DE3041006C2 - - Google Patents

Description

The invention relates to a locking device direction for one under the influence of a driving force standing construction part, in particular switching part for high and low voltage switchgear, which guided on a guide part and locked Condition due to a spring-loaded unlocking is partially locked, which in a recess of the Structural part arranged balls against one inclined surface inclined to the direction of action of the driving force presses on the guide part.

From DE-AS 12 29 625 a locking device for holding the movable contact piece of a circuit breaker, in particular compressed gas switch, is known. To switch off, compressed gas is admitted into a switching chamber, which moves a piston with a switching pin into the switch-off position. When the piston has reached the end position of the switch-off stroke, balls which are arranged in bores which are provided distributed uniformly over their circumference in a fixed sleeve are forced into a ring groove which is arranged in a bolt by a tube under spring pressure. which is carried by the piston ( 6 ). Due to the special design of the tube, the balls that are in engagement with the annular groove are held. Thus, the movable contact piece is latched against the force of the spring tensioned when switching off.

The structure of this known locking device is complicated. In addition, this device a relatively large trigger path.

In another not previously published lock lungsvorrichtung (P 29 43 104.7) is in an inner bore of a structural part engaging unlocking part provided by means of the balls in the locked position, the in openings of the construction part are arranged against an inclined surface on the guide part are pressed. To the construction part, which at for example connected to a shift rod, in To move towards a driving force in the switching position, is the unlocking part relative to the construction part to move so that the balls have a tapered section the unlocking part is assigned. This allows the balls are inserted into the openings Effect of the driving force, so that the construction part can be moved into the switch position.

This older locking device only has a small trigger path and requires no leverage mechanisms so that the idle time is very short Switching device are the result, but this is Ver locking device with regard to the triggering of the Unlocking part can be improved.

The object of the invention is a locking device to create with low idle times, in which one there is no separate release work for the unlocking part and the release solely by the size of the driving force on Construction part is controlled.

This object is achieved in that on the construction part a counter surface assigned to each ball che is formed, which in the locked state of Opposed surface on the guide part and with this an angle enclosing the balls under the action the driving force of the structural part radially outwards against the opened by the preloaded unlocking part brought closing force presses.

In accordance with the invention is now no separate off to do dissolving work to get the construction part into its To move the switch position under the influence of the driving force, rather, this triggering occurs automatically when the Driving force by the pretensioning force on the Ent locking part acting spring certain closing force increases. In this case, due to the assignment of the Inclined surface on the guide part and the counter surface on the cone structural part the balls against the closing force of the Ent locking part displaced radially outwards so that they disengage from the recess and the con structural part under the effect of the driving force on the balls is led past. It is obvious that this will result a very convenient structure for automation ge create is. By changing the preload the closing force vary accordingly, so that the Tripping can be set differently.  

The inclined surfaces on the guide expediently close part and the counter surface on the construction part one to Tip open the closing surface of the unlocking part An angle, being the closing surface of the unlocking part the surface to be understood is that which the balls in the locking position against the inclined surface on the guide part presses. With extraordinarily simple structural measures the radial outward force generated on the balls that the closing movement of the Ent locking part counteracts.

According to an advantageous embodiment, the closing surface provided on the unlocking part so that they are in the connection with the sloping surface the balls under the action of the leader force by the spring acting on the unlocking part inside, d. H. to the axis of the structural part. This means that after passing the counter surface at the Kon structural part the balls are pressed inwards and thus together with the structural part opposite the guide can be partially moved. It works in a more advantageous way Way the biasing force of the spring over the balls the same sensible with the driving force on the construction part, whereby the switching time is further reduced and, for example, on Switch piece held under spring force in an end position becomes.

It is also useful that the counter surface by a Thickening is formed on the structural part, which with the inner surface of the Guide part limited a passage for the balls. This allows the balls to be displaced radially outwards that the structural part be in the direction of the driving force  can be moved.

It is particularly advantageous that the unlocking part one behind the thickening on the structural part slidably mounted ring, the end face is radial so far above the thickening on the structural part stands that a passage of the balls between unlocking part and the inner surface of the guide part is locked. This means that the balls are always in front of the forehead Surface of the unlocking part are held and not on due to the assignment of the inclined surface and the Mating surface on the construction part conditionally on the balls acting radial force past the unlocking part can be. Due to the sliding arrangement the balls when moving the construction part due the preload in cooperation with the inclined surface on Guide part inwards, i.e. to the axis of the construction part that moves the balls between the unlocking part and the contact surface of the unlocking part on the con structural part to be displaced.

In this context, it is appropriate that the Face of the unlocking part opposite Flä surface of the construction part with that on the end face formed closing surface forms an angle which the after moving the construction due to driving force part between the end face of the unlocking part and the surface of the construction opposite this some balls entered under the pretensioning force of the Locking part presses radially outwards. During the Movement of the structural part thus exerts a force the balls that push them radially outwards  want. This has the consequence that when the construction returns partly the balls are pushed outwards when the Balls pass the inclined surface on the guide part so that the thickening of the construction part again on the balls can be guided past and under the pretension of the Spring is in the locked position.

The locking device according to the invention works in advantageously automatically depending on the Size of the driving force acting on the construction part, whereby by adjusting the preload on the Ent locking part acting spring the release force of the Ver locking device can be adjusted continuously. At the same time, the structure is such that the preload the spring in the same direction in the case of unlocking Driving force acts on the construction part and thus the Switching movement further favored.

An exemplary embodiment is described below with reference to the drawing described. It shows

Fig. 1 is a sectional view of a locking device according to the invention, and

Fig. 2 shows a part of a switch construction with built locking device.

According to Fig. 1 of the structural member 1 is force under the effect of schematically indicated by the arrow P ₁ the drive and is guided in a guide member 2. In the left half of Fig. 1, the construction part 1 is in the locked state, whereas the right half cut shows the construction part 1 in the unlocked position.

As can be seen from FIG. 1, the structural part 1 has a recess 3 which serves to receive balls 4 . The recess 3 has a depth which is smaller than the diameter of the balls 4 , so that the balls 4 can only be partially accommodated in the recess 3 , so that part of each ball 4 in the embedded position on the construction part 1 protrudes. The recess 3 is expediently formed by a circumferential groove in which the balls 4 are received as a ball ring. Instead of a continuous groove, however, individual cutouts can also be provided, in each of which a ball 4 is received.

The recess 3 is at its upper end by a Ver thickening 5 , which is above the bottom of the recess 3 before. The thickening 5 has an outer diameter which is smaller than the inner diameter of the guide section 6 of the guide part 2 . Behind the thickening of the con struction part 1 is designed as a ring entrie gelungteil 7 . The ring 7 is slidably arranged on a stub 8 projecting at the free end of the structural part 1 . The ring 7 has an outer diameter larger than the outer diameter of the thickening 5 , so that the ring 7 projects radially beyond the thickening 5 . As a result, in the locked state by the ring 7 , the Ver thickening 5 and an inclined surface 9 formed on the guide element 2 , a chamber is formed in which the balls 4 are held.

The inner bore of the guide element 2 is closed at the upper end by a cover 10 through which a screw 11 is screwed. A spring seat 12 arranged in the inner bore of the guide part below the cover 10 is fastened with the screw 11 . A spring 13 extends between the spring seat 12 and the ring 7 , this spring 13 being pretensioned. The bias can be changed by screwing the screw 11 ver.

Due to the force exerted by the spring 13 bias force, the ring 7 is pressed with its ren at äuße end of the structural member 1 facing end surface 14 closing surface 15 formed against the balls 4 in the locked state, so that this is pressed against the closing surface 15 opposite the inclined surface 9 which is inclined to the direction of action of the driving force. Since the balls partially extend into the recess 3 and partly extend over the inclined surface 9 , that is to say beyond the diameter of the guide section 6 , the structural part 1 is locked within the guide part 2 . The closing force in the locked position is determined here by the adjustable biasing force of the spring 13 .

The construction part 1 has in the region of its thickening 5 a counter surface 16 opposite the inclined surface 9 , on which the balls lie in the locked position. The counter surface 16 is inclined such that the balls 4 are pressed radially outward under the action of the downward driving force P ₁ . For this purpose, the inclined surface 9 and the counter surface 16 expediently form an acute angle which is open to the outside. The se training has the result that the locking position is maintained as long as the driving force P _{1 is} less than the closing force exerted by the biasing force of the spring 13 via the ring 7 on the balls 4 . However, as soon as the driving force P ₁ exceeds this closing force, the balls 4 are pressed radially outward, so that the structural part 1 with its thickness 5 can be guided past the balls 4 and the switch contact is closed. That is to say, so that the thickened portion 5 of the guide member 1 defines a passage for the balls with the inclined surface be behind the 9-sensitive inner surface 17, which is blocked only by the ring. 7

When the structural part 1 with its thickening 5 is guided past the balls 4 , the balls are pressed inwards by the ring 7 in cooperation with the inclined surface 9 towards the axis of the structural part 1 , so that they enter the space between the end face facing the structural part 1 14 of the ring 7 and the area 18 of the structural part 1 lying behind the thickening. This position is illustrated in Fig. 1 in the right half of the section. This displacement of the balls 4 between the ring 7 and the structural part 1 is largely caused by the inclined surface 9 in conjunction with the biasing force exerted by the spring 13 , this displacement advantageously being further favored in that the closing surface 15 of the ring 7 in opposite directions Direction to the inclination of the inclined surface 9 is inclined and includes an acute angle open to the axis of the structural part 1 .

In the right half of FIG. 1 shown th position of the construction part 1, the spring 13 also acts with its biasing force on the balls 4 and thus on the construction part 1 , so that this spring 13 expediently in the same direction with the driving force P ₁ the structural part acts and so holds, for example, a contact piece under spring force in an end position.

As soon as the construction part 1 in the opposite direction to the driving force P ₁ upwards, for example, is moved out of its switching position, the balls 4 emerge from the space between the ring 7 and the surface 18 of the construction part 1 and come back to the system Inclined surface 9 , the thickening 5 can pass the balls 4 . This leakage of the balls 4 is favored in that the surface 18 of the structural part 1 forms an angle with the closing surface 15 , which displaces the balls 4 radially outward under the action of the biasing force of the spring 13 . Expediently, the closing surface 15 and the surface 18 of the structural part therefore form an acute angle which is open towards the inner surface of the guide part 2 .

From Fig. 2 a part of the circuit construction can be seen in which the locking device according to the invention is used. The guide element 2 is fastened with a cross plate 19 which has a central bore 20 . In this central bore 20 , a connecting sleeve 21 (insulating piece) is used, by means of which the structural part 1 is connected to a shift rod 22 which is guided by a sleeve 23 by spacing 23 at a distance from the cross plate 19 arranged cross plate 24 . An aluminum plate 25 fastened to the switching rod 22 is provided below the cross plate and a copper winding 26 is provided in the cross plate 24 . The winding 26 and the aluminum plate form an electro-dynamic triggering device, by which the driving force P _{1 is} caused. The switching rod 22 closes, for example, a switching contact in a switching part for high and low voltage switching devices, preferably for mining and tunneling.

Claims (9)

1.Locking device for a structural part under the action of a driving force, in particular switching part for high and low voltage switching devices, which is guided on a guide part and is locked in the locked state by a resiliently biased unlocking part, which is arranged in a recess in the structural part against one of Direction of action of the driving force inclined inclined surface on the guide part presses, characterized in that on the structural part ( 1 ) each ball ( 4 ) associated mating surface ( 16 ) is ausgebil det, which is in the locked state of the inclined surface ( 9 ) on the guide part ( 2 ) and with this water encloses an angle which presses the balls ( 4 ) under the action of the driving force (P ₁ ) of the construction part radially outwards against the closing force applied by the pre-tensioned unlocking part ( 7 ). 2. Locking device according to claim 1, characterized in that the inclined surface ( 9 ) on the guide part ( 2 ) and the counter surface ( 16 ) on the con struction part include an open angle towards the closing surface ( 15 ) of the unlocking part. 3. Locking device according to claim 1 or 2, characterized in that the closing surface ( 15 ) on the unlocking part ( 7 ) with the inclined surface ( 9 ) on the guide part ( 2 ) at an angle which the balls under the action of a spring ( 13th ) applied to the unlocking part of the biasing force in the recess ( 3 ) of the construction part ( 2 ), which has a smaller diameter compared to the ball. 4. Locking device according to claim 3, characterized in that the closing surface ( 15 ) on the unlocking part ( 7 ) with the inclined surface ( 9 ) on the guide part includes an acute angle towards the axis of the structural part ( 1 ). 5. Locking device according to one of claims 1 to 4, characterized in that the counter surface ( 16 ) is formed by a connection ( 5 ) on the structural part ( 1 ) which with the inner surface of the guide part ( 2 ) adjoining behind the inclined surface has a passage limited for the balls ( 4 ). 6. Locking device according to one of claims 1 to 6, characterized in that the unlocking part ( 7 ) behind the thickening ( 5 ) on the structural part ( 1 ) is displaceably mounted ring, the end face ( 14 ) radially so far over the thickening ( 5 ) on the construction part protrudes that a passage of the balls ( 4 ) between the unlocking part ( 7 ) and the inner surface of the guide part is blocked. 7. Locking device according to one of claims 1 to 6, characterized in that the end face ( 14 ) of the unlocking part ( 7 ) opposite surface ( 18 ) of the structural part ( 1 ) forms an angle with the closing surface formed on the end face ( 15 ), which pushes the structural part ( 1 ) depending on the driving force between the end face ( 14 ) of the unlocking part and the water opposite surface ( 18 ) of the structural part les balls ( 4 ) under the biasing force of the unlocking part ( 7 ) radially outwards. 8. Locking device according to one of claims 1 to 7, characterized in that the biasing force for the unlocking part ( 7 ) is adjustable. 9. Locking device according to claim 8, characterized in that for adjusting the biasing force by a screw ( 11 ) adjustable spring seat ( 12 ) is provided for the spring ( 13 ).