71.060.99 其他无机化学品 标准查询与下载

T/SDSCCE 022-2022 碘化亚铜

本文件规定了碘化亚铜的要求、试验方法、检验规则及标志和随行文件、包装、运输、贮存。 本文件适用以硫酸铜、碘化钾、亚硫酸钠为原料或以精碘、纯铜粉为原料生产的碘化亚铜。

Cuprous iodide

T/CPCIF 0163-2021 工业硫酰氯

项    目　指    标 　优级品　一级品　合格品 色度（K2CrO4）                       ≤　1#　2#　3# 68 ℃～70 ℃馏出的体积分数a，φ/%      ≥　98.0　97.0　96.0 蒸馏残留物，w/%                      ≤　0.005　0.010　0.30 a  68 ℃～70 ℃馏出的体积分数是表征硫酰氯含量的指标，也可以参考附录A方法直接测定硫酰氯含量，具体  要求可由供需双方协商。

Sulfuryl chloride for industrial use

T/CPCIF 0169-2021 锂电池废料回收产物 电极材料粉

项    目　指    标 　Ⅰ  类　Ⅱ  类　Ⅲ  类 　一  型　二  型　　一  型　二  型 镍钴合量（Ni＋Co）w/%         ≥　35.0　16.0　—　＜0.02　— 锰（Mn）w%                   ≤　18.0　15.0　≥35.0　＜0.1　— 锂（Li）a w/%                   ≥　5.0　3.0　4.0　3.0　2.0 铜（Cu）w/%                   ≤　2.0　3.0　1.0　0.1　2.0 铁（Fe）w%                    ≤　0.5　2.0　0.1　≥27.0　≥17.0 铝（Al）w%                    ≤　1.0　4.0　1.5　0.3　3.8 氟（F）w%                     ≤　0.1　0.5　0.1　—　— 磷（P）w%                     ≥　—　—　—　15.0　10.0 铅（Pb）w%                    ≤　0.005　0.02　0.005　0.005　0.005 镉（Cd）w/%                   ≤　0.005　0.02　0.005　0.005　0.005 铬（Cr）w%                    ≤　0.005　0.01　0.005　0.005　0.005 粒径/mm                       ≤　0.25　0.25　0.25　0.25　0.25 a  如为采用优先提锂工艺的Ⅰ类产品，其锂指标参数可供需协商确定。

Recycling products from lithium-ion battery wastes— Selected electrode material powder

T/NAHIEM 40-2021 纳米银及其制品抗菌除味性能评价

本文件规定了纳米银材料及其制品的抗菌除味性能的评价技术要求、试验方法。

Antibacterial and deodorizing performance evaluation of nano silver and its products

T/ZZB 2292-2021 纳米银抗菌溶液

本文件规定了纳米银抗菌溶液的术语和定义、基本要求、技术要求、试验方法、检验规则、标志、包装、运输、贮存、质量证明书和质量承诺。 本文件适用于以水为溶剂制成的纳米银抗菌溶液。

Antibacterial solution containing silver

T/SHXCL 0006-2021 特种光学材料用氟化物

本文件规定了特种光学材料用氟化物（以下简称氟化物）的分类、要求、试验方法、检验规则及标志、包装、运输、贮存。 本文件适用于氟化钙、氟化钡、氟化锶、氟化铝。

The fluoride for special optical material

T/SHXCL 0003-2021 无机金属离子抗菌抗病毒添加剂

本文件规定了无机金属离子抗菌抗病毒添加剂（以下简称添加剂）的术语和定义、技术要求、试验方法、检验规则及标志、包装、运输、贮存。 本文件适用于以磷酸锆或玻璃等无机微纳米材料为载体，负载银、锌、铜、银锌等无机金属离子，具有抗菌抗病毒功能组分（结构单元）的粉末类材料添加剂，可应用于纤维、织物、薄膜、塑料、涂料和陶瓷等。其他材料的抗菌抗病毒添加剂也可以参照本文件执行。

Inorganic metal-ion antibacterial and antiviral additives

KS M ISO 7103:2017 工业用液化无水氨 取样 实验室取样

Liquefied anhydrous ammonia for industrial use — Sampling — Taking a laboratory sample

KS M ISO 7103-2017(2022) 工业用液化无水氨.取样.实验室取样

Liquefied anhydrous ammonia for industrial use — Sampling — Taking a laboratory sample

KS M ISO 7106:2017 工业用液化无水氨 油含量的测定 重量法和红外光谱测定法

Liquefied anhydrous ammonia for industrial use — Determination of oil content — Gravimetric and infra-red spectrometric methods

KS M ISO 7106-2017(2022) 工业用液化无水氨.油含量的测定.重量法和红外光谱法

Liquefied anhydrous ammonia for industrial use — Determination of oil content — Gravimetric and infra-red spectrometric methods

KS M ISO 7105:2017 工业用液化无水氨 水含量的测定 卡尔 费歇尔（KarlFischer）法

Liquefied anhydrous ammonia for industrial use — Determination of water content — Karl Fischer method

KS M ISO 7106-2017 工业用液化无水氨 - 油含量的测定 - 重量和红外光谱测定方法

Liquefied anhydrous ammonia for industrial use — Determination of oil content — Gravimetric and infra-red spectrometric methods

KS M ISO 7105-2017(2022) 工业用液化无水氨.水含量的测定.卡尔费休法

Liquefied anhydrous ammonia for industrial use — Determination of water content — Karl Fischer method

KS M ISO 7105-2017 用于工业用途的液化无水氨 - 含水量的测定 - 卡尔费休法

Liquefied anhydrous ammonia for industrial use — Determination of water content — Karl Fischer method

KS M ISO 7103-2017 用于工业用途的液化无水氨 - 取样 - 取实验室样品

Liquefied anhydrous ammonia for industrial use — Sampling — Taking a laboratory sample

GSO IEC/TR 62010:2017 分析仪系统 维护管理

1.1 Purpose This document is written with the intention of providing an understanding of analyser maintenance principles and approaches. It is designed as a reference source for individuals closely involved with maintenance of analytical instrumentation, and provides guidance on performance target setting, strategies to improve reliability, methods to measure effective performance, and the organisations, resources and systems that need to be in place to allow this to occur. Effective management of on-line analysers is only possible when key criteria have been identified and tools for measuring these criteria established. On-line analysers are used in industry for the following reasons: • Safety and environmental. One category of on-line analyser is those used to control and monitor safety and environmental systems. The key measured parameter for this category of analyser is on-line time. This is essentially simpler to measure than an analyser’s contribution to profits but as with process analysers applied for profit maximisation, the contribution will be dependent upon ability to perform its functional requirements on demand. • Asset protection and profit maximisation. On-line analysers falling into this category are normally those impacting directly on process control. They can impact directly on protection of assets (e.g. corrosion, catalyst contamination) or product quality, or can be used to optimise the operation of the process (e.g. energy efficiency). For this category of analysers, the key measured parameter is either the cost of damage to plant or the direct effect on overall profit of the process unit. Justification as to whether an analyser is installed on the process can be sought by quantifying the payback time of the analyser, the pass/fail target typically being 18 months. The contribution of the analyser to reduction in extent of damage to, or the profit of, the process unit, is difficult to measure. However, this contribution will be dependent upon the analyser’s ability to perform its functional requirements upon demand. This document focuses on the cost/benefits associated with traditional analyser maintenance organisations. Due to the complexity of modern analysers, support can be required from laboratory or product quality specialists, for example for chemometric models, who can work for other parts of the organisation. Inclusion of their costs in the overall maintenance cost is therefore important. 1.2 Questions to be addressed When considering on-line analyser systems and their maintenance, the following key points list is useful in helping decide where gaps exist in the maintenance strategy. • What is the uptime of each critical analyser? Do you measure uptime and maintain records? Do you know the value provided by each analyser and therefore which ones are critical? Do you meet regularly with operations (‘the customer’) to review priorities? • What is the value delivered by each analyser in terms of process performance improvement (i.e. improved yield values, improved quality, improved manufacturing cycle time and/or process cycle time, process safety (e.g. interlocks), environmental importance)? Is this information readily available and agreed to in meetings with operations? Is the value updated periodically? This is a preview - click here to buy the full publication – 10 – IEC TR 62010:2016  IEC 2016 • What is the utilisation of each critical analyser? That is, if the analyser is used in a control loop, what percentage of the time is the loop on manual due to questions about the analyser data? Do you keep records on the amount of time that analyser loops are in automatic? Do you meet regularly with operations to review the operator’s views about the plausibility of the analyser data? • Do you have a regular preventive maintenance programme set up for each analyser which includes regular calibrations? Does the calibration/validation procedure include statistical process control (SPC) concepts – upper/lower limits and measurement of analyser variability (or noise)? Is the procedure well documented? Do you conduct it regularly, even when things are running well? • Do you have trained personnel (capable of performing all required procedures and troubleshooting the majority of analyser problems) who are assigned responsibility for the analysers? Do the trained personnel understand the process? Do they understand any lab measurements which relate to the analyser results? • Do the trained maintenance personnel have access to higher level technical support as necessary for difficult analyser and/or process problems? Do they have ready access to the individual who developed the application? Do they have ready access to the vendor? Can higher level support personnel connect remotely to the analyser to observe and troubleshoot? • Do you have a maintenance record keeping systems, which documents all activity involving the analysers, including all calibration/validation records, all repairs and/or adjustments? • Do you use the record keeping system to identify repetitive failure modes and to determine the root cause of failures? Do you track the average time-to-repair analyser problems? Do you track average time-between-failures for each analyser? • Do you periodically review the analysers with higher level technical resources to identify opportunities to significantly improve performance by upgrading the analyser system with improved technology or a simpler/more reliable approach? • Do you meet regularly with operations personnel to review analyser performance, update priorities, and understand production goals? • Do you have a management framework that understands the value of the analysers and are committed to and supportive of reliable analysers? • Do you know how much the maintenance programme costs each year and is there a solid justification for it? Consideration of the above questions will help to identify opportunities for continuously improving the reliability of installed process analysers. Once the opportunities are identified the following clauses are intended to give guidance in achieving the solutions with the aim of: • maximising performance and benefit of installed analysers; • achieving full operator confidence in the use of on-line analysers; • analyser output data becoming reliable enough to be used by operators, control systems, and other users, in order to improve plant operation versus world class manufacturing metrics to become the best process analysers possible.

Analyser systems - Maintenance management

T/ACREI 34001-2017 《盖板玻璃抛光用稀土抛光粉》

本标准规定了盖板玻璃抛光用稀土抛光粉的要求、试验方法、检验规则和标志、包装、运输、贮存及质量说明书。 本标准适用于钠硅酸盐体系盖板玻璃抛光用稀土抛光粉。

Rare earth polishing powder for cover glass polishing

BS PD IEC/TR 62010:2016 分析器系统.维护管理

Analyser systems. Maintenance management

GSO ISO 7103:2016 工业用液化无水氨 取样 实验室取样

This International Standard specifies the apparatus and the procedure to be used for taking a reprensentative laboratory sample* of liquefied anhydrous ammonia for industrial use, from a container (barrel, cylinder, tank, etc.).

Liquefied anhydrous ammonia for industrial use -- Sampling -- Taking a laboratory sample