Explanation Given information: The emissivity and absorptivity of the absorber is 0.9 , the temperature at the top surface of the absorber is 35 ° C , the heat flux due to solar radiation is 500 W / m 2 , the surrounding temperature is 0 ° C , the convective heat transfer coefficient is 5 W / m 2 ⋅ K and the ambient temperature is 25 ° C . Write the expression for the differential equation for the steady one-dimensional heat conduction through the wall. d 2 T d x 2 = 0 ...... (I) Write the expression for the Fourier law of heat conduction. q ˙ 0 = − k d T d x ...... (II) Here, the heat flux is q ˙ 0 , the thermal conductivity is k and the temperature is T . Write the expression for the net heat flux absorbed by the solar collector at the top surface. q ˙ 0 = α q solar − ε σ ( T 0 4 − T surr 4 ) − h ( T 0 − T ∞ ) ...... (III) Here, the absorptivity of the plate is α , the emissivity of the plate is ε , the heat flux due to solar radiation is q solar , the Stefan’s Boltzmann constant is σ , the initial temperature ( at x = 0 ) is T 0 , the temperature of surrounding is T surr , the convective heat transfer coefficient is h and the ambient temperature is T ∞ . Calculation: Integrate Equation (I) on the both side. ∫ ( d 2 T d x 2 ) = ∫ 0 d T d x = C 1 ...... (IV) Here, the arbitrary constant is C 1 . Integrate Equation (IV) on the both sides. ∫ ( d T d x ) = ∫ C 1 T ( x ) = C 1 x + C 2 ...... (V) Here, the arbitrary constant is C 2 . Apply boundary conditions in Equation (II) and Equation (IV) to find the arbitrary constants C 1 and C 2 . Substitute 0 for x and T 0 for T in Equation (II). q ˙ 0 = − k d T 0 d x d T 0 d x = − q ˙ 0 k ...... (VI) Substitute T 0 for T in Equation (IV). d T 0 d x = C 1 Substitute C 1 for d T 0 d x in Equation (VI). C 1 = − q ˙ 0 k Substitute 0 for x and T 0 for T in Equation (V). T 0 = C 1 ( 0 ) + C 2 C 2 = T 0 Substitute − ( q ˙ 0 k ) for C 1 and T 0 for C 2 in Equation (V)

6th Edition

ISBN: 9780073398198

Author: CENGEL

Publisher: RENT MCG

See similar textbooks

Question

Chapter 2, Problem 66P

To determine

The proof of T(x)=−(q˙0/k)x+T0 .

The net flux q˙0 absorbed by the solar collector.

Expert Solution & Answer

Want to see the full answer?

Check out a sample textbook solution

See solution

Chapter 2, Problem 65P

Chapter 2, Problem 67P

Students have asked these similar questions

A boiler with 80% efficiency produces steam at 40bar and 500 C at a rate of 1.128kg/s. The temperature of the feed water is raised from 25 C to 125 C in the economizer and the ambient air is drawn to the boiler at a rate of 2.70 kg/s at 16 C. The flue gases leave the chimney at rate of 3 kg/s at 150 C with specific heat of 1.01 kJ/kg.K. The dryness fraction of steam collected in the steam drum is 0.95. 1- Determine the heat value of the fuel. 2- The equivalence evaporation. 3- Draw the heat balance sheet.

A rotating shaft is made of 42 mm by 4 mm thick cold-drawn round steel tubing and has a 6 mm diameter hole drilled transversely through it. The shaft is subjected to a pulsating torque fluctuating from 20 to 160 Nm and a completely reversed bending moment of 200 Nm. The steel tubing has a minimum strength of Sut = 410 MPa (60 ksi). The static stress-concentration factor for the hole is 2.4 for bending and 1.9 for torsion. The maximum operating temperature is 400˚C and a reliability of 99.9% is to be assumed. Find the factor of safety for infinite life using the modified Goodman failure criterion.

I need help with a MATLAB code. This code just keeps running and does not give me any plots. I even reduced the tolerance from 1e-9 to 1e-6. Can you help me fix this? Please make sure your solution runs. % Initial Conditions rev = 0:0.001:2; g1 = deg2rad(1); g2 = deg2rad(3); g3 = deg2rad(6); g4 = deg2rad(30); g0 = deg2rad(0); Z0 = 0; w0 = [0; Z0*cos(g0); -Z0*sin(g0)]; Z1 = 5; w1 = [0; Z1*cos(g1); -Z1*sin(g1)]; Z2 = 11; w2 = [0; Z2*cos(g2); -Z2*sin(g2)]; [v3, psi3, eta3] = Nut_angle(Z2, g2, w2); plot(v3, psi3) function dwedt = K_DDE(~, w_en) % Extracting the initial condtions to a variable % Extracting the initial condtions to a variable w = w_en(1:3); e = w_en(4:7); Z = w_en(8); I = 0.060214; J = 0.015707; x = (J/I) - 1; y = Z - 1; s = Z; % Kinematic Differential Equations dedt = zeros(4,1); dedt(1) = pi*(e(3)*(s-w(2)-1) + e(2)*w(3) + e(4)*w(1)); dedt(2) = pi*(e(4)*(w(2)-1-s) + e(3)*w(1) - e(1)*w(3)); dedt(3) = pi*(-e(1)*(s-w(2)-1) - e(2)*w(1) + e(4)*w(3));…

Chapter 2 Solutions

HEAT+MASS TRANSFER:FUND.+APPL.

Ch. 2 - How does transient heat transfer from steady heat...Ch. 2 - Is heat transfer a scalar or a vector quantity?...Ch. 2 - Does a hear flux vector at a point P on an...Ch. 2 - From a heat transfer point of view, what is the...Ch. 2 - What is heat generation in a solid? Give examples.Ch. 2 - Heat generation is also referred to as energy...Ch. 2 - In order to size the compressor of a new...Ch. 2 - In order to determine the size of the heating...Ch. 2 - Consider a round potato being baked in an oven....Ch. 2 - Consider an egg being cooked in boiling water in a...

Knowledge Booster

The proof of T ( x ) = − ( q ˙ 0 / k ) x + T 0 . The net flux q ˙ 0 absorbed by the solar collector.

The proof of T(x)=−(q˙0/k)x+T0 . The net flux q˙0 absorbed by the solar collector.

Want to see the full answer?

Chapter 2 Solutions

The proof of T(x)=−(q˙0/k)x+T0 .

The net flux q˙0 absorbed by the solar collector.