Electronics and inhabitants of the InternationalSpace Station generate a significant amount ofthermal energy that the station must get rid of. Theonly way that the station can exhaust thermalenergy is by radiation, which it does using thin,1.8-m-by-3.6-m panels that have a workingtemperature of about 6 °C and an emissivity of0.85.Part AHow much power is radiated from each panel? Assume that the panels are in the shade so that the absorbed radiation willbe negligible. The temperature of deep space, which the panels face, is close to 0 K.Hint: Don't forget that the panels have two sides!Express your answer with the appropriate units.► View Available Hint(s)P =SubmitμAValuePrevious AnswersW....?

Given:Thickness of panels, t=1.8 m by 3.6 mArea of each panel, Working temperature of…

Electronics and inhabitants of the International Space Station generate a significant amount of thermal energy that the station must get rid of. The only way that the station can exhaust thermal energy is by radiation, which it does using thin, 1.8-m-by-3.6-m panels that have a working temperature of about 6 °C and an emissivity of 0.85. How much power is radiated from each panel? Assume that the panels are in the shade so that the absorbed radiation will be negligible. The temperature of deep space, which the panels face, is close to 0 K. Hint: Don't forget that the panels have two sides! Express your answer with the appropriate units. ► View Available Hint(s) P = μA Value W ?

Electronics and inhabitants of the International Space Station generate a significant amount of thermal energy that the station must get rid of. The only way that the station can exhaust thermal energy is by radiation, which it does using thin, 1.8-m-by-3.6-m panels that have a working temperature of about 6 °C and an emissivity of 0.85. How much power is radiated from each panel? Assume that the panels are in the shade so that the absorbed radiation will be negligible. The temperature of deep space, which the panels face, is close to 0 K. Hint: Don't forget that the panels have two sides! Express your answer with the appropriate units. ► View Available Hint(s) P = μA Value W ?

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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Concept explainers

Energy transfer

The flow of energy from one region to another region is referred to as energy transfer. Since energy is quantitative; it must be transferred to a body or a material to work or to heat the system.

Molar Specific Heat

Heat capacity is the amount of heat energy absorbed or released by a chemical substance per the change in temperature of that substance. The change in heat is also called enthalpy. The SI unit of heat capacity is Joules per Kelvin, which is (J K-1)

Thermal Properties of Matter

Thermal energy is described as one of the form of heat energy which flows from one body of higher temperature to the other with the lower temperature when these two bodies are placed in contact to each other. Heat is described as the form of energy which is transferred between the two systems or in between the systems and their surrounding by the virtue of difference in temperature. Calorimetry is that branch of science which helps in measuring the changes which are taking place in the heat energy of a given body.

Question

Electronics and inhabitants of the International
Space Station generate a significant amount of
thermal energy that the station must get rid of. The
only way that the station can exhaust thermal
energy is by radiation, which it does using thin,
1.8-m-by-3.6-m panels that have a working
temperature of about 6 °C and an emissivity of
0.85.
Part A
How much power is radiated from each panel? Assume that the panels are in the shade so that the absorbed radiation will
be negligible. The temperature of deep space, which the panels face, is close to 0 K.
Hint: Don't forget that the panels have two sides!
Express your answer with the appropriate units.
► View Available Hint(s)
P =
Submit
μA
Value
Previous Answers
W
....
?

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