DE19630470C1 - Current-limiting circuit-breaker switch with two lugs on centrally pivoted lever - Google Patents

Abstract

The invention concerns a current-limiting power circuit-breaker with a contact arrangement including two or more fixed contact members (8, 9) and containing one or more two-armed contact members (11) that can rotate about an axle (10), and in their closed normal position connect the two fixed contact members (8, 9); the fixed contact members (8, 9) are designed so that, in case of an overload, the rotating contact member (11) swivels into an opened safety position, due to electrodynamic forces. In order to have the rotatable contact member (11) held securely in the safety position until released by actuation of a corresponding control element, the invention proposes that one or more lug-shaped latching members (18, 19) be arranged on the rotatable contact member (11), which are moved along with it if the contact member (11) swivels from the normal position into the safety position, and in this position be prevented from swivelling back into the normal position by one or more spring-loaded locking elements (31, 32) that are arranged in the interrupter chamber so that they cannot rotate, and can be shifted in the axial direction.

Description

The invention relates to a current limiting power counter.

Such a circuit breaker is for example from the EP 0 560 696 A1 is known. It includes one in a Schaltam mergehäuse arranged contact arrangement with two fixed Switch pieces, each with rail-shaped conductors corresponding terminals are connected. Besides, is a two-armed, rotatable contact piece about an axis see which in its closed position (basic lung) connects the two fixed contacts, the fixed contact pieces are designed such that in the event of an overload (e.g. a short circuit) between them and the current-carrying rotatable contact piece of the developing magnetic fields result in forces that Swivel the rotatable contact from its basic position (electrodynamic opening) and in an open end position (Securing position)  bring. In this position the rotatable contact piece then held until an ent speaking control element released and for example way back into his by means of a prestressed compression spring Basic position is pivoted back.

Both from EP 0 406 130 A1 and from DE-AS 11 97 964 are current limiting circuit breakers with rotating Contact pieces known in which on the respective switching piece a nose-shaped locking element is arranged, which itself when the switching piece swivels away from it Basic position moved into a safety position and in this position from a spring-loaded locking member is prevented from swiveling back into the basic position.

The invention has for its object a performance specify switch of the type mentioned, in which in the Secured position of the rotatable contact piece up to Release by actuating an appropriate control element is kept safe.

This object is achieved by the features of Claim 1 solved. More, be disclose particularly advantageous embodiments of the invention the subclaims.

The invention is essentially based on the idea that the rotatable contact piece at least one nose-shaped catch element is arranged, which when pivoting the Switch piece from the basic position to the safety position moved and in this position by at least one turn  firmly arranged in the chamber housing and in the axial direction device movable spring-loaded locking member on the Swiveling back into the basic position is prevented.

In an advantageous embodiment of the invention is a the axis coaxially and on an actuator of the Circuit breaker arranged rotatably arranged driver hen which at least one recovers in the circumferential direction kende gap-shaped recess, along which the na Sen-shaped locking element is pivotable. That - in scope seen direction - first end of the gap-shaped recess  has a driving surface which is chosen such that them from the nose-shaped locking element only after reaching the Secure position of the rotatable contact piece is reached and in the case of electrodynamic opening of the rotatable Switch piece whose braking movement brakes.

The second end of the gap-shaped recess preferably has a stop surface on which the rotatable switch piece in its home position. Besides, that can rotatable contact piece by means of the stop surface at a (e.g. manual) operation of the circuit breaker by Rotation of the corresponding control element against the pressure corresponding contact springs also in its fuse position can be pivoted. The rotating contact piece will in this case too, by blocking the nose-shaped Locking elements by means of at least one axially displaceable Locking member held in its secure position.

To make the rotating contact piece particularly secure in its ge Hold the open position in another execution tion form of the invention on the rotatable contact piece two 1800 pre-staggered nose-shaped locking elements hen. To block the locking elements are in this version tion form two axially displaceable spring struck locking elements provided axially in front and behind the rotatable contact piece are arranged and their lock surfaces together result in a surface that swings back of the rotatable contact piece in its basic position different.

To further easily release the rotatable It has to reach switching piece from the safety position  proved to be advantageous, the contact surfaces of the With participant part and the locking member at least in a part richly wedge-shaped, so that when the Carrier by means of the corresponding control element axial displacement of the locking member against the restoring force corresponding locking member springs. This will make the Latch released by the locking member and the locking piece through the contact springs in its basic position pivoted back.

Further details and advantages of the invention emerge from the following embodiment explained with reference to figures example. Show it:

Figure 1 is a perspective view of the contact arrangement of a circuit breaker according to the invention, in which a hous seteil of the two-part interrupter housing is removed.

FIG. 2 shows a perspective view of the rotatable contact piece of the contact arrangement shown in FIG. 1 with a driver part arranged on an axis and two locking members;

Fig. 3 shows a section the rear locking member is not shown by the method shown in Fig. 2 rotatable switching piece in its base position along the there III III with designated line, keitsgründen from Clear and are indicated by broken lines are not reproduced in FIG. 2 fixed contact pieces ;

Fig. 4 is a Fig. 3 corresponding section with the rotatable switching element and in its securing position

Fig. 5 is a perspective view of a locking member shown enlarged.

In Fig. 1, 1 denotes a circuit breaker which comprises a switch chamber housing with the housing parts 2 , 3 and a contact arrangement arranged in the housing. At the circuit of the circuit breaker 1 to a corresponding circuit, two terminals 4 , 5 are provided, which are connected via loop-shaped rail-shaped conductors 6 , 7 with two fixed switching elements 8 , 9 ( Fig. 3). The fixed contact pieces 8 , 9 are bridged by means of a contact piece 11 which can be rotated about an axis 10 against the pressure of corresponding contact springs 100 ( FIG. 3). The two arms 12 , 13 of the rotatable contact piece 11 press against contact pads 14 , 15 against corresponding contact pads 16 , 17 of the fixed contact pieces 8 , 9 . On the rotatable switching piece 11 , two opposite nose-shaped Rastelemen te 18 , 19 are arranged rotatably.

With 20 in Fig. 2 is also about the axis 10 schwenkba rer driver, which can be connected via two guide pins 21 , each with a claw coupling 22 , 23 . These claw couplings are connected, for example, via corresponding actuating elements of the lock, not shown, of the circuit breaker 1 or to adjacent contact arrangements for the further network phases.

The driver 20 has in its central region a slot-shaped recess 24 which extends in the circumferential direction of the driver and along which the nose-shaped latching elements 18 , 19 can be pivoted. From the recess 24 - seen in the circumferential direction - with respect to each of the two locking elements each have a driver surface 25 or 27 and a stop surface 26 or 28 ( Fig. 3), the functions of which are explained below. Between the driver surfaces 25 and 27 and the opposite arms 12 , 13 of the rotatable contact piece 11 there is a sector-shaped gap, which compensates for the tolerances and fire losses from the contact pieces.

On the guide pin 21 of the driver 20 , two ring-shaped locking members 31 , 32 with axially existing control cams 33 , 34 are mounted (in FIGS . 1 and 2, the locking member 31 is shown for reasons of clarity shifted towards the viewer). These locking members are axially pressed via springs 101 (only one of the two Fe dashed lines in Fig. 2) against the rotatable switching element 11 , so that the switching element facing front surfaces 35 , 36 of the control cams 33 , 34 on the outer surfaces 37 , 38 of the nose-shaped locking elements 18 , 19 rest.

The locking members 31 , 32 are rotatably mounted in the switching chamber housing and for this purpose have cams 39 , 40 which engage in corresponding rail-shaped recesses of the switching chamber housing (not shown).

The mode of operation of the blocking elements 31 , 32 is discussed below: If, for example, an overload occurs (for example a short circuit), the rotatable switching element 11 is rotated in the direction of arrow 41 ( FIG. 3) due to the magnetic forces until the nose-shaped latching elements 18 , 19 strike the stop surfaces 26 , 28 of the recess 24 and prevent the switching piece 11 from rotating further. Even before the stop surfaces 26 , 28 have been reached , the rotatable contact piece 11 has reached its securing position and the lug-shaped locking elements 18 , 19 have released the control cams 33 , 34 , so that these are further pressed together by the pressure of the locking members 101 and with their locking elements 18 , 19 facing blocking surfaces 42 , 43 ( FIG. 5) prevent the locking elements 18 , 19 - and thus also the rotatable switching element 11 - from turning back ( FIG. 4).

The process is similar if, instead of an electrodynamic rotation of the rotatable switching element 11, this is pivoted by actuation of the driver 20 (e.g. manual actuation of the circuit breaker, the actuating element being connected to the driver via the claw coupling 22 ). In this case, the rotatable contact piece 11 and thus also the nose-shaped latching elements 18 , 19 are rotated via the driver surfaces 25 , 27 of the gap-shaped recess 24 . If the nose-shaped locking elements have been pivoted ver by an angle corresponding to the securing position of the rotatable contact member 11, the control cam 33, 34 is released by the catch elements 18, 19 are and, in turn, form a blocking surface which prevents a pivoting back of the rotary contact piece. 11

In order to release the rotatable contact piece 11 from the securing position again, it is provided that the two locking members 31 , 32 are supported on the driver 20 via wedge-shaped surfaces 44-47 . If the driver 20 rotates ver in the direction of the basic position of the rotatable contact piece 11 , the corresponding wedge-shaped surfaces 46 , 47 of the driver 20 press the locking members 31 , 32 away from the contact piece and the nose-shaped latching elements 18 , 19 become free. The contact springs 100 then press the rotatable switching piece 11 back into its basic position.

If the contact piece 11 has been pivoted into the securing position by rotation of the driver 20 , the corresponding contact springs 100 also press the driver 20 into the starting position (a corresponding lock spring can therefore be dimensioned weaker than in known circuit breakers).

In order to ensure a safe release of the rotatable contact piece 11 , it is necessary that after blocking the nose-shaped latching elements 18 , 19 by the locking surfaces 42 , 43 of the control cams 33 , 34 the driver 20 still has a certain freewheel; the locking elements 18 , 19 are therefore not clamped between the stop surfaces 26 , 28 of the driver 20 and the locking surfaces 42 , 43 of the control cams 33 , 34 . Rather, there must be a corresponding minimum distance between the stop surfaces 26 , 28 and the corresponding latching elements 18 , 19 in the securing position (cf. FIG. 4). This minimum distance is to be selected such that when the driver 20 rotates, the control cams 33 , 34 of the locking members 31 , 32 are pressed so far in the direction of the locking member springs 101 due to the wedge-shaped surfaces 44-47 that the locking elements 18 , 19 no longer pass through the control cams 33 , 34 are blocked.

So that the impact of the locking elements 18 , 19 on the stop surfaces 26 , 28 is not too hard during the electrodynamic rotation of the rotary contact 11 and this may be damaged, it has proven to be advantageous that the stop surfaces made of a damping material, e.g. B. made of plastic, rubber or an energy-consuming metal foam. Another advantageous alternative be is to design the housing parts 2 , 3 such that the stop surfaces are in the housing parts.

The invention is of course not based on the above described embodiment limited. So you can Invention, for example, instead of moving axially with two real locking elements with only one locking element ren, provided the locking surface on the control cam accordingly is chosen broadly.

Instead of one of the two side surfaces of the control cam as The control cam can also form a restricted area with a Recess provided in the respective front surface of the control cam is located, so that after a predetermined baren swivel path of the rotatable contact piece the locking element is pressed into this recess.

Reference list

1 circuit breaker
2 , 3 housing parts
4 , 5 terminals
6 , 7 conductors
8 , 9 fixed contact pieces
10 axis
11 rotating contact
12 , 13 arms (of the rotatable contact)
14-17 contact requirements
18 , 19 nose-shaped locking elements
20 drivers
21 guide pins
22 , 23 claw couplings
24 slit-shaped recess
25 , 27 driving surfaces
26 , 28 stop surfaces
31 , 32 locking members
33 , 34 control cam
35 , 36 front surfaces
37 , 38 outer surfaces (locking elements)
39 , 40 cams
41 Direction arrow
42 , 43 restricted areas (control cams)
44 , 45 contact surfaces, wedge-shaped surfaces (locking members)
46 , 47 contact surfaces, wedge-shaped surfaces (driver)
100 contact springs
101 pawl springs.

Claims (11)

1. Current-limiting circuit breaker with a contact arrangement arranged in a switching chamber housing with the features:

• a) the contact arrangement comprises at least two fixed contact pieces ( 8 , 9 ) and at least one two-armed, about an axis ( 10 ) rotatable contact piece ( 11 ) which wel ches in its closed basic position with the fixed contact pieces ( 8 , 9 ) connec det ,
• b) the fixed contact pieces ( 8 , 9 ) are designed such that, in the event of an overload between them and the current-carrying rotating switching piece ( 11 ) due to the magnetic fields, forces arise which the rotating contact piece ( 11 ) against the pressure of at least one Swivel the contact spring ( 100 ) from its normal position into an open safety position.
• c) on the rotatable contact piece ( 11 ) at least one nose-shaped locking element ( 18 , 19 ) is arranged, which moves with a pivoting of the switching piece ( 11 ) from the basic position to the hedging position and in this position by at least one non-rotatable in the Schaltkammergehäu arranged and in the direction of the axis ( 10 ) ver pushable spring-loaded locking member ( 31 , 32 ) on the pivoting back into the basic position is changed.

2. Circuit breaker according to claim 1, characterized in that a control cam ( 33 , 34 ) is arranged on the blocking member ( 31 , 32 ), the locking element ( 18 , 19 ) facing side of which is designed as a blocking surface ( 42 , 43 ), which fixes the rotatable contact piece ( 11 ) in the locked position in this position. 3. Circuit breaker according to claim 1 or 2, characterized in that a pivotable about the axis ( 10 ) driver ( 20 ) is provided which has at least one gap-shaped recess ( 24 ) along which the nose-shaped latching element ( 18 , 19 ) in Circumferential direction is pivotable. 4. Circuit breaker according to claim 3, characterized in that - seen in the circumferential direction - the gap-shaped recess ( 24 ) at one end has a stop surface ( 26 , 28 ) which is selected such that it is in the pivoting movement of the rotatable contact ( 11 ) of the nose-shaped locking element ( 18 , 19 ) is only achieved after reaching the secured position of the rotatable contact piece ( 11 ). 5. Circuit breaker according to claim 3, characterized in that the housing parts ( 2 , 3 ) are designed such that the stop surfaces ( 26 , 28 ) of the nose-shaped locking elements ( 18 , 19 ) in the housing parts ( 2 , 3 ). 6. Circuit breaker according to claim 4 or 5, characterized in that the stop surface ( 26 , 28 ) consists of a damping material. 7. Circuit breaker according to one of claims 3 to 6, characterized in that a guide pin ( 21 ) is provided on the side of the driver ( 20 ) facing away from the latching element ( 18 , 19 ), on which the locking member ( 31 , 32 ) is arranged to be longitudinally displaceable is. 8. Circuit breaker according to one of claims 3 to 7, characterized in that - seen in the circumferential direction - the other end of the gap-shaped recess ( 24 ) forms a driving surface ( 25 , 27 ) for the rotatable switching piece ( 11 ) in its basic position, and that when the driver ( 20 ) rotates, the rotatable switching piece ( 11 ) can be pivoted from the driver surface ( 25 , 27 ) against the pressure of the contact spring ( 100 ) into its securing position. 9. Circuit breaker according to one of claims 3 to 8, characterized in that the contact surfaces ( 44-47 ) of the driver ( 20 ) and the locking member ( 31 , 32 ) are wedge-shaped at least in a partial area, such that when in its securing position be sensitive rotatable contact ( 11 ) upon rotation of the driver ( 20 ) an axial displacement of the locking member ( 31 , 32 ) against the restoring force of a compression spring ( 101 ), so that the locking element ( 18 , 19 ) by the locking member ( 31 , 32 ) is released and the rotatable contact piece ( 11 ) is pivoted into its basic position by the contact spring ( 100 ). 10. Circuit breaker according to one of claims 1 to 9, characterized in that on the rotatable contact piece ( 11 ) two nose-shaped latching elements ( 18 , 19 ) are arranged offset by 180 °. 11. Circuit breaker according to one of claims 1 to 10, characterized in that two axially displaceable spring-loaded locking elements ( 31 , 32 ) are provided, which are arranged axially in front of and behind the rotatable switching element ( 11 ), and their respective locking surfaces ( 42 , 43 ) together result in a surface which prevents the rotatable switching element ( 11 ) from pivoting back into its basic position.