Reducing Contact Thermal Resistance

Boyd Blog — Wed, 13 May 2020 12:53:00 +0000

Improving Heat Transfer Between Surfaces and Overall Thermal Performance

This thermal resistance can be expressed as Rja, where:

Rja – Thermal resistance from the device junction to ambient air or water
Rjc – Thermal resistance from the device junction to the package case, determined by the electronic device manufacturer (designer has no direct influence)
Rcs – Thermal resistance from the package case to the heat sink or cold plate, determined by the size and quality of the contact areas between the electronic device and the heat sink or cold plate, the materials used, and contact pressure
Rsa – Thermal resistance from the heat sink or cold plate to ambient air or water, determined by the heat sink or cold plate design (material and geometry)

Therefore, one way to reduce Rja is to reduce Rcs, the contact resistance between the electronic device case and ambient-cooled, finned heat sinks or liquid-cooled cold plates. There are several factors that impact Rcs, including surface flatness, surface roughness, contact force or clamping pressure, surface cleanliness, and interface materials.

Surface Flatness and Surface Roughness

Surface flatness can be understood as widely spaced surface irregularities or “waviness” of a surface. Surface roughness is the submicron scale irregularities of a surface, usually as a result of machining, usage, and/or wear.

The contact between two imperfect surfaces will result in air gaps between them. (See Fig. 1.) Most contact areas consist of more than 90% air voids, which represent a significant resistance to heat transfer since air is not a very effective thermal conductor. Table 1 shows typical surface roughness values for different manufacturing processes.

Table 1:

Process	Units in µm	Units in µin
Polishing	0.1 – 0.4	4 – 16
Grinding	0.1 – 1.6	4 – 64
Laser Cutting	0.8 – 6.3	32 – 252
Die Casting	0.8 – 1.6	32 – 64
Machining	0.8 – 1.6	32 – 64
Extrusion	0.8 -3.2	32 – 128
Drilling	1.6 – 6.3	64 – 252

A mounting surface flatness of 0.001 in/in is generally required for satisfactory contact between the electronic device and the heat sink or cold plate. The surface roughness should be equivalent to that of the electronic device, where 32-64 µin is usually adequate. Finer finishes add unnecessary cost with little or no improvement in thermal performance. Surface flatness is typically much more critical than surface finish in achieving a good thermal interface.

Contact Force

Another very important factor in minimizing contact thermal resistance is contact force, or the force with which the electronic device is pushed against the heat sink or cold plate. Electronic device and heat sink surfaces will never be perfectly flat. Consequently, there will always be air gaps in between. However, as the contact force pushing the two surfaces together increases so does the number of contact points between the two surfaces, resulting in a lower case-to-sink thermal resistance, Rcs. This relationship between force and thermal resistance does not follow a linear curve. As contact force is increased, contact thermal resistance will decrease until a point where it will show diminishing returns in thermal resistance reduction and maximum force the package can handle is approached. The electronic device manufacturer should be contacted for recommended contact forces.

Surface Cleanliness

Mounting surface cleanliness is also important in minimizing contact thermal resistance. Mounting surfaces should be kept free of all foreign material, such as dirt, oil, oxides, and films. Since most heat sinks and cold plates are stored after machining, a cleaning operation is recommended prior to mounting the device. A satisfactory cleaning technique is to lightly polish the mounting surface with 3M Scotch Brite® No.000 fine steel wool, followed by a semiconductor cleaning solvent wipe.

Thermal Interface Material

Finally, in order to further improve Rcs, an appropriate Thermal Interface Material (TIM) should be used to fill air gaps between the two surfaces. There are a number of technologies that can be used, including thermal greases and thermally conductive compounds, elastomers, adhesive tapes, etc., each with their own characteristics (operating temperatures, ease of application, curing time, pressure requirements, etc.) that can make them more or less desirable depending on the application. Contact Boyd to consult on how to select the appropriate TIM for your application. Table 2 shows typical thermal resistance and thermal conductivity values for these TIMs.

Interface	Thickness (in.)	Thermal Conductivity, k(W/m-K)	Rcs(°C/W)
Dry Joint	N/A	N/A	2.9
Thermal Grease	0.003	0.7	0.9
Thermal Compound	0.005	1.2	0.8
Elastomer	0.010	5.0	1.8
Adhesive Tape	0.009	0.7	2.7

Contact Thermal Resistance Factors Review

Contact conditions encompass a number of areas including surface flatness, surface roughness, surface cleanliness, contact pressure, and interface materials. There are many technologies and techniques available for optimizing the thermal path from the electronic device junction to the heat sink. It’s important to minimize the thermal resistance in order to maintain the electronic device temperature below its maximum rated value and increase the end product reliability.

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How Thermal Interface Material Works

Boyd Blog — Thu, 16 Jan 2020 13:53:00 +0000

What is Thermal Interface Material?

Many engineers focus more on heat sink design but often forget to spend time considering how heat gets from the heat source to the heat sink. Even the smoothest surface has some level of surface roughness. The roughness of two surfaces in contact with each other creates air pockets. Since air is a good thermal insulator, air pockets from mating surface roughness impedes heat transfer from one surface to another.

In the image below, heat coming from the black surface can only conduct through to the grey heat sink at the points highlighted in red. Orange arrows help visualize that heat is coming from the entire black surface but is restricted through these contact points. Air pockets are represented in light blue. Heat can transfer through the blue air pockets, albeit highly inefficient and very little compared to the level of conduction through the red contact points.

This is applicable for any electrical device, commonly enclosed in a case, that transfers heat to a metal heat sink without a thermal interface material.

What does Thermal Interface Material do?

This is where using thermal interface material comes in. TIM replaces most of these air pockets with a material optimized for better thermal conductivity. By using thermal interface material, we increase how much heat is transferred away from the heat source and into the heat sink.

In the diagram below, dark blue represents thermal interface material. Most of the light blue air pockets have been eliminated and replaced with a more conductive material. Heat is now efficiently conducting across the entire surface. This improves heat transfer away from the heat source significantly. It’s nearly impossible to remove 100% of air in most cases so there are still small air pockets in little nooks and crannies. But the thermal performance in this instance is greatly improved to the scenario with no TIM present.

Thermal interface material comes in many different formats and options: electrically isolating or electrically conductive, silicone base or silicone free, compliant or hard, solid or liquid or both, etc. TIM selection is a very application specific decision.

Learn More about Thermal Interface Materials

Learn more about the different types of Thermal Interface Materials, typical options available for each, and common uses for them. Or estimate the impact of adding different thermal interface materials in Boyd Genie in your air cooled heat sink application.

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