WO2012123323A1 - Electrical contact arrangement - Google Patents

Abstract

An electrical contact arrangement has a first contact piece (3, 3a) and a second contact piece (4, 4a). The two contact pieces (3, 3a, 4, 4a) are electrically conductively contact-connected to one another so as to form a contact point (5). The contact point (5) is surrounded by a shielding shroud (8, 8a). A first current path across the contact point (5) and a second current path across the shielding shroud (8, 8a) are formed between the two contact pieces (3, 3a, 4, 4a).

Description

description

The invention relates to an electrical contact arrangement having a first contact piece and a second contact piece, which are contacted to form a contact point with each other in an electrically conductive manner and with a con ^¬ contact point dielectrically shielding shield cap.

Such electrical contact assemblies are beschrie ^¬ ben for example, in Japanese Unexamined Patent Publication JP60-170174. In the local electrical contact arrangements, a first contact piece is in each case contacted with a second contact piece in an electrically conductive manner, so that a contact point is formed between the two contact pieces. To shield the con ^¬ tact provide dielectric, each is a

Umbrella hood arranged around the contact point around. A

Umbrella hood homogenizes the contour of the contact point in order to use the contact arrangement in the high voltage range can.

A contact arrangement, in the course of a conductor run is ei ^¬ ne discontinuity, which is normally equipped with an import pedanzerhöhenden contact resistance. This results in a flow of current through the contact arrangement heat. A dissipation of heat by direct radiation into the environment is hindered by the umbrella hood. Thus, on the one hand, the shielding cap is necessary in order to homogenize the outer contour of the electrical contact arrangement in order to be able to transport large amounts of energy in the high-voltage region via the electrical contact arrangement. On the other hand, the screen hood obstructs a direct emission of thermal energy from the contact point and thus limits their load capacity. Thus, there is an object to provide an electric Kontaktanord ^¬ voltage, which on the one hand has a good dielectric Fes ^¬ ACTION and secondly a high current carrying capacity on ^¬.

According to the invention this is achieved in an electrical contact arrangement of the type mentioned above in that between the first contact piece and the second contact piece, a first current path via the contact point and a second current path are formed on the screen hood.

The use of the screen hood as a current path for the transmission of electrical energy makes it possible to create current heat also immediacy bar in the shield cap. Since the Schirmhau be a homogenization of the outer contour of the electrical contact assembly, heat from the outer shield can be radiated me directly. Thus, the heat can be passed out of the electrical contact arrangement in a direct manner. The screen hood is therefore no longer a barrier to a part of the heat radiation, since in the

Umbrella hood resulting heat directly from the Schirmhaube forth in the environment can be derived. For conducting an electric current, the shield cap is made of a material which is electrically conductive. For this purpose, for example, metals such as aluminum, copper, etc. can be used. Such materials can also cause an influence of electric fields with their metallic surfaces. Thus, the screen hood can serve as a current path and on the other hand as a shielding element for influencing electric fields.

A contact arrangement according to the invention can preferably be used in compressed gas insulation of electrical energy transmission systems. Within an encapsulating housing, an insulating gas is subjected to an increased pressure relative to atmospheric pressure. The encapsulating housing takes in its In ^¬ neren phase conductor for guiding an electric current on. Part of these phase conductors are, for example, contact arrangements.

Due to the compression of the insulating gas Isolierab ^¬ states can be reduced compared to atmospheric conditions. Accordingly compact such systems can be out ^¬ leads. In compact systems high power can be transmitted via a contact arrangement according to the invention, since even with compact dimensions, large amounts of heat can be led out of the contact arrangement.

A further advantageous embodiment can provide that the first current path and the second current path are electrically pa ^¬ rallel connected.

At a contact point formed between a first and a second contact piece, an occurrence of a contact resistance that normally increases the impedance of the electrical contact arrangement occurs. Is now a elekt ^¬ driven parallel connection of a second current path to the current path, which is formed via the contact point, seen ^¬, it is clear about the shield cover, a current path that the impedance of an electrical contact arrangement according to the invention compared to an exclusively a current path via the contact point reducing electrical contact arrangement. The current heat generated in the electrical contact arrangement is reduced by a parallel connection of the first and the second current path. In addition, the current heat can be discharged directly through the current-carrying screen hood in the second current path to the environment. This reduces the heating of the electrical contact arrangement. The contact arrangement can thus carry a larger current without overheating.

A further advantageous embodiment can provide that the second current path encompasses the first current path. By gripping around the first current path, the outer contour of the electric Kontaktanord ^¬ voltage can be smoothed by means of the shield cap. This provides a possibility to form the first current path almost arbitrarily, since its outer contour is smoothed by the enclosing umbrella hood. This makes it possible, for example, to allow at the contact ^{¬ point} protruding edges, bolt heads, etc., to realize the best possible tension of the two contact pieces. The first and second current paths should preferably be arranged coaxially with each other.

Furthermore, it can be advantageously provided that the first and the second current path lead to an electric current divided into the first and the second current path.

Guiding a split current makes it possible to conduct a first partial current in the interior of the electrical contact arrangement via the first current path and a second partial current in the exterior via the second current path. In this case, it is possible to set up the impedance ratios at the first and at the second current path in such a way that, for example, a uniform distribution to the two current paths takes place, or one or the other current path is optimized with regard to its impedance and thus a comparatively greater proportion of the current leads to be split electric current.

Thus, it is for example possible to perform targeted in the outer upper ^¬ area, ie within the second current path RESIZE ^¬ ßere current components. However, it can also be provided that, for example, at an occurrence of the Skin- this effect is counteracted by a reduced An ^¬ part of the part to electric current is passed through selection of the impedance ratios in the shielding hood. In this case, the impedance of the first current path should be lower than the impedance of the second current path.

It can also be advantageously provided that the contact ^{¬ point} a rigid angle composite of first contact piece and second contact piece forms and the shield cap is movable relative to at least one of the two contact pieces, in particular to both contact pieces. The two contact pieces can be joined at the contact angle ^¬ rigidly to each other so that forces between the first contact piece and the second contact piece can be exchanged via the contact point. So it is beispielswei ^¬ se possible conclusions about the contact point thermally induced change in length to transfer and let them take example from a compensation element. In order to avoid tension in the electrical contact arrangement, the screen hood should be relatively movable ^¬ at least to one of the two contact pieces. It can be provided that the screen hood can rotate for example about an axis or is displaceable along an axis. It can be provided for example that the screen cover is connected angularly ^¬ rigid with one of the contact pieces, for example by means of a press fit or a material-locking joining process, whereas to the other contact piece a relative mobility between the contact piece and shield hood is possible. In particular, at a relative movability of the shield cover at both Kontaktstü ^¬ CKEN the contact point can be spanned by the shield cap and, for example for inspection or repair work are moved by an axial Unlike the contact point.

It can be provided that the relative mobility of the shielding hood with respect to the contact pieces is limited. For example, the use of securing means such as screws, bolts, spring washers, etc. may be provided. By the securing means unintentional release of the shield cap is prevented by the contact pieces, for example, as a result of vibration. A further advantageous embodiment may provide that a sliding contact element is arranged between at least one contact piece and the screen hood.

In order to ensure a permanent contact between the shield cap and at least one of the Kontaktstü ^¬ bridge even with relative movements, the use of a sliding contact element between the shield hood and contact piece can be provided. The sliding contact element should be elastically deformable in order to compensate for relative movements can. A sliding contact element may for example be a contact blade, a contact finger, a contact spring o. Ä., Which is inserted into a joint gap between the shield cap and one of the contact pieces. A sliding contact element can be used in ^¬ particular at the points at which a contact piece to the screen hood can perform a relative movement. Thus, it is also possible for a relative movement to occur to achieve a permanent electrically conductive connection between the shield cap and one or both of the contact pieces. It can be provided for example that the screen cover is connected win ^¬ kelstarr with one of the contact pieces, a connection to the other contact piece allows for example by means of a press ^¬ fit or a material-locking joining process, wohinge ^¬ gene relative movability between the contact piece and shield hood. However, it can also be provided that both contact pieces are movable relative to the screen hood. In this case, at least one sliding contact element is to be provided in each case between the first contact piece and the shielding hood and between the second contact piece and the shielding hood.

Furthermore, it can be advantageously provided that a recess is arranged at least in one of the contact pieces, wel ^¬ che serves a recording of fasteners to produce a composite of the two contact pieces. An introduction of recesses in at least one or both of the contact pieces makes it possible to provide receiving volumes in the contour of the contact ^{pieces in} order to be able to receive, for example, bolts or the like. For example, the recess in the manner of a groove, in particular a

Ring groove to be configured, in which, for example, the heads of mounting bolts are added.

The recesses are spanned by the umbrella hood, so that the emergence of discharge phenomena on the body edges of the recess or on the fastening means arranged within the recess is prevented.

Advantageously, it can furthermore be provided that the shielding hood is a sleeve, in particular with an outer jacket surface tapered conically at the end.

A shield hood m the form of a sleeve allows to use ^¬ example, cylindrical, in particular circular cylindrical Kon ^¬ clock pieces, which project into the sleeve so that the sleeve enclosed by a contact point stirnseiti can be formed between the contact pieces. The sle se itself shields and surrounds the contact point, wherein the sleeve is part of a second current path arranged parallel to the first current path. An end conical tapering of the outer circumferential surfaces of the sleeve gives a dielectrically güns term form, so that the front sides of the shield cap ^{¬ are} electrically disturbed. Also can recesses in the shielding hood at ^¬ play, be introduced which pass through a wall of the shielding cover completely, so can make fluid communication via the recesses with the environment at the pitch located inside the shield hood areas. Thus, recesses of the umbrella hood may open, for example, in recesses of the contact pieces, which are provided for receiving the fastening means. Thus, a flow is additionally conveyed by means of a fluid at the electrical contact arrangement, whereby the Cooling of the electrical contact arrangement is supported. The screen hood can for example have a cylindrical, in particular ^¬ circular cylindrical outer surface. It can be provided that the outer lateral surface tapers conically towards the end. It can also be provided to use a barrel-shaped curved outer circumferential surface.

A further advantageous embodiment may provide that at least one, in particular both contact pieces have an impact on ^¬ which limit movability of the shield cover.

The use of a stop on the contact pieces makes it possible to limit the mobility of the umbrella hood. So ^¬ with example, it is possible to set up a lubricious screen ^¬ hood on the contacts and those preventing them an axial movement by stops on the contacts. This only allows movement within the limit given by the stops. A Be ^¬ limitation of the movement can be provided, for example, in a coaxial direction. A stop may be formed, for example, in that a cross-sectional reduction is made at the contact pieces, so that a circumferential shoulder is drawn into the contour of the contact pieces. Thus, on the one hand, a limitation of the mobility of the canopy can be forced. On the other hand, the transition between the shield cap and contact piece can be additionally dielectrically shielded.

A further advantageous embodiment may provide that the shield cover is integrally formed.

The shielding hood can be shaped, for example, in the casting process, so that a one-piece surface is provided on the shielding hood, which serves to homogenize electromagnetic fields. In addition, it can be further provided that the shield cover is advantageously formed in several pieces.

A multi-part molding can, for example, take place such that the umbrella hood has a plurality of shells, wherein joining gaps remain between the shells. The joining gaps may have a width such that a sufficient amount of fluid ^¬ de can pass therethrough. This makes it possible in a simple manner to form recesses in the shield cap, which support a flow through the recesses for receiving fasteners in the contact pieces to achieve improved cooling of the contact arrangement. In the following an embodiment of the invention is shown in a drawing and described in more detail below.

1 shows a first embodiment variant of a Kontaktan ^¬ order, the

Figure 2 shows a second embodiment variant of a Kontaktan ^¬ order and the

3 shows a cross section through a third embodiment ^¬ variant of a contact arrangement.

The objects of Figures 1 and 2 are each intended for use in gas-insulated switchgear or gas-insulated lines, d. h., The contact arrangements shown in the two figures are arranged within a compressed gas insulation.

FIG. 1 symbolically shows an encapsulating housing 1 in FIG

Cut. The encapsulating housing 1 is tubular and has a tube axis 2. Within the encapsulation Housing 1, a first contact piece 3 and a second contact piece 4 are arranged. The two contact pieces 3, 4 are each formed rotationally symmetrical and arranged coaxially to the tube axis 2. Their axes of rotation correspond to the tube axis 2. Alternatively, a deviating position within the encapsulating be provided. ^{By way of} example, a plurality of contact arrangements within one and the same encapsulating housing 1 can also be arranged so as to be electrically insulated from each other, so that a pressurized gas therein serves to electrically insulate the contact arrangements with one another and with respect to the encapsulation housing 1.

The two contact pieces 3, 4 have a circular cross-section. The second contact piece 4 passes through an electrical insulator 10a in the form of a pot. The electrical insulator 10a and the second contact piece 4 can be fluid-tightly connected to each other ^¬ . The contact arrangement is positioned inside the encapsulating housing 1 via the electrical insulator 10a. The two contact pieces 3, 4 are aligned coaxially with one another and their end faces touch one another. Between the two end faces a contact point 5 of the electrical contact arrangement is formed. Via the contact point 5, a first current path is formed. With respect to the contact point 5, the two contact pieces 3, 4 have a mirror-symmetrical design. The two contact pieces 3, 4 have spaced apart from their end faces in each case an annular groove 6a, 6b. The annular groove 6a, 6b runs coaxially around the tube axis 2 and opens in the radial direction. Thus, 4 is formed in each case a recess in the two contact pieces 3 may be included in WEL che attachment means for clamping the two blocks Kontaktstü ^¬ 3 4. It can be provided that in the groove flanks of the contact pieces 3, 4 of the two annular grooves 6a, 6b, which face each other, aligned cross-recesses are introduced, in which threaded bolts can be inserted to the two contact pieces 3, 4 angle rigid with each other connect to. Alternatively, it can also be provided that only in one of two contact pieces 3, 4, a through hole is provided, wherein in the other of the two contact pieces 3, 4 aligned threaded blind holes are arranged so that a Verbolzung can take place directly, so that only one of the two contact pieces 3, 4 must have an annular groove 6a, 6b (see illustration of Figure 2).

Starting from the contact point 5 in the axial direction following the annular grooves 6a, 6b, further annular grooves 7a, 7b are arranged on the outer circumference of the two contact pieces 3, 4.

An umbrella hood 8 spans the contact point 5, the two annular grooves 6a, 6b and the other annular grooves 7a, 7b in the direction of the tube axis 2. The shield cap 8 is formed in the manner of a sleeve, sleeve openings are complementary in shape to the cross section of the two contact pieces 3, 4 are formed , so that the contact pieces 3, 4 can be gripped by the umbrella cover 8 flush. The outer contour of the shielding cap 8 is selected such that at least to the front ends of the shielding cap 8, a conically sloping jacket region is formed, so that at the front ends of the shielding cap 8 angled body edges are avoided. Preferably, the entire outer surface of the

Umbrella hood 8 be designed bulbous rounded.

In the shield cover 8 a plurality of through holes 9 is ^¬ arranged, which in the assembled condition, the annular grooves 6a, 6b connect to receive the fixing means to the vicinity of the contact ^¬ arrangement. As a result, the possibility ^{exists of} allowing the interior of the contact arrangement to be flooded by the insulating gas, which is located in the interior of the encapsulating ^housing .

In the other annular grooves 7a, 7b respectively elastically deformable sliding contact elements are arranged, which enables electrical contacting of the respective contact piece 3, 4 with the shield cap 8. Thus, via the screen hood 8 parallel to the first current path, a second current ^¬ path formed. As a sliding contact element, for example, contact blades, coil springs o. Ä. Can be used. In the first embodiment variant according to FIG. 1, the use of a one-piece shielding cap 8 is provided. In this case, the shielding hood 8 on one of the contact pieces 3 for mounting the first contact arrangement, recorded 4 scho ^¬ ben so that the two annular grooves 6a, 6b of the two contact pieces 3, 4 are accessible. Subsequently, a win ^¬ kelstarrer composite of the two contact pieces 3, 4 for Ausbil ^¬ tion of the contact pieces 5 are made, whereupon the

Umbrella cap 8 is moved over the contact point, so that the shield cover 8 with the sliding contact elements, which are inserted in the further annular grooves 7a, 7b in contact ^¬ sets.

FIG. 2 shows a second embodiment variant of an electrical contact arrangement, wherein the representation of an encapsulating housing was dispensed with. As in FIG. 1, a connection of the contact arrangement to an electrical insulator 10b is provided. The electrical insulator 10b has a different shape than the electrical insulator 10a shown in FIG. The electrical insulator 10b of FIG. 2 is a disk insulator which extends in a plane. In the electrical insulator 10b, an electrode 11 is inserted. By means of the electrode 11 can be transmitted, an electrical potential through the elekt ^¬ step insulator 10b therethrough. To the

Electrode 11, for example, a contact ^piece can be connected ^¬ sen.

2 shows 4a a first contact piece 3a and a contact piece two ^¬ tes. The two contact pieces 3a, 4a are formed differently from each other. The two contact pieces 3a, 4a are rotationally symmetrical body with a kreisför ^¬ shaped cross section, which is coaxial with a tube axis. 2 extends. The axes of rotation correspond to the tube axis 2. The first contact piece 3a and the second contact piece 4a face each other frontally, wherein between the end faces a contact point 5 is formed. The first contact-piece 3a is equipped with an annular groove 6c, so that fastening means are received in the annular groove 6c Kgs ^¬ NEN which serve an angularly rigid composite of the two contact portions 3a, 4a. The second contact piece 4a has an end face on a circular surface, in which through holes are introduced. The first contact piece 3a has in a flank of the annular groove 6c aligned through ^¬ bores. In the through holes of the edge of the annular groove 6 c bolts are used, which engage in the passage ^¬ holes of the second contact piece 4 a and enforce them completely. The figure 2 shows the possibility of the threaded bolt, which end in the annular groove 6c of the first contact ^¬ piece 3a to let protrude toward ^¬ into threads of the electrode 11 so that the first contact piece 3a with the interposition of the second contact piece 4a against the electrical de 11 is braced, so that a rigid-angle composite zwi ^¬ rule first contact piece 3a and second contact piece 4a is given. Alternatively it can also be provided that the second contact piece 4a has threaded holes, so that a direct clamping of the two contact pieces 3a, 4a is possible.

For receiving a shield cover 8a, the two Kon ^¬ clock pieces 3a, 4a on the sides facing each other cross-sectional reductions, so that CKEN at the two Kontaktstü- 3a, 4a, respectively, a shoulder is formed 12th The school ^¬ tern 12 are mirror-symmetrical with respect to the contact point 5 and act as a stop. As a result, a flat groove is formed in the composite of the two contact pieces 3a, 4a, in the groove bottom of which the annular groove 6c of the first contact piece 3a opens. Furthermore, further annular grooves 7c, 7d are arranged in the groove bottom of the flat annular groove, which in each case rotate around the tube axis 2 on the outer shell side. In the flat ring groove first and second contact piece 3a, 4a, a screen hood 8a is inserted. The shield cover 8a is prevented from axial BEWE ^¬ supply by the oppositely directed shoulders 12 of the two contact portions 3a, 4a. Thus, the shield may dome 8a only a rotation around the tube axis 2 vollzie ^¬ hen and limited by the shoulders 12 minimum play in the axial direction run. For electrically contacting the shielding hood 8a with the first and second contact piece 3a, 4a, sliding contact elements, for example in the form of elastically deformable contact fingers, contact blades, coil springs, etc., are inserted into the further annular grooves 7c, 7d. In this way, a second current path to the first current path formed over the contact point 5 is realized between the two contact pieces 3a, 4a via the sliding contact elements 7c, 7d and the shielding cap 8a.

Is formed can be carried 8a an embodiment of the shield cover such that the shield cover 8a for example, from half-shells is ^¬ quantitative sets together, which are placed from the radial directions between the shoulders 12 and be clamped after a completed insertion against each other, so that a sleeve-shaped shield cover 8a. It can be provided that corresponding joints between the half-shells are designed such that an entry of insulating gas is made possible in the interior of the contact arrangement and thereby a discharge of heat from the interior of the contact arrangement is conveyed.

FIG. 3 shows a further first contact piece 3b in cross-section. The further first contact piece 3b has a circular cross-section, wherein at its one further second contact piece end facing by cross-section reduction, a section is formed with a square cross-section. The square section section is shown in FIG. The other second contact piece is designed to slide ^¬ cher way. On the periphery of querschnittsre ^¬ duced each section flat bars 13 are listed screwed. The outer surface of the flat bars 13 is the rounded ^¬ art that, in cooperation with the cross-section reduced portion ^¬ a circular cross section is formed. The portions of the further first and further second contact piece 3b of square cross section are mitein ^¬ other electrically conductive contact. The flat bars 13 span over the contacting point of the further first contact piece 3b and the further second contact piece and form a parallel current path. The flat rails 13 act as a screen hood. To improve the contact resistance, elastically deformable contact ^elements can be arranged between the flat rails 13 and the further contact pieces, for example.

Claims

claims

1. Electrical contact arrangement with a first contact piece (3, 3a) and a second contact piece (4, 4a), which are contacted with the formation of a contact point (5) electrically conductively and with a contact point (5) dielectrically shielding screen hood (8, 8a)

d a d u r c h e c e n c i n e s that

between the first contact piece (3, 3a) and the second contact piece (4, 4a) a first current path via the contact point (5) and a second current path via the shield cap (8, 8a) is formed.

2. Electrical contact arrangement according to claim 1,

d a d u r c h e c e n c i n e s that

the first current path and second current path are electrically connected in pa rallel ^¬.

3. Electrical contact arrangement according to one of claims 1 or 2,

d a d u r c h e c e n c i n e s that

the second current path encompasses the first current path.

4. Electrical contact arrangement according to one of claims 1 to 3,

d a d u r c h e c e n c i n e s that

the first and the second current paths lead an electric current divided on the first and the second current path.

5. Electrical contact arrangement according to one of claims 1 to 4,

d a d u r c h e c e n c i n e s that

the contact point (5) forms a rigid connection between the first contact piece (3, 3a) and the second contact piece (4, 4a) and the shield cap (8, 8a) is relatively at least one of the two contact pieces (3, 3a, 4, 4a), in particular to ^¬ contact pieces (3, 3a, 4, 4a) is movable.

6. Electrical contact arrangement according to claim 5, characterized in that a

between at least one contact piece (3, 3a, 4, 4a) and the screen hood (8, 8a) is arranged a sliding contact element.

7. Electrical contact arrangement according to one of claims 1 to 6,

d a d u r c h e c e n c i n e s that

in at least one of the contact pieces (3, 3a, 4, 4a) an off ^¬ recess (6a, 6b, 6c, 6d) is arranged, which serves a Recordin ^¬ me of fastening means to produce a composite of the two contact pieces (3, 3a, 4, 4b).

8. Electrical contact arrangement according to one of claims 1 to 7,

d a d u r c h e c e n c i n e s that

the shielding hood (8, 8a) is a sleeve, in particular with end-side conically tapered outer circumferential surface.

9. Electrical contact arrangement according to claim 1 to 8, d a d e r c h e c e n e c i n e that t

at least one, in particular both contact pieces (3, 3a, 4, 4a) have a stop (12), which limit a mobility of the screen hood (8, 8a).

10. Electrical contact arrangement according to one of claims 1 to 9,

d a d u r c h e c e n c i n e s that

the screen hood (8, 8a) is integrally formed.

11. Electrical contact arrangement according to one of claims 1 to 9,

d a d u r c h e c e n c i n e s that

the screen hood (8, 8a) is formed in several pieces.