EP4388570A1 - Vacuum switch device and method for producing a vacuum switch device - Google Patents

Abstract

The present invention relates to a vacuum switch device (1), having: a housing (5, 6, 10), at one end of which a fixed contact (2) is arranged; a bellows (7), which is fastened on one side to a flange (10) at the other end of the housing (5, 6, 10) and on the other side to a moving contact (3); and a guide bearing (9, 20, 30) for the moving contact (3), which bearing is fastened to the flange (10) and guides the moving contact (3) in a sliding manner, characterised in that the guide bearing (9, 20, 30) is secured on the flange (10) by an adhesive layer (11). The present invention also relates to a method for producing a vacuum switch device.

Description

Description

Vacuum switchgear and manufacturing method for a vacuum switchgear

The present invention relates to a vacuum switching device according to the preamble of claim 1 and a manufacturing method for a vacuum switching device according to the preamble of claim 13.

From the operating instructions "3TM vacuum contactor 7.2 kV - 15 kV, 3-pole, 4.15 kV - 6.9 kV, 1-pole", order no.: 9229 0106 100 0, Siemens AG 2020 a switching device for medium voltage is known, which has a vacuum switching device with an electromagnetic drive. The magnetic drive can exert a magnetic force on a so-called anchor plate and attract it. The movement of the anchor plate is mechanically converted into a movement for pressing a movable contact to a fixed contact inside of the vacuum switching device.The moveable contact is led out of the vacuum via a flexible spring bellows.

A vacuum switching device with a stored-energy mechanism is known from the "3AH4 vacuum circuit-breaker" catalogue, Article No. EMMS-K1511-A041-A6, Siemens AG 2018.

A vacuum switching device within the meaning of the invention has, for example, a fluid-tight housing, inside which there is a vacuum (or an extremely low gas pressure of less than 10~ ³ mbar, preferably less than 10~ ⁶ mbar). Typically, the housing is formed in part as an alumina ceramic insulator bonded to other components of the housing at a metallic flange area. If a movable contact is quickly pulled away from the fixed contact, for example by means of a spring force, an arc that occurs is quickly extinguished. Typically, the current is interrupted in the area of the zero crossing. Vacuum switching devices are particularly well suited for switching alternating current because an arc is always broken when the current crosses zero. The movable contact is brought out of the vacuum via a flexible spring bellows. To stabilize and center the moving contact rod, a guide bearing, preferably made of plastic, is used, which is attached to the flange of the moving contact.

Until now, the guide bearing has often been attached using a separate part, a bearing cap. The bearing cap is soldered to the flange of the moving contact during the soldering process and serves as a mount for the bearing. After inserting the plastic flagers, for example. Fold the top edge of the bearing cap over to secure the bearing. There are also known solutions in which a type of nozzle is pulled out of the flange, which is used to attach the bearing. Furthermore, bearings are known which snap into a locked state during assembly. To do this, the plastic bearing is designed to include snap-in hooks that can snap into the flange opening. This construction is i . A. Mechanically less stable than the first solution given.

Based on previous vacuum switching devices, the object of the invention is to specify a vacuum switching device that is comparatively simple and inexpensive to manufacture and allows a long service life.

The invention solves this problem by a vacuum switching device according to claim 1.

The housing has, for example, a metallic flange as a “cover” and another metallic flange as a “bottom”, which are connected to a ceramic insulating body (e.g. made of aluminum oxide) in the shape of a cylinder jacket. The interior of the housing is evacuated.

A bellows is a wavy component that is thrown up like an accordion and with little mechanical resistance. is compressible and expandable while being fluid-tight and long-lasting. A bellows is z. B. made from thin sheet metal.

A flange is i . i.e. R. a metal connector.

An adhesive layer within the meaning of the invention is a layer less than 5 mm thick with an adhesive that hardens after application and provides high mechanical strength against tearing out when the vacuum switching device is switched on and off and against twisting and buckling movements when switching. As an adhesive Adhesive can be used at least partially an epoxy resin.

A pilot bearing is a component to guide the moving contact through the housing. The movable contact is typically designed in the manner of a bolt, so that the guide bearing provides an elongate hollow cylinder for receiving the bolt. For reasons of cost and because of the good sliding properties of the material, the guide bearing is often made of plastic and formed, for example, by injection molding or by machining. In such a case, the adhesive layer connects a plastic guide bearing to a metal flange.

The adhesive layer between the guide bearing and the flange has the advantage that previously required production steps can be omitted. There is no need to lock the plastic guide bearing on the flange with a metal sheet that is bent radially inward to fix it. This enables fast and more cost-effective production.

Furthermore, it is a significant advantage that, compared to previous designs, an anti-twist device can be aligned between the rod and bearing or a bearing mount can be carried out subsequently to a soldering process for the production of the fluid-tight housing. Another advantage is that the extensive bonding achieves a particularly high level of mechanical stability, which increases the lifespan and service life of the kuumschalteinrichtung increased. A longer life or Service life in turn enables cost savings on the customer side.

In a further development of the vacuum switching device, additional mechanical stabilization can be achieved in that a mechanical locking device presses the guide bearing and the flange together and/or prevents the components from being pulled apart. This relieves the adhesive connection and ensures mechanical stability, e.g. B. also in cases in which the adhesive layer could be loosened by heating during operation of the vacuum switching device as a result of a current flow. The mechanical locking device can, for example, as a so-called. Be trained snap nose. This is a spring device which is fixed at one of its two ends to a cylindrical stabilizing area of the guide bearing and from this in the longitudinal direction (coaxial to the direction in which the movable contact is guided), d. H . towards the contact surface, protrudes. In this context, protruding means that there is a hollow space between the spring device and the stabilization area. This allows the spring means by exerting a pressure from the outside inwards, d. H . in the direction of the stabilization area, are pressed against the stabilization area. The spring device is dimensioned in such a way that it is compressed when the guide bearing is pushed onto the flange. If the flange comes to rest on the contact surface with the adhesive layer, the spring device can snap out again, forming the cavity, and lock the flange in the manner of a barb. It is particularly preferred to subsequently also fill the cavity between the spring device and the stabilization area with the adhesive. After hardening, the lock can no longer be released.

In comparison to previous solutions, which were locked with a sheet metal, the contact area to the flange no longer hollow, but solid to form a contact surface for the adhesive.

In a preferred embodiment of the vacuum switching device according to the invention, the vacuum switching device is designed for low voltage. In the context of the invention, low voltage is characterized by an electrical voltage of up to 1 kV.

In a preferred embodiment of the vacuum switching device according to the invention, the vacuum switching device is designed for medium voltage. In the context of the invention, medium voltage is characterized by an electrical voltage between 1 kV and 52 kV.

In a preferred embodiment of the vacuum switching device according to the invention, the vacuum switching device is designed for high voltage. In the context of the invention, high voltage is characterized by an electrical voltage of more than 52 kV.

In a preferred embodiment of the vacuum switching device according to the invention, the guide bearing has a roughened contact surface on its side facing the flange. Roughened in the context of the invention means that the surface is no longer smooth. A roughened contact surface has z. B. Projections and/or indentations of more than 0.1 mm in height or depth up . A roughened contact surface offers the advantage that a larger surface area is provided for an adhesive, so that a greater mechanical load-bearing capacity of the adhesive bond is achieved.

In a further preferred embodiment of the vacuum switching device according to the invention, the flange has a roughened contact surface on its side facing the guide bearing. Roughened within the meaning of the invention means that the surface is no longer smooth. A roughened surface z. B. Projections and/or indentations of more than 0.1 mm height or . depth up . A roughened surface of the flange offers the advantage that a larger surface area is provided for an adhesive, so that a greater mechanical load-bearing capacity of the adhesive connection is achieved.

In a further preferred embodiment of the vacuum switching device according to the invention, the contact surface has projections. Projections within the meaning of the invention are elevations of any shape compared to the plane of the contact surface, which, for example, B. are at least one mm higher. If indentations are provided on the contact surface, then all areas that are not indented correspond to projections within the meaning of the invention. Protrusions are advantageous because they provide a particularly roughened surface for the adhesive and thus further increase adhesion.

If the movable contact is designed like a bolt, the guide bearing can also be designed radially symmetrically, for example. In such a case, the contact surface z. B. an annular circumferential surface.

In a further preferred embodiment of the vacuum switching device according to the invention, the projections are at least partially arranged transversely to the direction of rotation of the contact surface. The direction of rotation of the contact surface refers to the guide bearing encircling the moving contact, ie. H . forms a peripheral surface for contacting the flange. With a radially symmetrical design of the guide bearing, this direction of rotation can correspond to a circular path on the contact surface. In a different geometric design of the guide bearing, the direction of rotation can also be designed to be multiple or polygonal. Longitudinal to the direction of rotation corresponds to an alignment of the projections with their long side along the circumference around the movable contact, which offers comparatively little resistance to rotational movements during bonding for strength. Longitudinal, for example, includes an orientation of 0° up to +/- 30° relative to the direction of rotation. Transverse to the circumferential direction corresponds to an orientation of the projections with their short side along the circumference around the movable contact, which presents their long side during the bonding and offers a comparatively large resistance to rotational movements. Transverse includes, for example, an orientation of +/- 60° to 90° relative to the direction of rotation.

In a further preferred embodiment of the vacuum switching device according to the invention, the projections are at least partially wave-shaped. This is an advantage because wavy protrusions can be easily manufactured for the guide bearing by plastic injection molding.

In a further preferred embodiment of the vacuum switching device according to the invention, the projections are at least partially cuboid. This is an advantage because wavy projections can also be easily manufactured for the guide bearing using a plastic injection molding process.

In a further preferred embodiment of the vacuum switching device according to the invention, the flange has depressions on its side facing the guide bearing, which are designed to complement the projections on the guide bearing. A complementary designed surface of the flange offers the advantage that projections and depressions can fen interlocking, which allows a particularly strong resistance to torsional forces when shifting. The mechanical strength of the adhesive bond is further improved. In a further development, adhesive gaps can advantageously be provided between the indentations and the projections, so that the adhesive can continue to wet the entire surface of both components to be connected.

In the form of execution explained at the outset, projections are on the guide bearing and, if necessary. Indentations provided on the flange. Just as preferred and technically just as easy However, it is also possible to implement projections on the flange and, if necessary. Provide recesses on the guide bearing.

In a further preferred embodiment of the vacuum switching device according to the invention, the guide bearing has recesses arranged on the contact surface for receiving excess adhesive. This is an advantage because when the guide bearing is pressed onto the flange during production, a consistently thick layer of adhesive is always formed.

In a further preferred embodiment of the vacuum switching device according to the invention, the recesses are designed as at least one annular circumferential groove.

In a further preferred embodiment of the vacuum switching device according to the invention, the guide bearing has a boundary wall on the outer edge of the contact surface, which protrudes at least as high above the contact surface as the projections, and that at least one barrier wall on the side of the contact facing the movable contact surface is arranged which protrudes at least as high above the contact surface as the projections, wherein the barrier wall encloses a flow-through opening for a fluid, and wherein the flow-through opening is arranged between the guide bearing and the movable contact. This has the advantage that the boundary wall and the barrier wall together form a border for the adhesive layer and thus reduce smearing of superfluous adhesive during manufacture.

In a further preferred embodiment of the vacuum switching device according to the invention, the contact surface has at least one adhesive opening for receiving adhesive. Experiments have shown that, in particular, wetting the inner walls of openings in the contact surface after the adhesive has hardened increases the mechanical strength of the adhesive bond. In the simplest case it is at the gluing openings around holes. It is particularly preferred if so much adhesive is applied during manufacture that the adhesive is pressed through the at least one adhesive opening onto the back (or the side of the guide bearing facing away from the contact surface).

A lance of glue then forms in the opening and outside the opening, on the back, a thickening. The adhesive thus forms a rivet-like or mushroom-like shape at the gluing opening, which increases both the security against torsion and the pull-out strength of the glued joint.

In a further preferred embodiment of the vacuum switching device according to the invention, the guide bearing has a stabilizing part that tapers in the direction of the fixed contact, on which a radially inwardly bendable spring part is arranged, which, in the installed state, ensures a press fit of the flange on the contact surface of the guide bearing and / or provides on an inside of the bellows. In conjunction with the adhesive layer, this additional locking further increases the mechanical strength.

In a further preferred embodiment of the vacuum switching device according to the invention, the guide bearing and/or the flange have locking elements for the positive connection between the guide bearing and the flange. For example, catches and recesses can be used as locking elements. A bayonet lock can also be formed by means of the guide bearing and/or the flange. As a result, the mechanical stability, in particular under thermal stress, can be increased even further.

Based on previous manufacturing methods for a vacuum switching device, the invention also has the task of specifying a manufacturing method for a vacuum switching device that is comparatively simple and inexpensive and enables the vacuum switching device to have a long service life. The invention solves this problem with a vacuum switching device according to claim 13 . Preferred embodiments of the manufacturing method according to the invention are explained in the dependent claims 14 and 15 . This results in the same advantages as described above for the vacuum switching device according to the invention.

For a better explanation of the invention show in a schematic representation

Figure 1 from an exemplary embodiment of a vacuum switching device according to the invention, and

FIG. 2 shows a first exemplary embodiment for a guide bearing, and

Figure 3 is a detailed view of the guide bearing according to Figure 2, and

FIG. 4 shows a second exemplary embodiment of a guide bearing, and

FIG. 5 shows a detailed view of the guide bearing according to FIG. 5, and

FIG. 6 shows a detailed view of a side of a guide bearing facing away from the contact surface, and

FIG. 7 shows a detailed view of a guide bearing with a spring part.

In the following figures, components with the same function are provided with the same reference symbols.

FIG. 1 shows an exemplary embodiment of a vacuum switching device 1 according to the invention with a metallic cover 5 on which the vacuum switching device 1 is inserted Fixed contact 2 is attached. The cover 5 connects to a ceramic insulating body 6 made of aluminum oxide. The insulating body 6 in turn is connected to a metallic flange 10 . The cover 5 , the ceramic insulating body 6 and the flange 10 form a fluid-tight housing for the vacuum switching device 1 . A movable contact 3 touches the fixed contact 2 in the illustrated switched-on state of the switching device 1 . The movable contact 3 is fixedly connected to a metallic spring bellows 7 at the attachment point 8 .

At its other end, the metallic spring bellows 7 connects to the flange 10 in a fluid-tight manner. The interior of the housing is evacuated so that the area 4 in which the contacts 2, 3 touch or come close, can be kept evacuated.

The movable contact 3 can be pulled away from the fixed contact 2 to separate the conductive connection. In order to make this possible, the movable contact is slidably mounted in a guide bearing 9 . The guide bearing 9 has a step 14 on which the flange 10 rests. The guide bearing 9 forms a contact surface 12 with the flange 10 which is provided with a layer of adhesive 11 . A rear side 35 of the guide bearing is formed on the side facing away from the adhesive layer.

FIG. 2 shows a first exemplary embodiment of a guide bearing 20 . The guide bearing 20 has a hollow, cylindrical opening 21 for receiving the movable contact. In a stabilization area 22, the diameter of the hollow cylinder tapers in the direction of the fixed contact. Attached to the stabilization area 22 is an attachment area 23 which is provided for forming an adhesive connection with the flange. For this purpose, the attachment area 23 has a contact surface 12 which is designed to be annular in the circumferential direction 38 . Wave-like projections 24 are arranged on the contact surface 12 . The wave-like projections 24 enable a particularly good and stable adhesive connection to the flange if an adhesive layer is applied to the wave-shaped profile 24 during the manufacturing process is applied. The contact surface 12 has a plurality of adhesive openings 25 through which excess adhesive can be pressed during the manufacturing process. He can reach the back 35 (not shown) and rivets or. mushroom-shaped form. This further increases the mechanical stability of the adhesive connection. The step 14 has a number of anti-slip devices 40 which are designed as small and comparatively thin webs. The webs 40 make it possible that when the flange 10 is pressed onto the step 14 or the webs 40 a further improved twisting or. Slip resistance of the connection is achieved.

Several through-flow openings 26 are provided, which enable fluid exchange with the environment when shifting. In this way, the non-evacuated area between the bellows, guide bearing and moving contact is connected to the environment.

Depending on the design and area of application of the vacuum switching device, a gas such as air or an electrical insulating gas such as sulfur hexafluoride or dried compressed air can be exchanged with the environment. For specific purposes, insulating oil or the like can also be discharged through the through-flow openings. A boundary wall 27 is provided on the outer edge of the contact surface 12 and protrudes at least as much beyond the contact surface 12 as the projections 24 . It thus represents a barrier so that no excess adhesive can be smeared to the outside.

Two recesses 28, 29 are provided, which serve to accommodate excess adhesive. The two recesses 28 , 29 are designed as circumferential grooves and enclose the wave-shaped profiled area 24 on both sides.

FIG. 3 shows a detailed view of FIG. 2, in which a barrier wall 32 for the through-flow opening 26 can be seen in particular. The barrier wall 32 is at the movable chen contact facing side of the contact surface 12 and is at least as high above the contact surface 12 as well as the projections 24 . The barrier wall 32 thus enables the through-flow opening to be shielded from excess adhesive and thus ensures that excess adhesive cannot block the through-flow openings 26 during the manufacture of the vacuum switching device.

FIG. 4 shows a guide bearing 30 in which a different type of projection was selected compared to FIG. These are cuboid elements pointing radially outwards. These cuboid projections 31 also form a very good slip resistance for the adhesive layer.

FIG. 5 shows a detailed view of FIG.

FIG. 6 shows a detailed view of a side of a guide bearing or a rear side 35 according to FIG. The through-flow openings 26 and the bonding openings 25 can be seen. The gluing openings 25 and the through-flow openings 26 open into depressions 36 on the rear side 35 .

Guide means 50, 51, which are used to guide a complementarily shaped movable contact 3 in a torsion-proof manner, can also be seen. The guide means 50 is a projection with a rectangular cross-section, while the guide means 51 is designed as a region that is flattened relative to the circular path.

FIG. 7 shows a detailed view of a guide bearing 9 with a spring part 13 . The guide bearing 9 has a stabilizing part 41 that tapers in the direction of the fixed contact, on which a spring part 13 that can be bent radially inward in the direction 42 is arranged 12 of the guide bearing 9 and/or on an inside of the spring bellows 7 . In conjunction with the layer of adhesive 11 , this additional locking further increases the mechanical strength.

Claims

patent claims 1. Vacuum switching device (1), having A housing (5, 6,10) with a fixed contact at one end (2) and a bellows (7) which is fixed on the one hand to a flange (10) at the other end of the housing (5, 6,10) and on the other hand to a moving contact (3), and a guide bearing (9 ,20,30) for the moving contact (3) fixed to the flange (10) and slidably guiding the moving contact (3), characterized in that the guide bearing (9,20,30) is fixed to the flange (10 ) is fixed with an adhesive layer (11). 2. Vacuum switching device (1) according to claim 1, characterized in that the guide bearing (9,20,30) has a roughened contact surface (24) on its side facing the flange (10). 3. Vacuum switching device (1) according to claim 2, characterized in that the contact surface (12) has projections (24,31). 4. Vacuum switching device (1) according to claim 3, characterized in that the projections (24,31) are arranged at least partially transversely to the circumferential direction (38) of the contact surface (12). 5. Vacuum switching device (1) according to claim 3 or 4, characterized in that the projections (24,31) are at least partially wavy (24). 6. Vacuum switching device (1) according to any one of the preceding claims, characterized in that the projections (24,31) are at least partially cuboid (31). 7. Vacuum switching device (1) according to any one of claims 3 to 6, characterized in that the flange (10) on its side facing the guide bearing (9,24,31) has depressions which lead to the projections (24,31) on the Guide bearings (9,20,30) are designed to be complementary. 8. Vacuum switching device (1) according to any one of the preceding claims, characterized in that the guide bearing (9,20,30) on the contact surface (12) arranged recesses (25,28,29) for receiving excess adhesive. 9. Vacuum switching device (1) according to claim 8, characterized in that the recesses (25,28,29) are designed as at least one annular peripheral groove (28,29). 10. Vacuum switching device (1) according to any one of claims 2 to 9, characterized in that the guide bearing (9,20,30) on the outer edge of the contact surface (12) has a boundary wall (27) which protrudes at least as high over the contact surface (12) as the projections (24,31), and that at least one barrier wall ( 32) is arranged on the side of the contact surface (12) facing the movable contact (3), which protrudes at least as high over the contact surface (12) as the projections (24, 31), the barrier wall (32) having a through-flow opening (32) bordered for a fluid, and wherein the flow opening (32) between the guide bearing (9,20,30) and movable contact (3) is arranged. 11. Vacuum switching device (1) according to any one of the preceding claims, characterized in that the contact surface (12) has at least one adhesive opening (25) for receiving adhesive. 12. Vacuum switching device (1) according to any one of the preceding claims, characterized in that the guide bearing 17 (9.20.30) has a stabilizing part (41) tapering in the direction of the fixed contact (2), on which a radially inwardly bendable spring part (13) is arranged, which in the mounted state has a clamping fit of the flange (10) on the contact surface (12) of the guide bearing (9,20,30) and/or on an inside of the spring bellows (7). 13. Manufacturing method for a vacuum switching device (1), with the steps: Provision of a housing (5, 6, 10), at one end of which a fixed contact (2) is arranged, and provision of a bellows (7) which, on the one hand, is attached to a flange (10) at the other end of the housing (5, 6, 10 ) and on the other hand is attached to a moving contact (3), and pressing a guide bearing (9,20,31) for the moving contact (3) to the flange (10), the guide bearing (9.20.31) slidably guides the movable contact (3), characterized by the step of: applying a layer of adhesive (11) to the guide bearing (9,20,31) and/or the flange (10). 14. Manufacturing method according to claim 13, characterized in that a contact surface (12) with projections (24,31) is used for the guide bearing (9,20,31), which is arranged on the side facing the flange (10). 15. Manufacturing method according to claim 14, characterized in that the guide bearing (9,20,31) with a stabilizing part (41) tapering in the direction of the fixed contact (2) is pushed along the movable contact (3) in the direction of the fixed contact (2). is, wherein a radially inwardly bendable spring part (13) is bent inwards by the flange (10) until the contact surface (12) is pressed against the flange (10), whereupon the spring part (13) snaps back radially outwards and a Clamp fit of the flange (10) on the contact surface 18 (12) of the guide bearing (9,20,31) and/or on an inside of the spring bellows (13).