TOUGHNESS CONSIDERATIONS FOR STRAIN-BASED DESIGN

被引:0
作者
Wang, Yong-Yi [1 ]
Liu, Ming [1 ]
Tyson, Bill [2 ]
Gianetto, James [2 ]
Horsley, David [3 ]
机构
[1] Ctr Reliable Energy Syst, 5960 Venture Dr,Suite B, Dublin, OH 43017 USA
[2] CANMET NRCan, Ottawa, ON K1A 0G1, Canada
[3] BP Explorat & Prod Technol, Calgary, AB, Canada
来源
PROCEEDINGS OF THE ASME INTERNATIONAL PIPELINE CONFERENCE 2010, VOL 4 | 2010年
关键词
Pipeline; strain-based design; girth weld; toughness; constraint effects;
D O I
暂无
中图分类号
TE [石油、天然气工业];
学科分类号
0820 ;
摘要
Toughness is a critical parameter in all phases of a pipeline service life. There are a variety of toughness testing forms, ranging from relatively inexpensive small-scale laboratory specimens to highly sophisticated full-scale tests. The correlation of physically significant parameters, such as transition temperature and upper shelf energy/toughness, from those test fauns is examined. The ultimate objective is to understand of the similitude of various specimen forms. The similitude allows the prediction of large-scale behavior from small-scale laboratory test specimens. The paper presents data developed from various current and past research programs. The trends exhibited by the various forms of specimens are examined. The implications of those trends in the strain-based design of pipelines are summarized at the end of the paper.
引用
收藏
页码:175 / +
页数:3
相关论文
共 50 条
[21]   MULTI-TIER TENSILE STRAIN MODELS FOR STRAIN-BASED DESIGN PART 1-FUNDAMENTAL BASIS [J].
Wang, Yong-Yi ;
Liu, Ming ;
Zhang, Fan ;
Horsley, David ;
Nanney, Steve .
PROCEEDINGS OF THE 9TH INTERNATIONAL PIPELINE CONFERENCE - 2012, VOL 4, 2013, :447-458
[22]   The role of anisotropy, toughness transferability, and weld misalignment in the strain based design of pipelines [J].
Wang, Yong-Yi ;
Liu, Ming .
PROCEEDINGS OF THE SEVENTEENTH (2007) INTERNATIONAL OFFSHORE AND POLAR ENGINEERING CONFERENCE, VOL 1- 4, PROCEEDINGS, 2007, :3164-+
[23]   Recent advances in curved wide plate testing and implications for strain-based design [J].
Fairchild, D. P. ;
Cheng, W. ;
Ford, S. J. ;
Minnaar, K. ;
Biery, N. E. ;
Kumar, A. ;
Nissley, N. E. .
INTERNATIONAL JOURNAL OF OFFSHORE AND POLAR ENGINEERING, 2008, 18 (03) :161-170
[24]   Development of a high strength steel line pipe for strain-based design applications [J].
Shinohara, Yasuhiro ;
Hara, Takuya ;
Tsuru, Eiji ;
Asahi, Hitoshi ;
Terada, Yoshio ;
Doi, Naoki ;
Ayukawa, Naoshi ;
Murata, Masahiko .
PROCEEDINGS OF THE SEVENTEENTH (2007) INTERNATIONAL OFFSHORE AND POLAR ENGINEERING CONFERENCE, VOL 1- 4, PROCEEDINGS, 2007, :2949-+
[25]   RESEARCH ON ASEISMATIC MEASURES OF GAS PIPELINE CROSSING A FAULT FOR STRAIN-BASED DESIGN [J].
Gu, Xiaoting ;
Zhang, Hong .
PROCEEDINGS OF THE ASME PRESSURE VESSELS AND PIPING CONFERENCE 2009, VOL 5, 2010, :571-580
[26]   Failure prevention of seafloor composite pipelines using enhanced strain-based design [J].
Thang, Vul ;
Hui, David ;
Zhou, Jianren ;
Marshall, Peter W. .
REVIEWS ON ADVANCED MATERIALS SCIENCE, 2022, 61 (01) :306-321
[27]   Strain-based design for segmental tunnel lining under thrust jack load [J].
Ouyang, Ziyan ;
Naito, Clay ;
Quiel, Spencer ;
Mooney, Michael .
STRUCTURE AND INFRASTRUCTURE ENGINEERING, 2025,
[28]   Concepts of grade X100 for high toughness and strain based design application [J].
Schwinn, Volker ;
Fluess, Peter ;
Liessem, Andreas ;
Schroeder, Jens .
PROCEEDINGS OF THE EIGHTEENTH (2008) INTERNATIONAL OFFSHORE AND POLAR ENGINEERING CONFERENCE, VOL 4, 2008, :27-+
[29]   Evaluation of Mechanical Properties and Microstructure of X70 Pipeline Steel with Strain-Based Design [J].
Liu, Denghui ;
Dong, Yifan ;
Li, Rutao ;
Jiang, Jinxing ;
Li, Xiaoyuan ;
Wang, Zhenlong ;
Zuo, Xiurong .
METALS, 2022, 12 (10)
[30]   MULTI-TIER TENSILE STRAIN MODELS FOR STRAIN-BASED DESIGN PART 2-DEVELOPMENT AND FORMULATION OF TENSILE STRAIN CAPACITY MODELS [J].
Liu, Ming ;
Wang, Yong-Yi ;
Song, Yaxin ;
Horsley, David ;
Nanney, Steve .
PROCEEDINGS OF THE 9TH INTERNATIONAL PIPELINE CONFERENCE - 2012, VOL 4, 2013, :415-425
12345