Comparison Between Different Calculation Methods for Determining Bolting-Up Torque Moments

Alexander Mutz, M. Schaaf, S. Hufnagel
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Abstract

The ASME BPVC, Section III, Appendix XI [1] regulates the flange calculation for class 2 and 3 components in Suisse nuclear power plants, and it is also used for class 1 flanges. The most common European Standard for the design of bolted flanged joints is EN 1591-1 [2], the required gasket characteristics for this calculation procedure are defined in EN 13555 [3]. These characteristics can be determined experimentally and they are not only used in EN 1591-1 but also in more realistic finite-element calculations. Finite element calculations are carried out for a certain number of combinations of flange and gasket materials as well as bolt types in order to prove compliance with the integrity and tightness of the connections in the assembly and subsequent operational states, taking into account the tightening torques. A total of almost 400 different combinations of flange, bolt and gasket geometries and materials were examined. The focus is laid on flange types fabricated according to European standards which are generally thinner — looking at the wall thickness or flange ring in the same pressure range — than in the ASME world. In this paper the bolting-up torque moments determined with the European standard EN 1591-1 for the flange connections, are assessed with twice elastic slope method, limit load and elastic-plastic stress analysis according to ASME BPVC, Section VIII, Div. 2. [4] Proof of acceptability of the nonlinear finite element-calculations are conducted according to ASME standard procedures like ASME SECTION III, Appendices EE and FF for the level D.
不同紧固力矩计算方法的比较
设计螺栓法兰连接最常用的欧洲标准是EN 1591-1[2],该计算过程所需的垫片特性在EN 13555[3]中定义。这些特性可以通过实验确定,它们不仅用于EN 1591-1,还用于更现实的有限元计算。考虑到拧紧扭矩,对一定数量的法兰和垫圈材料组合以及螺栓类型进行了有限元计算,以证明在装配和随后的操作状态下连接的完整性和严密性符合要求。总共测试了近400种不同的法兰、螺栓和垫片几何形状和材料组合。重点放在根据欧洲标准制造的法兰类型上,这些法兰类型通常比ASME世界更薄-在相同压力范围内观察壁厚或法兰环。根据ASME BPVC, Section VIII, Div. 2,用两次弹性斜率法、极限载荷和弹塑性应力分析来评估根据欧洲标准EN 1591-1确定的法兰连接的紧固力矩。[4]非线性有限元计算的可接受性证明是根据ASME标准程序进行的,如ASME第III节,D级附录EE和FF。
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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