PHOTONIS Technologies SAS Fission Chambers For In-Core Use, Pulse Mode Operation CFUR44

Description
Photonis fission chambers for in-core use can be made to operate at temperatures up to 600°C depending on the reactor types and the detection requirements. In-core measurements of neutron flux ranges Tight stainless steel structure Customization according to the user’s needs Description They are critical components for reactor neutron flux monitoring, and can be used to detect thermal neutrons in high flux, to monitor the reactor fuel burn-up, to control start-up, intermediate and power ranges. Gas filled neutron detectors are designed to operate in three modes. Pulse mode analyzes and counts individual detector pulses. Fluctuation, or Campbell mode, is used to analyze the fluctuation of the direct current from the detector. Current mode is used to measure the mean of the direct current from the detector. Fission chambers are filled with the appropriate gas for both high-temperature or fast response and are extremely radiation resistant. Depending on the type of fission chamber required, a BNC or HN connector can be mounted on the integrated mineral insulated cable designed specifically for the detector. Fission chambers for in-core use are designed to be movable inside the reactor core during operation. In research environments, our 1.5 mm external diameter subminiature chambers allow measurements close to the physical phenomenon.

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Fission Chambers For In-Core Use, Pulse Mode Operation - CFUR44 - PHOTONIS Technologies SAS
Merignac, France
Fission Chambers For In-Core Use, Pulse Mode Operation
CFUR44
Fission Chambers For In-Core Use, Pulse Mode Operation CFUR44
Photonis fission chambers for in-core use can be made to operate at temperatures up to 600°C depending on the reactor types and the detection requirements. In-core measurements of neutron flux ranges Tight stainless steel structure Customization according to the user’s needs Description They are critical components for reactor neutron flux monitoring, and can be used to detect thermal neutrons in high flux, to monitor the reactor fuel burn-up, to control start-up, intermediate and power ranges. Gas filled neutron detectors are designed to operate in three modes. Pulse mode analyzes and counts individual detector pulses. Fluctuation, or Campbell mode, is used to analyze the fluctuation of the direct current from the detector. Current mode is used to measure the mean of the direct current from the detector. Fission chambers are filled with the appropriate gas for both high-temperature or fast response and are extremely radiation resistant. Depending on the type of fission chamber required, a BNC or HN connector can be mounted on the integrated mineral insulated cable designed specifically for the detector. Fission chambers for in-core use are designed to be movable inside the reactor core during operation. In research environments, our 1.5 mm external diameter subminiature chambers allow measurements close to the physical phenomenon.

Photonis fission chambers for in-core use can be made to operate at temperatures up to 600°C depending on the reactor types and the detection requirements.

  • In-core measurements of neutron flux ranges
  • Tight stainless steel structure
  • Customization according to the user’s needs

Description

They are critical components for reactor neutron flux monitoring, and can be used to detect thermal neutrons in high flux, to monitor the reactor fuel burn-up, to control start-up, intermediate and power ranges.

Gas filled neutron detectors are designed to operate in three modes. Pulse mode analyzes and counts individual detector pulses. Fluctuation, or Campbell mode, is used to analyze the fluctuation of the direct current from the detector. Current mode is used to measure the mean of the direct current from the detector.

Fission chambers are filled with the appropriate gas for both high-temperature or fast response and are extremely radiation resistant. Depending on the type of fission chamber required, a BNC or HN connector can be mounted on the integrated mineral insulated cable designed specifically for the detector. Fission chambers for in-core use are designed to be movable inside the reactor core during operation. In research environments, our 1.5 mm external diameter subminiature chambers allow measurements close to the physical phenomenon.

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Technical Specifications

  PHOTONIS Technologies SAS
Product Category Radiation Detectors
Product Number CFUR44
Product Name Fission Chambers For In-Core Use, Pulse Mode Operation
Detector Style Fixed Installation
Types of Radiation Detectors Ionization Chamber
Types of Ionizing Radiation Detected Gamma Ray; Neutron
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