FR2818003A1 - SWITCHING DEVICE HAVING A DOUBLE-CUTTING FLOATING MOUNTED ROTATING CONTACT - Google Patents

Abstract

The invention relates to a switching device for multi-pole low voltage circuit breakers, comprising a pair of fixed contacts (26, 28) on conductor rails (30, 32), a rotating contact (14) mounted floating and with double break. Two contact pressure springs (42, 44) provide symmetrical loading of the rotary contact (14) and the contact elements.

Description

1i 2818003 The invention relates to a switching device comprising a

  rotary contact mounted floating and double break, in particular for a multipolar power circuit breaker, comprising a housing of insulating material, a switching drive associated with each pole and mounted in bearings of the insulating housing, so as to rotate around a axis perpendicular to the longitudinal extension of the rotary contact, comprising: - two fixed contact elements, - the rotary contact produced in the form of a floating mounted contact element with two arms, which comprises terminal contacts which cooperate with the fixed contacts, - two contact pressure springs supported on the contact element and each exerting on the contact element a torque directed towards the closing movement, - in which is produced, on each contact pressure spring , on the one hand, a driving element in cooperation with the switching drive, and

  on the other hand a support element acting on the contact element.

  In a double-break switching device without fixed mounting of the movable contact element, for example according to document EP 314 540 B1, the problem arises of a regular distribution of the contact pressure on the two fixedly mounted contacts . The position of the movable contact in relation to the fixed mounted contacts can change during the lifetime of the circuit breaker. The distribution with respect to the force and the position of the cooperating switching elements must still occur after a large number of switching operations, when the switching elements have worn out. In the above-mentioned switching device, a contact pressure spring is arranged respectively on one side of the movable contact element, and it must cause self-centering. However, the torques of the contact pressure springs generate a force which deviates laterally on the contact element. The lateral deviation is limited by the fact that the movable contact element is guided in slots of partition walls which subdivide the housing into separate chambers for the arc extinguishing sheets. Due to the partition walls, the structure of the housing is more complicated. With increased wear and, as a result, tilting of the movable contact element during

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  switching movements, contact may occur in the slots and so

  friction losses in the slots.

  The objective underlying the invention is to improve a double-break rotary contact without fixed mounting of the movable rotary contact element, so that asymmetrical tilting torques do not occur on the element. of contact

mobile rotary.

  This objective is achieved by the object explained in the description which follows, of which

  Advantageous developments also emerge.

  The essence of the invention of the switching device resides in the fact that the two contact pressure springs exert on the two sides of the rotary contact element the most identical possible torques, which load

  symmetrically the stationary contact elements and the terminal contacts.

  Thus, it is possible to dispense with guide slots for the rotary contact element and it is possible to omit the partition walls in which were to be present.

the guide slots.

  Thanks to the particular embodiment of the contact pressure springs, preferably in the form of torsion springs, an excellent self-centering of

the rotary contact element.

  The mounting of the rotary contact can be facilitated, because the

housing in a simpler way.

  The details of the cut-off device can be as follows, without limiting the object claimed. The breaking device is provided in particular for a low-voltage multipolar power circuit breaker comprising a housing made of insulating material, and it comprises a rotary double-breaking contact, a switching drive associated with each pole and mounted in bearings in the housing insulator so as to rotate about an axis perpendicular to the longitudinal extension of the rotary contact. The circuit breaker itself is constituted by two fixed contact elements connected to conductive rails, and by a rotary contact element mounted floating and produced with two arms, which carries terminal contacts which cooperate with the fixed contact elements. Two contact pressure springs, preferably produced in the form of torsion springs, bear on a mounting stud on the rotary contact element and each exert on the rotary contact element a torque directed towards the closing movement. . The pressure springs of

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  contact have no other support on or in the circuit breaker housing. Preferably, the contact pressure springs are produced, on both sides of the rotary contact element, symmetrically with respect to the shape and the exercise of the force; one end of each contact pressure spring is produced as a driving element in cooperation with the switching drive, the other end of each contact pressure spring being produced

  in the form of a support element acting on the rotary contact element.

  Other developments of the invention will be described in the following.

  The support element of each contact pressure spring is produced in the form of a bar situated parallel to the axis of the torsion spring, and moreover the contact pressure springs are produced in pairs symmetrically on both sides. of the bar. The bar is parallel to the axis of rotation and perpendicular to the

  longitudinal direction of the switching element.

  The length of the bar of one of the torsion springs is greater than the total length of the other torsion spring, so that the other torsion spring can

  come to rest in the space covered by the bar of the first torsion spring.

  The contact pressure springs are produced in the form of torsion springs on both sides of their bars. Partial springs have

  winding directions opposite to each other.

  Preferably, the mounting stud is cylindrical and arranged

  perpendicular to the longitudinal direction of the switching element.

  Other advantages and features emerge more clearly from the

  description which follows of an embodiment described by way of example and illustrated in the

  attached drawings. The figures show: - Figure 1, an exploded illustration of the structure of the switching device; - Figure 2, a perspective illustration of half of a housing, comprising constituent elements placed therein; - Figure 3, the details of the conductor rails, the rotary contact element, the torsion springs and the driver; - Figure 4, a side view of the open housing (according to Figure 2); - Figure 5, a view of the assembly with a partially sectioned housing; and

  - Figure 6, the two torsion springs.

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  Figure 1 shows an exploded illustration of a low voltage power circuit breaker 10. The conductive track of the contact passes through the housing 12 of injected insulating material. The conductive track is opened and closed by a switching element 14 with double break (in the form of rotary contact). The switching element 14 is movable around the axis of rotation 16 between a closed position and an open position. The switching element 14 is produced in the form of a lever with two arms 18, 20 the ends of which (end contacts 22, 24) are covered by contact supports made of contactor material. The terminal contacts 22, 24 cooperate respectively with the two opposite contact supports 26, 28 (fixed contacts) and they form pairs of contacts. In the figure, the terminal contacts 22, 24 and the contact supports 26, 28 are further illustrated - separated from the lever arms 18, 20 or the conductor rails 30, 32. During the

  manufacturing they are each fixed by brazing on the corresponding supports.

  The electrical connection of the conductive track takes place at the level of the conductive rails 30, 32 (not shown), which exit on two opposite sides of the housing 12. The housing is designed in two halves and preferably made symmetrically,

  so that it can be assembled with two identical housing halves 12.1, 12.2.

  Each pair of contacts 22, 28 or 24, 26 has been associated with an arc extinguishing chamber 36 or 38 comprising a stack of extinguishing plates which

  are located on respective opposite sides in the housing 12.

  In the circuit-breaker on position, the nominal current flows through the conductive track, returning via one of the conductive rails, passing through the fixed contact 26, the switching element 14 and the fixed contact 28 to leave the housing via the second conductor rail by a connection tab. By rotating the movable switching element 14 clockwise, the two pairs of contacts 22, 28 or 24, 26 are separated, and two arcs of light occur simultaneously in series. The conductor rails are preferably made in the form of a conductive loop in order to exploit the electrodynamic effect for rapid opening.

of the circuit breaker.

  The switching drive actuates the switching element 14 by means of coaches 40.12 and 40.2 located coaxially with the axis of rotation 16. The coaches are produced in the form of half-shells which are mounted to rotate in the holes 39 housing halves 12.1; 12.2. The holes form,

2818003

  for the switching drive, a fixed axis perpendicular to the longitudinal direction of the switching element. The two half-shells 40.1, 40.2 surround the rotary contact element, except for notches 50, 50 'formed at the inner edge which are crossed by the lever arms 18, 20. The driving effect on the lever arms 18, 20 is obtained by stops 48, 48 ', 49, 49' at the edge of the half

training shells 40.1, 40.2.

  The actuation mechanism via the holding latch is mechanically coupled to the drivers 40.1, 40.2, in order to transmit the opening and closing movements to the various conductive tracks of the circuit breaker. The

  details of the actuation mechanism are not illustrated.

  The rotary switching element 14 is held and guided by the torsion springs 42, 44 (see also FIG. 6). The torsion springs are mounted on a mounting stud 21 which extends on both sides of the rotary contact element coaxially along the axis of rotation 16. During assembly, the mounting stud can be pushed into a central bore of the rotary contact element with two arms. The mounting stud 21 does not have a bearing in the coaches 40.1, 40.2. The mounting of the switching element 14 is provided in floating coaxial with the axis of rotation 16. Thanks to the floating mounting of the switching element and thanks to the symmetrical load of the two torsion springs 42, 44, the rotary contact double break is mounted so that a regular distribution of the contact pressure of the terminal contacts 22, 24 on the corresponding fixed contacts 26, 28 is ensured. Thus, the movable switching element 14 is resiliently mounted and can compensate for manufacturing tolerances of the individual components and of the housing as well as contact wear resulting from the switching operations. The axis of rotation 16 of the rotary contact element 14 is a floating axis,

  because there is no direct physical mounting.

  Figure 2 shows the assembly of parts corresponding to their

position of figure 1.

  Figure 3 shows the assembly of the individual parts that are the conductor rails 30 and 32, the rotary contact element 14, the torsion springs 42, 44 and the

  coaches 40.1; 40.2 in the two housing halves 12.1, 12.2.

  A side view on the housing half 12.1 is illustrated in FIG. 4.

  In particular, note the positions of the torsion springs 42, 44. The springs of

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  torsion are loosely located on the mounting stud 21, so that the torsion springs 42, 44 do not jam the mounting stud even when they are fully tightened, so there is no entraining effect between the mounting stud and the

torsion springs.

  Figure 5 shows a view (perpendicular to the view of Figure 4) on the assembly with a partially sectioned housing and the drivers 40. 1; 40.2 partially in section. The other parts are identifiable in correspondence of their

  reference figures of figure 1.

  In FIG. 6, the contact pressure springs are illustrated individually and in their position with respect to each other and with respect to the rotary contact element. The torsion springs 42, 44 hold and guide the rotary contact element 14 inside the drives 401 .; 40.2. The contact pressure springs are produced in pairs on both sides of the rotary contact element 14 and symmetrically coaxially along the axis of rotation 16 and they are loosely arranged on the mounting stud 21 (Figure 1) . The two torsion springs 42, 44 are wound with four turns on both sides of the rotary contact element and they bear against the rotary contact element 14. Since the two torsion springs stress the contact element rotatable in the closing direction, one of the torsion springs 42 attacks the upper face, and the other 44 the face

  bottom of the rotary contact element 14.

  The support element of each torsion spring with respect to the rotary contact element is produced in the form of a bar 43, 45. The bars are located parallel to the axis of rotation 16 and perpendicular to the longitudinal direction

of the rotary contact element.

  The length LI 'of the bar 43 of one of the contact pressure springs (first torsion spring 42) is greater than the total length L1 of the other contact pressure spring 44, while having the same diameter of the spring turns, so that the other contact pressure spring can occupy the space capped by the bar of the first contact pressure spring. The position of the two springs

  torsion with respect to each other is illustrated in Figure 5.

  The ends of the torsion springs protrude beyond the diameter of the spring turn and each is bent to form a catch hook 46, 47. The laterally projecting catch hooks respectively attack counter bearings

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  52, 52 'or the drive half-shells, the counter bearings 52 (see Figure 1) of one of the torsion springs located inside and the counter bearing 52' of the other spring torsional lying on the surface of the drive half-shells 40.1; 40.2. The drive hooks are opposite to each other axially with respect to the axis of

  rotation 16 of the switching drive.

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Claims (7)

  1. Switching device comprising a floating mounted double-contact rotary contact, in particular for a low-voltage multipolar power circuit breaker (10), comprising a housing made of insulating material (12), a switching drive (40) associated with each pole and mounted in bearings (39) in the insulating housing (12.1; 12.2) so as to rotate about an axis (16) perpendicular to the longitudinal extension of the rotary contact, comprising: - two fixed contact elements ( 26, 28), - the rotary contact produced in the form of a contact element (14) mounted floating and with two arms, which comprises terminal contacts (22, 24) which cooperate with the elements fixed contacts (26, 28), -   - two contact pressure springs (42, 44) supported on the contact element (14) and each exerting on the contact element (14) a torque directed towards the closing movement, - in which is produced, on each contact pressure spring (42, 44), on the one hand a driving element (46, 47) in cooperation with the switching drive, and on the other hand a support element (43, 45) acting on the contact element (14), characterized in that the two contact pressure springs (42, 44) are arranged on a mounting stud (21) on the contact element (14) and are produced so as to exert on both sides of the contact element (14) rotational torques which symmetrically load the fixed contact elements (26, 28) and the contacts terminals (22, 24).   2. Switching device according to claim 1, characterized in that the springs   contact pressure (42, 44) are made in the form of torsion springs.   3. Switching device according to claim 2, characterized in that the torsion springs (42, 44) are produced in pairs symmetrically on both sides of the element rotary contact (14).   4. Switching device according to either of claims 2 and 3,   characterized in that the supporting element of each torsion spring (42, 44) is made   in the form of a bar (43, 45) located parallel to the axis of the torsion spring.   5. Switching device according to claim 4, characterized in that the length (Li ') of the bar (45) of one of the torsion springs (42) is greater than the 9 2818003   total length (L1) of the other torsion spring (44), so that the other torsion spring (44) can come to rest in the space (LI ') capped by the bar (43) of the first torsion spring (42).   6. Switching device according to any one of the preceding claims,   characterized in that the mounting stud (21) is arranged perpendicular to the   longitudinal direction of the switching element (14).   7. Switching device according to any one of the preceding claims,   characterized in that the switching drive is designed as two   drive half shells (40.1, 40.2) surrounding the rotary contact element (14).