A method for producing a tube (101-104), the method comprising: providing a preform (1a-c, 70) in a mandrel (2), the preform (1a-1c, 70) having two ends; flow forming the preform (1a-c, 70) with a plurality of rollers (4-5,31-38) such that in one flow forming pass neither one of the two ends of the preform (1a-1c, 70) is flow formed, thereby producing the tube (101-104); and mechanically forming mechanical connection ends on the two ends of the tube (101-104). Also, a seamless tube (101-104), a pipeline comprising a plurality of seamless tubes (101-04), and a machine for flow forming a preform (1a-1c, 70) into a tube (101-104).

A method for producing a tube (101-104), the method comprising: providing a preform (1a-c, 70) in a mandrel (2), the preform (1a-1c, 70) having two ends; flow forming the preform (1a-c, 70) with a plurality of rollers (4-5,31-38) such that in one flow forming pass neither one of the two ends of the preform (1a-1c, 70) is flow formed, thereby producing the tube (101-104); and mechanically forming mechanical connection ends on the two ends of the tube (101-104). Also, a seamless tube (101-104), a pipeline comprising a plurality of seamless tubes (101-04), and a machine for flow forming a preform (1a-1c, 70) into a tube (101-104).

Embodiments of the present disclosure include a method for fabricating a perforating gun including forming an expendable hollow carrier (EHC) via a drawing process. The method also includes determining a wall thickness of the EHC is above a threshold. The method includes machining a coupling component to at least one end of the EHC. The method further includes installing perforating components within an interior of the EHC.

Embodiments of the present disclosure include a method for fabricating a perforating gun including forming an expendable hollow carrier (EHC) via a drawing process. The method also includes determining a wall thickness of the EHC is above a threshold. The method includes machining a coupling component to at least one end of the EHC. The method further includes installing perforating components within an interior of the EHC.

Rolling stand for oblong metal products comprising a plurality of rolling rolls (11) each installed on a respective rotation shaft (12). Between at least one rotation shaft (12) and the respective rolling roll (11), a coupling member (15) is provided and is configured to couple the rolling roll (11) and the rotation shaft (12) to each other. The coupling member (15) comprises a tubular body (16) interposed between the rolling roll (11) and the rotation shaft (12) and provided with a chamber (17) in which a deformer element (18) is inserted mobile.

Rolling stand for oblong metal products comprising a plurality of rolling rolls (11) each installed on a respective rotation shaft (12). Between at least one rotation shaft (12) and the respective rolling roll (11), a coupling member (15) is provided and is configured to couple the rolling roll (11) and the rotation shaft (12) to each other. The coupling member (15) comprises a tubular body (16) interposed between the rolling roll (11) and the rotation shaft (12) and provided with a chamber (17) in which a deformer element (18) is inserted mobile.

Embodiments of the present disclosure include a method for fabricating a perforating gun including forming an expendable hollow carrier (EHC) via a drawing process. The method also includes determining a wall thickness of the EHC is above a threshold. The method includes machining a coupling component to at least one end of the EHC. The method further includes installing perforating components within an interior of the EHC.

Embodiments of the present disclosure include a method for fabricating a perforating gun including forming an expendable hollow carrier (EHC) via a drawing process. The method also includes determining a wall thickness of the EHC is above a threshold. The method includes machining a coupling component to at least one end of the EHC. The method further includes installing perforating components within an interior of the EHC.

A rotary crimping tool assembly includes a tool housing defining a crimping chamber, and one or more crimp wheels within the crimping chamber. The crimping chamber is configured to receive the portion of the structure in proximity to the crimp wheel(s). The crimp wheel(s) are configured to be pressed into and rotated relative to the portion of the structure to form one or more crimps in the portion of the structure.

A rotary crimping tool assembly includes a tool housing defining a crimping chamber, and one or more crimp wheels within the crimping chamber. The crimping chamber is configured to receive the portion of the structure in proximity to the crimp wheel(s). The crimp wheel(s) are configured to be pressed into and rotated relative to the portion of the structure to form one or more crimps in the portion of the structure.