Fundamentals of Heat and Mass Transfer
Fundamentals of Heat and Mass Transfer
7th Edition
ISBN: 9780470501979
Author: Frank P. Incropera, David P. DeWitt, Theodore L. Bergman, Adrienne S. Lavine
Publisher: Wiley, John & Sons, Incorporated
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Chapter 12, Problem 12.30P

A furnace with a long, isothermal, graphite tube of diameter D   = 12.5   m m is maintained at T f = 2000 K and is used as a blackbody source to calibrate heat flux gages. Traditional heat flux gages are constructed as blackened thin films with thermopiles to indicate the temperature change caused by absorption of the incident radiant power over the entire spectrum. The traditional gage of interest has a sensitive area of 5 mm2 and is mounted coaxial with the furnace centerline, but positioned at a distance of L   = 60   m m from the beginning of the heated section. The cool extension tube serves to shield the gage from extraneous radiation sources and to contain the inert gas required to prevent rapid oxidation of the graphite tube

Chapter 12, Problem 12.30P, A furnace with a long, isothermal, graphite tube of diameter D=12.5mm is maintained at Tf=2000K and

(a) Calculate the heat flux (W/m2) on the traditional gage for this condition, assuming that the extension tube is cold relative to the furnace.

(b) The traditional gage is replaced by a solid-state (photoconductive) heat flux gage of the same area, but sensitive only to the spectral region between 0.4   a n d   2.5 μ m . Calculate the radiant heat flux incident on the solid-state gage within the pre- scribed spectral region.

(c) Calculate and plot the total heat flux and the heat flux in the prescribed spectral region for the solid- state gage as a function of furnace temperature for the range . Which gage will have an output signal that is more sensitive to changes in the furnace temperature?

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Chapter 12 Solutions

Fundamentals of Heat and Mass Transfer

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