Experimental and Numerical Study of NACA and Conventional Riveting Procedure

Q4 Engineering Fatigue of Aircraft Structures Pub Date : 2017-12-01 DOI:10.1515/fas-2017-0012

Wojciech Wronicz, J. Kaniowski, Maciej Malicki, Paweł Kucio, R. Klewicki

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引用次数: 4

Abstract

Abstract Fatigue behaviour is one of the most important properties of modern airplanes and rivets influence it strongly. According to the literature, the NACA riveting offers a multiple increase in the fatigue life of joints. The aim of this paper is to investigate the benefits offered by the NACA riveting procedure with respect to the residual stress and strain distribution after riveting as well as rivet hole expansion. Experimental and numerical approaches were adopted. The conventional riveting with both the universal and countersunk rivets was compared with the NACA riveting. The countersunk angle and depth in the case of the NACA riveting was modified somewhat relative to the values met in the literature. For these three cases, strain gauge measurements during riveting, hole expansion measurements and FE calculations were performed. The hole expansion measurement with the use of Computer Tomography(CT) was proposed. Only the FE calculations unambiguously indicate better fatigue properties of the NACA riveting. The proposed method of hole expansion measurement requires further research to increase its accuracy.

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NACA与常规铆接工艺的实验与数值研究

摘要疲劳性能是现代飞机最重要的性能之一，铆钉对飞机的疲劳性能影响很大。根据文献，NACA铆接提供了一个数倍的增加疲劳寿命的接头。本文的目的是研究NACA铆接程序在铆接后的残余应力和应变分布以及铆钉孔膨胀方面所提供的好处。采用了实验和数值方法。将通用铆钉和沉头铆钉的常规铆接与NACA铆接进行了比较。在NACA铆接的情况下，沉角和深度相对于文献中所满足的值有所修改。对于这三种情况，进行了铆接过程中的应变片测量、孔膨胀测量和有限元计算。提出了利用计算机断层扫描(CT)测量孔膨胀的方法。只有有限元计算明确地表明NACA铆接具有较好的疲劳性能。提出的孔膨胀测量方法需要进一步研究以提高其精度。

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

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0.00%

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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.