An instrument transformer for high current and/or high voltage conversion includes a housing and at least an active part, which is electrically insulated by an isolation material. The isolation material includes or is a paste and/or pulp. A method for producing the instrument transformer includes the filling of a housing of the instrument transformer with paste and/or pulp, particularly with paste and/or pulp including paper material and/or cellulose, solved in a solvent, particularly at least one ionic liquid.

An instrument transformer for high current and/or high voltage conversion includes a housing and at least an active part, which is electrically insulated by an isolation material. The isolation material includes or is a paste and/or pulp. A method for producing the instrument transformer includes the filling of a housing of the instrument transformer with paste and/or pulp, particularly with paste and/or pulp including paper material and/or cellulose, solved in a solvent, particularly at least one ionic liquid.

A combined instrument transformer for HV applications which includes a current instrument transformer CT, having a current transformer core and a current transformer primary duct fitted into the current transformer core, and a voltage instrument transformer VT, having a voltage transformer core and voltage transformer windings fitted around at least a portion of the voltage transformer core. The current instrument transformer and the voltage instrument transformer are housed in a common internal volume of a single enclosure, the internal volume being delimited by a lateral wall, a base disk insulator and a substantially planar cover.

A combined instrument transformer for HV applications which includes a current instrument transformer CT, having a current transformer core and a current transformer primary duct fitted into the current transformer core, and a voltage instrument transformer VT, having a voltage transformer core and voltage transformer windings fitted around at least a portion of the voltage transformer core. The current instrument transformer and the voltage instrument transformer are housed in a common internal volume of a single enclosure, the internal volume being delimited by a lateral wall, a base disk insulator and a substantially planar cover.

The present invention refers to HV apparatus, in particular a HV dry current transformer, insulated with an insulating gel, or a voltage transformer, insulated with an insulating gel. The dry HV current transformer comprises at least two electrically conductive elements i.e. a head transformer cover, a head housing base, a core casing and a primary conductor. In the dry HV current transformer at least one of the electrically conductive elements has a coating made of solid insulating material separating the surface of the conductive elements from the insulating gel and adapted for limiting the electron emission from the conductive elements into the insulating gel. The voltage transformer comprises a bottom external housing, a bottom support flange, a core. In the voltage transformer at least one of the electrically conductive elements has a coating made of solid insulating material separating the surface of the conductive elements from the insulating gel and adapted for limiting the electron emission from the conductive elements into the insulating gel.

A device for compensating for vibration and/or material stress of a component of a high-voltage system filled with a viscous medium includes a piston and a housing. A first end piece of the piston may be coupled to the component of the system. A second end piece of the piston may be at least partly within the housing and enclosed thereby, enabling movement of the piston and the housing in opposite directions along an axis. The second end piece may be coupled to an inner wall of the housing by at least one spring. The piston and the housing are surrounded by the medium filling the system. A method and computer program product for computer-aided design of a device for compensating for vibration and/or material stress of a component of the system filled with a viscous medium are also provided.

A device for compensating for vibration and/or material stress of a component of a high-voltage system filled with a viscous medium includes a piston and a housing. A first end piece of the piston may be coupled to the component of the system. A second end piece of the piston may be at least partly within the housing and enclosed thereby, enabling movement of the piston and the housing in opposite directions along an axis. The second end piece may be coupled to an inner wall of the housing by at least one spring. The piston and the housing are surrounded by the medium filling the system. A method and computer program product for computer-aided design of a device for compensating for vibration and/or material stress of a component of the system filled with a viscous medium are also provided.

A high voltage instrument transformer includes a measuring assembly and isolator, with at least one sensor for partial discharge measurements. A method for partial discharge recognition in high voltage instrument transformers includes a detection of a signal from at least one sensor for partial discharge measurements, particularly a Transient Earth Voltage sensor.

A high voltage instrument transformer includes a measuring assembly and isolator, with at least one sensor for partial discharge measurements. A method for partial discharge recognition in high voltage instrument transformers includes a detection of a signal from at least one sensor for partial discharge measurements, particularly a Transient Earth Voltage sensor.

The invention relates to a high-voltage device (1), in particular a measuring transducer, with an encapsulating housing (2) and with at least one active component (3), which is arranged in the encapsulating housing (2). The at least one active component (3) is coated with at least one polymer (4). A method according to the invention for increasing the dielectric strength in a high-voltage device (1) involves at least one active component (3), which is arranged in an encapsulating housing (2), in particular filled with clean air (6), being coated with at least one polymer (4), in particular by shrink-fitting a shrink tube and/or by immersion-bath coating and/or by spray coating, wherein the polymer (4) is applied in particular as polytetrafluoroethylene (PTFE), polychlorotrifluoroethylene (PCTFE), polyolefin and/or an ethylenetetrafluoroethylene copolymer (ETFE).