NL194415C - High voltage switch device. - Google Patents

Description

1 194415

High voltage switch in direction

The invention relates to a high-voltage switching device, in particular a rotary isolating switch with two current path halves, with at least two contact fingers which form part of the first current path half and form substantially parallel and with a contact finger at the end of the second current path half. mounted contact piece in the closed state touched by the contact fingers, the longitudinal axis of the contact piece being perpendicular to the plane traversed during the opening movement of the two flow path halves and the contact piece having a circular cross-section.

Such a high-voltage switching device is known from the German "Gebrauchsmuster" 8,915,586. With this device the current path halves are rotated in a plane until they form substantially a straight line and the contact piece is received between the contact fingers. The contact fingers are pressed apart but there is virtually no relative movement between the contact elements.

Hereby only a relatively low contact pressure can be obtained and only a single contact point will be present, as a result of which the current carrying capacity of the switching device will be limited.

The invention now has for its object to obviate these drawbacks and to that end provides that the contact piece has at least one depression which runs around its circular cross-section.

This embodiment ensures that the ideal progression of the contact pressure up to the end position of the switching device is guaranteed. This means that the maximum contact pressure is only achieved at the full insertion depth. As a result, the wear of both the contact fingers and the contact piece 20 is considerably reduced. At the same time, the contact piece with one of the contact fingers always has two contact points, thereby doubling the current carrying capacity of the switching device.

In particular, said circumferential depression will have a wedge-shaped cross-section, wherein the flanks of the depression in the area of the contact points with the contact fingers make an angle of at least 30 ° and at most 85 ° with the longitudinal axis of the contact piece. The said angle will preferably be at least 45 °. The contact pressure will hereby be increased above the spreading force.

It can be provided here that the angle between the wedge flanks of the depressions and the longitudinal axis of the contact piece is greater in the area of the contact locations than in the vicinity of the edge. The angle will preferably be greater than 15 ° and smaller than 50e in the vicinity of the edge.

This ensures that the contact fingers are reliably absorbed by the depression.

The contact points between the contact fingers and the contact piece will preferably be at the edge of the depression.

It can be provided that the contact piece has several depressions, which in each case correspond with two contact fingers and which extend along its circular cross-section. This allows the current-carrying capacity of the switching device to be increased.

According to an embodiment of the invention, the contact piece may have a bore perpendicular to its longitudinal axis. The contact piece can thereby be connected by press fit to the end of the second flow path half projecting into the bore. The second flow path half can be substantially tubular. The contact piece can in this case be connected to the second flow path half by a transverse wood, which is fixed by an axially directed bolt passing through a bore which runs perpendicular to the longitudinal axis of the contact piece.

According to an embodiment of the invention, the contact piece can be rotatably mounted about its longitudinal axis on the second flow path half. This ensures that when the contact areas of the contact piece wear out, this can be turned slightly so that new contact points are created.

The contact piece can herein have a bore running along the longitudinal axis of the contact piece. The contact piece can then be connected to the end of the second flow path half through a connecting bolt arranged in a bore, running in the direction of the longitudinal axis of the contact piece.

In particular, the contact piece can be of two or more parts. Thereby, the contact piece 50 can be divided within the depression, or between two depressions. The parts of the contact piece will then preferably have substantially the same shape. In such an embodiment, an insulating intermediate layer can be provided between the parts of the contact piece. Due to the same shape of the contact piece parts, a symmetrical course of the current and thereby an optimum current lining can be guaranteed.

To further increase the contact surface, in each case two contact piece parts of the contact piece having a depression can be arranged on opposite sides of the second flow path half.

194415 2

According to an embodiment of the invention, the contact piece can be clamped on both sides at the end of the second flow path half. This clamping can take place via two hand-shaped holders arranged at the end of the second flow path half. These holders can be welded to the second flow path half but also screwed to it.

There is also the possibility of tripping the contact piece at the end of the second flow path half. When the hand-shaped holders are used, a middle body may be present between them.

It is also to be noted that German Patent No. 555,956, in which two contact points are present between a contact finger and the contact piece. In this case, however, the two contact points are realized at the expense of the favorable course of the contact force, while the contact pressure is only achieved in the end position.

Furthermore, the German "Offenlegungsschrift" 2,149,132 and the German Offenlegungsschrift 2,619,205 show rotary conductor switches in which the first current path half has a large number of contact fingers, while the contact piece is very heavy. In the first case, the contact piece is formed by a sphere provided with a cylindrical bore and in the second case by a frame, which comprises a carrier and is of substantially star-shaped design. The solid sphere was considered necessary to keep the heating in the area of the contact points as low as possible, to ensure a short high current carrying capacity and to be able to realize a sufficient current cross section. In the second embodiment, the transition cross-section is limited, while the flow path halves, viewed in side view, may not be offset relative to each other. This would cause two of the contact fingers to be lifted and the current-carrying capacity of the switching device to be reduced.

20

In the following, the switching device according to the invention, and in this case a rotary isolating switch, is explained on the basis of a drawing illustrating only exemplary embodiments. Figure 1 shows a side view of a rotary switch in the closed state, without piece insulators and without drive; figure 2 shows a top view of the subject according to figure 1; Figure 3 is a side view of the contact area of a first embodiment of a rotary switch according to the invention without the preceding contact finger; Figure 4 shows a front view - from the direction of the second flow path half - of the contact fingers and of the contact piece of a first embodiment of a rotary switch according to the invention in the closed state; Figure 5 is a side view of the contact piece of the rotary switch according to Figure 4; figure 6 shows a front view - from the direction of the second flow path half - of the contact fingers and of the contact piece of a second embodiment of a rotary switch according to the invention in the closed state; Figure 7 shows a front view - from the direction of the second flow path half - of the contact fingers and of the contact piece of a third embodiment of a rotary switch according to the invention in the closed state; Figure 8 is a front view - from the direction of the second flow path half - of the contact fingers and 40 of the contact piece of a fourth embodiment of a rotary switch according to the invention in the closed state; Figure 9 is a side view of the contact area of a fifth embodiment of a rotary switch according to the invention in the closed state; Fig. 10 is a side view of the end of the second flow path half of a sixth embodiment 45 of an open position rotary switch according to the invention; Fig. 11 is a side view of the contact area of a seventh embodiment of a rotary switch according to the invention in the closed state; Figure 12 is a side view of the contact area of an eighth embodiment of a rotary switch according to the invention in the closed state; Fig. 13 is a side view of the contact area of a ninth embodiment of a rotary switch according to the invention in the closed state; and Figure 14 is a side view of the contact area of a tenth embodiment of a rotary switch according to the invention in the closed state. 1

Figure 1 shows a side view of a rotary switch 1 in the closed state; Not shown here are - and in all other figures - piece insulators, the drive and the basic chassis. In figure 2 the rotary switch 1 according to figure 1 is shown in top view. The rotary diverter switch 3 194415 1 has two current path halves 2, 3, at least two contact fingers 4, 5 forming essentially parallel and forming a part of the first current path half 2 and one arranged in the closed state by the end of the second current path half 3. contact fingers 4, 5 touched contact piece 6. Figure 3 clearly shows that the longitudinal axis of the contact piece 6 runs perpendicular to the opening surface tensioned by the opening movement of the two flow path halves 2, 3. In combination with Figure 4, it can be seen that the contact piece 6 has a circular cross-section.

The measure according to the invention can clearly be seen from figures 3 and 4, namely that the contact piece 6 has a recessed recess along its circular cross-section. In figure 4 it is furthermore clear that two contact points 10 exist between the contact piece 6 and in each case one of the contact fingers 4,5, which guarantee an increased current carrying capacity.

From the side view of the contact piece 6 shown in Figure 5, it is clear that the circumferential depression of the contact piece 6 has a wedge-shaped cross-section. The angle α between the wedge flanks of the depression in the area of the contact points with the contact fingers not shown in Figure 5 and the longitudinal axis of the contact piece 6 should be at least 30 ° and at most 85 °. It is particularly advantageous if the angle α between the wedge flanks of the depression in the area of the contact points with the contact fingers not shown in Figure 5 and the longitudinal axis of the contact piece 6 reaches a value of at least 45 °. With a value for α of more than 45 °, the contact force is increased beyond the opening force and, consequently, the contact pressure is advantageously increased.

With particular advantage, the contact piece 6 according to the invention, as shown in Figure 6, is implemented by the fact that the angle α between the wedge flanks of the depression and the longitudinal axis of the contact piece 6 in the area of the contact locations is greater than the angle B in the vicinity of the edge of the contact piece 6. This ensures that the contact fingers 4, 5 are reliably absorbed by the depression and at the same time a reinforcement of the spreading force is guaranteed, without the contact piece 6 having too large a diameter. The angle B between the wedge flanks of the depression and the longitudinal axis of the contact piece 6 in the vicinity of the edge is preferably greater than 15 ° and less than 50 °. The transition from corner B in the area of the edge to the corner α in the area of the contact locations can, as shown in Fig. 6, be stepped, but advantageously also stepless. A value of up to 85 ° for the angle α can be useful for the outlined angle of the angles. As a result of the described design of the contact piece 6 of the rotary disconnect switch, a high degree of self-adjustment is obtained which prevents the contact fingers 4, 5 from being lifted when the transverse path 2, 3 is caused and the offset of the current path halves caused thereby.

Figure 7 shows a third embodiment of the contact piece 6, wherein due to the fact that the contact points between the contact fingers 4, 5 and the contact piece 6 are located on the edge of the depression, a particularly small contact area and thus a high contact pressure is guaranteed. .

The rotary diverter switch according to the invention is particularly advantageously further developed by the fact that the contact piece 6, as shown in Fig. 8, has several depressions, each corresponding with two contact fingers 4, 5 and running along its circular cross-section.

Both the contact piece 6 shown in Figure 8 and the contact piece 6 shown in Figure 9 have a bore extending perpendicular to their longitudinal axis. In the case of the contact piece 6 shown in Figure 8, the connection to the second flow path half is effected by the fact that the contact piece 6 is connected by press fit to the end of the second bore extending perpendicularly to the longitudinal axis of the contact piece 6 current section half 3.

An alternative attachment of the contact piece 6 to the second flow path half 3 is shown in figure 9. In figure 9 the second flow path half 3 is of tubular design. Here, the contact piece 6 is connected to the second flow path half 3 via a transverse wood 7 connected to an axial bolt 8 which is located perpendicular to the longitudinal axis of the contact piece 6 and which lies in the second flow path half 3.

In this embodiment, the transverse wood 7 can advantageously serve simultaneously as a locking bolt of a catch hook system.

The contact piece 6 is particularly advantageous due to the fact that it is rotatable about its longitudinal axis 50 on the second flow path half 3. This ensures that when the contact areas of the contact piece 6 wear out, rotation of the contact piece is carried out with little effort. contact piece 6 provides the contact fingers 4, 5 new contact points. Contact pieces 6 designed in this way are shown in the further figures. The different embodiments of the contact pieces 6 have in common that they have a bore running along the longitudinal axis of the contact piece 6. As shown in Figs. 10, 55, the connection of the contact piece 6 to the end of the second flow path half 3 takes place via a connecting bolt 9 arranged in the bore along the longitudinal axis of the contact piece 6. The connecting bolt 9 is advantageously designed as a screw bolt, so that turning the contact piece 6 after loosening

Claims (27)

194415 4 of the connecting bolt 9 can take place without problems and at the same time a high current-carrying capacity is guaranteed with a tightened connecting bolt 9. A further favorable embodiment experiences the contact piece 6 by the fact that, as shown in figure 10 and in the following figures, it is of two or more parts. Due to the fact that the contact piece 6 is of multi-part design, an optimum current flow can be guaranteed. The contact piece 6 can be shared either within the depression or between two depressions. In both cases, the parts of the contact piece 6 advantageously have substantially the same shape, since such a symmetrical flow is guaranteed. To further optimize the flow, a two-part contact piece 6 can be interrupted by an insulating intermediate layer; this will be further described with reference to an exemplary embodiment. Figure 11 shows an embodiment of a rotary switch according to the invention in the closed state, wherein the contact piece 6 consists of two contact piece parts 11,12 each provided with a depression. In the embodiment shown, the end of the second flow path half 3 is formed by a flat segment 10 of the tubular second flow path half 3. In the embodiment shown in Figure 11, the contact piece 6 is divided between two depressions and the parts of the contact piece 6 are on opposite sides of the flat segment 10 of the second flow path half 3 attached to the second flow path half 3 by means of the connecting bolt 9. This embodiment shown in Fig. 11 has the advantage that it is particularly simple to realize in terms of production. A high-voltage switching device, in particular a rotary conductor switch, with two current path-45 halves, with at least two, substantially. contact fingers arranged parallel to a part of the first flow path half and having a contact piece arranged at the end of the second flow path half, in contact with the contact fingers in the closed state, the longitudinal axis of the contact piece running perpendicularly to the opening movement of the two flow path halves and the contact piece has a circular cross-section, characterized in that the contact piece (6) has at least one depression that runs around its 50 circular cross-section. High-voltage switchgear according to claim 1, characterized in that the circumferential recess has a wedge-shaped cross-section. High-voltage switchgear according to claim 2, characterized in that the wedge flanks of the depressions in the area of the contact points with the contact fingers (4, 5) make an angle of at least 30 ° 55 and at most 85 ° with the longitudinal axis of the contact piece (6). High-voltage switching device according to claim 3, characterized in that the wedge flanks of the depressions in the area of the contact points with the contact fingers (4, 5) preferably make an angle of at least 194415 at least 45 ° with the longitudinal axis of the contact piece ( 6). High-voltage switchgear according to one of claims 2 to 4, characterized in that the angle between the wedge flanks of the depressions and the longitudinal axis of the contact piece (6) is greater in the area of the contact plates than in the vicinity of the edge. High-voltage switching device according to claim 5, characterized in that the angle between the wedge flanks of the depressions and the longitudinal axis of the contact piece (6) in the vicinity of the edge is greater than 15 ° and less than 50 °. High-voltage switchgear according to one of claims 1 to 6, characterized in that the contact positions between the contact fingers (4, 5) and the contact piece (6) are located on the edge of the depression. 10 High-voltage switchgear according to one of Claims 1 to 7, characterized in that the contact piece (6) has several depressions, corresponding in each case with two contact fingers (4, 5), running around its circular cross-section. High-voltage switching device according to one of claims 1 to 8, characterized in that the contact piece (6) has a bore perpendicular to its longitudinal axis. High-voltage switchgear according to claim 9, characterized in that the contact piece (6) is connected by press fit to the end of the second current path half (3) projecting into the bore perpendicular to the longitudinal axis of the contact piece (6). High-voltage switch device according to claim 9, characterized in that the second current path half (3) is essentially tubular. High-voltage switching device according to claim 11, characterized in that the contact piece (6) is connected to the second current path half (3) via a transverse wood (7) connected to a transverse wood (7) lying in the second current path half (3), bore-engaging axial bolt (8) standing along the longitudinal axis of the contact piece (6). 13. High-voltage switching device as claimed in any of the claims 1 to 8, characterized in that the contact piece (6) is rotatably arranged about its longitudinal axis on the second current path half (3). High-voltage switching device according to claim 13, characterized in that the contact piece (6) has a bore running along the longitudinal axis of the contact piece (6). 15. High-voltage switching device as claimed in claim 14, characterized in that the contact piece (6) is connected to the end of the second current path half (3) via a connection bolt (9) arranged in the bore along the longitudinal axis of the contact piece (6). . High-voltage switching device according to one of claims 1 to 15, characterized in that the contact piece (6) is of two or more parts. High-voltage switchgear according to claim 16, characterized in that the contact piece (6) is divided within the depression. High-voltage switching device according to claim 16 or 17, characterized in that the contact piece (6) is divided between two depressions. High-voltage switching device according to one of claims 16 to 18, characterized in that the parts of the contact piece (6) have substantially the same shape. High-voltage switching device according to one of claims 16 to 19, characterized in that the contact piece (6) is interrupted by an insulating intermediate layer. The side view of the contact area of a further embodiment of a rotary switch according to the invention shown in Figure 12 is characterized in that the contact piece 6 is clamped on both sides at the end of the second flow path half 3. This measure guarantees an increased current-carrying capacity as opposed to the attachment to a point of the second flow path half 3. In the embodiment shown in Figure 12, the two-sided clamping takes place via two hand-shaped holders 13, 14 arranged on the end 25 of the second flow path half 3. The contact piece parts 11, 12 of the contact piece 6 are arranged between the two hand-held holders 13, 14, between which there is an insulating intermediate layer 15, which ensures a suitable current flow. A further increase in the current carrying capacity is ensured by the fact that the contact piece 6 is clamped three-fold at the end of the second current path half 3; such an embodiment is shown in figure 13. To that end, a middle body 16 is provided between the hand-shaped holders 13, 14. As can be seen in Figure 13, in the illustrated embodiment, the contact piece 6 is divided between two depressions into two contact piece parts 11,12. A further improvement of the current flow can be achieved in the present embodiment by the fact that the contact piece parts 11, 12 of the contact piece 6 are divided within the depression. In the embodiment shown in Figures 12 and 13, the hand-shaped holders 13, 14 are welded to the otherwise tubular second flow path half 3. Figure 14 shows an embodiment in which the connection of the hand-shaped holders 13, 14 to the otherwise tubular second flow path half 3 is effected via a screw connection, here via two screw bolts 17, 18 and two nuts 19, 20. 40 High-voltage switchgear according to one of claims 16 to 20, characterized in that two contact piece parts (11, 12) of the contact piece (6) each are arranged on opposite sides of the second current path half (3). High-voltage switching device according to one of claims 1 to 21, characterized in that the contact piece (6) is clamped on both sides at the end of the second current path half (3). High-voltage switching device according to claim 22, characterized in that the two-sided clamping takes place via two hand-shaped holders (13.14) arranged at the end of the second current path half (3). High-voltage switch device according to claim 23, characterized in that the hand-shaped holders 50 (13, 14) are welded to the second current path half (3). High-voltage switch device according to claim 23, characterized in that the hand-shaped holders (13.14) are screwed to the second current path half (3). High-voltage switchgear according to one of claims 1 to 21, characterized in that the contact piece (6) is clamped three-fold at the end of the second current path half (3). High-voltage switching device according to one of claims 23 to 25 and according to claim 26, characterized in that a middle body (16) is provided between the hand-shaped holders (13, 14). Hereby 8 sheets of drawing