The Dos and Don’ts of Duct Design

System Components are Often Overlooked

Air filters, hydronic coils, and evaporator coils are the most often overlooked components in a duct system. It’s easy to miss their resistance to airflow when calculating the required duct sizing friction rate. The pressure losses of these system components must be accounted for in the friction rate worksheet. The friction rate worksheet is a document in Manual D that provides guidance on what component losses to capture.

This means referencing manufacturer’s performance data and determining the correct airflow by following ACCA Manual S guidelines as a first step.

Coil manufacturers provide expanded tables of airflow (in cfm) vs. pressure drops, but air filters often have a different format. Although it is not uncommon to see air filter cfm vs. pressure drop tables, they may be displayed as air velocity (fpm) vs. pressure drop. This requires an additional step to convert your design cfm into velocity.

Another overlooked issue is incorrectly sizing supply registers and return grilles. These should be sized by referencing design cfm, throw, spread, and pressure drop, all while maintaining an acceptable noise criterion (NC) within the space (NC < 30 dB). If a grille or register is too small, it will have a high pressure drop, reduced airflow, and excessive noise.  Do you have to turn up your television volume late at night when your furnace or air-handler turns on? Check your grilles and register sizing.

Sizing ductwork or calculating the friction rate without accounting for all component pressure losses may result in various issues. Some of these include:

• Improper airflow;
• Inadequate cooling;
• Objectionable noise;
• Increased motor watt draw;
• Increased duct leakage; and
• Reduced filtration.

Each of these issues can cause various comfort issues and premature equipment failure. 

Start With the End in Mind

The end is design airflow. To determine cooling design airflow, follow the guidance in ACCA Manual S. This ensures the system’s Sensible Heat Factor (SHF) will meet the home’s Sensible Heat Ratio (SHR) requirements. To determine heating design airflow, refer to the furnace manufacturer’s airflow ratings that fall within their listed temperature rise range.

For both cooling and heating design airflows, refer to the equipment’s fan table and note the maximum external static pressure (ESP). It is best practice to use no more than 70% of the maximum ESP as a starting point when calculating the friction rate on a variable-speed blower.

For example, a variable-speed blower with a maximum ESP of 0.9 in. at the design airflow should not exceed a design ESP of 0.63 in.

 0.9 in. x 0.7 = 0.63 in.

You can use an ESP at or below the maximum ESP for a constant-torque blower. For example, it is acceptable to use up to 0.9-in. ESP for a constant torque motor that has a maximum ESP of 0.9 in. at the design airflow.

Some furnaces may not allow you to use all the blower speeds for heating airflow, so pay close attention to the furnace’s capabilities when you determine a starting ESP.

Using Math to Account for Component Losses

After calculating the total component losses (TCL), deduct this from the blower ESP to determine the available static pressure (ASP), or ASP = ESP – TCL. Now use the friction rate formula to calculate the duct sizing friction rate.

Friction Rate = (ASP x 100) / (Total Effective Length (TEL))

The total effective length, in units of feet, is the sum of all the individual duct fitting losses along the critical path. These losses are represented in straight feet of duct.  In other words, a smooth, round elbow can be represented as having the same pressure loss as 20 feet of straight duct with the same airflow velocity. ACCA Manual D has duct fitting tables with corresponding equivalent lengths (ELs). These conservative values are based on the upper airflow velocity limits (900 fpm for supply fittings and 700 fpm for return fittings).

The critical path (CP) is the supply and return duct pathway, from the fan to the grille, that has the largest pressure loss in the duct system, or the longest TEL.  This is usually the longest supply run and the longest return run, but not always.  Once you have determined the critical path & TEL, all the ducts can be sized using the equal friction rate method.  Some design software allows you to easily calculate the TELs of each branch, enabling individual friction rates for each duct circuit. This method is sometimes referred to as variable friction rate.