Leaving Air Temperature for Round Duct Calculator

Entering Air Temperature (

T_{e}

Surrounding Air Temperature (

T_{a}

Overall Heat Transfer Coefficient (

U

Air Flow Rate (

Q

Air Density (

ρ

Duct Length (

L

Duct Diameter (

D

Cross-Sectional Area (

A

in²

Average Velocity (

V

fpm

Dimensionless Constant (

y

dimensionless

Leaving Air Temperature (

T_{l}

1. What is a Leaving Air Temperature for Round Duct Calculator?

Definition: This calculator computes the temperature of air leaving a round duct ( $T_{l}$ ) based on the entering air temperature, surrounding air temperature, and a dimensionless parameter $y$ , calculated using the air flow rate, duct diameter, and standard air specific heat ( $C_{p} = 0.24 Btu/lb_f-°F$ ).

Purpose: It is used in HVAC design to determine the outlet air temperature of a round duct, accounting for heat transfer through duct walls, aiding in system performance and thermal comfort.

2. How Does the Calculator Work?

The calculator uses the following formulas for round ducts:

Leaving Air Temperature: $T_{l} = \frac{T_{e} (y - 1) + 2 T_{a}}{(y + 1)}$ Dimensionless Constant: $y = \frac{2.5 D V ρ C_{p}}{U L}, A = \frac{π D^{2}}{4}, V = \frac{144 Q}{A}$ Specific Heat: $C_{p} = 0.24 Btu/lb_f-°F$

Where:

$T_{l}$ : Temperature of air leaving duct (°F, °C)
$T_{e}$ : Temperature of air entering duct (°F, °C)
$T_{a}$ : Temperature of air surrounding duct (°F, °C)
$y$ : Dimensionless constant
$A$ : Cross-sectional area of duct (in²)
$Q$ : Air flow rate (cfm, m³/s)
$V$ : Average velocity (fpm)
$ρ$ : Air density (lb_f/ft³, kg/m³)
$C_{p}$ : Specific heat of air (0.24 Btu/lb_f-°F)
$U$ : Overall heat transfer coefficient (Btu/hr-ft²-°F, W/m²-K)
$L$ : Duct length (ft, m)
$D$ : Diameter of round duct (in., ft, m)

Unit Conversions:

Temperatures ( $T_{e}$ , $T_{a}$ , $T_{l}$ ): °F, °C (°F = °C × 9/5 + 32)
Heat Transfer Coefficient ( $U$ ): Btu/hr-ft²-°F, W/m²-K (1 W/m²-K = 0.176110 Btu/hr-ft²-°F)
Air Flow Rate ( $Q$ ): cfm, m³/s (1 m³/s = 2118.88 cfm)
Air Density ( $ρ$ ): lb_f/ft³, kg/m³ (1 kg/m³ = 0.062428 lb_f/ft³)
Duct Length ( $L$ ): ft, m (1 m = 3.28084 ft)
Diameter ( $D$ ):
- in.: No conversion
- ft: 1 ft = 12 in.
- m: 1 m = 39.3701 in.

Steps:

Enter the entering air temperature ( $T_{e}$ ), surrounding air temperature ( $T_{a}$ ), overall heat transfer coefficient ( $U$ ), air flow rate ( $Q$ ), air density ( $ρ$ ), duct length ( $L$ ), and duct diameter ( $D$ ).
Convert all inputs to consistent units (e.g., °F, Btu/hr-ft²-°F, cfm, lb_f/ft³, in., ft).
Calculate the cross-sectional area ( $A = \frac{π D^{2}}{4}$ ).
Calculate the average velocity ( $V = \frac{144 Q}{A}$ ).
Calculate the dimensionless constant ( $y$ ) using $C_{p} = 0.24 Btu/lb_f-°F$ .
Calculate the leaving air temperature ( $T_{l}$ ).
Display $A$ , $V$ , $y$ , and $T_{l}$ with 5 decimal places, or in scientific notation if the value is greater than 10,000 or less than 0.00001.

3. Importance of Leaving Air Temperature Calculation

Calculating the leaving air temperature is crucial for:

HVAC System Design: Determines the outlet air temperature to ensure it meets design requirements, optimizing system performance.
Energy Efficiency: Helps design ducts to minimize unwanted heat transfer, reducing energy consumption.
Thermal Comfort: Ensures delivered air temperature provides occupant comfort.

4. Using the Calculator

Examples:

Example 1: For $T_{e} = 131.10 °F$ , $T_{a} = 40 °F$ , $D = 24 in.$ , $Q = 3052.08 cfm$ , $ρ = 0.075 lb_f/ft³$ , $U = 0.73 Btu/hr-ft²-°F$ , $L = 40 ft$ , leaving air temperature in °F:
- $A = \frac{π \times 24^{2}}{4} \approx 452.389 in²$
- $V = \frac{144 \times 3052.08}{452.389} \approx 971.42 fpm$
- $y = \frac{2.5 \times 24 \times 971.42 \times 0.075 \times 0.24}{0.73 \times 40} \approx 36.01$
- $T_{l} = \frac{131.10 \times (36.01 - 1) + 2 \times 40}{36.01 + 1} \approx \frac{4586.35 + 80}{37.01} \approx 126.05$
- Since all values are < 10000 and > 0.00001, display with 5 decimal places: $A = 452.38900 in²$ , $V = 971.42000 fpm$ , $y = 36.01000$ , $T_{l} = 126.05000$
Example 2: For $T_{e} = 55 °C$ , $T_{a} = 4.4 °C$ , $D = 0.5 m$ , $Q = 0.5 m³/s$ , $ρ = 1.2 kg/m³$ , $U = 4.1 W/m²-K$ , $L = 12 m$ , leaving air temperature in °C:
- Convert: $T_{e} = 55 \times 9 / 5 + 32 = 131 °F$ , $T_{a} = 4.4 \times 9 / 5 + 32 = 39.92 °F$
- $D = 0.5 \times 39.3701 \approx 19.68505 in.$
- $Q = 0.5 \times 2118.88 \approx 1059.44 cfm$
- $ρ = 1.2 \times 0.062428 \approx 0.074914 lb_f/ft³$
- $U = 4.1 \times 0.176110 \approx 0.722051 Btu/hr-ft²-°F$
- $L = 12 \times 3.28084 \approx 39.37008 ft$
- $A = \frac{π \times {19.68505}^{2}}{4} \approx 304.306 in²$
- $V = \frac{144 \times 1059.44}{304.306} \approx 501.34 fpm$
- $y = \frac{2.5 \times 19.68505 \times 501.34 \times 0.074914 \times 0.24}{0.722051 \times 39.37008} \approx 15.60$
- $T_{l} = \frac{131 \times (15.60 - 1) + 2 \times 39.92}{15.60 + 1} \approx \frac{1912.6 + 79.84}{16.60} \approx 120.03 °F$
- Convert to °C: $(120.03 - 32) \times 5 / 9 \approx 48.91$
- Since all values are < 10000 and > 0.00001, display with 5 decimal places: $A = 304.30600 in²$ , $V = 501.34000 fpm$ , $y = 15.60000$ , $T_{l} = 48.91000$
Example 3: For $T_{e} = 100 °F$ , $T_{a} = 80 °F$ , $D = 1 ft$ , $Q = 500 cfm$ , $ρ = 0.08 lb_f/ft³$ , $U = 0.5 Btu/hr-ft²-°F$ , $L = 50 ft$ , leaving air temperature in °F:
- Convert: $D = 1 \times 12 = 12 in.$
- $A = \frac{π \times 12^{2}}{4} \approx 113.097 in²$
- $V = \frac{144 \times 500}{113.097} \approx 636.62 fpm$
- $y = \frac{2.5 \times 12 \times 636.62 \times 0.08 \times 0.24}{0.5 \times 50} \approx 14.62$
- $T_{l} = \frac{100 \times (14.62 - 1) + 2 \times 80}{14.62 + 1} \approx \frac{1362 + 160}{15.62} \approx 97.44$
- Since all values are < 10000 and > 0.00001, display with 5 decimal places: $A = 113.09700 in²$ , $V = 636.62000 fpm$ , $y = 14.62000$ , $T_{l} = 97.44000$

5. Frequently Asked Questions (FAQ)

Q: What does the leaving air temperature represent?
A: The leaving air temperature ( $T_{l}$ ) is the temperature of air exiting a round duct, calculated based on the entering air temperature and heat transfer through the duct walls.

Q: How can I determine the input parameters?
A: Entering and surrounding air temperatures ( $T_{e}$ , $T_{a}$ ) are measured or estimated. Duct diameter ( $D$ ) and length ( $L$ ) are obtained from design specifications. Air flow rate ( $Q$ ), density ( $ρ$ ), and heat transfer coefficient ( $U$ ) are measured or derived from standards. Specific heat is fixed at $C_{p} = 0.24 Btu/lb_f-°F$ .

Q: Why is the leaving air temperature important in HVAC design?
A: It ensures the HVAC system delivers air at the desired temperature, optimizing thermal comfort and energy efficiency.