RU2549366C2 - Distribution device - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: distribution device with an insulating body comprises movable contacts supported by the first end of at least two contact levers respectively. Each contact lever is mounted around a turning pin (21) supported by a support arm of the working mechanism thus ensuring at least turn-out of contact levers into position of contacts closure. The device also comprises a contact-pressing device, which contains two torsional springs (31, 32) acting independently on each of contact levers. Each torsional spring is placed around a contact lever on which it acts so that the axis of spring rotation is shifted in direction of the second end of the contact lever in regard to the turning pin axis.

EFFECT: limited movement of contact levers at turning of the support arm into position of contact closure with potential optimisation for selected dimensions and placement of the contact-pressing spring.

9 cl, 6 dwg

Description

BACKGROUND OF THE INVENTION

The invention relates to the field of switchgears such as a circuit breaker or differential circuit breaker, in particular single-pole neutral circuit breakers. Such circuit breakers are often used in final distribution installations, in particular in buildings, to protect the electrical circuit by disconnecting both the phase wire and the neutral wire.

The invention relates in particular to a switchgear with an insulating housing comprising movable contacts, including at least one phase movable contact and one neutral movable contact, supported by the first end of at least two contact levers, respectively, wherein each contact lever is mounted around a pivot pin so as to at least rotate said contact lever to the locked position of said contacts, said device comprising t contact pressure means acting on said contact levers to apply a contact pressure to said contact levers.

Prior art

Patent application EP 0042778 describes a single-pole circuit-breaker with a neutral circuit, containing two movable contacts, respectively, of a phase circuit and a neutral circuit, wherein said contacts are supported by contact levers of insulating material pivotally mounted around a pivot pin resting on a support in the form of a plate of a working mechanism, and for its part, the said support is pivotally mounted on a fixed pin. Around the pivot pin of the contact levers there is placed a spiral spring twisted by a spiral, which biases the said contact levers to the locked position of the movable contacts.

One of the drawbacks of the prior art circuit breaker is that the sizing and location of the contact pressure spring are not optimized.

SUMMARY OF THE INVENTION

The objective of the invention is to eliminate the disadvantages of the switchgear of the prior art by proposing a switchgear with an insulating housing containing movable contacts, including at least one phase movable contact and one neutral movable contact supported by the first end of at least two contact levers, respectively, with wherein each contact lever is mounted around the pivot pin so as to at least provide rotation of said contact pin yeah, in the closed position of said contacts, said device comprising a contact pressing means acting on said contact lever to apply a contact pressing force to said contact lever, said device being characterized in that the contact pressing means comprises two torsion springs independently acting respectively on said contact arm supporting a phase movable contact and said contact arm supporting a neutral movable contact, each torsion spring develops a torsional force around the axis of rotation of said spring, wherein each torsion spring is located relative to the contact lever on which it acts, so that the axis of rotation of said spring is biased towards the second end of said contact lever relative to the axis of said rotary pin .

The device preferably comprises a working mechanism provided with a support arm supporting a pivot pin around which the contact arms are mounted, said support arm being adapted to move the contact arms between the opening position and the closing position of said movable contacts, each torsion spring being located between the contact arm, which is affected by said torsion spring, and by said support arm.

The support arm is preferably arranged around an axis that is identical to the axis of the pivot pin.

According to one embodiment, each torsion spring comprises a first link pressing on the abutment of the support arm and a second link acting on one of the contact arms. The second link of each torsion spring preferably interacts with the stop of the contact lever, which is affected by said torsion spring, wherein said stop is biased relative to the pivot pin in the direction of the second end of said contact lever. The contact lever stop is preferably located at the second end of said contact lever.

According to one embodiment, the first link of each contact spring has a longer length than the length of the second link of said contact spring. The length of the first link is at least preferably more than twice the length of the second link.

According to one embodiment, the first links of the torsion springs are connected to form a flexible assembly comprising the two torsion springs.

The operating mechanism preferably further comprises:

- a handle pivotally mounted on an insulating casing for controlling opening and closing by movable contacts,

- transmitting means located between said handle and contact levers, including a breakable mechanical connection, and

- the switching lever connected to the switching means for detecting a malfunction of the electrical circuit, wherein said switching lever is designed to bring the contact levers into the open position, causing the opening of said openable mechanical connection.

Brief Description of the Drawings

Other advantages and features will be more apparent from the following description of individual embodiments of the invention, given by way of non-limiting examples and presented in the accompanying drawings.

Figure 1 is a view of the inner part of the circuit breaker according to the invention, which represents the majority of the elements of the working mechanism.

Figure 2 is a partial view of the working mechanism on which one of the contact levers is dismantled so that the support arm and contact pressure means are visible.

Figure 3 - view of the working mechanism, which presents most of the elements of the kinematic connection between the working handle and the movable contacts.

Figure 4 corresponds to Figure 3, on which one of the contact levers is dismantled so that the contact pressure means is visible.

5 is a view with a spatial separation of the parts of the contact levers, the support arm and the contact pressure means.

6 is a view with a spatial separation of the details of the working mechanism and the shutdown mechanism.

Detailed Description of Embodiment

As can be seen in FIG. 1, the circuit breaker 1 comprises an insulating casing 3 essentially formed by two half-shells, with the upper half-shell removed so that the inside of said circuit breaker is visible. Case 3 has a common parallelepiped shape corresponding to a modular system. The housing 3 has a rear panel 5 for mounting on a rail and a front panel 7 provided with an opening for the handle 9 to pass through it. The switch 1 contains a neutral opening circuit and a phase opening circuit located respectively on each side of the insulating partition 11 inserted between two half-shells and extending parallel to the main panels of the housing 3. In FIG. 1, only a phase opening circuit can be seen, the neutral opening circuit is located behind the insulating partition 11.

The phase opening circuit contains a phase movable contact 13 supported by the first end of the contact arm 15. Similarly, the neutral opening circuit contains a neutral movable contact 17 supported by the first end of the other contact arm 19. The contact arms 15 and 19 are made of insulating material and rotatably mounted on the rotary pin 21.

The circuit breaker 1 contains a working mechanism located in the upper part of the housing 3, above the insulating partition 11. This working mechanism is common for the phase movable contact 13 and the neutral movable contact 17. The rotary pin 21 for articulating the contact levers 15 and 19 rests on the support arm 23 (FIG. 5) in the form of a plate, often called a mounting plate, wherein said support arm is pivotally mounted on the housing. The support arm 23 in this case is pivotally mounted about an axis parallel and identical to the axis of the pivot pin 21 of the contact levers 15 and 19. The pivot axis of the support arm 23 and the pivot axis for articulating the contact arms 15 and 19 are made in the form of a shaft 21, which is firmly attached to the support the lever 23. The ends of the shaft 21 are mounted in supports located in the half-shells of the housing 3. The contact levers 15, 19 also contain supports for the said contact levers 15 and 19 for engagement with the shaft 21 respectively on each side of the support arm 23.

Installation with the possibility of rotation of the support arm 23 on the housing 3 allows you to move the contact levers 15 and 19 between the opening position of the movable contacts 13 and 17 and the closing position of the said movable contacts. On the support arm 23 there are stops serving to interact with the contact levers 15 and 19, in order to rotate the latter around the shaft 21 to the locked position of the movable contacts 13 and 17. A spring 90 installed between the housing and the support arm 23 causes the support arm 23 to rotate around shaft 21 to the locked position of the movable contacts 13 and 17.

Installation with the possibility of rotation of the contact levers 15 and 19 on the support arm 23, in turn, provides limited movement of the said contact levers, in particular, when the support arm 23 is rotated to the locked position of the movable contacts 13 and 17.

Each of the contact levers 15 and 19 contains a screen 26, which prevents particles generated by the electric arc from entering and penetrating into the working mechanism. The screen 26 is adapted to slide along the fixed wall 61 so as to perform a protective function, at least at the beginning of the opening of the contacts. The surfaces of the screen 26 and the fixed wall 27 are facing each other and are located close enough to each other so that the said fixed wall cleans the surface of the screen being exposed to the electric arc, which prevents the accumulation of any deposits.

The operating mechanism comprises contact pressure means acting on contact levers 15 and 19 for applying a pressing force to said contact levers and for bringing said contact levers into the closing position of movable contacts 13 and 17. Contact pressure means comprises two torsion springs 31 and 32, respectively acting to the contact arm 15 supporting the phase movable contact 13 and to the contact arm 19 supporting the neutral movable contact 17. Each torsion spring 31 and 32 is provided with a pivot tnym pin around which it develops a torsional force. The torsion springs 31 and 32 are mounted so that their respective pivot pins are offset relative to the shaft 21 to the second end of the contact levers. This second end of the contact levers 15 and 19 is located essentially opposite the first end of the said lever supporting the movable contacts 13 and 17. Such an arrangement of the springs 31 and 32 and their corresponding pivot pins prepares the force exerted by the said springs on the contact levers 15 and 19 and therefore to the movable contacts 13 and 17 supported by said contact levers. This arrangement of the springs 31 and 32, and, in particular, the location of their pivot pins, can also reduce their size.

More specifically, each torsion spring 31 and 32 is located between the contact levers 15 and 19, which are affected by said torsion spring, and the support arm 23. Thus, the dimensions of the torsion springs 31 and 32 are selected so as to exert a closing force on the movable contacts 13 and 17, providing a limited rotation of the contact levers 15 and 19 relative to the support arm, in accordance with the degree of wear of said contacts. The dimensions of the torsion springs 31 and 32 do not allow the contact levers 15 and 19 to be rotated from the opening position to the closed position of the contacts 13 and 17, this function is performed by the support lever 23. Thus, the dimensions of the torsion springs 31 and 32 are selected exclusively in accordance with the applied contact pressure by force, whereby the dimensions of said springs are reduced.

As can be seen from FIG. 2 and 4, the torsion springs 31 and 32 used are coil springs. Each torsion spring 31 and 32 contains a first link 35 and 36, pressing on the stop 39 of the support arm, and a second link 41 and 42, acting on one of the mentioned contact levers 15 and 19. The second link 41 and 42 of each torsion spring 31 and 32 interacts with an emphasis 45 and 46 of the contact lever 15 and 19, which is affected by said torsion spring. This stop 45 and 46 is offset relative to the shaft 21, which is a pivot pin of the contact lever 15 and 19, to the second end of the contact lever located opposite the first end supporting the movable contacts 13 and 17. The stop 45 and 46 of the contact lever 15 and 19 are located, essentially at the second end of said contact arm. Therefore, the contact force exerted by the torsion springs 31 and 32 is maximum.

The spiral turns of the torsion springs 31 and 32 surrounding the pivot pin of said springs are offset relative to the shaft 21. Thus, in addition to increasing the contact pressure and reducing the size of the contact pressure means 31 and 32, the overall dimensions of the working mechanism at the level of the shaft 21 are reduced. Given the complexity of the working mechanism with regard to joints around the shaft 21, this displacement of the turns of the torsion springs 31 and 32 relative to the shaft 21 simplifies the said working mechanism, and its assembly is simplified.

In the presented embodiment, the first links 35 and 36 of the torsion springs 31 and 32 are connected to each other in a single flexible unit that combines the said torsion springs. As can be seen from FIGS. 2 and 4, the first link 35 and 36 of each torsion spring 31 and 32 is longer than the second link 41 and 42 of said torsion spring. More precisely, the length of the first link 35 and 36 is at least more than twice the length of the second link 41 and 42. This arrangement, in particular, facilitates the assembly of the operating mechanism, in particular due to the length of the links, which provides flexibility, required for installation on spring pins.

The operating mechanism of the circuit breaker may be as described in European patent application EP 0295158.

In the presented embodiment, the working mechanism comprises transmission means located between the handle 9 and the contact levers 15 and 19, or more precisely, between the handle and the support arm 23. This means the support arm 23 is moved between the opening position and the closing position of the movable contacts 13 and 17 .

As can be seen from Fig.6, the switching lever 53 connected to the switching means, provides for the detection of a malfunction in the electric circuit and acts on the working mechanism in order to open the contacts of the circuit breaker. The switching means includes an electromagnetic breaker 55 and a thermal breaker, i.e. bimetallic plate 57. The switch lever 53 is pivotally mounted on the pivot pin 59 supported by the support lever 23, with a predetermined offset relative to the pivot pin 21. The switch lever 53 is designed to bring the contact levers 15 and 19 to the open position, causing the mechanical means to be disconnected 61 transmission (Figs. 1 and 2).

The transmission means includes a transmission rod 51 connected to the inner base of the handle to form a knee-lever joint eccentric to the pivot pin 63 of the handle. An openable mechanical link 61 is located between the transmission rod 51 and the support arm 23. In the locked position, the openable mechanical link 61 provides manual control of the operating mechanism by the handle 9. Moving the shut-off lever 53 to the off position due to the action of the disconnector 55 causes the mechanical link 61 to instantly open , which leads to automatic shutdown of the working mechanism, regardless of the handle 9. The switching lever 53 is connected to a return spring (not shown), which serves for the machine nical recovery mechanical linkage 61 when moving the handle 9 in the opening position after turning off the operating mechanism in case of malfunction.

As can be seen from FIG. 6, the unlockable mechanical link 61 includes a locking hook 65 pivotally mounted on the pivot pin 67 of the support arm 23. The nose portion 69 of the locking hook opposite the pivot pin 67 cooperates when the coupling position 61 is locked with the mounting groove 71 located on the upper arm the turning lever 53. The transmitting rod 51 is connected to the locking hook 65 at the point of articulation, which is able to move in the hole of the support lever 23 when performing a trip. This hole is non-through or through and has the shape of a circular sector with a pivot pin 67 in the center. The articulation point is located between the pivot pin 67 and the nose portion 69 of the locking hook. The breakable mechanical coupling 61 forms a step-down phase of the kinematic coupling of the operating mechanism, providing a reduction in the shut-off force developed by the magnetothermal breaker.

As can be seen from FIGS. 2 and 6, the bimetallic thermal breaker plate 57 interacts with the shut-off lever 53 by means of a one-way rotary guide rail 81. The guide rail 81 is formed by a connected lever, one end of which is freely connected to the lower lever of the shut-off lever 53 at the joint 83. The bent middle part of the lever of the transfer lever presses the bulge 85 of the shut-off lever 53 so as to translate the latter into the off position when the bimetal plate 51 deviates to the right when an overload current flows through the pole. During this thermal shutdown phase, the guide rail 81 is a rigid kinematic connection between the bimetallic plate 57 and the switch lever 53. The joint point 83 is located between the bulge 85 and the pivot pin 21 of the switch lever 53. The purpose of this arrangement of the pivot pin 83 in the immediate vicinity of the pivot pin the pin 21 is to minimize the movement of the pivot pin 83 along an arc of a circle with the pivot pin 21 in the center or even to prevent such movement when moving electric by the magnetic switch 55 of the support arm 23.

When the operating mechanism is brought manually or automatically to the open position, the end 87 of the guide rail 81, opposite the joint 83, may come up against a stop formed by the protrusion of the housing, which will lead to the opening of the kinematic connection with the shut-off lever 53. The support lever 23 can turn counterclockwise around of the pivot pin 21, and the middle region of the guide rail 81 will move away from the bulge 85. The articulation point 83 of the guide rail 81 can naturally be formed by the pivot pin 21 of the switch ychaga 53.

The functioning of such a working mechanism is well known to specialists in this field of technology and it makes no sense to describe it in more detail. This operation is also described in European Patent Application EP 0295158.

Claims (9)

1. Switchgear (1) with an insulating body (3) containing movable contacts, including at least one phase movable contact (13) and one neutral movable contact (17), supported by the first end of at least two contact levers ( 15, 19) respectively, with each contact lever mounted around the pivot pin (21), which provides at least a rotation of the contact lever to the contact closure position, the device comprising contact pressure means acting on contact levers for applying contact pressure to the contact levers, characterized in that the contact pressure means comprises two torsion springs (31, 32), independently acting respectively on the contact lever supporting the phase movable contact and the contact lever supporting the neutral movable contact, each the spring develops a torsional force around the axis of rotation of the said spring, and each torsion spring is located relative to the contact lever on which it acts, so at the same time that the axis of rotation of said spring is displaced in the direction of the second end of the contact lever relative to the axis of the pivot pin, and that it comprises a working mechanism provided with a support lever (23) supporting the pivot pin (21), around which the contact levers are mounted, the supporting lever is adapted to move the contact levers between the opening position and the closing position of the movable contacts, and each torsion spring (31, 32) is placed between the contact levers (15, 19), which are affected by the torso ion spring, and support arm. 2. The device according to claim 1, characterized in that the support arm (23) is pivotally mounted around an axis that is identical to the axis of the pivot pin (21). 3. The device according to claim 1, characterized in that each torsion spring (31, 32) contains a first link (35, 36), pressing on the stop (39) of the support arm (23), and a second link (41, 42), acting on one of the contact levers (15, 19). 4. The device according to claim 3, characterized in that the second link (41, 42) of each torsion spring (31, 32) interacts with the stop (45, 46) of the contact lever (15, 19), which is affected by the torsion spring, this stop is offset relative to the pivot pin (21) in the direction of the second end of the contact lever. 5. The device according to claim 4, characterized in that the emphasis (45, 46) of the contact lever (15, 19) is located on the second end of said contact lever. 6. The device according to claim 3, characterized in that the length of the first link (35, 36) of each contact spring (31, 32) is greater than the length of the second link (41, 42) of the contact spring. 7. The device according to claim 6, characterized in that the length of the first link (35, 36) is at least more than twice the length of the second link (41, 42). 8. The device according to claim 3, characterized in that the first links (35, 36) of the torsion springs (31, 32) are connected to a flexible unit containing the two mentioned torsion springs. 9. The device according to any one of claims 1 to 8, characterized in that the working mechanism further comprises:
- a handle (9), rotatably mounted on an insulating body (3) to control the opening and closing of the movable contacts (13, 17),
- transmission means located between the aforementioned handle and contact levers (15, 19), including a breakable mechanical connection (61), and
- a turn-off lever (53) connected to a turn-off means (55, 57) for detecting a malfunction in an electric circuit, said turn-off lever being used to bring the contact levers (15, 19) to the open position, causing the said open mechanical link to open.

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