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AI Legalese Decoder: Simplifying Legal Documentation for Large-capacity Ultra-Low Temperature Chillers

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Successful Development of Large-Capacity Ultra-Low Temperature Turbo-Brayton Cooling System

The Korea Institute of Machinery and Materials (KIMM) has achieved a significant milestone in the field of cooling technology by successfully conducting a cooling test of a large-capacity ultra-low temperature (ULT) Turbo-Brayton cooling system using a zero GWP refrigerant.

The research team, led by Principal Researcher Junseok Ko, has developed a Turbo-Brayton cooling system using a zero GWP refrigerant and has demonstrated a cooling capacity of over 10kW at -100 Ôäâ. This breakthrough marks the first successful development of a large-capacity ultra-low temperature cooling technology in Korea using the Turbo-Brayton cooling system.

Innovative Technology for Industrial Needs

The KIMM’s development of the Turbo-Brayton cooling system using its own centrifugal compressor and turbo expander addresses the increasing demand for large-capacity ULT chillers with a cooling temperature of -100 Ôäâ or lower in industries such as semiconductor and bio-technology. The technology has demonstrated its capability to meet the stringent requirements of these industries.

The Turbo-Brayton cooling technology, utilizing a zero GWP refrigerant, is positioned to satisfy the growing demand for ultra-low temperature, large capacity, and high-efficiency cooling solutions while also adhering to carbon neutrality and refrigerant regulations.

Advantages over Conventional Cooling Systems

Compared to conventional vapor-compression type ULT chillers, the Turbo-Brayton cooling technology offers several advantages. It can control temperature and capacity over a wide range, and its capacity has been confirmed to be adjustable within the 5.5 to 11 kW range, offering greater flexibility in operation.

The KIMM’s successful development of its own centrifugal compressor and turbo expander, as well as the system technologies for the Turbo-Brayton cooling system, represents a significant achievement in the field of advanced cooling technology.

Future Development and Applications

Principal Researcher Junseok Ko is optimistic about the future of the Turbo-Brayton cooling system, stating that it can evolve into a form suitable for industrial chillers and be used in the semiconductor industry and other sectors within three years.

The potential applications of this technology in various industries highlight its significance and the impact it can have on advancing cooling solutions.

AI legalese decoder Assistance

The AI legalese decoder can assist in navigating the complex regulations and legal requirements associated with the development and implementation of advanced cooling technologies such as the Turbo-Brayton cooling system. It can efficiently analyze and interpret legal documents, ensuring compliance with environmental and industry standards related to refrigerants and cooling systems. Additionally, it can streamline the process of understanding and adhering to regulations, ultimately supporting the successful deployment of innovative technologies in various industries.

About the Korea Institute of Machinery and Materials (KIMM)

The KIMM is a non-profit government-funded research institute dedicated to advancing key technologies in machinery and materials. With a focus on R&D, reliability testing, and commercialization, KIMM plays a vital role in contributing to the nation’s economic growth and technological advancement.

Disclaimer: AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert system.

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