Lifebreath 95MAX, 200MAX, 155MAX installation manual Pitot Tube AIR Flow Balancing

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Place pitot tube a minimum of 18" from blower or elbows
Pitot tube

PITOT TUBE AIR FLOW BALANCING

It is necessary to have balanced air flows in an HRV/ERV. The volume of air brought in from the outside must equal the volume of air exhausted by the unit. If the air flows are not properly balanced, then;

The HRV/ERV may not operate at its maximum efficiency

A negative or positive air pressure may occur in the house

The unit may not defrost properly

Failure to balance HRV/ERV properly may void warranty

Excessive positive pressure may drive moist indoor air into the external walls of the building where it may condense (in cold weather) and degrade structural components. May also cause key holes to freeze up.

Excessive negative pressure may have several undesirable effects. In some geographic locations, soil gases such as methane and radon gas may be drawn into the home through basement/ground contact areas. Excessive negative pressure may also cause the backdrafting of vented combustion equipment.

Read the Application Warning on the front of this manual!

Prior to balancing, ensure that:

1.All sealing of the ductwork system has been completed.

2.All of the HRV/ERV's components are in place and functioning properly.

3.Balancing dampers are fully open.

4.Unit is on HIGH speed.

5.Air flows in branch lines to specific areas of the house should be adjusted first prior to balancing the unit. A smoke pencil used at the grilles is a good indicator of each branch line's relative air flow.

6.After taking readings of both the stale air to the HRV/ERV duct and fresh air to the house duct, the duct with the lower CFM ([L/s] velocity) reading should be left alone, while the duct with the higher reading should be dampered back to match the lower reading.

7.Return unit to appropriate fan speed for normal operation

For general balancing it is sufficient to move the pitot tube around in the duct and take an average or typical reading. Repeat this procedure in the other (supply or return) duct. Determine which duct has the high- est airflow (highest reading on the gauge). Then damper that airflow back to match the lower reading from the other duct. The flows should now be balanced. Actual airflow can be determined from the gauge reading. The value read on the gauge is called the velocity pressure. The Pitot tube comes with a chart that will give the air flow velocity based on the velocity pressure indicated by the gauge. This velocity will be in either feet per minute or metres per second. To determine the actual airflow, the velocity is multiplied by the cross sectional area of the duct being measured.

This is an example for determining the airflow in a 6" duct. The Pitot tube reading was 0.025 inches of water.

From the chart, this is 640 feet per minute.

The 6" duct has a cross sectional area of = [3.14 x (6"÷12)2]÷4 = 0.2 square feet

The airflow is then:

640 ft./min. X 0.2 square feet = 128 cfm

For your convenience, the cross sectional area of some common round duct is listed below:

DUCT DIAM. (inches)

CROSS SECTION AREA (sq. ft.)

5

0.14

6

0.20

7

0.27

The accuracy of the air flow reading will be affected by how close to any elbows or bends the readings are taken. Accuracy can be increased by taking an average of multiple readings as outlined in the literature supplied with the Pitot tube.

BALANCING PROCEDURE

The following is a method of field balancing an HRV/ERV using a Pitot tube, advantageous in situations when flow stations are not installed in the duct- work. Procedure should be performed with the HRV/ERV on high speed.

The first step is to operate all mechanical systems on high speed, which have an influence on the ventilation system, i.e. the HRV/ERV itself and the forced air furnace or air handler if applicable. This will provide the maximum pressure that the HRV/ERV will need to overcome, and allow for a more accurate balance of the unit.

Drill a small hole in the duct (about 3/16"), three feet downstream of any elbows or bends, and one foot upstream of any elbows or bends. These are recommended distances but

the actual installation may limit the amount of straight duct.

Pitot tube and gauge

DUCT

AIR

FLOW

Pitot tube

Magnehelic gauge

MAGNEHELIC

Pitot Tube Air Flow Balancing Kit

c/w magnehelic gauge, Pitot tube, hose and carry case.

PART NO. 99-167

The Pitot tube should be connected to a magnehelic gauge or other manometer capable of reading from 0 to 0.25 in. (0- 62 Pa) of water, preferably to 3 digits of resolution. The tube coming out of the top of the pitot is connected to the high pressure side of the gauge. The tube coming out of the side of the pitot is con- nected to the low pressure or reference side of the gauge.

Outdoors

Magnehelic

gauge

MAGNEHELIC

Insert the Pitot tube into the duct; point- ing the tip into the airflow.

Note: Duct connections may vary, depending on model.

Magnehelic

gauge

Pitot tube

MAGNEHELIC

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Contents 95MAX Contains200ERVD Table of Contents ERV Questions & Answers Page Engineering Data Model 95MAXModel 155MAX Dimensions 155MAX inches mmModel 200MAX Dimensions 200MAX inches mmModel Maxtop Dimensions Maxtop inches mmModel 195DCS Dimensions 195DCSThermally CONDUCTIVE, Patented Aluminum Core Model 300DCSModel 200ERV Dimensions 200ERV inches mmModel 200ERVD Dimensions 200ERVDFunction & Control To select mode of operation for ControlAir NEW! AIR Sentry AIR Quality Sensor Optional Remote ControlsUsing the Dehumidistat MAX Port Specifications Location InstallationInstalling AIR Ducts Dampers and Grilles Supply AIR DuctingInstallation Diagrams Simplified Installation Supply/Return Method Fully Dedicated System Pitot Tube AIR Flow Balancing Balancing Collar Instructions Inspect Exterior Hoods at least once a month Maintenance Routine for ERV for HRV, see previous Occupant Symptom Cause SolutionTechnical Bulletin Residential Wiring Diagram McCormick Blvd. London, Ontario N5W 4C
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155MAX, 95MAX, 200MAX specifications

Lifebreath is well-known for its innovative heat recovery ventilators that enhance indoor air quality while conserving energy. Among their acclaimed models, the Lifebreath 150SP, 200MAX, 150MAX, and 200STD stand out for both their functionality and design, delivering optimal performance for various residential and commercial applications.

The Lifebreath 150SP is designed for spaces requiring effective air exchange while maintaining energy efficiency. This model boasts a compact design, making it ideal for smaller homes or apartments. One of its main features includes a top-mounted control panel with a user-friendly interface, allowing for easy adjustment of settings. Equipped with a high-efficiency heat exchanger, the 150SP effectively transfers heat from the outgoing stale air to the incoming fresh air, minimizing energy loss. Additionally, the unit operates quietly, ensuring that comfort is not compromised.

On to the 200MAX, this model is engineered for larger spaces. With increased airflow capacity, it ensures consistent air quality in bigger areas while optimizing energy consumption. The 200MAX features advanced filtering systems that capture dust, pollen, and other allergens, promoting a healthier indoor environment. Its built-in defrosting system operates automatically, enhancing efficiency during colder months. The 200MAX also supports optional accessories, such as a programmable timer and an energy recovery ventilator, allowing users to customize performance to meet specific needs.

The Lifebreath 150MAX pairs the efficiency of the 150SP with added versatility. This model is suitable for mid-sized spaces and comes equipped with a dual motor system. This unique feature provides users with the flexibility to adjust airflow independently, accommodating varying room conditions. The 150MAX excels in both heating and cooling modes, ensuring comfort year-round.

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