DE202011110166U1 - Cooling device for an electrical switchgear, in particular of medium and high voltage engineering - Google Patents

Abstract

Cooling device (10, 30) for an electrical switchgear in particular the medium or high voltage engineering, wherein the switchgear is provided with at least one area in which an elevated temperature may be present, and wherein the cooling device (10, 30) provided for cooling this area characterized in that the cooling device (10, 30) either comprises at least one feed tube (19) for air or a gas, with which the air or the gas can be directed to the area, or at least one feed channel (34, 38) for a liquid with which the liquid can be fed to the area in a targeted manner.

Description

The invention relates to a cooling device for an electrical switchgear in particular the medium or high voltage engineering, wherein the switchgear is provided with at least one area in which an elevated temperature may be present, and wherein the cooling device is provided for cooling this area. The invention also relates to a corresponding electrical switchgear.

For example, in an air-insulated switchgear one or more electrical switches are housed in a housing, which are designed to interrupt a high current. Particularly in the area of the contact surfaces of the two contacts of such a switch, elevated temperatures may occur in the switched-on state of the switch. Such an area with an optionally present elevated temperatures is also referred to as "hot spot".

For cooling an electrical switchgear, it is known, for example, to supply cold air in the lower region of the housing, which then rises inside the housing and leaves the housing again in the upper region. During this movement can be absorbed by the air that heat that arises within the housing of the electrical switchgear. Among other things, the above-mentioned "hot spots" can thus be cooled by the air.

Even if the movement of the air through the housing of the electrical switchgear is at least partially supported by the natural convection, so the cost of supplying a sufficient amount of cooled air is relatively high.

The object of the invention is to provide a cooling device that requires less effort.

The invention solves this problem by a cooling device according to claim 1 and by an electrical switchgear according to claim 2.

According to the invention, the cooling device either has at least one feed tube for air or a gas, with which the air or gas can be fed to the region in a targeted manner, or at least one feed channel for a liquid, with which the liquid can be fed to the region in a targeted manner.

In the invention, therefore, the intended for cooling air or the gas or liquid is precisely fed exactly where there are the "hot spots". The "hot spots" are therefore specifically cooled. This makes it possible to achieve a greater cooling effect with less effort than in the prior art.

If air or gas is provided as the cooling medium, then it is advantageous if the supply pipe is open on one side and aligned with the region with the elevated temperature. Thus, the air or gas can be targeted to the respective "hot spot" supplied.

If a liquid is provided as the cooling medium, then it is advantageous if the supply channel is formed as a recess in a component of the switchgear. Thus, the liquid can be fed through the recess targeted to the respective "hot spot".

In one embodiment of the invention, the feed tube or the feed channel is connected to a supply device with which the air or the gas or the liquid can be supplied. It is particularly advantageous if the electrical energy for driving the supply device can be branched off from the switchgear, in particular via an inductive coupling.

In another embodiment of the invention, the temperature of the region in which an elevated temperature may be present can be determined, in particular measurable, and the volume of the air or gas or liquid pumped through the feed tube or through the feed channel per unit of time is Dependent on the measured temperature controlled and / or regulated.

Other features, applications and advantages of the invention will become apparent from the following description of embodiments of the invention, which are illustrated in the figures of the drawing. All described or illustrated features, alone or in any combination form the subject matter of the invention, regardless of their summary in the claims or their dependency and regardless of their formulation or representation in the description or in the drawing.

1 shows a schematic view of a first embodiment of a cooling device according to the invention,

and 2 shows a schematic view of a second embodiment of a cooling device according to the invention.

In the 1 is a cooling device 10 shown, which can be used for use in air or gas-insulated electrical switchgear in particular the medium or high voltage technology.

For example, in an air-insulated switchgear one or more electrical switches are housed in a housing, which are designed to interrupt a high current. In the 1 is an example of a disconnector 11 shown in a schematic way. This circuit breaker 11 is from a fixed contact 12 and a moving contact 13 built up. The fixed contact 12 has a ladder 14 with an approximately hemispherical contact surface, for example 15 on and the moving contact 13 has a ladder 16 with an approximately U-shaped contact surface 17 on. The U-shaped contact surface 17 is in its dimensions to the hemispherical contact surface 15 customized. The moving contact 13 is in the direction of the arrow 18 movable back and forth.

In the switched-on state of the disconnector 11 , the Indian 1 is shown, is the U-shaped contact surface 17 of the moving contact 13 over the hemispherical contact surface 15 of the fixed contact 12 pushed so that touch the two components. In this state, especially in contact areas of the two contact surfaces 15 . 17 elevated temperatures arise. This may result, inter alia, from the fact that in these contact areas increased ohmic contact resistances are present, so that the flowing current leads to the elevated temperature. Such an elevated temperature region is also referred to as a "hot spot".

At the cooler 10 of the 1 is or is the disconnector 11 one or more feed tubes 19 assigned. In the 1 are exemplary two such feed pipes 19 shown.

In these feed tubes 19 they are tubular conduits that can be made of an electrically non-conductive and heat-resistant material, for example of a plastic. The feed pipes 19 can be flexible or flexible, for example by means of incorporated beads or the like. The feed pipes 19 are mounted in a manner not shown within the electrical switchgear.

The feed pipes 19 are each provided with an open end. The other end of the feed pipes 19 is connected to a non-illustrated supply device, from the air into the supply pipes 19 introduced, in particular can be pumped into it. The feed pipes 19 may be provided at their open end with a nozzle or the like, with which the emerging from the open end of the air can be aligned in a desired direction.

Each of the feed tubes 19 is geared towards a specific goal. These goals are essentially those touch areas of the circuit breaker 11 , which may have an elevated temperature when switched on. The feed pipes 19 are therefore geared to the "hot spots". This is in the 1 through the arrows 20 shown.

In operation, air is passing through the supply pipes 19 pumped through. The air enters at the open ends of the feed tubes 19 and then gets to the respectively associated "hot spots" of the switchgear. The "hot spots" are thus cooled during operation of the switchgear by means of the supplied air.

The number of feed tubes 19 , their respective diameter and / or the volume of the per unit time through the respective feed tubes 19 The air pumped through may vary depending on the particular destination of the individual feed tubes 19 determined and optionally adjusted accordingly.

Optionally, the temperature may be measured at one or more of the "hot spots" using sensors. For example, a sensor on one of the conductors 14 . 16 be arranged. In this case, the volume of the per unit time through the respective feed tubes 19 be controlled and / or regulated as a function of the measured / s temperature / s.

With the help of the feed pipes 19 thus become the "hot spots" of the circuit breaker 11 specifically cooled.

The supply device to which the supply pipes 19 can be connected, can be arranged outside the electrical switchgear. Optionally, the supply device may be provided with a cooler or the like, with which the air provided for cooling and sucked in by the supply device can be cooled.

In the case of an air-insulated switchgear, the air intended for cooling can be sucked in by the supply device outside the switchgear. Optionally, air may be drawn in from an area outside the building where the electrical switchgear is housed. In this case, if necessary, can be dispensed with the aforementioned cooler.

The above-explained cooling device 10 can be used in a similar manner in a gas-insulated switchgear. In this case, the housing of the electrical switchgear is sealed gas-tight and filled with an insulating gas. The insulating gas provided for the cooling must then be sucked in by the supply device within the housing. The Supply device with the optional cooler may be accommodated for this purpose, optionally within the housing of the electrical switchgear. In this case, the electrical energy for the drive of the supply device and possibly also for the radiator via an inductive coupling of one of the two conductors 14 . 16 be diverted.

In the 2 is a cooling device 30 shown, which can be used for use in air or gas-insulated electrical switchgear in particular the medium or high voltage technology.

In the 2 is a circuit breaker 31 present, which is constructed in the same way as the disconnector 11 of the 1 , The features of the circuit breaker 31 of the 2 are therefore identified with the same reference numerals as in the circuit breaker 11 of the 1 , Furthermore, in view of the features and operation of the circuit breaker 31 of the 2 to the explanations of the disconnector 11 of the 1 directed.

Like in the 2 is shown schematically, are the fixed contact 12 and the moving contact 13 at least partially provided with recesses to which a liquid can be supplied. It is understood that even only either the fixed contact 12 or the moving contact 13 can be provided with such recesses.

In the present embodiment of 2 is the area of the fixed contact 12 , which is the hemispherical contact surface 15 forms, with a loop-shaped feed channel 33 provided, the non-illustrated connecting pipes 34 the liquid can be supplied or removed. The direction of movement of the liquid is in the 2 with an arrow 35 characterized.

In a similar way is in the 2 that area of the moving contact 13 who is the leader 16 forms, with a loop-shaped feed channel 37 provided, which also not shown connecting pipes 38 the liquid can be supplied or removed. The direction of movement of the liquid is in the 2 with an arrow 39 characterized.

The feed channels 33 . 37 are over the connecting pipes 34 . 38 with a supply device 41 connected, from which the liquid into the feed channels 33 . 37 introduced, in particular can be pumped into it. The feed channels 33 . 37 and the connecting pipes 34 . 38 form individual cooling circuits for the liquid.

Each of the feed channels 33 . 37 is assigned to a specific destination. These goals are essentially those touch areas of the circuit breaker 31 , which may have an elevated temperature when switched on. The feed channels 33 . 37 are therefore assigned to the "hot spots".

In operation, the liquid passes through the feed channels 33 . 37 pumped through. The liquid flows through the loop-type feed channels 33 . 37 and arrives in this way to the respectively associated "hot spots" of the switchgear. The "hot spots" are thus cooled during operation of the switchgear by means of the supplied liquid.

The number of feed channels 33 . 37 , their respective diameter and / or the volume of the per unit time through the respective feed channels 33 . 37 The fluid pumped through can vary depending on the particular destination of the individual delivery channels 33 . 37 determined and optionally adjusted accordingly.

Optionally, the temperature may be measured at one or more of the "hot spots" using sensors. For example, a sensor on one of the conductors 14 . 16 be arranged. In this case, the volume of the per unit time through the respective feed channels 33 . 37 be pumped and / or regulated as a function of the measured / s temperature / s.

With the help of the feed channels 33 . 37 thus become the "hot spots" of the circuit breaker 31 specifically cooled.

The supply device 41 to which the feed channels 33 . 37 over the connecting pipes 34 . 38 can be connected, can be arranged outside the electrical switchgear. Optionally, the supply device 41 be provided with a cooler or the like, with which the intended for the cooling and sucked by the supply device liquid can be cooled. As liquid, any liquid medium can be used, which can absorb as much heat per unit volume.

The supply device 41 optionally with the cooler may optionally be housed within the housing of the electrical switchgear. In this case, the electrical energy for the drive of the supply device 41 and possibly also for the radiator via an inductive coupling of one of the two conductors 14 . 16 be diverted.

Claims (12)

Cooling device ( 10 . 30 ) for an electrical switchgear, in particular of the medium or high-voltage technology, wherein the switchgear is provided with at least one region in which an elevated temperature can be present, and wherein the cooling device ( 10 . 30 ) is provided for cooling this area, characterized in that the cooling device ( 10 . 30 ) either at least one feed tube ( 19 ) for air or a gas with which the air or the gas can be supplied to the area in a targeted manner, or at least one feed channel ( 34 . 38 ) for a liquid, with which the liquid can be fed targeted to the area. Electrical switchgear, in particular of medium or high-voltage engineering, with at least one region in which an elevated temperature can be present, and with a cooling device ( 10 . 30 ) for cooling this area, characterized in that the cooling device ( 10 . 30 ) either at least one feed tube ( 19 ) for air or a gas with which the air or the gas can be supplied to the area in a targeted manner, or at least one feed channel ( 34 . 38 ) for a liquid, with which the liquid can be fed targeted to the area. Cooling device ( 10 ) or switchgear according to claim 1 or 2, wherein the feed tube ( 19 ) is unilaterally open and aligned with the elevated temperature zone. Cooling device ( 10 ) or switchgear according to claim 3, wherein the open end of the feed tube ( 19 ) is provided with a nozzle. Cooling device ( 10 ) or switchgear according to claim 3 or 4, wherein the feed tube ( 19 ) is flexible and fixed within the switchgear. Cooling device ( 30 ) or switchgear according to claim 1 or 2, wherein the feed channel ( 33 . 37 ) is formed as a recess in a component of the switchgear. Cooling device ( 30 ) or switchgear according to claim 6, wherein the switchgear a circuit breaker ( 31 ), and wherein the feed channel ( 33 . 37 ) within a leader ( 16 ) of the disconnector ( 31 ) and / or within a contact area ( 15 ) forming portion of the circuit breaker ( 31 ) is available. Cooling device ( 10 . 30 ) or switchgear according to one of the preceding claims, wherein the feed tube ( 19 ) or the feed channel ( 33 . 37 ) with a supply device ( 41 ), with which the air or the gas or the liquid can be supplied. Cooling device ( 10 . 30 ) or switchgear according to claim 8, wherein the supply device ( 41 ) is associated with a radiator. Cooling device ( 10 . 30 ) or switchgear according to claim 8 or 9, wherein the supply device ( 41 ) is arranged within a housing of the switchgear. Cooling device ( 10 . 30 ) or switchgear according to claim 10, wherein the electrical energy for the drive of the supply device ( 41 ) is branched off in particular via an inductive coupling of the switchgear. Cooling device ( 10 . 30 ) or switchgear according to one of the preceding claims, wherein the temperature of the region in which an elevated temperature may be present, can be determined, in particular is measurable, and wherein the volume of the / per unit time through the feed tube ( 19 ) or through the feed channel ( 33 . 37 ) or air or gas or liquid pumped and / or controlled as a function of the measured temperature.

Images