A method and a facility for filling a high- or medium-voltage gas-insulated electrical apparatus in which the insulating gas comprises a mixture of heptafluoroisobutyronitrile ((CF.sub.3).sub.2CFCN) and carbon dioxide. The method and the facility using a mixture of (CF.sub.3).sub.2CFCN and CO.sub.2 in pressurised liquid form which is heated to a temperature no lower than the critical temperature of the mixture.

The present invention relates to an electrical insulation system having a low environmental impact comprising two fundamental elements: a) a gaseous medium formed by one or more highly fluorinated fluoroketones having between 4 and 12 carbons, at least another additional dielectric gas, other than the fluoroketones, with a vapor pressure greater than 500 mbar and less than 15000 mbar at 0 C., such as fluoronitrile (CF.sub.3).sub.2CFCN, for example, and one or more vector gases; and b) a molecular sieve capable of discriminating water molecules from molecules of other gases present in the gaseous medium of the system. The invention also relates to the use of the insulation system and to the medium- or high-voltage electrical switchgear comprising a complete enclosure in which there are arranged live electrical components and an electrical insulation system according to the invention.

An apparatus for heating an insulation fluid in a medium-voltage or high-voltage switchgear comprises an infrared source which is adapted to emit infrared radiation of at least one wavelength. Thus, at least one vibrational or rotational mode of at least one component of the insulation fluid is excited by absorption of at least a part of the infrared radiation, and condensation of the insulation fluid is efficiently prevented by this direct heating of the insulation fluid. A closed loop temperature regulator is used to heat only when required. A circulator in a heating chamber further provides for a mixing of the insulation fluid, thus preventing steep temperature gradients.

The gas-circuit-breaker includes a container, opposing part, movable-part, and nozzle. An arc-extinguishing gas fills the container. The opposing-part is housed in the container and includes an opposing-arc-contact and an exhaust stack. The movable-part is housed in the container and includes a movable-arc-contact coming in contact with the opposing-arc-contact in a connected-state and separating from the opposing-arc-contact in an open-state; and a pressure-accumulation-part where an arc-extinguishing gas pressure increases. The nozzle is housed in the container and includes a space where arc-discharge occurs between the movable-arc-contact and the opposing-arc-contact. The nozzle includes a middle-part where the opposing-arc-contact is inserted and one or more jet-holes that eject, toward the space, partial arc-extinguishing gas flowing in from a flow-passage between the pressure-accumulation-part and the middle-part. The arc-extinguishing gas whose pressure increases in the pressure-accumulation-part flows into the space via the flow-passage and the jet-holes to extinguish the arc-discharge.

The invention relates to the use of a gas as a medium for electrically isolating and/or extinguishing electric arcs, said gas comprising a hexafluorobutene. The invention also relates to an electric device comprising a sealed chamber inside which electric components and said gas are located.

A container for storing and transporting a dielectric insulation medium, including: a container interior for containing the dielectric insulation medium, and connecting means for connecting the container to an electrical apparatus of medium or high voltage and filling a housing of the electrical apparatus with the dielectric insulation medium, said dielectric insulation medium being a mixture of an organofluorine compound or a mixture of organofluorine compounds as component A, the molar percentage of component A being in a range from 1 to 15 mol %, and a carrier gas compound or a mixture of carrier gas compounds other than an organofluorine compound as component B.

The component B may include nitrogen, the molar percentage of nitrogen in the dielectric insulation medium being at least 65 mol %, and the minimum storage and transportation temperature of the container is equal or higher than the cricondentherm of the insulation medium.

The invention relates to medium- or high-voltage, gas-insulated electrical apparatus (10) comprising: a hermetically sealed chamber (12) filled with a dielectric gas, the gas containing at least one of fluoronitrile, carbon dioxide, dinitrogen or dioxygen; at least two electrical contacts (16, 20) arranged coaxially with a main axis (A) of the chamber (12), of which at least one (20) can move axially inside the chamber (12) between a closed position in which the two contacts (16, 20) are in electrical contact with one another and an open position in which the contacts (16, 20) are located at a distance from one another; and a cut-off mechanism (14) for extinguishing the electric arc that forms between the two contacts (16, 20) as the at least one moving contact (20) moves from the closed position into the open position. The cut-off mechanism is of the rotating arc type.

The present invention relates to an electrical apparatus for the generation, the transmission, and/or the distribution of electrical energy comprising a housing enclosing an electrical apparatus interior space, at least a portion of the electrical apparatus interior space forming an insulation space, in which an electrical component is arranged and which contains an insulation medium surrounding the electrical component. The insulation medium contains an organofluorine compound. The electrical apparatus further comprises an adsorber comprising a zeolite for removing at least a part of a contaminant and/or decomposition product resulting from arcing or partial discharge in the insulation space. The apparatus is characterized in that the zeolite contains:

less than 0.5 at % of magnesium (Mg)

less than 0.5 at % of calcium (Ca) and

less than 0.5 at % of iron (Fe).

The disclosure relates to a gas insulated electric apparatus, which includes an enclosure, an electric high voltage appliance arranged inside the enclosure and a permeation barrier arranged within the enclosure and circumferentially surrounding the electric high voltage appliance, whereby the enclosure contains an insulation gas including at least 70% by volume of CO.sub.2 and including an elevated and pre-determined operating gas pressure level, and the permeation barrier includes a permeation layer surrounded on at least one side by a flow promoter layer and/or a surface activation and/or primer layer.

A method for deriving at least one operating parameter of a fluid-insulated electrical apparatus, in particular of gas-insulated switchgear. The operating parameter is dependent on a dielectric breakdown strength of an insulation fluid of the electrical apparatus. The insulation fluid includes at least three components that are assigned to at least a first and a second component group such that at least one component group comprises at least two components. The component groups differ in their weighted average values of the molecular masses of the components in the respective component groups. At least one quantity which is indicative of the concentration of the first component group and of the concentration of the second component group is determined from the insulation fluid, e.g. by measuring one or more measurement variables with one or more sensors. The operating parameter is then derived using the at least one quantity.