仪器控制检测标准仪器控制-中析研究所检测

(CMA)

(CNAS)

(ISO)

(高新技术企业)

仪器控制相关标准参考信息

GB/Z 41476.4-2022 无损检测仪器　1 MV以下X射线设备的辐射防护规则　第4部分：控制区域的计算
简介：
信息：ICS：19.100 CCS：N78 发布：2022-04-15 实施：2022-11-01

ASTM D7282-2014 放射能测量用仪器安装, 校准和质量控制的标准实施规程
简介：5.1x00a0;This practice is consistent with a performance-based approach wherein the frequency of re-calibration and instrument testing is linked to a laboratoryx0027;s continuing performance with its quality control results. Under the premise of this practice, a laboratory demonstrates that its instrument performance is acceptable for analyzing sample test sources. 5.2x00a0;When a laboratory demonstrates acceptable performance based on continuing instrument quality control data (that is, QC charts), batch QC samples (that is, blanks, laboratory control samples, replicates, matrix spikes, and other batch QC samples as may be applicable) and independent reference materials, traditional schedule-driven instrument recalibration is permissible but unnecessary. 5.3x00a0;When continuing instrument QC, batch QC, or independent reference material sample results indicate that instrument response has exceeded established control or tolerance limits, instrument calibration is required. Other actions related to sample analyses on the affected instruments may be required by the laboratory QM. 5.4x00a0;The data obtained while following this Practice will most likely reside in computer storage. This data remains in the computer storage where it is readily retrievable and as necessary is used to produce plots, graphs, spreadsheets and other types of displays and reports. Frequency and performance of data storage backup should be specified in the laboratory QM. 1.1x00a0;This practice covers consensus criteria for the calibration and quality control of nuclear instruments. This practice is provided for establishing appropriate quality control parameters at instrument startup, calibration of nuclear counting instruments and the continuing monitoring of quality control parameters. Calibrations are usually performed to establish the operating parameters of the instrument. This practice addresses the typically used nuclear counting instruments: alpha spectrometer, gamma spectrometer, gas proportional counter and liquid scintillation counter. 1.2x00a0;The values stated in SI units are to be regarded as standard. The values given in parentheses are mathematical conversions that are provided for information only and are not considered standard. 1.3x00a0;This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use.
信息：ICS：17.240 CCS：发布：2014 实施：

EN 62340-2010 核电站.仪器和控制设备的安全重要性.应对共因失效(CCF)的要求
简介：
信息：ICS： CCS：发布：2010-05-01 实施：

GB/T 9332-2008 船舶电气装置.控制和仪器回路用150/250V(300V)电缆
简介：本标准适用于额定电压 150/250V(300V）（见第 4 章 ) 固定敷设的挤包绝缘电缆。主要用于船舶及离岸装置控制和仪器回路用屏蔽和非屏蔽电缆。第 8 章所列各类电缆 , 除非本标准另有规定 , 结构要求和试验方法应符合 GB/T 20637—2006 的规定。本标准的目的 :——旨在按 GB/T 13029.1-2003 要求所选择和安装的电缆标准化 , 从而保证其安全、可靠 ;——规定了电缆的生产要求以及与安全直接或间接相关的特性 ; ——规定了检查产品是否符合本标准要求的试验方法。
信息：ICS：29.060.20 CCS：K13 发布：2008-12-31 实施：2009-11-01

IEC 62671:2013 核电站 - 仪器与控制重要安全 - 选择和使用有限功能的工业数字设备
简介：
信息：ICS：27.120.20 CCS：发布：2013-02-20 实施：

IEC 62465-2010 核电站.仪器使用和控制安全性重要事项.电力电缆系统老化管理
简介：This International Standard provides strategies, technical requirements, and recommendedpractices for the management of normal ageing of cabling systems that are important tosafety in nuclear power plants. The main requirements are presented in the body of thisInternational Standard followed by a number of informative annexes with examples of cabletesting techniques, procedures, and equipment that are available for the nuclear industry touse to ensure that ageing degradation will not impact plant safety.This International Standard covers cables and their accessories (e.g., connectors) installed innuclear power plants (inside and outside the containment). It provides requirements toperform cable testing for the purposes of predictive maintenance, troubleshooting, ageingmanagement, and assurance of plant safety. It is concerned with Instrumentation and Control(I&C) cables, signal cables, and power cables of voltages less than 1 kV. More specifically,this International Standard focuses on in-situ testing techniques that have been establishedfor determining problems in cable conductors (i.e., copper wire) and, to a lesser extent, oninsulation material (i.e., polymer). It follows the IEC 62342 standard on “Management ofAgeing” that was prepared to provide general guidelines for management of ageing of I&Ccomponents in nuclear power plants, including cables. It should be pointed out that cabletesting technologies are evolving and new methods are becoming available that are notcovered in this International Standard. More specifically, this International Standard coverstypical cable testing methods that have been in use in the nuclear power industry over the lastdecade. It should also be pointed out that a single cable testing technique is unlikely toprovide conclusive results, and a reliable diagnosis normally requires a combination oftechniques.
信息：ICS：27.120.20 CCS：F83 发布：2010-05 实施：

DB/T 13-2021 地面震动观测仪器接口与控制
简介：
信息：ICS：91.120.25 CCS：P15 发布：2021-09-06 实施：2022-01-01

IEC/IEEE 62582-3:2012 核电站 - 安全重要的仪器和控制 - 电气设备状态监测方法 - 第3部分:断裂伸长率
简介：
信息：ICS：27.120.20 CCS：发布：2012-12-12 实施：

EN 61226-2010 核电站.仪器和控制设备的安全重要性.仪表和控制功能分级
简介：
信息：ICS： CCS：发布：2010-03-01 实施：

ASTM D7282-21e1 放射性测量用仪器的设置、校准和质量控制的标准实施规程
简介：
信息：ICS：17.240 CCS：发布：2021-05-15 实施：

KS C IEC 62385-2012 核电站.安全的重要测量控制.安全系统仪器渠道的性能评估方法
简介：이 표준의 목적은 응답 시간 시험, 교정 확인, 기타 방법을 통해 안전 계통 계기 채널의
信息：ICS：27.120.20 CCS：K59 发布：2012-12-12 实施：2012-12-12

ISO/PAS 3930:2009 测量车辆废气排放的仪器——计量技术要求；计量控制和性能测试
简介：
信息：ICS：13.040.50 CCS：发布：2009-12-15 实施：

ASTM D7282-21 放射性测量用仪器的设置、校准和质量控制的标准实施规程
简介：
信息：ICS：17.240 CCS：发布：2021-05-15 实施：

IEC 62566:2012 核电站 - 仪器与控制重要安全 - 执行A类功能的系统的Hdl编程集成电路的开发
简介：
信息：ICS：27.120.20 CCS：发布：2012-01-26 实施：

ISO/PAS 3930-2009 测量机动车尾气排放仪器.计量和技术要求.计量控制和性能试验
简介：
信息：ICS：13.040.50;43.180 CCS：R17 发布：2009-12 实施：

KS C IEC 62705-2019 核电站 - 对安全重要的仪器和控制 - 辐射监测系统（RMS）:特性和生命周期
简介：
信息：ICS：27.120.20 CCS：发布：2019-04-23 实施：

GOST R IEC 62385-2012 核电站.仪器和控制对安全的重要性.安全系统仪器通道的性能评估方法
简介：
信息：ICS：27.120.20 CCS：发布：2012 实施：2013-06-01

IEC 61500:2009 核电站 - 对安全重要的仪器和控制 - 执行A类功能的系统中的数据通信
简介：
信息：ICS：27.120.20 CCS：发布：2009-10-28 实施：

IEC/IEEE 62582-5:2015 核电站 - 对安全重要的仪器和控制 - 电气设备状态监测方法 - 第5部分:光时域反射计
简介：
信息：ICS：27.120.20 CCS：发布：2015-06-19 实施：

ASTM F50-2012 在控制尘埃区域和清洁室中用能够检测单次微米和大粒子仪器连续测定空气中悬浮微粒的大小及计数的标准实施规程
简介：The primary purpose of this practice is to describe a procedure for collecting near real-time data on airborne particle concentration and size distribution in clean areas as indicated by single particle counting techniques. Implementation of some government and industry specifications requires acquisition of particle size and concentration data using an SPC. The processing requirements of many products manufactured in a clean room involves environmental cleanliness levels so low that a single particle counter with capability for detecting very small particles is required to characterize clean room air. Real-time information on concentration of airborne particles in size ranges from less than 0.1 x03BC;m to 5 x03BC;m and greater can be obtained only with an SPC. Definition of particles larger than approximately 0.05 x03BC;m may be carried out with direct measurement of light scattering from individual particles; other techniques may be required for smaller particles, such as preliminary growth by condensation before particle measurement. Particle size data are referenced to the particle system used to calibrate the SPC. Differences in detection, electronic and sample handling systems among the various SPCs may contribute to differences in particle characterization. Care must be exercised in attempting to compare data from particles that vary significantly in composition or shape from the calibration base material. Variations may also occur between instruments using similar particle sensing systems with different operating parameters. These effects should be recognized and minimized by using standard methods for SPC calibration and operation. In applying this practice, the fundamental assumption is made that the particles in the sample passing through the SPC are representative of the particles in the entire dust-controlled area being analyzed. Care is required that good sampling procedures are used and that no artifacts are produced at any point in the sample handling and analysis process; these precautions are necessary both in verification and in operation of the SPC.1.1 This practice covers the determination of the particle concentration, by number, and the size distribution of airborne particles in dust-controlled areas and clean rooms, for particles in the size range of approximately 0.01 to 5.0 x03BC;m. Particle concentrations not exceeding 3.5 x00D7; 106 particles/m3 (100 000/ft3) are covered for all particles equal to and larger than the minimum size measured. 1.2 This practice uses an airborne single particle counting device (SPC) whose operation is based on measuring the signal produced by an individual particle passing through the sensing zone. The signal must be directly or indirectly related to particle size. Note 18212;The SPC type is not specified here. The SPC can be a conventional optical particle counter (OPC), an aerodynamic particle sizer, a condensation nucleus counter (CNC) operating in conjunction with a diffusion battery or differential mobility analyzer, or any other device capable of counting and sizing single particles in the size range of concern and of sampling in a cleanroom environment. 1.3 Individuals performing tests in accordance with this practice shall be trained in use of the SPC and shall understand its operation. 1.4 Since the concentration and the particle size distribution of airborne particles are subject to continuous variations, the choice of sampling probe configuration, locations and sampling times will affect sampling results. Further, the differences in the physical measurement, electronic and sample handling systems between the vario......
信息：ICS：13.040.30 (Workplace atmospheres) CCS：发布：2012 实施：

EN 62138-2009 核电站.仪器和控制设备的安全重要性.执行B类或C类功能的计算机系统的软件情况
简介：
信息：ICS： CCS：发布：2009-08-01 实施：

IEC/IEEE 62582-5-2015 核电站 - 对安全重要的仪器和控制 - 电气设备状态监测方法 - 第5部分:光时域反射计
简介：
信息：ICS：27.120.20 CCS：发布：2015-06-19 实施：

DIN EN 61500-2011 核电厂.安全性重要仪器和控制.执行A类功能系统的数据通信(IEC 61500-2009).德文版 EN 61500-2011
简介：
信息：ICS：27.120.20 CCS：F82 发布：2011-12 实施：2011-12-01

IEC 61226:2009 核电站 - 对安全重要的仪器和控制 - 仪表和控制功能的分类
简介：
信息：ICS：27.120.20 CCS：发布：2009-07-08 实施：

GOST 30630.1.9-2015 机械, 仪器以及其他工业产品的机械环境稳定性试验方法. 随机振动试验的数字控制特征
简介：
信息：ICS：19.040 CCS：J04 发布：2015 实施：2017-03-01

IEC/IEEE 62582-1:2011 核电站 - 安全重要的仪器和控制 - 电气设备状态监测方法 - 第1部分:总则
简介：
信息：ICS：27.120.20 CCS：发布：2011-08-31 实施：

EN 60987-2009 核电站.仪器和控制设备的安全重要性.基于计算机系统的硬件设计要求
简介：
信息：ICS： CCS：发布：2009-06-01 实施：

ASTM F3064/F3064M-2015 推进系统的仪器和传感器控制, 操作特征以及安装的标准规格
简介：1.1x00a0;This specification covers minimum requirements for the control, indication, and operational characteristics of propulsion systems. It was developed based on propulsion system installed on aeroplanes, but may be applicable to other applications as well. 1.2x00a0;The applicant for a design approval must seek the individual guidance to their respective CAA body concerning the use of this standard as part of a certification plan. For information on which CAA regulatory bodies have accepted this standard (in whole or in part) as a means of compliance to their Aeroplane Airworthiness regulations (Hereinafter referred to as x201c;the Rulesx201d;), refer to ASTM F44 webpage (www.ASTM.org/COMITTEE/F44.htm) which includes CAA website links. 1.3x00a0;Unitsx2014;The values stated are SI units followed by imperial units in brackets. The values stated in each system may not be exact equivalents; therefore, each system shall be used independently of the other. Combining values from the two systems may result in non-conformance with the standard. 1.4x00a0;This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use.
信息：ICS： CCS：发布：2015 实施：

IEC/IEEE 62582-4:2011 核电站 - 对安全重要的仪器和控制 - 电气设备状态监测方法 - 第4部分:氧化诱导技术
简介：
信息：ICS：27.120.20 CCS：发布：2011-08-31 实施：

BS IEC 62003-2009 核电站.重要安全性仪器装置和控制装置.电磁兼容性试验要求
简介：
信息：ICS：27.120.20 CCS：F83 发布：2009-05-31 实施：2009-05-31

GOST 30630.1.9-2015 机械, 仪器以及其他工业产品的机械环境稳定性试验方法. 随机振动试验的数字控制特征
简介：
信息：ICS：19.040 CCS：发布：2015 实施：2017-03-01

IEC/IEEE 62582-2:2011 核电站 - 仪器和控制重要安全 - 电气设备状况监测方法 - 第2部分:压头模数
简介：
信息：ICS：27.120.20 CCS：发布：2011-08-31 实施：

DIN EN 50288-7 Berichtigung 1-2009 模拟和数字通信及控制中使用的多元件金属电缆.第7部分:仪器和控制电缆分规范.技术勘误DIN EN 50288-7(VDE 0819-7)-2006
简介：
信息：ICS：33.120.20 CCS：K13 发布：2009-05-01 实施：

KS C IEC 61500-2014(2020) 核电站 - 对安全重要的仪器和控制 - 执行A类功能的系统中的数据通信
简介：
信息：ICS：27.120.20 CCS：发布：2014-12-26 实施：

IEC 61513:2011 核电站 - 仪器和控制重要的安全 - 系统的一般要求
简介：
信息：ICS：27.120.20 CCS：发布：2011-08-25 实施：

EEMUA PUB NO 178-2009 仪器电气安全设计指南,仪器/控制面板和控制系统(第2版)
简介：
信息：ICS： CCS：发布：2009-01-01 实施：

KS C IEC 61513-2014(2019) 核电站 - 仪器和控制重要的安全 - 系统的一般要求
简介：
信息：ICS：27.120.20 CCS：发布：2014-12-26 实施：

IEC 60092-504 CORR 1-2011 船舶电气装置.第504部分:专用功能部件.控制装置和仪器.勘误表1
简介：
信息：ICS：47.020.60 CCS：U62 发布：2011-01 实施：

KS B ISO 3158-2008 计时仪器控制位置符号
简介：
信息：ICS：39.040.10 CCS：发布：2008-09-05 实施：

KS C IEC 60987-2014(2019) 核电站 - 对安全重要的仪器和控制 - 基于计算机的系统的硬件设计要求
简介：
信息：ICS：27.120.20 CCS：发布：2014-12-26 实施：

IEC 60092-504 Corrigendum 1-2011 船舶电气装置.第504部分:专用功能部件.控制装置和仪器.勘误表1
简介：
信息：ICS：47.020.60 CCS：U62 发布：2011-01 实施：

DIN IEC 60671 Berichtigung 1-2008 核电站.使用仪器和控制设备的安全重要性.监视测试.技术勘误DIN IEC 60671(VDE 0491-100)-2007-12
简介：
信息：ICS：27.120.20 CCS：F80 发布：2008-08 实施：

KS B ISO 3511-3-2014(2019) 过程测量控制功能和仪表 - 符号表示第3部分仪器互连图的详细符号
简介：
信息：ICS： CCS：发布：2014-12-17 实施：

GOST R IEC 62340-2011 核电站.对安全性重要的仪器及控制设备.应对共因失效(CCF)的要求
简介：
信息：ICS：27.120.20 CCS：发布：2011 实施：2012-07-01

BS IEC 62340-2008 核电站.仪器和控制设备的安全重要性.应对共因失效(CCF)的要求
简介：I&C systems important to safety may be designed using conventional hard-wired equipment, computer-based equipment or by using a combination of both types of equipment. This International Standard provides requirements and recommendations1 for the overall architecture of I&C systems, which may contain either or both technologies. The scope of this standard is: a) to give requirements related to the avoidance of CCF of I&C systems that perform category A functions; b) to additionally require the implementation of independent I&C systems to overcome CCF, while the likelihood of CCF is reduced by strictly applying the overall safety principles of IEC SC 45A (notably IEC 61226, IEC 61513, IEC 60880 and IEC 60709); c) to give an overview of the complete scope of requirements relevant to CCF, but not to overlap with fields already addressed in other standards. These are referenced. This standard emphasises the need for the complete and precise specification of the safety functions, based on the analysis of design basis accidents and consideration of the main plant safety goals. This specification is the pre-requisite for generating a comprehensive set of detailed requirements for the design of I&C systems to overcome CCF. This standard provides principles and requirements to overcome CCF by means which ensure independence2: a) between I&C systems performing diverse safety functions within category A which contribute to the same safety target; b) between I&C systems performing different functions from different categories if e.g. a category B function is claimed as back-up of a category A function and; c) between redundant channels of the same I&C system. The implementation of these requirements leads to various types of defence against initiating CCF events. Means to achieve protection against CCF are discussed in this standard in relation to: a) susceptibility to internal plant hazards and external hazards; b) propagation of physical effects in the hardware (e.g. high voltages); and c) avoidance of specific faults and vulnerabilities within the I&C systems notably: 1) propagation of functional failure in I&C systems or between different I&C systems (e.g. by means of communication, fault or error on shared resources), 2) existence of common faults introduced during design or during system operation (e.g. maintenance induced faults), 3) insufficient system validation so that the system behaviour in response to input signal transients does not adequately correspond to the intended safety functions, 4) insufficient qualification of the required properties of hardware, insufficient verification of software components, or insufficient verification of compatibility between replaced and existing system components.
信息：ICS：27.120.20 CCS：F60 发布：2008-03-31 实施：2008-03-31

KS B ISO 3511-2-2014(2019) 过程测量控制功能和仪器 - 符号表示 - 第2部分:扩展基本要求
简介：
信息：ICS： CCS：发布：2014-12-17 实施：

DIN EN 62340-2010 核电站.仪器和控制设备对安全的重要性.应对共因失效(CCF)的要求(IEC 62340-2007).德文版本EN 62340-2010
简介：
信息：ICS：27.120.20 CCS：F69 发布：2010-12 实施：2010-12-01

NEMA WC 53-2008 试验用挤压介电,控制,仪器及便携式电缆标准试验方法
简介：
信息：ICS： CCS：发布：2008-01-01 实施：

IEEE 1687-2014 嵌入半导体设备内仪器的获取和控制(IEEE计算机协会)
简介：
信息：ICS： CCS：发布：2014-11-03 实施：

DIN EN 61226-2010 核电站.仪器和控制对安全的重要性.安全系统测量途径的性能评估用方法(IEC 61226-2009).德文版本EN 61226-2010
简介：
信息：ICS：27.120.20 CCS：F69 发布：2010-08 实施：2010-08-01

GOST R 52931-2008 工艺监测与控制仪器.通用规范
简介：
信息：ICS：17.020 CCS：发布：2008 实施：2009-07-01

KS R ISO PAS 3930-2014 用于测量车辆废气排放的仪器 - 计量和技术要求;计量控制和性能测试
简介：
信息：ICS： CCS：发布：2014-08-18 实施：

BS IEC 62465-2010 核电站.仪器使用和控制安全性重要事项.电力电缆系统老化管理
简介：
信息：ICS：27.120.20 CCS：F69 发布：2010-07-31 实施：2010-07-31

GOST R 52931-2008 工艺监测与控制仪器.通用规范
简介：
信息：ICS：17.020 CCS：发布：2008 实施：2009-07-01

IEC 62705:2014 核电站 - 对安全重要的仪器和控制 - 辐射监测系统（RMS）:特性和生命周期
简介：
信息：ICS：27.120.20 CCS：发布：2014-07-24 实施：

IEC 62340-2007 核电站.仪器和控制设备对安全的重要性.应对共因失效(CCF)的要求
简介：I&C systems important to safety may be designed using conventional hard-wired equipment,computer-based equipment or by using a combination of both types of equipment. ThisInternational Standard provides requirements and recommendations1 for the overallarchitecture of I&C systems, which may contain either or both technologies.The scope of this standard is:a) to give requirements related to the avoidance of CCF of I&C systems that performcategory A functions;b) to additionally require the implementation of independent I&C systems to overcome CCF,while the likelihood of CCF is reduced by strictly applying the overall safety principles ofIEC SC 45A (notably IEC 61226, IEC 61513, IEC 60880 and IEC 60709);c) to give an overview of the complete scope of requirements relevant to CCF, but not tooverlap with fields already addressed in other standards. These are referenced.This standard emphasises the need for the complete and precise specification of the safetyfunctions, based on the analysis of design basis accidents and consideration of the main plantsafety goals. This specification is the pre-requisite for generating a comprehensive set ofdetailed requirements for the design of I&C systems to overcome CCF.This standard provides principles and requirements to overcome CCF by means which ensureindependence2:a) between I&C systems performing diverse safety functions within category A whichcontribute to the same safety target;b) between I&C systems performing different functions from different categories if e.g. acategory B function is claimed as back-up of a category A function and;c) between redundant channels of the same I&C system.The implementation of these requirements leads to various types of defence against initiatingCCF events.Means to achieve protection against CCF are discussed in this standard in relation to:a) susceptibility to internal plant hazards and external hazards;b) propagation of physical effects in the hardware (e.g. high voltages); andc) avoidance of specific faults and vulnerabilities within the I&C systems notably:1) propagation of functional failure in I&C systems or between different I&C systems (e.g.by means of communication, fault or error on shared resources),2) existence of common faults introduced during design or during system operation (e.g.maintenance induced faults),3) insufficient system validation so that the system behaviour in response to input signaltransients does not adequately correspond to the intended safety functions,4) insufficient qualification of the required properties of hardware, insufficient verificationof software components, or insufficient verification of compatibility between replacedand existing system components.
信息：ICS：27.120.20 CCS：F09;F69 发布：2007-12 实施：

ASTM D7282-14 放射性测量用仪器的设置、校准和质量控制的标准实施规程
简介：
信息：ICS：17.240 CCS：发布：2014-06-01 实施：

NF C19-205-2010 核电站.仪器和控制对安全的重要性.仪表和控制功能分类.
简介：
信息：ICS：27.120.20 CCS：F82 发布：2010-07-01 实施：2010-07-09

IEC 60987:2007 核电站 - 对安全重要的仪器和控制 - 基于计算机的系统的硬件设计要求
简介：
信息：ICS：27.120.20 CCS：发布：2007-08-27 实施：