A wire rod disposing device includes: a wire rod delivering mechanism configured to deliver a wire rod from a nozzle at a predetermined speed; a movable stage serving as a member support part configured to support a base plate serving as a disposition target member such that the wire rod is routed after the wire rod is delivered from the nozzle and curved; and a tension application mechanism configured to apply tension to the wire rod, the wire rod being routed to the base plate by being delivered from the nozzle.

A wire rod disposing device includes: a wire rod delivering mechanism configured to deliver a wire rod from a nozzle at a predetermined speed; a movable stage serving as a member support part configured to support a base plate serving as a disposition target member such that the wire rod is routed after the wire rod is delivered from the nozzle and curved; and a tension application mechanism configured to apply tension to the wire rod, the wire rod being routed to the base plate by being delivered from the nozzle.

The invention relates to a device and a method for winding toroidal cores arranged on a toroidal core plane with a wire arranged on a winding plane. The device additionally comprises: a protective cover which is arranged substantially on the toroidal core plane and perpendicularly to the winding plane, is movably mounted in a translational manner horizontally on the toroidal core plane, and is designed to be guided over some regions of the toroidal core during operation, and thereby protect the toroidal core, and to produce an inner mold for at least one wire winding, said wire being wound on the mold. The device additionally comprises: a slide which is arranged substantially on the toroidal core plane and parallel to the protective cover and which is slidably mounted about the protective cover, surrounds some regions of the protective cover, and is designed to push the at least one wire winding wound on the protective cover from the protective cover onto the toroidal core during operation by means of a translational movement.

The invention relates to a device and a method for winding toroidal cores arranged on a toroidal core plane with a wire arranged on a winding plane. The device additionally comprises: a protective cover which is arranged substantially on the toroidal core plane and perpendicularly to the winding plane, is movably mounted in a translational manner horizontally on the toroidal core plane, and is designed to be guided over some regions of the toroidal core during operation, and thereby protect the toroidal core, and to produce an inner mold for at least one wire winding, said wire being wound on the mold. The device additionally comprises: a slide which is arranged substantially on the toroidal core plane and parallel to the protective cover and which is slidably mounted about the protective cover, surrounds some regions of the protective cover, and is designed to push the at least one wire winding wound on the protective cover from the protective cover onto the toroidal core during operation by means of a translational movement.

A method of winding coilware via a winding machine having a plurality of winding devices, which are drivable by a plurality of drives which comprise at least a supply roll and a winding body, includes providing the coilware from the supply roll and winding the coilware over at least one deflection roll onto the winding body, where at least one drive is adjusted as a function of a position-dependent compensation signal at least partly compensating a defect, and where the position-dependent compensation signal for the drive is provided by acquiring a time domain interference variable during a winding operation, transforming the acquired interference variable into a frequency domain spectrum, filtering the spectrum via a filter specific to the winding device assigned to the drive, transforming the filtered spectrum back into the time domain to provide a time-dependent compensation signal, and transforming the time-dependent compensation signal into the position-dependent compensation signal.

A wireless charging coil with a high Q factor includes a plurality of wire groups. Each of the wire groups includes a plurality of wires, a self-bonding film and a plurality of insulation layers. The wires are spun together in a helical manner to form a self-woven structure of the wire group. The self-bonding film surrounds the plurality of wires, and each of the insulation layers covers a surface of a wire. The plurality of wire groups together are wound into a plurality of turns on a same winding surface, and all of the plurality of wire groups are wound on the same winding surface. Each turn is wound by the plurality of wire groups.

A wireless charging coil with a high Q factor includes a plurality of wire groups. Each of the wire groups includes a plurality of wires, a self-bonding film and a plurality of insulation layers. The wires are spun together in a helical manner to form a self-woven structure of the wire group. The self-bonding film surrounds the plurality of wires, and each of the insulation layers covers a surface of a wire. The plurality of wire groups together are wound into a plurality of turns on a same winding surface, and all of the plurality of wire groups are wound on the same winding surface. Each turn is wound by the plurality of wire groups.

Methods, apparatus, systems, and computer-readable media are provided for tracking amounts of wires provided to a winding head during a winding operation of a wire distribution system. The wires can be tracked using one or more wire tracking devices that can be disposed at one or more locations within the wire distribution system. The wire tracking devices can provide information related to the amounts of wires and the types of wires being used to wind about a winding head/form. The information can be used to check for errors during a winding operation and indicate the progress of the winding operation. The information can also be used to update wire-availability data to reflect the amount of wire that has been provided during the winding operation.

Methods, apparatus, systems, and computer-readable media are provided for tracking amounts of wires provided to a winding head during a winding operation of a wire distribution system. The wires can be tracked using one or more wire tracking devices that can be disposed at one or more locations within the wire distribution system. The wire tracking devices can provide information related to the amounts of wires and the types of wires being used to wind about a winding head/form. The information can be used to check for errors during a winding operation and indicate the progress of the winding operation. The information can also be used to update wire-availability data to reflect the amount of wire that has been provided during the winding operation.

Methods, apparatus, systems, and computer-readable media are provided for tracking amounts of wires provided to a winding head during a winding operation of a wire distribution system. The wires can be tracked using one or more wire tracking devices that can be disposed at one or more locations within the wire distribution system. The wire tracking devices can provide information related to the amounts of wires and the types of wires being used to wind about a winding head/form. The information can be used to check for errors during a winding operation and indicate the progress of the winding operation. The information can also be used to update wire-availability data to reflect the amount of wire that has been provided during the winding operation.