DocumentCode
1117664
Title
Resistance buildup in electrical connectors due to fretting corrosion of rough surfaces
Author
Bryant, Michael D.
Author_Institution
Dept. of Mech. Eng., Texas Univ., Austin, TX, USA
Volume
17
Issue
1
fYear
1994
fDate
3/1/1994 12:00:00 AM
Firstpage
86
Lastpage
95
Abstract
A comprehensive model to predict the contact resistance during the nth fretting cycle and the ultimate usable lifetime of the contact has been developed. This model incorporates contact wipe, fretting vibration amplitude and frequency, contaminant chemistry, material properties, plating thickness, asperity deformations, normal load, electrical load, and surface topography. It is assumed that fretting vibrations separate contacting asperities and expose virgin metallic a-spots to environmental contaminant attack. The model calculates the amount of corrosive product produced on the exposed surfaces during the separation phase of a cycle of fretting. As fretting motions pull the exposed corroded asperities back together, a mismatch in size occurs and some of the corrosive product is scraped off and deposited in the valleys. Eventually, the valleys fill and separate the a-spots, resulting in “ultimate” failure. A material balance between amounts produced and scraped off estimates the amount of corrosive product dragged into the contact. Shifting of molecules via plastic deformation mix particles of corrosive product into the asperity metal. Assumptions that correlate mixing to plastic flow and the use of modern composite theory lead to an estimate of the conductivity within the contaminated asperity. Results show a monotonic increase in contact resistance over time. Initial increases are slow, followed by rapid increases. Predicted failure times are consistent with field measurements
Keywords
contact resistance; corrosion; electric connectors; failure analysis; reliability; wear; asperity deformations; contact resistance; contact wipe; contaminant chemistry; corrosive product; electrical connectors; electrical load; failure times; fretting corrosion; fretting vibration amplitude; plastic deformation; plating thickness; resistance buildup; rough surfaces; separation phase; surface topography; usable lifetime; virgin metallic a-spots; Chemistry; Connectors; Contact resistance; Deformable models; Electric resistance; Frequency; Plastics; Predictive models; Surface contamination; Surface topography;
fLanguage
English
Journal_Title
Components, Packaging, and Manufacturing Technology, Part A, IEEE Transactions on
Publisher
ieee
ISSN
1070-9886
Type
jour
DOI
10.1109/95.296373
Filename
296373
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