xrf哪些检测标准xrf哪些-中析研究所检测

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xrf哪些相关标准参考信息

ASTM E3295-22 法医聚合物检查中使用微X射线荧光（μ-XRF）的标准指南
简介：
信息：ICS： CCS：发布：2022-11-01 实施：

ISO/TR 18336-2016 铁矿业良好XRF实验室实施规程指南
简介：
信息：ICS：73.060.10 CCS：发布：2016-02-00 实施：

ISO 12677-2011 用X射线荧光对耐火产品(XRF)进行化学分析.熔铸珠法
简介：
信息：ICS：81.080 CCS：Q40 发布：2011-10 实施：

ASTM D6502-10(2022) 用X射线荧光（XRF）测量工艺水中低水平悬浮固体和离子固体的在线综合样品的标准试验方法
简介：
信息：ICS：13.060.50 CCS：发布：2022-11-01 实施：

ASTM E2119-2016 采用现场便携式X射线荧光 (XRF) 设备对油漆或者其他涂料中铅含量进行原位测量的质量系统标准实施规程
简介：5.1x00a0;This practice provides procedures to generate and document QC data for ensuring that an XRF is operating within acceptable tolerances throughout the testing period when being used to collect lead results during a lead-based pain (LBP) inspection for the purposes of generating lead classification results. 5.2x00a0;This practice is intended to supplement XRF instrument manufacturer protocols and Performance Characteristic Sheets (PCSs)4 through the use of QA and QC procedures to provide uniform lead testing practices among the wide variety of available field-portable XRF instruments. 5.3x00a0;While the QC results collected using this practice can provide assurances that an XRF instrument is operating within acceptable tolerances, this practice does not determine an actual level of confidence for a classification result obtained from an XRF measurement. 5.4x00a0;This practice does not address selection of test locations or representative sampling for leaded paint. Additional information on conducting measurements of lead in leaded paint or other coatings may be found in the HUD Guidelines, Chapter 7. 5.5x00a0;This practice involves the use of field-portable XRF instruments that may contain radioactive materials that emit X rays and gamma rays. These instruments are intended for use only by qualified, trained personnel. 5.6x00a0;The use of field-portable XRF instruments for measurement of lead may not accurately reveal low but still potentially hazardous levels of lead. 1.1x00a0;This practice covers the collection and documentation of quality control (QC) measurements for determining acceptable levels of instrumental performance when using field-portable energy-dispersive x-ray fluorescence spectrometry devices (XRFs) for the purposes of generating lead classification results from measurements on paint and other coating films within buildings and related structures. 1.2x00a0;QC procedures covered in this provisional practice include the performance of calibration checks, substrate bias checks, and specific instructions for documenting the collected data for later use in reporting the results. 1.3x00a0;No detailed operating instructions are provided because of differences among the various makes and models of suitable instruments. Instead, the analyst is to follow the instructions provided by the manufacturer of the particular XRF device or other relevant sources of information on XRF operation. 1.4x00a0;This practice contains notes which are explanatory and are not part of the mandatory requirements of this provisional practice. 1.5x00a0;The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard. 1.6x00a0;This standard does not purport to addre......
信息：ICS： CCS：发布：2016 实施：

ISO 12677:2011 用X射线荧光（XRF）对耐火制品进行化学分析——熔铸珠法
简介：
信息：ICS：81.080 CCS：发布：2011-09-26 实施：

FZ/T 01163-2022 纺织品及其附件总铅和总镉含量的测定 X射线荧光光谱（XRF）分析法
简介：
信息：ICS：59.080.01 CCS：发布：2022-04-08 实施：2022-10-01

ASTM D6502-10(2015) 通过X射线荧光（XRF）测量过程水中低浓度悬浮固体和离子固体的在线综合样品的标准测试方法
简介：
信息：ICS：13.060.50 CCS：发布：2015-04-01 实施：

ASTM C1508-01(2011) 用X射线荧光（XRF）光谱法测定UF₆和硝酸铀酰中溴和氯的标准试验方法
简介：
信息：ICS：71.040.50 CCS：发布：2011-06-01 实施：

ISO 22863-4:2021 焰火.特殊化学物质测定的试验方法.第4部分:用X射线荧光光谱法（XRF）分析铅和铅化合物
简介：
信息：ICS：71.100.30 CCS：发布：2021-03-17 实施：

DIN EN 15063-1-2015 铜和铜合金.用波长色散X-射线荧光光谱法(XRF)测定主要成分和杂质.第1部分:常规方法的指导方针;德文版本EN 15063-1-2014
简介：
信息：ICS：77.040.20;77.120.30 CCS：H26;H62 发布：2015-03 实施：

EN ISO 12677-2011 通过荧光分析(XRF)进行耐火制品的化学分析
简介：This International Standard specifies a method for the chemical analysis of refractory and technical ceramicraw materials, intermediates and products, by means of the X-ray fluorescence (XRF) fused cast-beadmethod. Typical materials that can be analysed byThis standard are given in Clause 3.This InternationalStandard is not applicable to non-oxide materials, such as silicon carbides or nitrides, etc. The method isapplicable to a wide range of materials containing a wide range of elements.
信息：ICS：81.080 CCS：发布：2011 实施：

ASTM D5381-93(2021) 颜料和填充剂的X射线荧光（XRF）光谱的标准指南
简介：
信息：ICS：87.060.10 CCS：发布：2021-02-01 实施：

NF A08-701-1-2015 铜和铜合金.用波长分布X-射线荧光光谱法(XRF)测定主要结构和杂质.第1部分:常规测量指南
简介：La présente Norme européenne fournit des lignes directrices sur les concepts et les modes opératoires d'étalonnage et d'analyse du cuivre et des alliages de cuivre par spectrométrie de fluorescence X à dispersion en longueur d'onde.
信息：ICS：77.120.30 CCS：H62;H13 发布：2015-02-14 实施：2015-02-14

ASTM D6502-10 通过X射线荧光（XRF）测量过程水中低浓度悬浮固体和离子固体的在线综合样品的标准测试方法
简介：
信息：ICS：13.060.50 CCS：发布：2010-05-01 实施：

ASTM E2119-20 使用现场便携式X射线荧光（XRF）器件对涂料或其他涂料中铅含量进行原位测量的质量体系标准实践
简介：
信息：ICS：13.080.10 CCS：发布：2020-09-01 实施：

BS EN 15063-1-2014 铜和铜合金.用波长色散X射线荧光光谱测定法(XRF)测定主要元素和杂质.常规方法指南
简介：
信息：ICS：77.040.20;77.120.30 CCS：H62 发布：2014-12-31 实施：2014-12-31

DIN 51001 Bb.1-2010 氧化原材料和基础材料测试.X射线荧光法(XRF)测试通用基础.XRF试样测定用材料分组方法总则
简介：
信息：ICS：71.060.20 CCS：G13 发布：2010-05 实施：

KS D ISO 17054-2018 通过X射线荧光光谱法（XRF）分析高合金钢的常规方法
简介：
信息：ICS：77.080.20 CCS：发布：2018-12-28 实施：

ASTM D7085-04(2010)e1 用X射线荧光光谱法（XRF）测定流体催化裂化催化剂中化学元素的标准指南
简介：
信息：ICS：71.040.50 CCS：发布：2010-04-01 实施：

ASTM D7085-04(2018) 用X射线荧光光谱法（XRF）测定流体催化裂化催化剂中化学元素的标准指南
简介：
信息：ICS：71.040.50 CCS：发布：2018-11-01 实施：

EN 15063-1-2014 铜及铜合金.用波长分散X光线荧光光谱法(XRF)测定主要成分及杂质.第1部分:日常方法指南
简介：This European Standard provides guidance on the concepts and procedures for the calibration and analysis of copper and copper alloys by wavelength dispersive X-ray fluorescence spectrometry.
信息：ICS：77.040.20;77.120.30 CCS：H62 发布：2014-12 实施：

ISO 17054:2010 通过X射线荧光光谱法（XRF）分析高合金钢的常规方法
简介：
信息：ICS：77.080.20 CCS：发布：2010-02-02 实施：

ASTM C1456-13(2018) 用于测定钆/钆（或两者）在氧化钆 - 氧化铀丸或X射线荧光（XRF）中的标准测试方法
简介：
信息：ICS：27.120.30 CCS：发布：2018-11-01 实施：

ASTM C1456-13 用于测定钆/钆（或两者）在氧化钆 - 氧化铀丸或X射线荧光（XRF）中的标准测试方法
简介：
信息：ICS：27.120.30 CCS：发布：2013-07-01 实施：

ISO 17054-2010 用X射线荧光光谱法(XRF)近似技术分析高合金钢的常规方法
简介：This European Standard specifies a procedure on how to improve the performance of a routine XRF method,already in use for analysis of high alloy steels, by using a ”near by technique”.The ”near by technique” requires at least one target sample (preferable a CRM) of a similar composition asthe unknown sample.
信息：ICS：77.080.20 CCS：H26 发布：2010-02 实施：

ISO 16169:2018 用ISO 12677 X射线荧光法（XRF）制备分析用碳化硅和类似材料-熔铸珠法
简介：
信息：ICS：81.080 CCS：发布：2018-07-26 实施：

ASTM F2980-13 用现场便携式X射线荧光（XRF）分析玻璃中重金属的标准试验方法
简介：
信息：ICS：81.040.10 CCS：发布：2013-02-15 实施：

DIN 51399-2-2010 润滑剂试验.添加剂中元素的含量、磨损和其他污染物的测定.第2部分:波长色散X射线荧光光谱法(XRF)
简介：This document specifies a method for direct detemination of elements content in lubricants, which derive from the additive fraction, wear and other contaminations. The determination is effected by XRF.
信息：ICS：75.100 CCS：E34 发布：2010-01 实施：

ASTM C1508-18 用X射线荧光（XRF）光谱法测定UF6和硝酸铀酰中溴和氯的标准试验方法
简介：
信息：ICS：71.040.50 CCS：发布：2018-06-01 实施：

DIN EN ISO 12677-2013 耐火制品的X射线荧光(XRF)化学分析方法.熔铸珠法(ISO 12677-2011).德文版本EN ISO 12677-2011
简介：This International Standard specifies a method for the chemical analysis of refractory and technical ceramic raw materials,intermediates and products,by means of the X-ray fluorescence (XRF) fused cast-bead method. Typical materials that can be analysed by this standard are given in Clause 3. This International Standard is not applicable to non-oxide materials,such as silicon carbides or nitrides,etc. The method is applicable to a wide range of materials containing a wide range of elements.
信息：ICS：81.080 CCS：Q40 发布：2013-02 实施：

ASTM D6502-2010(2015) 利用X射线荧光 (XRF) 测量生产用水中低水平悬浮固体和离子固体即时整合样品的标准试验方法
简介：5.1x00a0;Corrosion products, in the form of particulate and dissolved metals, in the steam and water circuits of electricity generating plants are of great concern to power plant operators. Aside from indicating the extent of corrosion occurring in the plant, the presence of corrosion products has deleterious effects on plant integrity and efficiency. Deposited corrosion products provide sites at which chemicals, which are innocuous at low levels, may concentrate to corrosive levels and initiate under-deposit corrosion. Also, corrosion products in feedwater enter the steam generating components where deposition on heat transfer surfaces reduces the overall efficiency of the plant. 5.2x00a0;Most plants perform some type of corrosion product monitoring. The most common method is to sample for long time periods, up to several days, after which laboratory analysis of the collected sample gives the average corrosion product level over the collection time period. This methodology is referred to as integrated sampling. With the more frequent measurements in the on-line monitor, a time profile of corrosion product transport is obtained. Transient high corrosion product levels can be detected and measured, which cannot be accomplished with integrated sampling techniques. With this newly available data, plant operators may begin to correlate periods of high corrosion product levels with controllable plant operating events. In this way, operators may make more informed operational decisions with respect to corrosion product generation and transport. 1.1x00a0;This test method covers the operation, calibration, and data interpretation for an on-line corrosion product (metals) monitoring system. The monitoring system is based on x-ray fluorescence (XRF) analysis of metals contained on membrane filters (for suspended solids) or resin membranes (for ionic solids). Since the XRF detector is sensitive to a range of emission energy, this test method is applicable to simultaneous monitoring of the concentration levels of several metals including titanium, vanadium, chromium, manganese, iron, cobalt, nickel, copper, zinc, mercury, lead, and others in a flowing sample. A detection limit below 1 ppb can be achieved for most metals. 1.2x00a0;This test method includes a description of the equipment comprising the on-line metals monitoring system, as well as, operational procedures and system specifications. 1.3x00a0;The values stated in SI units are to be regarded as standard. No other units of measurement are included in this 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：13.060.50 CCS：发布：2010 实施：

EJ/T 20161-2018 乏燃料后处理溶解液中铀、钚的测定混合KED/XRF法
简介：
信息：ICS：27.120.30 CCS：F48 发布：2018-01-18 实施：2018-05-01

ASTM F2980-2013 用现场便携式X射线荧光 (XRF) 分析玻璃种重金属的标准试验方法
简介：5.1x00a0;Waste glass is currently recycled into various consumer products. This test method has been developed as a tool for evaluation of heavy metals in glass to satisfy reporting requirements for maximum allowable content for some applications. 5.2x00a0;The ranges within which this test method is quantitative are given in Table 1. 5.3x00a0;For amounts of the analyte elements outside the ranges in Table 1, this test method provides screening results. That is, it provides an unambiguous indication that each element can be described as present in an amount greater than the scope upper limit or that the amount of the element can be described as less than the scope lower limit with a high degree of confidence.Note 2x2014;In general, when a quantitative result is obtained, the analyst can make a clear decision as to whether a material is suitable for the intended purpose. When the contents of elements of interest are outside the quantitative range, the analyst can still make a decision whether the amount is too high or whether additional analyses are required. 5.4x00a0;These methods can be applied to glass beads, plate glass, float glass, fiber glass, or ground glass. This test method has been validated for the ranges of matrix compositions that are summarized in Table 2.TABLE 2 Matrix Components and Ranges Oxide Scope Lower Limit, % Scope Upper Limit, % SiO2 58 80 Al2O3 1 10 Na2O 3
信息：ICS：81.040.10 (Raw materials and raw glass) CCS：发布：2013 实施：

BS EN 10315-2006 临近技术使用的X射线荧光光谱法(XRF)高合金钢分析的常规方法
简介：This European Standard specifies a procedure on how to improve the performance of a routine XRF method,already in use for analysis of high alloy steels, by using a ”near by technique”.The ”near by technique” requires at least one target sample (preferable a CRM) of a similar composition asthe unknown sample.The method is applicable to analysis of either chill-cast or wrought samples having a diameter of at least25 mm and with a carbon concentration of less than 0,3 % (see NOTE). Other elements should have aconcentration below 0,2 %.NOTE High carbon concentrations, in combination with high Mo and Cr concentrations, could have undesirablestructural effects on the sample and could affect the determination of phosphorus and chromium, in particular.Matrix effects exist between the elements listed. To compensate for those inter-element effects, mathematicalcorrections shall be applied. A variety of computer programs for corrections is commonly used and included inthe software package from the manufacturers.
信息：ICS：77.040.30;77.140.20 CCS：H11 发布：2009-09-30 实施：2009-09-30

EJ/T 20161-2018 乏燃料后处理溶解液中铀、钚的测定混合KED/XRF法
简介：
信息：ICS：27.120.30 CCS：F48 发布：2018-01-18 实施：2018-05-01

ASTM E2926-2013 采用微束X射线荧光(微束XRF)光谱法对玻璃进行鉴识对比的标准试验方法
简介：4.1x00a0;x00b5;-XRF provides a means of simultaneously detecting major, minor, and trace elemental constituents in small glass fragments such as those frequently examined in forensic case work. It can be used at any point in the analytical scheme without concern for changing sample shape or sample properties, such as RI, due to its totally nondestructive nature. 4.2x00a0;Limits of detection (LOD) are dependent on several factors, including instrument configuration and operating parameters, sample thickness, and atomic number of the individual elements. Typical LODs range from parts per million (x00b5;gg-1) to percent (%). 4.3x00a0;x00b5;-XRF provides simultaneous qualitative analysis for elements having an atomic number of eleven or greater. This multi-element capability permits detection of elements typically present in glass such as magnesium (Mg), silicon (Si), aluminum (Al), calcium (Ca), potassium (K), iron (Fe), titanium (Ti), strontium (Sr), and zirconium (Zr), as well as other elements that may be detectable in some glass by x00b5;-XRF (for example, molybdenum (Mo), selenium (Se), or erbium (Er)) without the need for a predetermined elemental menu. 4.4x00a0;x00b5;-XRF comparison of glass fragments provides additional discrimination power beyond that of RI or density comparisons, or both, alone. 4.5x00a0;The method precision should be established in each laboratory for the specific conditions and instrumentation in that laboratory. 4.6x00a0;When using small fragments having varying surface geometries and thicknesses, precision deteriorates due to take-off-angle and critical depth effects. Flat fragments with thickness greater than 1.5 mm do not suffer from these constraints, but are not always available as questioned specimens received in casework. As a consequence of the deterioration in precision for small fragments and the lack of appropriate calibration standards, quantitative analysis by x00b5;-XRF is not typically used. 4.7x00a0;Appropriate sampling techniques should be used to account for natural heterogeneity of the material, varying surface geometries, and potential critical depth effects. 4.8x00a0;Inductively Coupled Plasma-Optical Emission Spectrometry (ICP-OES) and Inductively Coupled Plasma-Mass Spectrometry (ICP-MS) may also be used for trace elemental analysis of glass and offer lower minimum detection levels and the ability for quantitative analysis. However, these methods are destructive, and require larger sample sizes and much longer sample preparation times (Test Method E2330). 4.9x00a0;Laser Ablation-Inductively Coupled Plasma-Mass Spectrometry (LA-ICP-MS) uses comparable specimen sizes to those used for x00b5;-XRF but offers better LODs, quantitative capability and less analysis time. LA-ICP-MS drawbacks are greater instrument cost and complexity of operation. 4.10x00a0;Scanning Electron Microscopy with EDS (SEM-EDS) is also available for elemental analysis, but it is of limited use for forensic glass source discrimination due to poor detection limits for higher atomic number elements present in glass at trace concentration levels. However, discrimination of sources that have indistinguishable RIs and densities may be possible. 1.1x00a0;This test method is for the determination of major, minor, and trace elements present in glass fragments. The elemental composition of a......
信息：ICS：81.040.10 (Raw materials and raw glass) CCS：Q30 发布：2013 实施：

ASTM D5381-93(2009) 颜料和填充剂的X射线荧光（XRF）光谱的标准指南
简介：
信息：ICS：87.060.10 CCS：发布：2009-02-01 实施：

ASTM F2980-13(2017) 用现场便携式X射线荧光（XRF）分析玻璃中重金属的标准试验方法
简介：
信息：ICS：81.040.10 CCS：发布：2017-11-01 实施：

GOST R 55410-2013 耐火材料. X射线荧光(XRF)分析
简介：
信息：ICS：81.080 CCS：发布：2013 实施：2014-06-01

ASTM C1456-08 用X射线荧光法（XRF）测定氧化钆铀氧化物芯块中铀或钆或两者的标准试验方法
简介：
信息：ICS：27.120.30 CCS：发布：2008-12-01 实施：

ASTM D8127-17e1 使用用于在线润滑剂的X射线荧光（XRF）的耦合颗粒和元素分析的标准测试方法
简介：
信息：ICS：75.100 CCS：发布：2017-07-01 实施：

ASTM C1456-2013 用X射线荧光法(XRF)测定氧化钆和氧化铀颗粒中铀或钆(或者两者)的试验方法
简介：5.1x00a0;This test method is applicable to samples containing 1 to 108201;% gadolinium oxide and 90 to 998201;% uranium oxide on the x201c;as receivedx201d; basis. The method may be used to determine concentration of either uranium, gadolinium, or both. 5.2x00a0;Either wavelength-dispersive or energy-dispersive X-ray fluorescence systems may be used provided the software accompanying the system is able to accommodate the use of internal standards. 1.1x00a0;This test method describes the steps necessary for the preparation and analysis by X-ray fluorescence (XRF) of gadolinium or uranium (or both) in gadolinium oxide-uranium oxide pellets or powders. 1.2x00a0;This test method requires the use of appropriate internal standard(s). Care must be taken to ascertain that samples analyzed by this method do not contain the internal standard element(s) or that this contamination has been corrected for mathematically whenever present. Such corrections are not addressed in this test method. 1.3x00a0;This standard contains notes that are explanatory and are not part of the mandatory requirements of the standard. 1.4x00a0;The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard. 1.5x00a0;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. Specific precautions are given in Section 8 and various notes throughout the method.
信息：ICS：27.120.30 (Fissile materials and nuclear fuel tech CCS：发布：2013 实施：

DIN 51418-1-2008 X射线光谱测定法.X射线散射和X射线荧光分析(XRF).第1部分:定义和基本原理
简介：
信息：ICS：01.040.71;71.040.50 CCS：N54 发布：2008-08 实施：

ASTM D8127-17 使用用于在线润滑剂的X射线荧光（XRF）的耦合颗粒和元素分析的标准测试方法
简介：
信息：ICS：75.100 CCS：发布：2017-07-01 实施：

ASTM F2980-2013(2017) 用现场便携式X射线荧光(XRF)分析玻璃种重金属的标准试验方法
简介：5.1x00a0;Waste glass is currently recycled into various consumer products. This test method has been developed as a tool for evaluation of heavy metals in glass to satisfy reporting requirements for maximum allowable content for some applications. 5.2x00a0;The ranges within which this test method is quantitative are given in Table 1. 5.3x00a0;For amounts of the analyte elements outside the ranges in Table 1, this test method provides screening results. That is, it provides an unambiguous indication that each element can be described as present in an amount greater than the scope upper limit or that the amount of the element can be described as less than the scope lower limit with a high degree of confidence. Note 2:x00a0;In general, when a quantitative result is obtained, the analyst can make a clear decision as to whether a material is suitable for the intended purpose. When the contents of elements of interest are outside the quantitative range, the analyst can still make a decision whether the amount is too high or whether additional analyses are required. 5.4x00a0;These methods can be applied to glass beads, plate glass, float glass, fiber glass, or ground glass. This test method has been validated for the ranges of matrix compositions that are summarized in Table 2. 5.5x00a0;Detection limits, sensitivity, and element ranges will vary with matrices, detector type, and other instrument conditions and parameters. 5.6x00a0;All analytes are determined as the element and reported as such. These include all elements listed in Table 1. This test method may be applicable to other glass matrices, additional elements, and wider concentration ranges provided the laboratory is able to validate the broadened scope of this test method. 1.1x00a0;This test method covers field portable X-ray fluorescence (XRF) spectrometric procedures for analyses of arsenic and lead in glass compositions using field portable energy dispersive XRF spectrometers. 1.2x00a0;The mass fraction range of arsenic within which this test method is quantitative is given in Table 1. Scope limits were determined from the interlaboratory study results using the approach given in Practice E1601. 1.3x00a0;The mass fraction range for which lead was tested is given in Table 1. However, lead results cannot be considered quantitative on the basis of single-sample results because the precision performance is not good enough to allow laboratories to compare results in a quantitative manner. Note 1:x00a0;
信息：ICS：81.040.10 CCS：Q37 发布：2013 实施：

ASTM D6502-08 用X射线荧光（XRF）连续测量工艺水中低水平可过滤物质（悬浮固体）和不可过滤物质（离子固体）的在线复合样品的标准试验方法
简介：
信息：ICS：13.060.50 CCS：发布：2008-05-01 实施：

ASTM D8127-2017 利用X射线荧光(XRF)对在用润滑剂进行颗粒物和元素耦合分析的标准试验方法
简介：5.1 It has been shown in many industries that separating information regarding small or dissolved elemental materials in the lubricant from suspended particulate is crucial. In many cases only an overall elemental analysis is provided, which may not capture significant wear or even machinery failure events. Such events are often accompanied by a sudden increase in the production of large particulate, which is suspended in and can be detected in the machineryx2019;s lubricant. This test method specifically targets such particulate, which has historically been difficult to quantify. Users of the technique include numerous military organizations, and maintainers of wind turbines, nuclear power facilities, and offshore rigs. 1.1x00a0;This automatic wear particle analysis2 test method for in-service lubricants describes using a combination of pore blockage particle counting and energy dispersive X-ray fluorescence (EDXRF) spectrometry for the quantitative determination of solid particle counts larger than four (4) micrometres, and elemental content of suspended particulate of iron (Fe) and copper (Cu) in such lubricants. 1.2x00a0;This test method provides for the determination of the elemental content of suspended particulate of Fe greater than 48201;x03bc;m in the range of 6 mg/kg to 223 mg/kg. Suspended particulate of copper greater than 48201;x03bc;m is determined in the range of 3.5 mg/kg to 92.4 mg/kg in the lubricant. Total particle count greater than 48201;x03bc;m is determined in the range of 118201;4958201;particles/mL greater than 48201;x03bc;m to 28201;1698201;5008201;particles/mL greater than 48201;x03bc;m in the lubricant. 1.3x00a0;This test method is applicable to all known in-service lubricants (API Groups I-V) at any stage of degradation. 1.4x00a0;This test method uses an empirical inter-element correction methodology. 1.5x00a0;The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard. 1.6x00a0;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. 1.7x00a0;This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.
信息：ICS：75.100 CCS：E34 发布：2017 实施：

DIN EN ISO 12677-2012 耐火制品的X射线荧光(XRF)化学分析方法.熔铸珠法(ISO 12677-2011).德文版 EN ISO 12677-2011
简介：
信息：ICS：81.080 CCS：Q40 发布：2012-01 实施：

ASTM C1456-2008 用X射线荧光法(XRF)测定氧化钆和氧化铀颗粒中铀或钆或者两者的试验方法
简介：This test method is applicable to samples containing 2 to 10 % gadolinium oxide and 90 to 98 % uranium oxide on the x201C;as receivedx201D; basis. The method may be used to determine concentration of either uranium, gadolinium, or both. Either wavelength-dispersive or energy-dispersive X-ray fluorescence systems may be used provided the software accompanying the system is able to accommodate the use of internal standards.1.1 This test method describes the steps necessary for the preparation and analysis by X-ray fluorescence (XRF) of gadolinium or uranium (or both) in gadolinium oxide-uranium oxide pellets or powders. 1.2 This test method requires the use of appropriate internal standard(s). Care must be taken to ascertain that samples analyzed by this method do not contain the internal standard element(s) or that this contamination has been corrected for mathematically whenever present. Such corrections are not addressed in this test method. 1.3 This standard contains notes that are explanatory and are not part of the mandatory requirements of the standard. 1.4 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard. 1.5 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. Specific precautions are given in Section 8 and various notes throughout the method.
信息：ICS：27.120.30 (Fissile materials and nuclear fuel tech CCS：F46 发布：2008 实施：

ASTM E2119-16 使用现场便携式X射线荧光（XRF）器件对涂料或其他涂料中铅含量进行原位测量的质量体系标准实践
简介：
信息：ICS：13.080.10 CCS：发布：2016-03-01 实施：

GOST R 55080-2012 铸铁. X射线荧光光谱(XRF)分析法
简介：
信息：ICS：77.080.10 CCS：发布：2012 实施：2014-01-01

VDI 2267 Blatt 12-2007 Determination of suspended matter in ambient air - Measurement of As@ Ca@ Cd@ Co@ Cr@ Cu@ Fe@ Mn@ Ni@ Pb@ Sb and Zn by energy dispersive X-ray fluorescense (ED XRF)
简介：
信息：ICS：/ CCS：/ 发布：2007-07-01 实施：2011-05-10

ISO/TR 18336:2016 铁矿石行业良好XRF实验室实践指南
简介：
信息：ICS：73.060.10 CCS：发布：2016-02-11 实施：

NF B40-677-2011 X射线荧光法(XRF)对耐火产品进行化学分析.铸珠熔融法.
简介：
信息：ICS：81.080 CCS：Q40 发布：2011-11-01 实施：2011-11-26

DIN EN 15063-1-2007 铜和铜合金.用波长色散X-射线荧光光谱法(XRF)测定主要成分和杂质.第1部分:常规方法的指导方针
简介：This part of this European Standard provides guidance on the concepts and procedures for the calibration and analysis of copper and copper alloys by wavelength dispersive X-ray fluorescence spectrometry.
信息：ICS：77.040.20;77.120.30 CCS：H26;H62 发布：2007-01 实施：

ISO/TR 18336-2016 铁矿业良好XRF实验室实施规程指南
简介：
信息：ICS：73.060.10 CCS：D31 发布：2016-02-01 实施：

BS EN ISO 12677-2011 通过荧光分析(XRF)进行耐火制品的化学分析
简介：
信息：ICS：81.080 CCS：Q40 发布：2011-10-31 实施：2011-10-31

DIN EN 15063-2-2007 铜和铜合金.用波长色散X-射线荧光光谱法(XRF)测定主要成分和杂质.第2部分:常规方法
简介：This part of this European Standard specifies a routine method for analysing copper and copper alloys by wavelength dispersive X-ray fluorescence spectrometry.The method is applicable to:— all elements detectable by XRF: impurities, minor and main constituents;— analysis of either unwrought, including chill-cast or wrought products.
信息：ICS：77.040.20;77.120.30 CCS：H26;H62 发布：2007-01 实施：