A method of manufacturing a winding assembly for an electrical machine, the method comprising: forming, by three-dimensional, 3D, printing, an electrically insulating body comprising a channel defining a winding path, the channel having an inlet and an outlet; heating the electrically insulating body to a temperature above the melting point of an electrically conducting material; flowing the electrically conducting material through the inlet to the outlet to fill the channel; and cooling the electrically insulating body to solidify the electrically conducting material within the channel, thereby forming said winding assembly.

A method of manufacturing a winding assembly for an electrical machine, the method comprising: forming, by three-dimensional, 3D, printing, an electrically insulating body comprising a channel defining a winding path, the channel having an inlet and an outlet; heating the electrically insulating body to a temperature above the melting point of an electrically conducting material; flowing the electrically conducting material through the inlet to the outlet to fill the channel; and cooling the electrically insulating body to solidify the electrically conducting material within the channel, thereby forming said winding assembly.

The present invention relates to a dry-type plug-in bushing, a manufacturing method of same, and a high-voltage installation, more specifically, to a plug-in high-voltage bushing for connecting an external electrical conductor to a high-voltage installation filled with an insulating body, and to a high-voltage installation comprising said bushing. The dry-type plug-in bushing comprises: a conducting body; a cast-type resin insulating body surrounding the conducting body; an electric field-control electrode made of a semi-conducting synthetic resin material, coupled to an upper end of a lower support fitting; the lower support fitting connected to the outer circumference of a lower part of the cast-type resin insulating body; and injected insulating body produced by an insert injection including the outer circumference of the cast-type resin insulating body and electric field-control electrode, having formed thereon a plurality of fins; and a stress cone connected to a lower end of the cast-type resin insulating body.

The present invention relates to a dry-type plug-in bushing, a manufacturing method of same, and a high-voltage installation, more specifically, to a plug-in high-voltage bushing for connecting an external electrical conductor to a high-voltage installation filled with an insulating body, and to a high-voltage installation comprising said bushing. The dry-type plug-in bushing comprises: a conducting body; a cast-type resin insulating body surrounding the conducting body; an electric field-control electrode made of a semi-conducting synthetic resin material, coupled to an upper end of a lower support fitting; the lower support fitting connected to the outer circumference of a lower part of the cast-type resin insulating body; and injected insulating body produced by an insert injection including the outer circumference of the cast-type resin insulating body and electric field-control electrode, having formed thereon a plurality of fins; and a stress cone connected to a lower end of the cast-type resin insulating body.

An object of the present invention is to provide an insulation sheet having high thermal conductivity in the in-plane direction.

The present invention provides an insulation sheet comprising insulating particles and a binder resin, wherein, for the entire cross-section of the sheet perpendicular to the in-plane direction, the insulation sheet contains 75 to 97% by area of the insulating particles, 3 to 25% by area of the binder resin, and 10% by area or less of the voids.

An object of the present invention is to provide an insulation sheet having high thermal conductivity in the in-plane direction.

The present invention provides an insulation sheet comprising insulating particles and a binder resin, wherein, for the entire cross-section of the sheet perpendicular to the in-plane direction, the insulation sheet contains 75 to 97% by area of the insulating particles, 3 to 25% by area of the binder resin, and 10% by area or less of the voids.

A spark plug insulator comprising a ceramic body with a photopolymerized and sintered microstructure. The spark plug insulator can have one or more complex geometries, such as dual axial bores, channels or grooves for wiring or the like, or internal wells. In one embodiment, an internal well is situated in the nose portion of the axial bore. The internal well has a terminal end, a base, and a ceramic bounding ring that is diametrically reduced with respect to a diameter at the base of the internal well. In some embodiments, there is a center electrode shield portion adjacent the internal well, where a diameter of the center electrode shield portion is diametrically reduced with respect to the diameter at the base of the internal well.

A spark plug insulator comprising a ceramic body with a photopolymerized and sintered microstructure. The spark plug insulator can have one or more complex geometries, such as dual axial bores, channels or grooves for wiring or the like, or internal wells. In one embodiment, an internal well is situated in the nose portion of the axial bore. The internal well has a terminal end, a base, and a ceramic bounding ring that is diametrically reduced with respect to a diameter at the base of the internal well. In some embodiments, there is a center electrode shield portion adjacent the internal well, where a diameter of the center electrode shield portion is diametrically reduced with respect to the diameter at the base of the internal well.

A cable includes an insulating part and one or more conducting parts disposed inside the insulating part. The insulating part includes a polymer resin layer with a product of shrinkage ratios C.sub.MD*TD, which is expressed as a product of a longitudinal shrinkage ratio and a transverse shrinkage ratio, of less than 0.24.

A cable includes an insulating part and one or more conducting parts disposed inside the insulating part. The insulating part includes a polymer resin layer with a product of shrinkage ratios C.sub.MD*TD, which is expressed as a product of a longitudinal shrinkage ratio and a transverse shrinkage ratio, of less than 0.24.