To sustain the transition to a greener economy and greener manufacturing,it is necessary to develop new approaches and technologies to repair metal components;this will result in a drastic reduction in energy and mate...To sustain the transition to a greener economy and greener manufacturing,it is necessary to develop new approaches and technologies to repair metal components;this will result in a drastic reduction in energy and material usage.In this study,wire arc additive manufacturing(WAAM)was used to deposit a layer of new material on an existing surface,with the objective of finding the optimal configuration that maximized the layer quality and material efficiency.The parameters considered are the stepover among the deposited beads and the inclination of the torch with respect to the repaired surfaces.The inclination angle is crucial when repairing complex surfaces,like those of a mold,owing to accessibility issues,the torch cannot be maintained orthogonal to the surfaces along the entire toolpath.Different configurations were tested in order to assess the quality of the materials in terms of the presence of material voids,depth of penetration,and the heat affected zone(HAZ)and to understand the effects of these variables on the material efficiency and thickness of the repairing layer.It should be noted that by adopting deposition parameters set to have a low heat input,the use of a tilting angle has beneficial effects on the quality of the deposited layer and the process efficiency.Metallurgical and geometrical measurements were carried out to assess the effect of these two variables depositing a layer of plain carbon steel.展开更多
The fracture-cave reservoirs controlled by strike-slip faults are the main targets for oil and gas exploration of ultradeep carbonate in the Tarim Basin.It is of great significance to clarify the distribution rules of...The fracture-cave reservoirs controlled by strike-slip faults are the main targets for oil and gas exploration of ultradeep carbonate in the Tarim Basin.It is of great significance to clarify the distribution rules of fractures related to strike-slip faults for guiding the exploration and development of ultra-deep oil and gas.In this study,six groups of strike-slip fault 3D models based on discrete element numerical simulation method have been created to investigate characteristics of fault-related fracture development and distribution law.In addition,we compared the modeling results to the measurement of fractures from the outcrop of a strike-slip fault in the Northern Tarim Basin to verify their validity.The results show that the stress environment is stable in the simple strike-slip section,and fractures intersecting with the strike-slip direction at a small angle are the principal fracture.In the releasing stepover and double-bend sections,the maximum principal stress changes from horizontal to vertical during the formation of pull-apart zones,where the principal fractures intersect the strike-slip direction at a large angle.The maximum principal stress in the restraining stepover and double-bend section remains horizontal,but their strikes change significantly with the increment of fault displacement.Thus,fractures intersecting the strike-slip direction at a small angle will become principal fractures early on,while those parallel to or anti-intersecting the strike-slip direction at a small angle will become principal fractures later.There are obvious differences in the development of fractures in different structural positions of strike-slip faults.Fractures are mainly concentrated in the fault tips,connections,and fault plane,and the magnitude of the fault damage zone is relatively larger in the first two.Compared with fault displacement,the principal damage zone(PDZ)shows stronger control on the distribution and development intensity of fractures.With the increment of fault displacement,the width of the fault damage zone and the fracture density first rapidly increases before the formation of PDZ and then slows down.Moreover,the formation time of PDZ in the restraining double-bend and stepover section is earlier than the simple strike-slip,releasing double-bend,and releasing stepover sections,and absorb more strain before the formation of the principal displacement zone.Thus,the restraining sections have the highest fracture intensity,followed by the pull-apart sections,then the simple strikeslip section.The results play an important role in understanding the development law of fractures related to strike-slip faults in different arrangements and move modes.展开更多
文摘To sustain the transition to a greener economy and greener manufacturing,it is necessary to develop new approaches and technologies to repair metal components;this will result in a drastic reduction in energy and material usage.In this study,wire arc additive manufacturing(WAAM)was used to deposit a layer of new material on an existing surface,with the objective of finding the optimal configuration that maximized the layer quality and material efficiency.The parameters considered are the stepover among the deposited beads and the inclination of the torch with respect to the repaired surfaces.The inclination angle is crucial when repairing complex surfaces,like those of a mold,owing to accessibility issues,the torch cannot be maintained orthogonal to the surfaces along the entire toolpath.Different configurations were tested in order to assess the quality of the materials in terms of the presence of material voids,depth of penetration,and the heat affected zone(HAZ)and to understand the effects of these variables on the material efficiency and thickness of the repairing layer.It should be noted that by adopting deposition parameters set to have a low heat input,the use of a tilting angle has beneficial effects on the quality of the deposited layer and the process efficiency.Metallurgical and geometrical measurements were carried out to assess the effect of these two variables depositing a layer of plain carbon steel.
基金This work was financially supported by the National Natural Science Foundation of China(Grant No.U21B2062)the 2021 American Association of Petroleum Geologists Foundation Grants-in-Aid Program.
文摘The fracture-cave reservoirs controlled by strike-slip faults are the main targets for oil and gas exploration of ultradeep carbonate in the Tarim Basin.It is of great significance to clarify the distribution rules of fractures related to strike-slip faults for guiding the exploration and development of ultra-deep oil and gas.In this study,six groups of strike-slip fault 3D models based on discrete element numerical simulation method have been created to investigate characteristics of fault-related fracture development and distribution law.In addition,we compared the modeling results to the measurement of fractures from the outcrop of a strike-slip fault in the Northern Tarim Basin to verify their validity.The results show that the stress environment is stable in the simple strike-slip section,and fractures intersecting with the strike-slip direction at a small angle are the principal fracture.In the releasing stepover and double-bend sections,the maximum principal stress changes from horizontal to vertical during the formation of pull-apart zones,where the principal fractures intersect the strike-slip direction at a large angle.The maximum principal stress in the restraining stepover and double-bend section remains horizontal,but their strikes change significantly with the increment of fault displacement.Thus,fractures intersecting the strike-slip direction at a small angle will become principal fractures early on,while those parallel to or anti-intersecting the strike-slip direction at a small angle will become principal fractures later.There are obvious differences in the development of fractures in different structural positions of strike-slip faults.Fractures are mainly concentrated in the fault tips,connections,and fault plane,and the magnitude of the fault damage zone is relatively larger in the first two.Compared with fault displacement,the principal damage zone(PDZ)shows stronger control on the distribution and development intensity of fractures.With the increment of fault displacement,the width of the fault damage zone and the fracture density first rapidly increases before the formation of PDZ and then slows down.Moreover,the formation time of PDZ in the restraining double-bend and stepover section is earlier than the simple strike-slip,releasing double-bend,and releasing stepover sections,and absorb more strain before the formation of the principal displacement zone.Thus,the restraining sections have the highest fracture intensity,followed by the pull-apart sections,then the simple strikeslip section.The results play an important role in understanding the development law of fractures related to strike-slip faults in different arrangements and move modes.