DE3514184A1 - High-voltage switch with a switching-on resistor - Google Patents

Abstract

The high-voltage switch with a switching-on resistor has a main switching point and, parallel thereto, an auxiliary switching point, the switching-on resistor (19) being connected in series with the auxiliary switching point. A moving contact (17) of the auxiliary switching point is driven via a thrust-crank drive (16) such that it closes before the main switching point and opens again after closing of the main switching point. In the case of this high-voltage switch, it is intended to achieve a movement sequence which can be matched in a simple manner to different network conditions, while saving components in the drive. This is achieved in that the thrust-crank drive (16) has a joint (23) which can be pressed through, and in that the moving contact (17) is coupled to two stop rings (34, 35) which interact with two stops (36, 37). When the auxiliary switching point is already switched on, the first stop ring (34) strikes on the first stop (36), and the joint (23) which can be pressed through is moved from a first stable position, via a dead point, into a second stable position. At the same time, the moving contact (17) moves somewhat in the switching-off direction and opens the auxiliary switching point. <IMAGE>

Description

High-voltage switch with on-resistance

The present invention relates to a high voltage switch with Switch-on resistance according to the preamble of claim 1.

The published patent application DE 31 32 821 already discloses a high-voltage switch known, in which parallel to a main switching point the series connection of a Secondary switching point with a switch-on resistor.

The main switching point is controlled by a lever mechanism assigned to it operated, while another lever mechanism on a movable contact of the secondary switching point works. The lever mechanism assigned to the secondary switching point is designed in such a way that that the secondary switching point always closes before the main switching point when switched on and then opens again after closing the main switching point.

In order to achieve this sequence of movements of the secondary switching point a large number in the associated lever mechanism of parts necessary, which may only have small manufacturing tolerances, since this is the only way to jam the lever mechanism can be excluded. Such precisely manufactured parts are expensive.

The invention aims to provide a remedy here. The invention as it is in the claims is characterized solves the problem with a generic High-voltage switch to achieve a sequence of movements, which results in savings components of the drive in a simple manner to different network conditions can be adjusted.

The advantages achieved by the invention are essentially therein to see that more simply trained and therefore more economical drive parts can be used. The manufacturing tolerances that are always possible do not fall here weight. Furthermore, it is easily possible to change only part of the Modify the sequence of movements of the auxiliary switch point, so that the high-voltage switch can be adapted in this way to different network conditions.

The further refinements of the invention are the subject of the dependent Expectations.

In the following, the invention is illustrated by means of only one embodiment Illustrative drawings explained in more detail.

It shows: FIG. 1 a schematic representation of the drive for a Main and a secondary switching point, Fig. 2 is a section through the Drive area of the auxiliary switching point in the definitely switched off state, drive elements the main switching point are shown in dashed lines, FIG. 3 is a greatly simplified one Section through the drive area of the auxiliary switching point, showing the moving contact the secondary switching point is switched on, FIG. 4 shows a greatly simplified section through the drive area of the auxiliary switching point when the high-voltage switch is definitely switched on, 5 shows a greatly simplified section through the drive area of the auxiliary switching point at the moment in which their movable contact is maximally open, Fig. 6 a Section through a spring element and FIG. 7 a section through an example Friction spring assembly.

In all figures, parts that have the same effect are given the same reference numerals Mistake.

In Figure 1, a drive 1 moves over a through an isolator column 2 passed through insulating drive rod 3 and via a lever arrangement 4 a Wave 5.

The shaft 5 is only hinted at, conductive Deflection housing 6 supported, which is supported on the insulator column 2. One on the rotary lever 7 non-positively attached to the shaft 5 acts via a first slider crank drive 8 on a movable con- clock 9 of a main switching point 10. The movable contact 9 cooperates with a fixed contact 11, which is connected to a power connector 12. A non-positively attached to the shaft 5 Lever 15 moves a movable contact via a second slider crank drive 16 17 of a secondary switching point 18. The secondary switching point 18 is electrically in series switched with a switch-on resistor 19s and this series circuit is in parallel to the main switching point 10. A flexible, conductive connection 20 between the power connection 12 and a fixed contact 21 of the secondary switch point 18 provides a parallel connection while the other parallel connection is formed by the deflection housing 6.

The main switching point 10 and the series connection of the secondary switching point 18 and switch-on resistor 19 are surrounded by insulating housings (not shown).

Figure 2 shows the drive area of the secondary switch point 18 at definite switched off high-voltage switch.

The lever 15 forms a push-through lever with a hinged lever 22 Joint 23. The end of the lever 22 facing away from the lever 15 comprises a joint pin 24 and is connected via this to a first holder 25 of a spring element 26. A second holder 27 of the spring element 26 is adjacent to one on the lever 15 to the shaft 5 arranged pivot point 28 connected.

Furthermore, one end of a connecting rod is on the hinge pin 24 29 articulated, the other end of which is articulated to a guide piece 30. This guide piece 30 slides in one with the deflection housing 6 over ribs 31 connected cylindrical sleeve 32 and is rigid with one end of a rod made of or tubular insulating material manufactured actuating rod 33 connected. That the other end of the actuating rod 33 penetrates the perforated disks of the switch-on resistance 19 and is connected to the movable contact 17 of the auxiliary switching point 18.

A first impact ring 34 is firmly seated on the actuating rod 33, which is also supported on the guide piece 30. A second serve ring 35 is also rigidly attached to the actuating rod 33.

In the area between the impact rings 34, 35 surround two stops 36, 37 the actuating rod 33 concentrically. The two stops 36, 37 support on opposite sides on a common, they in the axial direction cushioning spring package 38 which can be acted upon on both sides and are together with this carried by a bracket 39. The holder 39 is rigid in the sleeve 32 attached.

A section through the spring element 26 is shown in FIG. Each of the two brackets 25, 27 has an eyelet 45 for attachment and takes one end of a train spring 46, which the two brackets 25, 27 in the axial Direction applied. Die'Halterung 25 partially includes the holder 27 and leads the tension spring 46. The holder 27 carries a damping device 47, which by means of a retaining screw 48 is attached. The retaining screw 48 holds a damper washer 49 so that it can slide in the axial direction along the shaft 48a of the same. The damper disk 49 is supported on the one hand by a shoulder 50 of the holder 25 the spring force of the tension spring 46 is applied and on the other hand it is supported a spring assembly 51 and presses it against a shoulder 52 of the holder 27.

In Figure 7, a cylindrically constructed friction spring assembly is schematically shown, for example, in the arrangements according to Figure 2 (spring package 38) and Figure 6 (spring assembly 51) between force-transmitting parts, such as the two stops 36, 37 can be installed. The friction spring package consists of outer spring washers 60 and inner spring washers 64, which alternate are stacked on top of each other. Each outer spring ring 60 has conical chamfers on the inside 61, 62, which are carried out identically from both sides and which are in one Meet edge 63. Each inner spring ring 64 has conical chamfers 65, 66 on the outside on, which are executed identically from both sides and which are in one Meet edge 67. The chamfers 61 and 65 as well as 62 and 66 fit when stacking the Friction spring package exactly on top of one another. End rings 68, which halved inner spring washers 64 correspond to form the ends of the friction spring assembly. When stacking the spring washers remain between the shoulders of the outer spring rings 60 gaps 69 and between the Shoulders of the inner spring washers 64 column 70. The sum of the gap distances represents the represents the maximum spring deflection of the friction spring assembly.

To explain the mode of operation, FIG. 1 is considered in more detail. The two slider crank drives 8, 16 are rigidly coupled via the shaft 5, with the slider crank drive 16 is designed so that when it is switched on always first the secondary switching point 18 switches on and the switch-on resistor 19 into the current path switches.

The current path then leads from the power connection 12 via the flexible connection 20, the closed secondary switching point 18 and the switch-on resistor 19 to the Deflection housing 6 and from there, as a rule, further via a similar arrangement to a current outlet on the other side of the high-voltage switch. After the main switching point 10 has been closed, the secondary switching point 18 goes immediately again, and the current path then leads from the power connection 12 via the closed Main switching point 10 directly on the deflector housing 6. Based on FIG. 2 is intended to show the course of the switch-on movement of the movable contact 17 of the auxiliary switching point 18 and compared with that of the movable contact 9 of the main switching point 10 will. The one for the movement of the movable contact 17 of the auxiliary switch point 18 effective length in crank mechanism 16 is the center distance between shaft 5 and hinge pin 24.

This length is much greater than the effective length of the for the movement of the main switching point 10 provided rotary lever 7. It turns out as advantageous, a transmission ratio between the effective length of the rotary lever 7 and effective length in the slider crank drive 16 in the range of 1: (1.4 to 1.8) to choose.

As soon as the switch-on process, starting from that shown in FIG Position of the slider crank drive 16 begins, the movable contact 17 runs Secondary switching point 18 due to the transmission ratio greater than 1: 1 im Counterclockwise in front of the movable contact 9 of the main switching point 10. That Spring element 26 initially holds levers 15 and 25 in a first stable position so together that the push-through joint 23 is certainly not stretched. Of the movable contact 17 of the secondary switch point 18 is first in the "on" position and closes the current path in which the switch-on resistor 19 is effective.

The transmission ratio 1: 1.5 is preferably chosen because it follows that the secondary switching point 18 is around 8 to 10 milliseconds ahead the main switching point 10 turns on. This period of time is sufficient for most practical ones Operational cases. However, it is easily possible by lengthening or shortening the Lever 15 in the area between the pivot point 28 and the shaft 5 this period of time to enlarge or reduce, without other parts of the Slider crank drive 16 must be modified.

By increasing the time span, the load duration of the Switch-on resistance 19 increased and this has the consequence that switch-on overvoltages in the network at the place of use of the high-voltage switch for a longer period of time. and thus can be reduced to smaller values. In networks that are designed so that no high switch-on overvoltages can occur, it is sufficient to keep them short Time to dampen, so that the switch-on resistor 19 only act during a shorter time got to. In this case, the mechanics ensure that the switch-on resistance 19 is actually only loaded for a comparatively short time, it can be correspondingly more scarce dimensioned and made cheaper.

FIG. 3 shows schematically the moment when the secondary switching point is switched on 18. The first impact ring 34 strikes the first cushioned stop 36, which dampens the impact energy. The further movement is via the connecting rod 29 of the hinge pin 24 blocked in the switch-on direction.

However, the lever 15 is driven by the high-voltage switch in the Moved further counterclockwise. The push-through joint 23 becomes as a result stretched against the spring force of the spring element 26. This stretching process goes further to a dead center, which is characterized in that the axes of the Pivot point 28, the push-through joint 23 and the hinge pin 24 in one Lie level. Shortly before reaching this dead center, the main switching point has 10 is also switched on and the current now flows through this switching point.

After passing the dead center position tilts, driven by the spring force of the spring element 26, the push-through joint 23 in a second stable position around. As a result of this tipping over, a force is applied to the connecting rod 29 Switch-off direction effective, which opens the secondary switching point 18. The lever 15 then moves a little counterclockwise until it is definitely closed of the switch-on process. Figure 4 shows the position of the slider crank drive 16 at definitely switched on high voltage switch. The distance between the service ring 34 and stop 36 shows that the contacts 17, 21 of the auxiliary switching point 18 except Are engaging.

Based on the. Position of the slider crank drive shown in FIG 16 begins the switching off process of the high-voltage switch. The lever 15 moves clockwise and the contact spacing of the already open auxiliary switching point 18 is increasing. Only now does the main switching point 10 open and interrupt the Current path. When switching off, this is also due to the transmission ratio greater than 1: 1 of the main switching point 10 leading secondary switching point 18 has so always a higher dielectric strength than the main switching point.

Towards the end of the switch-off movement, the slider crank drive reaches 16 the position shown in FIG. The spring element 26 holds up to this position the push-through joint 23 in the second stable position. After serving of the second impact ring 35 on the sprung second stop 37 is the further movement of the hinge pin 24 is blocked in the disconnection direction.

However, the lever 15 is driven by the high-voltage switch in the Moved clockwise. The push-through joint 23 is consequently again to dead center stretched and after passing the dead center position it tilts, as a result of the force originating from the spring element 26, back into the first one stable position back. As a result of this tipping over, the movable contact 17 becomes the Secondary switching point 18 moved slightly in the switch-on direction. The lever 15 moves however, continue in a clockwise direction until it reaches the definitive switch-off position shown in FIG reached, and takes the movable contact 17 with the slider crank drive 16. As a result of the tipping over, the second impact ring 35 is no longer in contact here either the second stop 37 on.

The function of the spring element 26 is to be explained with reference to FIG will. If the tension spring 46 is attached to the two eyelets 45 in the opposite direction acting forces are stretched, the shoulder 50 rises from the damper disk 49 away. If the tension spring is suddenly relieved, as it does after tipping over of the push-through joint 23 takes place, the shoulder 50 strikes the damping disk 49, the force of the train spring 46 is decisive for the impact energy. The impact energy is dampened by the spring assembly 51, so that the two Brackets 25, 27 are protected from mechanical overload.

A friction spring package, as shown in Figure 7, can be advantageous Use where large impact energies are dampened in the smallest of spaces have to.

With mechanical loading of the stops 36, 37 in the axial direction, the outer spring rings 60 and the inner spring rings 64 are pushed onto one another and stretched or

pressed together, the column 69, 70 between the individual spring washers. The chamfers 61 and 65 as well as 62 and 66 rub intensely on each other, thereby a large part of the impact energy becomes converted into frictional heat. Friction spring packages work down to -50 OC without any loss of performance and are therefore particularly good for high-voltage switches installed outdoors suitable.

The area around the push-through joint is particularly advantageous 23 constructed symmetrically, since in this way jamming of the arrangement is reliably avoided. In a first constructive embodiment, two levers 15 and two levers 22 arranged in parallel and the spring element 26 is fastened between them. At a second structural design is a simple lever arrangement on each side consisting of lever 15 and lever 22, a spring element 26 is attached.

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Claims (7)

PATENT CLAIMS 1. High-voltage switch with switch-on resistor (19) and with at least one main and one secondary switch point (10, 18), wherein the at least one secondary switching point (18) in series with the switch-on resistor (19) and this series connection is in parallel with the at least one main switching point (10) is switched, and each a movable contact (9, 17) of the at least one Main and the at least one secondary switch point (10, 18) of one each via one common shaft (5) driven slider crank drive (8, 16) can be actuated, wherein the at least one secondary switching point (18) always before the at least one main switching point (10) closes and immediately after closing the at least one main switching point (10) opens again, characterized in that the on the movable contact (17) of the auxiliary switching point (18) acting crank drive (16) a push-through Has joint (23), and that the movable contact (17) of the at least one Secondary switching point (18) is coupled with two impact rings (34, 35), which in such a way with two stops (36, 37) cooperate that after the impact of the first Impact ring (34) on the first stop (36), which when the secondary switching point is switched on (18) takes place, the push-through joint (23) from the drive of a first stable one Location is carried away over a dead center, and that after the impact of the second Impact ring (35) on the second stop (37), which is towards the end of the disconnection process takes place, the push-through joint (23) from the drive from a second stable position is passed over a dead center. 2. High-voltage switch according to claim 1, characterized in that that the push-through joint (23) at least one on the shaft (5) frictionally attached first lever (15) and at least one steered to a connecting rod (29) second lever (22) and at least one spring element (26) which is attached to the two levers (15, 22) is articulated. 3. High-voltage switch according to claim 2, characterized in that that the spring element (26) has a tension spring (46) and a damping device (47) having a first spring assembly (51). 4. High-voltage switch according to claim 3, characterized in that that one end of the tension spring (46) by means of a first holder (25) on a Hinge pin (24) is attached, which connects the second lever (22) to the connecting rod (29) connects, and that the other end by means of a second bracket (27) to a pivot point (28) of the first lever arranged adjacent to the shaft (5) (15) is coupled. 5. High-voltage switch according to claim 4, characterized in that that the first holder (25) serves as a guide part for the tension spring (46) and partially the second holder (27) which carries the first spring assembly (51) comprises. 6. High-voltage switch according to claim 1, characterized in that that the first stop (36) and the second stop (37) are resilient in the axial direction are formed, and that the two stops (36, 37) on opposite sides Sides on a common, double-sided pressurized second spring package (38) prop up. 7. High-voltage switch according to one of claims 3 to 6, characterized characterized in that at least one of the spring assemblies (38, 51) contains friction springs.