White Papers

Mini-fridges, commonly filled with beer and the occasional moldering sandwich, have become a ubiquitous fixture in college dorm rooms and office break areas. But for some reason they never seem to cool their contents as well as their full-size cousins in the kitchen. This paper, based on a series of blog entries, presents a light-hearted look at the problem and offers a solution. In doing so, it demonstrates some practical thermal analysis methods using Mentor Graphics FloTHERM and proves that thermal simulation can help engineers design better products for consumers.

This paper examines the thermal performance limits of a flip chip package. A PGA package with Direct Chip Attach (DCA) interconnect was chosen to demonstrate the approach.

Experiments were performed with a thermal test chip to validate the CFD model, which was used to predict the thermal performance limits of the package. Overall simulation and experimental to within 6%.

This paper describes the 3D thermal investigation of a digital rectifier module, dissipating the maximum amount of heat when operating at 110V. A 3D numerical CFD model of the whole package was constructed in FloTHERM.

The results of several rectifier configurations (including changes in components arrangement and ventilation entrance/exhaust) were investigated in order to identify deficient ventilation and high temperature regions.

This paper shows how the adiabatic heat transfer coefficient concept can be used in system-level thermal design with CFD by exploiting the principle of superposition. The method requires no additional analysis methods except for matrix multiplication.

For forced convection systems where radiation and natural convection effects are minimal, the results of this study have shown excellent correlation.

This paper presents the thermal analysis performed on an aircraft engine Electronic Control Unit (ECU) installed in the engine environment. Part of the nacelle and ECU are modeled with and without cooling air, as specified by the engine manufacturer.

Different geometric configurations are simulated providing boundary conditions for a detailed thermal analysis of the ECU itself.

This article shows measured and simulated airflows through Hybricon’s 9 slot CompactPCI tower, demonstrating the accuracy of the simulations. Actual airflow measurements for two competitors’ enclosures are also presented to demonstrate just how important the simulation-measurement process is in chassis development.

FloTHERM simulations were compared with airflow and temperature measurements performed with Cambridge Accusense ATM-24 equipment.