ES2928732T3 - Load cut-off switch or short-circuit currents - Google Patents

Abstract

It is a load-breaking or short-circuit current disconnector (1) that comprises a main circuit (2) for the circulation of electric current and a secondary circuit (3) for the circulation of electric current in shunt. The main circuit (2) is made up of a switch-disconnector (4) with a fixed contact (5) and a mobile one (6), while the secondary circuit (3) is made up of a vacuum switch (7) that is activated by the mobile contact. (6) of the switch-disconnector (4), so that the on-load or short-circuit disconnector (1) of the invention can carry out at least three operating positions, performing - breaking - disconnecting - grounding. (Automatic translation with Google Translate, without legal value)

Description

DESCRIPTION

Load cut-off switch or short-circuit currents

Object of the invention

The present invention relates to a load break switch or short-circuit current switch, for application in electric power distribution networks, comprising a main circuit for circulating electric current and a secondary circuit for circulating electric current in shunt. The main circuit comprises a switch-disconnector with a fixed contact and a mobile contact, while the secondary circuit comprises a vacuum interrupter that is actuated by the mobile contact of the switch-disconnector.

The load break or short-circuit current switch of the invention can adopt at least three operating positions, connection - break - disconnection, as well as a fourth grounding position, in the latter case comprising a grounding contact. , thus compactly arranging a load break switch or short-circuit current switch capable of executing up to four operating positions.

Background of the invention

Currently, the electrical switchgear used in electricity distribution networks is installed in usually metallic enclosures, called cells. Said switchgear includes operating means that carry out the functions of cutting - sectioning - grounding of the installation.

On the one hand, operating means such as disconnectors are used that comprise two contacts that can be joined to let the current pass or leave a physical separation determined by the safety standard or the manufacturer to prevent the passage of the current, and which also comprise a third contact for grounding the electrical circuit. But these disconnectors are sometimes not capable of performing the functions of the switch, that is, cutting the current when the circuit is on load or in the event of a fault due to overcurrent, if they have not been designed for it or do not have the appropriate extinguishing means. .

The use of operating means based on SF6 gas contact separation technology in order to cut the current (the current when the circuit is on load or fault current due to overcurrent) is known. This solution presents numerous advantages in terms of the compactness of the electrical switchgear, its cost and its performance, mainly due to the exceptional properties of SF6 gas, such as dielectric strength, thermal conductivity, chemical stability, etc. However, SF6 gas has the drawback of being part of the gases with a great environmental impact due to its high greenhouse effect potential (GWP = 22800).

On the other hand, operating means constituted by vacuum switches are known, which consist of a bottle inside which is housed a pair of electrical contacts, one fixed and the other mobile that moves by operating a operating mechanism, to perform the functions of cutting - connection of the corresponding electrical circuit. But these vacuum interrupters are not used for current cutting functions when the circuit is on load due to their high cost.

In this sense, solutions are known in which a vacuum interrupter is placed in a secondary or bypass circuit in such a way that the cut-off of the electrical current is guaranteed and at the same time the cost of this technology is reduced due to the fact that the interrupter The vacuum used can have lower benefits as it has to withstand electrical current for a shorter time. This secondary circuit is permanently inactive and is only traveled by electric current when the switch-disconnector arranged in a main circuit has begun its opening sequence, through a progressive transfer of electric current from the main circuit to the secondary circuit. As the vacuum interrupter is generally at rest, it does not have to be dimensioned based on the restrictive electrical and dielectric performance of the permanent regime, such as the closing power against short circuit.

There are examples of the state of the art that deal with this type of solutions that include a main circuit provided with a first means of operation, such as a switch-disconnector, through which the electric current circulates in a permanent regime and a secondary circuit provided with a second means of operation, such as a vacuum interrupter, through which the electrical current flows in shunt, that is, in the opening sequence of the switch-disconnector, the mobile contact of this last element intercepts during its travel of opening with a free end of the secondary circuit and electric current begins to circulate through the secondary circuit at the same time that it circulates through the main circuit. In this way, continuing with the opening sequence, the switch-disconnector is separated from the main circuit without any electric arc being produced in the circuit. The continuation of the opening sequence and therefore the actuation of the mobile contact of the switch-disconnector on the secondary circuit opens the vacuum interrupter, interrupting the electric current, extinguishing the electric arc and thus obtaining the cutting maneuver position. Next, the mobile contact of the switch-disconnector is separated from the free end of the secondary circuit and allows the vacuum interrupter to close its contacts, but without the passage of electric current, since the secondary circuit remains open. At this moment, the sectioning maneuver position has been obtained. In case of have an earthing contact, the mobile contact of the switch-disconnector would follow its opening sequence and when said mobile contact intercepted the earthing contact, the earthing position would be obtained.

In this sense, some public documents that define this type of solution can be cited, for example, ES2387862T3, ES2526220T3, ES2525080T3, DE102004006476B4 or WO2006074975A1.

In document ES2387862T3, the mobile contact of the main circuit disconnector, in its opening sequence, intercepts/interacts with an actuation means arranged in the branch of the secondary circuit and which is associated with the vacuum interrupter by means of a kinematic chain or movement transmission system to act on the mobile contact of said vacuum interrupter and cause its opening. The actuation means is arranged at the free end of the branch of the secondary circuit, connected to it by means of an articulated area equipped with a stop that stops the movement of the actuation means in the opening direction of the disconnector and a spring that returns it. to the stop position at the closing of the disconnector. The actuation means comprises a first face covered by a conductor directed towards the disconnector and a second face opposite to the first and covered with an insulator. The kinematic chain that transmits the movement to the mobile contact of the vacuum interrupter comprises a plurality of elements, such as a mobile part, a rod associated with the mobile contact of the vacuum interrupter, a joint that allows the articulation between the rod and the part mobile, another fixed articulation around which the mobile part rotates, the articulated area that joins the means of actuation with the branch of the secondary circuit, etc. This plurality of elements in the kinematic chain implies a greater space for its assembly, which makes the electrical switchgear itself take up more space and be less compact. Likewise, having so many elements in the kinematic chain makes the transmission of the movement more complex, which reduces its reliability, since all the elements must be well synchronized, and also increases its cost.

Similarly, in the document ES2526220T3 there is a means of actuation of the mobile contact of the vacuum interrupter in the branch of the secondary circuit, with the difference that in this solution the mobile contact of the vacuum interrupter is blocked in its open position until the main circuit disconnector performs the closing sequence. The purpose of this blocking is to protect against a possible quick reclosing of the secondary circuit. However, this blocking means that the vacuum interrupter is not ready for the next breaking maneuver and that the entire branch of the secondary circuit or derivation is not at the same electrical potential while the disconnector is kept open. Likewise, in a similar way to the solution of document ES2387862T3, the kinematic chain that transmits the movement to the mobile contact of the vacuum interrupter comprises a plurality of elements, such as a drive cam, springs, a lever (foldable if necessary), a coupling finger, protruding washers, offset parts, etc., which implies a greater space for its assembly, which makes the electrical switchgear itself take up more space and be less compact. As in the previous case, it supposes the complication of the transmission of the movement due to the need of synchronization of all the elements, as well as the economic inconvenience.

The object of the document ES2525080T3 is to simplify the kinematic chain to transmit the movement to the mobile contact of the vacuum interrupter. In the solution of this document, the number of elements of the kinematic chain (referred to as "control mechanism" in the document) is reduced, which comprises a rotary rocker as means of actuation of the mobile contact of the vacuum interrupter, which connects a rod that is associated with the moving contact of the vacuum interrupter with the moving contact of the main circuit. In this way, a unitary and flexibly mounted rocker replaces a control mechanism made up of parts articulated with each other. As in the previous cases, the actuating means of the mobile contact of the vacuum interrupter, specifically the rocker, is part of the branch of the secondary circuit, the electrical conduction through the branch of the secondary circuit being provided by it. rocker or optionally by a conductive commutation lug, electrically connected to the mobile contact of the vacuum interrupter and extending to a free end superimposed approximately on a free end of the rocker that intercepts the mobile contact of the main circuit, rubbing this mobile contact of the circuit over the free end of the switch tab.

Document DE102004006476B4 also defines an actuation means for the mobile contact of the vacuum interrupter that is part of the branch of the secondary circuit, comprising in said secondary circuit the complete kinematic chain for the transmission of movement to the mobile contact of the vacuum interrupter.

On the contrary, in the document WO2006074975A1 the drive means is part of the main circuit, since in this case the drive means is a cam disc that is electrically and mechanically connected to the moving contact of the main circuit. In this solution, the mobile contact of the vacuum interrupter comprises at its free end an electrically conductive pin element and this pin is intercepted by the cam disc in the opening sequence of the main circuit. In this sense, the cam disc comprises a guide slot in which the pin element is inserted and as the main circuit follows its opening sequence, the pin is forced to go through said guide slot, the pin in turn transmitting said movement. to the moving contact of the vacuum interrupter. Electric current flows in shunt through the pin element and the cam disc. In the closing sequence of the main circuit, the cam disc does not interfere with the pin element, so the vacuum interrupter is not subjected to any action and remains with its contacts closed. This solution It entails the drawback that the guide groove of the cam disc must have a path that is synchronized with the movement path of the mobile contact of the main circuit, so that as said mobile contact of the main circuit moves, the pin element is located at the appropriate point of the guide groove to convert the angular displacement of the mobile contact of the main circuit into a linear displacement that the pin element must transmit to the mobile contact of the vacuum interrupter. In addition, the vacuum interrupter is fixed, that is, the vacuum interrupter does not include any movement, so the guide groove must have a more precise layout.

Regarding the arrangement of the vacuum interrupter in a fixed, static manner, this characteristic, which is also fulfilled in the aforementioned examples of the state of the art, entails another drawback, that referring to the absorption of the shock when the actuating means or the same moving contact of the main circuit intersects with the moving contact of the vacuum interrupter or, in the case of the last example, with the latch element, since the vacuum interrupter and its connections on the secondary circuit do not include any damping means against said hit of the moment of interception.

Description of the invention

The load breaker or short circuit current switch object of the present invention, as defined in independent claim 1 and in the dependent claims, is applicable to electric power distribution facilities, such as transformation centers. electricity, distribution centers, substations, etc., for the protection and operation of electrical circuits, and solves each and every one of the problems mentioned above.

Specifically, said load break switch or short-circuit current switch can be incorporated into an enclosure, and this enclosure can be sealed, and insulated in any dielectric gas such as air, dry air, N ² , O ² , CO ² , or gas mixtures such as fluoroketones with carrier gases such as CO ² , N ² , O ² , air or mixtures thereof, or gas mixtures such as hydrofluoroolefins with carrier gases such as N ² , O ² , dry air, helium, CO ² or mixtures thereof, or sulfur hexafluoride, etc.

The enclosure can comprise at least one means of electrical connection, such as a male or female type bushing, and at least one means of mechanical connection accessible both from its interior and from its exterior, so as to facilitate the coupling of other elements with the enclosure, such as a drive mechanism by means of the mechanical connection means or other electrical switchgear by means of the electrical connection means. The load break switch or short-circuit current switch of the invention is installed inside said casing and therefore insulated in the same gas that contains the casing.

The switch for breaking load or short circuit currents comprises a main circuit for circulating electric current and a secondary circuit for circulating electric current in shunt. The main circuit comprises at least a first operating means, such as a switch-disconnector provided with a fixed contact and a mobile contact, while the secondary circuit comprises at least a second operating means, such as a vacuum switch. comprising inside a fixed contact and a mobile contact.

The load break or short-circuit current switch can adopt at least three operating positions, connection - break - disconnection - earthing, so that the switch-disconnector can also include an earthing contact. In this way, the vacuum interrupter located in the secondary circuit performs the breaking operation and the switch-disconnector of the main circuit performs the connection, sectioning and grounding operations, thus compactly arranging a load breaking switch or of short-circuit currents capable of executing up to four operating positions.

In this sense, in the opening sequence of the switch-disconnector, the mobile contact of this last element intercepts in the course of its opening stroke with a free end of the secondary circuit and the electric current begins to circulate through the secondary circuit at the same time. that circulates through the main circuit. The vacuum interrupter is located at the free end of the secondary circuit, so the vacuum interrupter is actuated by the displacement of the mobile contact of the switch-disconnector. In this state in which the electric current flows through both the main circuit and the secondary circuit, continuing with the opening sequence, the moving contact of the switch-disconnector is separated from the main circuit without any electric arc being produced in the circuit. .

Following the opening sequence, the mobile contact of the switch-disconnector acts on the vacuum interrupter, interrupting the electric current, extinguishing the electric arc and thus obtaining the cutting maneuver position. The mobile contact of the switch-disconnector of the main circuit comprises an actuation means that moves integrally with said mobile contact of the switch-disconnector, said actuation means being connected to the mobile contact by means of a first articulation element, such as a spring for example. return, in such a way that the activation means is the one that acts directly on the vacuum interrupter in the opening sequence of the load break switch or short-circuit currents. It is understood by act directly on the vacuum interrupter, which the same actuation means made up of a single element separates the contacts of the vacuum interrupter, thereby simplifying the kinematic chain, implies less space for mounting, which means that the switchgear itself takes up less space and is more compact. Likewise, having fewer elements in the kinematic chain makes the transmission of the movement easier, which increases its reliability and also makes its cost more economical. The fixed contact of the vacuum interrupter is connected to a fixed part of the secondary circuit by means of a second articulation element, such as a return spring, leaving the mobile contact of the vacuum interrupter free to be actuated by the actuating means in the opening sequence of the load break switch or short-circuit currents. For this, the mobile contact of the vacuum interrupter comprises a stop means with which it mechanically and electrically connects the actuation means in the opening sequence of the load break switch or short-circuit currents. The stop means can comprise at least one bolt, for example, in the form of a latch like the one present in door locks, so that in an opening sequence of the load cut-off switch or short-circuit currents the means of The actuator engages said latch and pulls it until it is released when the vacuum interrupter reaches its cut-off position. In the opening sequence, the actuating means engages the latch on the side that is not curved, which prevents said latch from retracting, and the actuating means is released due to its tilting in the first articulation element, which is when the vacuum switch reaches its cut-off position.

The fixed contact of the vacuum interrupter is connected to the fixed part of the secondary circuit via the second linkage element, so that the vacuum switch comprises a movement around said second linkage element, such as a pendulum movement. Due to this movement of the vacuum interrupter, said vacuum interrupter and also the connections of the same on the secondary circuit do not suffer any dry impact when the actuating means intercepts the mobile contact of the vacuum interrupter, the same movement damps or absorbs a large part of the impact.

Once the cutting maneuver position has been obtained, the actuation means that is connected to the mobile contact of the switch-disconnector is separated from the free end of the secondary circuit, that is, from the stop means of the mobile contact of the vacuum interrupter, and allows the vacuum interrupter to close its contacts, but without the passage of electric current since the secondary circuit remains open, and to return to its initial position thanks to the action of the second articulation element. At this moment, the sectioning maneuver position has been obtained. From this point, the mobile contact of the switch-disconnector would follow its opening sequence and when said mobile contact intercepted the grounding contact, the grounding position would be obtained.

The actuation means comprises a first electrically conductive face and a second electrically insulating or insulated face opposite to the first face, so that in the opening sequence of the load break switch or short-circuit currents, the electrically conductive face is the one that it connects mechanically and electrically with the stop means of the moving contact of the vacuum interrupter.

In the closing sequence of the load break switch or short-circuit current switch, the actuation means does not interfere electrically or mechanically with the vacuum interrupter, and therefore neither with the secondary circuit, because the actuation means comprises the second insulating or electrically insulated face and because in the closing sequence the latch of the stop means of the mobile contact of the vacuum interrupter retracts allowing the actuation means to pass through or the actuation means itself retracts and does not interfere with the means top.

The switch-disconnector comprises an actuation shaft that acts on its mobile contact to execute both the opening sequence and the closing sequence of the load break switch or short-circuit currents.

The possibility has been contemplated that the load-cutting or short-circuit current switch may comprise a casing, in which some of its elements are at least partially integrated, such as the mobile contact of the switch-disconnector, the means of drive, the earthing contact of the switch - disconnector, etc.

Lastly, the load break switch or short-circuit current switch can comprise a three-phase configuration and comprise part of its elements corresponding to the three phases, at least partially, incorporated inside the casing.

Description of the figures

To complement the description and in order to help a better understanding of the characteristics of the invention, according to a preferred example of its practical embodiment, a set of figures is attached as an integral part of said description, in which, For illustrative and non-limiting purposes, the following has been represented:

Figure 1.- Shows a perspective view of the enclosure that incorporates the cut-off switch inside load or short-circuit currents of the invention, where at least one means of electrical connection and one means of mechanical connection accessible from the outside of said casing have been represented.

Figure 2.- Shows an elevation view of the load break switch or short-circuit current switch of the invention.

Figure 3.- Shows a sectional elevation view of the load cut-off or short-circuit current switch in its connection position (the main electrical circuit is closed), where the electrical current circulates only through the main circuit.

Figure 4.- Shows a sectional elevation view of the load break switch or short-circuit current switch once the opening sequence has begun, where the electric current flows through both the main circuit and the secondary circuit.

Figure 5.- Shows a sectional elevation view of the load break switch or short-circuit current switch following the opening sequence, where the electric current only circulates through the bypass secondary circuit.

Figure 6.- Shows a sectional elevation view of the load or short-circuit current break switch following the opening sequence, in its cut-off position.

Figure 7.- Shows a sectional elevation view of the load break switch or short-circuit current switch following the opening sequence, in its isolating position.

Figure 8.- Shows a sectional elevation view of the load cut-off or short-circuit current switch, in its grounding maneuver position.

Figure 9.- Shows a detail of the stop means for the mobile contact of the vacuum interrupter according to a first possible embodiment.

Figure 10.- Shows a detail of the means for stopping the mobile contact of the vacuum interrupter according to a second possible embodiment.

Preferred embodiment of the invention

Figure 1 shows an enclosure (22) inside which the load break switch or short-circuit current switch (1) object of the present invention is installed, and this enclosure (22) can be watertight, and insulated at any time. dielectric gas such as air, dry air, N ² , O ² , CO ² , or gas mixtures such as fluoroketones with carrier gases such as CO ² , N ² , O ² , air or mixtures of the themselves, or gas mixtures such as hydrofluoroolefins with carrier gases such as N ² , O ² , dry air, helium, CO ² or mixtures thereof, or sulfur hexafluoride, etc.

The casing (22) comprises at least one electrical connection means (23), such as a male or female type bushing, and at least one mechanical connection means (24) accessible both from inside the casing (22) and from the outside, in such a way that the coupling of other elements with the casing (22) is facilitated, such as, for example, a maneuvering mechanism by means of the mechanical connection means (24) or other electrical switchgear by means of the electrical connection means (23). ). The load break switch or short circuit current switch (1) of the invention is installed inside said casing (22) and therefore insulated in the same gas that contains the casing (22).

As shown in figures 2-8, the load break switch or short circuit current switch (1) comprises a main circuit (2) for circulating electric current and a secondary circuit (3) for circulating electricity. shunt electrical current. The main circuit (2) comprises at least one first operating means, such as a switch-disconnector (4), provided with a fixed contact (5) and a mobile contact (6), while the secondary circuit (3) It comprises at least one second operating means (7), such as a vacuum switch, which includes a fixed contact (8) and a mobile contact (9) inside. The load break or short-circuit current switch (1) can adopt at least three operating positions, connection - break - disconnection - earthing, so that the switch - disconnector (4) can also include a make contact to ground (15). In this way, the vacuum switch (7) arranged in the secondary circuit (3) performs the cutting operation, as shown in figure 6, while the switch-disconnector (4) of the main circuit (2) performs the connection, sectioning and grounding operations, as shown in figures 3, 7 and 8 respectively.

Starting from the connection position of the load break switch or short-circuit current switch (1) shown in figure 3, in the opening sequence, the mobile contact (6) of the switch-disconnector (4) intercepts in the course of its opening stroke with a free end of the secondary circuit (3) and the electric current begins to circulate through the secondary circuit (3) at the same time that it circulates through the main circuit (2), as shown in the Figure 4. At the free end of the secondary circuit (3) is the vacuum switch (7), so that the vacuum switch ⁽ 7 ⁾ is activated by the displacement of the mobile contact (6) of the switch-disconnector (4).

From this state in which the electric current flows through both the main circuit (2) and the secondary circuit (3), continuing with the opening sequence, the mobile contact (6) of the switch-disconnector (4) is separates from the fixed contact (5) and therefore from the main circuit (2) without producing any electric arc in the circuit, as shown in figure 5, now circulating the electric current only through the secondary circuit (3) .

As shown in figures 3-8, the mobile contact (6) of the switch-disconnector (4) of the main circuit (2) comprises an actuation means (10) that moves integrally with said mobile contact (6). of the switch-disconnector (4), said actuation means (10) being connected to the mobile contact (6) by means of a first articulation element (11), such as a return spring, so that the actuation means (10 ) is the one that acts directly on the vacuum interrupter (7) in the opening sequence of the load break switch or short-circuit currents (1).

The fixed contact (8) of the vacuum interrupter (7) is connected to a fixed part (25) of the secondary circuit (3) by means of a second articulation element (12), such as a return spring, so that the vacuum interrupter (7) containing the contacts (8, 9) comprises a movement around said second articulation element (12), such as a pendulum movement. The mobile contact (9) of the vacuum interrupter (7) is free to be activated by the activation means (10) in the opening sequence of the load break switch or short-circuit currents (1). For this, as shown in figures 3-10, the mobile contact (9) of the vacuum interrupter (7) comprises a stop means (13) with which it connects mechanically and electrically the actuation means (10). in the opening sequence of the load break switch or short-circuit currents (1). The stop means (13) can comprise at least one latch (14), for example in the form of a latch like the one present in door locks, as shown in figure 9, so that in a sequence of opening of the load break switch or short-circuit current switch (1) the actuation means (10) engages said latch (14) and pulls it until it is released when the vacuum switch (7) reaches its cut-off maneuver position, represented in figure 6. In the opening sequence, the actuation means (10) hooks the bolt (14) on the side that is not curved, which prevents said bolt (14) from retracting, and the actuation means (10) is released due to its tilting in the first articulation element (11), which is when the vacuum interrupter (7) reaches its cutting maneuver position represented in figure 6.

The possibility has also been contemplated that the stop means (13) may comprise at least one bolt (14) connected to a different element of the stop means (13) by means of a mechanism (16), as shown in the figure. figure 10, so that in an opening sequence of the load break switch or short-circuit current switch (1) the actuation means (10) engages said latch (14) and this latch (14) retracts once the cut-off position of the vacuum switch (7).

Once the cutting maneuver position has been obtained, as shown in figure 6, the actuation means (10) that is connected to the mobile contact (6) of the switch-disconnector (4) is separated from the free end of the secondary circuit (3), that is, of the stop means (13) of the mobile contact (9) of the vacuum interrupter (7), and allows the vacuum interrupter (7) to close its contacts (8, 9), but without the passage of electric current since the secondary circuit (3) remains open, and that it returns to its initial position thanks to the action of the second articulation element (12).

At this time, the load break switch or short-circuit current switch (1) is in the sectioning position, as shown in figure 7. From this point on, the mobile contact (6) of the switch-disconnector (4) can follow its opening sequence and when said mobile contact (6) intercepts the grounding contact (15) the grounding position is obtained, as shown in figure 8.

As shown in figures 3-8, the actuation means (10) comprises a first face (19) electrically conductive and a second face (20) insulating or electrically insulated opposite the first face (19), in such a way that that in the opening sequence of the load break switch or short-circuit current switch (1) the first electrically conductive face (19) is the one that connects mechanically and electrically with the stop means (13) of the mobile contact (9) of the vacuum switch (7), so that said mobile contact (9) is mechanically actuated while allowing the electrical conduction of the current through the secondary circuit (3).

In the closing sequence of the load break switch or short-circuit current switch (1), the actuation means (10) does not interfere electrically or mechanically with the vacuum switch (7), and therefore neither with the secondary circuit ( 3), due to the fact that the actuation means (10) comprises the second face (20) insulating or electrically insulated and due to the fact that in the closing sequence the bolt (14) of the stop means (13) of the mobile contact (9 ) of the vacuum interrupter (7) retracts allowing the actuation means (10) to pass through or the actuation means (10) itself retracts and does not interfere with the stop means (13).

The switch-disconnector (4) comprises a drive shaft (17), as shown in figures 2-8, that acts on the mobile contact (6) to execute both the opening sequence and the closing sequence of the load break switch or short-circuit currents (1) due to the action of a operating mechanism not represented in the figures and which can be coupled to the casing (22) through the mechanical connection means (24) shown in figure 1.

The possibility has been contemplated that the load break switch or short-circuit current switch (1) may comprise a casing (18), as shown in figures 2-8, where at least partially some of its elements, such as the mobile contact (6) of the switch-disconnector (4), the actuation means (10), the grounding contact (15) of the switch-disconnector (4), etc.

Finally, the load breaker or short-circuit current switch (1) can comprise a three-phase configuration and therefore comprise part of its elements corresponding to the three phases, at least partially, incorporated inside the casing (18).

Claims (12)

1. Switch for breaking load or short circuit currents (1) comprising a main circuit (2) for circulating electric current and a secondary circuit (3) for circulating electric current in shunt, in which the circuit main circuit (2) includes a switch-disconnector (4) provided with a fixed contact (5) and a mobile contact (6), and in which the secondary circuit (3) includes a vacuum switch (7) which in turn It comprises a fixed contact (8) and a mobile contact (9), the vacuum interrupter (7) being activated by the movement of the mobile contact (6) of the switch-disconnector (4), in which the mobile contact (6) of the switch-disconnector (4) of the main circuit (2) comprises an actuation means (10) that moves integrally with said mobile contact (6) of the switch-disconnector (4), said actuation means (10) being connected to the mobile contact (6) of the switch-disconnector (4) by means of a first element joint (11), so that the drive means (10) acts on the vacuum switch (7) in the opening sequence of the load break switch or short-circuit currents (1), and characterized in that the switch vacuum switch (7) is connected to a fixed part (25) of the secondary circuit (3) by means of a second articulation element (12), so that the vacuum switch (7) comprises a movement around said second element of joint (12). Load-break or short-circuit breaker (1) according to claim 1, characterized in that the movement of the vacuum interrupter (7) around the second articulation element (12) is a pendulum movement. 3. Load-cutting or short-circuit current switch (1) according to claim 1 or 2, characterized in that it comprises at least three operating positions, connection - cutting - sectioning - grounding, so that the switch - disconnector (4) includes an earthing contact (15). 4. Load break switch or short-circuit current switch (1) according to any of the preceding claims, characterized in that the fixed contact (8) of the vacuum switch (7) is connected to the fixed part (25) of the circuit secondary (3) through the second articulation element (12), leaving the mobile contact (9) of the vacuum switch (7) free to be actuated by the actuation means (10) in the opening sequence of the cut-off switch in load or short-circuit currents (1). 5. Load break switch or short-circuit current switch (1) according to claim 4, characterized in that the mobile contact (9) of the vacuum switch (7) comprises a stop means (13) with which it connects mechanical and electrically the activation means (10) in the opening sequence of the load cut-off switch or short-circuit currents (1). 6. Load-break or short-circuit current switch (1) according to claim 5, characterized in that the stop means (13) comprises at least one bolt (14) in the form of a latch, so that in a sequence opening of the load break switch or short-circuit currents (1) the actuating means (10) engages said latch (14) and pulls it until it is released when the vacuum interrupter (7) reaches its cut-off position , while in a closing sequence of the load break switch or short-circuit current switch (1) the bolt (14) retracts allowing the actuation means (10) to pass. 7. Load break switch or short circuit current switch (1) according to claim 5, characterized in that the stop means (13) comprises at least one latch (14) connected to a different element of the stop means (13). ) by means of a mechanism (16), so that in an opening sequence of the load break switch or short-circuit currents (1) the actuating means (10) engages said latch (14) and this latch (14) is closed. retracts once the cut-off position of the vacuum interrupter (7) has been reached, while in a closing sequence of the cut-off switch on load or short-circuit currents (1) the drive means (10) retracts and does not interferes with the stop means (13). 8. Load break switch or short circuit current switch (1) according to any of the preceding claims, characterized in that the actuation means (10) comprises a first electrically conductive face (19) and a second insulating face (20). or electrically insulated opposite the first face (19). 9. Load-break switch or short-circuit current switch (1) according to any of the preceding claims, characterized in that the first articulation element (11) and the second articulation element (12) comprise return springs. 10. Load-cutting or short-circuit current switch (1) according to any of the previous claims, characterized in that the switch-disconnector (4) comprises a drive shaft (17) that acts on the mobile contact (6) of the switch - disconnector (4). 11. Load break switch or short-circuit current switch (1) according to any of the preceding claims, characterized in that it comprises a casing (18). 12. Load break switch or short-circuit current switch (1) according to any of the preceding claims, characterized in that it comprises a three-phase configuration.