCooling only or hot water 1217 1217 1217Gas or electric heat 965 965 965Evaporator coils—aluminum fins, standard airflow face area5-row, 10 fpi 559 N/A N/AEvaporator coils—aluminum fins, high airflow face area5-row, 10 fpi 1224 1224 1224 Hot water coil1-row 373 373 3732-row 449 449 449Electric Heat100 kW low capacity electric heat 1555 1555 1555160 kW medium capacity electric heat 1575 1575 1575200 kW high capacity electric heat 1600 1600 1600Gas Heat400 MBh low fire furnace 1630 1630 1630640 MBh medium fire furnace 1690 1690 1690790 MBh high fire furnace 1780 1780 1780Exhaust air fan assembly1 fan, bottom or back return 525 525 5252 fans, bottom or back return 785 785 785Accessory itemsVariable frequency drive—SAF 150 150 150Insulation liners2", 1.5 lbs., with solid liners:weight per foot of unit length

25 25 25

Table 47: Coil Weights

UnitWeight (lbs)

6 Row DX HGRH

15–20 118 70

26–35 164 82

40 187 92

50 231 92

Table 48: Supply, Exhaust and Return Fan Motors

Motor hpWeight (lbs)

Totally enclosed

5 85

7.5 140

10 170

15 235

20 300

25 330

30 390

40 510

Weight formulaBase curb wt. (lb.) = 170 + 0.74 [170 + 2 × curb length (in.)] + additional weight (steps 1-3 below) as required

Component Lbs.Basic unit 5,720

Economizer 1,06530% efficiency filters 4Supply fan 965DX coil— high airflow 1,224SAF motor—40 hp 510

Liners 650= 10,138 lbs

Liner calculationsSection Economizer 6

Filter 2Supply fan 6Heat 4DX coil 4Discharge plenum 4Total length of air handler (feet)

26

× 25 lbs. per ft. = 650 lbs.

Daikin CAT 250-8 87

Electrical Data
Electrical Data
Power Wiring

Table 49: Recommended Supply Data

Ampacity No. of Power Wires per Phase Wire GaugeInsulation

Rating(0°C)

30 1 10 75 40 1 8 7555 1 6 7570 1 4 7585 1 3 7595 1 2 75130 1 1 75150 1 1/0 75175 1 2/0 75200 1 3/0 75230 1 4/0 75255 1 250 75

AmpacityNo. of Power Wires per Phase Wire Gauge

Insulation Rating(0°C)

MPS 015–020 MPS 026–050 MPS 062–075 MPS 015–020 MPS 026–050 MPS 062–075 MPS 015–075300 2 2 1 1/0 1/0 300 75350 2 2 1 2/0 2/0 400 75400 2 2 2 3/0 3/0 3/0 75460 2 2 2 4/0 4/0 4/0 75510 2 2 2 250 250 250 75600 3 3 2 3/0 3/0 350 75690 3 3 2 4/0 4/0 400 75765 3 3 2 250 250 500 75

Table 50: SAF Data and MPS 062–075 EAF Data

HP Voltage Amps

5 208 15.05 230 13.25 460 6.65 575 5.2

7.5 208 23.07.5 230 19.47.5 460 9.77.5 575 8.010 208 26.010 230 25.010 460 13.010 575 10.015 208 37.415 230 35.415 460 17.715 575 14.120 208 49.020 230 47.020 460 24.020 575 19.025 208 63.025 230 60.025 460 31.025 575 24.030 208 74.030 230 70.030 460 35.030 575 28.040 208 11.040 230 96.040 460 48.040 575 38.0

Table 51: Condenser Fan Quantity Data

Unit Size Condenser Fan Quantity

015–020 2026–035 3040–050 4062–070 6

075 8

Table 52: Condenser Fan Motor Data

VoltageFull Load Amps Per Condenser

Fan Motor

208/230 4460 2575 1.7

88 Daikin CAT 250-8

Electrical Data

Table 53: MPS 015–050 Axial Propeller Exhaust Fan Data (MPS 062–075 use 1 or 2 5hp Motors - see Figure 50)

Size Voltage HP Amps Qty. Total (Amps)

15

208 1 4.2 1 4.2230 1 4.0 1 4.0460 1 2.0 1 2.0575 1 1.7 1 1.7

17

208 1 4.2 1 4.2230 1 4.0 1 4.0460 1 2.0 1 2.0575 1 1.7 1 1.7

26

208 1 4.2 2 8.4230 1 4.0 2 8.0460 1 2.0 2 4.0575 1 1.7 2 3.4

30

208 1 4.2 2 8.4230 1 4.0 2 8.0460 1 2.0 2 4.0575 1 1.7 2 3.4

35

208 1 4.2 2 8.4230 1 4.0 2 8.0460 1 2.0 2 4.0575 1 1.7 2 3.4

40

208 1 4.2 3 12.6230 1 4.0 3 12.0460 1 2.0 3 6.0575 1 1.7 3 5.1

50

208 1 4.2 3 12.6230 1 4.0 3 12.0460 1 2.0 3 6.0575 1 1.7 3 5.1

Table 54: Energy Recovery Exhaust Fan

Cabinet Application Size (in [mm])Motor

HPQuantity

15Economizer 18 [457.2] 4.0 1

30% OA 18 [457.2] 4.0 1100% OA 18 [457.2] 4.0 1

17Economizer 22 [558.8] 8.0 1

30% OA 18 [457.2] 4.0 1100% OA 18 [457.2] 4.0 1

20Economizer 22 [558.8] 8.0 1

30% OA 18 [457.2] 4.0 1100% OA 22 [558.8] 8.0 1

26, 30Economizer 18 [457.2] 4.0 2

30% OA 18 [457.2] 4.0 1100% OA 22 [558.8] 8.0 1

35Economizer 22 [558.8] 8.0 2

30% OA 22 [558.8] 8.0 1100% OA 22 [558.8] 8.0 1

40Economizer 22 [558.8] 8.0 2

30% OA 22 [558.8] 8.0 1100% OA 18 [457.2] 4.0 2

50Economizer 22 [558.8] 8.0 2

30% OA 22 [558.8] 8.0 1100% OA 22 [558.8] 8.0 2

Daikin CAT 250-8 89

Electrical Data

Table 55: Energy Recovery Exhaust Fan Amps

Cabinet Application Voltage Amps Quanity Total Amps

15/17 All208/230 8.8 1 8.8

460 4.0 1 4.0575 4.0 1 4.0

20 Economiuzer208/230 13.5 1 13.5

460 6.1 1 6.1575 6.1 1 6.1

20100% &

0-30% OA

208/230 8.8 1 8.8460 4.0 1 4.0575 4.0 1 4.0

26-35 Economizer208/230 13.5 2 27.0

460 6.1 1 6.1575 6.1 1 6.1

26-35 0-30% OA208/230 8.8 1 8.8

460 4.0 1 4.0575 4.0 1 4.0

26-35 100% OA208/230 13.5 1 13.5

460 6.1 1 6.1575 6.1 1 6.1

40

Economizer208/230 13.5 2 27.0

460 6.1 2 12.2575 6.1 2 12.2

0-30% OA208/230 13.5 1 13.5

460 6.1 1 6.1575 6.1 1 6.1

100% OA208/230 8.8 1 8.8

460 4.0 1 4.0575 4.0 1 4.0

50

Economizer& 100% OA

208/230 13.5 2 27.0460 6.1 2 12.2575 6.1 2 12.2

0-30% OA208/230 13.5 1 13.5

460 6.1 1 6.1575 6.1 1 6.1

Table 56: Rated Load Amps Per Compressor—MPS 015–050

Size Voltage Comp #1 Comp #2 Comp #3 Comp #4

15208/230 25.0 23.1 - -

460 12.2 12.2 - -575 9.3 8.7 - -

17208/230 25.0 27.6 - -

460 12.2 13.1 - -575 9.3 11.5 - -

20208/230 17.3 39.1 17.3 -

460 9.6 18.6 9.6 -575 7.7 15.4 7.7 -

26208/230 25.0 25.0 25.0 -

460 12.2 18.6 12.2 -575 9.3 9.3 9.3 -

30208/230 39.1 27.6 27.6 -

460 18.6 13.1 13.1 -575 15.4 11.5 11.5 -

35208/230 39.1 39.1 27.6 -

460 18.6 18.6 13.1 -575 15.4 15.4 11.5 -

40208/230 39.1 39.1 27.6 27.6

460 18.6 18.6 13.1 13.1575 15.4 15.4 11.5 11.5

50208/230 39.1 39.1 39.1 39.1

460 18.6 18.6 18.6 18.6575 15.4 15.4 15.4 15.4

90 Daikin CAT 250-8

Electrical Data

Supply Power Wiring Data Electric Heater Data

The following formulas can be used to calculate Minimum circuit Ampacity (MCA) and Maximum Rated Overcurrent Protection Device (MROPD).

Cooling Only/Cooling with Gas Heat/Hot Water Heat

MCA = 1.25 x current draw of largest motor/compressor + current draw of the rest of the motors/compressors + 1 (controls).

MROPD = 2.25 x current draw of largest motor/compressor + current draw of the rest of motors/compressors + 1 (controls).

Elect. Heat (sizes 15–70 and size 75 with 160–200 kW)

MCA = 1.25 x (supply fan motor amps + exhaust fan motor amps + transformer) + electric heat load.

MROPD = 2.25 (largest fan motor) + electric heat load + remaining fan motor + transformer.

Electric Heat (Size 75, 100 kW)

MCA = 1.25 x current draw of largest motor/compressor + current draw of the rest of the motors/compressors + 1 (controls).

MROPD = 2.25 x current draw of largest motor/compressor + current draw of the rest of motors/compressors + 1 (controls).

Table 57: Rated Load Amps—MPS 062–075

Model VoltageCircuit 1 Circuit 2

RLA / comp

Comp Qty

RLA / comp

Comp Qty

062

208-60-3 56.7 2 56.7 2

230-60-3 51.3 2 51.3 2

460-60-3 23.1 2 23.1 2

575-60-3 19.9 2 19.9 2

070

208-60-3 36.8 3 36.8 3

230-60-3 33.3 3 33.3 3

460-60-3 17.9 3 17.9 3

575-60-3 12.8 3 12.8 3

75

208-60-3 53.2 3 53.2 3

230-60-3 48.1 3 48.1 3

460-60-3 18.6 3 18.6 3

575-60-3 14.7 3 14.7 3

Table 58: MPS 020–050 Electric Heater DatakW Voltage Amps18 208 5018 230 4518 460 2318 575 1836 208 10036 230 9036 460 4536 575 3654 208 15054 230 13054 460 6554 575 5272 208 20072 230 17372 460 8672 575 7090 208 25090 230 21790 460 10890 575 87108 460 130108 575 104

Table 59: MPS 062–075 Electric Heat Data

Model208/60/3 240/60/3 480/60/3 600/60/3

kW FLA Stages kW FLA Stages kW FLA Stages kW FLA Stages

100 74.7 207.4 4 99.5 239.4 4 99.5 119.7 4 99.5 95.7 4160 119.7 332.0 4 159.2 383.0 4 159.2 191.5 4 159.2 153.2 4200 - - - - - - 199.0 239.4 4 199.0 191.5 4

Daikin CAT 250-8 91

Engineering Guide Specification
Part 1: General

1.01 Section Includes:A Packaged rooftop air conditioners.

1.02 ReferencesA AFBMA 9-Load Ratings and Fatigue Life for Ball

Bearings.

B AMCA 99-Standards Handbook.

C AMCA 210-Laboratory Methods of Testing Fans for Rating Purposes.

D AMCA 300-Test Code for Sound Rating Air Moving Devices.

E AMCA 500-Test Methods for Louver, Dampers, and Shutters.

F ARI 410-Forced-Circulation Air-Cooling and Air-Heating Coils.

G ARI 430-Central-Station Air-Handling Units.

H ARI 435-Application of Central-Station Air-Handling Units.

I IBC 2000 - International Building Code.

J NEMA MG1-Motors and Generators.

K National Electrical Code.

L NFPA 70-National Fire Protection Agency.

M SMACNA-HVAC Duct Construction Standards-Metal and Flexible.

N UL 900-Test Performance of Air Filter Units.

1.03 SUBMITTALS

A Shop Drawings: Indicate assembly, unit dimensions, weight loading, required clearances, construction details, field connection details, electrical characteristics and connection requirements.

B Product Data:

1 Provide literature that indicates dimensions, weights, capacities, ratings, fan performance, and electrical characteristics and connection requirements.

2 Provide computer generated fan curves with specified operating point clearly plotted.

3 Manufacturer's installation instructions.

1.04 Operation And Maintainence Data

A Maintenance Data: Provide instructions for installation, maintenance and service.

1.05 Qualifications

A Manufacturer: Company specializing in manufacturing the Products specified in this section with minimum five years documented experience, who issues complete catalog data on total product.

B Startup must be done by trained personnel experienced with rooftop equipment.

C Do not operate units for any purpose, temporary or permanent, until ductwork is clean, filters and remote controls are in place, bearings lubricated, and manufacturers' installation instructions have been followed.

1.06 Delivery, Storage, And Handling

A Deliver, store, protect and handle products to site.

B Accept products on site and inspect for damage.

C Store in clean dry place and protect from weather and construction traffic. Handle carefully to avoid damage to components, enclosures, and finish.

Part 2: Products

2.01 ManufacturersA Basis of Design: Daikin International

1 Daikin.

2 Trane.

3 Carrier.

4 York.

5 AAON.

2.02 General DescriptionA Furnish as shown on plans, Daikin Maverick

Singlezone Heating and Cooling Unit(s) model MPS. Unit performance and electrical characteristics shall be per the job schedule.

B Configuration: Fabricate as detailed on prints and drawings:

1 Return plenum/economizer section.

2 Filter section.

3 Cooling coil section.

4 Supply fan section.

5 Gas heating section.

6 Electric heating section.

7 Hot water heating section.

8 Condensing unit section.

C The complete unit shall be cETLus/MEA listed.

D The burner and gas train for the unit furnace shall be cETLus approved.

E Each unit shall be specifically designed for outdoor rooftop application and include a weatherproof cabinet. Each unit shall be completely factory assembled and shipped in one piece. MPS packaged units shall be shipped fully charged with Refrigerant 410A and oil.

92 Daikin CAT 250-8


F The unit shall undergo a complete factory run test prior to shipment. The factory test shall include final balancing of the supply fan assemblies, a refrigeration circuit run test, a unit control system operations checkout, a unit refrigerant leak test and a final unit inspection.

G All units shall have decals and tags to indicate caution areas and aid unit service. Unit nameplates shall be fixed to the main control panel door. Electrical wiring diagrams shall be attached to the control panels. Installation, operating and maintenance bulletins and start-up forms shall be supplied with each unit.

H Performance: All scheduled capacities and face areas are minimum accepted values. All scheduled amps, kW, and HP are maximum accepted values that allow scheduled capacity to be met.

I Warranty: The manufacturer shall provide 12-month parts only warranty. Defective parts will be repaired or replaced during the warranty period at no charge. The warranty period shall commence at startup or six months after shipment, whichever occurs first.

2.03 Cabinet, Casing, And FrameA Panel construction shall be double-wall construction for all

panels. All floor panels shall have a solid galvanized steel inner liner on the air stream side of the unit to protect insulation during service and maintenance. Insulation shall be a minimum of 1" thick with an R-value of [4.0 on MPS 015–050 ton units] [6.5 on MPS 062–075 ton units], and shall be neoprene coated glass fiber. Panel design shall include no exposed insulation edges. Unit cabinet shall be designed to operate at total static pressures up to [5.0 on sizes 020–050] [6.5 on sizes 062–075] inches w.g.

B Double wall construction shall be the minimum design in all sections down stream of the cooling coil section. This shall include the fan, gas heat, and discharge plenum sections as a minimum.

C Exterior surfaces shall be constructed of pre-painted galvanized steel for aesthetics and long term durability. Paint finish to include a base primer with a high quality, polyester resin topcoat of a neutral beige color. Finished panel surfaces to withstand a minimum 750-hour salt spray test in accordance with ASTM B117 standard for salt spray resistance.

D Service doors shall be provided on both sides of the fan section, coil section, economizer section, control panel, and the filter section in order to provide user access to unit components. All service access doors shall be mounted on multiple, stainless steel hinges and shall be secured by a latch system. Removable service panels secured by multiple mechanical fasteners are not acceptable.

E The unit base shall overhang the roof curb for positive water runoff and shall seat on the roof curb gasket to provide a positive, weathertight seal. Lifting brackets shall

be provided on the unit base to accept cable or chain hooks for rigging the equipment.

2.04 Supply Fan

A Supply fan shall be a [SWSI airfoil centrifugal fan] [DWDI on sizes 062–075 with gas or electric heat]. The fan blade design shall be a double blade with the airfoil geometry, a backward inclined blade fan wheel design will not be acceptable. The fan wheel shall be Class II construction with aluminum fan blades welded to the back plate and end rim. The supply fan shall be mounted using solid-steel shafts and wheel hubs with mating keyways.

B The fan assembly shall have fixed pitched drives with a minimum of two belts. The drives shall be selected with a minimum diameter of 4 inches and a 1.2 service factor. The belts shall be of the grip-notch design.

C All fan assemblies shall be statically and dynamically balanced at the factory, including a final trim balance, prior to shipment. All fan assemblies shall employ solid steel fan shafts. Heavy-duty concentric locking pillow block type, self-aligning, grease lubricated ball bearings shall be used. Bearings shall be sized to provide a L-50 life at 250,000 hours. The entire fan assembly shall be isolated from the fan bulkhead and mounted on spring isolators [1" on sizes 015–050] [2" on sizes 062–075].

D Fan motors shall be heavy-duty 1800 rpm open drip-proof (ODP) type with grease lubricated ball bearings. Motors shall be premium efficiency. Motors shall be mounted on an adjustable base that provides for proper alignment and belt tension adjustment. Motors shall be suitable for use with a variable frequency drive.

E The supply fan shall be capable of airflow modulation from 30% to 100% of the scheduled designed airflow. The fan shall not operate in a state of surge at any point within the modulation range.

2.05 Exhaust FanA Exhaust fans shall be provided. Blades shall be constructed

with fabricated steel and shall be securely attached to fan shafts. All exhaust fan assemblies shall be statically and dynamically balanced. Motors shall be permanently lubricated, heavy-duty type, carefully matched to the fan load. Ground and polished steel fan shafts shall be mounted in permanently lubricated and sealed ball bearings. Bearings shall be selected for a minimum (L10) life in excess of 100,000 hours at maximum cataloged operating speeds.

B The unit DDC controller shall provide building static pressure control. A factory mounted exhaust fan variable frequency drive shall provide proportional control of the exhaust fans from 25% to 80% of the supply air fan designed airflow. The field shall mount the required sensing tubing from the building to the factory mounted building static pressure sensor.

Daikin CAT 250-8 93


2.06 Variable Air Volume ControlA An electronic variable frequency drive shall be provided

for the supply air fan. Each drive shall be factory installed in a conditioned cabinet. Drives shall meet UL Standard 95-5V. The completed unit assembly shall be listed by a recognized safety agency, such as ETL. Drives are to be accessible through a hinged door assembly. Mounting arrangements that expose drives to high temperature unfiltered ambient air are not acceptable.

B The unit manufacturer shall install all power and control wiring.

C The supply air fan drive output shall be controlled by the factory installed main unit control system and drive status and operating speed shall be monitored and displayed at the main unit control panel.

2.07 ElectricalA Unit wiring shall comply with NEC requirements and with

all applicable UL standards. All electrical components shall be UL recognized where applicable. All wiring and electrical components provided with the unit shall be number and color-coded and labeled according to the electrical diagram provided for easy identification. The unit shall be provided with a factory wired weatherproof control panel. Unit shall have a single point power terminal block for main power connection. A terminal board shall be provided for low voltage control wiring. Branch short circuit protection, 115-volt control circuit transformer and fuse, system switches, and a high temperature sensor shall also be provided with the unit. Each compressor and condenser fan motor shall be furnished with contactors and inherent thermal overload protection. Supply fan motors shall have contactors and external overload protection. Knockouts shall be provided in the bottom of the main control panels for field wiring entrance.

B A single non-fused disconnect switch shall be provided for disconnecting electrical power at the unit. Disconnect switches shall be mounted internally to the control panel and operated by an externally mounted handle.

C A GFI receptacle shall be unit mounted. The receptacle will require a field power connection independent from the unit's main power block and/or disconnect.

D A GFI receptacle shall be unit mounted. The receptacle shall be powered by a factory installed and wired 120 V, 20 amp power supply. The power supply shall be wired to the line side of the unit's main disconnect, so the receptacle is powered when the main unit disconnect is off. This option shall include a GFI receptacle, transformer, and a branch circuit disconnect. The electrical circuit shall be complete with primary and secondary overload protection.

2.08 Cooling SectionA The cooling coil section shall be installed in a draw through

configuration, upstream of the supply air fan. The coil

section shall be complete with a factory piped cooling coil and an ASHRAE 62.1 compliant sloped drain pan.

B Direct expansion (DX) cooling coils shall be fabricated of seamless high efficiency copper tubing that is mechanically expanded into high efficiency aluminum plate fins. Coils shall be a multi-row, staggered tube design with a minimum of 4 rows and a maximum of 12 fins per inch. All units shall have two independent refrigerant circuits and shall use an interlaced coil circuiting that keeps the full coil face active at all load conditions. All coils shall be factory leak tested with high pressure air under water.

C [Optional] Direct expansion (DX) cooling coils shall be fabricated of seamless high efficiency copper tubing that is mechanically expanded into high efficiency aluminum plate fins. Coils shall be a multi-row, staggered tube design with a minimum of 6 rows for maximum dehumidification effect. All units shall have two independent refrigerant circuits and shall use an interlaced coil circuiting that keeps the full coil face active at all load conditions. All coils shall be factory leak tested with high pressure air under water.

D A stainless steel positively sloped drain pan shall be provided with the cooling coil. The drain pan shall extend beyond the leaving side of the coil. The drain pan shall have a minimum slope of 1/8" per foot to provide positive draining. The slope of the drain pan shall be in two directions and comply with ASHRAE Standard 62.1 The drain pan shall be connected to a threaded drain connection extending through the unit base.

2.09 Staged Gas Heating SectionA The rooftop unit shall include a natural gas heating section.

The gas furnace design shall be one or more natural gas fired heating modules factory installed downstream of the supply air fan in the heat section. Each module shall have two stages of heating control. The heating module shall be a tubular design with in-shot gas burners. The heat exchanger tubes shall be constructed of 20 ga, G160, aluminized steel. The module shall have an induced draft fan that will maintain a negative pressure in the heat exchanger tubes for the removal of the flue gases.

B Each burner module shall have two flame roll-out safety protection switches and a high temperature limit switch that will shut the gas valve off upon detection of improper burner manifold operation. The induced draft fan shall have an airflow safety switch that will prevent the heating module from turning on in the event of no airflow in the flue chamber.

C The factory-installed DDC unit control system shall control the gas heat module. Field installed heating modules shall require a field ETL certification. The manufacturer's rooftop unit ETL certification shall cover the complete unit including the gas heating modules.

D The heating modules shall have a field installed kit for conversion of the unit to LP gas.

94 Daikin CAT 250-8


2.10 Modulating Gas Heating SectionA [015–050 Low Capacity] The rooftop unit shall include a

natural gas heating section. The gas furnace design shall have a natural gas fired heating module factory installed downstream of the supply air fan in the heat section. The module shall be complete with furnace controller and control valve capable of modulating operation from 100% down to 28% of full fire capacity. The heating module shall be a tubular design with in-shot gas burners. The heat exchanger tubes shall be constructed of stainless steel. The module shall have an induced draft fan that will maintain a negative pressure in the heat exchanger tubes for the removal of the flue gases.

B [015–050 High Capacity] The rooftop unit shall include a natural gas heating section. The section design shall be two natural gas fired heating modules factory installed downstream of the supply air fan in the heat section. One module shall have two stages of capacity control. The other module shall be complete with furnace controller and control valve capable of modulating operation from 100% down to 14% of the unit's total full fire capacity. The heating modules shall be a tubular design with in-shot gas burners. The heat exchanger tubes shall be constructed of stainless steel. The module shall have an induced draft fan that will maintain a negative pressure in the heat exchanger tubes for the removal of the flue gases.

C Each 015–050 size burner module shall have two flame roll-out safety protection switches and a high temperature limit switch that will shut the gas valve off upon detection of improper burner manifold operation. The induced draft fan shall have an airflow safety switch that will prevent the heating module from turning on in the event of no airflow in the flue chamber.

D Each 062–075 natural gas fired furnace shall be installed in the unit heat section. The heat exchanger shall include a type 321 stainless steel cylindrical primary combustion chamber, a type 321 stainless steel header, type 321 stainless steel secondary tubes and type 321 stainless steel turbulators. The heat exchanger shall have a condensate drain. Clean out of the primary heat exchanger and secondary tubes shall be accomplished without removing casing panels or passing soot through the supply air passages. The furnace section shall be positioned downstream of the supply air fan to maintain positive pressure around the heat exchanger.

The furnace will be supplied with a modulating forced draft burner. The burner shall be controlled for low fire start. The burner shall be capable of continuous modulation between 33% and100% of rated capacity and shall operate efficiently at all firing rates.

The burner shall be specifically designed to burn natural gas and shall include a microprocessor based flame safeguard control, combustion air proving switch, pre-purge timer and spark ignition. The gas train shall include redundant gas valves, maximum 0.5psi pressure regulator, shutoff cock, pilot gas valve, pilot pressure regulator, and pilot cock.

E The burner shall be rated for operation and full modulation capability at inlet gas pressures down to 7.5 W.C.

F The factory-installed DDC unit control system shall control the gas heat module. Field installed heating modules shall require a field ETL certification. The manufacturer's rooftop unit ETL certification shall cover the complete unit including the gas heating modules.

2.11 Electric Heating SectionA Heating coils shall be constructed of a low watt density,

high nickel chromium alloy resistance wire, mechanically stacked and heli-arc welded to corrosion resistant terminals. A corrosion resistant heavy gauge rack shall support the elements. Safety controls shall include automatic reset high limit control with manual reset backup line break protection. Heating element branch circuits shall be fused to maximum of 48 Amps per NEC requirements.

B The electric heat section shall be positioned downstream of the supply air fan.

C Proof of airflow must be established any time the electric heat element is energized.

D The electric heat elements shall be controlled by the factory installed main unit DDC control system. The control system will have four distinct stages of heating on any unit over 25 tons. Each stage control contactor shall be a three pole contactor. When the stage control contactor is not energized, it must break all three phases of power input to the electric heater.

E The electrical power supply for the electric heater shall be from the rooftop unit control panel. Unit shall have a single point power supply connection. Independent supply power connection to the electric heater will not be accepted.

F All disconnects must be three pole to remove power from all incoming legs.

2.12 Hot Water Heating SectionA A [1] [2] row hot water heating coil shall be factory

installed in the unit heat section. Coils shall be fabricated of seamless 5/8" diameter copper tubing that is mechanically expanded into high efficiency rippled and corrugated aluminum plate fins. All coil vents and drains shall be factory installed. The hot water heat section shall be installed downstream of the supply air fan. A factory-tested

Unit Size Staged Heat Modulating Heat015–050 7–14" w.c. 10–14" w.c.062–075 — 7.5–13.5" w.c.

Daikin CAT 250-8 95


diffuser shall be used in order to provide air distribution across the coil.

B Hot water coil shall be fully cased to allow for easy replacement.

C Factory shall provide a field piping vestibule. The control valve shall be field supplied and installed in the unit heater vestibule. The control valve shall be capable of receiving a 2 - 10 VDC signal. Connection holes through the base of the unit in the field piping vestibule shall be cut and sealed by the field.

D All coil connections shall be copper, steel connections shall not be allowed in order to prevent dielectrics and corrosion.

E Fluid pressure drop shall conform to the mechanical schedule.

F Freeze protection by the DDC controller and use the discharge air sensor. DDC controller shall be capable of sending an alarm signal.

G Coil shall be factory leak tested with high pressure air under water.

2.13 Modulating Hot Gas Reheat Coil Sec-tion A Unit shall be equipped with a hot gas reheat coil with hot

gas coming form the unit condenser.

B The hot gas reheat option shall have a fully modulated control to allow for unit leaving air temperature control to +/- 2°.

C The modulating hot gas reheat systems shall allow for independent control of the cooling coil leaving air temperature and the reheat coil leaving air temperature. The cooling and reheat leaving air temperature setpoints shall be adjustable through the unit MT III controller.

D Hot gas coil shall be an all aluminum design. The aluminum tube shall be a micro channel design with high efficiency aluminum fins. Fins shall be brazed to the tubing for a direct bond. Each condenser coil shall be factory leak tested with high-pressure air under water.

E Hot gas coil shall be sized to allow for full condensing across the operation range of the unit. High temperature liquid shall be piped downstream of the unit's condenser coils into the liquid line.

F The refrigeration circuit shall not require receivers. The hot gas coil shall be used for refrigerant storage when the unit is not operation in a dehumidification or reheat mode.

Hot Gas Reheat Coil Section A Unit shall be equipped with a hot gas reheat coil with hot

gas coming from the unit condenser.

B Hot gas coil shall be an all aluminum design. The aluminum tube shall be a micro channel design with high efficiency aluminum fins. Fins shall be brazed to the tubing

for a direct bond. Each condenser coil shall be factory leak tested with high-pressure air under water.

C Hot gas coil shall be sized to allow for full condensing across the operation range of the unit. High temperature liquid shall be piped downstream of the unit's condenser coils into the liquid line.

D The refrigeration circuit shall not require receivers. The hot gas coil shall be used for refrigerant storage when the unit is not operation in a dehumidification or reheat mode.

2.14 Filters

Draw-Through Filters

A Sizes 020–050 shall be provided with a draw-through filter section. The filter rack shall be designed to accept a 2" prefilter and a 4" final filter. The unit design shall have a hinged access door for the filter section. The manufacturer shall ship the rooftop unit with 2" construction filters. The contractor shall furnish and install, at building occupancy, the final set of filters per the contract documents.

B Size 062–075 ton units shall be provided with a draw-through filter section. The filter section shall be supplied complete with the filter rack as an integral part of the unit. The draw-through filter section shall be provided with [panel] [cartridge] filters.

C Panel filters on size 062–075 units shall be 2" thick AmericanAirFilter 30% efficient pleated panel filters. Filters shall be frame mounted and shall slide into galvanized steel racks contained within the unit. Filters shall be installed in an angular arrangement to maximize filter area and minimize filter face velocity. Filters shall be accessible from both sides of the filter section.

D Cartridge filters on size 062–075 ton units shall have [12" deep [60–65%] [90–95%] efficient, UL Std. 900, Class 1, AmericanAirFilter cartridge filters. 2" panel, 30% efficient pre-filters shall be included. Cartridge filters shall consist of filter media permanently attached to a metal frame and shall slide into a gasketed, extruded aluminum rack contained within the unit. The filter rack shall have secondary gasketed, hinged end panels to insure proper sealing. Filters shall be accessible from both sides of the filter section.

2.15 Outdoor/Return Air SectionA Sizes 015–050 shall be provided with an outdoor air

economizer section. The 0 to 100% outside air economizer section shall include outdoor, return, and exhaust air dampers. The outdoor air hood shall be factory installed and constructed from galvanized steel finished with the same durable paint finish as the main unit. The hood shall include moisture eliminator filters to drain water away from the entering air stream. The outside and return air dampers shall be sized to handle 100% of the supply air volume. The dampers shall be opposed blade design. Damper blades shall be gasketed with side seals to provide

96 Daikin CAT 250-8


an air leakage rate of 4 cfm / square foot of damper area at 1" differential pressure per ASHRAE 90.1 Energy Standard. Leakage rate to be tested in accordance with AMCA Standard 500.

B Sizes 062–075 shall be provided with an outdoor air economizer section. The 0 to 100% outside air economizer section shall include outdoor, return, and exhaust air dampers. Outdoor air shall enter from both sides of the economizer section through horizontal, louvered intake panels complete with rain lip and bird screen. The floor of the outdoor air intakes shall provide for water drainage. The economizer section shall allow return air to enter from the [bottom] [back] of the unit.

The outside and return air dampers shall be sized to handle 100% of the supply air volume. The dampers shall be opposed sets of parallel blades, arranged vertically to converge the return air and outdoor air streams in multiple, circular mixing patterns. Daikin UltraSeal low leak dampers shall be provided. Damper blades shall be fully gasketed and side sealed. Damper leakage shall be less than 0.2% at 1.5 inches static pressure differential. Leakage rate to be tested in accordance with AMCA Standard 500. Damper blades shall be operated from multiple sets of linkages mounted on the leaving face of the dampers.

C A barometric exhaust damper shall be provided to exhaust air out of the back of the unit. A bird screen shall be provided to prevent infiltration of rain and foreign materials. Exhaust damper blades shall be lined with vinyl gasketing on contact edges.

D Control of the OA/RA dampers shall be by a factory installed direct coupled actuator. Damper actuator shall be of the modulating, spring return type. An adjustable dry bulb control shall be provided to sense the dry-bulb temperature of the outdoor air stream to determine if outdoor air is suitable for “free” cooling. If outdoor air is suitable for “free” cooling, the outdoor air dampers shall modulate in response to the unit's temperature control system.

E A return air plenum shall be provided with a 0 to 30% outdoor air hood. The hood shall allow outdoor air to enter at the back of the return air plenum. The outdoor air hood shall be factory installed and constructed from galvanized steel finished with the same durable paint finish as the main unit. The hood shall include moisture eliminator filters to drain water away from the entering air stream. The return air plenum shall allow return air to enter from the bottom of the unit. The outdoor air damper shall be controlled by a factory installed direct coupled actuator. The unit controller shall control the actuator to an outdoor air position setpoint that is adjustable from 0 to 30%. Upon unit shut down during unoccupied periods the outdoor air damper shall be power driven closed.

2.16 100% Outdoor SectionA Unit shall be equipped with a low leak OA damper. OA

shall enter the unit through the end of the unit and shall have hoods sized to prevent water carry over during inclement weather. Damper shall be controlled with a modulating, direct coupled actuator to allow for field adjustment of unit airflow.

B Damper blades shall be gasketed with side seals to provide an air leakage rate of no more than 4 cfm / square foot of damper area at 1" differential pressure per ASHRAE 90.1 Energy Standard. Leakage rate to be tested in accordance with AMCA Standard 500. Damper blades shall be operated from multiple sets of linkages mounted on the leaving face of the dampers.

2.17 Condensing SectionA Condenser coils shall be an all aluminum design. The

aluminum tube shall be a micro channel design with high efficiency aluminum fins. Fins shall be brazed to the tubing for a direct bond. Each condenser coil shall be factory leak tested with high-pressure air under water. Condenser coils shall be protected from incidental contact to coil fins by a coil guard. Coil guard shall be constructed of cross wire welded steel with PVC coating.

B Condenser fans shall be direct drive, axial type designed for low tip speed and vertical air discharge. Condenser fan rpm shall be 1140 rpm maximum. Fan blades shall be constructed of steel and riveted to a steel center hub. Condenser fan motors shall be heavy-duty, inherently protected, three-phase, non-reversing type with permanently lubricated ball bearing and integral rain shield.

C Each circuit shall have fan cycling of at least one condenser fan to maintain positive head pressure. An ambient thermostat shall prevent the refrigeration system from operating below [0ºF on sizes 015–050] [45ºF on sizes 062–075.

D Condenser coils shall be protected from hail damage as an integral part of the unit design. Hail guards shall be provided on all units with vertical mounted condenser coils.

E Each unit shall have multiple, heavy-duty scroll compressors. Each compressor shall be complete with gauge ports, crankcase heater, sight-glass, anti-slug protection, motor overload protection and a time delay to prevent short cycling and simultaneous starting of compressors following a power failure. Compressors shall be isolated with resilient rubber isolators to decrease noise transmission.

F Each unit shall have two independent refrigeration circuits. Each circuit shall be complete with a low pressure control, filter-drier, liquid moisture indicator/sight-glass, thermal expansion valve, and a manual reset high pressure safety switch. The thermal expansion valve shall be capable of modulation from 100% to 25% of its rated capacity. Sight-glasses shall be accessible for viewing without disrupting

Daikin CAT 250-8 97


unit operation. Each circuit shall be dehydrated and factory charged with Refrigerant 410A and oil.

2.18 Roof CurbA A prefabricated 14-gauge galvanized steel, mounting curb

shall be provided for field assembly on the roof decking prior to unit shipment.

B The size 015–050 roof curb shall be a full perimeter type with complete perimeter support of the air handling section and condensing section.

C The size 062–075 roof curb shall provide complete perimeter support of the air handling section and rail support of the condensing section. Supply and return opening duct frames shall be provided as part of the curb structure allowing duct connections to be made directly to the curb prior to unit arrival.

D The curb shall be a minimum of 14" high and include a nominal 2" x 4" wood nailing strip. Gasket shall be provided for field mounting between the unit base and roof curb.

2.19 ControlsA Provide a complete integrated microprocessor based Direct

Digital Control (DDC) system to control all unit functions including temperature control, scheduling, monitoring, unit safety protection, including compressor minimum run and minimum off times, and diagnostics. This system shall consist of all required temperature sensors, pressure sensors, controller and keypad/display operator interface. All MCBs and sensors shall be factory mounted, wired and tested.

B The stand-alone DDC controllers shall not be dependent on communications with any on-site or remote PC or master control panel for proper unit operation. The microprocessor shall maintain existing set points and operate stand alone if the unit loses either direct connect or network communications. The microprocessor memory shall be protected from voltage fluctuations as well as any extended power failures. All factory and user set schedules and control points shall be maintained in nonvolatile memory. No settings shall be lost, even during extended power shutdowns.

C The DDC control system shall permit starting and stopping of the unit locally or remotely. The control system shall be capable of providing a remote alarm indication. The unit control system shall provide for outside air damper actuation, emergency shutdown, remote heat enable/disable, remote cool enable/disable, heat indication, cool indication, optimal start, and fan operation.

D All digital inputs and outputs shall be protected against damage from transients or incorrect voltages. All field wiring shall be terminated at a separate, clearly marked terminal strip.

E The DDC controller shall have a built-in time schedule. The schedule shall be programmable from the unit keypad interface. The schedule shall be maintained in nonvolatile memory to insure that it is not lost during a power failure. There shall be one start/stop per day and a separate holiday schedule. The controller shall accept up to sixteen holidays each with up to a 5-day duration. Each unit shall also have the ability to accept a time schedule via BAS network communications.

F The keypad interface shall allow convenient navigation and access to all control functions. The unit keypad/display character format shall be 4 lines x 20 characters. All control settings shall be password protected against unauthorized changes. For ease of service, the display format shall be English language readout. Coded formats with look-up tables will not be accepted. The user interaction with the display shall provide the following information as a minimum:

G If the unit is to be programmed with a night setback or setup function, an optional space sensor shall be provided. Space sensors shall be available to support field selectable features. Sensor options shall include:

1 Zone sensor with tenant override switch.

2 Zone sensor with tenant override switch plus heating and cooling set point adjustment. (Space Comfort Control systems only).

H The display shall provide the following information as required by selected unit options:

1 Unit status showing stages or % capacity for cooling, heating, and economizer operation.

2 Supply, return, outdoor, and space air temperature.

3 Duct and building static pressure; the control contractor is responsible for providing and installing sensing tubes.

4 Supply fan and return fan status and airflow verification.

5 Supply and return VFD speed.

6 Outside air damper position and economizer mode.

7 Cooling and heating changeover status.

8 Occupied and unoccupied.

9 Date and time schedules.

10 Up to 10 current alarms and 25 previous alarms with time and date.

11 Dirty filter status.

12 Morning warm-up or night setback status.

13 System operating hours of the SAF, EAF, compressors, economizer, and heat.

I The keypad shall provide the following set points as a minimum as required by selected unit options:

1 Six control modes including off manual, auto, heat/cool, cool only, heat only, and fan only.

98 Daikin CAT 250-8


2 Four occupancy modes including auto, occupied, unoccupied and bypass (tenant override with adjustable duration).

3 Control changeover based on return air temperature, outdoor air temperature, or space temperature.

4 Primary cooling and heating set point temperature based on supply or space temperature.

5 Night setback and setup space temperature.

6 Cooling and heating control differential (or dead band).

7 Cooling and heating supply temperature reset options based on one of the following: Return air temperature, outdoor air temperature, space temperature, airflow, or external (1–5 VDC) signal.

8 Reset schedule temperature.

9 High supply, low supply, and high return air temperature alarm limits.

10 Ambient compressor and heat lockout temperatures.

11 Compressor interstage timers duration.

12 Duct and building static pressure.

13 Minimum outdoor airflow reset based on external reset (1–5 VFD) percent of cfm capacity, and fixed outdoor damper position.

14 Economizer changeover based on enthalpy, dry bulb or network signal.

15 Current time and date.

16 Occupied/unoccupied time schedules with allowances for holiday/event dates and duration.

17 Two types of service modes including timers normal (all time delays) and timers fast (all time delays 20 seconds).

18 Tenant override time.

J Open Communications Protocol—The unit control system shall have the ability to communicate to an independent Building Management System (BMS) through a direct [BACnet ethernet] [BACnet MSTP] [LonTalk] communication connection. The independent BMS system shall have access to [quantity from specification] “read only’ variables and [quantity from specification] “read & and write” variables. Communications shall not require field mounting of any additional sensors or devices at the unit. [The communications protocol shall be LONMARK 3.4 certified under the [Discharge Air] [Space Comfort] functional profiles.]

The BMS system shall be capable of interacting with the individual rooftop controllers in the following ways:

1 Monitor controller inputs, outputs, set points, parameters and alarms.

2 Set controller set points and parameters.

3 Clear alarms.

4 Reset the cooling and heating discharge air temperature set point (VAV and CAV-DTC units).

5 Reset the duct static pressure set point (VAV units).

6 Set the heat/cool changeover temperature (VAV and CAV-DTC units).

7 Set the representative zone temperature (CAV-ZTC units).

K It will be the responsibility of the Systems Integrating Contractor to integrate the rooftop data into the BMS control logic and interface stations.

2.20 Energy Recovery WheelA The rooftop unit shall be provided with an AHRI certified

rotary wheel air-to-air heat exchanger in a cassette frame complete with seals, drive motor and drive belt. The energy recovery wheel shall be an integral part of the rooftop unit with unitary construction and does not require field assembly. Bolt-on energy recovery units that require field assembly and section to section gasketing and sealing are not acceptable.

B The wheel capacity, air pressure drop and effectiveness shall be AHRI certified per AHRI Standard 1060. Thermal performance shall be certified by the manufacturer in accordance with ASHRAE Standard 84, Method of Testing Air-to-Air Heat Exchangers and AHRI Standard 1060, Rating Air-to-Air Heat Exchangers For Energy Recovery Ventilation Equipment.

C The rooftop unit shall be designed with a track so the entire energy recovery wheel cassette can slide out from the rooftop unit to facilitate cleaning.

D The unit shall have 2” Merv 7 filters for the outdoor air before the wheel to help keep the wheel clean and reduce maintenance. Filter access shall be by a hinged access door with ¼ turn latches.

E The wheel shall be wound continuously with one flat and one structured layer in an ideal parallel plate geometry providing laminar flow and minimum pressure drop-to-efficiency ratios. The matrix design shall have channels to reduce cross contamination between the outdoor air and the exhaust air. The layers shall be effectively captured in aluminum and stainless steel segment frames that provide a rigid and self-supporting matrix. All diameter and perimeter seals shall be provided as part of the cassette assembly and shall be factory set. Drive belt(s) of stretch urethane shall be provided for wheel rim drive without the need for external tensioners or adjustment.

F The total energy recovery wheel shall be coated with silica gel desiccant permanently bonded without the use of binders or adhesives, which may degrade desiccant performance. The substrate shall be lightweight polymer and shall not degrade nor require additional coatings for application in marine or coastal environments. Coated segments shall be washable with detergent or alkaline coil

Daikin CAT 250-8 99


cleaner and water. Desiccant shall not dissolve nor deliquesce in the presence of water or high humidity.

G Wheels shall be provided with removable energy transfer matrix. Wheel frame construction shall be a welded hub, spoke and rim assembly of stainless, plated and/or coated steel and shall be self-supporting without matrix segments in place. Segments shall be removable without the use of tools to facilitate maintenance and cleaning.

H Wheel bearings shall be selected to provide an L-10 life in excess of 400,000 hours. Rim shall be continuous rolled stainless steel. Wheels shall be connected to the shaft by means of taper lock hubs.

I The exhaust air fan shall be a direct drive SWSI plenum fan. The exhaust fan shall be sized for the airflow requirements per the construction schedule. The unit controller shall control the exhaust fan to maintain building pressure. A VFD shall be provided for the exhaust fan motor or the exhaust fan motor shall be an ECM motor.The rooftop unit shall have single point electrical power connection and shall be ETL listed.

J The control of the energy recovery wheel shall be an integral part of the rooftop unit’s DDC controller. The DDC controller shall have visibility of the outdoor air temperature, leaving wheel temperature, return air temperature, and exhaust air temperature. These

temperatures shall be displayed at the rooftop units DDC controller LCD display. All of these temperatures shall be made available through the BACnet interface.

1 [Optional] The rooftop unit with the energy recovery wheel shall incorporate the economizer operation. The energy recovery wheel shall have a bypass damper. When the unit is in the economizer mode of operation the energy recovery wheel shall stop and the bypass dampers shall be opened. The outdoor air shall be drawn through the bypass dampers to reduce the pressure drop of the outdoor airstream.

2 [Optional] The rooftop unit DDC controller shall provide frost control for the energy recovery wheel. When a frost condition is encountered the unit controller shall stop the wheel. When in the frost control mode the wheel shall be jogged periodically and not be allowed to stay in the stationary position.

3 [Optional] The rooftop unit DDC controller shall provide frost prevention for the energy recovery wheel. The DDC controller will start and stop the energy wheel to prevent the wheel from reaching a frost condition.

4 [Optional] The rooftop unit DDC controller shall provide a VFD for frost prevention for the energy recovery wheel. The speed of the energy wheel shall be varied to prevent a frost condition on the wheel.

100 Daikin CAT 250-8

© 2013 Daikin Applied 12/12

Daikin Training and Development

Now that you have made an investment in modern, efficient Daikin equipment, its care should be a high priority. For training information on all Daikin HVAC products, please visit us at www.DaikinApplied.com and click on Training, or call 540-248-9646 and ask for the Training Department.

Warranty

All Daikin equipment is sold pursuant to its standard terms and conditions of sale, including Limited Product Warranty. Consult your local Daikin Representative for warranty details. Refer to Form 933- 430285Y. To find your local Daikin Representative, go to www.DaikinApplied.com.

Aftermarket Services

To find your local parts office, visit www.DaikinApplied.com or call 800-37PARTS (800-377-2787). To find your local service office, visit www.DaikinApplied.com or call 800-432-1342.

This document contains the most current product information as of this printing. For the most up-to-date product information, please go to www.DaikinApplied.com.

Products manufactured in an ISO certified facility.

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