DE1538466B2 - ONE OR MULTIPOLE PUSH BUTTON OPERATED OVERCURRENT SWITCH - Google Patents

Description

The invention relates to a single-pole or multi-pole push-button overcurrent switch with thermal and electromagnetic release and a contact bridge that connects with the push button is connected by means of a toggle lever, and with a release shaft designed as a half-wave, the is provided with two levers, one of which with the armature of the electromagnetic release and the other cooperates with the bimetal strip of thermal trip.

In a known overcurrent switch of this type (German Auslegeschrift 1 152 746), the push-button-side Lever of the toggle lever with a two-armed, angled crank articulated connected, which is fixedly pivoted at the end of one arm and with one at the free End of the other arm attached bolt engages in a transverse slot of the push button. To release this known overcurrent switch is a force storage lever, which under the action of a cocked Torsion spring stands and rests with its free end on the half-shaft. Gives the half-wave the energy storage lever free, then this strikes against a projection of the lever on the pushbutton side of the knee lever, so that this knee lever buckles and initiates the release. By using the crank and the energy storage lever are used to manufacture and assemble the well-known overcurrent switch difficult and expensive. In particular, the triggering is achieved by the additional energy storage lever delayed and the actuation of the overcurrent switch by the respective tensioning of the torsion spring difficult.

The invention is based on the object of simplifying the known overcurrent switch and so on train that with low forces a quick electromagnetic and thermal release is achieved is, so that the overcurrent switch according to the invention in particular as a multi-pole overcurrent switch can be trained.

This object is achieved according to the invention in a single or multi-pole push-button operated Overcurrent switch of the type mentioned is solved in that the articulated with the push button connected lever of the toggle lever is designed as an angle lever and with his free arm in the Switch-on position is supported on the half-shaft and that for locking the push button with the angle lever rotatably connecting axis in the switched-on position a stationary pivotable pawl is provided, which by means of a spring with the contact bridge-side lever of the toggle lever in connection stands.

In contrast to the well-known overcurrent switch, in which only the Energy storage lever is released, takes place in the overcurrent switch according to the invention by rotation the release shaft immediately releases the angular lever of the push button Knee lever and thus a buckling of the knee lever, so that the release is much faster and with lower forces than with the known overcurrent switch. This is done by the The locking pawl and the spring acting on the contact bridge-side lever of the toggle lever, the knee joint pulled together and thereby the contact bridge with its contact pieces from the fixed contact pieces picked up.

To support the switch-off movement of the contact bridge, the contact bridge engages with the axis connecting the lever of the toggle lever to a spring, the other end of which is arranged in a stationary manner. In known overcurrent switches provided with a toggle lever, the toggle lever is over its Pushed through dead center so that the two levers of the toggle lever form an obtuse angle and thereby a self-locking of the toggle lever is given (German patent specification 881 238). When the invention Overcurrent switch, however, the toggle lever is not bent to dead center, but only until shortly before dead center, the levers of the toggle lever forming an obtuse angle. This has the advantage that the knee joint is one during the entire triggering of the switch Moves to reduce the angle. It is therefore necessary to pivot the two levers of the toggle lever of the Overcurrent switch according to the invention requires a significantly lower force when it is triggered than in the case of the known switches, in which the two levers of the toggle lever off during triggering their over-center position must be pivoted out.

In the formation of the overcurrent switch according to the invention As a multi-pole overcurrent switch, there is a coil for the electromagnetic in every circuit Trip provided, of which one coil is polarized. This results in a relatively large Attracting force for the magnet armature, which ensures perfect electromagnetic release is. This simple polarity reversal of a coil means that complicated and expensive parts can be achieved a phase shift between the magnetic fluxes avoided.

In the case of a multi-pole design of the overcurrent switch, a bimetal strip is arranged in each circuit. In order to achieve a very fast tripping, especially in the event of an overcurrent in a single phase To achieve, each bimetal strip engages with its free end in a recess of a slidable A release plate that has an approximately U-shaped lever pivoted on it for each bimetal strip has, on one leg of which the associated bimetal strip acts and the other leg is supported on one lever of the half-wave. The same current flows through all the bimetal strips, so all bimetal strips bend in the same way. The bimetal strips act on one leg the U-shaped lever, which is with its other leg on one lever of the half-shaft prop up. The release plate is moved over the U-shaped lever in the same direction up to a stop postponed. Since the release plate cannot move any further afterwards, the bimetallic strips another pivot of the U-shaped lever, which is now a pivot of one lever cause the half-wave and thus also the half-wave itself, whereby the triggering is initiated.

If an overcurrent only flows through one or two bimetal strips, while another bimetal strip remains de-energized or a normal current flows through it, then this holds the other bimetallic strip the release plate back, so that a displacement of the release plate by the rest Bimetal strips cannot be made. The other bimetal strips pivot by means of their associated U-shaped lever corresponding to the

Half-wave attached lever, which initiates thermal tripping. With asymmetrical load The thermal release of the individual circuits is therefore much faster than with symmetrical loading. This is a particular advantage of the overcurrent switch according to the invention.

The stop limiting the sliding movement of the release plate can consist of a screw, which can be arranged in a temperature compensation bimetallic strip, whereby the influence the ambient temperature is switched off.

An exemplary embodiment of the invention is shown in the figures with the features essential to the invention shown. It shows

Fig. 1 is a section through a push button operated Overcurrent switch in its off position,

FIG. 2 shows the same section as FIG. 1, however in the on position of the overcurrent switch,

Fig. 3 is a section along the line III-III of Fig. 1,

F i g. 4 shows a section along the line IV-IV of FIG. 2,

Fig. 5 is a section along the line V-V of F i g. 2, with the magnet armature in the attracted state,

6 shows a plan view of the release plate in the area of the bimetallic strips and

Fig. 7 is the same plan view as Fig. 6, wherein the release plate and the bimetallic strips are in a different position.

The three-pole overcurrent switch shown has a housing made in one piece from insulating material 1, with the interposition of an insulating plate 2 of a plate-shaped, made of metal existing cover 3 is covered, which is connected to the housing 1 by means of screws 3 '. To the Einlochbef attachment of the switch is riveted to the cover 3, a threaded sleeve 4 on which a locking washer 5 and a fastening nut 6 are arranged.

For the electrical connection, the three-pole Overcurrent switch in each circuit connection lugs 7 and 8, which are provided with connecting screws 9. The connecting lugs 7 of the two Circuits are at their upper end according to FIG. 3 with the beginning 10 of a coil 11 electrically connected, the end 12 of which is in electrical connection with a connecting rail 13. The connecting rail 13 has, as can be seen from FIG. 1, a right-angled bend 13 'which is provided with a fixed contact piece 14. How out F i g. 3, the beginning is 10 and the end 12 of the coil 11 of the middle circuit swapped around, even with symmetrical loading of the three circuits to achieve a sufficiently large tripping magnetic force. With the fixed contact piece 14, a contact piece 15 of a contact bridge 16 works together, which is another contact piece 17, which cooperates with a fixed contact piece 18. The fixed contact piece 18 is located on a connecting rail 19, on which one leg of a U-shaped, directly heated Bimetal strip 20 is attached mechanically and electrically conductive. The other leg of the bimetal strip 20 is in a mechanically solid and electrically conductive connection with the terminal lug 8.

For the three circuits, three contact bridges 16 are provided, which are made of insulating material Switching bridge 21 are inserted loosely and are each under the action of a compression spring 22. Every contact bridge 16 has a bore 23 into which a corresponding pin 24 of the switching bridge 21 engages. The switching bridge 21 can be in a metallic frame 25 or in the housing 1 in a vertical position Direction according to FIG. 1 slidably guided. The frame 25 is in corresponding recesses

ίο of the housing 1 inserted immovably.

By means of an axis 26, which is guided in the frame 25, the switching bridge 21 with a lever 27 is in articulated connection. The lever 27 is articulated to an angle lever 29 by means of an axis 28.

IS the and together with this forms a toggle lever. The angle lever 29 is guided with its axis 30 on the one hand in slots of the frame 25 and on the other hand mounted displaceably in an elongated hole 31. The elongated hole 31 is located in a switching part 32, which is rigidly attached to a switching rod 33, which is rigidly connected with a push button 34 stands. A cap 35 is snapped onto the push button 34 and has a thickening at its upper end 36 has to increase the grip of the push button 34 for manual release. This cap 35 with the thickening 36 is part of the push button 34. The push button 34 also includes a ring-like part 37 which is fastened below the cap 35 on the push button 34. On the push button 34, an opening spring 38 acts, the lower end of which is attached to a frame 25 attached cup-like spring plate 39 is supported.

A pawl 41 is pivotably mounted on an axis 40 arranged in the frame 25, on which a spring 42 acts, the other end of which is hooked into the lever 27. With the pawl 41 a lateral extension 43 of the switching part 32 works together. In the in F i g. 2 drawn switch-on position the lateral extension 43 is supported by the action of the opening spring 38 on the pawl 41 from. In this switched-on position, the angle lever 29 lies with its right end 29 'on an im Frame 25 rotatably mounted half-shaft 44. On the half-shaft 44, two levers 45 and 46 are rigid attached. The lever 45 has a stop lug 47 on which a magnet armature 48 can act, which by means of an axis 49 is pivotably mounted in the frame 25. The magnet armature 48 has a plate-shaped Part 50, which cooperates with two magnetic yoke plates 51 of the coils 11. All the coils 11 are wound onto a one-piece bobbin 52, which is connected by one with the two magnetic yoke plates 51 connected magnetic core 53 is penetrated. Two springs 54 embrace with one of them The end of the axis 49 and the other end of the axis 26. A torsion spring 55 holds the magnet armature 48 in the in F i g. 2 position shown.

On the upper cross piece of the stamped from sheet metal and U-shaped bent frame 25 is a release plate 56 slidably mounted. As shown in FIGS. 6 and 7, the release plate 56 has in the area of the upper ends 57 of the bimetal strips 20 recesses 58 and 59 into which the ends 57 of the bimetal strips 20 protrude. On the underside of the release plate 56 are bimetal strips for each 20 U-shaped lever 61 mounted pivotably by means of bolts 60. On one leg 62 of the U-shaped lever 61 act the ends 57 of the

Claims (6)

5 6 Bimetal strips 20 when they are bent. With a release follows, since it is under the effect the other leg 63 is supported by the U-shaped springs 42, 54 of the toggle levers 27, 29 together. Lever 61 on lugs 64 and 65 of the lever 46 pulled and the switching bridge 21 with the contact Half-wave 44 from. The movement of the release plate 56 bridges 16 is moved into the switch-off position, in the direction of arrow 66 is indicated by a button as an on 5 is used to turn on the push button 34 from the impact acting screw 67 is limited, which is in an off position according to FIG. 1 in the switch-on Bend 68 of the frame 25 is screwed. development according to FIG. 2 pressed, then supports itself The mode of operation of the overcurrent switch is as follows: the angle lever 29 with its free narrowing: Occurs with symmetrical loading of the three arms under the action of the torsion spring 44 ' Circuits of the switch in its switched-on position io again reached its blocking position, half-wave 44 according to FIG. 2 an overcurrent in all current from. Pivoting now takes place by means of the axis 30 then all the bimetallic coatings of the angle lever 29 are bent around the half-shaft 44 20 evenly to the right according to FIG. 2 counterclockwise according to FIG. 2 and equal through. The ends 57 of the bimetal strips 20 act in a timely manner to push through the toggle lever 27, 29 as well on the legs 62 of the U-shaped lever 61 a. Since 15 a tensioning of the springs 42, 54. After reaching the other legs 63 of the U-shaped lever of the switched-on position according to FIG. 2 puts the 61 at the lugs 64 and 65 of the lever 46 unlock pawl 41 on the axis 30 under the action against the force of a tensioned spring 42 arranged on the half-shaft 44. Neten, sufficiently strong and the half-wave 44 in the For manual release, the push button 34 needs the position according to FIG. 2 holding torsion spring 44 'only from the housing 1 according to FIG. 2, the release plate 56 is pulled in the direction and into the position according to FIG. 1 brought the arrow 66 up to the stop on the screw 67 to be. With this movement the approach pushes with it. Then the 43 is pivoted on the pawl 41 and swivels it in the clock-U-shaped lever 61, whereby the lever 46 and clockwise according to FIG of the angle lever 29 releases. F i g. 2 is pivoted so that the angle lever 29 By the springs 42 and 54, the knee is then released under the action of the springs 42 and 54 lever 27, 29 pulled together and this is the. The toggle lever 27, 29 is pulled together by these springs switching bridge 21 with the contact bridges 16 in FIGS. 42, 54 and the switching bridge 21 is in the switched-off position according to FIG. 1 brought
with the contact bridges 16 in the switch-off position 30. The screw 67 can also be in a temperature according to FIG. 1 brought. The position of the bimetallic compensation bimetallic strips must be screwed in, so strip 20 with their ends 57, the release plate 56 that then the thermal release of the switch is un- and the U-shaped lever 61 and the lever 46 depending on the ambient temperature,
with its approaches 64 and 65 is shown in Fig. 6 dashed- The housing 1 is shown on the outside in the area of the switching dotted. After the bimetallic bridge 21 has cooled down, a cup-like recess 69 for engaging 20 presses its ends 57 the release plate, a signal contact part and a through-56 return to the original position. break 70 for receiving a plunger, by means of It happens that only in one circuit of the switching bridge 21 the signal contacts of the an overcurrent occurs, e.g. B. according to FIG. 7 actuated in the lower part of the signal contact. In the current circuit, then only the associated 40 circles of the signal contact part can be used for remote display Bimetallic strip 20 through, while the other two switch positions of the switch are optical the bimetallic strip 20 are switched on in their original position or acoustic signaling means that remain. The upper ends 57 of these two the on and off positions of the switch Bimetal strips 20 hold the trigger plate 56 in the signal. in Fig. 7 shown position in which the release 45 The lever 27, the angle lever 29, the pawl plate 56 at a certain distance from the 41 and the armature 48 are stamped parts and for Screw 67 is located. Since the release plate 56 is U-shaped to achieve the widest possible support cannot move further, it is immediately bent when it is deflected. Your equally trained thighs, from bending of the lower bimetal strip 20 by its those in the F i g. 1 and 2 each only the front one upper end 57 of the corresponding U-shaped lever 50 can be seen are from axles 26, 28, 30, 40 61 pivoted and penetrated by its leg 63 of the attachment and 49. Set 65 and thus also the lever 46 clockwise - The frame 25 inserted into the housing 1 forms sense according to FIG. 2 swiveled, whereby the exhaust with the stored in it and attached to it solution is initiated. In the case of asymmetrical over-parts, a structural unit that is outside the housing 1 load is triggered earlier than at 55 installed and after completion in the housing 1 symmetrical overload. can be used. After this insertion, When an overcurrent of z. B. pay attention to the insulation plate 2 and the cover 3 on the compartment nominal current strength, the armature 48 housing 1 is placed and tightened by means of the screws 3 'and fixed counterclockwise according to. The push button 34 protrudes from FIG. 2 and against the action of the torsion spring 60 threaded sleeve 4 out. Finally, the 55 is pivoted in such a way that its outer right-hand end hits the pushbutton 34 with the stop lug 47 of the lever 45, which is provided with the thickening 36. The lever cap 35 is placed, which here engages with the push button 45 and thus also with the 34 rigidly connected to it.
Half shaft 44 are pivoted clockwise,
whereby the trip is initiated (Fig. 1). 65 claims: If, in the event of thermal or electromagnetic triggering, the push button 34 is actuated in the 1st single-pole or multi-pole push button switch position according to Fig. 2 held, then overcurrent switch with thermal and electrical magnetic release and a contact bridge that connects to the push button by means of a toggle lever is in connection, and with a release shaft designed as a half-wave, which has two levers is provided, one of which with the armature of the electromagnetic release and the other cooperates with the bimetal strip of thermal release, characterized in that that the lever of the toggle lever (27, 29) which is hingedly connected to the push button (34) is designed as an angle lever (29) and is supported with his free arm in the switched-on position on the half-shaft (44) and that for Locking of the axis which rotatably connects the push button (34) to the angle lever (29) (30) in the switched-on position a stationary pivotably mounted pawl (41) is provided is, which by means of a spring (42) with the contact bridge-side lever (27) of the toggle lever (27, 29) is in connection. 2. Overcurrent switch according to claim 1, characterized in that the contact bridge (16) with the lever (27) of the toggle lever (27,29) connecting axis (26) a spring (54) attacks, the other end of which is fixed (axis 49). 3. Overcurrent switch according to claim 1, characterized in that the two levers of the The toggle lever (27, 29) form an obtuse angle in the on position in a manner known per se and that freely moving knee joint (axis 28) during the entire triggering of the Switch executes a movement reducing this angle. 4. Overcurrent switch according to claim 1 with arranged in each circuit for the coil electromagnetic release, characterized in that a coil (11) is polarized. 5. Overcurrent switch according to claim 1, with arranged in each circuit bimetal strips, characterized in that each bimetallic strip (20) with its free end (57) into a recess (58, 59) a sliding release plate (56) engages, which for each bimetal strip (20) has a pivotably mounted on it, approximately U-shaped lever (61) on which one leg (62) acts on the associated bimetallic strip (20) and the other leg (63) is supported on one lever (46) of the half-shaft (44). 6. Overcurrent switch according to claim 5, characterized in that the displacement movement the release plate (56) is limited by an adjustable stop (screw 67), the can be arranged in a temperature compensation bimetallic strip. For this purpose 2 sheets of drawings