We will explore an example that connects the basic definitions and equations for different modes of heat transfer with a real-world application. Read the problem carefully. An architect is starting to create a plan for a building. The building is expected to be 25 m high with a rectangular base (footprint) of 35 m by 15 m. For a sustainibility-minded design, the architect needs to account for heat load of the building under extreme conditions. So, she asked for your help to find out, under an extreme condition, the rate of heat transfer through (a) vertical walls (b) the roof, and (c) the floor of the building. These information will help the architect to prioritize which surfaces need what type of insulation so that the heat transfer for the entire building can be minimized. Assume the extreme condition is a summer day at noon which is characterized by air temperature of 40°C and sky temperature of 285 K. Under this condition the roof receives an average normal solar irradiation of 600 W/m², and solar irradiation on the vertical walls can be neglected. The solar absorptivity of the paint on the building is 0.4, emissivity of the paint is 0.3, and average convection coefficient for both the roof and the walls can be approximated as 8 W/m².K. The temperature of the surfaces of the building is maintained at 20°C. The floor of the building has an approximate temperature gradient of 20 K/m (the floor is at higher temperature than the ground). The thermal conductivity of the floor base is 1.1 W/m.K. Ignore radiative heat transfer via the floor.
We will explore an example that connects the basic definitions and equations for different modes of heat transfer with a real-world application. Read the problem carefully. An architect is starting to create a plan for a building. The building is expected to be 25 m high with a rectangular base (footprint) of 35 m by 15 m. For a sustainibility-minded design, the architect needs to account for heat load of the building under extreme conditions. So, she asked for your help to find out, under an extreme condition, the rate of heat transfer through (a) vertical walls (b) the roof, and (c) the floor of the building. These information will help the architect to prioritize which surfaces need what type of insulation so that the heat transfer for the entire building can be minimized. Assume the extreme condition is a summer day at noon which is characterized by air temperature of 40°C and sky temperature of 285 K. Under this condition the roof receives an average normal solar irradiation of 600 W/m², and solar irradiation on the vertical walls can be neglected. The solar absorptivity of the paint on the building is 0.4, emissivity of the paint is 0.3, and average convection coefficient for both the roof and the walls can be approximated as 8 W/m².K. The temperature of the surfaces of the building is maintained at 20°C. The floor of the building has an approximate temperature gradient of 20 K/m (the floor is at higher temperature than the ground). The thermal conductivity of the floor base is 1.1 W/m.K. Ignore radiative heat transfer via the floor.
Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
ChapterMA: Math Assessment
Section: Chapter Questions
Problem 1.1MA
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