Trimech-Main-Site-Group-Navigation Trimech-Main-Site-Group-Navigation Trimech-Main-Site-Group-Navigation Solid-Solutions-Group-Navigation Javelin-Group-Navigation Solid-Print-Group-Navigation 3DPRINTUK-Group-Navigation Trimech-Enterprise-Solutions-Group-Navigation Trimech-Enterprise-Solutions-Group-Navigation Trimech-Advanced-Manufacturing-Group-Navigation Trimech-Staffing-Solutions-Group-Navigation
With over 35 years of experience, the TriMech Group offers a comprehensive range of design, engineering, staffing and manufacturing solutions backed by experience and expertise that is unrivalled in the industry. The TriMech Group's solutions are delivered by the divisions and brands shown here, use the links above to visit the group's websites and learn more.

CFD Simulation: Validating SOLIDWORKS Flow Simulation for Thermal Analysis

Friday September 15, 2023 at 8:00am

SOLIDWORKS Simulation is used to predict a wide range of design and engineering scenarios using real-world physics in a virtual environment.

In this series, we’re looking at three simulation applications: fluid dynamics, linear analysis, and electronic cooling. We’ll validate the results of these studies to show you how accurate virtual testing with SOLIDWORKS can be.

Last time we looked at how we could validate the performance of the finite element analysis (FEA) software SOLIDWORKS Simulation through a pre-tensioned pin.


We’re putting SOLIDWORKS Flow Simulation to the test with a conjugate heat transfer scenario, comparing thermal resistance data from an experimental test rig against a virtual setup in SOLIDWORKS Flow Simulation.

Comparing results from the virtual analysis against physical test data is an excellent way to validate and have confidence in the software, as it proves that it can replicate what happens in a real-world scenario.

Ultimately, this allows you to predict whether a new design will meet its intended purpose prior to investing in prototyping or production, resulting in significant time and cost savings.

Preparing the Model for Analysis

The setup involves a computer chip (power transistor) and heat sink described in Unshrouded Plate Fin Heat Sinks for Electronics Cooling: Validation of a Comprehensive Thermal Model and Cost Optimization in Semi-Active Configuration by Ventola et al.

The experimental test rig described by Ventola et al. is show below.

A computer chip (transistor) is mounted on a heat sink which has a thermocouple fitted to record the temperature. This is then fitted into a ducting system with fan to provide cooling.

To replicate the test rig, a 3D CAD model was created in SOLIDWORKS.

A chip component provides the heat power.

An aluminium heat sink sits on top.

A thermal contact resistance was also assigned to the faces between chip and heat sink of 7.75e-5 K.m2/W

An air cavity was created which surrounded the fins of the heat sink (at ambient pressure and temperature). This meant the flow simulation could be considered as an internal study.

Heat conduction and gravity were also activated.



Several studies were run at various volume flow rates corresponding to different fan speeds on the experimental test rig.

Each one corresponded to a particular air temperature and heat power on the chip.


A mesh sensitivity study was run with just under 2.5 million cells.

The outputs of this showed little difference when compared against a faster model containing less than 90 thousand cells (within 4%).

Results for the fast simulation are reported for all except the test case (marked with an *).


Comparison of results from hand calculation (analytical), test rig data (experimental) and SOLIDWORKS Flow Simulation results.

The following formula was used to calculate the thermal resistance:


2D cut plot showing velocity.
3D surface plot showing temperature.
ISO surface plots showing temperature.
2D Cut plot showing temperature with velocity vectors.
2D Cut plot showing temperature (transverse).


SOLIDWORKS Flow Simulation matched the experimental test rig data to within 4% of the calculated thermal resistance values. This is an excellent result.

From this point onwards, having a validated model means the effect of any new design changes can be quickly investigated through SOLIDWORKS Flow Simulation with confidence to avoid any costly failures.

It can also help to optimise the design by answering questions such as:

  1. Can a cheaper fan be used?
  2. Would a higher power chip overheat?
  3. Does the heat sink need to be so big?
  4. Would other components be cooled enough if added?
  5. Can the position of the fan be changed to make the design more compact?
  6. Would restricted access cause ventilation dead spots?

Adding the power of SOLIDWORKS Flow Simulation to your design portfolio means having the ability to answer all these questions more. It allows you to design in an affordably rapid manor and try out many “What if…?” scenarios that would simply take too long, or be too costly by and other method.

To find out more, visit our SOLIDWORKS Flow Simulation pages, where you can find the package to suit your needs.

Or get in touch to see how SOLIDWORKS can help improve the products you design and manufacture.

Take the Next Steps...

If you need help with SOLIDWORKS Simulation, our team can help you achieve accurate results and sharpen your skills.

Here’s a quick rundown of how we can help you get the best from SOLIDWORKS Simulation and virtual testing with our Simulation services.

Not only do we offer CPD-accredited training courses, but also finger-tip access to an expert Technical Support team and consultants who will tailor to your needs.

Related Blog Posts

How to Find Your SOLIDWORKS Serial Number
SOLIDWORKS serial numbers can be found within the Help section of your SOLIDWORKS session and within your Windows Registry.
Top 3 Benefits of SOLIDWORKS Composer
Discover the three key benefits SOLIDWORKS Composer and how they apply to businesses in any industry.
What are the Best File Formats to Export from SOLI
Discover the best neutral file formats to use when exporting files from SOLIDWORKS.

 Solid Solutions | Trimech Group