L22 | Heat Loss & Gain

Brian Rickard

11 Dec 201712:04

Summary

TLDRThe transcript outlines a step-by-step process for calculating the heat load of a wall, crucial for determining the right heating and cooling system size. It introduces the formula for heat load, explains the importance of the R-value chart, and demonstrates how to calculate the wall's area, R-value, and U-factor. The example uses specific temperatures for indoor and outdoor conditions to find the temperature difference, ultimately calculating the heat transfer in BTUs per hour, essential for maintaining a consistent 68°F indoor temperature.

Takeaways

📝 The script provides a step-by-step guide on how to calculate the heat load for a building, specifically using an example wall.
📐 It emphasizes the importance of calculating the area of the wall, which is found by multiplying the width by the height.
🏠 The example uses a wall with dimensions of 20 feet by 9 feet, resulting in an area of 180 square feet.
🔢 The script explains the necessity of understanding the R-value of different materials in the wall construction for accurate heat load calculation.
⚙️ It details the process of calculating the total R-value by adding the R-values of each material layer in the wall.
🔄 The U-factor is derived from the R-value and is crucial for the heat load formula; it represents the coefficient of heat conductivity.
🌡️ The script mentions the need to determine the temperature difference between the inside and outside of the wall for the calculation.
📉 The U.S. National Oceanic and Atmospheric Administration website is suggested as a resource for finding design temperatures for different regions.
✂️ The U-factor is calculated as the reciprocal of the total R-value, and it's common practice to keep three decimal places without rounding up.
📈 The final heat load (Q prime) is calculated using the formula: Area x U-factor x Temperature Change, resulting in BTUs per hour.
🏢 For a complete building, the process would need to be repeated for all walls and the roof to determine the total heating and cooling requirements.
🛠️ The calculated heat load can be used to size the appropriate heating and cooling system to maintain a consistent indoor temperature.

Q & A

What is the purpose of the heat load calculation discussed in the script?
-The purpose of the heat load calculation is to determine the amount of heat that will be lost through a wall, which is essential for designing heating and cooling systems in buildings.
What formula is used to calculate the heat load in the script?
-The formula used to calculate the heat load is Q' = Area × U-factor × ΔT, where Q' is the total heating and cooling load in BTUs per hour, Area is the area of the wall, U-factor is the coefficient of heat conductivity, and ΔT is the change in temperature.
How is the area of the wall calculated in the script?
-The area of the wall is calculated by multiplying the width by the height of the wall. In the script, a wall that is 20 feet wide and 9 feet high has an area of 180 square feet.
What is the R-value and how is it used in the heat load calculation?
-The R-value is a measure of thermal resistance, indicating the ability of a material to resist heat flow. It is used to calculate the overall thermal resistance of the wall, which is then used to determine the U-factor.
How do you determine the R-value of the materials in the wall?
-The R-value of each material in the wall is determined using an R-value chart or specific R-value data for the materials. These values are then added together to get the total R-value of the wall assembly.
What is the U-factor and how is it related to the R-value?
-The U-factor is the coefficient of heat conductivity and is the inverse of the R-value. It is calculated as U-factor = 1 / R-value and is used in the heat load calculation formula.
Why is it important not to round up the U-factor when calculating it from the R-value?
-It is important not to round up the U-factor because rounding up could result in an overestimation of heat loss, potentially leading to an oversized and inefficient heating and cooling system.
What are the typical temperatures used for the inside and outside of the wall in the script's example?
-In the script's example, the typical temperature used for the inside of the wall is 68 degrees Fahrenheit, while the outside temperature is based on a design temperature of 4 degrees Fahrenheit for winter conditions.
How is the change in temperature (ΔT) calculated in the script?
-The change in temperature (ΔT) is calculated by subtracting the outside temperature from the inside temperature. In the script, ΔT is 68 degrees Fahrenheit minus 4 degrees Fahrenheit, which equals 64 degrees Fahrenheit.
What is the final result of the heat load calculation for the example wall in the script?
-The final result of the heat load calculation for the example wall is 875.52 BTUs per hour, which represents the total heating and cooling load for that wall.
How can the heat load calculation be applied to an entire building?
-The heat load calculation can be applied to an entire building by calculating the heat load for each wall, the roof, and any other relevant surfaces, and then summing these values to determine the total heating and cooling load for the entire structure.