Establishment and Study of Pulsed X-ray Reference Radiation Field

Research on radiation protection dosimetry mainly focuses on continuous radiation in the world, but pulsed ionizing radiation has been widely used in the fields of industrial detection, X-ray diagnosis, security inspection and scientific research. The active electronic dosimeter has been widely used in the fields of environmental monitoring, regional monitoring, personal dose monitoring and emergency monitoring. The active electronic dosimeters are calibrated in continuous radiation field, and they cannot measure short pulse and high dose rate pulsed ionizing radiation accurately. The active radiation dosimeter can be divided into G-M counter type, scintillator detector type, semiconductor detector type and ionization chamber type according to different radiation detection principles. The measurement of pulsed X-ray dose is very difficult due to its short duration and high instantaneous dose rate. Taking nanosecond radiation pulse as an example, its single pulse dose usually reaches more than 1 μSv, and the instantaneous dose rate can reach more than 105 Sv/h. For G-M counter and semiconductor detector, there are problems of measurement stacking and detection dead time, so it is difficult to achieve such a high dose-rate response, and there is an over-response problem in the instrument, which will inevitably affect the accuracy of monitoring results. The measurement of pulsed radiation dose (rate) is difficult. However, pulsed ionizing radiation has been widely used in many fields, such as the development of new detector, industrial flaw detection, X-ray diagnosis, nuclear emergency response and scientific research, etc. In this paper, the reference ionizing radiation field of pulsed X-ray was established based on steady-state X-ray machine, pulsed X-ray machine and portable X-ray machine. In order to measure the dose of pulsed reference field, the theoretical calculation, Monte Carlo simulation and experiment method were used to develop a secondary standard ionization chamber for millisecond pulsed X-rays. From the experimental data, it can be seen that the mainstream active dosimeters currently sold have low pulse dose response and even give false readings, which are not suitable for short pulse and high dose rate measurement and early warning, will cause safety trouble to personal. The dosimetric characteristics, such as pulse time, pulse dose and instantaneous dose rate were studied based on pulsed X-ray secondary standard ionization chamber and pulsed time measurement system. The lower limit and upper limit of instantaneous dose rate of the established pulsed X-ray reference radiation field are 2.5×10-3 Sv/h and 6.7×105 Sv/h respectively. Pulse time is adjustable between 50 ns and 10 s. The dose rate range of pulsed X-ray reference radiation field established in this study covers environmental level, radiation protection level, diagnosis level, treatment level, emergency level and nuclear critical accident level, which can be used to calibrate the pulsed radiation dose monitoring instrument. It is helpful to further study the pulsed radiation response characteristics of active radiation dosimeter and personal radiation dosimeter. Ausführliche Beschreibung

Gespeichert in:

Autor*in:	GAO Fei;WANG Feifei;LIU Yuntao;DING Yuyang;CHEN Yizhen;NI Ning;WANG Ziling;LIU Jiarui;WANG Ziye;ZHAO Xu [verfasserIn]

Format:	E-Artikel
Sprache:	Englisch ; Chinesisch

Erschienen:	2023

Schlagwörter:	pulsed x-ray pulse time measurement system nuclear criticality nuclear criticality accident gamma radiation detection and alarm system pulsed radiation field

Übergeordnetes Werk:	In: Yuanzineng kexue jishu - Editorial Board of Atomic Energy Science and Technology, 2022, 57(2023), 2, Seite 389-397
Übergeordnetes Werk:	volume:57 ; year:2023 ; number:2 ; pages:389-397

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Katalog-ID:	DOAJ088541126

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520			\|a Research on radiation protection dosimetry mainly focuses on continuous radiation in the world, but pulsed ionizing radiation has been widely used in the fields of industrial detection, X-ray diagnosis, security inspection and scientific research. The active electronic dosimeter has been widely used in the fields of environmental monitoring, regional monitoring, personal dose monitoring and emergency monitoring. The active electronic dosimeters are calibrated in continuous radiation field, and they cannot measure short pulse and high dose rate pulsed ionizing radiation accurately. The active radiation dosimeter can be divided into G-M counter type, scintillator detector type, semiconductor detector type and ionization chamber type according to different radiation detection principles. The measurement of pulsed X-ray dose is very difficult due to its short duration and high instantaneous dose rate. Taking nanosecond radiation pulse as an example, its single pulse dose usually reaches more than 1 μSv, and the instantaneous dose rate can reach more than 105 Sv/h. For G-M counter and semiconductor detector, there are problems of measurement stacking and detection dead time, so it is difficult to achieve such a high dose-rate response, and there is an over-response problem in the instrument, which will inevitably affect the accuracy of monitoring results. The measurement of pulsed radiation dose (rate) is difficult. However, pulsed ionizing radiation has been widely used in many fields, such as the development of new detector, industrial flaw detection, X-ray diagnosis, nuclear emergency response and scientific research, etc. In this paper, the reference ionizing radiation field of pulsed X-ray was established based on steady-state X-ray machine, pulsed X-ray machine and portable X-ray machine. In order to measure the dose of pulsed reference field, the theoretical calculation, Monte Carlo simulation and experiment method were used to develop a secondary standard ionization chamber for millisecond pulsed X-rays. From the experimental data, it can be seen that the mainstream active dosimeters currently sold have low pulse dose response and even give false readings, which are not suitable for short pulse and high dose rate measurement and early warning, will cause safety trouble to personal. The dosimetric characteristics, such as pulse time, pulse dose and instantaneous dose rate were studied based on pulsed X-ray secondary standard ionization chamber and pulsed time measurement system. The lower limit and upper limit of instantaneous dose rate of the established pulsed X-ray reference radiation field are 2.5×10-3 Sv/h and 6.7×105 Sv/h respectively. Pulse time is adjustable between 50 ns and 10 s. The dose rate range of pulsed X-ray reference radiation field established in this study covers environmental level, radiation protection level, diagnosis level, treatment level, emergency level and nuclear critical accident level, which can be used to calibrate the pulsed radiation dose monitoring instrument. It is helpful to further study the pulsed radiation response characteristics of active radiation dosimeter and personal radiation dosimeter.
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653		0	\|a Nuclear and particle physics. Atomic energy. Radioactivity
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allfields	(DE-627)DOAJ088541126 (DE-599)DOAJ801c9c14da734efb9fd40684dc7ec1db DE-627 ger DE-627 rakwb eng chi TK9001-9401 QC770-798 GAO Fei;WANG Feifei;LIU Yuntao;DING Yuyang;CHEN Yizhen;NI Ning;WANG Ziling;LIU Jiarui;WANG Ziye;ZHAO Xu verfasserin aut Establishment and Study of Pulsed X-ray Reference Radiation Field 2023 Text txt rdacontent Computermedien c rdamedia Online-Ressource cr rdacarrier Research on radiation protection dosimetry mainly focuses on continuous radiation in the world, but pulsed ionizing radiation has been widely used in the fields of industrial detection, X-ray diagnosis, security inspection and scientific research. The active electronic dosimeter has been widely used in the fields of environmental monitoring, regional monitoring, personal dose monitoring and emergency monitoring. The active electronic dosimeters are calibrated in continuous radiation field, and they cannot measure short pulse and high dose rate pulsed ionizing radiation accurately. The active radiation dosimeter can be divided into G-M counter type, scintillator detector type, semiconductor detector type and ionization chamber type according to different radiation detection principles. The measurement of pulsed X-ray dose is very difficult due to its short duration and high instantaneous dose rate. Taking nanosecond radiation pulse as an example, its single pulse dose usually reaches more than 1 μSv, and the instantaneous dose rate can reach more than 105 Sv/h. For G-M counter and semiconductor detector, there are problems of measurement stacking and detection dead time, so it is difficult to achieve such a high dose-rate response, and there is an over-response problem in the instrument, which will inevitably affect the accuracy of monitoring results. The measurement of pulsed radiation dose (rate) is difficult. However, pulsed ionizing radiation has been widely used in many fields, such as the development of new detector, industrial flaw detection, X-ray diagnosis, nuclear emergency response and scientific research, etc. In this paper, the reference ionizing radiation field of pulsed X-ray was established based on steady-state X-ray machine, pulsed X-ray machine and portable X-ray machine. In order to measure the dose of pulsed reference field, the theoretical calculation, Monte Carlo simulation and experiment method were used to develop a secondary standard ionization chamber for millisecond pulsed X-rays. From the experimental data, it can be seen that the mainstream active dosimeters currently sold have low pulse dose response and even give false readings, which are not suitable for short pulse and high dose rate measurement and early warning, will cause safety trouble to personal. The dosimetric characteristics, such as pulse time, pulse dose and instantaneous dose rate were studied based on pulsed X-ray secondary standard ionization chamber and pulsed time measurement system. The lower limit and upper limit of instantaneous dose rate of the established pulsed X-ray reference radiation field are 2.5×10-3 Sv/h and 6.7×105 Sv/h respectively. Pulse time is adjustable between 50 ns and 10 s. The dose rate range of pulsed X-ray reference radiation field established in this study covers environmental level, radiation protection level, diagnosis level, treatment level, emergency level and nuclear critical accident level, which can be used to calibrate the pulsed radiation dose monitoring instrument. It is helpful to further study the pulsed radiation response characteristics of active radiation dosimeter and personal radiation dosimeter. pulsed x-ray pulse time measurement system nuclear criticality nuclear criticality accident gamma radiation detection and alarm system pulsed radiation field Nuclear engineering. Atomic power Nuclear and particle physics. Atomic energy. Radioactivity In Yuanzineng kexue jishu Editorial Board of Atomic Energy Science and Technology, 2022 57(2023), 2, Seite 389-397 (DE-627)578537303 (DE-600)2451932-7 10006931 nnns volume:57 year:2023 number:2 pages:389-397 https://doaj.org/article/801c9c14da734efb9fd40684dc7ec1db kostenfrei https://www.aest.org.cn/CN/10.7538/yzk.2022.youxian.0176 kostenfrei https://doaj.org/toc/1000-6931 Journal toc kostenfrei GBV_USEFLAG_A SYSFLAG_A GBV_DOAJ GBV_ILN_2055 AR 57 2023 2 389-397
spelling	(DE-627)DOAJ088541126 (DE-599)DOAJ801c9c14da734efb9fd40684dc7ec1db DE-627 ger DE-627 rakwb eng chi TK9001-9401 QC770-798 GAO Fei;WANG Feifei;LIU Yuntao;DING Yuyang;CHEN Yizhen;NI Ning;WANG Ziling;LIU Jiarui;WANG Ziye;ZHAO Xu verfasserin aut Establishment and Study of Pulsed X-ray Reference Radiation Field 2023 Text txt rdacontent Computermedien c rdamedia Online-Ressource cr rdacarrier Research on radiation protection dosimetry mainly focuses on continuous radiation in the world, but pulsed ionizing radiation has been widely used in the fields of industrial detection, X-ray diagnosis, security inspection and scientific research. The active electronic dosimeter has been widely used in the fields of environmental monitoring, regional monitoring, personal dose monitoring and emergency monitoring. The active electronic dosimeters are calibrated in continuous radiation field, and they cannot measure short pulse and high dose rate pulsed ionizing radiation accurately. The active radiation dosimeter can be divided into G-M counter type, scintillator detector type, semiconductor detector type and ionization chamber type according to different radiation detection principles. The measurement of pulsed X-ray dose is very difficult due to its short duration and high instantaneous dose rate. Taking nanosecond radiation pulse as an example, its single pulse dose usually reaches more than 1 μSv, and the instantaneous dose rate can reach more than 105 Sv/h. For G-M counter and semiconductor detector, there are problems of measurement stacking and detection dead time, so it is difficult to achieve such a high dose-rate response, and there is an over-response problem in the instrument, which will inevitably affect the accuracy of monitoring results. The measurement of pulsed radiation dose (rate) is difficult. However, pulsed ionizing radiation has been widely used in many fields, such as the development of new detector, industrial flaw detection, X-ray diagnosis, nuclear emergency response and scientific research, etc. In this paper, the reference ionizing radiation field of pulsed X-ray was established based on steady-state X-ray machine, pulsed X-ray machine and portable X-ray machine. In order to measure the dose of pulsed reference field, the theoretical calculation, Monte Carlo simulation and experiment method were used to develop a secondary standard ionization chamber for millisecond pulsed X-rays. From the experimental data, it can be seen that the mainstream active dosimeters currently sold have low pulse dose response and even give false readings, which are not suitable for short pulse and high dose rate measurement and early warning, will cause safety trouble to personal. The dosimetric characteristics, such as pulse time, pulse dose and instantaneous dose rate were studied based on pulsed X-ray secondary standard ionization chamber and pulsed time measurement system. The lower limit and upper limit of instantaneous dose rate of the established pulsed X-ray reference radiation field are 2.5×10-3 Sv/h and 6.7×105 Sv/h respectively. Pulse time is adjustable between 50 ns and 10 s. The dose rate range of pulsed X-ray reference radiation field established in this study covers environmental level, radiation protection level, diagnosis level, treatment level, emergency level and nuclear critical accident level, which can be used to calibrate the pulsed radiation dose monitoring instrument. It is helpful to further study the pulsed radiation response characteristics of active radiation dosimeter and personal radiation dosimeter. pulsed x-ray pulse time measurement system nuclear criticality nuclear criticality accident gamma radiation detection and alarm system pulsed radiation field Nuclear engineering. Atomic power Nuclear and particle physics. Atomic energy. Radioactivity In Yuanzineng kexue jishu Editorial Board of Atomic Energy Science and Technology, 2022 57(2023), 2, Seite 389-397 (DE-627)578537303 (DE-600)2451932-7 10006931 nnns volume:57 year:2023 number:2 pages:389-397 https://doaj.org/article/801c9c14da734efb9fd40684dc7ec1db kostenfrei https://www.aest.org.cn/CN/10.7538/yzk.2022.youxian.0176 kostenfrei https://doaj.org/toc/1000-6931 Journal toc kostenfrei GBV_USEFLAG_A SYSFLAG_A GBV_DOAJ GBV_ILN_2055 AR 57 2023 2 389-397
allfields_unstemmed	(DE-627)DOAJ088541126 (DE-599)DOAJ801c9c14da734efb9fd40684dc7ec1db DE-627 ger DE-627 rakwb eng chi TK9001-9401 QC770-798 GAO Fei;WANG Feifei;LIU Yuntao;DING Yuyang;CHEN Yizhen;NI Ning;WANG Ziling;LIU Jiarui;WANG Ziye;ZHAO Xu verfasserin aut Establishment and Study of Pulsed X-ray Reference Radiation Field 2023 Text txt rdacontent Computermedien c rdamedia Online-Ressource cr rdacarrier Research on radiation protection dosimetry mainly focuses on continuous radiation in the world, but pulsed ionizing radiation has been widely used in the fields of industrial detection, X-ray diagnosis, security inspection and scientific research. The active electronic dosimeter has been widely used in the fields of environmental monitoring, regional monitoring, personal dose monitoring and emergency monitoring. The active electronic dosimeters are calibrated in continuous radiation field, and they cannot measure short pulse and high dose rate pulsed ionizing radiation accurately. The active radiation dosimeter can be divided into G-M counter type, scintillator detector type, semiconductor detector type and ionization chamber type according to different radiation detection principles. The measurement of pulsed X-ray dose is very difficult due to its short duration and high instantaneous dose rate. Taking nanosecond radiation pulse as an example, its single pulse dose usually reaches more than 1 μSv, and the instantaneous dose rate can reach more than 105 Sv/h. For G-M counter and semiconductor detector, there are problems of measurement stacking and detection dead time, so it is difficult to achieve such a high dose-rate response, and there is an over-response problem in the instrument, which will inevitably affect the accuracy of monitoring results. The measurement of pulsed radiation dose (rate) is difficult. However, pulsed ionizing radiation has been widely used in many fields, such as the development of new detector, industrial flaw detection, X-ray diagnosis, nuclear emergency response and scientific research, etc. In this paper, the reference ionizing radiation field of pulsed X-ray was established based on steady-state X-ray machine, pulsed X-ray machine and portable X-ray machine. In order to measure the dose of pulsed reference field, the theoretical calculation, Monte Carlo simulation and experiment method were used to develop a secondary standard ionization chamber for millisecond pulsed X-rays. From the experimental data, it can be seen that the mainstream active dosimeters currently sold have low pulse dose response and even give false readings, which are not suitable for short pulse and high dose rate measurement and early warning, will cause safety trouble to personal. The dosimetric characteristics, such as pulse time, pulse dose and instantaneous dose rate were studied based on pulsed X-ray secondary standard ionization chamber and pulsed time measurement system. The lower limit and upper limit of instantaneous dose rate of the established pulsed X-ray reference radiation field are 2.5×10-3 Sv/h and 6.7×105 Sv/h respectively. Pulse time is adjustable between 50 ns and 10 s. The dose rate range of pulsed X-ray reference radiation field established in this study covers environmental level, radiation protection level, diagnosis level, treatment level, emergency level and nuclear critical accident level, which can be used to calibrate the pulsed radiation dose monitoring instrument. It is helpful to further study the pulsed radiation response characteristics of active radiation dosimeter and personal radiation dosimeter. pulsed x-ray pulse time measurement system nuclear criticality nuclear criticality accident gamma radiation detection and alarm system pulsed radiation field Nuclear engineering. Atomic power Nuclear and particle physics. Atomic energy. Radioactivity In Yuanzineng kexue jishu Editorial Board of Atomic Energy Science and Technology, 2022 57(2023), 2, Seite 389-397 (DE-627)578537303 (DE-600)2451932-7 10006931 nnns volume:57 year:2023 number:2 pages:389-397 https://doaj.org/article/801c9c14da734efb9fd40684dc7ec1db kostenfrei https://www.aest.org.cn/CN/10.7538/yzk.2022.youxian.0176 kostenfrei https://doaj.org/toc/1000-6931 Journal toc kostenfrei GBV_USEFLAG_A SYSFLAG_A GBV_DOAJ GBV_ILN_2055 AR 57 2023 2 389-397
allfieldsGer	(DE-627)DOAJ088541126 (DE-599)DOAJ801c9c14da734efb9fd40684dc7ec1db DE-627 ger DE-627 rakwb eng chi TK9001-9401 QC770-798 GAO Fei;WANG Feifei;LIU Yuntao;DING Yuyang;CHEN Yizhen;NI Ning;WANG Ziling;LIU Jiarui;WANG Ziye;ZHAO Xu verfasserin aut Establishment and Study of Pulsed X-ray Reference Radiation Field 2023 Text txt rdacontent Computermedien c rdamedia Online-Ressource cr rdacarrier Research on radiation protection dosimetry mainly focuses on continuous radiation in the world, but pulsed ionizing radiation has been widely used in the fields of industrial detection, X-ray diagnosis, security inspection and scientific research. The active electronic dosimeter has been widely used in the fields of environmental monitoring, regional monitoring, personal dose monitoring and emergency monitoring. The active electronic dosimeters are calibrated in continuous radiation field, and they cannot measure short pulse and high dose rate pulsed ionizing radiation accurately. The active radiation dosimeter can be divided into G-M counter type, scintillator detector type, semiconductor detector type and ionization chamber type according to different radiation detection principles. The measurement of pulsed X-ray dose is very difficult due to its short duration and high instantaneous dose rate. Taking nanosecond radiation pulse as an example, its single pulse dose usually reaches more than 1 μSv, and the instantaneous dose rate can reach more than 105 Sv/h. For G-M counter and semiconductor detector, there are problems of measurement stacking and detection dead time, so it is difficult to achieve such a high dose-rate response, and there is an over-response problem in the instrument, which will inevitably affect the accuracy of monitoring results. The measurement of pulsed radiation dose (rate) is difficult. However, pulsed ionizing radiation has been widely used in many fields, such as the development of new detector, industrial flaw detection, X-ray diagnosis, nuclear emergency response and scientific research, etc. In this paper, the reference ionizing radiation field of pulsed X-ray was established based on steady-state X-ray machine, pulsed X-ray machine and portable X-ray machine. In order to measure the dose of pulsed reference field, the theoretical calculation, Monte Carlo simulation and experiment method were used to develop a secondary standard ionization chamber for millisecond pulsed X-rays. From the experimental data, it can be seen that the mainstream active dosimeters currently sold have low pulse dose response and even give false readings, which are not suitable for short pulse and high dose rate measurement and early warning, will cause safety trouble to personal. The dosimetric characteristics, such as pulse time, pulse dose and instantaneous dose rate were studied based on pulsed X-ray secondary standard ionization chamber and pulsed time measurement system. The lower limit and upper limit of instantaneous dose rate of the established pulsed X-ray reference radiation field are 2.5×10-3 Sv/h and 6.7×105 Sv/h respectively. Pulse time is adjustable between 50 ns and 10 s. The dose rate range of pulsed X-ray reference radiation field established in this study covers environmental level, radiation protection level, diagnosis level, treatment level, emergency level and nuclear critical accident level, which can be used to calibrate the pulsed radiation dose monitoring instrument. It is helpful to further study the pulsed radiation response characteristics of active radiation dosimeter and personal radiation dosimeter. pulsed x-ray pulse time measurement system nuclear criticality nuclear criticality accident gamma radiation detection and alarm system pulsed radiation field Nuclear engineering. Atomic power Nuclear and particle physics. Atomic energy. Radioactivity In Yuanzineng kexue jishu Editorial Board of Atomic Energy Science and Technology, 2022 57(2023), 2, Seite 389-397 (DE-627)578537303 (DE-600)2451932-7 10006931 nnns volume:57 year:2023 number:2 pages:389-397 https://doaj.org/article/801c9c14da734efb9fd40684dc7ec1db kostenfrei https://www.aest.org.cn/CN/10.7538/yzk.2022.youxian.0176 kostenfrei https://doaj.org/toc/1000-6931 Journal toc kostenfrei GBV_USEFLAG_A SYSFLAG_A GBV_DOAJ GBV_ILN_2055 AR 57 2023 2 389-397
allfieldsSound	(DE-627)DOAJ088541126 (DE-599)DOAJ801c9c14da734efb9fd40684dc7ec1db DE-627 ger DE-627 rakwb eng chi TK9001-9401 QC770-798 GAO Fei;WANG Feifei;LIU Yuntao;DING Yuyang;CHEN Yizhen;NI Ning;WANG Ziling;LIU Jiarui;WANG Ziye;ZHAO Xu verfasserin aut Establishment and Study of Pulsed X-ray Reference Radiation Field 2023 Text txt rdacontent Computermedien c rdamedia Online-Ressource cr rdacarrier Research on radiation protection dosimetry mainly focuses on continuous radiation in the world, but pulsed ionizing radiation has been widely used in the fields of industrial detection, X-ray diagnosis, security inspection and scientific research. The active electronic dosimeter has been widely used in the fields of environmental monitoring, regional monitoring, personal dose monitoring and emergency monitoring. The active electronic dosimeters are calibrated in continuous radiation field, and they cannot measure short pulse and high dose rate pulsed ionizing radiation accurately. The active radiation dosimeter can be divided into G-M counter type, scintillator detector type, semiconductor detector type and ionization chamber type according to different radiation detection principles. The measurement of pulsed X-ray dose is very difficult due to its short duration and high instantaneous dose rate. Taking nanosecond radiation pulse as an example, its single pulse dose usually reaches more than 1 μSv, and the instantaneous dose rate can reach more than 105 Sv/h. For G-M counter and semiconductor detector, there are problems of measurement stacking and detection dead time, so it is difficult to achieve such a high dose-rate response, and there is an over-response problem in the instrument, which will inevitably affect the accuracy of monitoring results. The measurement of pulsed radiation dose (rate) is difficult. However, pulsed ionizing radiation has been widely used in many fields, such as the development of new detector, industrial flaw detection, X-ray diagnosis, nuclear emergency response and scientific research, etc. In this paper, the reference ionizing radiation field of pulsed X-ray was established based on steady-state X-ray machine, pulsed X-ray machine and portable X-ray machine. In order to measure the dose of pulsed reference field, the theoretical calculation, Monte Carlo simulation and experiment method were used to develop a secondary standard ionization chamber for millisecond pulsed X-rays. From the experimental data, it can be seen that the mainstream active dosimeters currently sold have low pulse dose response and even give false readings, which are not suitable for short pulse and high dose rate measurement and early warning, will cause safety trouble to personal. The dosimetric characteristics, such as pulse time, pulse dose and instantaneous dose rate were studied based on pulsed X-ray secondary standard ionization chamber and pulsed time measurement system. The lower limit and upper limit of instantaneous dose rate of the established pulsed X-ray reference radiation field are 2.5×10-3 Sv/h and 6.7×105 Sv/h respectively. Pulse time is adjustable between 50 ns and 10 s. The dose rate range of pulsed X-ray reference radiation field established in this study covers environmental level, radiation protection level, diagnosis level, treatment level, emergency level and nuclear critical accident level, which can be used to calibrate the pulsed radiation dose monitoring instrument. It is helpful to further study the pulsed radiation response characteristics of active radiation dosimeter and personal radiation dosimeter. pulsed x-ray pulse time measurement system nuclear criticality nuclear criticality accident gamma radiation detection and alarm system pulsed radiation field Nuclear engineering. Atomic power Nuclear and particle physics. Atomic energy. Radioactivity In Yuanzineng kexue jishu Editorial Board of Atomic Energy Science and Technology, 2022 57(2023), 2, Seite 389-397 (DE-627)578537303 (DE-600)2451932-7 10006931 nnns volume:57 year:2023 number:2 pages:389-397 https://doaj.org/article/801c9c14da734efb9fd40684dc7ec1db kostenfrei https://www.aest.org.cn/CN/10.7538/yzk.2022.youxian.0176 kostenfrei https://doaj.org/toc/1000-6931 Journal toc kostenfrei GBV_USEFLAG_A SYSFLAG_A GBV_DOAJ GBV_ILN_2055 AR 57 2023 2 389-397
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source	In Yuanzineng kexue jishu 57(2023), 2, Seite 389-397 volume:57 year:2023 number:2 pages:389-397
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callnumber-first	T - Technology
author	GAO Fei;WANG Feifei;LIU Yuntao;DING Yuyang;CHEN Yizhen;NI Ning;WANG Ziling;LIU Jiarui;WANG Ziye;ZHAO Xu
spellingShingle	GAO Fei;WANG Feifei;LIU Yuntao;DING Yuyang;CHEN Yizhen;NI Ning;WANG Ziling;LIU Jiarui;WANG Ziye;ZHAO Xu misc TK9001-9401 misc QC770-798 misc pulsed x-ray misc pulse time measurement system misc nuclear criticality misc nuclear criticality accident gamma radiation detection and alarm system misc pulsed radiation field misc Nuclear engineering. Atomic power misc Nuclear and particle physics. Atomic energy. Radioactivity Establishment and Study of Pulsed X-ray Reference Radiation Field
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topic_title	TK9001-9401 QC770-798 Establishment and Study of Pulsed X-ray Reference Radiation Field pulsed x-ray pulse time measurement system nuclear criticality nuclear criticality accident gamma radiation detection and alarm system pulsed radiation field
topic	misc TK9001-9401 misc QC770-798 misc pulsed x-ray misc pulse time measurement system misc nuclear criticality misc nuclear criticality accident gamma radiation detection and alarm system misc pulsed radiation field misc Nuclear engineering. Atomic power misc Nuclear and particle physics. Atomic energy. Radioactivity
topic_unstemmed	misc TK9001-9401 misc QC770-798 misc pulsed x-ray misc pulse time measurement system misc nuclear criticality misc nuclear criticality accident gamma radiation detection and alarm system misc pulsed radiation field misc Nuclear engineering. Atomic power misc Nuclear and particle physics. Atomic energy. Radioactivity
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title	Establishment and Study of Pulsed X-ray Reference Radiation Field
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title_full	Establishment and Study of Pulsed X-ray Reference Radiation Field
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author_browse	GAO Fei;WANG Feifei;LIU Yuntao;DING Yuyang;CHEN Yizhen;NI Ning;WANG Ziling;LIU Jiarui;WANG Ziye;ZHAO Xu
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author-letter	GAO Fei;WANG Feifei;LIU Yuntao;DING Yuyang;CHEN Yizhen;NI Ning;WANG Ziling;LIU Jiarui;WANG Ziye;ZHAO Xu
title_sort	establishment and study of pulsed x-ray reference radiation field
callnumber	TK9001-9401
title_auth	Establishment and Study of Pulsed X-ray Reference Radiation Field
abstract	Research on radiation protection dosimetry mainly focuses on continuous radiation in the world, but pulsed ionizing radiation has been widely used in the fields of industrial detection, X-ray diagnosis, security inspection and scientific research. The active electronic dosimeter has been widely used in the fields of environmental monitoring, regional monitoring, personal dose monitoring and emergency monitoring. The active electronic dosimeters are calibrated in continuous radiation field, and they cannot measure short pulse and high dose rate pulsed ionizing radiation accurately. The active radiation dosimeter can be divided into G-M counter type, scintillator detector type, semiconductor detector type and ionization chamber type according to different radiation detection principles. The measurement of pulsed X-ray dose is very difficult due to its short duration and high instantaneous dose rate. Taking nanosecond radiation pulse as an example, its single pulse dose usually reaches more than 1 μSv, and the instantaneous dose rate can reach more than 105 Sv/h. For G-M counter and semiconductor detector, there are problems of measurement stacking and detection dead time, so it is difficult to achieve such a high dose-rate response, and there is an over-response problem in the instrument, which will inevitably affect the accuracy of monitoring results. The measurement of pulsed radiation dose (rate) is difficult. However, pulsed ionizing radiation has been widely used in many fields, such as the development of new detector, industrial flaw detection, X-ray diagnosis, nuclear emergency response and scientific research, etc. In this paper, the reference ionizing radiation field of pulsed X-ray was established based on steady-state X-ray machine, pulsed X-ray machine and portable X-ray machine. In order to measure the dose of pulsed reference field, the theoretical calculation, Monte Carlo simulation and experiment method were used to develop a secondary standard ionization chamber for millisecond pulsed X-rays. From the experimental data, it can be seen that the mainstream active dosimeters currently sold have low pulse dose response and even give false readings, which are not suitable for short pulse and high dose rate measurement and early warning, will cause safety trouble to personal. The dosimetric characteristics, such as pulse time, pulse dose and instantaneous dose rate were studied based on pulsed X-ray secondary standard ionization chamber and pulsed time measurement system. The lower limit and upper limit of instantaneous dose rate of the established pulsed X-ray reference radiation field are 2.5×10-3 Sv/h and 6.7×105 Sv/h respectively. Pulse time is adjustable between 50 ns and 10 s. The dose rate range of pulsed X-ray reference radiation field established in this study covers environmental level, radiation protection level, diagnosis level, treatment level, emergency level and nuclear critical accident level, which can be used to calibrate the pulsed radiation dose monitoring instrument. It is helpful to further study the pulsed radiation response characteristics of active radiation dosimeter and personal radiation dosimeter.
abstractGer	Research on radiation protection dosimetry mainly focuses on continuous radiation in the world, but pulsed ionizing radiation has been widely used in the fields of industrial detection, X-ray diagnosis, security inspection and scientific research. The active electronic dosimeter has been widely used in the fields of environmental monitoring, regional monitoring, personal dose monitoring and emergency monitoring. The active electronic dosimeters are calibrated in continuous radiation field, and they cannot measure short pulse and high dose rate pulsed ionizing radiation accurately. The active radiation dosimeter can be divided into G-M counter type, scintillator detector type, semiconductor detector type and ionization chamber type according to different radiation detection principles. The measurement of pulsed X-ray dose is very difficult due to its short duration and high instantaneous dose rate. Taking nanosecond radiation pulse as an example, its single pulse dose usually reaches more than 1 μSv, and the instantaneous dose rate can reach more than 105 Sv/h. For G-M counter and semiconductor detector, there are problems of measurement stacking and detection dead time, so it is difficult to achieve such a high dose-rate response, and there is an over-response problem in the instrument, which will inevitably affect the accuracy of monitoring results. The measurement of pulsed radiation dose (rate) is difficult. However, pulsed ionizing radiation has been widely used in many fields, such as the development of new detector, industrial flaw detection, X-ray diagnosis, nuclear emergency response and scientific research, etc. In this paper, the reference ionizing radiation field of pulsed X-ray was established based on steady-state X-ray machine, pulsed X-ray machine and portable X-ray machine. In order to measure the dose of pulsed reference field, the theoretical calculation, Monte Carlo simulation and experiment method were used to develop a secondary standard ionization chamber for millisecond pulsed X-rays. From the experimental data, it can be seen that the mainstream active dosimeters currently sold have low pulse dose response and even give false readings, which are not suitable for short pulse and high dose rate measurement and early warning, will cause safety trouble to personal. The dosimetric characteristics, such as pulse time, pulse dose and instantaneous dose rate were studied based on pulsed X-ray secondary standard ionization chamber and pulsed time measurement system. The lower limit and upper limit of instantaneous dose rate of the established pulsed X-ray reference radiation field are 2.5×10-3 Sv/h and 6.7×105 Sv/h respectively. Pulse time is adjustable between 50 ns and 10 s. The dose rate range of pulsed X-ray reference radiation field established in this study covers environmental level, radiation protection level, diagnosis level, treatment level, emergency level and nuclear critical accident level, which can be used to calibrate the pulsed radiation dose monitoring instrument. It is helpful to further study the pulsed radiation response characteristics of active radiation dosimeter and personal radiation dosimeter.
abstract_unstemmed	Research on radiation protection dosimetry mainly focuses on continuous radiation in the world, but pulsed ionizing radiation has been widely used in the fields of industrial detection, X-ray diagnosis, security inspection and scientific research. The active electronic dosimeter has been widely used in the fields of environmental monitoring, regional monitoring, personal dose monitoring and emergency monitoring. The active electronic dosimeters are calibrated in continuous radiation field, and they cannot measure short pulse and high dose rate pulsed ionizing radiation accurately. The active radiation dosimeter can be divided into G-M counter type, scintillator detector type, semiconductor detector type and ionization chamber type according to different radiation detection principles. The measurement of pulsed X-ray dose is very difficult due to its short duration and high instantaneous dose rate. Taking nanosecond radiation pulse as an example, its single pulse dose usually reaches more than 1 μSv, and the instantaneous dose rate can reach more than 105 Sv/h. For G-M counter and semiconductor detector, there are problems of measurement stacking and detection dead time, so it is difficult to achieve such a high dose-rate response, and there is an over-response problem in the instrument, which will inevitably affect the accuracy of monitoring results. The measurement of pulsed radiation dose (rate) is difficult. However, pulsed ionizing radiation has been widely used in many fields, such as the development of new detector, industrial flaw detection, X-ray diagnosis, nuclear emergency response and scientific research, etc. In this paper, the reference ionizing radiation field of pulsed X-ray was established based on steady-state X-ray machine, pulsed X-ray machine and portable X-ray machine. In order to measure the dose of pulsed reference field, the theoretical calculation, Monte Carlo simulation and experiment method were used to develop a secondary standard ionization chamber for millisecond pulsed X-rays. From the experimental data, it can be seen that the mainstream active dosimeters currently sold have low pulse dose response and even give false readings, which are not suitable for short pulse and high dose rate measurement and early warning, will cause safety trouble to personal. The dosimetric characteristics, such as pulse time, pulse dose and instantaneous dose rate were studied based on pulsed X-ray secondary standard ionization chamber and pulsed time measurement system. The lower limit and upper limit of instantaneous dose rate of the established pulsed X-ray reference radiation field are 2.5×10-3 Sv/h and 6.7×105 Sv/h respectively. Pulse time is adjustable between 50 ns and 10 s. The dose rate range of pulsed X-ray reference radiation field established in this study covers environmental level, radiation protection level, diagnosis level, treatment level, emergency level and nuclear critical accident level, which can be used to calibrate the pulsed radiation dose monitoring instrument. It is helpful to further study the pulsed radiation response characteristics of active radiation dosimeter and personal radiation dosimeter.
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