Experimental Validation of Riveting Process Fe Simulation

Q4 Engineering

Fatigue of Aircraft Structures Pub Date : 2018-12-01 DOI:10.2478/fas-2018-0006

Wojciech Wronicz

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引用次数: 0

Abstract

Abstract Rivets are critical areas in metal airframes from the fatigue point of view. Fatigue behaviour of riveted joints depends strongly on the residual stress system around the rivet holes. The both most convenient and most common method of determining these stresses is the Finite Element (FE) analyses. The validation of models used is necessary to ensure the reliability of results. This paper presents the validation process of the riveting FE simulations for the universal and the countersunk rivets. At first, the material model of the rivets was validated with the use of the force–displacement curves of the press stamp obtained experimentally. Because of the displacement measurement method, it was necessary to take into account the flexibility of the stand. After that, good correlation between the numerical simulations and the experiment was obtained for both rivet types. At the second stage, strains around driven heads measured with the use of strip gauge patterns were compared with the results of the FE simulations. Quite good correlation was obtained for the countersunk rivet. In the case of the universal rivet, the numerical results are significantly higher values than the measured ones. Differences in correlation of the experiments and FE simulations for the analysed rivet types probably result from material differences of the rivets.

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铆接过程Fe仿真的实验验证

摘要从疲劳角度来看，铆钉是金属机身的关键区域。铆接接头的疲劳性能在很大程度上取决于铆钉孔周围的残余应力系统。确定这些应力的最方便和最常见的方法是有限元分析。为了确保结果的可靠性，有必要对所使用的模型进行验证。本文介绍了通用铆钉和沉头铆钉铆接有限元模拟的验证过程。首先，利用实验获得的冲压件的力-位移曲线对铆钉的材料模型进行了验证。由于采用了位移测量方法，因此有必要考虑支架的灵活性。之后，两种铆钉类型的数值模拟与实验之间都获得了良好的相关性。在第二阶段，将使用带规模式测量的从动头周围的应变与有限元模拟结果进行了比较。沉头铆钉获得了很好的相关性。在通用铆钉的情况下，数值结果明显高于测量值。所分析铆钉类型的实验和有限元模拟的相关性差异可能是由于铆钉的材料差异造成的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Fatigue of Aircraft Structures Engineering-Safety, Risk, Reliability and Quality

CiteScore

0.40

自引率

0.00%

发文量

期刊介绍： The publication focuses on problems of aeronautical fatigue and structural integrity. The preferred topics include: full-scale fatigue testing of aircraft and aircraft structural components, fatigue of materials and structures, advanced materials and innovative structural concepts, damage tolerant design of aircraft structure, life extension and management of ageing fleets, structural health monitoring and loads, fatigue crack growth and life prediction methods, NDT inspections, airworthiness considerations.