ASTM D257-07 中文版 绝缘材料直流电阻和电导测试.…

ASTMD257概述ASTMD257是由美国材料和试验协会（ASTM）制定的一项标准，用于测试电绝缘材料的体积电阻率。

体积电阻率是一个重要的电气性能指标，它表示了材料在电场作用下的导电性能。

ASTMD257标准规定了测试方法和评估电绝缘材料体积电阻率的标准计算方法，广泛应用于电子、电气工业中。

测试方法ASTMD257标准定义了两种方法来测试电绝缘材料的体积电阻率，分别是方法A和方法B。

下面将详细介绍这两种方法的测试步骤。

方法A方法A是ASTMD257标准中推荐的主要测试方法，适用于大部分常见的电绝缘材料。

测试过程如下：1.准备试样：根据材料的特性和形状，选择合适的尺寸和形状的试样。

确保试样表面平整、无气孔和污染物。

2.测量试样尺寸：使用精确的测量工具，测量试样的长度、宽度和厚度。

尺寸测量精度对测试结果影响很大，因此需要严格控制。

3.准备电极：在试样的两端制作电极，可以使用导电涂料、金属箔等导电材料。

4.连接电极：将电极与试样固定连接，确保电极与试样之间的接触良好，并尽量减小接触电阻。

5.测量电阻：使用电阻计测量试样的电阻值。

在测试过程中，可以根据需要改变电场的大小和方向，以获得更准确的测试结果。

方法B方法B是ASTMD257标准中备用的测试方法，适用于某些特殊的电绝缘材料。

测试过程如下：1.准备试样：准备与方法A相同的试样。

2.准备电极：使用导电涂料、金属箔等导电材料，在试样两端制作电极。

3.连接电极：将电极与试样固定连接，确保接触良好。

4.测量体积电阻率：使用专用的体积电阻率测试仪器，测量试样的体积电阻率。

该仪器可以通过应用不同电场强度和时间来模拟实际工作条件下的电场效应。

结果评价根据ASTMD257标准规定，测试结果将以体积电阻率（单位：Ω·cm）的形式进行报告。

报告中应包括测试方法、测试条件、试样尺寸、测量数据和计算结果。

同时，还需要对测量结果进行评价和比较。

常见的评价方法包括：•与标准值对比：将测量结果与标准值进行比较，判断材料的导电性能是否达到要求。

astm257标准
ASTM D257标准是美国材料和试验协会（ASTM）制定的标准，
涉及到材料的电阻率或电导率的测试方法。

这个标准主要用于测量
固体绝缘材料的电阻率，包括塑料、橡胶、纤维和其他绝缘材料。

该标准旨在提供一种标准化的测试方法，以便不同实验室和组织之
间进行可比较的测试结果。

ASTM D257标准包括了两种测试方法，平板电阻率测试和体积
电阻率测试。

平板电阻率测试是通过在材料上施加一定的电压，然
后测量通过材料的电流来计算电阻率。

而体积电阻率测试则是将材
料制成特定形状的样品，然后测量通过样品的电流和施加在样品上
的电压，也是用来计算电阻率。

这个标准的应用非常广泛，特别是在电气和电子工业中，因为
电阻率或电导率是评估绝缘材料性能的重要指标。

此外，该标准还
在材料研究和开发、质量控制以及产品认证等方面发挥着重要作用。

总的来说，ASTM D257标准对于测量固体绝缘材料的电阻率提
供了一种标准化的方法，有助于确保不同实验室和组织之间获得可
比较的测试结果，同时也为电气和电子工业以及其他相关领域提供了重要的参考依据。

ASTM D类最新标准目录( 一）D4-86(2004) 沥青含量试验方法D5-06e1 沥青材料的渗透性试验方法D6-95(2000)e1 油及沥青混合物加热损失试验方法D8-02 与道路和路面材料相关的术语D9-05 与木材相关的术语D12-88(1998) 未加工的桐油D13-02 松节油规范D16-03 与涂料、清漆、亮漆和有关产品相关的术语D20-03 路面焦油的蒸馏试验方法D25-99(2005) 圆木桩D29-98 虫胶树脂的抽样和试验方法D34-91(2003) 白颜料化学分析指南D36-95(2000)e1 沥青软化点试验方法(沥青软化点测定器)D38-94(2000)e1 木材防腐剂的抽样试验方法D41-05 铺屋面、防潮及防水用沥青底层D43-00 屋顶、防潮及防水材料用杂酚油底漆D49-83(2002) 铅丹的化学分析D50-90(2005) 含铁和锰的黄色、橙色、红色和褐色涂料的化学分析试验方法D56-05 泰格密闭闪点试验器测定闪点的试验方法D61-75(2004) 硬沥青的软化点的试验方法(水中方块试验法)D69-01 磨擦带的试验方法D70-03 半固态沥青材料的比重和密度的试验方法D71-94(2004) 固体硬沥青和地沥青的相对密度试验方法(变位法)D75-03 集料的抽样D76-99(2005) 纺织材料的抗拉试验机D79-86(2004) 氧化锌颜料D81-87(2003) 碱性碳酸盐铅白颜料D83-84(2002) 铅丹颜料D85-05 赭色颜料规范D86-05 大气压下石油产品蒸馏试验方法D87-04 石蜡熔点的试验方法(冷却曲线)D88-94(2005) 赛波特粘度的试验方法D91-02 润滑油的沉淀值试验方法D92-05a 用克利夫兰德开杯法测定石油产品的闪点和燃点的试验方法D93-02a 用潘斯基-马丁斯仪闭杯闪点测定器测定闪点的试验方法D94-02 石油产品的皂化值试验方法D95-05e1 蒸馏法测定石油产品及沥青材料中水的试验方法D97-05a 石油的倾点的试验方法D98-05 氯化钙D113-99 沥青材料的延展性的试验方法D115-02 电绝缘用含清漆试验溶剂的试验方法D116-86(2006) 电气设备用上釉陶瓷材料的试验D117-02 产自石油的电绝缘油的试验方法和规范导则D120-02a 橡胶绝缘手套D121-05 煤和焦炭术语D123-03 与纺织材料相关的术语D124-88(1998) 脱胶的豆油D126-87(2002) 含铬酸铅和氧化铬绿的黄、橙和绿色颜料的化学分析方法D127-05 石油蜡包括凡士林滴熔点的试验方法D128-98(2003)e1 润滑脂分析试验方法D129-00(2005) 石油产品中硫含量试验方法(通用氧弹法)D130-04e1 用铜条变色法检测石油产品对铜腐蚀性的测试方法D139-95(2001)e1 沥青材料浮选试验的检测方法D140-01 沥青材料的抽样D143-94(2000)e1 洁净木材小样品的试验D146-04 防水与屋面材料用沥青浸渍的油毡和编织物的抽样与试验方法D149-97a(2004) 固体电绝缘材料在工业电源频率下的介电击穿电压和介电强度的试验方法D150-98(2004) 固体电绝缘材料的(恒久电介质)的交流损耗特性和介电常数的测试方法D153-84(2003) 颜料比重测试方法D154-85(2001) 清漆试验D156-02e1 石油产品赛波特比测试方法(赛波特比色计法)D167-93(2004)e1 块焦比重和孔隙度的试验方法D168-94(2000) 杂酚油焦炭渣的测试方法D173-03 屋顶和防水材料用饱和沥青棉织物D176-00 电绝缘用固体充填化合物与浸渍剂的试验方法D178-01(2005) 橡胶绝缘垫子D185-84(1999 颜料,糊剂及涂料中粗颗粒的试验方法D187-94(2003)e1 煤油燃烧质量的测试方法D189-05 石油产品康拉孙残碳测试方法D197-87(2002) 粉煤的取样方法与细度试验方法D198-05a 结构尺寸木料静力试验法D202-97(2002)e1 电绝缘用未浸渍纸的抽样和试验方法D204-02 缝线的测试方法D209-81(2003) 灯黑颜料D210-05 骨炭颜料D211-67(2002) 铬黄和铬橙颜料D215-91(2002) 白色亚麻籽油涂料的化学分析D217-02 润滑剂针入度的测试方法D225-04 表面有矿物颗粒的沥青屋面板D226-06 铺顶和防水用沥青饱和有机毡D227-03 铺顶和防水用焦油沥青饱和有机毡D228-06 沥青屋面卷材,盖板和瓦的试验方法D229-01 电绝缘用硬质薄板及板材的试验方法D233-02 松脂的抽样和测试试验方法D234-82(1998) 生亚麻子油D235-02 矿物溶剂油(石油溶液油)(烃干洗溶液)规格D237-57(1997) 橙色紫胶和其他虫胶D240-02 弹式量热器测定液烃燃料燃烧热的试验方法D242-04 沥青铺路混合料用矿物填料D243-02 规定残渣渗透性测试方法D244-04 乳化沥青的测试方法D245-06 制定目测分等木材的结构等级及有关允许性能的规程D246-04 杂酚油和杂酚油-煤焦油溶液的蒸馏试验方法D256-06 塑料及电绝缘材料的抗冲击性的测试方法D257-99(2005) 绝缘材料的直流电阻或电导的试验方法D260-86(2001) 熟亚麻籽油D261-75(1999) 铁蓝颜料D262-81(1999) 群青蓝颜料D263-05 氧化铬绿颜料D267-82(2003) 黄青铜粉规格D268-01 涂料及其相关涂层和原料用挥发性溶剂及化学中间体的抽样和测试D269-97(2002) 松香和松香衍生物中不溶物的试验方法D276-00a 纺织品中纤维的鉴定方法(AATCC方法20)D279-02 颜料渗出的试验方法D280-01 颜料吸收的水份(及试验条件下挥发的其他物质)的测试方法D281-95(2002) 用刮刀磨损法测定颜料油吸附性的试验方法D283-84(1999) 一氧化铜和铜涂料化学分析试验方法D287-92(2006) 原油和石油产品API比重的试验方法(液体比重计法)D291-86(2002) 烟煤立方英尺重量的试验方法D293-93(2004) 焦炭筛析分析试验方法D295-99(2004) 电绝缘用棉质漆布的试验方法D297-93(2002)e2 橡胶制品的测试方法.化学方法D299-04e1 石棉纱的标准规范D301-95(2004) 可溶性硝化纤维素的试验方法D304-05 n-丁醇(丁醇)D305-84(2003) 黑色涂料中的溶剂萃取材料的试验方法D312-00 屋顶用沥青D315-95(2004)e1 机织石棉带的标准规范D319-04 合成的戊醇D322-97(2002)e1 蒸馏法测定汽油发动机废机油中汽油稀释剂的试验方法D323-99a 石油产品蒸气压力的测试方法D329-02 丙酮D330-93(2001) 2-丁氧基乙醇D331-05 2-乙氧基乙醇D332-87(2004) 白色颜料着色力的试验方法D333-01 透明漆和着色漆的试验方法D341-03 液体石油产品粘度-温度关系曲线图D344-97(2004) 用擦试外规评定法对涂料相对遮盖力的测试方法D345-02 道路和结构用氯化钙的抽样和试验方法D346-04e1 实验室分析用焦炭试样的收集和制备D347-97 杂酚油和煤焦油的体积和比重修正表D348-00 电绝缘用刚性管的测试方法D349-99(2004) 电绝缘用层压圆棒的试验方法D350-01 电绝缘用经处理软套管的试验方法D351-97(2003) 天然白云母块及薄片目检质量分级D352-97(2003) 电绝缘用涂浆云母的试验方法D358-98 涂料耐大气老试验用木片规格D360-89(2001) 紫胶清漆规范D363-90(2000) 磷酸三甲苯酯规格D365-01(2005) 可溶性硝酸纤维素基溶液的试验方法D367-94(2000)e1 杂酚油中苯不溶物的测试方法D368-89(2002) 杂酚油及油质防腐剂比重的试验方法D369-84(2002) 杂酚油馏份与残渣比重的测试方法D370-02e1 油质防腐剂脱水作用的试验方法D372-00(2006) 电绝缘用经处理的软套管规格D374-99(2004) 固体电绝缘厚度的测试方法D374M-99(2005) 固体电绝缘厚度的标准测试方法(米制)D375-95(2004)e1 石棉粗砂的标准规范D378-00 平型橡胶传送带的测试方法D380-94(2006) 橡胶软管的测试方法D381-04 用喷射蒸发法测定燃烧中原在胶的测试方法D387-00 使用机械研磨机测定有色颜料主色和着力色的试验方法D388-05 用排列法测定煤的分类D390-92(1999) 海上,陆地及淡水中用木桩,电杆和木材的防腐处理用煤柏油杂酚油规程D391-94(2000)e1 杂酚油-煤焦油溶液D395-03 橡胶压缩永久变形特性的试验方法D396-05 燃料油规范D402-02 稀释沥青产品蒸馏的测试方法 Standard Test Method for Distillationof Cut-Back Asphalt ic (Bituminous) ProductsD409-02 粉碎机法测定煤炭可磨性的试验方法 Standard Test Method for Grindabilityof Coal by t he Hardgrove-Machine MethodD411-98(2003) 电绝缘用紫胶片试验方法 Standard Test Methods for ShellacUsed for Electrical I nsulationD412-98a(2002)e1 硫化橡胶、热塑橡胶和热塑合成橡胶的拉伸试验方法 Standard Test Methods f or VulcanizedRubber and Thermoplastic Elastomers—TensionD413-98(2002)e1 橡胶特性-与软质基底粘附性的试验方法 Standard Test Methods for RubberPro perty—Adhesion to Flexible SubstrateD420-98(2003) 土壤粒度分析的测试方法 Standard Guide to SiteCharacterization for Engineering, Design, and ConstructionPurposesD421-85(2002) 土壤粒度分析试验方法 Standard Practice for Dry Preparationof Soil Samples for Particle-Size Analysis and Determination ofSoil ConstantsD422-63(2002)e1 土壤粒度分析试验方法 Standard Test Method forParticle-Size Analysis of Soils D425-88(2001) 土壤离心湿度当量试验方法 Standard Test Method for CentrifugeMoisture Equiva lent of SoilsD427-04 用水银法测量土壤收缩系数的测试方法 Test Method for Shrinkage Factors ofSoils by t he Mercury MethodD429-03e1 橡胶特性与硬质基底粘附性的试验方法 Standard Test Methods for RubberProperty—Adhesion to Rigid SubstratesD430-06 橡胶变质的动态疲劳试验方法 Standard Test Methods for RubberDeterioration-Dynamic FatigueD434-95 Standard Test Method for Resistance toSlippage of Yarns in Woven Fabrics Using a St andard SeamD440-86(2002) 煤的跌落粉碎试验 Standard Test Method of Drop ShatterTest for CoalD441-86(2002) 煤的滚筒试验 Standard Test Method of Tumbler Test for CoalD444-88(2003) 锌黄颜料(铬酸锌黄)的化学分析方法 Standard Test Methods for Chemical Analysis of Zinc YellowPigment (Zinc Chromate Yellow)D445-06 透明和不透明液体运动粘度的测试方法.(包括动态粘度的计算) Standard Test Method for Kinematic Viscosity ofTransparent and Opaque Liquids (and the Calculation of DynamicViscosity)D446-06 玻璃毛细管运动粘度计操作说明书和规范 Standard Specifications and OperatingInstructi ons for Glass Capillary Kinematic ViscometersD448-03a 道路和桥梁建筑的集料尺寸分类 Standard Classification for Sizes ofAggregate for Roa d and Bridge ConstructionD449-03 防潮和防水用沥青规范 Standard Specification for AsphaltUsed in Dampproofing and WaterproofingD450-96(2006) 铺屋面,防潮与防水用硬煤沥青 Standard Specification for Coal-TarPitch Used in Roofing, Dampproofing, and WaterproofingD451-91(2002) 沥青屋顶制品用粒状矿物铺面材料筛分分析试验方法 Standard Test Method for Si eveAnalysis of Granular Mineral Surfacing For Asphalt RoofingProductsD452-91(2002) 沥青层面制品表面修整用非粒状矿物的筛分试验方法 Standard Test Method for Si eveAnalysis of Surfacing for Asphalt Roofing ProductsD453-94(2000)e1 杂酚油-煤焦油溶液中焦油酸含量的测试方法 Standard Test Method for Tar Aci ds inCreosote-Coal Tar SolutionsD454-04 用加热及空气压力测定橡胶变质的试验方法 Standard Test Method for RubberDeteriorat ion by Heat and Air PressureD459-00 肥皂和其它洗涤剂的术语规范 Standard Terminology Relating toSoaps and Other Deter gentsD460-91(2005) 肥皂和其它洗涤剂粒度的试验方法 Standard Test Methods for Samplingand Che mical Analysis of Soaps and Soap ProductsD464-05 松脂油产品包括妥尔油和其他相关产品的皂化值的试验方法 Standard Test Methods for Saponification Number of Naval Store Products Including Tall Oil and Other Related ProductsD465-05 松脂制品包括妥尔油及其它相关产品酸值的试验方法 Standard Test Methods for Acid N umberof Naval Stores Products Including Tall Oil and Other RelatedProductsD470-05 电线和电缆用交联绝缘与套管的测试方法 Standard Test Methods for CrosslinkedInsulati ons and Jackets for Wire and CableD471-98e2 液体对橡胶性能影响的测试方法 Standard Test Method for RubberProperty-Effect of LiquidsD473-02 萃取法测定原油和燃料油中沉积物的试验方法 Standard Test Method for Sediment inCr ude Oils and Fuel Oils by the Extraction MethodD476-00(2005) 二氧化钛颜料规范 Standard Classification for DryPigmentary Titanium Dioxide P roductsD478-02 锌黄(铬酸锌)颜料 Standard Specificationfor Zinc Yellow (Zinc Chromate) PigmentsD480-88(2003) 铝粉和铝粉浆的抽样和试验方法 Standard Test Methods for Samplingand Testin g of Flaked Aluminum Powders and PastesD482-03 石油产品灰分的测试方法 Standard Test Method for Ash fromPetroleum ProductsD483-04 石油制植物喷洒油不磺化残渣的试验方法 Standard Test Method for UnsulfonatedResidu e of Petroleum Plant Spray OilsD490-92(2005) 道路柏油 Standard Specification for Road TarD494-04 Standard Test Method for Acetone Extraction ofPhenolic Molded or Laminated Products Standard TestMethod for Acetone Extraction of Phenolic Molded or LaminatedProductsD495-99(2004) 固体电绝缘材料的耐高压低电流干电弧性能的测试方法 Standard Test Method for High-Voltage, Low-Current, Dry Arc Resistance of Solid ElectricalInsulationD500-95(2003) 磺化油和硫化油的化学分析和试验方法D501-03 碱性洗涤剂的抽样和化学分析试验方法D502-89(2003) 肥皂和其它洗涤剂粒度的试验方法D509-05 松香分级和抽样试验方法D511-03 水中钙镁离子的测试方法D512-04 测定水中氯离子含量的试验方法D513-02 水中二氧化碳溶解量和总量的试验方法D516-02 水中硫酸铁的试验方法D517-98(2003) 沥青厚板材D518-99 橡胶变质表面龟裂的试验方法D519-04 羊毛条中纤维长度的试验方法D520-00(2005) 锌粉颜料规范D521-02 锌粉(金属锌粉)的化学分析试验方法D522-93a(2001) 用锥形心轴仪测定涂覆有机涂层延伸率的试验方法D523-89(1999) 镜面光泽的试验方法D524-04 石油产品中兰氏残炭的试验方向D525-05 汽油氧化稳定性的试验方法(诱导期方法)D528-97(2002) 纸和纸板的机器定向试验方向D529-04 沥青材料的加速风化试验条件和程序的测试方法(碳弧法)D531-00(2005) 普西和琼斯橡胶压缩试验方法D542-00 透明有机塑料的折射指数的试验方法D543-06 塑料耐化学试剂性能的试验方法D545-99(2005) 混凝土用预制伸缩缝纫填料的试验方法(非挤压和弹性型)D546-05 道路和铺砌材料用矿物填料筛分的测试方法D548-97(2002) 纸张水溶解酸碱度的试验方法D555-84(1998) 干性油试验D558-04 土壤水泥混合物的水分与密度关系的试验方法D559-03 压实的掺土水泥混合物的湿润与干燥的试验方法D560-03 压实的掺土水泥混合物的冻融试验方法D561-82(2003) 涂料用炭黑颜料D562-01(2005) 斯氏粘度计测定涂料稠度的试验方法D563-88(1996)e1 醇酸树脂和树脂溶液中苯酐含量的试验方法D564-87(2002) 液体涂料催干剂的试验方法D565-99(2005) 白色矿物油中可碳化物质的试验方法D566-02 润滑脂滴点的试验方法D570-98(2005) 塑料吸水率的试验方法D572-04 用加热法和氧化法进行的橡胶变质的试验方法D573-04 在空气烤炉中作橡胶变质的试验方法D575-91(2001) 橡胶压缩特性的试验方法D578-05 玻璃纤维丝D579-04 原织物玻璃纤维D580-04 机织玻璃纤维带D581-99 机织玻璃纤维套管的编织D584-96(2005) 原毛中羊毛含量实验室测试方法D585-97(2002) 纸张、纸板、纤维板和相关产品的单批取样和验收方法D586-97(2002) 纸中灰分含量的试验方法D589-97(2002) 纸的不透明度的测试方法D590-93(2002) 纸中石油蜡的测试方法D596-01 水分析结果的报告D600-90(2001) 液体涂料催干剂D601-87(1998) 奥气油(永久液体)D602-81(2003) 硫酸钡颜料规范D605-82(2003) 硅酸镁颜料(滑石)D607-82(2003) 湿磨云母颜料D608-05 邻苯二甲酸二丁酯D609-00 涂料、油漆以及改性涂料与相关涂料产品的测试用冷轧钢板的制备D610-01 涂漆钢表面锈蚀程度评价的试验方法D611-04 石油产品和烃类溶剂苯胺点和混合苯胺点的试验方法D612-88(2004) 石蜡中可碳化物质的试验方法D613-05 十六烷法测定柴油燃料燃烧质量的试验方法D618-05 塑料及电绝缘材料的调理方法D619-99(2004) 电绝缘用硫化纤维的测试方法D622-99(2005) 汽车空气制动和真空制动系统用橡胶软管试验方法D623-99e1 橡胶特性-压缩中热的产生及挠曲疲劳的试验方法D624-00e1 橡胶的热塑性弹性的耐老化性的抗撕裂强度的试验方法D628-95(2004)e1 石棉套管的标准规范D629-99 纺织品定量分析试验方法D632-01 氯化钠D633-97(2005) 道路柏油的体积修正表D635-06 自承塑料在水平状态时的燃烧速率或者燃烧蔓延程度及燃烧时间的试验方法D638-03 塑料拉伸性能的试验方法D642-00(2005) 船用集装箱、组合件和单体加载的抗压缩能力的测试方法D643-97(2002) 用厦泊测试仪测试纸的折痕持久性的标准试验方法D644-99(2002) 用烘干法测定纸和纸板中水分的测试方法D645/D645M-97(2002) 纸和纸板厚度的测试方法D646-96(2001) 纸张及纸板的基本重量的试验方法(单位面积的重量)D648-06 在挠曲负荷下塑料的挠曲温度的试验方法D653-05 土壤、岩石和其内部所含液体的相关术语D660-93(2005) 外用漆龟裂程度评价方法D661-93(2005) 外用漆破裂程度评价的试验方法D662-93(2005) 外用漆侵蚀程度评价的试验方法D664-06 电位滴定法测定石油产品酸值的试验方法D665-06 水存在下抑制的矿物油防锈特性的试验方法D668-99(2004) 电绝缘用硬条和硬管尺度测量的测试方法D669-03 层压薄板与层压板的平行于层片的耗散系数和介电常数的试验方法D685-93(2002) 检测调理纸和纸制品D686-93(2002) 纸中矿物填料和矿物涂料的定性测试方法D689-03 纸张的内部耐撕裂的试验方法D692-00(2004) 沥青铺路砌混合用粗集料D693-03a 碎石路面用压碎集料D695-02a 硬质塑料抗压特性的试验方法D696-03 从-30摄氏度到30摄氏度的塑料线性热膨胀系数的试验方法D698-00ae1 实验室中用12000ft-lbt/ft(600KN-m/m)作用力测定土壤压力特性的试验方法D704-99(2004) 三氯氰胺甲醛模制化合物D705-99(2004) 脲甲醛模制化合物D706-05 乙酸纤维素模制和挤压化合物D707-05 醋酸丁酸纤维素模制与挤压料规格D709-01 层压热固材料D710-97(2002) 电绝缘用硫化纤维薄板、条和管D711-89(2004) 路标漆不粘着时间的试验方法D713-90(2004) 路标漆进行路面使用的试验方法D714-02e1 涂料起泡程度的试验方法D715-86(2003) 硫酸钡颜料分析的标准试验方法D716-86(2003) 评定云母颜料的标准试验方法D717-86(2003) 硅酸镁颜料分析的标准试验方法D718-86(2003) 硅酸铝颜料的分析标准试验方法D720-91(2004)e1 煤自由膨胀指数的试验方法D721-05 石油蜡含油量的试验方法D722-93(2002) 纸的抗油脂性标准试验方法D724-99(2003) 纸表面可湿性的测试方法(接触角法)D726-94(2003) 空气中无孔纸的透气性的测试方法D727-96(2001) 真空方法测定屋顶和地板油毡煤油值的试验方法D731-95(1999) 热固模塑料粉末的模塑指数的试验方法D732-02 用穿孔工具测量塑料剪切强度的测试方法D737-04 纺织纤维透气率的试验方法D740-05 丁酮规范D746-04 用冲击法测定塑料及弹性材料的脆化温度的试验方法D747-02 用悬臂梁法对塑料表观弯曲系数的测试方法D748-00(2005)e1 固定式云母介电电容器用天然云母块和云母薄片D750-00 用碳弧型装置和风化装置对橡胶变质的测试方法D751-06 涂层织物的测试方法D763-01 未加工棕土和焙烧棕土颜料D765-87(2003) 未加工黄土和焙烧黄土颜料技术规范D768-01 黄色氧化铁的水合物D769-01 黑色合成氧化铁D770-05 异丙醇规范D772-86(2005) 外部涂料剂落程度评价的试验方法D774/D774M-97(2002) 纸张抗破碎强度的测试方法D776-92(2001) 干热对纸和纸板特性的影响的试验方法D777-97(2002) 经过处理的纸和纸板易燃性的标准试验方法D778-97(2002) 纸萃液(热萃取和冷萃取法)氢离子浓度(pH)的标准试验方法D779-03 纸、纸板和其他印刷材料用干烧指示器法测试耐水性的测试方法D780-95(2003) 纸印刷油墨渗透性的测试方法(蓖麻油试验)D784-03 电绝缘材料用橙色紫胶和其他印度虫胶D785-03 塑料和电绝缘材料的洛氏硬度的测试方法D787-96(2003) 乙基纤维模制和挤压化合物D788-05 甲基丙烯酸酯模制和挤压化合物的分类系统D789-06 聚酰胺相对粘度,熔点和含水量的测试方法D790-03 未增强和增强塑料及电绝缘材料的挠曲性的试验方法D792-00 用位移法测定塑料密度和比重(相对密度)的标准试验方法D800-05 工业用金属除垢剂化学分析试验方法D801-02 二聚戊烯抽样和测试的试验方法D802-02 松油抽样和测试的试验方法D803-03 妥儿油的测试试验方法D804-02 松脂制品包括妥儿油及相关产品的术语D806-00(2006) 掺土水泥混合物中水泥含量的试验方法D807-05 工业锅炉用水引起脆裂倾向的评价方法(美国矿业局的脆变检查器方法)D808-05 新的和使用过的石油产品中氯含量的试验方法(氧弹法)D813-06 测定橡胶龟裂扩展的试验方法D814-95(2005) 橡胶特性挥发性液体蒸汽渗透性的试验方法D816-06 橡胶胶水的试验方法D817-96(2004) 乙酸丙酸纤维素和醋酸丁酸纤维素的试验方法D820-93(2003) 含合成洗涤剂肥皂的化学分析试验方法D822-01 用经过过滤明光碳弧灯和水中曝光装置对涂料及相关涂层和材料上做的导电试验D823-95(2001) 色漆,清漆,喷漆及有关产品制成厚度均匀漆膜试片的方法D824-94(2002) 用皱文纸测定吸水率的测试方法D828-97(2002) 纸和纸板拉力破坏强度的测试方法D829-97(2002) 纸和纸制品湿抗拉断裂强度的标准试验方法D831-94(2004) 电缆及电容器油的气体含量的测试方法D832-92(2001)e1 低温状态下的橡胶试验D841-02 甲苯的硝化定级D843-06 硝化二甲苯D847-04 苯,甲苯,二甲苯,溶剂石脑油和类似的工业芳烃酸度的试验方法D848-03 工业芳烃的酸洗颜色的标准试验方法D849-05 工业芳烃对铜条腐蚀的标准试验方法D850-03 工业芳轻及相关物质的蒸溜法D852-02 苯凝固点的试验方法D853-04 工业芳烃中硫化氢和二氧化硫含量(定性)的标准试验方法D854-06 土壤比重的试验方法D857-02 水中铝含量的测试方法D858-02 水中锰含量的试验方法D859-05 水中二氧化硅的测试方法D861-01a 用特克斯制命名纤维,纱的半制品,纱和其它纺织品线度D865-99(2005) 橡胶的空气中加热变质试验方法(试管法)D866-99(2004) 电线及电缆用丁苯合成橡胶套D868-85(2003) 路标漆渗色程度评价的试验方法D869-85(2004) 涂漆沉降程度评价试验方法D870-02 水浸渍法涂层耐水试验D871-96(2004) 测试乙酸纤维素的试验方法D873-02 航空燃料的氧化稳定性的测试方法D874-06 润滑油和添加剂中硫酸盐类灰分的测试方法D876-00 电绝缘用刚性氧化乙烯聚合物管的测试方法D877-02e1 用圆盘电极测定电绝缘液体介电击穿电压的试验方法D878-01e1 绝缘油中无机氯化物和硫酸盐的测试方法D880-92(2002) 船用集装箱的冲击试验的试验方法D882-02 塑料薄板材抗拉特性的试验方法D883-00 塑料相关术语D885-06 由人造有机纤维制成的轮胎帘子线,轮胎帘布和工业长纱线的测试D887-82(2003)e1 水沉积物抽样D888-05 水中溶解氧的试验方法D889-99(2004) 松香中油挥发性的试验方法D890-98(2003) 液体松脂中水含量的试验方法D891-95(2004) 液态工业化合物的比重,表观比重的测试方法D892-05 润滑油发泡特性的标准试验方法D893-05a 用过的润滑油中不溶物的试验方法D896-04 胶粘剂耐化学试剂粘法的试验方法D897-01e1 胶粘剂粘结力的抗拉性的测试方法D898-05 胶粘剂固体单位面积涂用重量的试验方法D899-00 单位面积涂用液体胶粘剂的重量的测试方法D902-00 电绝缘用挠性涂树脂玻璃布和玻璃布带的测试方法D903-98(2004) 胶粘剂粘结抗剥落或爆皮强度的试验方法D904-99(2005) 人造光(碳弧型)和自然光对胶粘剂试样的曝光D905-03 用压缩荷载法测定胶粘剂的抗剪切强度性能的试验方法D906-98(2004) 用拉力负荷法测定胶合板结构中胶粘剂剪切强度特性的试验方法D907-05e1 胶粘剂术语D909-01e1 增压进料法测定航空汽油抗震性的试验方法(联邦试验方法No.791b) D910-04a 航空汽油技术规范D912-81(1999) 防污涂料用氧化亚铜D913-03e1 路标漆耐磨程度的评价方法D914-00(2006) 乙基纤维的试验方法D918-99(2003) 纸和纸板的抗粘结性试验方法D919-97(2002) 纸和纸板的铜值测试方法D922-00a(2006) 非硬质聚氯乙烯管D923-97 电绝缘液体的抽样方法D924-04 电绝缘液体的损耗因数(或功率因数)和介电常数(电容率)的测试方法D925-06 橡胶特性.表面着色(接触、色移和扩散)的试验方法D926-04 用平行板法测量橡胶的塑性和弹性D928-03 碳酸氢钠D932-85(2002) 水和水沉积物中嗜铁细菌含量试验方法D933-84(2003) 水沉积物的检验和分析结果的报告方法D934-80(2003) 用X射线衍射法作水沉积物中结晶化合物的识别方法D937-04 石油脂的针入度试验方法D938-05 石油蜡(包括凡士林)凝固点的测试方法D942-02 氧弹法测定润滑脂氧化稳定性的试验方法D943-04a 防腐蚀矿物油氧化特性的试验方法D945-06 用机械示波器测定在压缩应力和剪切应力下橡胶特性的试验方法D946-82(2005) 路面建造用按贯入度级配的沥青膏D950-03 胶粘剂抗冲击强度的试验方法D951-99(2004) 用喷射法测定船运集装箱的耐水性的试验方法D952-02 薄板塑料和电绝缘材料粘结强度的试验方法D953-02 塑料支承强度的测试方法D955-00 模制塑料模型尺寸收缩率的测量方法D957-95(2006)e1 塑料生产用模型表面温度的测定D960-02a 生蓖麻油D961-86(2001) 脱水蓖麻油D962-81(2003) 涂料用铝粉和铝浆颜料D964-03 防污漆用铜粉D968-05 用落沙磨蚀法测定有机涂层耐磨性的试验方法D969-85(2003) 路标漆渗色程度的实验室试验方法D971-99a(2004) 环法测定油水界面张力的试验方法D972-02 润滑脂和润滑油蒸发损失的测试方法D974-04 用颜色指示剂滴定法测定酸碱值的标准试验方法D975-06 柴油技术规范D976-04be1 馏分燃料正十六烷指数的计算方法D977-05 乳化沥青D979-01(2006)e1 沥青铺面混合料的取样方法D982-05 Standard Test Method for Organic Nitrogen in Paper andPaperboard D984-97(2002)。

ASTM D257-07 中文版绝缘材料直流电阻和电导测试.…ASTMD绝缘材料直流电阻或电导的标准试验方法本标准是以固定代号D发布的。

其后的数字表示原文本正式通过的年号在有修订的情况下为上一次的修订年号圆括号中数字为上一次重新确认的年号。

上标符号（ε）表示对上次修改或重新确定的版本有编辑上的修改。

本标准经批准用于国防部所有机构。

1.范围本试验方法包含直流绝缘电阻体积电阻和表面电阻的测量所用直流程序。

通过该测量及样本和电极的几何尺寸可以计算出电绝缘材料的体积电阻和表面电阻同时还可以计算出相应的电导和电导率。

这些试验方法不适用于测量中等导电材料的电阻电导。

这些材料评估可采用试验方法D4496。

本标准描述了几种可选择的测量电阻（或电导）的普通方法。

特殊材料科采用最合适的标准ASTM试验方法进行测试这些特殊材料具有电压应力范围和有限起电时间同时规定了样本结构和电极几何形状。

这些个别特殊试验方法将能更好得定义测量值的精度和偏差。

本试验方法包括以下章节：试验方法或步骤章节计算13设备和试验方法的选择7清洗固体样本10.1 样本的状态调节11屏蔽电极的有效面积附录X2电极系 6绝缘电阻或电导材料的影响因素附录X1湿度控制11.2 液体样本和电池9.4精度和偏差15 电阻或电导测量步骤12 引用文件 2 报告14 抽样8 重要性和用途 5 样本安装10 试验方法摘要 4 术语 3 绝缘电阻体积电阻和表面电阻或电导测量用试验样本9 典型测量方法附录X3本标准并没有完全列举所有的安全声明如果有必要根据实际使用情况进行斟酌。

使用本规范前使用者有责任制定符合安全和健康要求的条例和规范并明确该规范的使用范围。

引用文件ASTM标准：D150固体电绝缘材料的（恒久电介质）的交流损耗特性和介电常数的测试方法D374固体电绝缘材料厚度的标准试验方法D1169电绝缘液电阻率(电阻系数)试验方法D1711电绝缘相关术语D4496中等导电材料直流电阻或导电性的标准试验方法D5032用水甘油溶液设备维持恒定相关湿度的规程D6054测试用电工绝缘材料的调节规程E104用水溶液保持相对恒定湿度的标准实施规程术语定义：以下定义直接来自术语标准D1711适用于本标准正文所用术语。

表面电阻测试湿度标准全文共四篇示例，供读者参考第一篇示例：表面电阻测试湿度标准表面电阻测试是指对材料表面的电阻进行测试，以确定其导电性能。

在不同的湿度条件下，材料的表面电阻会发生变化，这主要是由于水分的影响。

对于一些对湿度敏感的材料，测试时需要按照一定的湿度标准进行操作，以确保测试结果的准确性和可靠性。

湿度对材料的表面电阻有着重要的影响。

在高湿度环境下，材料表面会吸收大量的水分，导致电阻值下降；而在低湿度环境下，水分被减少，电阻值会上升。

进行表面电阻测试时，需要保持相对恒定的湿度条件，以确保测试结果的可比性。

在实际应用中，为了保证测试的准确性和可重复性，国际上制定了一些与湿度有关的标准，以规范表面电阻测试过程中的湿度条件。

下面将介绍几种常见的表面电阻测试湿度标准。

1. ASTM D257-07标准ASTM D257-07是美国材料和测试协会（ASTM）发布的标准，用于规定塑料、涂料和其他绝缘材料的表面电阻测试方法。

该标准规定，在进行表面电阻测试时，应该将相对湿度控制在45%~55%的范围内，以确保测试结果的准确性和可靠性。

2. IEC 60093标准3. GB/T 1410标准除了以上几种标准外，不同行业和应用领域还可能有其他的表面电阻测试湿度标准。

在进行表面电阻测试时，应该根据具体的要求和标准，选择合适的湿度条件进行测试，以确保测试结果的准确性和可信度。

在实际应用中，表面电阻测试湿度标准的严格执行，对于确保测试结果的准确性和可靠性至关重要。

只有在适当的湿度条件下进行测试，才能保证测试结果的可比性和可重复性，为材料的导电性能提供准确的评估和分析。

在进行表面电阻测试时，一定要严格遵守相应的湿度标准，以确保测试结果的准确性和可信度。

第二篇示例：表面电阻测试是一种广泛应用于电子设备制造领域的测试方法，它通过测量材料表面的电阻值来评估材料的导电性能。

在进行表面电阻测试时，通常需要考虑到环境因素对测试结果的影响，其中湿度是一个重要的参数。

老化测试项目及其检测标准(科标)老化测试项目及其检测标准（科标化工检测中心）该文档主要介绍了塑料、橡胶、汽车材料的相关检测项目以及检测标准，我中心是一家权威的化工材料分析测试机构，主营橡胶、塑料、涂料、油漆、油墨、化工助剂、胶黏剂等化工材料的成分分析，性能检测，老化测试以及配方研发等检测服务。

检测项目/参数序号检测产品/类别序号1检测标准（方法）名称及编号（含年号）名称光源暴露试验方法通则塑料实验室光源暴露试验方法第1部分：通则ISO4892-1:1999汽车外饰材料的氙弧灯加速暴露试验SAEJ2527:2019汽车内饰材料的氙弧灯加速暴露试验SAEJ2412:2019塑料实验室光源暴露试验方法第2部分：氙弧灯ISO2氙弧灯光老化4892-2:2019/Amd1:2019室内用塑料氙弧光暴露试验方法ASTM D4459-06非金属材料氙弧灯老化的仪器操作方法ASTMG155-05a塑料暴露试验用有水或无水氙弧型曝光装置的操作限制范围或说明1塑料ASTM D2565-99(2019)塑料实验室光源暴露试验方法第3部分：荧光紫外灯ISO 4892-3:20193荧光紫外灯老化汽车外饰材料UV 快速老化测试SAE J2020:2019塑料紫外光暴露试验方法ASTMD4329-05非金属材料UV 老化的仪器操作方法ASTM G154-06塑料实验室光源暴露试验方法第4部分：开放式碳4碳弧灯老化弧灯ISO 4892-4:2019/CORR 1：2019塑料实验室光源曝露试验方法第4部分：开放式碳弧灯GB/T16422.4-19965荧光紫外灯老化机械工业产品用塑料、涂料、橡胶材料人工气候老化试验方法荧光紫外灯GB/T14522-2019中心以化工行业技术需求和科技进步为导向，以资源整合、技术共享为基础，分析测试、技术咨询为载体，致力于搭建产研结合的桥梁。

以“专心、专业、专注“为宗旨，致力于实现研究和应用的对接，从而推动化工行业的发展。

EVERGREEN-PLASTICPoly-Lite PC质量检验标准核准：审核：拟定：修订记录目录修订记录 (2)目录 (3)前言 (4)1.0 范围 (5)2.0 引用文件 (6)3.0 术语和定义 (6)4.0 质量要求 (7)5.0检测规则 (10)6.0标志、包装、贮存、运输 (12)前言连平长荣塑胶有限公司根据目前国际及国内电子、电器等尖端市场对光学薄膜的大量需求，引进国内外最先进的挤出成型设备再结合国内高端技术进行科学改进，专业生产聚碳酸酯薄膜（PC film）和片材（PC sheet）之质量已完全达到目前市场中的高品质产品，长荣公司可根据不同行业的使用要求生产不同品质等级之材料，满足不同客户群的使用。

因在PC挤出成型行业中目前国内及行业中尚未出台相关的国家标准及行业标准，为保证我司产品质量的可靠性及可验证性，特根据《中华人民共和国标准化法》制定本企业标准，以作为供需双方及相关使用行业的参考，当国家标准或行业标准颁布实施时，本标准将自行作废而依照其新标准。

本标准由连平长荣塑胶有限公司提出；本标准由连平长荣塑胶有限公司起草；本标准由连平长荣塑胶有限公司批准；本标准起草人：彭艾华1.0范围本标准规定了聚碳酸酯（PC）薄膜、片材的产品分类、技术要求、试验方法、检验规则、标志、标签、运输、贮存。

本标准适用于经挤出加工面成的聚碳酸酯（PC）薄膜、片材。

Poly-Lite PC产品有薄膜（PC film）和片材（PC sheet），厚度0.125mm-1.00mm产品代码:例：Poly-Lite PC- PL 101 （-1 W ）①②③①等级:G 通用 FR 阻燃环保②品种：1本色透明、抛光，2哑光，3细砂，4中砂，5粗砂③颜色： W白色，BU兰色，T茶色，G绿色，R 红色，Y黄色，B黑色，O橙色薄膜为卷筒状，片材为长方形状。

光面产品为平整、光洁的；磨砂/哑光产品，磨砂面呈凹凸不平的砂粒状，哑光面为比较粗糙、不会有明显的反光。

橡胶电性能的四大技术参数
1、绝缘电阻和绝缘电阻率
绝缘物在规定条件下的直流电阻。

及固体和膏体形状的各种绝缘材料体积和表面电阻值的测定。

介电损耗角正切又称介质损耗角正切，是指电介质在单位时间内每单位体积中，将电能转化为热能（以发热形式）而消耗的能量。

表征电介质材料在施加电场后介质损耗大小的物理量，以tanδ来表示，δ是介电损耗角。

介质损耗角是在交变电场下，电介质内流过电流向量和电压向量之间的夹角
在强电场作用下，固体电介质丧失电绝缘能力而由绝缘状态突变为良导电状态。

导致击穿的最低临界电压称为击穿电压。

均匀电场中，击穿电压与固体电介质厚度之比称为击穿电场强度（简称击穿场强，又称介电强度），它反映固体电介质自身的耐电强度。

不均匀电场中，击穿电压与击穿处固体电介
质厚度之比称为平均击穿场强，它低于均匀电场中固体电介质的介电强度。

不同电介质在相同温度下,其击穿场强不同。

表面电阻率测试标准1 Purpose:目 的：1.1To define the requirements and procedures of surface resistivity test.本文旨在定义表面电阻测量的要求和步骤。

2 Scope:范 围：2.1The test method described in the document cover direct­current procedures forthe determination of DC surface resistance and surface resistivity of electricalmaterials.本方法用来测量电气材料的直流表面电阻，表面电阻率。

2.2This document shall be applicable to solid materials and products used and/orproduced by PEAK, except of metal materials..本规范适用于必佳公司内生产及使用的,除金属材料外，其它固体材料及产 品的表面电阻和/或表面电阻率的测试。

3 Instrument ：测试仪器3.1MCP­HT260 Resistivity meterMCP­HT260型电阻率测试仪3.2Model PSI­870 Surface Resistance/Resistivity IndicatorPSI­870 型 表面电阻/表面电阻率测试仪3.3PRF­912 miniature concentric ring fixturePRF­912型微型同心环型电极3.4SRM­110 Surface Resistivity MeterSRM­110 型表面电阻率测试仪。

4 External Reference documents:外部参考文件：4.1ASTM D257­93 ：Standard test methods for DC resistance or conductance ofinsulating materials绝缘材料的直流电阻或电导实验方法4.2ASTM D4496: Test method for DC resistance or conductance of moderatelyconductive materials中等导电材料的直流电阻或电导实验方法。

常见的塑料检测标准和方法如何选择塑料检测设备随着科学技术的突飞猛进，各种新型材料层出不穷，尤其是高分子材料在近几年有了飞速的发展。

塑料材料作为其分支，目前在某些领域已经可以取代木材、金属材料。

为了使塑料材料及其制品能够安全可靠的使用，对其进行力学性能检验是非常必要的。

1、常规电子万能材料试验机该类试验机是万能材料试验机的主流产品，它以伺服电机作为动力源，丝杠、丝母作为执行元件，实现试验机移动横梁的速度控制，具有操作简单，对试验员的要求不高，试验行程可按需要任意定制。

虽然控制方式较为单一，但其控制精度和控制范围很高、很宽。

如越联YL-1107拉力试验机，分辨率为1/250000，力量精度≤±0.5%，其速度调整范围可达5mm/min~500mm/min，无级调速，小吨位机型很容易实现。

如做摩擦系数时，满值负载只有5N.具有极大的配置灵活性，如果增配不同吨位的传感器、夹具、附件、可实现一机多用。

完成拉、压、弯、剪、剥离、撕裂、摩擦系数、扭转等的功能。

根据塑料力学性能检验的相关标准，无论从控制方式还是速度范围、试验行程及试验机的吨位看，该类机型都是塑料力学性能检验的首选。

2、三闭环电子万能材料试验机该类试验机具有常规电子万能类试验机的速度范围宽，试验行程大，配置灵活的特点，又具有电液伺服类试验机力、位移、变形控制的优点。

因而是性能较好的一种试验机，但该类试验机很少有10KN以下的机型，塑料类最常用的不易选择做塑料材料的试验。

3、简易电拉由于塑料拉伸强度是塑料力学性能检验的一个非常重要的指标，在前些年，塑料种类还不是很多，应用也不是非常广的时期，国家标准对塑料要求的力学性能检验项目比较为单一。

一种价格低廉用途单一，以电机作为动力源的拉伸试验机俗称电拉被广泛使用。

这种设备只能用来做单一的拉伸试验，能处理的数据非常有限，控制测量精度也相对较低，现在虽然在某些场合依然有所使用，但因其功能比较单一，已经逐渐为市场所淘汰。

常见绝缘材料表面/体积电阻率测试标准FT-304绝缘材料表面/体积电阻率测试仪一、概况：(1)适用标准：GB/T 22042-2008《服装防静电性能表面电阻率试验方法》；EN 《防护服静电性能第1部分表面电阻检验方法和要求》；GB/T 1410-2006《固体绝缘材料体积电阻率和表面电阻率试验方法》（与国际标准IEC93-1980等效）；FZ/T 64013-2008 《静电植绒毛绒》；SJ/10694-2006《电子产品制造与应用系统防静电检测通用规范》及ASTM D257《绝缘材料的直流电阻或电导试验方法》要求制作。

GB/T 2439-2001《硫化橡胶或热塑性橡胶导电性能和耗散性能电阻率的测定》；GB/T 10581-2006 《绝缘材料在高温下电阻和电阻率的试验方法》；GB/T 1692-2008 《硫化橡胶绝缘电阻率的测定》；GB/T 《纺织品静电性能的评定第４部分：电阻率》GB/T 10064-2006《测定固体绝缘材料绝缘电阻的试验方法》。

(2)适用范围：适用于测量粉末、粉体、颗粒物、电子元器件、介质材料、电线电缆、防静电产品、如防静电鞋、防静电塑料橡胶制品、计算机房防静电活动地板等电阻值等绝缘性能的检验和电子电器产品的绝缘电阻测量。

本仪器测量高电阻测微电流。

(3)特点：采用四探针测量法、仪器体积小、重量轻、高稳定性，高准确度的数字高阻测量仪器。

本仪器配不同的测量电极(夹具)可以测量不同材料(固体、粉体或液体)的体积电阻率和表面电阻率或电导率及方阻。

(4)材料的导电性是用电阻率ρ（单位：欧·米）或电导率σ（单位：欧-1·米-1）来表示的。

两者互为倒数，并且都与试样的尺寸无关，而只决定于材料的性质。

工程上习惯将材料根据导电性质粗略地分为超导体、导体、半导体和绝缘体四类。

二、表面电率阻率/体积电阻率测试仪技术指标1、电阻测量范围：×104Ω～1×1016Ω。

Designation:D 257–07An American National StandardStandard Test Methods forDC Resistance or Conductance of Insulating Materials 1This standard is issued under the fixed designation D 257;the number immediately following the designation indicates the year of original adoption or,in the case of revision,the year of last revision.A number in parentheses indicates the year of last reapproval.A superscript epsilon (e )indicates an editorial change since the last revision or reapproval.This standard has been approved for use by agencies of the Department of Defense.1.Scope*1.1These test methods cover direct-current procedures for the measurement of dc insulation resistance,volume resistance,and surface resistance.From such measurements and the geometric dimensions of specimen and electrodes,both vol-ume and surface resistivity of electrical insulating materials can be calculated,as well as the corresponding conductances and conductivities.1.2These test methods are not suitable for use in measuring the electrical resistance/conductance of moderately conductive e Test Method D 4496to evaluate such materials.1.3This standard describes several general alternative methodologies for measuring resistance (or conductance).Specific materials can be tested most appropriately by using standard ASTM test methods applicable to the specific material that define both voltage stress limits and finite electrification times as well as specimen configuration and electrode geom-etry.These individual specific test methodologies would be better able to define the precision and bias for the determina-tion.1.4The procedures appear in the following sections:Test Method or Procedure SectionCalculation13Choice of Apparatus and Test Method 7Cleaning Solid Specimens 10.1Conditioning of Specimens11Effective Area of Guarded ElectrodeAppendix X2Electrode Systems6Factors Affecting Insulation Resistance or Conductance Measurements Appendix X1Humidity Control11.2Liquid Specimens and Cells 9.4Precision and Bias15Procedure for the Measurement of Resist-ance or Conductance 12Referenced Documents 2Report 14Sampling8Significance and Use 5Specimen Mounting10Summary of Test Methods4Terminology3Test Specimens for Insulation,Volume,and Surface Resistance or Conductance Determination 9Typical Measurement MethodsAppendix X31.5This 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 appro-priate safety and health practices and determine the applica-bility of regulatory limitations prior to use.2.Referenced Documents 2.1ASTM Standards:2D 150Test Methods for AC Loss Characteristics and Per-mittivity (Dielectric Constant)of Solid Electrical Insula-tionD 374Test Methods for Thickness of Solid Electrical Insu-lationD 1169Test Method for Specific Resistance (Resistivity)of Electrical Insulating LiquidsD 1711Terminology Relating to Electrical InsulationD 4496Test Method for D-C Resistance or Conductance of Moderately Conductive MaterialsD 5032Practice for Maintaining Constant Relative Humid-ity by Means of Aqueous Glycerin SolutionsD 6054Practice for Conditioning Electrical Insulating Ma-terials for TestingE 104Practice for Maintaining Constant Relative Humidity by Means of Aqueous Solutions3.Terminology3.1Definitions —The following definitions are taken from Terminology D 1711and apply to the terms used in the text of this standard.3.1.1conductance,insulation ,n —the ratio of the total volume and surface current between two electrodes (on or in a specimen)to the dc voltage applied to the two electrodes.3.1.1.1Discussion —Insulation conductance is the recipro-cal of insulation resistance.1These test methods are under the jurisdiction of ASTM Committee D09on Electrical and Electronic Insulating Materials and are the direct responsibility of Subcommittee D09.12on Electrical Tests.Current edition approved May 15,2007.Published June 2007.Originally approved in st previous edition approved in 2005as D 257–99(2005).2For referenced ASTM standards,visit the ASTM website,,or contact ASTM Customer Service at service@.For Annual Book of ASTM Standards volume information,refer to the standard’s Document Summary page on the ASTM website.1*A Summary of Changes section appears at the end of this standard.Copyright ©ASTM International,100Barr Harbor Drive,PO Box C700,West Conshohocken,PA 19428-2959,United States.w w.bz f x w .c o mductance is the reciprocal of surface resistance.3.1.3conductance,volume ,n —the ratio of the current in the volume of a specimen between two electrodes (on or in the specimen)to the dc voltage applied to the two electrodes.3.1.3.1Discussion —V olume conductance is the reciprocal of volume resistance.3.1.4conductivity,surface ,n —the surface conductance multiplied by that ratio of specimen surface dimensions (dis-tance between electrodes divided by the width of electrodes defining the current path)which transforms the measured conductance to that obtained if the electrodes had formed the opposite sides of a square.3.1.4.1Discussion —Surface conductivity is expressed in siemens.It is popularly expressed as siemens/square (the size of the square is immaterial).Surface conductivity is the reciprocal of surface resistivity.3.1.5conductivity,volume ,n —the volume conductance multiplied by that ratio of specimen volume dimensions (distance between electrodes divided by the cross-sectional area of the electrodes)which transforms the measured conduc-tance to that conductance obtained if the electrodes had formed the opposite sides of a unit cube.3.1.5.1Discussion —V olume conductivity is usually ex-pressed in siemens/centimetre or in siemens/metre and is the reciprocal of volume resistivity.3.1.6moderately conductive ,adj —describes a solid mate-rial having a volume resistivity between 1and 10000000V -cm.3.1.7resistance,insulation,(R i ),n —the ratio of the dc voltage applied to two electrodes (on or in a specimen)to the total volume and surface current between them.3.1.7.1Discussion —Insulation resistance is the reciprocal of insulation conductance.3.1.8resistance,surface,(R s ),n —the ratio of the dc voltage applied to two electrodes (on the surface of a specimen)to the current between them.3.1.8.1Discussion —(Some volume resistance is unavoid-ably included in the actual measurement.)Surface resistance is the reciprocal of surface conductance.3.1.9resistance,volume,(R v ),n —the ratio of the dc voltage applied to two electrodes (on or in a specimen)to the current in the volume of the specimen between the electrodes.3.1.9.1Discussion —V olume resistance is the reciprocal of volume conductance.3.1.10resistivity,surface,(r s ),n —the surface resistance multiplied by that ratio of specimen surface dimensions (width of electrodes defining the current path divided by the distance between electrodes)which transforms the measured resistance to that obtained if the electrodes had formed the opposite sides of a square.multiplied by that ratio of specimen volume dimensions (cross-sectional area of the specimen between the electrodes divided by the distance between electrodes)which transforms the measured resistance to that resistance obtained if the electrodes had formed the opposite sides of a unit cube.3.1.11.1Discussion —Volume resistivity is usually ex-pressed in ohm-centimetres (preferred)or in ohm-metres.V olume resistivity is the reciprocal of volume conductivity.4.Summary of Test Methods4.1The resistance or conductance of a material specimen or of a capacitor is determined from a measurement of current or of voltage drop under specified conditions.By using the appropriate electrode systems,surface and volume resistance or conductance may be measured separately.The resistivity or conductivity can then be calculated when the required speci-men and electrode dimensions are known.5.Significance and Use5.1Insulating materials are used to isolate components of an electrical system from each other and from ground,as well as to provide mechanical support for the components.For this purpose,it is generally desirable to have the insulation resis-tance as high as possible,consistent with acceptable mechani-cal,chemical,and heat-resisting properties.Since insulation resistance or conductance combines both volume and surface resistance or conductance,its measured value is most useful when the test specimen and electrodes have the same form as is required in actual use.Surface resistance or conductance changes rapidly with humidity,while volume resistance or conductance changes slowly although the final change may eventually be greater.5.2Resistivity or conductivity may be used to predict,indirectly,the low-frequency dielectric breakdown and dissi-pation factor properties of some materials.Resistivity or conductivity is often used as an indirect measure of:moisture content,degree of cure,mechanical continuity,or deterioration of various types.The usefulness of these indirect measure-ments is dependent on the degree of correlation established by supporting theoretical or experimental investigations.A de-crease of surface resistance may result either in an increase of the dielectric breakdown voltage because the electric field intensity is reduced,or a decrease of the dielectric breakdown voltage because the area under stress is increased.5.3All the dielectric resistances or conductances depend on the length of time of electrification and on the value of applied voltage (in addition to the usual environmental variables).These must be known and reported to make the measured value of resistance or conductance meaningful.Within the electrical insulation materials industry,the adjective “apparent”is gen-erally applied to resistivity values obtained under conditions of arbitrarily selected electrification time.See X1.4.5.4V olume resistivity or conductivity can be calculated from resistance and dimensional data for use as an aid in2w w.bz f x w .c oinsulating material,either with regard to processing or to detect conductive impurities that affect the quality of the material and that may not be readily detectable by other methods.5.5V olume resistivities above 1021V ·cm (1019V ·m),cal-culated from data obtained on specimens tested under usual laboratory conditions,are of doubtful validity,considering the limitations of commonly used measuring equipment.5.6Surface resistance or conductance cannot be measured accurately,only approximated,because some degree of volume resistance or conductance is always involved in the measure-ment.The measured value is also affected by the surface contamination.Surface contamination,and its rate of accumu-lation,is affected by many factors including electrostatic charging and interfacial tension.These,in turn,may affect the surface resistivity.Surface resistivity or conductivity can be considered to be related to material properties when contami-nation is involved but is not a material property of electrical insulation material in the usual sense.6.Electrode Systems6.1The electrodes for insulating materials should be of a material that is readily applied,allows intimate contact with the specimen surface,and introduces no appreciable error because of electrode resistance or contamination of the specimen (5).The electrode material should be corrosion-resistant under the conditions of test.For tests of fabricated specimens such as feed-through bushings,cables,etc.,the electrodes employed are a part of the specimen or its mounting.Measurements of insulation resistance or conductance,then,include the contami-nating effects of electrode or mounting materials and are generally related to the performance of the specimen in actual use.6.1.1Binding-Post and Taper-Pin Electrodes ,Fig.1and Fig.2,provide a means of applying voltage to rigid insulating materials to permit an evaluation of their resistive or conduc-tive properties.These electrodes simulate to some degree the actual conditions of use,such as binding posts on instrument panels and terminal strips.In the case of laminated insulating materials having high-resin-content surfaces,somewhat lower insulation resistance values may be obtained with taper-pin than with binding posts,due to more intimate contact with the body of the insulating material.Resistance or conductance values obtained are highly influenced by the individual contact between each pin and the dielectric material,the surface roughness of the pins,and the smoothness of the hole in the dielectric material.Reproducibility of results on different specimens is difficult to obtain.6.1.2Metal Bars in the arrangement of Fig.3were prima-rily devised to evaluate the insulation resistance or conduc-tance of flexible tapes and thin,solid specimens as a fairly simple and convenient means of electrical quality control.This arrangement is somewhat more satisfactory for obtaining approximate values of surface resistance or conductance when the width of the insulating material is much greater than its thickness.3The boldface numbers in parentheses refer to the list of references appended to these test methods.FIG.1Binding-Post Electrodes for Flat,Solid SpecimensFIG.2Taper-Pin Electrodes3w w.bz f x w .c o6.1.3Silver Paint ,Fig.4,Fig.5,and Fig.6,is available commercially with a high conductivity,either air-drying or low-temperature-baking varieties,which are sufficiently po-rous to permit diffusion of moisture through them and thereby allow the test specimen to be conditioned after the application of the electrodes.This is a particularly useful feature in studying resistance-humidity effects,as well as change with temperature.However,before conductive paint is used as an electrode material,it should be established that the solvent in the paint does not attack the material so as to change itselectrical properties.Reasonably smooth edges of guard elec-trodes may be obtained with a fine-bristle brush.However,for circular electrodes,sharper edges can be obtained by the use of a ruling compass and silver paint for drawing the outline circles of the electrodes and filling in the enclosed areas by brush.A narrow strip of masking tape may be used,provided the pressure-sensitive adhesive used does not contaminate the surface of the specimen.Clamp-on masks also may be used if the electrode paint is sprayed on.6.1.4Sprayed Metal ,Fig.4,Fig.5,and Fig.6,may be used if satisfactory adhesion to the test specimen can be obtained.Thin sprayed electrodes may have certain advantages in that they are ready for use as soon as applied.They may be sufficiently porous to allow the specimen to be conditioned,but this should be verified.Narrow strips of masking tape or clamp-on masks must be used to produce a gap between the guarded and the guard e a tape that is known not to contaminate the gap surface.6.1.5Evaporated Metal may be used under the same con-ditions given in 6.1.4.6.1.6Metal Foil ,Fig.4,may be applied to specimen surfaces as electrodes.The usual thickness of metal foil used for resistance or conductance studies of dielectrics ranges from 6to 80µm.Lead or tin foil is in most common use,and is usually attached to the test specimen by a minimum quantity of petrolatum,silicone grease,oil,or other suitable material,as an adhesive.Such electrodes shall be applied under a smoothing pressure sufficient to eliminate all wrinkles,and to work excess adhesive toward the edge of the foil where it can be wiped off with a cleansing tissue.One very effective method is to use a hard narrow roller (10to 15mm wide),and to roll outward on the surface until no visible imprint can be made on the foil with the roller.This technique can be used satisfactorily only on specimens that have very flat surfaces.With care,the adhesive film can be reduced to 2.5µm.As this film is in series with theFIG.3Strip Electrodes for Tapes and Flat,Solid SpecimensFIG.4Flat Specimen for Measuring Volume and SurfaceResistances or ConductancesFIG.5Tubular Specimen for Measuring Volume and SurfaceResistances or Conductances4w w.bz f x w .c ospecimen,it will always cause the measured resistance to be too high.This error may become excessive for the lower-resistivity specimens of thickness less than 250µm.Also the hard roller can force sharp particles into or through thin films (50µm).Foil electrodes are not porous and will not allow the test specimen to condition after the electrodes have been applied.The adhesive may lose its effectiveness at elevated temperatures necessitating the use of flat metal back-up plates under pressure.It is possible,with the aid of a suitable cutting device,to cut a proper width strip from one electrode to form a guarded and guard electrode.Such a three-terminal specimen normally cannot be used for surface resistance or conductance measurements because of the grease remaining on the gap surface.It may be very difficult to clean the entire gap surface without disturbing the adjacent edges of the electrode.6.1.7Colloidal Graphite ,Fig.4,dispersed in water or other suitable vehicle,may be brushed on nonporous,sheet insulat-ing materials to form an air-drying electrode.Masking tapes or clamp-on masks may be used (6.1.4).This electrode material is recommended only if all of the following conditions are met:6.1.7.1The material to be tested must accept a graphite coating that will not flake before testing,6.1.7.2The material being tested must not absorb water readily,and6.1.7.3Conditioning must be in a dry atmosphere (Proce-dure B,Practice D 6054),and measurements made in this same atmosphere.6.1.8Liquid metal electrodes give satisfactory results and may prove to be the best method to achieving the contact to the specimen necessary for effective resistance measurements.The liquid metal forming the upper electrodes should be confined by stainless steel rings,each of which should have its lower rimreduced to a sharp edge by beveling on the side away from the liquid metal.Fig.7and Fig.8show two possible electrode arrangements.6.1.9Flat Metal Plates ,Fig.4,(preferably guarded)may be used for testing flexible and compressible materials,both at room temperature and at elevated temperatures.They may be circular or rectangular (for tapes).To ensure intimate contact with the specimen,considerable pressure is usually required.FIG.6Conducting-PaintElectrodesFIG.7Liquid Metal Electrodes for Flat,Solid Specimens5w w.bz f x w .c oPressures of 140to 700kPa have been found satisfactory (see material specifications).6.1.9.1A variation of flat metal plate electrode systems is found in certain cell designs used to measure greases or filling compounds.Such cells are preassembled and the material to be tested is either added to the cell between fixed electrodes or the electrodes are forced into the material to a predetermined electrode spacing.Because the configuration of the electrodes in these cells is such that the effective electrode area and the distance between them is difficult to measure,each cell constant,K ,(equivalent to the A/t factor from Table 1)can be derived from the following equation:K 53.6p C 511.3C (1)where:K has units of centimetres,andC has units of picofarads and is the capacitance of the electrode system withair as the dielectric.See Test Methods D 150for methods of measurement for C.6.1.10Conducting Rubber has been used as electrode ma-terial,as in Fig.4,and has the advantage that it can quickly and easily be applied and removed from the specimen.As the electrodes are applied only during the time of measurement,they do not interfere with the conditioning of the specimen.The conductive-rubber material must be backed by proper plates and be soft enough so that effective contact with the specimen is obtained when a reasonable pressure is applied.N OTE 1—There is evidence that values of conductivity obtained using conductive-rubber electrodes are always smaller (20to 70%)than values obtained with tinfoil electrodes (6).When only order-of-magnitude accuracies are required,and these contact errors can be neglected,a properly designed set of conductive-rubber electrodes can provide a rapid means for making conductivity and resistivity determinations.6.1.11Water is widely employed as one electrode in testing insulation on wires and cables.Both ends of the specimen mustconcentration of 1.0to 1.1%NaCl to ensure adequate conduc-tivity.Measurements at temperatures up to about 100°C have been reported as feasible.7.Choice of Apparatus and Test Method7.1Power Supply —A source of very steady direct voltage is required (see X1.7.3).Batteries or other stable direct voltage supplies have been proven suitable for use.7.2Guard Circuit —Whether measuring resistance of an insulating material with two electrodes (no guard)or with a three-terminal system (two electrodes plus guard),consider how the electrical connections are made between the test instrument and the test specimen.If the test specimen is at some distance from the test instrument,or the test specimen is tested under humid conditions,or if a relatively high (1010to 1015ohms)specimen resistance is expected,spurious resis-tance paths can easily exist between the test instrument and test specimen.A guard circuit is necessary to minimize interference from these spurious paths (see also X1.9).7.2.1With Guard Electrode —Use coaxial cable,with the core lead to the guarded electrode and the shield to the guard electrode,to make adequate guarded connections between the test equipment and test specimen.Coaxial cable (again with the shield tied back to the guard)for the unguarded lead is not mandatory here (or in 7.2.2),although its use provides some reduction in background noise (see also Fig.9).7.2.2Without Guard Electrode —Use coaxial cable,with the core lead to one electrode and the shield terminated about 1cm from the end of the core lead (see also Fig.10).7.3Direct Measurements —The current through a specimen at a fixed voltage is measured using any equipment that has the required sensitivity and accuracy (610%is usually adequate).Current-measuring devices available include electrometers,d-c amplifiers with indicating meters,and galvanometers.Typical methods and circuits are given in Appendix X3.When the measuring device scale is calibrated to read ohms directly no calculations are required for resistance measurements.7.4Comparison Methods —A Wheatstone-bridge circuit may be used to compare the resistance of the specimen with that of a standard resistor (see Appendix X3).7.5Precision and Bias Considerations :7.5.1General —As a guide in the choice of apparatus,the pertinent considerations are summarized in Table 2,but it is not implied that the examples enumerated are the only ones applicable.This table is not intended to indicate the limits of sensitivity and error of the various methods per se ,but rather is intended to indicate limits that are distinctly possible with modern apparatus.In any case,such limits can be achieved or exceeded only through careful selection and combination of the apparatus employed.It must be emphasized,however,that the errors considered are those of instrumentation only.Errors such as those discussed in Appendix X1are an entirely different matter.In this latter connection,the last column of Table 2lists the resistance that is shunted by the insulation resistanceFIG.8Liquid Metal Cell for Thin Sheet Material6w w.bz f x w .c obetween the guarded electrode and the guard system for the various methods.In general,the lower such resistance,the less probability of error from undue shunting.N OTE 2—No matter what measurement method is employed,the highest precisions are achieved only with careful evaluation of all sources of error.It is possible either to set up any of these methods from the component parts,or to acquire a completely integrated apparatus.In general,the methods using high-sensitivity galvanometers require a more permanent installation than those using indicating meters or recorders.The methods using indicating devices such as voltmeters,galvanometers,d-c amplifiers,and electrometers require the minimum of manual adjustment and are easy to read but the operator is required to make the reading at a particular time.The Wheatstone bridge (Fig.X1.4)and the potentiometer method (Fig.X1.2(b ))require the undivided attention of the operator in keeping a balance,but allow the setting at a particular time to be read at leisure.7.5.2Direct Measurements :7.5.2.1Galvanometer-Voltmeter —The maximum percent-age error in the measurement of resistance by thegalvanometer-voltmeter method is the sum of the percentage errors of galvanometer indication,galvanometer readability,and voltmeter indication.As an example:a galvanometer having a sensitivity of 500pA/scale division will be deflected 25divisions with 500V applied to a resistance of 40G V (conductance of 25pS).If the deflection can be read to the nearest 0.5division,and the calibration error (including Ayrton Shunt error)is 62%of the observed value,the resultant galvanometer error will not exceed 64%.If the voltmeter has an error of 62%of full scale,this resistance can be measured with a maximum error of 66%when the voltmeter reads full scale,and 610%when it reads one-third full scale.The desirability of readings near full scale are readily apparent.7.5.2.2Voltmeter-Ammeter —The maximum percentage er-ror in the computed value is the sum of the percentage errors in the voltages,V x and V s ,and the resistance,R s .The errors in V s and R s are generally dependent more on the characteristicsr v 5A t R v g v 5t A G v Circular (Fig.4)r v 5A t R v g v 5t A G v A 5p ~D 11g !24Rectangular r v 5A t R v g v 5t A G v A =(a +g)(b +g)Square r v 5A t R v g v 5t A G v A =(a +g)2Tubes (Fig.5)r v 5A t R vg v 5t A G v A =p D 0(L +g)Cablesr v 52p LR vln D 2D 1g v 5lnD 2D 12p LR vSurface Resistivity,V (per square)Surface Conductivity,S (per square)Effective Perimeter of Guarded Electrodep s 5P g R sg s 5gP G sCircular (Fig.4)p s 5P g R s g s 5g P G s P =p D 0Rectangular p s 5P g R s g s 5g P G s P =2(a +b +2g)Squarep s 5P g R s g s 5g P G s P =4(a +g)Tubes (Figs.5and 6)p s 5P g R sg s 5g P G sP =2p D 2Nomenclature:A =the effective area of the measuring electrode for the particular arrangement employed,P =the effective perimeter of the guarded electrode for the particular arrangement employed,R v =measured volume resistance in ohms,G v =measured volume conductance in siemens,R s =measured surface resistance in ohms,G s =measured surface conductance in siemens,t =average thickness of the specimen,D 0,D 1,D 2,g,L =dimensions indicated in Fig.4and Fig.6(see Appendix X2for correction to g ),a,b,=lengths of the sides of rectangular electrodes,and ln =natural logarithm.AAll dimensions are in centimetres.7w w.bz f x w .c oof the apparatus used than on the particular method.The most significant factors that determine the errors in V s are indicator errors,amplifier zero drift,and amplifier gain stability.Withis virtually nonexistent for carefully designed converter-type amplifiers.Consequently,the null method of Fig.X1.2(b )is theoretically less subject to error than those methods employ-ing an indicating instrument,provided,however,that the potentiometer voltage is accurately known.The error in R s is to some extent dependent on the amplifier sensitivity.For mea-surement of a given current,the higher the amplifier sensitivity,the greater likelihood that lower valued,highly precise wire-wound standard resistors can be used.Such amplifiers can be obtained.Standard resistances of 100G V known to 62%,are available.If 10-mV input to the amplifier or electrometer gives full-scale deflection with an error not greater than 2%of full scale,with 500V applied,a resistance of 5000T V can be measured with a maximum error of 6%when the voltmeter reads full scale,and 10%when it reads 1⁄3scale.7.5.2.3Comparison-Galvanometer —The maximum per-centage error in the computed resistance or conductance is given by the sum of the percentage errors in R s ,the galvanom-eter deflections or amplifier readings,and the assumption that the current sensitivities are independent of the deflections.The latter assumption is correct to well within 62%over the useful range (above 1⁄10full-scale deflection)of a good,modern galvanometer (probably 1⁄3scale deflection for a dc current amplifier).The error in R s depends on the type of resistor used,but resistances of 1M V with a limit of error as low as 0.1%are available.With a galvanometer or d-c current amplifier having a sensitivity of 10nA for full-scale deflection,500V applied to a resistance of 5T V will produce a 1%deflection.At this voltage,with the preceding noted standard resistor,and with F s =105,d s would be about half of full-scale deflection,with a readability error not more than 61%.If d x is approxi-mately 1⁄4of full-scale deflection,the readability error would not exceed 64%,and a resistance of the order of 200G V could be measured with a maximum error of 651⁄2%.7.5.2.4Voltage Rate-of-Change —The accuracy of the mea-surement is directly proportional to the accuracy of the measurement of applied voltage and time rate of change of the electrometer reading.The length of time that the electrometer switch is open and the scale used should be such that the time can be measured accurately and a full-scale reading obtained.Under these conditions,the accuracy will be comparable with that of the other methods of measuring current.7.5.2.5Comparison Bridge —When the detector has ad-equate sensitivity,the maximum percentage error in the com-puter resistance is the sum of the percentage errors in the arms,A,B,and N .With a detector sensitivity of 1mV/scale division,500V applied to the bridge,and R N =1G V ,a resistance of 1000T V will produce a detector deflection of one scale division.Assuming negligible errors in R A and R B ,with R N =1G V known to within 62%and with the bridge balanced to one detector-scale division,a resistance of 100T V can be mea-sured with a maximum error of 66%.FIG.9Connections to Guarded Electrode for Volume and Surface Resistivity Measurements (Volume Resistance hook-up shown)FIG.10Connections to Unguarded Electrodes for Volume and Surface Resistivity Measurements (Surface Resistance Hook-UpShown)8w w.bz f x w .c o。

Forpersonaluseonlyinstudyandresearch;notforcommercialuse肆Forpersonaluseonlyinstudyandresearch;notforcommercialuse节膁常见的塑料检测标准和方法薇检测项目/参数羈检测产羄检测标准(方法)名称及编号(含年号)肇品/类别序蚄名称号肅光源暴露试验膇1膄塑料实验室光源暴露试验方法第1部分:通则ISO4892-1:1999方法通则薂汽车外饰材料的氙弧灯加速暴露试验SAEJ2527:2004虿塑料芄汽车内饰材料的氙弧灯加速暴露试验SAEJ2412:2004 膇2蒆氙弧灯光老化塑料实验室光源暴露试验方法第2部分:氙弧灯ISO4892-2:2006/Amd1:2009室内用塑料氙弧光暴露试验方法ASTMD4459-06.薇检测项目/参数羈检测产羄检测标准(方法)名称及编号(含年号)肇品/类别序蚄名称号非金属材料氙弧灯老化的仪器操作方法ASTMG155-05a塑料暴露试验用有水或无水氙弧型曝光装置的操作ASTMD2565-99(2008)塑料实验室光源暴露试验方法第3部分:荧光紫外灯ISO4892-3:2006汽车外饰材料UV快速老化测试SAEJ2020:20033荧光紫外灯老化塑料紫外光暴露试验方法ASTMD4329-05非金属材料UV老化的仪器操作方法ASTMG154-06塑料实验室光源暴露试验方法第4部分:开放式碳弧灯ISO4892-4:2004/CORR1:20054碳弧灯老化塑料实验室光源曝露试验方法第4部分:开放式碳弧灯GB/T16422.4-1996机械工业产品用塑料、涂料、橡胶材料人工气候老化试验方法荧5荧光紫外灯老化光紫外灯GB/T14522-2008无负荷塑料制品的热老化ASTMD3045-92(2010)6热老化塑料热老化试验方法GB/T7141-2008塑料暴露于湿热、水溅和盐雾效应的测定ISO4611:2008 7湿热老化塑料暴露于湿热、水喷雾和盐雾中影响的测定GB/T12000-2003塑料拉伸性能的测定第1部分:总则GB/T1040.1-2006塑料拉伸性能的测定第2部分:模塑和挤塑塑料的试验条件GB/T1040.2-2006塑料拉伸性能的测定第3部分:薄膜和薄片的试验条件塑料8拉伸性能GB/T1040.3-2006塑料拉伸性能的测定第4部分:各向同性和正交各向异性纤维增强复合材料的试验条件GB/T1040.4-2006塑料拉伸性能的测定第5部分:单项纤维增强复合材料的试验条.薇检测项目/参数羈检测产羄检测标准(方法)名称及编号(含年号)肇品/类别序蚄名称号件GB/T1040.5-2008塑料拉伸性能的试验方法ASTMD638-10塑料拉伸性能的测定第1部分:一般原则ISO527-1:1993/Amd1:2005塑料拉伸性能的测定第2部分:模压和挤压塑料试验条件ISO527-2:1993/CORR1:1994塑料拉伸性能的测定第3部分:薄膜和薄板材试验条件ISO527-3:1995/CORR1:1998/CORR2:2001塑料拉伸性能的测定第4部分:各向同性和正交各向异性纤维增强复合材料的试验条件ISO527-4:1997塑料拉伸性能的测定第5部分:单项纤维增强复合材料的试验条件ISO527-5:2009塑料弯曲性能的测定GB/T9341-20089弯曲性能塑料和电绝缘材料弯曲性能试验方法ASTMD790-10塑料.弯曲性能测定BSENISO178–2003塑料简支梁冲击性能的测定第一部分:非仪器化冲击试验GB/T1043.1-200810简支梁冲击塑料缺口试样的CHARPY冲击强度的试验方法ASTMD6110–10塑料摆锤式CHARPY冲击特性的测定第1部分:非仪器冲击试验ISO179–1:2010塑料悬臂梁冲击强度的测定GB/T1843-200811悬臂梁冲击强度塑料IZOD冲击强度的试验方法ASTMD256-10塑料IZOD冲击强度的测定ISO180:2000/Amd1:2006 12硬度塑料硬度测定第二部分:洛氏硬度GB/T3398.2-2008塑料负荷变形温度的测定第1部分:通用试验方法13热变形温度GB/T1634.1-2004.薇检测项目/参数羈检测产羄检测标准(方法)名称及编号(含年号)肇品/类别序蚄名称号在挠曲负荷下塑料的挠曲温度的试验方法ASTMD648-07塑料载荷下挠曲温度的测定第1部分:一般试验方法ISO 13热变形温度75-1:2004塑料载荷下挠曲温度的测定第2部分:塑料和硬橡胶ISO75-2:2004热塑性塑料维卡软化温度(VST)的测定GB/T1633-2000 14维卡软化温度塑料维卡(Vicat)软化温度的测试方法ASTMD1525-09塑料热塑材料维卡软化温度的测定ISO306:2004塑料压缩性能的测定GB/T1041-200815压缩性能塑料压缩性能试验方法ISO604:2002硬塑料的压缩特性试验方法ASTMD695-1016撕裂性能塑料直角撕裂性能试验方法QB/T1130-1991塑料固体绝缘材料体积电阻率和表面电阻率试验方法GB/T1410-2006体积电阻率/表17绝缘材料表面电阻和体积电阻试验方法IEC60093:1980面电阻率绝缘材料直流电阻或电导试验方法ASTMD257-07塑料大气暴露试验方法GB/T3681-200018大气暴露塑料暴露于太阳辐射的方法第一部分:通则ISO877-1:2009塑料长期热暴露后时间—温度极限测定GB/T7142-2002 19时间—温度极限聚合物长期性能评估UL746B-2010塑料在玻璃下日光、自然气候或实验室光源暴露后颜色和性能变化的测定GB/T15596-200920塑料老化评价塑料在玻璃下日光、自然气候或实验室光源暴露后颜色和性能变化的测定ISO4582:200721变色评定纺织品色牢度试验评定变色用灰色样卡GB/T250-200822熔融指数热塑性塑料熔体质量流动速率和熔体体积流动速率的测定.薇检测项目/参数羈检测产羄检测标准(方法)名称及编号(含年号)肇品/类别序蚄名称号GB/T3682-2000绝缘材料电气强度试验方法第一部分:工频下试验23击穿电压GB/T1408.1-200624热应力开裂电线电缆用黑色聚乙烯塑料GB/T15065-2009附录A聚乙烯环境应力开裂试验方法GB/T1842-200825环境应力开裂聚乙烯环境应力开裂试验方法ASTMD1693-08设备和器具部件用塑料材料易燃性的试验UL94-2009 26垂直与水平燃烧塑料燃烧性能的测定水平法和垂直法GB/T2408-2008用氧指数法测定燃烧行为第1部分:导则GB/T2406.1-2008用氧指数法测定燃烧行为第2部分:室温试验GB/T2406.2-200927氧指数用氧指数法测定燃烧行为第1部分:导则ISO4589-1:1996用氧指数法测定燃烧行为第2部分:室温试验ISO4589-2:1996/Amd1:2005塑料吸水性试验方法ASTMD570-98(2005)28吸水性塑料吸水性试验方法GB/T1034-2008塑料塑料吸水性试验方法ISO62:2008(E)非泡沫塑料密度的测定第1部分浸渍法、液体比重瓶法和滴定法ISO1183.1-200429密度非泡沫塑料密度的测定第1部分浸渍法、液体比重瓶法和滴定法GB/T1033.1-2008塑料相对密度和密度试验方法–置换法ASTMD792-08固化的增强树脂燃烧损失的试验方法ASTMD2584-08 30灰分塑料.灰份的测定第1部分:一般方法ISO3451-1:2008塑料灰分的测定第一部分:通用方法GB/T9345.1-2008 31透光率透明塑料透光率和雾度试验方法ASTMD1003-11e1.薇检测项目/参数羈检测产羄检测标准(方法)名称及编号(含年号)肇品/类别序蚄名称号透明塑料透光率和雾度试验方法GB/T2410-2008透明塑料透光率和雾度试验方法ASTMD1003-07e132雾度透明塑料透光率和雾度试验方法GB/T2410-2008塑料差示扫描量热法(DSC)第1部分:通则GB/T19466.1-2004 33差示扫描量热塑料.差示扫描量热法(DSC).第1部分总则ISO11357-1-2009塑料差示扫描量热法(DSC)第2部分:玻璃化转变温度的测定GB/T19466.2-200434玻璃化转变温度塑料差示扫描量热法(DSC)第2部分:玻璃传导温度的测定ISO11357-2-1999塑料差示扫描量热法(DSC)第3部分:熔融和结晶温度及热焓的测定GB/T19466.3-2004熔融和结晶温度35及热焓塑料差示扫描量热法(DSC)第3部分:熔化和结晶焓和温度的测定ISO11357-3-2011塑料差示扫描量热法(DSC)第6部分:氧化诱导时间(等温OIT)和氧化诱导温度(动态OIT)的测定GB/T19466.6-2009氧化诱导时间和36氧化诱导温度塑料差示扫描量热法(DSC)第6部分:氧化诱导时间(等温OIT)和氧化诱导温度(动态OIT)的测定ISO11357-6-2008塑料热塑性塑料颗粒外观试验方法SH/T1541-2006热塑性塑料颗粒37外观试验金属穿孔板试验筛GB/T6003.2-1997电线电缆用黑色聚乙烯塑料GB15065-2009附录A38炭黑分散度桥梁缆索用高密度聚乙烯护套料CJ/T297-200839炭黑含量聚乙烯管材和管件炭黑含量的测定(热失重法)GB13021-1991塑料冲击法脆化温度的测定GB/T5470-200840脆化温度塑料.冲击脆化温度的测定ISO974-2000塑料.冲击脆化温度的测定ASTMD746-2007..薇检测项目/参数羈检测产羄检测标准(方法)名称及编号(含年号)肇品/类别序蚄名称号41邵氏硬度塑料和硬橡胶使用硬度计测定压痕硬度ISO868-2003塑料薄膜和薄片摩擦系数测定方法动态及静态摩擦GB/T10006-198842系数塑料薄膜和薄片摩擦系数测定方法ISO8295-1995 43塑料粒表观密度塑料能从规定漏斗流出的材料表观密度的测定GB/T1636-2008 橡胶和塑料软耐臭氧性能橡胶和塑料软管静态条件下耐臭氧性能的评价GB/T24134-2009管汽车内饰材料燃1汽车内饰材料的燃烧特性GB8410-2006烧性能汽车零部件耐候2汽车零部件耐候性试验一般规则QC/T17-2009性试验汽车塑料制品通3汽车塑料制品通用试验方法QC/T15-1992用试验方法轿车内饰材料散4轿车内饰材料散发性能测试标准TS-INT-001-2009发性能测试标准汽车材料汽车内饰件雾化5大众标准雾化测试PV3015-1994检测方法汽车内饰件气味6大众标准气味测试PV3900-2000检测方法汽车内饰件有机7大众标准有机物散发测试PV3341-1995物散发检测方法汽车内饰件甲醛8大众标准甲醛散发PV3925-1994散发检测方法如何选择塑料检测设备..随着科学技术的进，各种新型材料层，尤其是高分子材料在近几年有了飞 速的发展。

常见的塑料检测标准和方法如何选择塑料检测设备随着科学技术的突飞猛进，各种新型材料层出不穷，尤其是高分子材料在近几年有了飞速的发展。

塑料材料作为其分支，目前在某些领域已经可以取代木材、金属材料。

为了使塑料材料及其制品能够安全可靠的使用，对其进行力学性能检验是非常必要的。

1、常规电子万能材料试验机该类试验机是万能材料试验机的主流产品，它以伺服电机作为动力源，丝杠、丝母作为执行元件，实现试验机移动横梁的速度控制，具有操作简单，对试验员的要求不高，试验行程可按需要任意定制。

虽然控制方式较为单一，但其控制精度和控制范围很高、很宽。

如越联YL-1107拉力试验机，分辨率为1/250000，力量精度≤±0.5%，其速度调整范围可达5mm/min~500mm/min，无级调速，小吨位机型很容易实现。

如做摩擦系数时，满值负载只有5N.具有极大的配置灵活性，如果增配不同吨位的传感器、夹具、附件、可实现一机多用。

完成拉、压、弯、剪、剥离、撕裂、摩擦系数、扭转等的功能。

根据塑料力学性能检验的相关标准，无论从控制方式还是速度范围、试验行程及试验机的吨位看，该类机型都是塑料力学性能检验的首选。

2、三闭环电子万能材料试验机该类试验机具有常规电子万能类试验机的速度范围宽，试验行程大，配置灵活的特点，又具有电液伺服类试验机力、位移、变形控制的优点。

因而是性能较好的一种试验机，但该类试验机很少有10KN以下的机型，塑料类最常用的不易选择做塑料材料的试验。

3、简易电拉由于塑料拉伸强度是塑料力学性能检验的一个非常重要的指标，在前些年，塑料种类还不是很多，应用也不是非常广的时期，国家标准对塑料要求的力学性能检验项目比较为单一。

一种价格低廉用途单一，以电机作为动力源的拉伸试验机俗称电拉被广泛使用。

这种设备只能用来做单一的拉伸试验，能处理的数据非常有限，控制测量精度也相对较低，现在虽然在某些场合依然有所使用，但因其功能比较单一，已经逐渐为市场所淘汰。

ASTM D257-07 中文版绝缘材料直流电阻和电导测试.…ASTMD绝缘材料直流电阻或电导的标准试验方法本标准是以固定代号D发布的。

其后的数字表示原文本正式通过的年号在有修订的情况下为上一次的修订年号圆括号中数字为上一次重新确认的年号。

上标符号（ε）表示对上次修改或重新确定的版本有编辑上的修改。

本标准经批准用于国防部所有机构。

1.范围本试验方法包含直流绝缘电阻体积电阻和表面电阻的测量所用直流程序。

通过该测量及样本和电极的几何尺寸可以计算出电绝缘材料的体积电阻和表面电阻同时还可以计算出相应的电导和电导率。

这些试验方法不适用于测量中等导电材料的电阻电导。

这些材料评估可采用试验方法D4496。

本标准描述了几种可选择的测量电阻（或电导）的普通方法。

特殊材料科采用最合适的标准ASTM试验方法进行测试这些特殊材料具有电压应力范围和有限起电时间同时规定了样本结构和电极几何形状。

这些个别特殊试验方法将能更好得定义测量值的精度和偏差。

本试验方法包括以下章节：试验方法或步骤章节计算 13设备和试验方法的选择 7清洗固体样本样本的状态调节 11屏蔽电极的有效面积附录X2电极系 6绝缘电阻或电导材料的影响因素附录X1湿度控制液体样本和电池精度和偏差 15电阻或电导测量步骤 12引用文件 2报告 14抽样 8重要性和用途 5样本安装 10试验方法摘要 4术语 3绝缘电阻体积电阻和表面电阻或电导测量用试验样本 9典型测量方法附录X3本标准并没有完全列举所有的安全声明如果有必要根据实际使用情况进行斟酌。

使用本规范前使用者有责任制定符合安全和健康要求的条例和规范并明确该规范的使用范围。

引用文件ASTM标准：D150固体电绝缘材料的（恒久电介质）的交流损耗特性和介电常数的测试方法D374固体电绝缘材料厚度的标准试验方法D1169电绝缘液电阻率(电阻系数)试验方法D1711电绝缘相关术语D4496中等导电材料直流电阻或导电性的标准试验方法D5032用水甘油溶液设备维持恒定相关湿度的规程D6054测试用电工绝缘材料的调节规程E104用水溶液保持相对恒定湿度的标准实施规程术语定义：以下定义直接来自术语标准D1711适用于本标准正文所用术语。