EP0163053A1 - Voltage surge arrester - Google Patents

Abstract

1. An arrester comprising a dissipating member (102; 202; 302) consisting of at least one metal oxide element and contained in a housing (110; 210, 310) which is structurally combined with a part of a plug-in connection which is adapted to be inserted from the outside into a corresponding part (124; 224; 324) of th plug-in connection which is provided on a bushing in the enclosure (125; 225; 325) of a switching system, and which, when the plug-in connection has been made, has the dissipating member (102; 202; 302) linked via the plug-in connection to a conductor (201) in the interior of the enclosure (125; 225; 325), characterised in that a) both the housing (110; 210; 310) of the dissipating member (102; 202; 302) which consists of zinc oxide and also that (116; 216; 316) of one part of the plug-in connection consist of metal, b) when the plug-in connection is made, the housing (116; 216; 316) of one part of the plug-in connection and via this housing that (110; 210; 310) of the dissipating member (102; 202; 302) is connected in electrically manner to the enclosure (125; 225; 325) which is at earth potential, and c) one part of the plug-in connection is provided with a connecting device (138; 243; 343) for a cable.

Description

The invention relates to a surge arrester which has the features of the preamble of claim 1.

It is known in surge arresters (DE-AS 22 47 999, DE-AS 23 34 420), the metallic housing in which the arrester body formed from spark gaps and / or zinc oxide elements is located from the outside of a metallic encapsulation of a gas-insulated switchgear to be fixed on this encapsulation and to connect the arrester body through a bushing to the conductor lying inside the encapsulation, while the arrester body, on the other hand, is connected in an electrically conductive manner to the metallic housing, which, like the encapsulation, is grounded. Such an arrangement of a surge arrester requires consideration when designing the encapsulation. At least one subsequent Anbrin- g g _un difficult. Further disadvantages can be seen in the fact that both the control of the surge arrester and any replacement that may be necessary are not readily possible.

The invention has for its object to provide a surge arrester for encapsulated systems, which can be installed without difficulty and in particular also retrospectively and allows easy control and interchangeability. This object is achieved by a surge arrester with the features of claim 1.

As a result of the implementation as one part of a plug connection, for example as a socket for a cable plug, and because of the structural union of the housing containing the arrester body with the other, corresponding part of a plug connection, the assembly and disassembly of the surge arrester is limited to plugging in or Pulling the plug-in connection part which not only establishes the mechanical connection but also the electrical connections when plugged in. The exchange is therefore easy and does not require the encapsulation to be opened. The same applies to the maintenance and inspection of the surge arrester, even if the connector part has to be pulled. Since switchgear are often provided with additional, not required for the cable connection sockets, which are closed with a dummy plug when not in use, such sockets can often be used for attaching the surge arrester. But even if there is no free socket, the encapsulation need not be provided with an additional socket, because in this case a plug can be used, which also has a connecting device for a cable, a socket for a cable connection or more than one Can have a socket, one of which can serve for a cable connection and the other for a structurally combined with the surge arrester plug. The surge arrester is therefore combined with a cable connector.

The plug connection can be designed in the usual way, i.e. either with an outer cone or with an inner cone of the plug, in order to achieve an electrically sealed closure of the plug socket, so that the electrically conductive connections with the grounded encapsulation and the one connected to the other plug connection part can be produced in a simple manner Conductor can be produced, the surge arrester according to the invention is advantageously designed according to claim 2.

The housing containing the arrester body is expediently designed according to claim 3, wherein a releasable connection to the housing of the plug-in connection part is particularly advantageous if the plug-in connection part is a cable plug. Access to the arrester body then does not require opening the housing of the connector part. Advantageous designs of the housing, the connections of the conductor body with the contact body of the plug-in connection part and its housing and an insulating tube surrounding the conductor body including its closure parts are the subject of claims 4 to 7. The insulation of the conductor body can in addition to the insulation by an insulator surrounding it at a distance with a gas, but also with other insulating materials. For example, embedding in silicone rubber is also possible.

In order to be able to fill or refill gas in the surge arrester with gas insulation in a simple manner, the features of claim 8 can be provided. In addition, an overpressure relief device with an indicator is advantageously provided on the floor.

If the plug-in connection part is also to be used to connect a cable, not only embodiments are possible in which the plug-in connection part is provided with a connection device for a cable end. Embodiments in which the plug connection part is equipped with a socket for a cable plug can also be advantageous. In both cases, the plug connection part can be designed as a straight plug or as an angled plug. Furthermore, the cup-shaped housing containing the arrester body can be arranged relative to the plug pin both according to claim 13 and according to claim 14.

In the known surge arresters, the voltage distribution over the length of the generally rod-shaped arrester body is non-uniform, that is to say the grounded jacket of the conductor between the arrester body and the grounded jacket surrounding it at a constant distance existing voltage housing does not increase linearly from the grounded end of the arrester body to the other end. In order to obtain a more favorable voltage distribution without additional aids, the distance of the jacket of the arrester housing from the arrester body is therefore not constant in a preferred embodiment, but is preferably chosen such that the voltage between the arrester body and the jacket of the housing changes linearly in the longitudinal direction of the jacket body , that is, an isodynamic stress distribution is achieved.

• Fig. 1 einen Längsschnitt eines ersten Ausführungsbeispiels im montierten Zustand,
• Fig. 2 einen Längsschnitt eines zweiten Ausführungsbeibeispiels im montierten Zustand,
• Fig. 3 einen Längsschnitt eines dritten Ausführungsbeispiels im montierten Zustand,
• Fig. 4 einen Längsschnitt eines vierten Ausführungsbeispiels im montierten Zustand,
• Fig. 5 eine teilweise in Längsrichtung geschnitten dargestellte Ansicht eines fünften Ausführungsbeispiels im montierten Zustand,
• Fig. 6 einen Längsschnitt eines sechsten Ausführungsbeispiels im montierten Zustand,
• Fig. 7 eine teilweise in Längsrichtung geschnitten dar gestellte Ansicht eines siebten Ausführungsbeispiels.

The invention is explained in detail below on the basis of exemplary embodiments shown in the drawing. Show it:

• 1 is a longitudinal section of a first embodiment in the assembled state,
• 2 shows a longitudinal section of a second exemplary embodiment in the assembled state,
• 3 shows a longitudinal section of a third exemplary embodiment in the assembled state,
• 4 shows a longitudinal section of a fourth exemplary embodiment in the assembled state,
• 5 shows a view of a fifth exemplary embodiment in the assembled state, shown partly in section in the longitudinal direction,
• 6 shows a longitudinal section of a sixth embodiment in the assembled state,
• Fig. 7 is a partially sectioned longitudinal view of a seventh embodiment.

A surge arrester to be arranged outside a metal-encapsulated switch and to be connected to a conductor 1 lying inside the encapsulation of the switch has a columnar arrester body 2 formed from a plurality of stacked zinc oxide disks and concentrically spaced apart by a por cell tube 3 surrounds. This porcelain tube 3 is firmly and gas-tightly closed at one end by means of a disc-shaped base 5 inserted into this end with the interposition of a seal 4. On the inside of the base 5, the one end face of the arrester body 2 is supported with the interposition of a contact plate 6 and a prestressed spring assembly 7. The other end face of the arrester body 2 rests on a removable, metallic cover 8 which engages over this pipe end and forms a likewise gas-tight seal with the interposition of a seal 9.

The side of the cover 8 facing away from the arrester body 2 lies against the bottom of a pot-shaped, metallic housing 10 which concentrically surrounds the porcelain tube 3 at a distance. Both the bottom of the housing 10 and the cover 8 connected to it penetrate channels of a filling valve 11 or an overpressure relief device 12 having an indicator, both of which are arranged on the outside of the bottom of the housing 10.

A connection line 13, connected on the one hand to the contact plate 6, is passed through the bottom 5 in a gastight manner, the other end of which is connected to a dome-shaped counter-contact piece 14, the recess of which is open towards the bottom 5. One end of a prestressed coil spring 15 engages in this recess, the other end of which is supported on the base 5. The space between the housing 10 and the porcelain tube 3 is filled with an insulating material. The inside of the porcelain tube 3 is filled with nitrogen, but could also be filled with silicone rubber, for example.

The housing 10 is flanged on its open side to the metallic housing 16 of a connector so that the longitudinal axis of the housing 10 and the Ableiterkor ^p ers 2 contained therein are aligned with the longitudinal axis of the connector. As shown in FIG. 1, the metallic housing 16 widens conically after the end that can be connected to the housing 10 and has a flange and then merges into a cylindrical end section. On the inside of the conical section, there is an insulating body 17 of the plug which is made of silicone rubber and which is still there the beginning of the cylindrical section is initially very tapered and then forms a conical stopper which tapers slightly towards its free end, as is customary in the case of cable plugs, in order to be able to electrically close the associated socket.

In the longitudinal axis of the insulating body 17 is a rod 19 made of electrically highly conductive material, one end of which carries a spherical cap-shaped contact piece 20, which rests with its flat contact surface on the flat contact surface of the counter-contact piece 14 and supplements this against the rod 19 to form a ball. With the other end of the rod 19, a contact sleeve 21 is fixedly connected, which carries a multi-line contact element 22, if the socket is not equipped with a radially resilient socket body. A pressure body 23 which bears on the one hand on the insulating body 17 and on the other hand on the contact sleeve has a rounded shape for reasons of field control against the insulating body.

A receptacle designated as a whole as 24, as used for cable plugs, is provided for receiving the plug described above. Since the socket forms the feedthrough through the wall 25 of the encapsulation, the cup-shaped housing 26 consisting of insulating material is inserted into an opening 27 in the wall 25. The flange provided on the open edge of the housing 26 is pressed by means of screws 28 with the interposition of a seal 29 against the outside of the wall 25, so that the opening 27 is sealed. The bottom of the cup-shaped housing 26 penetrates centrally through a connection bolt 30 which serves to connect the conductor 1 and which is mechanically firmly and electrically conductively connected to the cup-shaped socket body 31 of the socket inside the housing 26. The multi-line contact element 22 contacts this cup-shaped socket body 31, which can be dispensed with if the socket body 31 has radially resilient tongues which can contact the contact sleeve 21 with the required contact pressure.

As shown in FIG. 1, when the plug is inserted into the socket 24, the metallic housing 16 engages over the flange of the cup-shaped housing 26 together with the screws 28 and comes into contact with the outside of the wall 25. The force with which the housing 16 pressed against the wall 25 and held in abutment against it, is applied to the outside of the conical part of the housing 16 with the aid of claws 32, which each protrude from the wall 25 by means of a stud 33; arranged nuts 34 are movable against the wall 25.

If there is a surplus socket, the plug carrying the surge arrester can be inserted into this socket. To replace the arrester body 2, it is sufficient to separate the housing 10 from the housing 16 by loosening the connecting screws. Of course, you can also pull the plug out of the socket 24 and insert another plug equipped with a surge arrester into the socket or temporarily close it with a dummy plug if an electrically tight seal is required - while the arrester body is being replaced.

The plug could also be designed in the form of an angled plug. For this purpose, it would only be necessary for a section to be connected to the conical part of the housing 16, for example in the form of a pipe bend, which then has at its free end the flange to which the housing 10 is screwed. In this case, the rod 19 and the insulating body 17 would extend through the elbow-like section to the end having the flange.

The exemplary embodiment shown in FIG. 2 shows that the plug can also be a cable plug, that is to say a plug with a connection device for a cable 135, which in the exemplary embodiment is a plastic-insulated, single-core cable.

Since parts of this second exemplary embodiment are identical to those of the first exemplary embodiment, corresponding parts are identified by reference numbers that are one hundred larger. In addition, reference is made to the explanations for the first exemplary embodiment with regard to the identical parts. This applies both to the pot-shaped housing 110 with the components contained in it, in particular the arrester body 102, and to the socket 124, which engages in an opening 127 in the wall 125 of the encapsulation of a gas-insulated switch and closes this opening in a gas-tight manner.

As shown in FIG. 2, the metallic housing 116 of the plug has a T-like shape. The two parts 136 and 137 of the housing 116, which form the two arms extending in opposite directions, are designed as a tube piece with an annular flange for connection to the housing 110 or as a bell-like cap, which has an insertion opening for the wire 135 is provided. A short cylindrical section extends at right angles to these two parts 136 and 137, followed by a conically widening section and then again by a cylindrical section. This part of the housing 116 thus has the shape of the housing 16 of the first embodiment, apart from the missing flange. Therefore, as in the first exemplary embodiment, the housing 116 can overlap the flange of the cup-shaped housing 126 of the socket 124 and the screws 128 and can rest on the outside of the wall 125 of the encapsulation when the plug is fully inserted into the socket 124. In connection with the stud bolts 133 and nuts 134 arranged on them, the claws 132 lying on the outside of the conical housing section position the plug in this position and exert the required compressive force on it.

The rod 119, which, as in the exemplary embodiment according to FIG. 1, penetrates a pressure body 123 and whose end section projecting over this pressure body forms the plug pin engaging in the socket body 131 of the socket or carries a contact sleeve 121 which, if necessary, can in turn carry a multi-line contact element . The other end of the rod 119 carries a clamp body 138 of a screw clamp close the wire 135. The rod 119 can be mechanically fixed and electrically conductively connected to this clamp body 138, the longitudinal axis of which lies in the longitudinal axis of the two parts 136 and 137, or, as in the exemplary embodiment, can be formed in one piece. The clamp body 138 is provided with a blind hole which is open to part 137 of the housing 116 and lies in the longitudinal axis of the clamp body and into which the stripped end 135 'of the wire 135 is inserted. A threaded hole, in which a clamping screw 139 is guided, penetrates into the blind hole from the side opposite the rod 119. With this clamping screw 139, the end section 135 'is fixed in the clamp body 138.

The contact piece 120, which is contacted by the mating contact piece 114, is electrically conductively connected to the terminal body 138 via a connecting line 140.

The connecting line 140, like the clamp body 138 and the rod 119, is embedded up to the pressure body 123 in the insulating body 117, which lies against the inner wall of the parts 136 and 137 and over part of the length of the housing part surrounding the rod 119. In order to be able to insert the wire 135 into the terminal, the section of the insulating body 117 located in part 137 of the housing is provided with a channel which is aligned with the blind hole of the terminal body 138 and in which the insulating body 117, which, as in the exemplary embodiment, consists of silicone rubber the wire insulation is present. A field control body 141 embedded in the insulating body 117 contacts the guide surface lying between the wire insulation and the jacket.

On the threaded bore of the clamp body 138, in which the clamping screw 139 is guided, an outwardly conically widening channel is aligned in the insulating body 117, into which a correspondingly conically shaped sealing plug 142 is inserted, which here forms an electrically sealed closure. The sealing plug can be removed if access to the clamping screw 139 or, for example, the application of a test voltage to the clamp body 138 is desired.

Since the surge arrester is combined with a cable plug, no additional socket is required here. If the plug is not to be designed as an angled plug, the blind hole in the clamp body 138 could be aligned with the longitudinal axis of the rod 119. The clamping screw could then penetrate into the clamp body 138 from the side opposite the connecting line 140.

In the exemplary embodiment shown in FIG. 3, the plug which is structurally combined with the surge arrester can also be inserted into a socket which is intended for receiving a cable plug. However, the connection of the cable to the plug is not made directly, but by means of a cable plug which can be inserted into a socket designated as a whole with 243. If there is no cable connection to the conductor 201 which is to be secured by means of the surge arrester and is located in the interior of the encapsulation, then the socket 243 is closed in an electrically tight manner by means of a blind plug.

Since essential parts of this third exemplary embodiment are designed in the same way as in the first and second exemplary embodiments, corresponding parts that are two hundred or hundred larger reference numbers are used in the following.

The housing 216 of the angled plug, to which the housing 210, in which the arrester body 202 is located, is detachably connected, differs from the housing 116 of the second exemplary embodiment only in that the part which is arranged coaxially with the housing 210 but points away therefrom 237 as the part 236, to which the housing 210 is screwed, is designed as a tube piece with a flange at its free end. In the part 237 of the housing 216, the cup-shaped housing 244, made of electrically insulating material, of the socket 243 is inserted. Through the bottom of the housing 244, an angled section of the rod 219 is tightly passed in the center thereof, which forms the plug pin of the plug at its end protruding from the housing 216 or, as in the embodiment game, carries a contact sleeve 221 on which a multi-line contact element can be arranged. The angled section of the rod 219 penetrating into the housing 244 is mechanically fixed and electrically conductive to a socket body 245 of the socket 243.

With the rod 219, in the exemplary embodiment via a second, angled section, which is aligned with the other section penetrating the housing 244, the contact piece 220 which connects to the arrester body 202 is connected and is contacted by the mating contact piece 214.

As in the exemplary embodiments according to FIGS. 1 and 2, in the housing 216 of the plug there is an insulating body 217 made of an elastic material, in the exemplary embodiment silicone rubber, which not only on the parts located in the housing 216, but also on the inside of the Housing 216 abuts, with the exception of that end section which, as in the exemplary embodiments according to FIGS. 1 and 2, engages over the open end of the socket 224 which forms the passage through the wall 225 of the encapsulation.

Those parts of the exemplary embodiment according to FIG. 3 which have not been explained above are designed as in the exemplary embodiments according to FIGS. 1 and 2, so that reference can be made to the explanations given there.

It would of course be possible to arrange the socket 243 or the housing 210 containing the conductor body 202 in a different angular position with respect to the section of the rod 219 which engages in the socket 224, in particular in alignment therewith.

In the exemplary embodiment according to FIG. 4, the housing 310 containing the conductor body 302 is flanged to the metallic housing 316 of a plug, as is also the case with the exemplary embodiment according to FIG. 1. For details, reference can therefore be made to the explanations for the first exemplary embodiment. However, this connector is not immediately in a socket 324 is used, which serves as a passage through a wall 325 of an encapsulation. Rather, as shown in FIG. 4, the housing 316 of the plug to be inserted into the socket 324 is provided with two sockets 343 and 346, both of which have the same design in the exemplary embodiment, but could also have a different design. The design of these two sockets 343 and 346 corresponds to the design of the socket 243 of the third embodiment. Therefore, reference is made to the statements made regarding the socket 243.

In one of the two sockets, in the exemplary embodiment the socket 346, the plug which is structurally combined with the housing 316 is inserted. A cable plug can be inserted into the other socket 343. The embodiment according to FIG. 4 can thus be used like that according to FIG. 3 if there is no free socket in the wall of the encapsulation. Therefore it is different from the embodiment shown in Figure 3 essentially only by the other type of connection between the arrester body and in the as ^-. Implementation serving receptacle 324 insertable plug. For further details, reference is therefore made to the explanations regarding the exemplary embodiment according to FIG. 3.

Of course, it would be possible to choose a different shape, for example a T-shape, instead of the Y-shape of the plug insertable into the socket 324 and its two sockets 343 and 346.

The embodiment of the high-voltage arrester according to the invention shown in FIG. 5 differs from that according to FIG. 1 only by a different design of the plug with which the surge arrester is structurally combined. With regard to the surge arrester, reference is therefore made to the explanations regarding the first exemplary embodiment.

The metallic housing 410, in which the arrester body 402 is located, is detachable and electrically conductive with the metallic Housing 416 of the connector connected. This housing 416 has a cylindrical shape, the edge zone facing away from the housing 410 being widened in order to be able to overlap a flange 450 of a socket designated 424 as a whole. However, the shape of the housing 416 largely depends on the shape of the socket 424. The housing 416 can therefore also have a different shape, for example a shape as in the exemplary embodiment according to FIG. The essential difference of the embodiment according to FIG. 5 compared to that according to FIG. 1 is therefore that the insulating body 417 of the plug does not form an outer cone, but rather an inner cone, so that the plug pin 421 projects into a cavity that widens conically towards the open end.

In the case of such plugs with an inner cone, as shown in FIG. 5, the socket 431 receiving the plug pin 421 is recessed in an insulating body 426, which forms an outer cone which is matched to the inner cone of the insulating body 417 and can thereby close the plug connection in an electrically tight manner to the outside.

As in the exemplary embodiment according to FIG. 1, the socket 424 forms a passage through the wall 425 of an encapsulation, within which the conductor is located, to which the conductor body 402 is to be connected in an electrically conductive manner. The arrester body 402 is grounded via the metallic housings 410 and 416 and the wall 425 which is at ground potential.

Of course, the exemplary embodiments according to FIGS. 2 to 4 could also be equipped with this so-called outer cone system, in which the plug pin projects into a conical cavity in its insulating body, because the surge arrester according to the invention can be adapted to all plug-in connection systems.

Another embodiment with the inner cone of its connector is shown in FIG. 6. Here, the insulating body 517 and the plug pin 521 of the plug which is structurally combined with the surge arrester are in the metallic housing 510 of the surge arrester integrated. The insulating body 517 even protrudes a little into the insulating tube 503 made of ceramic material, which surrounds the conductor body 502 at a distance. The insulating body 5 ₁₇ closes one end of the insulating tube 503, the other end of which is closed by means of a metallic cover 508 which contacts the one end of the conductor body 502. The other end of the conductor body 502 is contacted by a conductor rod 519 which penetrates the insulating body 517 centrally, the other end portion of which projects into a cavity delimited by the insulating body 517, which widens conically towards the open end. The end section of the conductor rod 519 protruding into this cavity or a contact piece arranged on it forms the plug pin of the plug structurally combined with the surge arrester.

At its open end, the metallic housing 510 is provided with a flange which can be screwed onto a flange ring 550 of a socket 524. The flange ring 550 of a bushing 524 which forms a feedthrough through the wall 525 of an encapsulation is firmly and tightly connected to the wall 525 in an electrically conductive manner. The plug socket 524 has a socket body 531 which receives the plug pin 521 and which contains a conical insulating body of the plug socket 524, which protrudes outward beyond the ring flange 550, so that it is safe to touch.

In the exemplary embodiments described so far, the metallic housing surrounding the arrester body at a distance has a circular cylindrical cross-sectional shape. The consequence of this housing shape is that the voltage acting between the arrester body and the metallic housing does not increase linearly from the grounded end of the arrester body towards the other end. A linear increase in voltage, that is to say an isodynamic voltage distribution over the length of the arrester body, is obtained in the exemplary embodiment according to FIG. 7, which differs from the exemplary embodiment according to FIG. 5 only by a different shape of the metallic housing 610, in which the arrester body 602 is arranged within the tubular insulator 603. As Fig. 7 shows, takes the distance of the wall of the metallic housing 610 from the conductor body 602, starting from the bottom of the housing 610, via which one end of the conductor body 602 is grounded, initially according to a parabola or parabolic function. In the subsequent section, the increase is disproportionate, so that overall a bell-like shape results.

An isodynamic voltage distribution through a correspondingly shaped, metallic housing of the surge arrester can of course also be realized in other embodiments, in particular also in the previously described embodiments.

In all of the exemplary embodiments, if the electrical connection to the wall of the encapsulation via the housing of the plug should not be sufficient, a connection for a connecting conductor can be provided on the plug housing or on the housing containing the arrester body, which connection can be connected to a component at ground potential is.

All of the features mentioned in the above description and also the features that can only be inferred from the drawing are further refinements of the invention, even if they are not particularly emphasized and are not mentioned in the claims.

Claims (17)

1. U erspannungsableiter _b with an _OX of at least one zinc idelement existing arrester body in a housing to be arranged outside the enclosure of the switchgear and on the encapsulation forming wall is at least indirectly to fasten, said arrester body one hand to the wall and on the other hand a bushing in the wall of the encapsulation is to be connected to a conductor inside the encapsulation, characterized in that the housing (10; 110; 210; 310; 410; 510; 610) is structurally combined with one part of a plug-in connection which can be plugged into a corresponding part (24; 124; 224; 324; 424; 524) of such a plug connection provided on the leadthrough, and that when the plug is inserted, the arrester body (2; 102; 202; 302; 402; 502; 602) is connected via its housing (10; 110; 210; 310; 410; 510; 610) to the wall (25; 125; 225; 325; 425; 525) of the encapsulation and via the plug connection to the conductor inside the encapsulation. _2nd Ü _b erspannungsleiter according to claim 1, characterized in that the structurally connected to the housing (10; 110; 210; 310; 410; 510; 610) of the Ableiterkörpers united part of the plug connection a metallic housing (16; 116; 216; 316; 510 ), which can be electrically conductively connected to the wall of the encapsulation, and that the arrester body (2; 102; 202; 302; 402; 502; ₆₀ 2) is electrically conductively connected on the one hand to the housing of the plug connection part and on the other hand to the contact body of the plug connection part is, wherein in the inserted state of the plug connector its contact body (21; 121; 221; 421; 521) contacts a mating contact of the plug connector provided on the bushing, which is in electrically conductive connection with the conductor inside the encapsulation. 3. Surge arrester according to claim 1 or 2, characterized in that the housing (10; 110; 210; 310) containing the arrester body (2; 102; 202; 302) is made of metal and by part of the housing (16; 116; 216; 316) of the connector part or is connected to it, preferably detachably. 4. Surge arrester according to claim 3, characterized by a releasable connection in the cable between the arrester body (2; 102; 202; 302) and the contact body (21) of the connector part, which one of an insulating body (17; -117; 217) of Plug connector part fixed contact piece (20) and a spring contact to this mating contact piece (14), which is in constant connection with the conductor body (2; 102; 202; 302). 5. Surge arrester according to one of claims 1 to 4, characterized in that its housing (10; 110; 210; 310) has the shape of a pot which is open towards the housing (16; 116; 216; 316) of the connector part and is detachably connected to a nozzle-like part of the housing of the plug connection part. 6. Surge arrester according to claim 5, characterized by an insulating tube (3) surrounding the arrester body (2; 102; 202; 302) at a distance, which is closed at one end by means of a metallic cover (8), on the inside of which the arrester body ( 2; 102; 202; 306) is supported in an electrically conductive manner and the outside of which is fixed in an electrically conductive manner on the inside of the bottom of the pot-shaped housing (10). 7. Surge arrester according to claim 6, characterized in that the other end of the insulating tube (3) is closed gas-tight by means of a second cover (5) on which one end of a prestressed spring (15) is supported, which with its other end Counter contact piece (14) presses against the contact piece (20). 8. Surge arrester according to one of claims 5 to 7, characterized by a filling valve (11) inserted into the bottom of the pot-shaped housing (10; 110; 210; 310) and the cover (8) resting against this bottom. 9. surge arrester according to one of claims 5 to 8, characterized by an in the bottom of the pot-shaped housing (10; 110; 210; 310) and the cover (8) attached to it overpressure relief device (12) with indicator. 10. Surge arrester according to one of claims 1 to 9, characterized in that the plug connection part is designed as a cable plug with a connecting device (138, 139) for a cable (135). 11. Surge arrester according to one of claims 1 to 9, characterized in that the plug connection part has a socket (243) for receiving a cable connector. 12. Surge arrester according to one of claims 1 to 11, characterized in that the plug connection part is designed as an angled plug. 13. Surge arrester according to one of claims 5 to 12, characterized in that the longitudinal axis of the pot-shaped housing (10; 110; 210) is arranged at right angles to the longitudinal axis of the plug pin (19,21; 119,121; 219,221). 14. Surge arrester according to one of claims 5 to 12, characterized in that the longitudinal axis of the cup-shaped housing (10) is arranged coaxially or parallel to the plug pin (19, 21). 15. Surge arrester according to one of claims 1 to 9, characterized in that the plug (316), which can be inserted into the bushing (324) forming the bushing, two sockets (343, 346) for receiving a cable plug or structurally with the housing (310) of the arrester body (302) merged plug (316). 16. Surge arrester according to one of claims 1 to 15, characterized in that the jacket of the rod-shaped arrester body (602) containing the metallic housing (610) surrounds the arrester body at a distance from the area of the end of the arrester body to be connected to the encapsulation (602) increases towards the other end. 17. Surge arrester according to claim 16, characterized in that the distance of the jacket of the metallic housing (610) from the arrester body (602) is selected in accordance with an isodynamic voltage distribution.

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