Finite element analysis in defining the optimal shape and safety factor of retentive clasp arms of removable partial denture

Finite element analysis in defining the optimal shape and safety factor of retentive clasp arms of removable partial denture

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Bacground/Aim.Retentive force of removable partial denture (RPD) directly depends on elastic force of stretched retentive clasp arms (RCAs).During deflection RCA must have even stress distribution.

Safety hellfire sloe gin factor is the concept which can be applied in estimating durability and functionality of RCAs.This study was based on analyzing properties of clasps designed by conventional clasp wax profiles and defining the optimal shapes of RCAs for stress distribution and safety factor aspects.Methods.

Computer-aided-design (CAD) models of RCAs with simulated properties of materials used for fabrication of RPD cobalt-chromium-molybdenum (CoCrMo) alloy, commercially pure titanium (CPTi) and polyacetale were analyzed.Results.The research showed that geometrics of Rapidflex profiles from the BIOS concept are defined for designing and modeling RCAs from CoCrMo alloys.

I-Bar and Bonihard clasps made from CPTi might have the same design as Co- CrMo clasp only by safety factor aspect, but it is obvious that CPTi are much more flexible, so their shape must be more massive.Polyacetale clasps should not be fabricated by BIOS concept for CoCrMo alloy.A proof for that is the low value of napoleon concealer safety factor.

Conclusion.The BIOS concept should be used only for RCAs made of CoCrMo alloy and different wax profiles should be used for fabricating clasps of other investigated materials.The contribution of this study may be the improvement of present systems for defining the clasps shapes made from CoCrMo alloys.

The more significant application is possibility of creating new concepts in defining shapes of RCA made from CPTi and polyacetale.