EP1169721A1 - Motor drive for automatic change-over switch with additional manual emergency operation function - Google Patents

Abstract

The invention relates to a motor drive for an automatic change-over switch that features an additional manual emergency operation function. The inventive drive is provided with a disk with a peripheral cam that engages in a gate plate. Said gate plate is functionally linked with the rotor of the switch via a pin. According to the invention, in the emergency operation mode, a turning handle is introduced into or placed onto the pin to adjust the switch rotor, thereby effecting a relative movement in the axial direction. Said relative movement releases the engagement between the gate plate and the cam. Once the turning handle is removed, said engagement is restored by means of a spring.

Description

 Motor drive for automatic diverter switch and additional manual emergency actuation function

description

The invention relates to a motor drive for automatic diverter switch and additional manual emergency actuation function, the drive having a disk with circumferential actuating cams and the actuating cam engaging in a link switch plate, which is in mechanical connection with the rotor of the switch via an axis, according to the preamble of the patent claim 1.

Automatic diverter switches with motor drive for connecting a consumer optionally with two energy sources are known. The energy sources mentioned are either the grid feed-in or a grid replacement system, e.g. an emergency generator. Automatic diverter switches are e.g. used in systems in which the power supply may only be interrupted briefly or not. Use is also particularly relevant when the system is far away from a control room and from the operator.

Transfer switches with motor drive are offered by Peterreins Schalttechnik GmbH, Schwabach, in different versions under the name "FMU-MOT". Known motor drives can also be retrofitted to existing diverter switches. Manual operation is required for emergency operation, for example in the event of a motor failure, with the above-mentioned types being operated manually with an additional rotary handle via a separate axis or additional intervention. However, it has been shown that, on the one hand, the mechanical transmission of power from the motor to the switch or to the switching elements is complicated, cost-intensive and prone to failure and, on the other hand, high forces have to be applied during manual operation in order to move the motor and the transmission. The conceivable removal of the motor drive for manual emergency operation is also technically very complex and does not meet the safety requirements.

From the patent DE41 42 548 C2, a drive for a disconnector, in particular for a catenary switch, is known, the drive containing a drive shaft which can be actuated by a motor or by hand and acts on the switch. A worm gear has a hollow shaft which can be driven by the motor and serves for concentric mounting of the drive shaft. Arranged in the hollow shaft is a clutch which separates the drive shaft and the hollow shaft from one another or connects them in a non-positive manner, which clutch can be disengaged against an actuating force when switching from motor to manual operation while removing the connection mentioned. The execution of a

Hollow shaft with an internal clutch is, however, structurally complicated and involves higher expenditure in terms of production technology, especially when it is taken into account that the load switch or diverter switch is usually motor-operated remotely and manual operation only takes place in exceptional situations.

It is therefore an object of the invention to provide a motor drive for automatic diverter switches and an additional manual emergency actuation function which allows the required motor forces to be transmitted in a simple manner to the switch shaft or the rotor of the switch, and on the other hand in a particularly simple manner Decoupling of the motor or transmission from the switching rotor is permitted, so that manual shifting is ensured with a tolerable effort. The construction is to be designed in such a way that a safe restart when the engine is started up again can be achieved without the risk of the engine blocking or the motor drive or the individual drive elements being destroyed.

The object of the invention is achieved with a motor drive according to the features of patent claim 1, the subclaims comprising at least expedient refinements and developments.

The basic idea of the invention is to ensure, in a constructively implemented manner, that a relative movement in the axial direction can be carried out in the event of an emergency actuation by inserting or placing a rotary handle on the drive axis, which serves to adjust the switching rotor. This relative movement releases the engagement which existed up to that point between a conventional shift control plate and an actuating cam which is arranged on the drive disk. After such decoupling, the desired switching between the switching positions I-O-II can then be carried out with the help of the rotary handle or the like.

By providing suitable spring elements, the latching state between the actuating cam and the link switching plate is restored after the rotary handle has been removed.

The link switch plate in operative connection with the control cam is designed so that regardless of the manual switching position when the motor drive is reactivated, the motor always engages in the respective subsequent switching direction that is desired and specified.

With the help of the rotary handle described above, which has an actuation extension, the desired manual emergency switching can be carried out in the event of an interruption in the operating current of the motor drive. In a preferred embodiment of the invention, an axially displaceable thrust washer, which comprises a thrust pin and a guide pin, is arranged above the link switching plate, radially surrounding the already mentioned axis.

A so-called shift plate carrier is also attached to the axle, the shift plate carrier having a chamfer or bevel on the side opposite the drive disk.

With axial displacement of the thrust washer, the pressure pin moves in the direction of the shift control plate and presses the latter against the chamfer or slope, so that a predeterminable tilt angle is set, with the result that the setting lifts off the actuating cam or the latter emerges from the setting.

A helical spring is arranged around the guide pin, which causes a spring-assisted return movement of the link switching plate and / or the twist grip, the guide pin slidingly sliding in a hole in the switching plate and e.g. is fixed by locking rings or similar fasteners.

In the operating state, the link switch plate is essentially parallel to the drive pulley and has lateral, anti-blocking bevels.

The run-on bevels prevent the actuating cam from hitting the link switch plate if the motor has been brought into the wrong direction of rotation due to incorrect switching in certain switching positions. The chamfers allow it in

Connection with the axial mobility of the link switching plate to raise it until the actuating cam of the drive disk engages again in the corresponding link of the switching plate.

The actuation extension of the rotary handle has a cross-section that is adapted to the axis, preferably rectangular or square, with a transverse pin at the free end of the extension is located, which is supported against the inner wall of the drive of the desired manual operation.

The cross pin mentioned has a multifunctional effect. The housing cover can have slots adapted to the switching positions. When the switching axis is pushed in or the rotary handle of the actuating extension is moved downwards, the cross pin dips into the interior of the housing through a slot assigned to the respective switching position and simultaneously actuates the pressure plate, i.e. shifts the latter down. As a result, the pressure pin also moves in the direction of the shift control plate and, due to the effect of the chamfer or bevel, brings it into an angular position with the aim of decoupling the control cam and the shift control plate.

The transverse pin now resting on the inside of the housing cover or the housing opening furthermore prevents the switching axis from being pressed out unintentionally during the rotation between the individual switching positions and, on the other hand, only releases the rotary movement when the link switching plate has been lifted sufficiently out of the engagement of the actuating cam. After the switching process has been carried out, the helical spring fixed to the guide pin presses the link switching plate back onto the drive pulley and additionally the actuation extension or the switching axis to the outside.

In other words, the construction with regard to the slot or slots is selected such that they have a depth or a distance from the housing surface in such a way that the actuating extension causes sufficient axial movement of the thrust washer and the pressure pin to decouple the switching plate and actuating cams then release the desired manual rotary movement for the emergency actuation.

In an alternative embodiment, the axis is guided so as to be longitudinally displaceable without leaving the basic principle of the invention, the axis being at least partially surrounding and connected to this, the link switch plate is arranged.

The axis and / or the link switch plate is supported by a spring at a fixed point, so that when the axis with the link switch plate is moved axially, the engagement with the actuating cam is released. Due to the spring force, when the longitudinal displacement force is released, the engagement state is restored, so that motor operation of the diverter switch can be restarted.

In this embodiment too, the link switch plate has lateral bevels as run-on bevels for the actuating cam, which is located on the drive disk.

In one embodiment of the invention, the link switching plate preferably has stop surfaces for limit switches at the end opposite the switching link. The stop surfaces can also be formed by plastic parts with a corresponding shape, which in turn are themselves rotatable.

By means of the above-described invention, it is possible in a particularly simple manner to transmit the required driving forces to a diverter switch or a switching rotor arranged there and, on the other hand, to decouple the motor drive from the switching rotor in the event of an emergency actuation, so that manual switching is possible without hindrance.

The invention will be explained in more detail below on the basis of an exemplary embodiment and with the aid of figures.

Here show:

Figure 1 is a side view with partial sectional view of the motor drive with drive pulley, adjusting cams and link switching plate. Figure 2 is a plan view of the unit from the drive pulley with adjusting cams and link switching plate.

Figure 3 is a side view of part of the drive housing with thrust washer and cross pin.

FIG. 4 shows an illustration similar to FIG. 3, but with a transverse pin in the actuating position and an axially displaced pressure disk;

Figure 5 is a plan view of part of the drive housing with recognizable slots for receiving the cross pin.

6 shows a representation of the chamfers in connection with the actuating cam on the drive pulley; and

7 shows a basic illustration of a further exemplary embodiment with an axially displaceable axis.

In the representation of the motor drive for automatic diverter switch according to FIG. 1, the actual switch is in a switch housing 1, connection contacts (not shown), switch contacts, switch base and a bearing plate for the switching rotor 2 being provided in this switch housing. The switching rotor 2 leads with a shaft end 3 to a corner gear 4, which is located in the drive housing 5. A geared electric motor 7 is flanged onto an intermediate carrier 6. The motor axis 8 carries a drive pulley 9, which has an actuating cam 10.

The adjusting cam 10 has a cylindrical shape with a rounded or conical top surface.

In operation, the actuating cam 10 is in engagement with a link switching plate 11, which is located on the axis 12. The gate switch plate 11 has recesses 13 into which the actuating cam 10 engages when the drive disk 9 rotates and with the aid of which the gate switch plate 11 can be moved. This movement is transmitted by means of the axis 12 and the corner gear 4 to the switching rotor 2, so that the desired switching movements and switching positions can be achieved.

As can be seen from FIG. 2 in connection with FIG. 6, the link switching plate 11 has lateral run-on bevels 14, which allow the control cam 10 to slide (again) into the recesses 13 after incorrect positioning or switching errors, without the switching plate or other mechanical elements to be damaged.

During this sliding of the actuating cam 10 on the run-up bevels 14, the link switching plate 11 guided on the switching plate carrier 15 is raised against the force of a helical spring 16.

In the event of an emergency actuation by inserting or placing a rotary handle (not shown) on the axle 12 or a corresponding axle extension, there is a relative movement in the axial direction, a thrust washer 17 being carried here.

The pressure plate 17 comprises a pressure pin 18, which exerts a force on the end of the link switching plate 11 located below.

Characterized in that the switch plate carrier 15 has a slope 19, the link switch plate 11 tilts backwards, in the example shown in the direction of the switch housing 6, whereby the front part of the link switch plate 11 moves out of the area of the actuating cam 10 of the drive pulley 9 and is then freely rotated can. The helical spring 16 already mentioned, which is located on a guide pin 20, ensures that after removing the emergency actuating device, the thrust washer 17 moves back into the initial state and the gate switching plate 11 comes into contact with the drive pulley 9, the actuating cam here 10 engages again in the recess 13 of the link switching plate 11.

The aforementioned bevel or chamfer 19 of the switch plate carrier is formed on the side opposite the drive disk 9.

With regard to the entraining movement of the link switching plate 11 by the actuating cam 10 on the drive disk 9, reference is made to FIG. 2.

As can be seen, the upper region of the axis 12 preferably has a square cross section and the switching plate carrier 15 is provided with a corresponding inner cross section.

The link switching plate 11 is angularly movable and at least partially axially displaceable, but is fixed radially in order to be able to transmit the desired forces in the motor drive.

In manual operation, the force required to adjust the switching rotor 2 is provided via the axis 12 or the inserted or attached rotary handle by means of the corner gear 4.

The pressure pin 18 is held in corresponding bores in both the pressure plate 17 and the link plate 11 by means of retaining rings. The guide pin 20 is only fixed in the thrust washer 17 and slides with its free end in a bore or recess in the link switching plate 11. With the dash-dotted representation according to FIG. 1, the angularly shifted position of the shift control plate 11 is clearly made when manual or emergency actuation is desired.

3 to 5 is the principle of ensuring one

Switching movement shown only after complete disengagement from the motor drive.

A cross pin 21 dips through one of the slots 22, which are arranged in the housing, into the interior of the housing and takes the thrust washer 17 along in the axial direction.

The diameter of the cross pin 21 in connection with the thickness of the housing wall ensures that such an axial displacement of the thrust washer 17 and thus a tilting of the link switching plate 11 takes place so that a safe decoupling is ensured before the manual switching process can be carried out. The transverse pin 21 resting on the inside of the housing also prevents the actuating extension 23, which acts as a switching axis, from being pressed out unintentionally.

Then, when the manual switching process has been carried out, the helical spring 16 presses the link switching plate 11 back onto the drive disk 9 and at the same time the actuation extension 23 upwards or outwards.

6, the actuating cam 10 can slide along the run-up bevels 14 and raise the link switching plate 11 against the action of the helical spring 16 and enter the recesses 13. This case is relevant if the motor has been switched in the wrong direction of rotation due to incorrect switching at certain switching positions. With the solution described it is effectively prevented that the actuating cam 10 strikes the outer edge of the link switching plate 11 and damages this or other parts. In a further embodiment shown in principle with FIG. 7, the axis 12 is arranged and guided in a longitudinally displaceable manner.

The axis is at least partially surrounded by the aforementioned shift control plate 11, the shift control plate 11 being supported via a spring to a fixed point 24, which can be part of the housing.

When shifting axially in the direction of the arrow, the link switching plate 11 is lifted off the drive pulley 9 and can be rotated unhindered in order to transmit the desired manual drive forces to the switching rotor.

There is the possibility of supporting both the link switch plate 11 against the fixed point 24 by means of a spring and the lower end of the axis by means of a spring, on the one hand to ensure the axial mobility and on the other hand to re-engage or couple the recesses 13 in the link switch plate 11 with respect to the Setting cam 10 to reach.

It is essential for the described exemplary embodiments that a relative movement in the axial direction can be carried out in the event of an emergency actuation by inserting or placing a rotary handle on the axis for adjusting the switching rotor, this relative movement ensuring that the

In the case of engine operation, the existing engagement between the link switch plate and the control cam on the drive pulley is released and, on the other hand, after the emergency handle has been removed after the emergency operation has been completed, it is restored by spring force.

Depending on the position of the actuating cam with respect to the actuation end of the axis, either a tilting movement of the link switching plate or a longitudinal displacement of the plate or, in the case of a plate permanently connected to the axis, a longitudinal displacement of the axis itself is carried out. Reference list

1 switch housing

2 switching rotor 3 shaft end

4 corner gears

5 drive housing

6 intermediate beams

7 Electric motor 8 Motor axis

9 drive pulley

10 control cams

11 link switch plate

12 axis 13 recess

14 bevels

15 switch plate carrier

16 coil spring

17 thrust washer 18 thrust pin

19 Sloping bracket bracket

20 guide pin

21 cross pin

22 slots 23 actuation extension

24 benchmark

Claims

claims

1. Motor drive for automatic diverter switch and additional manual emergency actuation function, wherein the drive has a disc with circumferential actuating cam and the actuating cam engages in a link switching plate, which is in mechanical operative connection with the rotor of the switch via an axis, characterized in that when actuated in an emergency a relative movement in the axial direction can be carried out by inserting or placing a rotary handle with an actuation extension on the axis for adjusting the switching rotor, this engagement releasing the engagement between the sliding plate and control cams and restoring them with spring force after removing the rotary handle.

2. Motor drive according to claim 1, characterized in that an axially displaceable thrust washer is arranged above the link switching plate, radially surrounding the axis, which comprises a pressure pin and a guide pin, a switching plate carrier is attached to the axis, the

Switch plate carrier on the opposite of the drive pulley

Side has a chamfer or bevel and that with axial displacement of the thrust washer, the pressure pin presses the link plate against the bevel or bevel and tilts by a predetermined angle so that the actuating cam emerges from the backdrop.

3. Motor drive according to claim 2, characterized in that a helical spring is arranged surrounding the guide pin in order to bring about a spring-assisted return movement of the link switching plate and / or the rotary handle, the guide pin slidingly sliding in a bore in the switching plate.

4. Motor drive according to one of the preceding claims, characterized in that the link switching plate extends in the operating state substantially parallel to the drive pulley and has lateral, anti-blocking bevels.

5. Motor drive according to one of the preceding claims, characterized in that the actuating extension of the rotary handle has an adapted to the axis, preferably rectangular or square cross-section, wherein at the free end of the extension there is a cross pin which is supported against a housing inner wall during manual operation .

6. Motor drive according to claim 5, characterized in that at least one slot adapted to the cross pin shape is provided in the area of a housing opening for receiving the axis or the actuating extension.

7. Motor drive according to claim 6, characterized in that the slot has a depth or a distance to the housing surface such that the actuating extension causes a sufficient axial movement of the thrust washer and the pressure pin for decoupling the switching plate and actuating cams to subsequently release the manual rotary movement and to hold the end dome position until the actuating extension is moved out.

8. Motor drive according to claim 1, characterized in that the axis is arranged and guided in a longitudinally displaceable manner, the axis being at least partially surrounding and connected to the link switching plate, the axis and / or the link switching plate continuing to become a fixed point via a Spring supports so that the axial Moving the axis with the shift control plate releases the engagement with the actuating cam.

9. Motor drive according to claim 8, characterized in that lateral bevels are formed as run-on bevels for the actuating cam on the link switching plate.

10. Motor drive according to one of the preceding claims, characterized in that the link switching plate preferably has stop surfaces for limit switches at the end opposite the switching link.