ASTM F18-1964(2006) 电子设备用玻璃金属底板评定标准规范和试验方法
时间:2024-05-17 19:29:54 来源: 标准资料网 作者:标准资料网 阅读:9312
【英文标准名称】:StandardSpecificationandTestMethodforEvaluationofGlass-to-MetalHeadersUsedinElectronDevices
【原文标准名称】:电子设备用玻璃金属底板评定标准规范和试验方法
【标准号】:ASTMF18-1964(2006)
【标准状态】:现行
【国别】:
【发布日期】:1964
【实施或试行日期】:
【发布单位】:美国材料与试验协会(US-ASTM)
【起草单位】:F01.03
【标准类型】:(TestMethod)
【标准水平】:()
【中文主题词】:玻璃;电子设备及元件;底座;金属;电子工程
【英文主题词】:electricaltesting;glasstometalsealing;mechanicaltestmethods
【摘要】:1.1Thisspecificationandtestmethodcoveracceptancerequirementsforheadersusedinelectrondevicesanddescribesproceduresfordeterminingconformancetotheserequirements.1.2Thevaluesstatedininch-poundunitsaretoberegardedasthestandard.Thevaluesgiveninparenthesesareforinformationonly.1.3Thefollowingsafetyhazardcaveatpertainsonlytothetestmethod(Sections6-12)describedinthisspecification.Thisstandarddoesnotpurporttoaddressallofthesafetyconcerns,ifany,associatedwithitsuse.Itistheresponsibilityoftheuserofthisstandardtoestablishappropriatesafetyandhealthpracticesanddeterminetheapplicabilityofregulatorylimitationspriortouse.
【中国标准分类号】:L93
【国际标准分类号】:
【页数】:5P.;A4
【正文语种】:
【英文标准名称】:Protectiveclothingagainstliquidandgaseouschemicals,includingliquidaerosolsandsolidparticles-Part1:Performancerequirementsforventilatedandnon-ventilated"gas-tight"(Type1)and"non-gas-tight"(Type2)chemicalprotectivesuits;Germa
【原文标准名称】:抗液体和气体化学制品(包括液态气溶胶和固体颗粒)的防护服.第1部分:透气式和不透气式“气密型”(1型)和“非气密型”(2型)防化服的性能要求.DINEN943-1-2002的勘误
【标准号】:DINEN943-1Berichtigung1-2006
【标准状态】:现行
【国别】:德国
【发布日期】:2006-05
【实施或试行日期】:
【发布单位】:德国标准化学会(DIN)
【起草单位】:
【标准类型】:()
【标准水平】:()
【中文主题词】:通气;气溶胶;防毒衣;呼吸管;化工防护套服;气密性;眼镜;使用说明;液态材料;作标记;最低要求;性能要求;防护服装;防护服;规范(验收);材料强度;试验;密封性;通风
【英文主题词】:
【摘要】:
【中国标准分类号】:C73
【国际标准分类号】:13_340_10
【页数】:2P.;A4
【正文语种】:德语
Product Code:SAE J2609
Title:Multi-Dimensional Thermal Properties of Insulated Heat Shield Material Systems
Issuing Committee:Formed Heat Shield Committtee
Scope:This test method measures the system material properties of an insulated formed heat shield under invehicle conditions. While the material properties of the individual components can often be determined via existing test methods, the system properties of the entire composite is typically much harder to ascertain (especially for multi-layer shields). System material properties include thermal conductivity in the lateral or in-plane (x) direction, thermal conductivity through the thickness or perpendicular (y), surface emissivity on the top and bottom sides of the shield and specific heat of the shield material.