- T2 300k L 1m A B T1 150k L 1m T1 150k L 1m D C T1 150k L 1m F Use The Boundary Conditions For The Problem In Hw3 In 1 (40.95 KiB) Viewed 36 times
- T2 300k L 1m A B T1 150k L 1m T1 150k L 1m D C T1 150k L 1m F Use The Boundary Conditions For The Problem In Hw3 In 2 (18.25 KiB) Viewed 36 times
- T2 300k L 1m A B T1 150k L 1m T1 150k L 1m D C T1 150k L 1m F Use The Boundary Conditions For The Problem In Hw3 In 3 (25.56 KiB) Viewed 36 times
T2=300K L=1m A B T1=150K L=1m T1=150K L=1m D C T1=150K L=1m
(f) Use the boundary conditions for the problem in HW3, in which the left side (AD) is subjected to a constant temperature T3 = 2006, the bottom side (DC) is subjected to an incoming heat flux qº=5000 W/m², and the right side (CB) is subjected to the convection that T.=150K and h=200 W/m². 9
K, and the top side (AB) is adiabatic. Repeat (b) for this new set of boundary conditions. Does this problem have an exact/analytic solution? • If yes, please use the analytic/exact solution as a benchmark to quantify the error in your FD solution. • If not, how do you know your solution is correct or not? How can you quantify the error?