Crack closure mechanisms in residual stress fields generated by laser shock peening: A combined experimental-numerical approach

•Identification of crack closure as important mechanism to retard FCP.•Interpretation of the FCP rate considering stress intensity factors and crack closure.•Numerical and experimental results of crack closure areas agree very well.•Crack closure does not necessarily cause a zero value stress intens...

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Veröffentlicht in:	Engineering fracture mechanics 2019-11, Vol.221, p.106630, Article 106630
Hauptverfasser:	Keller, S., Horstmann, M., Kashaev, N., Klusemann, B.
Format:	Artikel
Sprache:	eng
Schlagworte:	Compressive properties Computer simulation Contact stresses Crack closure Crack opening displacement Crack propagation Fatigue crack growth Fatigue cracks Fatigue failure Laser shock peening Laser shock processing Peening Residual stress Stress concentration Stress distribution Stress intensity factor Stress intensity factors
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description	•Identification of crack closure as important mechanism to retard FCP.•Interpretation of the FCP rate considering stress intensity factors and crack closure.•Numerical and experimental results of crack closure areas agree very well.•Crack closure does not necessarily cause a zero value stress intensity factor.•Fast prediction of FCP rates by stress intensity factor vs. applied load curves. Laser shock peening (LSP) is successfully applied to retard fatigue cracks in metallic lightweight structures by introducing specific, in particular compressive, residual stress fields. In this work, experiments and a multi-step simulation strategy are used to explain the fatigue crack retarding and accelerating mechanisms within these LSP-induced residual stress fields. Crack face contact is identified as main mechanism to retard the fatigue crack as the stress distribution changes and the stress intensity factor range decreases. Crack face contact is experimentally detected by load vs. crack opening displacement (COD) curves and scanning electron microscopy (SEM) of the crack faces, as well as during numerical simulations. The convincing agreement between experiment and simulation, especially regarding the specific crack face contact areas, allowed the proper evaluation of the stress intensity factors depending on the crack length. It is found that crack closure is indeed one of the main reasons for the efficient application of LSP for fatigue crack retardation. Furthermore, the occurrence of crack closure does not indicate a zero value stress intensity factor in complex residual stress fields, as the areas of crack face contact depend strongly on the LSP-induced compressive residual stresses.
doi_str_mv	10.1016/j.engfracmech.2019.106630
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Laser shock peening (LSP) is successfully applied to retard fatigue cracks in metallic lightweight structures by introducing specific, in particular compressive, residual stress fields. In this work, experiments and a multi-step simulation strategy are used to explain the fatigue crack retarding and accelerating mechanisms within these LSP-induced residual stress fields. Crack face contact is identified as main mechanism to retard the fatigue crack as the stress distribution changes and the stress intensity factor range decreases. Crack face contact is experimentally detected by load vs. crack opening displacement (COD) curves and scanning electron microscopy (SEM) of the crack faces, as well as during numerical simulations. The convincing agreement between experiment and simulation, especially regarding the specific crack face contact areas, allowed the proper evaluation of the stress intensity factors depending on the crack length. It is found that crack closure is indeed one of the main reasons for the efficient application of LSP for fatigue crack retardation. 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Laser shock peening (LSP) is successfully applied to retard fatigue cracks in metallic lightweight structures by introducing specific, in particular compressive, residual stress fields. In this work, experiments and a multi-step simulation strategy are used to explain the fatigue crack retarding and accelerating mechanisms within these LSP-induced residual stress fields. Crack face contact is identified as main mechanism to retard the fatigue crack as the stress distribution changes and the stress intensity factor range decreases. Crack face contact is experimentally detected by load vs. crack opening displacement (COD) curves and scanning electron microscopy (SEM) of the crack faces, as well as during numerical simulations. The convincing agreement between experiment and simulation, especially regarding the specific crack face contact areas, allowed the proper evaluation of the stress intensity factors depending on the crack length. 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Furthermore, the occurrence of crack closure does not indicate a zero value stress intensity factor in complex residual stress fields, as the areas of crack face contact depend strongly on the LSP-induced compressive residual stresses.</description><subject>Compressive properties</subject><subject>Computer simulation</subject><subject>Contact stresses</subject><subject>Crack closure</subject><subject>Crack opening displacement</subject><subject>Crack propagation</subject><subject>Fatigue crack growth</subject><subject>Fatigue cracks</subject><subject>Fatigue failure</subject><subject>Laser shock peening</subject><subject>Laser shock processing</subject><subject>Peening</subject><subject>Residual stress</subject><subject>Stress concentration</subject><subject>Stress distribution</subject><subject>Stress intensity factor</subject><subject>Stress intensity factors</subject><issn>0013-7944</issn><issn>1873-7315</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2019</creationdate><recordtype>article</recordtype><recordid>eNqNkEFP4zAQha0VK9Fl-Q9ecU4ZxyGp94YqFpCQuMDZGjvj1t3ECXaC4MRfx6UcOHKaGeu9b8aPsT8ClgJEfb5bUti4iLYnu12WIFR-r2sJP9hCrBpZNFJcHLEFgMi9qqpj9iulHQA09QoW7G2dvf-57YY0R-J7Cgaf-sR94JGSb2fseJpym7jz1LWJbyhQxIlabl55h4kiT9shU0ai4MPmL7_kduiND1lCLyNF31OYsCvC3OfBZiKOYxzQbn-znw67RKef9YQ9_rt6WN8Ud_fXt-vLu8JWAFMhVEMrwApV7RQ4wlaYmkwrAY1UlTSrxhmnbFMLJy8c1g4bU4KBSijCUsgTdnbg5rVPM6VJ74Y5hrxSl1JUpZLVh0odVDYOKUVyesy3Y3zVAvQ-b73TX_LW-7z1Ie_sXR-8lL_x7CnqZD0FS62PZCfdDv4blHc-BpIA</recordid><startdate>201911</startdate><enddate>201911</enddate><creator>Keller, S.</creator><creator>Horstmann, M.</creator><creator>Kashaev, N.</creator><creator>Klusemann, B.</creator><general>Elsevier Ltd</general><general>Elsevier BV</general><scope>6I.</scope><scope>AAFTH</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7SR</scope><scope>7TB</scope><scope>8BQ</scope><scope>8FD</scope><scope>FR3</scope><scope>JG9</scope><scope>KR7</scope></search><sort><creationdate>201911</creationdate><title>Crack closure mechanisms in residual stress fields generated by laser shock peening: A combined experimental-numerical approach</title><author>Keller, S. ; Horstmann, M. ; Kashaev, N. ; Klusemann, B.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c400t-197e80a4a96f90fead1b6ebd30ab3943b87fbf9c761f35fa6fa7b20b0419ea213</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2019</creationdate><topic>Compressive properties</topic><topic>Computer simulation</topic><topic>Contact stresses</topic><topic>Crack closure</topic><topic>Crack opening displacement</topic><topic>Crack propagation</topic><topic>Fatigue crack growth</topic><topic>Fatigue cracks</topic><topic>Fatigue failure</topic><topic>Laser shock peening</topic><topic>Laser shock processing</topic><topic>Peening</topic><topic>Residual stress</topic><topic>Stress concentration</topic><topic>Stress distribution</topic><topic>Stress intensity factor</topic><topic>Stress intensity factors</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Keller, S.</creatorcontrib><creatorcontrib>Horstmann, M.</creatorcontrib><creatorcontrib>Kashaev, N.</creatorcontrib><creatorcontrib>Klusemann, B.</creatorcontrib><collection>ScienceDirect Open Access Titles</collection><collection>Elsevier:ScienceDirect:Open Access</collection><collection>CrossRef</collection><collection>Engineered Materials Abstracts</collection><collection>Mechanical & Transportation Engineering Abstracts</collection><collection>METADEX</collection><collection>Technology Research Database</collection><collection>Engineering Research Database</collection><collection>Materials Research Database</collection><collection>Civil Engineering Abstracts</collection><jtitle>Engineering fracture mechanics</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Keller, S.</au><au>Horstmann, M.</au><au>Kashaev, N.</au><au>Klusemann, B.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Crack closure mechanisms in residual stress fields generated by laser shock peening: A combined experimental-numerical approach</atitle><jtitle>Engineering fracture mechanics</jtitle><date>2019-11</date><risdate>2019</risdate><volume>221</volume><spage>106630</spage><pages>106630-</pages><artnum>106630</artnum><issn>0013-7944</issn><eissn>1873-7315</eissn><abstract>•Identification of crack closure as important mechanism to retard FCP.•Interpretation of the FCP rate considering stress intensity factors and crack closure.•Numerical and experimental results of crack closure areas agree very well.•Crack closure does not necessarily cause a zero value stress intensity factor.•Fast prediction of FCP rates by stress intensity factor vs. applied load curves. 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subjects	Compressive properties Computer simulation Contact stresses Crack closure Crack opening displacement Crack propagation Fatigue crack growth Fatigue cracks Fatigue failure Laser shock peening Laser shock processing Peening Residual stress Stress concentration Stress distribution Stress intensity factor Stress intensity factors
title	Crack closure mechanisms in residual stress fields generated by laser shock peening: A combined experimental-numerical approach
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