Fatigue Crack Growth Behavior in Pipes and Elbows of Carbon Steel and Stainless Steel Materials

“…The data from literature includes the experimental study on FCG behaviour of a full-scale pipe bend of 219 mm outer diameter and thickness of 15.12 mm [5], made of carbon steel (SA333 Gr.6 grade) material. The schematic of the test pipe specimen is shown in Fig.…”

“…This is the focus of the present paper wherein; benchmark analysis has been carried out towards validation of numerical Fatigue Crack Growth (FCG) simulation. It may be highlighted that the characteristics of FCG had been investigated by many researchers in the past [3][4][5][6][7][8][9][10][11]. In the present research, two representative geometries studied in the open literature [4][5] have been selected.…”

“…It may be highlighted that the characteristics of FCG had been investigated by many researchers in the past [3][4][5][6][7][8][9][10][11]. In the present research, two representative geometries studied in the open literature [4][5] have been selected. The selected geometries are (i) a typical plate-type geometry with a specimen-type feature and (ii) a prototype pipe bend with the component feature.…”

“…The bending stress variation in the SFR piping system has a positive load ratio (R), which is defined as the ratio of the minimum stress ( min ) to maximum stress ( max ) during the cyclic load. Towards comparing the FCG behaviour of the specimen level plate-type geometry, data reported in [4] is used, and for the prototype geometric simulation, the full-scale pipe bend test data reported in [5] is used.…”

Specimen Level and Component Level Simulations of Fatigue Crack Growth Behavior under Cyclic Bending

“…The data from literature includes the experimental study on FCG behaviour of a full-scale pipe bend of 219 mm outer diameter and thickness of 15.12 mm [5], made of carbon steel (SA333 Gr.6 grade) material. The schematic of the test pipe specimen is shown in Fig.…”

“…This is the focus of the present paper wherein; benchmark analysis has been carried out towards validation of numerical Fatigue Crack Growth (FCG) simulation. It may be highlighted that the characteristics of FCG had been investigated by many researchers in the past [3][4][5][6][7][8][9][10][11]. In the present research, two representative geometries studied in the open literature [4][5] have been selected.…”

“…It may be highlighted that the characteristics of FCG had been investigated by many researchers in the past [3][4][5][6][7][8][9][10][11]. In the present research, two representative geometries studied in the open literature [4][5] have been selected. The selected geometries are (i) a typical plate-type geometry with a specimen-type feature and (ii) a prototype pipe bend with the component feature.…”

“…The bending stress variation in the SFR piping system has a positive load ratio (R), which is defined as the ratio of the minimum stress ( min ) to maximum stress ( max ) during the cyclic load. Towards comparing the FCG behaviour of the specimen level plate-type geometry, data reported in [4] is used, and for the prototype geometric simulation, the full-scale pipe bend test data reported in [5] is used.…”

Specimen Level and Component Level Simulations of Fatigue Crack Growth Behavior under Cyclic Bending

“…Fatigue crack growth study in pressure vessels and piping is being carried out by many researchers [13][14][15][16][17][18][19][20][21][22][23] . Darcis et al 18 reported the experimental investigation of fatigue crack growth rates in ferrite-pearlite pipeline steels using curved middle-tension M(T) specimens.…”

Experimental fatigue crack growth analysis and modelling in part‐through circumferentially pre‐cracked pipes under pure bending load

Fatigue crack growth behavior of a 170 mm diameter stainless steel straight pipe subjected to combined torsion and bending load