Standard No.:	GB 5172-2025
English Name:	Regulations for radiation safety and protection of particle accelerators
Chinese Name:	粒子加速器辐射安全与防护规定
Chinese Classification:	F70    Radiation protection and monitoring in general
Professional Classification:	GB    National Standard
Source Content Issued by:	SAMR;SAC
Issued on:	2025-12-02
Implemented on:	2026-7-1
Status:	to be valid
Superseding:	GB 5172-1985 The rule for radiation protection of particle accelerators
Target Language:	English
File Format:	PDF
Word Count:	6500 words
Translation Price(USD):	195.0
Delivery:	via email in 1~3 business day

GB 5172-2025 Regulations for radiation safety and protection of particle accelerators English, Anglais, Englisch, Inglés, えいご This is a draft translation for reference among interesting stakeholders. The finalized translation (passing through draft translation, self-check, revision and verification) will be delivered upon being ordered. ICS CCS H National Standard of the People's Republic of China ‌GB 5172-2025 Replaces GB 5172-1985 Regulations for radiation safety and protection of particle accelerators 粒子加速器辐射安全与防护规定 Issue date: 2025-12-02 Implementation date: 2027-01-01 Issued by the General Administration of Quality Supervision, Inspection and Quarantine of the People's Republic of China the Standardization Administration of the People's Republic of China Contents Foreword 1 Scope 2 Normative References 3 Terms and Definitions 4 General Requirements 5 Radiation Safety and Protection Design Requirements 6 Radiation Safety and Protection Requirements for Operation 7 Radiation Monitoring 8 Radioactive Waste Management 9 Decommissioning 1 Scope This standard specifies the general requirements for radiation safety and protection of particle accelerators. This standard applies to the radiation safety and protection of particle accelerators with energy not lower than 1 MeV. This standard does not apply to portable accelerators such as sealed neutron tubes and accelerators used for cargo/vehicle radiation inspection systems. 2 Normative References The following documents, or provisions thereof, are referenced in this standard. For dated references, only the edition cited applies. For undated references, the latest edition of the referenced document (including all amendments) applies. If other documents are superseded, modified, or revised by new ones, the new documents apply. GB 18871 Basic standards for protection against ionizing radiation and for the safety of radiation sources GB 14500 Regulations for radioactive waste management 3 Terms and Definitions For the purposes of this standard, the following terms and definitions apply. 3.1 particle accelerator A device that uses electric or electromagnetic fields to accelerate charged particles to specific energies and confines the movement of charged particles within a specific space. 3.2 particle accelerator facility A particle accelerator and the facilities housing and operating it, such as the building housing the particle accelerator, supporting systems and facilities. 3.3 accelerator room The location housing the particle source and the equipment for beam generation, acceleration, and transport of the particle accelerator. 3.4 beam terminal room The location where the beam extracted from the particle accelerator is used for purposes such as scientific research experiments, industrial applications, and medical treatments, e.g., beamline stations, irradiation rooms, and radiotherapy rooms. 3.5 target An object that can interact directly with particles to achieve the intended purpose. 3.6 prompt radiation The primary particles from the particle accelerator and secondary particles such as gamma rays and neutrons produced by their interaction with matter are collectively referred to as prompt radiation, which exists only during the operation of the particle accelerator. 3.7 induced radioactivity Radioactivity produced by unstable nuclides generated through nuclear reactions when particles such as protons and neutrons produced by the particle accelerator interact with surrounding materials such as air, cooling water, and accelerator components. 3.8 interlock system A safety control method (device) that interrelates the actions of relevant components, requiring each component to be in a specified state or operating condition; otherwise, the radiation source cannot be put into operation or use, or an operating radiation source is immediately shut down or constrained. 4 General Requirements 4.1 During the design, operation, and decommissioning of a particle accelerator facility, the principles of justification of practices, dose limitation and potential exposure restriction, and optimization of protection and safety shall be followed. 4.2 The annual dose limits for occupational exposure and public exposure shall comply with the relevant regulations on dose limits in GB 18871. 4.3 Dose constraint values shall be reasonably determined considering the characteristics of the particle accelerator and the application scenario. Generally, the dose constraint for occupational exposure shall not exceed 5 mSv/a, and the dose constraint for public exposure shall not exceed 0.1 mSv/a. 4.4 Radiation level monitoring of the particle accelerator workplace and surrounding environment shall be conducted regularly, and the effectiveness of radiation safety and protection measures shall be evaluated. 4.5 Radioactive waste generated during the operation and decommissioning of the particle accelerator shall be collected, stored, and disposed of properly and in accordance with regulations, following the principles of radioactive waste management to achieve waste minimization. 5 Radiation Safety and Protection Design Requirements 5.1 General Requirements 5.1.1 The principle of defense-in-depth shall be followed by establishing multiple safety and protection measures so that if one level of defense fails, it can be compensated for or corrected by the next level. Important systems, components, and equipment for radiation safety and protection shall have appropriate redundancy, diversity, and independence. 5.1.2 At the design stage of the particle accelerator facility, factors such as future application changes and development shall be appropriately considered. Radiation safety and protection facilities shall be reasonably laid out and designed with appropriate margins. 5.1.3 During the design and construction stages of the particle accelerator facility, personnel with relevant expertise in radiation protection shall participate and specifically organize or be responsible for the design of radiation safety and protection facilities. 5.1.4 The design of the radiation safety interlock system for the particle accelerator shall follow the fail-safe design principle. 5.2 Zoning of Radiation Workplaces 5.2.1 The radiation workplaces of the particle accelerator shall be divided into controlled areas and supervised areas. Areas that require or are likely to require special protection means or safety measures shall be designated as controlled areas, mainly including accelerator rooms, beam terminal rooms, and radioactive waste storage areas, etc. Areas adjacent to controlled areas, where special protection means or safety measures are not usually required but where occupational exposure conditions need to be regularly monitored and evaluated, shall be designated as supervised areas. 5.2.2 Entrances to controlled and supervised areas shall be marked with controlled area and supervised area signs. Entrances/exits of controlled areas and other appropriate locations shall also be marked with conspicuous ionizing radiation warning signs. 5.3 Radiation Shielding 5.3.1 Sufficient shielding shall be provided for accelerator rooms and beam terminal rooms to achieve the radiation shielding design objectives and to ensure that personnel exposure doses meet the requirements of 4.3.