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Risk management - Large scientific installations - General principles
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Basic data
| Standard ID | GB/T 44429-2024 (GB/T44429-2024) |
| Description (Translated English) | Risk management - Large scientific installations - General principles |
| Sector / Industry | National Standard (Recommended) |
| Classification of Chinese Standard | A02 |
| Word Count Estimation | 20,233 |
| Date of Issue | 2024-08-23 |
| Date of Implementation | 2024-08-23 |
| Issuing agency(ies) | State Administration for Market Regulation, China National Standardization Administration |
GB/T 44429-2024: Risk management - Large scientific installations - General principles
---This is a DRAFT version for illustration, not a final translation. Full copy of true-PDF in English version (including equations, symbols, images, flow-chart, tables, and figures etc.) will be manually/carefully translated upon your order.
Risk management - Large scientific installations - General principles
General Principles of Risk Management for Large Scientific Facilities
ICS 03.120.01
CCS A 02
National Standard of the People's Republic of China
Released on 2024-08-23
2024-08-23 implementation
State Administration for Market Regulation
The National Standardization Administration issued
Table of Contents
Preface ... Ⅲ
Introduction ... Ⅳ
1 Scope ... 1
2 Normative references ... 1
3 Terms and Definitions ... 1
4 Risk Management Principles ... 1
5 Risk Management Process ... 2
6 Risk Management Implementation ... 6
Appendix A (Informative) Criteria for Determining Probability Levels (Example) ... 9
Appendix B (Informative) Criteria for Determining Consequence Levels (Example) ... 10
Appendix C (Informative) Risk Assessment Matrix (Example) ... 11
References ... 12
Foreword
This document is in accordance with the provisions of GB/T 1.1-2020 "Guidelines for standardization work Part 1.Structure and drafting rules for standardization documents"
Drafting is required.
Please note that some of the contents of this document may involve patents. The issuing organization of this document does not assume the responsibility for identifying patents.
This document was proposed and coordinated by the National Technical Committee on Risk Management Standardization (SAC/TC 310).
This document was drafted by. Hefei Institutes of Physical Science, Chinese Academy of Sciences, Institute of Modern Physics, Chinese Academy of Sciences, Guangzhou Borgia Standards
and Testing Technology Co., Ltd., Institute of High Energy Physics, Chinese Academy of Sciences, Shaanxi Huada Technology Co., Ltd., Guangzhou Biaoxin Technology Co., Ltd.
Co., Ltd., University of Science and Technology of China, Dagang Holding Group Co., Ltd., China National Institute of Standardization, Hefei Zhongke Ion Medical Technology Equipment
Co., Ltd., China National Nuclear Power Co., Ltd., CNNC Wuhan Nuclear Power Operation Technology Co., Ltd., Nuclear Power Operation Research (Shanghai)
Co., Ltd., China Resources Biopharmaceutical Co., Ltd., Southwest Jiaotong University, Anhui Haifeng Analysis and Testing Technology Co., Ltd., Shandong Provincial Standardization Research Institute
Research Institute, Guizhou Provincial Institute of Standardization, and China University of Geosciences (Beijing) Zhengzhou Research Institute.
The main drafters of this document are. Song Yuntao, Li Jun, Ge Rui, Huang Suzhen, Wang Wenjian, Zhang Feng, Gao Daqing, Shi Jian, Cai Zhenbing,
Ding Haohao, Xu Yingcheng, Gao Xiaohong, Lu Xiaowei, Li Ya, Huang Yi, Quan Kunpeng, Ning Xiuli, Wu Qian, Zhang Luwei, Yu Qin, Wang Sicheng,
Ding Kaizhong, Xing Yixiang, Jiang Wenkang, Li Junjie, Dai Guangyu, Xu Han, Zhu Shuchao, Li Yanwei, Xin Lu, Zhang Wei, Zhou Xiangshan, Yang Fengjiang,
Liu Yaping, Liang Houguang, Wu Guanling, Yue Wen, She Dingshun.
Introduction
Large scientific facilities are completed through large-scale investment and engineering construction, and after completion, they are operated stably and continuously through long-term scientific and technological
Large scientific facilities are necessary for achieving breakthroughs in many areas of modern science and technology.
It is an indispensable scientific and technological infrastructure to safeguard national economic development, national security and social progress, and is the key to building a strong national
It is an important condition for becoming a national large-scale scientific research base with international competitiveness. It is the source of many high-tech technologies and the cradle of high-tech industries.
Large scientific facilities usually have the following characteristics.
The scientific and technological significance is significant, the impact is wide and long-term, the construction scale and cost are large, and the construction time is long; a)
The technology is comprehensive and complex, requiring the development of a large number of non-standard equipment during construction, and has the dual nature of engineering and development; b)
Its output is scientific knowledge and technological achievements, rather than direct economic benefits. After completion, it must be operated stably for a long time and not
Only through continuous development and sustained scientific activities can the predetermined scientific and technological goals be achieved;
c)
The entire process from project establishment, construction to utilization has shown strong openness and international characteristics. d)
This document is compiled under the guidance of GB/T 24353-2022 and combined with the characteristics and actual situation of my country's large scientific facilities.
The environmental information of large scientific facilities inside and outside, the determination of risk criteria, and the use of systematic methods and tools to identify, analyze, evaluate and respond to potential risks
Risk management helps large scientific facility organizations and personnel effectively manage the risks that large scientific facilities may face at various stages of their life cycle and take necessary measures.
Countermeasures and guide the implementation of management work.
This document serves as a general guideline for risk management of large scientific facilities. During implementation, it can be used as a reference and selection based on the internal and external environment of large scientific facilities.
Select to use.
General Principles of Risk Management for Large Scientific Facilities
1 Scope
This document defines the principles, processes and implementation of risk management for large scientific facilities.
This document applies to the risk management of large scientific facilities throughout their life cycle, and other facilities may refer to it for reference.
2 Normative references
The contents of the following documents constitute the essential clauses of this document through normative references in this document.
For referenced documents without a date, only the version corresponding to that date applies to this document; for referenced documents without a date, the latest version (including all amendments) applies.
in this document.
GB/T 24353-2022 Risk Management Guide
GB/T 27921-2023 Risk management risk assessment technology
3 Terms and definitions
The following terms and definitions apply to this document.
3.1
large scientific installation
It will be completed through large-scale investment and engineering construction, and after completion, it will be realized through long-term stable operation and continuous scientific and technological activities.
Large-scale facilities with scientific and technological goals.
3.2
Risk
The adverse impact of uncertainty on the entire life cycle of large scientific facilities.
3.3
Risk Management
Directs and controls the systematic application of management policies, procedures, and practices to communicate, consult, clarify the environment, and identify,
Activities to analyze, evaluate, respond to, monitor and review risks of large scientific facilities.
4 Risk Management Principles
4.1 Coordination
When carrying out risk management of large scientific facilities, it is advisable to clarify the rights and responsibilities of all parties and coordinate stakeholders to participate in the construction and operation of large scientific facilities.
Take into account the risk management process and its implementation, and coordinate with other management processes.
4.2 Inclusiveness
Large scientific facilities are complex and technologically complex. Stakeholders should combine their knowledge, opinions and cognition to participate in risk management in a timely manner and help improve the organization
Organize risk awareness and promote full communication of risk management information for large scientific facilities.
...
