Fatigue strength improvement of steel structures by high-frequency mechanical impact: Proposed fatigue assessment guidelines
Artikel i vetenskaplig tidskrift, 2013

In the past decade, high-frequency mechanical impact (HFMI) has significantly developed as a reliable, effective, and user-friendly method for post-weld fatigue strength improvement technique for welded structures. During this time, period 46 documents on HFMI technology or fatigue improvements have been presented within Commission XIII of the International Institute of Welding. This paper presents one possible approach to fatigue assessment for HFMI-improved joints. Stress analysis methods based on nominal stress, structural hot spot stress, and effective notch stress are all discussed. The document considered the observed extra benefit that has been experimentally observed for HFMI-treated high-strength steels. Some observations and proposals on the effect of loading conditions like high mean stress fatigue cycles, variable amplitude loading, and large amplitude/low cycle fatigue cycles are given. Special considerations for low stress concentration details are also given. Several fatigue assessment examples are provided in an appendix. A companion paper has also been prepared concerning HFMI equipment, proper procedures, safety, training, quality control measures, and documentation has also been prepared. It is hoped that these guidelines will provide stimulus to researchers working in the field to test and constructively criticize the proposals made with the goal of developing international guidelines relevant to a variety of HFMI technologies and applicable to many industrial sectors. The proposal can also be used as a means of verifying the effectiveness of new equipment as it comes to the market.

High-strength steels

Weld toe improvement

High-frequency mechanical impact (HFMI)

Effective notch stress

Fatigue improvement

Fatigue design

Hot spot stress


G.B. Marquis

E. Mikkola

Z. Barsoum

Welding in the World, Le Soudage Dans Le Monde

0043-2288 (ISSN) 18786669 (eISSN)

Vol. 57 6 803-822






Building Futures (2010-2018)





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