Use of a Ring DWTT Specimen for Determination of Steel NDT from Pipe of Diameter Less than DN500
It has become recognized that the drop weight tearing test (DWTT) energy better represents the ductile fracture resistance of pipe steels since it utilizes a specimen that has the full thickness of the pipe and has a fracture path long enough to reach steady-state fracture resistance. However, the A...
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| Published in: | Journal of failure analysis and prevention Vol. 16; no. 6; pp. 941 - 950 |
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| Abstract | It has become recognized that the drop weight tearing test (DWTT) energy better represents the ductile fracture resistance of pipe steels since it utilizes a specimen that has the full thickness of the pipe and has a fracture path long enough to reach steady-state fracture resistance. However, the API 5L code does not require it for pipe sizes less than DN500. The aim of this paper is to propose a DWTT specific to small diameter pipes based on a new specimen, the ring drop weight tearing test (RDWTT) specimen; to evaluate the transition temperature T t, DWTT and nil ductility temperature of the pipe steel API 5L X65; to introduce the transition temperature T t, DWTT in the transition temperature material master curve of the API 5L X65 steel; and to compare the prediction of the crack ductile extension in a pipe based on the RDWTT's energy and crack tip opening angle in the case of the steel API 5L X65. |
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| AbstractList | It has become recognized that the drop weight tearing test (DWTT) energy better represents the ductile fracture resistance of pipe steels since it utilizes a specimen that has the full thickness of the pipe and has a fracture path long enough to reach steady-state fracture resistance. However, the API 5L code does not require it for pipe sizes less than DN500. The aim of this paper is: to propose a DWTT specific to small diameter pipes based on a new specimen, the Ring Drop Weight Tearing Test (RDWTT) specimen, to evaluate the transition temperature T t, DWTT and nil ductility temperature (NDT) of the pipe steel API5L X65, to introduce the transition temperature T t, DWTT in the Transition Temperature Material Master Curve (TTMC) of the API5L X65 steel, to compare the prediction of the crack ductile extension in a pipe based on the RDWTT's energy and crack tip opening angle (CTOA) in the case of the steel API5L X65. 1.INTRODUCTION The Drop Weight Tear Test (DWTT) is an impact test used primarily to determine the nil ductility transition temperature or NDT of ferritic steels. The test consists of subjecting the specimen to a single impact load at a progression of selected temperatures. The impact load is delivered by a guided, free-falling weight with energy of 340 to 1630 J according to the yield strength of the steel to be tested. A stop is employed to prevent deflection of more than a few millimeters. In accordance with the API RP 5L3 specification [1], the DWTT specimens have a size of 76.2 mm × 305 mm × B (B is pipe thickness) in the transverse-longitudinal (T-L) direction. A pressed notch, a chevron notch or an electrical discharge wire-cut notch is machined into the specimens. It has become recognized that the DWTT better represents the ductile fracture resistance of pipe steels since it utilizes a specimen that has the full thickness of the pipe and has a fracture path long enough to reach steady-state fracture resistance. When plotting the DWTT fracture energy versus temperature, one distinguishes the following types of fracture: Brittle initiation followed by brittle propagation at temperature T< FITT Ductile initiation followed by brittle propagation for FITT < T < FTE Ductile initiation followed by ductile propagation for FTE< T < FPT Plastic collapse T> FPT It has become recognized that the drop weight tearing test (DWTT) energy better represents the ductile fracture resistance of pipe steels since it utilizes a specimen that has the full thickness of the pipe and has a fracture path long enough to reach steady-state fracture resistance. However, the API 5L code does not require it for pipe sizes less than DN500. The aim of this paper is to propose a DWTT specific to small diameter pipes based on a new specimen, the ring drop weight tearing test (RDWTT) specimen; to evaluate the transition temperature T t, DWTT and nil ductility temperature of the pipe steel API 5L X65; to introduce the transition temperature T t, DWTT in the transition temperature material master curve of the API 5L X65 steel; and to compare the prediction of the crack ductile extension in a pipe based on the RDWTT's energy and crack tip opening angle in the case of the steel API 5L X65. It has become recognized that the drop weight tearing test (DWTT) energy better represents the ductile fracture resistance of pipe steels since it utilizes a specimen that has the full thickness of the pipe and has a fracture path long enough to reach steady-state fracture resistance. However, the API 5L code does not require it for pipe sizes less than DN500. The aim of this paper is to propose a DWTT specific to small diameter pipes based on a new specimen, the ring drop weight tearing test (RDWTT) specimen; to evaluate the transition temperature T sub(t, DWTT) and nil ductility temperature of the pipe steel API 5L X65; to introduce the transition temperature T sub(t, DWTT) in the transition temperature material master curve of the API 5L X65 steel; and to compare the prediction of the crack ductile extension in a pipe based on the RDWTT's energy and crack tip opening angle in the case of the steel API 5L X65. |
| Author | Ben Amara, M Pluvinage, G Azari, Z Capelle, J |
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| Keywords | crack extension constraint Ring specimen NDT |
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| References | I Scheider (194_CR23) 2006; 73 C Ruggieri (194_CR11) 2000; 67 BS Henry (194_CR10) 1997; 57 MH Meliani (194_CR12) 2011; 167 A Coseru (194_CR8) 2014; 37 GM Wilkowski (194_CR4) 1980; 19 194_CR6 194_CR7 M Mouwakeh (194_CR9) 2011; 63 194_CR5 M Ben Amara (194_CR22) 2015; 18 194_CR2 SG Larsson (194_CR14) 1973; 21 194_CR1 194_CR21 194_CR20 GP Nikishkov (194_CR13) 1995; 50 B Yang (194_CR16) 2001; 64 194_CR18 G Pluvinage (194_CR15) 2001 K Wallin (194_CR17) 2010; 77 E Sugie (194_CR19) 1982; 104 Z Yang (194_CR3) 2014; 3 |
| References_xml | – volume-title: Notch Effects in Fatigue and Fracture year: 2001 ident: 194_CR15 doi: 10.1007/978-94-010-0880-8 contributor: fullname: G Pluvinage – volume: 73 start-page: 252 issue: 2 year: 2006 ident: 194_CR23 publication-title: Eng. Fract. Mech. doi: 10.1016/j.engfracmech.2005.04.005 contributor: fullname: I Scheider – ident: 194_CR5 doi: 10.1115/IPC2008-64060 – ident: 194_CR7 doi: 10.1115/IPC2000-130 – ident: 194_CR2 – volume: 19 start-page: 59 year: 1980 ident: 194_CR4 publication-title: Can. Metall. Q. doi: 10.1179/cmq.1980.19.1.59 contributor: fullname: GM Wilkowski – ident: 194_CR1 – ident: 194_CR20 – ident: 194_CR6 – volume: 37 start-page: 110 year: 2014 ident: 194_CR8 publication-title: Eng. Fail. Anal. doi: 10.1016/j.engfailanal.2013.11.001 contributor: fullname: A Coseru – volume: 67 start-page: 101 year: 2000 ident: 194_CR11 publication-title: Eng. Fract. Mech. doi: 10.1016/S0013-7944(00)00052-7 contributor: fullname: C Ruggieri – volume: 50 start-page: 65 issue: 1 year: 1995 ident: 194_CR13 publication-title: Eng. Fract. Mech. doi: 10.1016/0013-7944(94)00139-9 contributor: fullname: GP Nikishkov – ident: 194_CR21 doi: 10.1115/IPC2004-0145 – volume: 77 start-page: 285 issue: 2 year: 2010 ident: 194_CR17 publication-title: Eng. Fract. Mech. doi: 10.1016/j.engfracmech.2009.02.010 contributor: fullname: K Wallin – volume: 63 start-page: 79 year: 2011 ident: 194_CR9 publication-title: Res. J Aleppo Univ. Eng. Sci. Ser. contributor: fullname: M Mouwakeh – volume: 21 start-page: 263 issue: 4 year: 1973 ident: 194_CR14 publication-title: J. Mech. Phys. Solids doi: 10.1016/0022-5096(73)90024-0 contributor: fullname: SG Larsson – volume: 57 start-page: 375 year: 1997 ident: 194_CR10 publication-title: Eng. Fract. Mech. doi: 10.1016/S0013-7944(97)00031-3 contributor: fullname: BS Henry – ident: 194_CR18 – volume: 104 start-page: 338 issue: 4 year: 1982 ident: 194_CR19 publication-title: J. Press. Vessel Technol. doi: 10.1115/1.3264226 contributor: fullname: E Sugie – volume: 18 start-page: 355 issue: 4 year: 2015 ident: 194_CR22 publication-title: Phys. Mesomech. doi: 10.1134/S1029959915040086 contributor: fullname: M Ben Amara – volume: 64 start-page: 589 issue: 5 year: 2001 ident: 194_CR16 publication-title: Eng. Fract. Mech. doi: 10.1016/S0013-7944(99)00082-X contributor: fullname: B Yang – volume: 3 start-page: 1591 year: 2014 ident: 194_CR3 publication-title: Proced. Mater. Sci. doi: 10.1016/j.mspro.2014.06.257 contributor: fullname: Z Yang – volume: 167 start-page: 173 issue: 2 year: 2011 ident: 194_CR12 publication-title: Int. J. Fract. doi: 10.1007/s10704-010-9542-1 contributor: fullname: MH Meliani |
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| SubjectTerms | Crack propagation Crack tips Diameters Drop weight tests Ductile fracture Ductile-brittle transition Ductility Ductility tests Energy Engineering Sciences Fracture mechanics Fracture toughness High strength low alloy steels Mechanical engineering Mechanics Mechanics of materials Nondestructive testing Pipe Pipes Propagation Steel Steels Tearing Temperature Transition temperature |
| Title | Use of a Ring DWTT Specimen for Determination of Steel NDT from Pipe of Diameter Less than DN500 |
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