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# Effect of ERV on AC Run Time

Updated: Aug 20

My colleague and I had a recent discussion about his ongoing project. We focused on figuring out how adding an Energy Recovery Ventilator (ERV) to treat ventilation air impacts the run time of air conditioning equipment. To answer this, we used adicot.com's Psychrometric Chart 2-Condition Calclator and the methodology shown below to compare equipment run times with untreated ventilation air versus ventilation air treated by an ERV. The results showed an impressive 27% reduction in equipment run time due to the ERV implementation. You'll find the details of our approach in the following section.

To solve this problem, we assumed the following will be given:

Given:

• Equipment Cooling Capacity [BTU/h] provided by the manufacturer

• ASHRAE Outside air design temperatures (Dry bulb and wet bulb) [oF]

• Coil Leaving Air Temperatures (Dry bulb and wet bulb) [oF] provided by the manufacturer

• Ventilation air volume [cfm] per ASHRAE 62.# or Building Code

Procedure:

1. Calculate the Ventilation Air Total Cooling Load [BTU/h] (Psychrometric Chart 2-Condition Calculator)

2. Run time = Ventilation load/Equipment Capacity x 60 min [min]

Example:

• Equipment Cooling Capacity: 2.50 tons or 30,000 BTU/h

• Outside air temperatures in Boston, MA: 88oF / 72oF

• Coil Leaving Air Temperatures: 55oF / 54.9oF

• Ventilation air volume: 100 CFM

1. Calculate the total load of ventilation air using Psychrometric Chart 2-Condition Calculator where:

• Entering Conditions are outside air design temperatures

• Exiting Conditions are coil-leaving air temperatures Ventilation Air Total Cooling Load = 5,483 BTU/h

1. Run time =5,483 BTU/h / 30,000 BTU/h x 60 min/hr = 11 minutes/hour to condition the ventilation air

Adding an ERV: Replace outside air temperature with the ERV leaving air temperature (100 CFM @ 78 Dry bulb, 68 Wet bulb):