Engineering technology to design and construct a cooling system
using a cryocooler to create the cryogenic environment (below
-150℃) required by the cooling target

Cooling system divided into the cryogenic fluid cooling system using
cryogenic fluid (liquid nitrogen, liquid helium, etc.) and the cryogenic
conduction cooling system using a solid structure with good thermal
conductivity.

 

Client / Market

• Superconducting applications (superconducting power device, superconducting
  magnet, NMR, MRI, etc.), gas liquefaction/re-liquefaction

 

Necessity of this Technology

• Various cooling system combination depending on the requirements of the cooling
  target (temperature, pressure, cooling load, etc.)
• Cooling system design to minimize the cooling load of a cryocooler while satisfying
  the requirements of the cooling target.
• Suitable design margin for basic design of the cooling system and its components.

 

Technical Differentiation

• Cooling system design based on design and test experience of various cryogenic
  cooling systems (superconducting power cable, superconducting fault current
  limiter, SMES, NMR, etc.)
  - Cryogenic cooling system configuration to meet the requirements of the cooling
  target
  - Determination of design margin for the system and its components
  - Calculation of cooling load and selection of a cryocooler according to the system
  design
  - System basic design (system/component specification)
  - Detailed design of a system cooling structure (conduction cooling system)
  

 

Excellence of Technology

• Track record of cryogenic fluid cooling system design and test
  - Superconducting power cable cooling system (single-phase 154 kV, 1000 MVA, 100 m)
  Liquid nitrogen circulation cooling (70 K, 5 bar), Stirling cryocooler: 2kW @ 77 K
  - Superconducting fault current limiter cooling system (single phase 154 kV, 2 kA) Liquid
  nitrogen circulation cooling (71 K, 5 bar), Stirling cryocooler: 4 kW @ 77 K
• Track record of cryogenic conduction cooling system design and test
  - SMES (Superconducting Magnetic Energy Storage)
  Energy storage : 600 kJ, operating temperature: 20 K, 2 stage GM cryocooler
  - NMR (Nuclear Magnetic Resonance)
  Superconducting magnet : 9.4 T, operating temperature: 20 K, 2 stage pulse tube cryocooler
  

 

CURRENT INTELLECTUAL PROPERTY RIGHT STATUS

PATENT

• Pressurizing System for Cryogenic Pressure Vessel (KR1558840)
• System and Method for Superconducting Fault Current Limiter Recovery (KR1558839)
• Pressurization System using Floating Heater for Cryogenic Pressure Vessel (KR1569650)
• System and Method for Superconducting Fault Current Limiter Recovery (KR1601593)
• Recovery System for Superconducting Fault Current Limiter (KR1691983)
• Recovery System for Superconducting Fault Current Limiter (KR1691989)
• Recovery System for Superconducting Fault Current Limiter (KR1720752)

KNOW-HOW

• Cryogenic cooling system design technology