EP2347424A1

EP2347424A1 - Surge arrester with a varistor element and method for producing a surge arrester

Info

Publication number: EP2347424A1
Application number: EP09752782A
Authority: EP
Inventors: Dirk Springborn; Gundolf Barenthin; Erhard Pippert; Markus Sulitze
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2008-11-11
Filing date: 2009-11-02
Publication date: 2011-07-27
Also published as: US20110216464A1; AU2009315833A1; CN102209996B; BRPI0921887A2; KR20110082559A; CA2743094A1; DE102008057232A1; US8531812B2; WO2010054947A1; CN102209996A

Abstract

A surge arrester has a varistor element (6). A first and a second armature body (7, 8) are pressed against the varistor element (6) by means of a bracing device. At least one of the armature bodies (7, 8) has a shoulder (9a, 9b, 9c, 9d) on which a crossmember (1, 2) of the bracing device is supported. A tensioning leg (5a, 5b) is fitted to the crossmember (1, 2).

Description

description

Surge arrester having a varistor element and method of manufacturing a surge arrester

The invention relates to a surge arrester having a varistor element, against which at opposite ends a first and a second fitting body are pressed via a bracing device.

Such a surge arrester is known, for example, from US Pat. No. 4,812,944. The local surge arrester is limited at opposite ends of its varistor element of valve bodies. For bracing the valve body against the varistor element a clamping device is provided. It is proposed, for example, to form hooks on the fitting bodies, in which fibers or bands can be suspended. In order to achieve a tension between the valve bodies is further proposed to shrink the fibers or bands, for example by the action of heat radiation.

During a manufacturing process, hooking the fibers / tapes into the hooks requires a large number of work steps. Furthermore, the position of the fibers / tapes in the hook and the fitting body on the varistor element must be secured in a suitable manner until the surge arrester is distorted. Due to the complex construction of the overvoltage arrester, an assembly of the same is complicated.

Therefore, it is an object of the invention to provide a surge arrester ter, which is designed in a simplified and thus cheaper to manufacture. According to the invention this is achieved in a surge arrester of the type mentioned in that at least one of the fitting body has a shoulder on which a traverse of the bracing is supported and at least one tensile strand is struck on the traverse.

The use of a traverse on the bracing and a support of the traverse to a shoulder of the valve body are in itself rigid elements for transmitting contact forces between the bracing and the

Used valve bodies. So it is for example possible to put the crosshead under pretension on the shoulder. Thus, a self-locking construction is provided, which already causes a tension immediately after placing the traverse on the shoulder. Thus, there is a possibility, during the manufacture of a surge arrester, for example, after attachment of the bracing device to the fitting body free of stabilization frame or the like, to be transported and further processed.

It can be advantageously provided that mutually facing support surfaces are formed complementary shape on traverse and shoulder.

The traverse lies with a support surface on a support surface of the shoulder. In this case, the support surfaces should be at least partially complementary shape, so that accidental slipping or deflecting the traverse is prevented by the shoulder. For this purpose, it can be provided, for example, that the shape-complementary support surfaces have sections which at least partially have surface sections extending in the direction of the contact force to be generated by the clamping device. Such surface sections can, for. B. protrude perpendicularly from the support surfaces and protrude into this. In the support surfaces pins, holes, locking lugs, recesses and the like can be arranged. However, it is also possible, for example, to introduce profilings in support surfaces. For example, wave profiles, asymmetrical teeth, symmetrical teeth or the like can be used.

An advantageous embodiment may provide that a few number of tension cords is struck on a crossbar.

In order to ensure a support of the valve body via the Verspannein- direction, it is necessary that at least one tensile strand between valve bodies or one or more traverses transmits tensile forces. When using a pull string this can be struck, for example, centrally on the crossbar. The tension cord can itself be designed with an angle stiffness. However, it can also be provided that the tensile strand is unstable in itself, for example flexibly deformable or elastically extensible. In order to produce a uniformly distributed contact force between the valve bodies, the arrangement of an even number of tensile strands on a cross member may be advantageous. Thus, for example, be provided that on either side of a support surface one or more tensile cords are positioned so that after a successful placement of a traverse on a shoulder, transverse to a direction of traverse of the crossbar, both sides of the shoulder on the crossbar battered tensile strands extend. A traverse is a rigid body, to which, for example, several tensile cords are struck. The tension cords are spaced from each other. The traverse can be used to move forces between the traction strands are transmitted or forces are transferred to other components. A traverse is preferably formed as a cross member, which serves a mechanical stabilization, connection and attachment.

Furthermore, it can be advantageously provided that at least one of the fitting body relative to the Verspannrichtung the fitting body on the varistor element has a plurality of symmetrically distributed circumferentially arranged shoulders.

By means of a clamping device, a holding force between the valve bodies is generated in a clamping direction. The clamping direction preferably passes through the varistor element. Preferably, the individual tension cords should be arranged distributed on the outer circumference of the varistor element, so that a cage formed from the individual tensile strands surrounds the varistor element on the shell side. Thus, after the bracing has been braced, additional mechanical protection of the varistor element can be ensured. Assigning now several shoulders symmetrically distributed on the circumference of the fitting body, it is possible, for example, in a similar design of several trusses and several tension strands an approximately uniform distribution of tension cords. Due to the position of the shoulders, a position of the trusses is clearly defined. Consequently, a cage structure is formed around the varistor element by the tensile strands attached to the trusses. A bracing device can have a plurality of independently arranged on shoulders of a valve body truss.

Furthermore, it can be advantageously provided that the bracing device has two oppositely oriented uniform cross-members. If one equips the bracing with oppositely oriented similarly shaped trusses, so it is possible to connect the trusses by means of at least one, preferably by means of several, preferably in a paired number of tension strands with each other. It is thus possible, for example, to press fitting bodies located at opposite ends of the varistor element with shoulders arranged thereon with the interposition of the varistor element against one another. By choosing the length of the tension cords, there is a possibility to regulate the tensioning force to be applied by the tensioning device. Depending on requirements, the fitting body can be pressed against the varistor element with a more or less strong force. In addition to a formation of a mechanically rigid angular rigid

Überspannungsabieiters can be done by applying an increased clamping force and an electrical contacting of the valve body with the varistor element. This provides a possibility of electrically contacting the varistor element via the fitting bodies and of using the varistor element, for example, for protection against overvoltages in electrical power transmission devices.

Advantageously, it can be provided that the first and the second fitting body are shaped similarly.

A use of similar valve bodies makes it possible to choose a mounting position of the surge arrester comparatively free. Furthermore, the use of identical parts additionally reduces the number of components to be designed. As a result, the storage can be made cheaper, thereby reducing the total manufacturing costs for a surge arrester. A further object of the invention is to specify a method for producing a surge arrester having a first and a second fitting body, which are pressed against opposite ends of a varistor element by means of a bracing device.

According to the invention the object is achieved in a method of the above type in that at opposite ends of the varistor each of the first and the second Armatur- turkörper placed and pressed by external forces against the varistor element that a first and a second traverse at opposite ends at least a pull string are struck that the first cross member on a shoulder of the first fitting body and the second Traverse are placed on a shoulder of the second fitting body and the external forces are reduced and pressing the fitting body against the varistor element on the tensioned tensile strand and the traverses of the bracing takes place.

By placing the fitting body on the varistor element and pressing it against the varistor element by an external force, a compression of the assemblies to be joined together occurs. This compression can be in the range of a few millimeters, the compression should preferably be reversible. By connecting the two trusses a bracing is created, which can be placed on shoulders of the two fitting body. In this case, the dimension of the pull strands or should be chosen such that a smooth placement of the trusses is allowed on the shoulders, the train or strands are already exposed during placement of a bias. This preload Prevents unintentional release of the attached trusses against their pushing direction on the shoulders.

After placing the trusses, which are connected to each other via the at least one tensile strand, the external forces are reduced. Due to the reduction of the external forces, there is a reversal of the compression of the varistor element or of the fitting body during the application of the external forces. By the withdrawal of the external forces is an elongation of the stack of valve bodies and the varistor element. As a result, the tension cords are placed under increased tension. About the attached to the valve bodies trusses a lengthening of the valve body and the varistor element is limited and the stack pressed against each other.

Now an angle rigid stack is formed, which, for example, after a successful tightening of the tension cords is disassembled by again external forces from opposite directions can act on the valve body and compresses the stack of valve bodies and varistor, so that the tension cords are relaxed and the trusses can be taken down from the shoulders. This provides a possibility for carrying out, for example, repairs to surge arresters produced in this way.

In the following, an embodiment of the invention is shown schematically in a drawing and described in more detail below.

It shows the 1 shows a striking of tension cords on two trusses, the

2 shows a stack of valve bodies and a varistor element during the application of trusses

Shoulders of the fitting body, and the

Figure 3 is a strained surge arrester.

In the figure 1 an embodiment variant of a Verspannelementes is exemplified. A bracing device can have one or more bracing elements. In this case, the bracing element has a first cross member 1 and a second cross member 2. The first and the second traverse 1, 2 are designed as similar shaped body. Here are the

Trusses 1, 2 each have a cuboidal basic structure, wherein two opposite ends of the trusses 1, 2 each have broken corners in such a way that a portion of a lateral surface of a circular cylinder is formed. In the region of the rounded ends, the trusses 1, 2 each have recesses 3a, 3b. These recesses 3a, 3b are, for example, shaped like a blind hole. The recesses 3a, 3b lie in a support surface. The support surface is bounded by two mutually parallel body edges of the traverse 1, 2. The two parallel body edges go over into curved body edges of the rounded ends and connect the two mutually parallel body edges each end. In the support surface a recess 4 is formed. The recess 4 is formed in the present example as a groove. The support surface of the traverse 1, 2 with the corresponding recess 4 serves to be placed on a shape-complementary support surface of a shoulder 9a, 9b, 9c, 9d. In particular, through the recess 4, a transverse to the Verspannrichtung the bracing directed Abglei- th a crossbeam 1, 2 prevented by a shoulder 9a, 9b, 9c, 9d.

Pulling cords 5a, 5b are used in the recesses 3a, 3b. In the exemplary embodiment, the tension cords 5a, 5b are designed as dimensionally stable rods. The tension cords should preferably have an electrically insulating effect, so that formation of a flow path between the cross members 1, 2 arranged at the end of the tension strands and oriented opposite to one another is prevented. Fiberglass rods for forming the tension cords 5a, 5b have proven successful. In addition, other suitable materials may be used. The tension cords 5a, 5b are inserted into the recesses 3a, 3b of the trusses 1, 2 and struck there. An attack of the tension cords 5a, 5b on the trusses 1, 2 can be done by various methods or devices. It is thus possible, for example, to attach the tension cords 5a, 5b to the trusses 1, 2 in a material-locking, non-positive or positive-locking manner. In this case, it has proved favorable to clamp or compress the tension cords 5a, 5b in the recesses 3a, 3b.

After a successful striking of the tension cords 5a, 5b on the first and the second traverse 1, 2, a bracing element is formed, which can transmit forces between the traverses 1, 2 via the tension cords 5a, 5b.

FIG. 2 shows a stage during the manufacture of a surge arrester. The surge arrester has a varistor element 6. The varistor element 6 is, for example, a sintered metal oxide body which optionally has a multiplicity of stacked subsections. At the end of the varistor element 6, a first fitting body 7 and a second fitting body 8 arranged. The fitting body 7, 8 are designed to be electrically conductive, so that via the fitting body 7, 8, an electrical contacting of the varistor element 6 can take place. Thus, it is possible, for example, to loop the varistor element 6 between a live phase conductor and ground potential to protect an electrical device. Depending on requirements, various shapes for the fitting body 7, 8 may be provided. In the present example, the two fitting body 7, 8 are formed similarly, wherein they are opposite to each other aligned at opposite ends of the varistor element 6 are placed on the varistor element 6. The varistor element 6 preferably has circular end faces for this purpose. On the circular faces Kontaktierungsflachen the fitting body 7, 8 are placed. At the remote from the contacting surfaces of the valve body 7, 8 sides contacting blocks are provided. For example, cable lugs can be screwed to the contacting blocks in order to bring about electrical contacting of the surge arrester. It can also be provided that corresponding threaded rods or other suitable elements are screwed or formed on the contacting blocks.

With regard to their pressing direction against the varistor element 6, the two fitting bodies 7, 8 have radially projecting shoulders 9a, 9b, 9c, 9d on their circumference. These shoulders 9a, 9b, 9c, 9d are equipped with a support surface. In the support surfaces 4 surveys 10 are formed in the support surfaces of the trusses 1, 2 to the wells opposite. Thus, the support surfaces of the trusses 1, 2 at least partially opposite to the support surfaces of the shoulders 9a, 9b, 9c, 9d formed. The stack of first fitting body 7, varistor element 6 and second fitting body 8 is compressed by external forces F and compressed. Now, however, at least one bracing element can advantageously be placed on the shoulders 9a, 9b, 9c, 9d but several bracing elements. Here, the distance between mutually aligned arranged shoulders 9a, 9b, 9c, 9d on the first fitting body 7 and the second fitting body 8 is selected such that the tensioning device with the first cross member 1 and second cross member 2, via the ailing pull cords 5a, 5b with each other are connected, latching on the elevations 10 on the shoulders 9a, 9b, 9c, 9d are pushed in a direction of delay. Due to the counter-running recess 4 in the support surfaces of the trusses 1, 2 is a position assurance of the trusses 1, 2 at the shoulders 9a, 9b, 9c, 9d given. In the present example, two bracing elements forming a bracing device are provided which have similar braces 1, 2 and tension elements 5a, 5b. If necessary, the number of bracing elements can be increased. For example, it is possible to arrange three or four bracing elements around the varistor element 6 symmetrically distributed. For this purpose, a corresponding number of shoulders on the two valve bodies 7, 8 are provided.

After the bracing elements have been snapped onto the shoulders 9a, 9b, 9c, 9d, the external forces F are reduced. As a result, the compression caused on the armature bodies 7, 8 and the varistor element 6 reverses, so that an expansion of the armature body 7, 8 and the varistor element 6 takes place in the clamping direction of the clamping device. Thus, the Verspannelemente the bracing are set under increased tension. However, the bracing device is dimensioned such that the expanding stack of valve bodies 7, 8 and varistor element 6 itself can not fully expand to its original dimension.

For a sufficient tension of the valve bodies 7, 8 is given to the varistor element 6. During the unloading of the valve body 7, 8 and the varistor element 6 of the external forces F can also be provided that the tension cords 5a, 5b are elongated, so that also from the tension cords 5a, 5b may emanate an additional contact force.

About the trusses 1, 2 and the shoulders 9a, 9b, 9c, 9d to the first and the second fitting body 7, 8, a stable tension of the surge arrester takes place.

As shown in Figure 3, it is provided that the rounded ends of the trusses 1, 2 have a dielectrically shielding effect on the contacting blocks of the first and second fitting body 7, 8.

The surge arrester formed in this way can be surrounded by a housing for its protection. It is possible, for example, to use electrically insulating throws or to provide a plastic encapsulation on the surge arrester.

Claims

claims

1. surge arrester having a varistor element (6), against which at opposite ends a first and a second fitting body (7, 8) are pressed by a clamping device, characterized in that at least one of the fitting body (7, 8) has a shoulder (9a, 9b , 9c, 9d), on which a traverse (1, 2) of the bracing device is supported and at least one tensile strand is attached to the traverse (1, 2).

2. Surge absorber according to claim 1, characterized in that one of the support surfaces facing one another on traverse (1, 2) and

Shoulder (9a, 9b, 9c, 9d) are formed complementary to the shape.

3. Surge arrester according to claim 1 or 2, characterized in that a pair of tensile strands is struck on a traverse (1, 2).

4. surge arrester according to one of claims 1 to 3, characterized in that at least one of the fitting body (7, 8) relative to the Verspannrichtung the fitting body (7, 8) on the varistor element (6) a plurality of symmetrically distributed circumferentially arranged shoulders (9a, 9b, 9c, 9d).

5. surge arrester according to one of claims 1 to 4, characterized in that the bracing device comprises two oppositely oriented uniform cross-members (1, 2).

6. Surge arrester according to one of claims 1 to 5, characterized in that the first and the second valve bodies (7, 8) are of similar shape.

7. A method for producing a surge arrester having a first and a second valve body (7, 8), which are pressed by a bracing against opposite ends of a varistor element (6), characterized in that at opposite ends of the varistor each of the first and the second valve body (7, 8) are placed and pressed against the varistor element (6) by external forces, that - a first and a second traverse (1, 2) at opposite ends of at least one pull string (5a, 5b) are struck that

- the first crossmember (1) on a shoulder (9a, 9b, 9c, 9d) of the first fitting body (7) and the second crossmember (2) on a shoulder (9a, 9b, 9c, 9d) of the second fitting body (8) be set up and

- The external forces are reduced and a pressing of the valve body (7, 8) against the varistor element (6) via the tensioned tensile strand and the crossbars (1, 2) of the bracing takes place.