ASTM B799-95(2014)
使用亚硫酸/二氧化硫蒸汽测定金和钯涂层孔隙度的标准试验方法
Standard Test Method for Porosity in Gold and Palladium Coatings by Sulfurous Acid/Sulfur-Dioxide Vapor
ASTM B799-95(2014) 发布历史
ASTM B799-95(2014)由美国材料与试验协会 US-ASTM 发布于 1995。
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ASTM B799-95(2014) 使用亚硫酸/二氧化硫蒸汽测定金和钯涂层孔隙度的标准试验方法的最新版本是哪一版?
最新版本是 ASTM B799-95(2020) 。
ASTM B799-95(2014) 发布之时,引用了标准
- ASTM B374 电镀的相关标准术语*, 1996-01-09 更新
- ASTM B542 有关电触点及其使用的标准术语*, 2019-11-01 更新
- ASTM B735 用硝酸蒸气测定金属基材上金涂层孔隙率的标准试验方法
- ASTM B741 ASTM B741-95(2000)
- ASTM B765 电沉积镀层和相关金属镀层孔隙率试验的选择
- ASTM B798 通过凝胶体电极法在金属基底上的金或钯涂层中的孔隙率的标准测试方法*, 2020-04-01 更新
- ASTM B809 用湿硫黄蒸气("硫黄华")作金属涂层中孔隙率测试的标准试验方法*, 2024-01-09 更新
* 在 ASTM B799-95(2014) 发布之后有更新,请注意新发布标准的变化。
ASTM B799-95(2014)的历代版本如下:
- 2020年 ASTM B799-95(2020) 用亚硫酸/二氧化硫蒸气测定金和钯涂层孔隙率的标准试验方法
- 1995年 ASTM B799-95(2014) 使用亚硫酸/二氧化硫蒸汽测定金和钯涂层孔隙度的标准试验方法
- 1995年 ASTM B799-95(2009) 用亚硫酸/SO2蒸汽测试金和钯镀层孔隙度的标准试验方法
- 1995年 ASTM B799-95(2005) 用亚硫酸/SO2蒸汽测试金和钯镀层孔隙度的标准试验方法
- 2000年 ASTM B799-95(2000) 用亚硫酸/二氧化硫蒸气测定金和钯涂层孔隙率的标准试验方法
5.1 Gold coatings are often specified for the contacts of separable electrical connectors and other devices. Electrodeposits are the form of gold that is most used on contacts, although it is also employed as inlay or clad metal and as weldments on the contact surface. The intrinsic nobility of gold enables it to resist the formation of insulating oxide films that could interfere with reliable contact operation.
5.2 Palladium coatings are sometimes specified as alternatives to gold on electrical contacts and similar electrical component surfaces, both as electrodeposits and as inlay or clad metal. This test method is particularly suitable for determining porosity in palladium coatings, since the reactive atmosphere that is used does not attack the palladium if the specified test conditions are followed. In contrast, palladium coatings are attacked by nitric acid (HNO3) and other strong oxidizing agents, so that Test Method B735 cannot be used for determining the porosity in such coatings.
5.3 In order for these coatings to function as intended, porosity, cracks, and other defects in the coating that expose base-metal substrates and underplates must be minimal or absent, except in those cases where it is feasible to use the contacts in structures that shield the surface from the environment or where corrosion inhibiting surface treatments for the deposit are employed. The level of porosity in the coating that may be tolerable depends on the severity of the environment to the underplate or substrate, design factors for the contact device like the force with which it is mated, circuit parameters, and the reliability of contact operation that it is necessary to maintain. Also, when present, the location of pores on the surface is important. If the pores are few in number and are outside of the zone of contact of the mating surfaces, their presence can often be tolerated.
5.4 Methods for determining pores on a contact surface are most suitable if they enable their precise location and numbers to be determined. Contact surfaces are often curved or irregular in shape, and testing methods should be suitable for them. In addition, the severity of porosity-determining tests may vary from procedures capable of detecting all porosity to procedures that detect only highly porous conditions.
5.5 The present test method is capable of detecting virtually all porosity or other defects that could participate in corrosion reactions with the substrate or underplate. The test is rapid, simple, and inexpensive. In addition, it can be used on contacts having complex geometry such as pin-socket contacts (although with deep recesses it is preferred that the contact structures be opened to permit reaction of the sulfur dioxide with the interior significant surfaces).
5.6 The relationship of porosity levels revealed by particular tests to contact behavior must be made by the user of these tests through practical experience or by judgment. Thus, absence of porosity in the coating may be a requirement for some applications, while a few pores in the contact zone may be acceptable for others.
5.7 This test is considered destructive in that it reveals the p......
- 标准号
- ASTM B799-95(2014)
- 发布
- 1995年
- 发布单位
- 美国材料与试验协会
- 替代标准
- ASTM B799-95(2020)
- 当前最新
- ASTM B799-95(2020)
- 引用标准
- ASTM B374 ASTM B542 ASTM B735 ASTM B741 ASTM B765 ASTM B798 ASTM B809
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