The motivation of this research is to explore the viability of a method to directly verify whether or not an anaerobic adhesive within a threaded fastener assembly has cured sufficiently to provide secondary locking. Direct verification was implemented via the application of a test torque in the loosening direction of a fastener assembly with Loctite (given a 24 hour cure time). A three phase test plan was developed with the intent of identifying and utilizing this verification torque value which is unique to a given fastener assembly.
It was proved that the direct verification method, as outlined in the test plan, was in fact a valid method of verification in some cases. Results were dependent on the materials and coatings of the fastener assemblies. The curing properties of the liquid locking compound (LLC) with plain steel specimens resulted in a verification test that could accurately predict sufficient locking and cure (using distributions in torque measurements). Tests with zinc coated and stainless steel specimens, however, did not produce the same level of predictability in cure as the plain steel specimens.
The direct verification method as defined herein is not suited to certain materials and coatings. The less predictable curing properties of the stainless steel specimens caused complications in determining a verification torque that could reliably determine cure, resulting in dropping stainless steel from static and dynamic testing. The zinc coated specimen data was more consistent, but the adhesive did not add sufficient breakaway strength to the fastener assembly needed to define a usable verification value. These results led to the conclusion that the direct verification method as presented in this work is limited to more active material selections. One possibility to improve the secondary locking of less active materials is the use of a higher strength adhesive.
Testing to observe the effect of application of verification torque on the secondary locking was also performed. Multiple verifications were found to be destructive to the point that just over a third of samples failed that might have otherwise passed a single verification test. The single verification testing, on the other hand, caused substantially less locking mechanism degradation, leading to the use of a single verification torque in further testing.
Identifer | oai:union.ndltd.org:USF/oai:scholarcommons.usf.edu:etd-5277 |
Date | 01 January 2012 |
Creators | Hunter, Ryan |
Publisher | Scholar Commons |
Source Sets | University of South Flordia |
Detected Language | English |
Type | text |
Format | application/pdf |
Source | Graduate Theses and Dissertations |
Rights | default |
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