Category Archives: LED

Cooling High Power LEDs

Most LEDs are designed in SMT (surface mount technology) or COB (chip-on-board) packages. In the new 1~8W range of surface mount power LED packages, the heat flux at the devices thermal interface can range from 5 to 20 W/cm2. These AllnGaP and InGaN semiconductors have physical properties and limits similar to other transistors or ASICs (application specific integrated circuit). While the heat of filament lights can be removed by infrared radiation, LEDs rely on conductive heat transfer for effective cooling.

As higher powers are dissipated from LED leads and central thermal slugs, boards have changed to move this heat appropriately. Standard FR-4 technology boards can still be used for LEDs with up to 0.5 W of dissipation, but metallic substrates are required for higher levels. A metal core printed circuit board (MCPCB), also known as an insulated metal substrate (IMS) board, is often used underneath 1W and larger devices. These boards typically have a 1.6 mm (1/16 inch) base layer of aluminum with a dielectric layer attached. Copper traces and solder masks are added subsequently. The aluminum base allows the heat to move efficiently away from the LED to the system.

Increasing power density, a higher demand for light output, and space constraints are leading to more advanced cooling solutions. High-efficiency heat sinks, optimized for convection and radiation within a specific application, will become more and more important.

As with any semiconductor package, thermal resistance plays a significant role in the thermal management of LEDs. The highest thermal resistance in the heat transfer path is the junction-to-board thermal resistance (Rj-b) of the package [2]. Spreading resistance is also an important issue. Thermally enhanced spreader materials, such as metal core PCBs, cold plates, and vapor chambers for very high heat flux applications are viable systems to reduce spreading resistance. [3]

Linear heat sinks are available specifically for LED strips, such as OSRAM SYLVANIA’s DRAGONstick® linear LED strips, which are widely used in architectural lighting. For example,the maxiFLOW linear heat sink from Advanced Thermal Solutions, Inc., has a patented spread fin array that maximizes surface area for more effective convection (air) cooling, particularly when air flow is limited, such as inside display cases.

Round heat sinks are available specifically for round LED boards, which are used to replace halogen light bulbs, in applications such as spotlights and down lighting. A typical LED spotlight is shown in Figure 2 [5]. Here, a round QooLED© heat sink from Advanced Thermal Solutions is used for cooling three LEDs. The round heat sink has a special star-shaped profile fin design that maximizes surface area for more effective convection (air) and radiation cooling in the vertical mounting orientation, e.g., inside ceilings.

Active thermal management systems can be used for high-flux power LED applications. These include water cooling, two-phase cooling, and fans. Although active cooling methods may not be energy-justifiable for LEDs, reasons for using them include ensuring lumen output or maintenance-free operation, or to meet specific wavelength requirements.

Check out the new and improved LED Cooling Resource Kit

ATS, Advanced Thermal Solutions, Inc, has compiled several expert technical resources for thermally managing LED lighting. The Expert Resource Kit for Better Thermal Management of LED Lighting is compendium of free downloadable information.

The Kit is specifically for thermal management professionals in the LED lighting industry and for engineers who are responsible for ensuring the proper performance of LED designs.

Included in the Resource Kit are:

  • LED Heat Transfer and Cooling Options: Lighting the Way for LED Development
  • Mentor Graphics Webinar (free registration required): Diagnosing and Solving Thermal Challenges in Next Generation LED
  • ATS Case Study: Feasibility Study of an LED-Based Lighting System Using Analytical Modeling
  • ATS Article: How to Cool High Power LEDs
  • Clemens Lasance Lecture on LED Thermal Management: Thermal Management for LED Applications: What is the Role of the PCB?
  • Clemens Lasance, Michael Gay, Norm Berry, Richard A. Wessel on MCPCBs for LED Applications:MCPCBs for LED Applications, Thermal Management Material Specifications
  • Dr. Kaveh Azar Video Interview: LED Heat Sink Types and Applications

The free LED Cooling Resource Kit can be accessed at: http://qats.com/cms/free-thermal-management-led-lighting-resource-kit/

 

What are LED Heat Sinks and How to Use them: Interview with Dr. Kaveh Azar

Dr. Kaveh Azar, President and CEO of Advanced Thermal Solutions, and John O’Day, Director of Marketing, sat down to discuss what an LED heat sink is, and how to use them. Our 5 minute, informal interview is chock full of information on LED heat sinks.

ATS Updates LED Cooling Resource Kit

We’ve just updates our LED Cooling Resource Kit and we invite our readers to get their own copy. It’s openly available for free to thermal engineers and other LED lighting professionals.

The kit now includes a link to an LED light reference design and an interview with Dr. Kaveh Azar on the different types and applications for LED Lighting heat sinks.

You can get your copy by clicking to this link: LED Cooling Resource Kit

ATS Thermal Management Case Studies show real world thermal problems and solutions

We’ve written a number of case studies on thermal analysis and thermal design for LED Lights, thermally optimizing a PCB, and even liquid cooling. We thought we’d put them in one place up to now to make them easier to find. You can do this yourself as well by clicking on the drop down box “blog article categories” in the right hand column of our blog and choosing the category “case study”.

LED Lights:

Telecommunciations

Homeland Security

PCB:

Semiconductor Automatic Test Equipment

System Level Optimization

Computer High Power Boards

Liquid Cooling