Innovative welding technology reduces cost on liquid cooled Cold Plates – FSW

Posted on March 19, 2013 by

ARLINGTON HEIGHTS, ILLINOIS, USA, Tuesday, March 19, 2013: Hill Tech Sales, a leader in Components for Thermal Management and Electrical Power Conversion today posted information on friction stir welding in a cold plate construction.

Recently the only way to make certain configurations of high thermally efficient aluminum cold plates was by brazing. This is where a base, fins/tubulators and cover plate are brazed together to form one complete assembly.

Most designers would choose to avoid brazing if possible because of the inherent cost and issues that arise.

  • Annealing
  • Wasted material
  • Increased machining costs
  • Internal debris
  • Additional QA and testing

Annealing – When brazing is done the material is converted from its original temper, the annealing process re-creates the original hardness.

Wasted material comes about from more material being used to compensate for the distortion (warping/twisting) that occurs in brazing and post brazing annealing process. This allows the part to be machined to the original tolerances, with details and flatness required.

Increased machining costs occur because of the ability to consistently heat-treat a part. It is very difficult to accurately anneal a brazed part to a consistent hardness; the larger the part, the more difficult it becomes. This results in the machining being done at a much lower speed (increasing machine time). Why does this happen? When you run a part with inconsistent hardness through the machining center, if it is cutting through some material with a given hardness at a certain speed, and then all of a sudden hits a soft section, it will move through that material in a much more rapid and unpredictable manner, making it difficult to control machining accuracies and flatness.

Internal debris means that scrapping finished parts becomes inevitable. Debris develops and is sealed inside the part. When there is some highly detailed feature, i.e., fine fin pitches, stray material can become lodged between the fins reducing liquid flow and decreasing thermal performance in an unpredictable manner.  In some cases the additional debris only becomes loose over time and the restriction becomes apparent at that future time. To avoid this, additional quality assurance tests and cleaning processes can be implemented. This again is just adding cost.

Are there other alternatives? One method is called FSW – friction stir welding. The process (welding) is done by a specially ground tool in the milling machines that create a soft “plastic” state by using the spindle speed and feed rates to control the process.

friction stir welding head through material

Showing down ward pressure and rotation in friction stir welding through material

The key attribute of using FSW for heat sinks is that you are not changing the anneal of the material, so there is no need for additional annealing and eliminate the other problems that result from this process: Wasted material, Increased machining costs, Internal debris, and Additional QA testing.

In the traditional sense FSW is actually a whole lot closer to machining than welding. Once you have the proper tool, speeds & feeds, where the process control is locked down, it is a very, very, stable operation.

4 basic steps when FSW

Base material to be joined and joining tool

 

When considering companies to do FSW heat sinks for you, look for:

  1. Experience with this process – Look for a company that has done at least several hundred meters.
  2. Professional training – Has the personnel attended classes at the TWI training center in Cambridge, England? Do they have technical support from TWI for special projects like solid copper welding, welding solid aluminum and aluminum castings, or even dissimilar materials?
  3. Machining knowhow – One of the important aspects from a machining stand point is holding on to the parts during the FSW operation. The company should have experience machining aluminum for decades from very low speeds & feeds, up to speeds of 60,000 RPM, i.e. feed rates of over 350 inch/min.

Below additional history and detail about this process.

WA Technology

 

For more questions on this article contact:

Andrew Hill

Hill Technical Sales

216 West Campus Drive

Arlington Heights, IL 60004

Tel: +1- 847-255-4400 ext 12 Fax: +1-847-255-0192

You may also visit: http://www.hilltech.com/

 

 

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Hill Tech – HVR – Solar Power 2012

Posted on September 8, 2012 by

Hill Technical Sales will be assisting HVR this year at the solar show.

Come see us for expert assistance in the implementation of high energy resisters in your Power Electronics designs.

We will be posting photos and comments on this site during the show.

You may also contact Hill Tech at 847-255-4400 or visit www.hilltech.com

For more questions on this article contact:

Andrew Hill
Hill Technical Sales
216 West Campus Drive
Arlington Heights, IL 60004
Tel: +1- 847-255-4400 ext 12
Fax: +1-847-255-0192

You may also visit: http://www.hilltech.com/

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Hill Tech – Siba Fuse – Solar Power International 2012 – Booth # 2071

Posted on September 8, 2012 by

ARLINGTON HEIGHTS, ILLINOIS, USA, Saturday, September 08, 2012: Hill Tech Sales, a leader in Components for Electrical Power Conversion and Thermal Management today posted information on PV fuses for photovoltaic inverters, combiners and sub-combiners.

Hill Tech will be supporting Siba Fuse at the Solar Power International 2012 in Orlando, Florida this year, beginning Tuesday, September 10th to Thursday September 13th. This show will be held at the Orange County Convention Center – Orlando, Florida.

Siba will be showing its complete line of PV fuses:

  • Class: gPV
  • Voltage ratings: 600 to 1500VDC
  • Current ratings: 1 A to 450 A
  • Standards: UL 2579 and IEC 60 269-6
  • Approvals: E341342 and E341490 (UL)

These have high interrupt ratings up to 30kA, low I2T values, and a full range of fuse accessories from micro switches to fuse bases.

Our fuses are specifically designed for PV inverter protection, PV panel, and junction box protection. Please contact for more details as our LATEST PV Section was just released. It will appear in the new Siba 2013 catalog. Contact us at the below link for a copy of this new brochure.

If you are in the great lake region contact us to schedule a design review or product training at the booth during the show.

You may also contact Hill Tech at 847-255-4400 or visit www.hilltech.com

For more questions on this article contact:

Andrew Hill
Hill Technical Sales
216 West Campus Drive
Arlington Heights, IL 60004
Tel: +1- 847-255-4400 ext 12
Fax: +1-847-255-0192

You may also visit: http://www.hilltech.com/

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Cold-plate using internal extruded liquid channel paths

Posted on September 8, 2012 by

ARLINGTON HEIGHTS, ILLINOIS, USA, Friday, September 7, 2012: Hill Tech Sales, a leader in Components for Thermal Management and Electrical Power Conversion today posted information on cold-plate using internal extruded liquid channel paths.

Extruded liquid channel base, gasket and manifold

This is a construction example showing the extruded liquid channel base, with gasket interface and manifold connections

 

Typical flow path in cold plate, aluminum heat sink, manifolds show on edge of chiller plate

Choose among these four standard extruded liquid channel aluminum heat sink bases, in order to create your own custom configuration. Liquid cooled cold-plate can be up to 60 inches long.

This is a highly advanced, dependable liquid cooling technology utilizing internal liquid channels extruded into the cold-plate. No longer is expensive drilling and fabricated processes required. This extrusion technology overcomes past size limitations and comes in four standard sizes; lengths up to 60 inches!

Standard extruded channel alumium heat sink bases, cold-plate.

Standard extruded channel aluminum heat sink bases, liquid cooled cold-plate.

These can be configured in a number of parallel and series flow options provide an optimal thermal solution. The liquid channels locations were determined in order to accommodate almost all power semiconductors.  In addition, we can enhance thermal performance by using specifically designed turbulators which increase the flow rate in the fluid channel with only a minute increase in back pressure. Custom designed can a provided for specific thermal challenges.

We also provide other advanced thermal dissipation solutions:

  • VBA – Vacuum brazed cold-plate assemblies
  • Friction Stir Welding for air-cooled and liquid cooled cold plates
  • Copper cold plates
  • Heat pipes for High power industrial use: 30kW + heat pipe assemblies
  • Heat exchangers
  • Air-cooled bonded fin
  • Air-cooled pressed fin

 For more questions on this article contact:

Andrew Hill
Hill Technical Sales
216 West Campus Drive
Arlington Heights, IL 60004   
Tel: +1- 847-255-4400  ext 12
Fax: +1-847-255-0192    

You may also visit: http://www.hilltech.com/

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Large-scale industrial heat pipes for power electronic applications

Posted on August 31, 2012 by
Heat-pipe spreading in bonded fin heat sink

Heat moved evenly from devices to fins on outter edge of heat sink

ARLINGTON HEIGHTS, ILLINOIS, USA, Friday, August 31, 2012: Hill Tech Sales, a leader in Components for Thermal Management and Electrical Power Conversion today posted information on standard heat pipes to increase working size in a cold plate.

In the past engineers would not consider heat pipes for high power, power electronic applications for many reasons:

  • Low maximum heat energy transfer capacity – only 70 watts – 8mm tube OD.
  • Low temperature operation, (below the freezing point of water.
  • Limited working distance of 30 cm.

 

Heat Pipe spreading in a bonded fin heat sink

 With new heat pipe advancements tube OD’s of greater than 16mm can be built, allowing for heat energy transfer in the kilowatts, assemblies with capacity of 32kW or more can be made.

Other innovations include:

  • Antigravity Heat pipes with temperature ratings of +5 to +275 C
  • LTSC – low temperature Heat pipes with temperature ratings ·40 to +30″C
  • Diode type for heat transfer primarily in one direction
  • Variable conductive Heat pipes for self regulation and automatic temperature control
  • Flat profile for heat spreaders
  • Loop Heat pipes

Heat pipes in a heat exchanger assembly provide heat transfers with no pumps are moving mechanical parts adding to system reliability.

 Enhancing thermal spreading in high energy density regions can be addressed by using the flat profile heat pipes and fabricating them, stacked side by side in an assembled plate. Since the heat pipes themselves are rather inexpensive, it is good design practice to add additional pipes to improve your design margin.

 Note another inherent advantage in this concept is that this assembly now has improved built-in reliability through redundancy of heat transfer devices in the unlikely event of a single heat pipe failing.

For more questions on this article contact:

Andrew Hill
Hill Technical Sales
216 West Campus Drive
Arlington Heights, IL 60004   
Tel: +1- 847-255-4400  ext 12
Fax: +1-847-255-0192    

You may also visit: http://www.hilltech.com/

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