Why my heat node goes below zero??

조회 수: 15 (최근 30일)
준
2024년 12월 1일
댓글: Sandeep Mishra 2024년 12월 2일
% Simulation Parameters
dt = 10; % Time step [s]
t_max = 2000; % Maximum simulation time [s]
Nx = 34; % Number of horizontal nodes (가로)
Ny = 40; % Number of vertical nodes (세로)
dx = 1; dy = 1; % Spatial resolution
T_infinite = 20; % Ambient air temperature
sigma = 5.67e-8; % Stefan-Boltzmann constant
epsilon = 0.3;
h_air = 15; % Convective heat transfer coefficient [W/m^2K]
h = ones(Ny, Nx); % Initialize convective heat transfer coefficient
% Initialize material properties
k = 0.025 * ones(Ny, Nx); % Default thermal conductivity
c = ones(Ny, Nx); % Specific heat capacity
rho = 1.2 * ones(Ny, Nx);
T = T_infinite * ones(Ny, Nx); % Initial temperature field
T(i, end)=400;
T_conv_bottom=20;
T_conv_left=20;
% ABS (x=6:8, y=1:13), (x=28:30, y=1:13), (x=9:27, y=1:4)
k(1:13, 6:8) = 0.23; T(1:13, 6:8) = 21; rho(1:13, 6:8) = 1040;
k(1:13, 28:30) = 0.23; T(1:13, 28:30) = 21; rho(1:13, 28:30) = 1040;
k(1:4, 9:27) = 0.23; T(1:4, 9:27) = 21; rho(1:4, 9:27) = 1040;
c(1:13, 6:8) = 1.5; % 비열 [J/gK]
c(1:13, 28:30) = 1.5;
c(1:4, 9:27) = 1.5;
% Handle (x=6:9, y=29:30), (x=6:7, y=20:28)
k(29:30, 6:9) = 0.3; T(29:30, 6:9) = 19; rho(29:30, 6:9) = 950;
k(20:28, 6:7) = 0.3; T(20:28, 6:7) = 19; rho(20:28, 6:7) = 950;
c(29:30, 6:9) = 2.0;
c(20:28, 6:7) = 2.0;
% Vacuum (x=11, y=10:31), etc.
h(10:31, 11) = 0.0003;
h(10, 11:12) = 0.0003;
h(6:10, 12) = 0.0003;
h(6, 12:24) = 0.0003;
h(6:10, 24) = 0.0003;
h(10, 24:25) = 0.0003;
T(10:31, 25) = 14;
T(10:31, 11) = 14;
T(10, 11:12) = 14;
T(6:10, 12) = 14;
T(6, 12:24) = 14;
T(6:10, 24) = 14;
T(10, 24:25) = 14;
T(10:31, 25) = 14;
rho(10:31, 11) = 0;
rho(10, 11:12) = 0;
rho(6:10, 12) = 0;
rho(6, 12:24) = 0;
rho(6:10, 24) = 0;
rho(10, 24:25) = 0;
c(10:31, 11) = 0;
c(10, 11:12) = 0;
c(6:10, 12) = 0;
c(6, 12:24) = 0;
c(6:10, 24) = 0;
c(10, 24:25) = 0;
% Ice (x=15:21, y=27:30)
k(27:30, 15:21) = 2.2; c(27:30, 15:21) = 2.06; T(27:30, 15:21) = -15;
rho(27:30, 15:21) = 917;
c(27:30, 15:21) = 2.06;
% Water (x=13, y=12:30), etc.
k(12:30, 13) = 0.575; h(12:30, 13) = 200; c(12:30, 13) = 4.186; T(12:30, 13) = 4;
k(8:30, 14) = 0.575; h(8:30, 14) = 200; c(8:30, 14) = 4.186; T(8:30, 14) = 4;
k(8:26, 15:21) = 0.575; h(8:26, 15:21) = 200; c(8:26, 15:21) = 4.186; T(8:27, 15:21) = 4;
k(8:30, 22) = 0.575; h(8:30, 22) = 200; c(8:30, 22) = 4.186; T(8:30, 22) = 4;
k(12:30, 23) = 0.575; h(12:30, 23) = 200; c(12:30, 23) = 4.186; T(12:30, 23) = 4;
rho(12:30, 13) = 1000;
rho(8:30, 14) = 1000;
rho(8:36, 15:21) = 1000;
rho(8:30, 22) = 1000;
c(12:30, 23) = 4.186;
c(12:30, 13) = 4.186;
c(8:30, 14) = 4.186;
c(8:36, 15:21) =4.186;
c(8:30, 22) = 4.186;
c(12:30, 23) =4.186;
% Air inside tumbler (x=15:21, y=31:34), etc.
k(31:34, 15:21) = 0.025; h(31:34, 15:21) = 2;
k(31:32, 14) = 0.025; h(31:32, 14) = 2;
k(31, 13) = 0.025; h(31, 13) = 2;
k(31, 23) = 0.025; h(31, 23) = 2;
k(31:32, 22) = 0.025; h(31:32, 22) = 2;
T(31:32, 14) = 8;
T(31, 13) = 8;
T(31, 23) = 8;
T(31:32, 22) = 8;
T(31:34,15:21) = 8;
rho(31:34, 15:21) = 1.2;
rho(31:32, 14) = 1.2;
rho(31, 13) = 1.2;
rho(31, 23) = 1.2;
rho(31:32, 22) = 1.2;
c(31:34, 15:21) = 1.005;
c(31:32, 14) = 1.005;
c(31, 13) = 1.005;
c(31, 23) = 1.005;
c(31:32, 22) = 1.005;
% Stainless steel outside (x=12:14, y=34), etc.
k(34, 12:14) = 15.2; T(34, 12:14) = 19;
k(34, 22:24) = 15.2; T(34, 22:24) = 19;
k(33, 11:12) = 15.2; T(33, 11:12) = 19;
k(33, 24:25) = 15.2; T(33, 24:25) = 19;
k(32, 25:26) = 15.2; T(32, 25:26) = 19;
k(32, 10:11) = 15.2; T(32, 10:11) = 19;
k(9:32, 26) = 15.2; T(9:32, 26) = 19;
k(31:32, 11) = 15.2; T(31:32, 10) = 19;
k(9:32, 10) = 15.2; T(9:32, 10) = 19;
k(5:9, 11) = 15.2; T(5:9, 11) = 19;
k(5:9, 25) = 15.2; T(5:9, 25) = 19;
k(5, 11:25) = 15.2; T(5, 11:25) = 19;
rho(34, 12:14) = 8000;
rho(34, 22:24) = 8000;
rho(33, 11:12) = 8000;
rho(33, 24:25) = 8000;
rho(32, 25:26) = 8000;
rho(32, 10:11) = 8000;
rho(9:32, 26) = 8000;
rho(31:32, 11) = 8000;
rho(9:32, 10) = 8000;
rho(5:9, 11) = 8000;
rho(5:9, 25) = 8000;
rho(5, 11:25) = 8000;
c(34, 12:14) = 0.5;
c(34, 22:24) = 0.5;
c(33, 11:12) = 0.5;
c(33, 24:25) = 0.5;
c(32, 25:26) =0.5;
c(32, 10:11) = 0.5;
c(9:32, 26) = 0.5;
c(31:32, 11) =0.5;
c(9:32, 10) = 0.5;
c(5:9, 11) = 0.5;
c(5:9, 25) = 0.5;
c(5, 11:25) = 0.5;
% Stainless steel inside (x=13:14, y=33), etc.
k(33, 13:14) = 16.2; T(33, 13:14) = 5;
k(33, 22:23) = 16.2; T(33, 22:23) = 5;
k(32, 23:24) = 16.2; T(32, 23:24) = 5;
k(32, 12:13) = 16.2; T(32, 12:13) = 5;
k(11:31, 12) = 16.2; T(11:31, 12) = 5;
k(11:31, 24) = 16.2; T(11:31, 24) = 5;
k(11, 23:24) = 16.2; T(11, 23:24) = 5;
k(11, 12:13) = 16.2; T(11, 12:13) = 5;
k(7:10, 13) = 16.2; T(7:10, 13) = 5;
k(7:10, 23) = 16.2; T(7:10, 23) = 5;
k(7, 13:23) = 16.2; T(7, 13:23) = 5;
rho(33, 13:14) = 8000;
rho(33, 22:23) = 8000;
rho(32, 23:24) = 8000;
rho(32, 12:13) = 8000;
rho(11:31, 12) = 8000;
rho(11:31, 24) = 8000;
rho(11, 23:24) = 8000;
rho(11, 12:13) = 8000;
rho(7:10, 13) = 8000;
rho(7:10, 23) = 8000;
rho(7, 13:23) = 8000;
c(33, 13:14) = 0.5;
c(33, 22:23) = 0.5;
c(32, 23:24) = 0.5;
c(32, 12:13) = 0.5;
c(11:31, 12) = 0.5;
c(11:31, 24) = 0.5;
c(11, 23:24) = 0.5;
c(11, 12:13) = 0.5;
c(7:10, 13) = 0.5;
c(7:10, 23) = 0.5;
c(7, 13:23) = 0.5;
%lid
k(35:36,14:22)= 0.2;
T(35:36,14:22)= 15;
rho(35:36, 14:22) = 950;
c(35:36, 14:22) = 1.75;
% Simulation Loop
figure;
colormap(jet);
imagesc(flipud(T), [-20, 400]);
colorbar;
title('Initial Temperature Distribution (t = 0)');
xlabel('X-Axis (Nodes)');
ylabel('Y-Axis (Nodes)');
videoFile = 'simulation_result.mp4';
v = VideoWriter(videoFile, 'Motion JPEG AVI');
v.FrameRate = 10;
open(v);
for t = 1:t_max
T_new = T; % Create a new array for updated temperatures
% Update internal nodes
for i = 2:Ny-1
for j = 2:Nx-1
T_cond = k(i, j) / (rho(i, j) * c(i, j)) * ...
((T(i+1, j) - 2*T(i, j) + T(i-1, j)) / dx^2 + ...
(T(i, j+1) - 2*T(i, j) + T(i, j-1)) / dy^2);
T_conv = h(i, j) * (T_infinite - T(i, j)) / (rho(i, j) * c(i, j));
T_new(i, j) = T(i, j) + dt * (T_cond + T_conv);
end
end
% Boundary conditions
% Bottom boundary (convection)
for j = 1:Nx
T_conv_bottom = h_air / (rho(Ny, j) * c(Ny, j)) * (T_infinite - T(Ny, j));
T_new(Ny, j) = T(Ny, j) + dt * T_conv_bottom;
end
% Left boundary (convection)
for i = 1:Ny
T_conv_left = h_air / (rho(i, 1) * c(i, 1)) * (T_infinite - T(i, 1));
T_new(i, 1) = T(i, 1) + dt * T_conv_left;
end
% Top boundary (insulated)
T_new(1, 2:Nx-1) = T(2, 2:Nx-1);
% Right boundary (fixed 400°C and radiation from 38 to 37)
T_new(:, Nx) = 400;
for i = 2:Ny-1
if i == 38
q_rad = epsilon * sigma * ((T(i, Nx) + 273.15)^4 - (T(i, Nx-1) + 273.15)^4);
T_new(i, Nx-1) = T_new(i, Nx-1) + dt * q_rad / (rho(i, Nx-1) * c(i, Nx-1));
end
end
% Update temperature field
T = T_new;
% Visualization
if mod(t, 10) == 0
imagesc(flipud(T), [-20, 30]);
colorbar;
title(['Time = ', num2str(t * dt), ' seconds']);
xlabel('X-Axis (Nodes)');
ylabel('Y-Axis (Nodes)');
drawnow;
frame = getframe(gcf);
writeVideo(v, frame);
end
end
close(v);
  댓글 수: 4
이전 댓글 2개 표시
준
2024년 12월 2일
i changed the code and reuploaded whats the matter
Sandeep Mishra
Sandeep Mishra 2024년 12월 2일
Hi @준 최
Can you update the existing code or share the variable for easier diagnosis? Also, can you specify the issue you're encountering and your expected result?

댓글을 달려면 로그인하십시오.

이 질문에 답변하려면 로그인하십시오.

답변 (0개)

카테고리

Help CenterFile Exchange에서 Data Distribution Plots에 대해 자세히 알아보기

태그

제품

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by