An inductor for a converter of an electric machine includes a core defining a channel configured to receive transmission fluid on an outer surface of the core. Coils made of windings are wrapped on the core. The windings enclose an open side of the channel to define an oil flow passage, wherein oil flowing through the oil flow passage is in direct contact with both the windings and the core to absorb heat from the windings and the core.

An arrangement to cool a coil, comprising an enclosure, which at least partially incorporates or houses the coil, and a device to create an airflow to cool the coil, wherein the coil comprises at least one cooling channel to guide the airflow through the windings of the coil and an outer air duct lying radially in the outer circumference area of the coil or lying radially inside below an outer part of the coil, characterized in that an air guidance plate is placed at or near one longitudinal end of the outer air duct and/or of the coil to prevent bypasses of the airflow and/or to block at least partially the airflow through and/or along the outer air duct, achieves the object to cool a coil, especially a coil of a transformer, in an efficient manner using space-saving means.

An electrical device for connecting to a high-voltage network has a vessel, which is filled with an insulating fluid, an active part, which is arranged in the vessel and which has a magnetizable core and partial windings for producing a magnetic field in the core, and a cooling apparatus for cooling the insulating fluid. The electrical device can be operated at high temperatures. At least one barrier system is provided, which at least partly delimits encapsulated spaces, in each of which at least one partial winding is arranged, the barrier system guiding the insulating fluid cooled by the cooling apparatus across the encapsulated spaces in such a way that different encapsulated-space temperatures arise in the encapsulated spaces.

A first plate-like portion is provided with a plurality of first holes extending therethrough in a central axis direction. A second plate-like portion is provided with a plurality of second holes extending therethrough in the central axis direction. The plurality of first holes, the plurality of second holes, a first notch and a second notch overlap one another, to thereby form a flow path which connects one side and the other side of each of a plurality of insulating plates and through which insulating oil can flow in a first direction.

The present disclosure discloses a coil structure for a dry-type transformer and a winding method therefor. The coil structure for a dry-type transformer comprises multiple coil layers and a supporting framework, which is provided with multiple supporting layers. The spacer blocks of each intermediate supporting layer comprise a rising spacer block for rising and supporting spacer blocks in addition to the rising spacer block, a thickness of the rising spacer block being greater than a thickness of the supporting spacer block, and the rising spacer blocks of several intermediate supporting layers being staggered along the circumferential direction. The present disclosure decreases the height of the entire coil efficiently, meanwhile abates the problem that the wire is centralized in a single area, inhibits the temperature rise phenomenon of transformers efficiently, and prolongs the lifetime of transformers.

A support structure is configured to be arranged at least partially in a space provided between at least two coil segments of a transformer. The support structure comprises an elongated body having at least a first side and a second side. The support structure comprises at least one fluid passage opening provided in at least a section of the elongated body. The at least one fluid passage opening is configured to allow a fluid to pass therethrough from the first side to the second side. A transformer has a support structure arranged in a space between at least two coils segments of the transformer.

A coil component includes a body having first and second surfaces opposing each other, and third and fourth surfaces connected to the first and second surfaces and opposing each other, a support member disposed in the body, a coil disposed on at least one surface of the support member and including at least one turn around a core, a first non-magnetic layer extending from a side surface of the support member to the first to fourth surfaces of the body, and first and second external electrodes disposed on the body and connected to the coil.

A method for manufacturing an electric winding of an electromagnetic induction apparatus includes providing a conductor structure including a conductor element extending longitudinally along a main extension direction and one or more spacer tapes of electrically insulating material around said conductor element along said main extension direction, each spacer tape having spacer portions at corresponding lateral surfaces of said conductor element and spaced one from another along the lateral surfaces. The method includes forming an electric winding extending axially along a winding direction and having a plurality of turns arranged around said winding direction where each turn is formed by a corresponding longitudinal portion of said conductor element. The spacer portions are interposed between adjacent turns at opposite sides and respectively positioned spaced one from another to define an empty space to form a radial channel of the electric winding and configured for a passage of an electrically insulating medium

A multiple parallel conductor that is easy to produce and use and has a plurality of twisted, insulated individual conductors. The individual conductors are arranged above one another in a plurality of sub-conductor bundles arranged next to one another. A strip is applied to the multiple parallel conductor on a side surface of the multiple parallel conductor in the longitudinal direction of the multiple parallel conductor, on which strip spacer plates are arranged so as to be distributed in the longitudinal direction, and the multiple parallel conductor together with the strip and the spacer plates is wrapped with a wrapping.

A cooling structure for a transformer according to an embodiment includes a coil and a partition member. The partition member covers the coil along the axial direction on the downstream side in the flow direction of the refrigerant that flows along the axial direction parallel to the center axis of the coil.