Residual Stresses of Water-Jet Peened Austenitic Stainless Steel

The precipitation characterization of SUS 310S weld metal was investigated by TG/DSC and metallography technique. SMAW was selected for this study and then cut with water jet avoiding thermal effect. Austenitic is the main microstructure of weld metal because of high Creqv./Nieqv. Precipitation launched higher both %mass change and heat consumed as well as the precipitation temperature was around 800 degree Celsius.

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Development of Residual Stress Improvement for Nuclear Pressure Vessel Instrumentation Nozzle Weld Joint (P-43+P-8) by Means of Induction Heating

Volume 1: Plant Operations, Maintenance and Life Cycle; Component Reliability and Materials Issues; Codes, Standards, Licensing and Regulatory Issues; Fuel Cycle and High Level Waste Management ◽

10.1115/icone14-89297 ◽

2006 ◽

Author(s):

Takuro Terajima ◽

Takashi Hirano

Keyword(s):

Mechanical Properties ◽

Residual Stress ◽

Stainless Steel ◽

Austenitic Stainless Steel ◽

Residual Stresses ◽

Induction Heating ◽

Weld Joint ◽

Thermal Stresses ◽

Pressure Vessels ◽

Weld Joints

As a counter measurement of intergranular stress corrosion cracking (IGSCC) in boiling water reactors, the induction heating stress improvement (IHSI) has been developed as a method to improve the stress factor, especially residual stresses in affected areas of pipe joint welds. In this method, a pipe is heated from the outside by an induction coil and cooled from the inside with water simultaneously. By thermal stresses to produce a temperature differential between the inner and outer pipe surfaces, the residual stress inside the pipe is improved compression. IHSI had been applied to weld joints of austenitic stainless steel pipes (P-8+P-8). However IHSI had not been applied to weld joints of nickel-chromium-iron alloy (P-43) and austenitic stainless steel (P-8). This weld joint (P-43+P-8) is used for instrumentation nozzles in nuclear power plants’ reactor pressure vessels. Therefore for the purpose of applying IHSI to this one, we studied the following. i) Investigation of IHSI conditions (Essential Variables); ii) Residual stresses after IHSI; iii) Mechanical properties after IHSI. This paper explains that IHSI is sufficiently effective in improvement of the residual stresses for this weld joint (P-43+P-8), and that IHSI does not cause negative effects by results of mechanical properties, and IHSI is verified concerning applying it to this kind of weld joint.

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Measuring residual stresses in stainless steel—recent experiences within a VAMAS exercise

Powder Diffraction ◽

10.1154/1.3133146 ◽

2009 ◽

Vol 24 (S1) ◽

pp. S41-S44 ◽

Cited By ~ 3

Author(s):

A. T. Fry ◽

J. D. Lord

Keyword(s):

Residual Stress ◽

Stainless Steel ◽

Austenitic Stainless Steel ◽

Residual Stresses ◽

Best Practice ◽

Test Procedure ◽

Industrial Plant ◽

X Ray Diffraction ◽

X Ray ◽

Industrial Sectors

Residual stresses impact on a wide variety of industrial sectors including the automotive, power generation, industrial plant, construction, aerospace, railway and transport industries, and a range of materials manufacturers and processing companies. The X-ray diffraction (XRD) technique is one of the most popular methods for measuring residual stress (Kandil et al., 2001) used routinely in quality control and materials characterization for validating models and design. The VAMAS TWA20 Project 3 activity on the “Measurement of Residual Stresses by X-ray Diffraction” was initiated by NPL in 2005 to examine various aspects of the XRD test procedure in support of work aimed at developing an international standard in this area. The purpose of this project was to examine and reduce some of the sources of scatter and uncertainty in the measurement of residual stress by X-ray diffraction on metallic materials, through an international intercomparison and validation exercise. One of the major issues the intercomparison highlighted was the problem associated with measuring residual stresses in austenitic stainless steel. The following paper describes this intercomparison, reviews the results of the exercise and details additional work looking at developing best practice for measuring residual stresses in austenitic stainless steel, for which X-ray measurements are somewhat unreliable and problematic.

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Monotonic mechanical properties of plasma nitrided 316L polycrystalline austenitic stainless steel: Mechanical behaviour of the nitrided layer and impact of nitriding residual stresses

Materials Science and Engineering A ◽

10.1016/j.msea.2014.03.039 ◽

2014 ◽

Vol 605 ◽

pp. 51-58 ◽

Cited By ~ 22

Author(s):

J.C. Stinville ◽

J. Cormier ◽

C. Templier ◽

P. Villechaise

Keyword(s):

Mechanical Properties ◽

Stainless Steel ◽

Austenitic Stainless Steel ◽

Residual Stresses ◽

Mechanical Behaviour ◽

Nitrided Layer

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A new approach for the modelling of residual stresses induced by turning of 316L austenitic stainless steel

International Journal of Machining and Machinability of Materials ◽

10.1504/ijmmm.2008.023197 ◽

2008 ◽

Vol 4 (2/3) ◽

pp. 275

Author(s):

Frederic Valiorgue ◽

Joel Rech ◽

Hedi Hamdi ◽

Philippe Gilles ◽

Jean Michel Bergheau

Keyword(s):

Stainless Steel ◽

Austenitic Stainless Steel ◽

Residual Stresses ◽

New Approach ◽

316L Austenitic Stainless Steel

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Effect of pulsating water jet disintegration on hardness and elasticity modulus of austenitic stainless steel AISI 304L

The International Journal of Advanced Manufacturing Technology ◽

10.1007/s00170-020-05191-3 ◽

2020 ◽

Vol 107 (5-6) ◽

pp. 2719-2730

Author(s):

Dominika Lehocka ◽

Frantisek Botko ◽

Jiri Klich ◽

Libor Sitek ◽

Pavol Hvizdos ◽

...

Keyword(s):

Stainless Steel ◽

Austenitic Stainless Steel ◽

Elasticity Modulus ◽

Water Jet ◽

Aisi 304L ◽

Steel Aisi ◽

Pulsating Water Jet ◽

Stainless Steel Aisi

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Residual Stress Measurements and Modelling for Temper Bead Qualification

Volume 6B: Materials and Fabrication ◽

10.1115/pvp2013-97073 ◽

2013 ◽

Author(s):

Xavier Ficquet ◽

Vincent Robin ◽

Ed Kingston ◽

Stéphan Courtin ◽

Miguel Yescas

Keyword(s):

Heat Treatment ◽

Residual Stress ◽

Stainless Steel ◽

Austenitic Stainless Steel ◽

Residual Stresses ◽

Hole Drilling ◽

Stainless Steel Surface ◽

Element Analysis ◽

Stress Measurements ◽

Welding Processes

This paper presents results from a programme of through thickness residual stress measurements and finite element analysis (FEA) modelling carried out on a temper bead mock-up. Emphasis is placed on results comparison rather than the measurement technique and procedure, which is well documented in the accompanying references. Temper bead welding processes have been developed to simulate the tempering effect of post-weld heat treatment and are used to repair reactor pressure vessel components to alleviate the need for further heat-treatment. The Temper Bead Mock-up comprised of a rectangular block with dimension 960mm × 189mm × 124mm was manufactured from a ferritic steel forged block with an austenitic stainless steel buttering and a nickel alloy temper bead cladding. The temper bead and buttering surfaces were machined after welding. Biaxial residual stresses were measured at a number of locations using the standard Deep-Hole Drilling (DHD) and Incremental DHD (iDHD) techniques on the Temper Bead Mock-up and compared with FEA modelling results. An excellent correlation existed between the iDHD and the modelled results, and highlighted the need for the iDHD technique in order to account for plastic relaxation during the measurement process. Maximum tensile residual stresses through the thickness were observed near the austenitic stainless steel surface at 298MPa. High compressive stresses were observed within the ferritic base plate beneath the bimetallic interface between austenitic and ferritic steels with peak stresses of −377MPa in the longitudinal direction.

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