The present invention relates to an installation and method for winding an elongated flexible inductor, the proposed installation comprising a first conveyor (11) for moving the elongated flexible inductor (1) in a conveyance direction, supported on a conveyance surface (12); a retaining device (13) for fixing the flexible inductor (1) to said conveyance surface (12); winding means for winding a metallic lead wire (30) around a section of the flexible inductor (1) not supported on said conveyance surface (12), comprising at least one lead wire reel (31), a lead wire feed device (32) and a turning device (33), a holding device (20) provided for holding a portion of the already wound flexible inductor (1), being located opposite and spaced from the end of the first conveyor by a minimum predetermined distance, defining a winding area (50) susceptible to being accessed by said lead wire feed device (32); said turning device (33) causing the simultaneous turning of the first conveyor and of said holding device.

The present invention relates to an installation and method for winding an elongated flexible inductor, the proposed installation comprising a first conveyor (11) for moving the elongated flexible inductor (1) in a conveyance direction, supported on a conveyance surface (12); a retaining device (13) for fixing the flexible inductor (1) to said conveyance surface (12); winding means for winding a metallic lead wire (30) around a section of the flexible inductor (1) not supported on said conveyance surface (12), comprising at least one lead wire reel (31), a lead wire feed device (32) and a turning device (33), a holding device (20) provided for holding a portion of the already wound flexible inductor (1), being located opposite and spaced from the end of the first conveyor by a minimum predetermined distance, defining a winding area (50) susceptible to being accessed by said lead wire feed device (32); said turning device (33) causing the simultaneous turning of the first conveyor and of said holding device.

The present invention may provide a motor including a rotating shaft, a rotor coupled to the rotating shaft, and a stator disposed outside the rotor, wherein the stator includes a stator core having a plurality of teeth, and a coil wound around each tooth of the teeth, the coil is wound a plurality of turns around the tooth, and only the coil of (a*n+1).sup.th turns among the plurality of turns forms a first layer closest to the tooth, wherein a is the number of total stacked layers of the coil, and n is zero or a positive integer.

Disclosed is a method for fabricating coils including the steps of providing a liquid droplet having a diameter on length-scales ranging from hundreds of micrometers to nanometers and bringing a fiber into contact with the liquid droplet, wherein the radius of the liquid droplet is sufficiently high in comparison to the bending elastocapillary length which is defined as where E is the Young's modulus of the elastic fiber, r is the radius of the fiber and γ is the interfacial tension between the droplet and surrounding medium, so that capillary forces induce the spontaneous winding of the fiber around the droplet, to fabricate a coil with a diameter in the range from hundreds of micrometers to nanometers. Also disclosed is a system for making microcoils and to the product thereof.

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.

A pair of iron-based E-shaped cores is arranged so that middle leg core parts of respective E-shaped cores are disposed opposite each other, and coils are respectively attached to the middle leg core parts in a winding state. A cross-sectional area of the middle leg core part orthogonal to an extending direction thereof and a cross-sectional area of an outer leg core part orthogonal to an extending direction thereof have a specified relationship.

A pair of iron-based E-shaped cores is arranged so that middle leg core parts of respective E-shaped cores are disposed opposite each other, and coils are respectively attached to the middle leg core parts in a winding state. A cross-sectional area of the middle leg core part orthogonal to an extending direction thereof and a cross-sectional area of an outer leg core part orthogonal to an extending direction thereof have a specified relationship.

As wire is wound around and onto the surface of a former to form a coil, perturbations such as waves are introduced into turns of the coil, each perturbation being formed in a length of the wire less than the full length of a respective turn and projecting along the former surface, the perturbation having an initial shape and size. The coil is taken from the former and fixed in form. A surrounding jacket is radially collapsed onto the wire coil to uniformly press the coil against an internal compressible body in the course of which the overall diameter of the coil is reduced. Resulting stresses in the wire generated during the collapse are relieved by alteration of the perturbations from their initial shape and size to a subsequent shape and size.

As wire is wound around and onto the surface of a former to form a coil, perturbations such as waves are introduced into turns of the coil, each perturbation being formed in a length of the wire less than the full length of a respective turn and projecting along the former surface, the perturbation having an initial shape and size. The coil is taken from the former and fixed in form. A surrounding jacket is radially collapsed onto the wire coil to uniformly press the coil against an internal compressible body in the course of which the overall diameter of the coil is reduced. Resulting stresses in the wire generated during the collapse are relieved by alteration of the perturbations from their initial shape and size to a subsequent shape and size.

An inductor includes an air-core coil assembled with a T-shaped core and a composite magnetic material and resin mixture embedding the T-shaped core and the air-core coil. The air-core coil has: a coil member having a coil axis and first and second sides opposite to each other; and first and second leads that are integrally connected to the coil member. The first and second leads respectively have: first and second bent members at the first side; first and second ends at the second side; and first and second bottom extensions respectively connected between the first and second bent members and the first and second ends. The first and second bent members extend in a first direction parallel to the coil axis, the first and second ends extend in a second direction parallel to the coil axis, and the first and second bottom extensions extend perpendicular to the coil axis.