An automatic installation machine, which is connectable to a tool so as to install a wire thread insert in a thread bore, includes a drive unit providing movement between a first and a second rotation direction, a setting spindle in rotation coupling with the drive unit so that during a transmission of a rotation movement from the drive unit, the setting spindle is displaceable in longitudinal direction independent of the rotation movement. A first pneumatic cylinder has a movable piston oriented parallel to the longitudinal direction of the setting spindle and coupled with an offset with the setting spindle so that the setting spindle is axially displaceable by the pneumatic cylinder. An actuating mandrel is arranged within the setting spindle and is driven rotation free, and the installation machine includes a tool chuck via which the tool for installing the insert is connectable with the setting spindle.

An automatic installation machine, which is connectable to a tool so as to install a wire thread insert in a thread bore, includes a drive unit providing movement between a first and a second rotation direction, a setting spindle in rotation coupling with the drive unit so that during a transmission of a rotation movement from the drive unit, the setting spindle is displaceable in longitudinal direction independent of the rotation movement. A first pneumatic cylinder has a movable piston oriented parallel to the longitudinal direction of the setting spindle and coupled with an offset with the setting spindle so that the setting spindle is axially displaceable by the pneumatic cylinder. An actuating mandrel is arranged within the setting spindle and is driven rotation free, and the installation machine includes a tool chuck via which the tool for installing the insert is connectable with the setting spindle.

An object of the present invention is to suppress variations in an angle of a shoulder part of a segment coil to improve easiness in inserting segment coils in a stator core.

A stator of an electric motor according to the present invention includes a stator core 12 in which a plurality of slots 12a are formed, and a plurality of segment coils 11 of U shapes inserted respectively in the plurality of slots 12a.

The segment coil 11 includes a shoulder part 11a and a shoulder part 11b that are bent to form a U shape. In a front view of the U shape, a press mark 100a is formed on the shoulder part 11a and on the shoulder part 11b, the press mark being a dent sinking in a front-to-rear direction, from a front surface of the shoulder part 11a and from a front surface of the shoulder part 11b. The press mark 100a is formed also on a back surface of the shoulder part 11a and on a back surface of the shoulder part 11b.

An object of the present invention is to suppress variations in an angle of a shoulder part of a segment coil to improve easiness in inserting segment coils in a stator core.

A stator of an electric motor according to the present invention includes a stator core 12 in which a plurality of slots 12a are formed, and a plurality of segment coils 11 of U shapes inserted respectively in the plurality of slots 12a.

The segment coil 11 includes a shoulder part 11a and a shoulder part 11b that are bent to form a U shape. In a front view of the U shape, a press mark 100a is formed on the shoulder part 11a and on the shoulder part 11b, the press mark being a dent sinking in a front-to-rear direction, from a front surface of the shoulder part 11a and from a front surface of the shoulder part 11b. The press mark 100a is formed also on a back surface of the shoulder part 11a and on a back surface of the shoulder part 11b.

The invention relates to an apparatus and a method for shaping one or more conductor pieces arranged in a stator core, wherein the conductor piece is a hairpin with two elongate legs and a connection portion connecting these two legs, wherein a large number of conductor pieces is arranged in the stator core, which conductor pieces are arranged in rows extending in a radial direction on a plurality of circular paths extending in a circumferential direction, and wherein the shaping takes place in a free end of the conductor piece that projects from the stator core.

The invention relates to an apparatus and a method for shaping one or more conductor pieces arranged in a stator core, wherein the conductor piece is a hairpin with two elongate legs and a connection portion connecting these two legs, wherein a large number of conductor pieces is arranged in the stator core, which conductor pieces are arranged in rows extending in a radial direction on a plurality of circular paths extending in a circumferential direction, and wherein the shaping takes place in a free end of the conductor piece that projects from the stator core.

An article of manufacture for providing multi-colored aluminum spirals for document and book binding is disclosed. The article being a spiral made from a length of wire having a specified gauge that is processed by one or more drive rollers coupled to a forming machine using a method of manufacture. The method sets a pitch value for a manufactured spiral on a forming machine, sets a diameter value for the manufactured spiral on the forming machine, receives the length of wire by one or more drive rollers, processes the length of wire by the forming machine using the set pitch value and the set diameter value to create the spiral, dips a first portion of the spiral into a first anodizing solution, and dips one or more additional portions into additional anodizing solutions after the first anodizing solution has set.

An article of manufacture for providing multi-colored aluminum spirals for document and book binding is disclosed. The article being a spiral made from a length of wire having a specified gauge that is processed by one or more drive rollers coupled to a forming machine using a method of manufacture. The method sets a pitch value for a manufactured spiral on a forming machine, sets a diameter value for the manufactured spiral on the forming machine, receives the length of wire by one or more drive rollers, processes the length of wire by the forming machine using the set pitch value and the set diameter value to create the spiral, dips a first portion of the spiral into a first anodizing solution, and dips one or more additional portions into additional anodizing solutions after the first anodizing solution has set.

A material for porous metal body having a coil shape of a wire material wound in a helical shape, made of metal which having good thermal conductivity and can join by sintering; an average wire diameter Dw of the wire material is 0.05 mm to 2.00 mm inclusive, an average coil outer diameter Dc is 0.5 mm to 10.0 mm inclusive, a coil length L of 1 mm to 20 mm inclusive, and a winding number N is 1 to 10; and the plurality of materials for porous metal body are combined and sintered to form a metal porous body having a plurality of pores so that a pore ratio of the metal porous body is facilitated to be controlled.

A wire forming apparatus 1 comprises a rotary table 22 that is rotatably supported by a table body 21, a slide tool unit 100A that is attached to the rotary table 22 and supports a slide tool T1 capable of sliding toward a wire guide, and a tool slide mechanism 60 that is supported by the table body 21 and transmits a driving force for sliding the slide tool T1 to the slide tool unit 100A. The tool slide mechanism 60 has a single motive power transmission member 61 that is rotatably supported by the table body 21, and a driving force generated by a rotation of the motive power transmission member 61 is transmitted, in common, to a plurality of slide tools T1 attached to the rotary table 22.