A winding device includes: a winding core having a winding body and flanges provided on both sides of the winding body in a rotation-axis direction, the winding core being configured such that a wire rod supplied from a supply source is wound around the winding body being rotated; a guide member configured to be rotated together with the winding core, the guide member being configured to guide the wire rod to the winding body; and an axial-direction moving mechanism configured to move the guide member in the rotation-axis direction of the winding core.

The invention relates to a method for producing a helical metal body (1, 1′), in particular made of aluminum or an aluminum alloy. A blank is first produced in a primary shaping process, a metal forming process, or in a removal process, in particular a machining process, and one or more recesses (100, 101, 201, 202, 203) are then introduced into the blank using a removal process, said recesses defining a circumferential coil, the adjacent windings thereof being mutually spaced, in particular electrically insulated from one another.

A coil forming apparatus includes: a coil winding jig including a plurality of comb-shaped grooves; a coil conveying mechanism that pivotally conveys the belt-shaped coil along at least a portion of the outer periphery of the coil winding jig; and guide members guide the belt-shaped coil in an arc shape along an outer periphery of the coil winding jig while being in contact with the side ends, and allow the plurality of straight portions to be inserted into a respective one of the plurality of comb-shaped grooves in a second half portion of the belt-shaped coil upon pivot conveyance. The guide members include a reforming portion in a first half portion of the belt-shaped coil upon pivot conveyance, and the reforming portion deforms and reforms the belt-shaped coil in an arc shape in a state sandwiching the side ends of the belt-shaped coil.

The application discloses coils of an electrical machinery and a method for forming the coil, a stator of an electrical machinery and a method for forming the stator, and an electrical machinery. The method includes: providing a first conductor and a second conductor, a resistivity of the second conductor being lower than a resistivity of the first conductor; obtaining a rated current rising coefficient according to a desired power of the electrical machinery, the rated current rising coefficient being a ratio of a rated current of the electrical machinery with the desired power to a rated current of a reference electrical machinery; obtaining, according to the rated current rising coefficient, a first conductor turn number of the first conductor and a second conductor turn number of the second conductor in each coil; forming the coil according to the first conductor turn number and the second conductor turn number.

A motor for a surgical instrument includes a rotor and a stator. The rotor includes a shaft and a magnet. The stator includes (i) a cavity in which the rotor is disposed, and (ii) a coil assembly. The coil assembly includes multiple phase sets. The phase sets include multiple sets of wires. Each of the phase sets includes multiple coils and corresponds to a respective one of the sets of wires. The coils in each of the phase sets are at respective positions about the rotor. One of the sets of wires includes at least three wires. The stator causes the rotor to axially rotate a surgical tool of the surgical instrument based on current received at the sets of wires.

An electric work machine includes: a motor comprising a stator including coils, a rotor rotatable relative to the stator, and a rotor shaft fixed to the rotor; an output unit driven by the rotor shaft; a motor case including a main body having an insertion opening, and a lid disposed on one side in an axial direction relative to the main body and connected to the main body to close the insertion opening; and a resin portion that includes a first portion covering the coils and a second portion disposed on one side in the axial direction relative to the first portion. The first and second portions are integrated. Each of the first and second portions has a tubular shape. A second inner diameter indicating an inner diameter of the second portion is larger than a first inner diameter indicating an inner diameter of the first portion.

A method for producing a helical, electrically conducting body. The method including: producing a helical pattern as a lost mold made of a pattern material that can be at least one of liquefied and evaporated under the action of heat; covering the helical pattern with an insulating layer; embedding the helical pattern in foundry sand; pouring a metallic casting material into the lost mold, displacing the pattern material, and bonding with the insulating layer to form a cast body; and removing the cast body, together with the insulating layer adhering thereto, from the foundry sand.