Upfront thermal simulation helps design products for life or death situations
By Bob Cramblitt
 Upfront thermal simulation was an integral part of the design process for the SureFire X400, the first weapon-mounted assembly to combine a flashlight with a red targeting laser in the same lightweight package. |
When companies talk about life or death situations, it’s usually metaphorical. In the case of SureFire, maker of high-end illumination tools used by the U.S. military and law enforcement officers, it’s an all-consuming reality. It is a reality that has made upfront thermal simulation an integral part of the company’s design process.
The latest SureFire product, the X400, is the first weapon-mounted assembly to combine a flashlight with a red targeting laser in the same lightweight package. At the heart of the X400 is a powerful LED that cranks out more lumens than other light sources, but also generates a great deal more heat that has to be dissipated by the light housing.
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“Upfront thermal analysis with CFdesign has enabled us to explore uncharted territories,” says Deepanjan Mitra, SureFire’s thermal analysis engineer. “It has given us the chance to virtually test ideas and optimize designs before physically prototyping the product.”
From Incandescent To LEDAccording to Paul Kim, vice president of engineering for SureFire, thermal analysis became necessary when the company’s products converted from incandescent illumination to high-powered LED lighting.
“In terms of thermal management, LEDs are like semiconductor devices,” says Kim. “As you put out more light, you generate more heat. The cooler we can run the device, the more photons, or light, we can put out.”
Unlike semiconductors, whose failure might be an inconvenience or cause a temporary loss of data, SureFire products are required to function at all times under extreme environmental conditions in the field.
“When we say mission-critical, we mean that it must perform under all circumstances in all parts of the world,” says Kim. “In many cases, the operation of the flashlight could make a difference between life and death.”
Integrated CAD And CFD  From concept through the detailed design phase, Surefire engineers made product improvements by probing digital prototypes to pinpoint precise internal and external temperatures driven by natural convection and radiation. |
SureFire created the preliminary design for the X400 in Pro/ENGINEER, and then opened it in
CFdesign upfront CFD software. CFdesign is integrated with Pro/ENGINEER and other major CAD packages, so users can work directly on the CAD model, eliminating the translation step and data loss associated with traditional
CFD software. The associability between Pro/E and CFdesign provides flexibility to explore more options upfront in the design process, according to Mitra.
“Using the CAD package, I can choose the complexity of my models,” says Mitra. “For quick and dirty answers, I can suppress all cosmetic features and perform an analysis on the critical heat paths, which typically answers the more fundamental design questions.”
The quick analysis is followed by upfront analyses on full models which can illustrate more complex interactions and also be used as a marketing tool to highlight new features.
Simulating Flow-Field ConditionsAn important capability of upfront CFD for SureFire is the ability to simulate flow-field conditions such as convection coupled with heat generation. The results from these simulations are used to generate transient simulations that give SureFire engineers a picture of how fast temperatures rise in the flashlight according to factors such as materials, heat-sink design, LED power and fin spacing and design.
Thermal analysis was crucial in two major aspects of X400 design according to Kim and Mitra:
- Optimizing the design of housings, especially thermal isolation of the laser unit.
- Determining the best settings for thermal management firmware.
Flashlight housings primarily act as large heat sinks that need to be designed to dissipate as much heat into the ambient air as possible. This is especially important with LEDs and the high-powered LED lamp in the X400 dissipates almost 85 percent of its input power as heat.
 Full product details in the CAD model were included in the final stage of CFdesign analyses, providing a total picture of product performance before physical test validation. |
The X400 presents an additional challenge: isolating the laser housing. The laser diode needs to be maintained at a temperature well below that of the LED. Since the main lamp body is mechanically coupled to the laser housing for shock isolation, insulation is needed to minimize the amount of heat from the main lamp that reaches the laser housing.
SureFire used CFdesign to perform various “what-if” scenarios, balancing heat dissipation with the need to minimize the size and weight of the weapon-mounted light. To determine housing material and insulation thicknesses, SureFire ran thermal simulations showing how fast heat traveled to the laser housing. The simulations enabled SureFire to predict when the laser diode would fail based on a visualized temperature field.
“We simulated a bunch of scenarios with different housing materials and insulation thicknesses, which led to us being able to determine design requirements,” says Mitra. “This is really simple, since it only amounts to changing the material property of the part in CFdesign and rerunning the analysis.”
The other major simulation area for the X400 was thermal management. A microprocessor in the flashlight regulates power to the LED based on feedback from sensors, controlling the overall temperature of the device. Simulations helped SureFire determine optimal settings for the thermal management firmware.
“Simulations showed us the thermal characteristics of the whole assembly,” says Kim. “Using the results, we could define a cut-off temperature at which to activate the microprocessor-based thermal management algorithm.”
Time Savings And BeyondUsing CFdesign software early in the design process eliminated three different design prototypes that