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    <title>A533B Residual Stress: Four Problems on MechCalc how-to Guide</title>
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      <title>Where Does the Welding Residual Stress Intensity Factor Come From? Integrating an A533B Residual Profile into a SIF with BS 7910 Annex M.4.2</title>
      <link>https://mechcalc.net/blog/en/posts/bs7910-a533b-residual-kis-annexm/</link>
      <pubDate>Thu, 25 Jun 2026 10:00:00 +0800</pubDate>
      <guid>https://mechcalc.net/blog/en/posts/bs7910-a533b-residual-kis-annexm/</guid>
      <description>Across the four A533B welded-plate problems, the residual stress intensity factor K_I^S≈46 MPa·m^0.5 has always been entered directly into the FAD — but where does that number actually come from? This post uses the BS 7910 Annex M.4.2 calculator in mechCalc (finite-plate surface flaw, polynomial stress) to integrate the measured welding residual stress polynomial profile into the SIF at the deepest point of the crack, yielding 44.84 MPa·m^0.5 — only 2.5% off the 46 reported by FITNET — and shows how mechCalc reproduces this key intermediate quantity on its own.</description>
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      <title>Problem 4 — HLHT: the double dividend of PWHT, and a thought-provoking twist (the A533B high-load-ratio finale)</title>
      <link>https://mechcalc.net/blog/en/posts/bs7910-a533b-hlht-fad-walkthrough/</link>
      <pubDate>Wed, 24 Jun 2026 13:00:00 +0800</pubDate>
      <guid>https://mechcalc.net/blog/en/posts/bs7910-a533b-hlht-fad-walkthrough/</guid>
      <description>The finale of the four problems on the A533B-1 welded plate: same temperature and regime as Problem 3 (HLAW) — −30 ℃, high load ratio — but with post-weld heat treatment (PWHT). This article works through HLHT to show the double dividend of PWHT — it both relaxes the residual field (K_I^S 46→5) and restores toughness by an order of magnitude (K_mat 62→321) — and how this drives K_r down from 3.94 to 0.60; plus a thought-provoking twist: even with smaller residuals and higher toughness, HLHT fails at a slightly lower load than HLAW.</description>
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      <title>Problem 3 — HLAW: into the high load-ratio regime, where plasticity dilutes residual stress (A533B as-welded, −30 ℃)</title>
      <link>https://mechcalc.net/blog/en/posts/bs7910-a533b-hlaw-fad-walkthrough/</link>
      <pubDate>Wed, 24 Jun 2026 12:00:00 +0800</pubDate>
      <guid>https://mechcalc.net/blog/en/posts/bs7910-a533b-hlaw-fad-walkthrough/</guid>
      <description>Third of four problems on the welded A533B-1 plate: the HLAW specimen — as-welded, warmed to −30 ℃, with the load raised into the high load-ratio (large-plasticity) regime. We run it in mechCalc&amp;#39;s BS 7910 Clause 7 fracture assessment calculator to see how the assessment calls plastic collapse once L_r=1.80 exceeds the cut-off value L_r,max, and why the relative weight of residual stress is diluted by plasticity at high L_r so that fracture toughness becomes the governing factor.</description>
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      <title>Problem 2 — LLHT: PWHT Relaxes Residual Stress by an Order of Magnitude, Same Temperature and Region for a Head-to-Head</title>
      <link>https://mechcalc.net/blog/en/posts/bs7910-a533b-llht-fad-walkthrough/</link>
      <pubDate>Wed, 24 Jun 2026 11:00:00 +0800</pubDate>
      <guid>https://mechcalc.net/blog/en/posts/bs7910-a533b-llht-fad-walkthrough/</guid>
      <description>Second of four problems on the A533B-1 welded plate: same temperature as Problem 1 LLAW (−120 ℃), same region, same measured residual-stress profile — the only variable is that post-weld heat treatment (PWHT) was applied. Here we run LLHT in mechCalc&amp;#39;s BS 7910 Clause 7 fracture-assessment calculator and watch a counter-intuitive result: its primary SIF is actually higher than LLAW, yet the assessment point lands lower, because the residual K_I^S drops from 46 to 5.</description>
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      <title>Problem 1 LLAW: How far does residual stress push the assessment point past the FAL? — An A533B as-welded, low-temperature FAD walkthrough</title>
      <link>https://mechcalc.net/blog/en/posts/bs7910-a533b-llaw-fad-walkthrough/</link>
      <pubDate>Wed, 24 Jun 2026 10:00:00 +0800</pubDate>
      <guid>https://mechcalc.net/blog/en/posts/bs7910-a533b-llaw-fad-walkthrough/</guid>
      <description>One of the four A533B-1 welded-plate problems: the LLAW specimen — as-welded, −120 ℃, low load ratio. It is the first of the four to fracture (1.27 MN). This post walks step by step through entering, computing, and reading the FAD in mechCalc&amp;#39;s BS 7910 Clause 7 Fracture Assessment Calculator, to see exactly how the residual K_I^S of 46 MPa·m^0.5 pushes the assessment point to K_r=2.59, far beyond the Failure Assessment Line.</description>
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