A wire forming machine with a plurality of tools, a wire fed in a wire feeding direction including a supporting base, a main tool holder rotatably supported by the base holding one of the plurality of tools, a first control drive source configured to control a position of the main tool holder at an arbitrary rotation position; a holder supporting table rotatably supported by the supporting base, a second control drive source to control a position of the holder supporting table at an arbitrary rotation, a first sub tool holder rotatably supported by the holder supporting table about a first sub rotation axis, the sub tool holder holding one of the plurality of tools, and a first interlock mechanism including a gear group or a belt coupling interlockingly rotatably the sub tool holder to the main tool holder to transfer drive force of the first control drive source and holder.

A wire forming machine with a plurality of tools, a wire fed in a wire feeding direction including a supporting base, a main tool holder rotatably supported by the base holding one of the plurality of tools, a first control drive source configured to control a position of the main tool holder at an arbitrary rotation position; a holder supporting table rotatably supported by the supporting base, a second control drive source to control a position of the holder supporting table at an arbitrary rotation, a first sub tool holder rotatably supported by the holder supporting table about a first sub rotation axis, the sub tool holder holding one of the plurality of tools, and a first interlock mechanism including a gear group or a belt coupling interlockingly rotatably the sub tool holder to the main tool holder to transfer drive force of the first control drive source and holder.

A press (1) for the extrusion of non-ferrous metal section bars comprising a shear (2), an adjustment mechanism of the shear (3) and a matrix. Said shear (2) is adapted to perform both horizontal and vertical movements of the press (1) to adjust the correct distance between a blade (21) of the shear (2) and the matrix (11) of the press (1).

A press (1) for the extrusion of non-ferrous metal section bars comprising a shear (2), an adjustment mechanism of the shear (3) and a matrix. Said shear (2) is adapted to perform both horizontal and vertical movements of the press (1) to adjust the correct distance between a blade (21) of the shear (2) and the matrix (11) of the press (1).

An extrusion method using an extrusion press including an end platen to which a pressure ring is provided, a die, a container, a drive part for movement of the container, and a main cylinder device having an extrusion stem to form a billet into a shape includes extruding the billet loaded in the container by the extrusion stem from the die to shape it to an extruded material, releasing sealing pressure from the die, cutting the billet between the die and the container and between the die and the pressure ring by moving the die, and resuming shaping of extruded materials by the billet remaining inside the container.

An extrusion method using an extrusion press including an end platen to which a pressure ring is provided, a die, a container, a drive part for movement of the container, and a main cylinder device having an extrusion stem to form a billet into a shape includes extruding the billet loaded in the container by the extrusion stem from the die to shape it to an extruded material, releasing sealing pressure from the die, cutting the billet between the die and the container and between the die and the pressure ring by moving the die, and resuming shaping of extruded materials by the billet remaining inside the container.

A load binder includes a U-shaped bracket, a pawl member, a ratchet wheel, a ratchet wheel module, a spool, and a driving shaft structure. The spool is disposed in the U-shaped bracket which has a first through hole and a second through hole. The spool has a first locking groove and a second locking groove. The pawl member is rotatably connected with the U-shaped bracket and meshes with the ratchet wheel. The ratchet wheel module is connected with the ratchet wheel and passes through the first through hole into the first locking groove. The ratchet wheel module is soldered to the spool and rotatably connected with the U-shaped bracket. The driving shaft structure passes through the second through hole into the second locking groove. The driving shaft structure is soldered to the spool and rotatably connected with the U-shaped bracket. A method is used for manufacturing the load binder.

A load binder includes a U-shaped bracket, a pawl member, a ratchet wheel, a ratchet wheel module, a spool, and a driving shaft structure. The spool is disposed in the U-shaped bracket which has a first through hole and a second through hole. The spool has a first locking groove and a second locking groove. The pawl member is rotatably connected with the U-shaped bracket and meshes with the ratchet wheel. The ratchet wheel module is connected with the ratchet wheel and passes through the first through hole into the first locking groove. The ratchet wheel module is soldered to the spool and rotatably connected with the U-shaped bracket. The driving shaft structure passes through the second through hole into the second locking groove. The driving shaft structure is soldered to the spool and rotatably connected with the U-shaped bracket. A method is used for manufacturing the load binder.

A load binder includes a U-shaped bracket, a pawl member, a ratchet wheel, a ratchet wheel module, a spool, and a driving shaft structure. The spool is disposed in the U-shaped bracket which has a first through hole and a second through hole. The spool has a first locking groove and a second locking groove. The pawl member is rotatably connected with the U-shaped bracket and meshes with the ratchet wheel. The ratchet wheel module is connected with the ratchet wheel and passes through the first through hole into the first locking groove. The ratchet wheel module is soldered to the spool and rotatably connected with the U-shaped bracket. The driving shaft structure passes through the second through hole into the second locking groove. The driving shaft structure is soldered to the spool and rotatably connected with the U-shaped bracket. A method is used for manufacturing the load binder.

A load binder includes a U-shaped bracket, a pawl member, a ratchet wheel, a ratchet wheel module, a spool, and a driving shaft structure. The spool is disposed in the U-shaped bracket which has a first through hole and a second through hole. The spool has a first locking groove and a second locking groove. The pawl member is rotatably connected with the U-shaped bracket and meshes with the ratchet wheel. The ratchet wheel module is connected with the ratchet wheel and passes through the first through hole into the first locking groove. The ratchet wheel module is soldered to the spool and rotatably connected with the U-shaped bracket. The driving shaft structure passes through the second through hole into the second locking groove. The driving shaft structure is soldered to the spool and rotatably connected with the U-shaped bracket. A method is used for manufacturing the load binder.