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                 Fatigue Crack Propagation Behavior and Fatigue Life Prediction of L360MS

                             Pipeline Steel Welded Joint in Bimetallic Composite Pipe

                            LI Yangyang , WANG Jixiang , ZHOU Peishan , XU Yingchao , WANG Bin  1
                                        1
                                                                                    3
                                                                      1
                                                       2
                          (1. School of New Energy and Materials, Southwest Petroleum University, Chengdu 610500, China;
                                2. China Petroleum Pipeline Research Institute Co., Ltd., Langfang 065000, China;
                                 3. West-East Gas Transmission Branch, Pipe China, Shanghai 200122, China)
                       Abstract: Multi-layer and multi-pass butt welding of L360MS pipeline steel/N08825 nickel-based alloy bimetallic
                  composite pipe was carried out by using NiCrMo-3 alloy as welding material. The hardness and tensile properties of
                  welded joint of L360MS pipeline steel after stripping N08825 nickel-based alloy coating were measured. The fatigue
                  crack propagation test according to the actual operating conditions was carried out on welded joints of L360MS pipeline
                  steel. The crack length-cycle number curves in different regions were obtained by using the flexibility method. The
                  fatigue crack propagation behavior in different regions was studied on the basis of caculation of the Paris formula, and the
                  fatigue life was predicted. The results show that after tensile test, the joint specimen was fractured at base metal, and
                  the weld was in a high-strength matching state. The hardness of the weld was in the range of 220‒250 HV, which was
                  significantly higher than that of the base metal (170‒185 HV). The highest hardness appeared in the weld area adjacent
                  to the fusion line, and the lowest hardness appeared in the heat affected zone. The fatigue cracks in the base metal,
                  heat affected zone and weld mainly propagated in intergranular and transgranular modes. However, the fatigue crack
                  propagation path in the weld was more tortuous, accompanied by bifurcation and even annular cracks. The Paris material
                  constant C of the heat affected zone was the largest, followed by the base metal, and that of the weld was the smallest.
                  Under the stress ratio of 0.1, the fatigue crack propagation rates of the base metal and the heat affected zone were faster,
                  and that of the weld was the slowest. After modifying the material constant C, the life prediction formula of fatigue crack
                  propagation along the depth direction was obtained. It was predicted that the fatigue life of the heat-affected zone of the
                  pipe with semi-elliptical cracks along the circumference of the pipe body was the shortest, and the heat-affected zone was
                  the weakest area of the fatigue performance of the welded joint.
                       Key words: L360MS pipeline steel; welded joint; fatigue crack propagation; fatigue life
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