Carrier HRVCCSVB1100, ERVCCSHB1100, HRVCCSHB1100, ERVCCSVB1100 installation instructions Wall Control

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ERV / HRV

Connect Ducts to ERV/HRV

!CAUTION

PROPERTY DAMAGE HAZARD

Failure to follow this caution may result in minor property damage from sweating duct or loss of unit efficiency and capacity.

If ERV/HRV duct work is installed in an unconditioned space, insulated flexible duct is required.

Insulated flexible duct is required on both fresh-air inlet and exhaust-air outlet ducts connecting to exterior wall. When using insulated flexible duct, the vapor barrier of the flexible ducts must be taped very tight to prevent condensation problems. To reduce pressure drop, stretch the flex duct and support it in a proper manner to avoid reduced airflow.

When connecting the ERV/HRV to a return-air duct system, insulated flexible duct can be used. However, when metal or rigid ducts are applied use approximately 18-in. (457mm) of flexible duct at ERV/HRV ports for fresh-air supply, and stale-air return. When using metal duct from fresh-air supply to system duct work, the metal duct should be insulated. (See Fig. 8.) This can act as a silencer when connecting ducts to return-air duct system. This should eliminate transmission of noise or vibration from unit to main duct system.

STALE-AIR

RETURN

FRESH-AIR

SUPPLY

FLEXIBLE DUCTS CONNECTING TO

RETURN-AIR DUCT SYSTEM

A08102

Fig. 8 - Flexible Duct Fit-Up

Locate and Install Exterior Hoods

IMPORTANT: To prevent condensation problems, insulated flexible ducts are required on both fresh-air inlet and exhaust-air outlet ducts connecting between ERV/HRV and exterior wall.

Fresh-air intake and stale-air exhaust must be separated by at least 6 ft (1.8m). Fresh-air intake must be positioned at least 10 ft (3m) from nearest dryer vent, furnace exhaust, driveway, gas meter, or oil fill pipe. Fresh-air intake must be positioned as far as possible from garbage containers and potential chemical fumes. When possible, it is advised to locate the intake and exhaust hoods on same side of house or building. The intake and exhaust hoods should never be located on interior corners or in dead air pockets (See Fig. 7). Both intake and exhaust hoods must be 18-in. (457mm) from ground and at least 12-in. (305mm) above anticipated snow level.

After selecting proper hood locations, make appropriate size hole through exterior wall, pass flexible duct through hole and insert hood tube into duct. Tape duct vapor barrier tightly around hood tube and insert assembly back into wall and fasten securely.

Condensate Drain

(For ERV, skip this step and continue to the next step.)

To connect condensate drain, proceed as follows:

1.Punch out holes in foam insulation and door, then insert sleeved grommets into bottom of unit using the gasket washer and nut. (See Fig. 9.)

2.Cut two sections of plastic tubing, about 12-in. / 305mm long and attach them to each drain.

3.Join the two short sections of plastic tubing to the “T” con- nector and the main tube as shown.

4.Make a loop in the tubing below the “T” connector to create a trap to prevent sewer gases from entering the ventilation system. (See Fig. 9.)

5.Connect unit drain to building’s main drain. Provide slight slope from unit for run-off.

A99268

Fig. 9 - Condensate Drain With Loop Trap (HRV Only)

WALL CONTROL

Types

Four remote wall control options are available:

1.Basic Control (see Table 1).

2.OneTouch Control

3.Standard Control (includes dehumidistat)

4.Latent Control (includes humidistat for use with ERV’s only)

Table 1 – Basic Control

MODE

OPERATION

DAMPER

FAN

POSITION

SPEED

 

 

 

 

 

 

Off

Off

Closed to outside

Off

 

 

 

 

Low

Air exchange with

Open to outside

Low

outside

 

 

 

 

 

 

 

Intermittent

Air exchange with

Open to outside

Low

outside

 

 

 

 

 

 

 

High

Air exchange with

Open to outside

High

outside

 

 

 

 

 

 

 

Location

The Standard Control and the Latent Control sense humidity and not temperature. They must be located in an area where they will continually monitor fresh air circulating within the home. Install ERV/HRV wall controls as close as possible to main system thermostat and follow same guidelines as installing a thermostat (locate approximately 5 ft (1.5m) above floor, mount on an inside partitioning wall, etc.)

Wiring

Remove top cover assembly from wall control and pass thermostat wire through hole located on back of control before attaching to wall. Connect Y, R, G, and B (yellow, red, green, and black)

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Contents Table of Contents Safety ConsiderationsInstallation Considerations IntroductionComponent Description Inspect EquipmentUnit Installation Mount UnitIndependent System Application Forced-Air ApplicationWall Control Operation Humidity SelectorOneTouch Control Latent Control Integrated ControlOperating the ERV/HRV with Infinity Control AccessoriesElectrical Connections Balancing Procedure Set the unit to high speed Magnehelic gauge placementBalancing ERV/HRV Move tubing to Fresh air flow pressure tapsVentilation Evaluation Care and MaintenanceControl Board Operation Electrical Shock Hazard TroubleshootingCUT Hazard Troubleshooting LED flashes Green Thermistor errorHRV Defrost Cycles Resistance OhmsERV Defrost Cycles Connection Diagram Logic Diagram 3SI

ERVCCSVB1100, HRVCCSHB1100, ERVCCSHB1100, HRVCCSVB1100 specifications

The Carrier ERVCCSVB1100, HRVCCSVB1100, HRVCCSHB1100, and ERVCCSHB1100 represent the latest advancements in residential and commercial ventilation systems. These systems are designed to enhance indoor air quality while ensuring energy efficiency, making them ideal solutions for modern buildings.

One of the main features of these units is their recovery ventilation technology. Both the Energy Recovery Ventilator (ERV) and Heat Recovery Ventilator (HRV) options are engineered to efficiently transfer heat and moisture between incoming and outgoing air streams. This process reduces energy consumption by pre-conditioning fresh air, thereby minimizing the workload on heating and cooling systems.

The ERVCCSVB1100 and ERVCCSHB1100 models are particularly well-suited for humid climates where moisture control is critical. They utilize a sophisticated enthalpy exchange process, which allows excess humidity to be transferred from the stale air to the incoming fresh air, thereby reducing the burden on air conditioning systems and maintaining optimal indoor humidity levels. This feature is essential for enhancing occupant comfort and safeguarding building materials from moisture-related damage.

On the other hand, the HRVCCSVB1100 and HRVCCSHB1100 units shine in drier climates where humidity control is less of a concern. These systems focus on heat recovery, effectively transferring thermal energy without exchanging moisture. This is particularly advantageous during winter months, as they provide fresh air while conserving precious heat, thus optimizing energy utilization and contributing to lower utility bills.

Another critical characteristic of all four models is their quiet operation. Designed with sound-dampening technologies, they ensure minimal noise disturbance, thereby maintaining a peaceful indoor environment. This is especially valuable in residential settings or commercial spaces that require a distraction-free atmosphere.

Additionally, the units come with intelligent controls that allow users to monitor and adjust settings according to their specific needs. Features such as programmable timers and remote access capabilities provide convenience and flexibility for users, enabling them to optimize their indoor air quality effortlessly.

In summary, Carrier's ERVCCSVB1100, HRVCCSVB1100, HRVCCSHB1100, and ERVCCSHB1100 models offer a comprehensive suite of features, advanced technologies, and characteristics tailored to meet the demands of modern indoor environments. By integrating energy recovery ventilation with user-friendly controls, they set a new standard for efficiency, comfort, and air quality in various building types.
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