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Silicon carbide semiconductor switches enhance energy efficiency

Technology News |
By eeNews Europe

The KIT researchers will undertake the study in cooperation with their industrial partners TRUMPF Hüttinger and IXYS Semiconductor.

From the production of semiconductor to coating of displays to  processes in automobile manufacturing: Many industrial processes consume large amounts of electrical energy. Among them are also processes playing an important role for the transformation of the German energy system, such as floating zone melting processes to produce highly pure crystalline materials like silicon. By this process, the basic material is molten electrically within a small zone. By moving the melting zone, the material crystallizes purer than before. Amongst others, this is used for the production of highly pure monocrystalline silicon for solar cells.

So far, power supplies of floating zone systems are tube-based amplifiers with a maximum electrical efficiency of 65%. If they were replaced by power semiconductors made of silicon carbide, efficiency of power supplies  would be increased to more than 80%. So power consumption and greenhouse gas emissions would be reduced. For example, a single large-scale floating zone reactor, consisting of twenty 50 kW process power supplies with an annual operating time of 4800 hours, would lead to a reduction of electrical energy by more than 200,000 kWh and produce 109 tons of CO2 less (Federal Environmental Agency Germany, July 2013).

Feasibility of such power supplies is studied by researchers of the Light Technology Institute (LTI) of KIT in cooperation with the industry partners TRUMPF Hüttinger GmbH + Co. KG (Freiburg) and IXYS Semiconductor GmbH (Lampertheim) under the ‘Modular Medium-frequency Process Power Supply with Silicon Carbide Power Semiconductor Switches’ (MMPSiC) cooperation project. Silicon carbide has several advantages owing to the material’s wider electronic band gap which enables higher operating temperatures to be reached compared with conventional semiconductors. Power electronics based on silicon carbide is characterized by an enhanced energy efficiency and compactness.

“Power supply of energy-intensive industrial applications, such as a floating zone process, requires switching at high frequencies,” explained project manager Dr. Rainer Kling, LTI. “Silicon carbide has not yet been tested at these high frequencies. Here, we are entering  new territory.” Apart from long-term stability tests, the KIT researchers in the MMPSiC project are also studying the control and layout of the circuitry.

The MMPSiC project is funded by the Federal Ministry of Education and Research (BMBF) with about EUR 800,000 under the programs “Information and Communication Technology 2020” (IKT 2020) and “Power Electronics for Increasing Energy Efficiency” (LES 2). The LTI of KIT receives a substantial amount of about EUR 439,000. The total project volume amounts to EUR 1.3 million. The cooperation project started in 2014 and has a duration of three years.

Related articles and links:

www.kit.edu

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