as

mgrid_2/getmatrix.cpp

@@ -434,7 +434,7 @@ double FEM_Matrix::ThermalConductivity(const int subdomain)
     {
         // ceramic mug
         case 0:
-            lambda = 6.0;           // anything from 1 to 4
+            lambda = 10.0;           // anything from 1 to 4
             break;
 
         // water
@@ -682,7 +682,7 @@ double FEM_Matrix::Heat_transfer_coefficient(const int subdomain)
 
         // air to air (Free Convection Gas - Free Convection Gas : U = 1 - 2 W/m2K  (typical window, room to outside air through glass))
         case 2:
-            alpha = 1.0;
+            alpha = 15.0;
             break;
 
         default:

solid-cpp/ownSolver.cpp

@@ -167,6 +167,7 @@ int main(int argc, char **argv )
             uv[nodeIndex] = temperature[i];
         } 
 
+
         // ----- solve time step -----
         vector<double> G(Mdt.Nrows(), 0.0);        
         Mdt.Mult(G, uv);                                           // G = M/dt * u_{n}
@@ -188,17 +189,15 @@ int main(int argc, char **argv )
         cout << "% of elements above temperature " << goal_temp << "ºC: " << percentage_temp_reached << endl;
         time_count += dt;
 
-        // ----- write the heat-flux, so openFOAM can read it
-        // TODO: COMPUTE THE HEAT-FLUX FROM THE NEW uv TEMPERATURE SOLUTION
-        // "computeHeatFlux(heatFlux)"
+        // ----- compute and write the heat-flux, so openFOAM can read it
         for (int i = 0; i < numberOfVertices; ++i)
         {
-            heatFlux[i] = 300.0;
+            int nodeIndex = wetNodes[i];
+            heatFlux[i] = 15.0*(uv[nodeIndex] - 31.0);  // alpha is assumed 15.0 regardless of material
         } 
-
-
         participantSolid.writeData("Solid-Mesh", "Heat-Flux", vertexIDs, heatFlux);
 
+
         // ----- advance preCICE -----
         participantSolid.advance(dt);