DE69317198T2 - Mechanism for an earthing switch - Google Patents

Description

The invention is in the field of electrical switchgear used, for example, to protect medium-voltage transformers and comprising an earthing switch connected in series with a load switch or circuit breaker. It relates in particular to the mechanism for switching the earthing switch on and off by actuating the drive element associated with the load switch.

From the publication DE-C-611 677 it is known to operate a load switch and the earthing switch associated with it via the same drive element.

It is also known that such a mechanism can be designed as a spring-loaded mechanism which serves to be coupled to the drive element of the load switch connected in series with the earthing switch via a mutual locking mechanism, such that the drive element of the load switch simultaneously causes the load switch to be switched off and the earthing switch to be switched on, or the load switch to be switched on and the earthing switch to be switched off. In a manner also known, the earthing switch comprises a fixed contact electrically connected to the load switch and a movable contact carried by a rotating contact carrier and connected to earth.

Due to the direct coupling between the load switch and the earthing switch, it may happen that a blockage of the contact carrier caused by any reason prevents the operation of the associated load switch. Such a blockage is particularly serious for the equipment to be protected if it prevents the load switch from being switched off in the event of an operating fault.

Furthermore, from the document US-A-3 735 073 a pure load switch with a double spring mechanism is known, whereby a first spring serves to transfer the load switch from the off position to the on position and a second spring serves to overcome the electromagnetic forces occurring in the event of an electrical fault.

The present invention is based on the object of eliminating the disadvantage described above by means of a mechanism which is particularly reliable and safe with regard to the electrical protection functions ensured by the switchgear cell.

The mechanism according to the invention is described in claim 1.

Preferably, the overcoming of the jump point of the first mechanism occurs approximately at the end of the actuating stroke of the drive element associated with the load switch and the first angular position corresponds to the position of the contact carrier in the stable switch-off position of the earthing switch.

The operation of the drive element when switching on the earthing switch is referred to as "independent", i.e. the contact carrier only actually moves when the drive element has almost reached the end of its operating stroke and the load switch is therefore already switched off. On the other hand, the operation of the drive element when switching off the earthing switch is referred to as "dependent", i.e. the movement of the drive element immediately causes a movement of the contact carrier.

The first mechanism is preferably arranged at one end of the rotation axis of the contact carrier and the second mechanism at the other end of said rotation axis.

An embodiment of the invention is shown in the attached drawings and explained in more detail in the following description, specifying further advantages and features.

- Figure 1 shows a circuit cell, shown schematically for illustrative purposes, for accommodating a mechanism according to the invention;

- Figure 2 shows the circuit diagram of the switch cell from Figure 1;

- Figure 3 is a perspective view of the contact carrier of the earthing switch equipped with a mechanism according to a particular embodiment of the invention;

- Figures 4, 5 and 6 are detailed side views from the right of the first mechanism associated with the contact carrier of Figure 3, the first mechanism being shown in the stable off position, at the time of overcoming its jump point during the movement of the drive element for switching on the earthing switch or at the end of the movement of the actuating element for switching on the earthing switch;

- Figure 7 is a detailed side view from the left of an embodiment of the second mechanism associated with the contact carrier of Figure 3, the second mechanism being shown at the moment of overcoming its jump point when the earthing switch is switched on;

- Figures 8 and 9 are detailed side views from the right of the first mechanism, shown respectively in the stable closed position and at the moment of overcoming its jump point during the movement of the drive element to open the earthing switch;

- Figure 10 is a detailed left-hand side view of the second mechanism, shown at the moment of overcoming its jump point when the earthing switch is switched on;

- Figure 11 is a detailed right-hand side view of the first mechanism shown at the end of the travel of the drive element for opening the earthing switch.

Figures 1 and 2 show the switchgear cell 1 comprising an electrical infeed 2 and an electrical outfeed 6. Between the infeed 2 and the outfeed 6, for example, an SF6 load switch or circuit breaker 3 with three switch positions (on, off, earthing), a fuse 4 and an earthing switch 5 are connected in series. The earthing switch 5 comprises, in the conventional manner, a fixed contact 8 and a movable rotary contact 7. A mutual locking mechanism 11 is arranged between the drive element 13 of the load switch 3 and the mechanism for switching the earthing switch 5 off or on, such that the movement of the drive element 13 simultaneously switches the load switch 3 off and the earthing switch 5 on, or switches the load switch 3 on and off. Switching off the earthing switch 5 causes the earthing switch 5 to switch off. In the case of a three-phase supply, the switching cell 1 comprises three identical circuits connected in parallel as shown in Figure 2. Such a switching cell is particularly suitable for the protection of medium-voltage transformers.

Figure 3 shows a three-phase earthing switch with three fixed contacts 8a, 8b and 8c and three movable contacts 7a, 7b and 7c, the latter contacts being attached to a contact carrier 9 which can be pivoted about an axis 10. The mechanism for switching the earthing switch on and off is coupled in a known manner to the drive element 13 of the load switch 3 via a locking rod 11 which can be moved in a straight line along its longitudinal axis.

One of the ends of the rod 11 carries a transfer lever 12 which is articulated to the rotating drive element 13 of the load switch 3, while at the other end a guide body 11 a is attached to a link 34 aligned parallel to the rod 11, which serves to interact with the mechanism of the earthing switch 5.

According to the invention, the mechanism of the earthing switch comprises a first jump point mechanism 30 and a second jump point mechanism 20. For even force distribution on the movable arrangement, the jump point mechanisms 20 and 30 are preferably arranged on both sides of the axis of rotation 10 of the contact carrier 9.

The mechanisms 20 and 30 and their operation are described in more detail below with reference to Figures 4 to 11.

The first spring point mechanism 30 shown in Figures 4 to 6, 8, 9 and 11 is attached to a fixed chassis 40a on which the axis 10 of the contact carrier 9 is mounted. The mechanism 30 comprises an articulated lever 32 which is mounted so as to be rotatable about an axis 33 attached to a fixed chassis 40a. The articulated lever 32 has a first roller 35 which interacts with the linear guide 34 of the filling body 11a, and a second roller 36 which interacts with a complex-shaped guide 37 formed in section 9a of the contact carrier 9. The articulated lever 32 is acted upon by a tension spring 31 which is suspended between a point 31a of the articulated lever 32 and a point 31b of the fixed chassis 40a.

In the stable switch-off position shown in Figure 4, the contact carrier 9 forms an angle α with a freely selected, fixed reference line, in the present case, for example, the horizontal.

The second spring point mechanism 20 shown in Figures 7 to 10 comprises a tension spring 21 which is suspended between a point 21a of a rotation direction reversing lever 9b which is firmly connected to the contact carrier 9 and a point 21b of the fixed chassis 40b.

The way it works is now described in more detail. When the drive element 13 assigned to the load switch 3 is actuated with the aim of switching off the load switch 3 and switching on the earthing switch 5 (Figure 5, points 31a, 33 and 31b are aligned with one another), the rod 11 performs a straight downward movement and the guide 34 assigned to the guide body 11a slides over the roller 35.

The contact carrier 9 therefore remains in its position. After a certain idle stroke, the drive element 13 practically reaches the end of the stroke, the edge of the guide 34 comes to a stop against the roller 35 and pivots the articulated lever 32 about the axis 33. The spring 31, which had previously acted as an inhibiting force, reaches its jump point position (Figure 5, points 31a, 33 and 31b are aligned with one another), whereby the contact carrier 9 has retained its position unchanged due to the freewheeling of the roller 36 in the guide 37. As soon as the spring 31 has overcome its jump point position, it acts as a drive element via the roller 36 and the guide 37 and pivots the contact carrier 9. In this phase, the drive element 13 has reached the end of the stroke (see Figure 6).

During the rotation of the contact carrier 9, the spring 21 of the second mechanism 20, which has been acting as a brake until then, reaches its jump point position (Figure 7, points 21a, 33 and 21b are aligned with one another) when the contact carrier 9 forms an angle β with the freely selected fixed reference line, and then also acts as a drive element. As a result, the drive torques are evenly distributed between the two ends of the axis 10 and the switching-on process of the earthing switch 5 (Figure 8) is accelerated.

The switching on of the earthing switch 5 is described as independent, since the pivoting of the contact carrier 9 is not directly coupled to the movement of the drive element 13, but occurs with a slight delay. It is clear that a foreign body that may prevent the earthing switch 5 from switching on can in no way prevent the load switch 3 from switching off. Since the contact carrier 9 can be equipped with a position indicator, it is possible to check whether the earthing switch 5 is correctly switched on before any intervention in the installation.

When the drive element 13 associated with the load switch 3 is actuated with the aim of switching on the load switch 3 and switching off the earthing switch 5, the linkage 11 performs a movement in the opposite direction and takes the articulated lever 32 and the contact carrier 9 (see Figure 9) with it from the beginning. The switching off of the earthing switch 5 is referred to as dependent, since every movement of the drive element 13 immediately causes the pivoting of the contact carrier 9. It is clear that a foreign body which may prevent the earthing switch 5 from switching off will inevitably also prevent the load switch 3 from switching on.

As soon as the contact carrier 9a has reached an angular position α (see Figure 9), the spring 31 of the mechanism 30, which has acted as an inhibiting force until then, overcomes its jumping point and then acts as a drive element. The drive element 13 has then practically reached the end of its stroke.

When the contact carrier 9 finally reaches the angular position β shown in Figure 10, the angle of which corresponds to the position in Figure 7, the spring 31 of the mechanism 20, which has been acting as an inhibiting force up to that point, overcomes its jumping point and then also acts as a drive element. The contact carrier 9 then reaches the end of its switch-off stroke (see Figure 11) and once again assumes a stable switch-off position (see Figure 1).

According to the special embodiment of the invention described above, the jump point position of the spring 31 when the earthing switch 5 is switched on and the angular position α of the contact carrier arm in the switch-off position coincide; however, the person skilled in the art will immediately recognize that this feature does not necessarily have to be present.

The angular position β corresponding to the jump point position of the spring 21 associated with the mechanism 20 must, however, always lie between the angular positions α and γ corresponding to the jump point positions of the spring 31 associated with the mechanism 30 when the earthing switch is switched on or off. In this way, the jump point of the mechanism 30 is always overcome before the jump point of the mechanism 20 is overcome, regardless of the direction of actuation of the drive element 13; the three angular positions α, β and γ are preferably closer to the switch-off position than to the switch-on position.

It should also be noted that in the open position (Figure 4) and in the closed position (Figure 8) of the earthing switch, the irreversibility of the mechanism is ensured by the special shape of the link 37 and the relative position of the articulated lever 32 and its roller 36.

Claims (8)

1. A jump point mechanism for an earthing switch (5) which is designed to be coupled via a mutual locking mechanism (11) to the drive element (13) of a load switch (3) connected in series with said earthing switch, such that the drive element of the load switch simultaneously switches off the load switch (3) and switches on the earthing switch (5) or switches on the load switch (3) and switches off the earthing switch (5), said earthing switch comprising a fixed contact (8) electrically connected to the load switch and a movable contact (7) carried by a rotatable contact carrier (9) and electrically connected to earth, characterized in that it - a first jump point mechanism (30) controlled by the movements of the drive element (13), the jump position of which corresponds on the one hand to a first angular position (α) of the contact carrier (9) when the earthing switch is switched on and on the other hand to a second angular position (α) of the contact carrier (9) when the earthing switch is switched off, the first mechanism (30) having a first spring (31) which is attached at one of its ends to a fixed chassis (40a) and at its other end to an articulated lever (32) which pivots about a fixed axis (33) and cooperates on the one hand with the mutual locking mechanism (11a) and on the other hand with the contact carrier (9), and the jump position of the first spring (31) is reached when it is aligned with the pivot axis of the articulated lever (32), and - a second jump point mechanism (20) controlled by the movements of the contact carrier (9), the jump pitch of which corresponds to a third angular position (β) of the contact carrier lying between the said first and second angular positions, the overcoming of the jump point of the first mechanism (30) taking place before the overcoming of the jump point of the second mechanism (20) both when switching off and when switching on the earthing switch, the said second mechanism (20) comprises a second spring (21) which is suspended at one of its ends from a fixed chassis (40b) and at the other end from the contact carrier (9b), and the jump point of the second spring (21) is reached when it is aligned with the axis of rotation of the contact carrier (9). 2. Mechanism according to claim 1, characterized in that the overcoming of the jump point of the first mechanism (30) takes place approximately at the end of the actuating stroke of the drive element (13). 3. Mechanism according to one of claims 1 or 2, characterized in that the said first position (α) corresponds to the position of the contact carrier in the stable open position of the earthing switch. 4. Mechanism according to any one of claims 1 to 3, characterized in that the said first (α), second (α) and third (β) angular positions of the contact carrier (9) are closer to the stable open position of the earthing switch than to the stable closed position of the earthing switch. 5. Mechanism according to any one of claims 1 to 4, characterized in that the said articulated lever (32) cooperates on the one hand with the mutual locking mechanism (11 a) via a first guide body (34, 35) and on the other hand with the contact carrier (9) via a second guide body (36, 37). 6. Mechanism according to claim 5, characterized in that the first guide body consists of a first roller (35) firmly connected to the articulated lever (32) and a first slotted link (34) formed in a rod (11 a) for mutual locking and that the second guide body consists of a second roller (36) firmly connected to the articulated lever (32) and a complexly shaped second slotted link (37) formed in the contact carrier (9a). 7. Mechanism according to any one of claims 1 to 6, characterized in that the said first mechanism (30) is arranged at one end of the axis of rotation (10) of the contact carrier (9) while the second mechanism (20) is arranged at the other end of the said axis of rotation. 8. Mechanism according to claim 7, characterized in that the shape of the link (37) and the relative position of the link lever (32) and its roller (36) are designed so that they ensure the irreversibility of the mechanism in the stable off position and the stable on position.