Design and Simulation of a Heat Exchanger for a Mechanical Coffee Dryer

The drying of coffee is a critical aspect of the post-harvest process and plays a crucial role in achieving high-quality coffee. The drying process requires significant energy to remove moisture from the harvested beans, emphasizing the importance of using efficient equipment and sustainable sources. The capstone project focuses on designing a heat exchanger for a mechanical coffee drying system that uses biomass combustion. This report briefly covers coffee processing, heat exchangers, and computational fluid dynamics. The project compared various heat exchangers and deemed that a shell and tube heat exchanger could meet the requirements of drying 1000 kg of coffee. The project deliverables include a validation study for SolidWorks Flow Simulation 2023, a 3D model of the heat exchanger, and heat and flow simulations. Due to time constraints, there was no constructed physical prototype. Kern’s method was used to produce a thermal-hydraulic design for the first iteration of the shell and tube heat exchanger, and SolidWorks was used to adjust key geometric parameters until the drying goals were met. A validation study of conjugate heat transfer involving laminar and turbulent, incompressible flow in SolidWorks Flow Simulation 2023 was conducted with a max deviation of 3.8% from analytical results. The final heat exchanger design consisted of 19 (44 mm x 50 mm) tubes of 321 stainless steel alloy, one baffle cut 75%, and the tube bundle was 3.25 meters long with a 325.7 mm inner shell diameter. The weight of the tube bundle was 232 kg. The simulated air outlet temperature value reached 51.5°C, producing a pressure drop of 2890 Pascals. The power requirement to overcome pressure drop was calculated to be 4.9 kW, and the effectiveness of the simulated heat exchanger was 72.9%. A mesh convergence study was conducted to confirm the robustness of the simulation at 1.4 million cells.