RU2376670C2 - Switching device and toggle mechanism levers for air circuit breaker - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to electric engineering. According to the invention, device contains movable and fixed contacts by the number of phases, driving rotatable shaft, driving shaft lever, which is in coaxial position to the driving shaft with its one end being coupled with the movable contact, closing spring, drive lever connected with closing spring and toggle mechanism levers. The toggle mechanism levers consist of the first lever which is rotatable, the second lever with its one end being connected with the first lever and rotated by output power generated due to resiliency of closing spring. The second lever has a pair of extended parts linked with the first lever so that touching of the first lever can be avoided due to retaining it between the above extended parts. The third lever is also available in the toggle mechanism. One end of the third lever is connected with the second lever and rotates together the second lever to set movable contact into closing position.

EFFECT: wide range of application and improved reliability.

3 cl, 4 dwg

Description

The present invention relates to a switching device for an air circuit breaker and levers of a knee-lever mechanism of an air circuit breaker, and in particular, to a switching device for an air circuit breaker providing improved functional reliability, preventing grazing between its levers and the levers of the knee-lever mechanism.

Typically, an air circuit breaker is used as a low-voltage type circuit breaker that turns the load circuit on / off or an operation to disconnect the circuit when an abnormal electric current, such as a short circuit, earth fault, or excess electric current occurs.

In a conventional air circuit breaker, the levers of the knee-lever mechanism may be deformed or damaged due to the uneven state of the connection between them, or due to a collision or grazing between their side surfaces during charging by means of a closing spring and a closing operation.

Since the levers of the knee-lever mechanism are deformed and damaged, a dangerous deviation occurs between the opening and closing operations of the air circuit breaker. Due to the imbalance in the three-phase current and the voltage supplied to the load, when the air circuit breaker performs opening and closing operations, the load overheats or is damaged. In addition, the service life of the air circuit breaker is reduced.

Therefore, the purpose of the present disclosure is to provide a switching device for an air circuit breaker, providing improved functional reliability and preventing damage or deformation of the levers of the knee-lever mechanism due to grazing between them, and the levers of the knee-lever mechanism of the air switch.

Thus, according to one aspect of the present invention, there is provided a switching device for an air circuit breaker comprising:

a fixed contact connected to a power source of the main circuit or load circuit for each phase and provided according to each phase;

a movable contact located in accordance with the fixed contact and moved to the closed position to interact with the fixed contact or the opening position to separate from the fixed contact;

a drive shaft made rotatable to provide a driving force to move the movable contact to the closed position or the open position;

a drive shaft lever coaxially located on the drive shaft, one end of which is connected to a movable contact;

a closing spring to provide motive energy to move the movable contact to the closed position;

a drive lever connected to the closing spring and rotated by a driving force provided from the closing spring;

a first lever made rotatable, one end of which is connected to a drive lever for engagement with it;

a second lever rotated by connecting to a first lever having two plate parts and having an elongated part with respect to the first lever to prevent the first lever from being touched by positioning the first lever between the two plate parts;

a third lever, one end of which is connected to the second lever, and the other end is connected to the lever of the drive shaft and rotates with the second lever to move the movable contact to the closed position for rotation of the lever of the drive shaft.

According to another aspect of the present invention, levers of a knee-lever mechanism of a switching device for an air circuit breaker are provided, comprising:

a first lever made rotatable;

a second lever, at which one end is connected to the first lever, rotated by the discharging energy of elastic deformation of the closing spring and having a pair of elongated parts extending to the first lever so as to prevent grazing of the first lever by arranging the first lever between them;

a third lever, one end of which is connected to the second lever and rotates together with the second lever to move the movable contact to the closed position.

Preferably, the first lever is one plate portion, and the second lever includes a pair of plate parts spaced apart by a predetermined distance.

The above and other objects, features, aspects and advantages of the present disclosure will become apparent from the subsequent detailed description of the present invention, given with reference to the accompanying drawings.

The accompanying drawings, which are provided to provide an additional understanding of the invention, are included and form part of this description, illustrate embodiments of the invention and together with the description are intended to explain the principles of the invention. In the drawings:

FIG. 1 is a sectional view of a switching device for an air circuit breaker according to the present invention;

FIG. 2 is a sectional view illustrating a compressed state of a closing spring of a switching device for an air circuit breaker according to the present invention;

FIG. 3 is a sectional view illustrating a closed circuit state of a switching device for an air circuit breaker according to the present invention;

FIG. 4 is a perspective view illustrating the levers of a knee link mechanism of a switching device for an air circuit breaker according to the present invention.

Now will be described in more detail preferred embodiments of the present disclosure, examples of which are illustrated in the accompanying drawings.

Next, the switching device for the air circuit breaker according to the present invention and the levers of the knee link mechanism for the air circuit breaker are described in more detail with reference to the accompanying drawings.

As shown in FIG. 1 to 3, the switching device 2 for the air circuit breaker according to the present invention comprises a fixed contact 39, a movable contact 38, a drive shaft 3, a drive shaft lever 40, a spring 25 covering, a drive lever 24, and knee link levers 29, 34 and 35.

The levers 29, 34 and 35 of the knee-lever mechanism are called the first, second and third levers, respectively.

The fixed contact 39 is connected to the main circuit of the power source or the main load circuit in each of the three phases, for example R, S and T, and is arranged according to each phase. When the air circuit breaker is implemented as an air circuit breaker for a three-phase alternating current R, S and T, a fixed contact 39 is arranged according to each phase.

The movable contact 38 is arranged to correspond to the fixed contact 39. That is, when three fixed contacts 39 are provided, three movable contacts 38 are provided. The movable contact 38 is moved to the closed position to touch the fixed contact 39, or to the opening position separate from the fixed contact 39.

The drive shaft 3 rotates in such a way as to provide a driving force for moving the plurality of movable contacts (i.e., three movable contacts) simultaneously to the closing position or the opening position.

The drive shaft arm 40 is coaxially located on the drive shaft 3, and one end thereof is connected to the movable contact.

The closing spring 25 provides a motive force for moving the movable contact 38 to the closed position.

The drive lever 24 is connected to the closing spring 25 and rotates using moving energy from the closing spring 25.

The first lever 29 is rotatable, and one end thereof is connected to the drive lever 24 for mutual connection with it.

The second lever 34 is rotated by interconnecting with the first lever 29 and comprises two plate parts 34a and 34b. The second lever 34 has an elongated portion 55 that is elongated so as to prevent grazing of the first lever 29 by placing the first lever 29 between the plate parts 34a and 34b. The elongated portion 55 is composed of one pair of elongated portions 55a and 55b located, respectively, in the plate parts 34a and 34b.

The third lever 35 has one end connected to the second lever 34, and the other end connected to the lever 40 of the drive shaft. The third lever 35 rotates together with the second lever 34 so as to bring the movable contact 38 into the closed position, while rotating the lever 40 of the drive shaft.

As shown in FIG. 1-3, the switching device 2 for the air circuit breaker according to the present invention further comprises a rotational shaft 21, an abutment 22, a pair of side panels 9, a first latch 27, an on lever 28, a roller lock 30, a second latch 31, an off lever 32, a contact axis 36 opening spring 37 and lower assembly 39-1.

The stop 22 is mounted on the rotational shaft 21, so as to rotate manually or automatically. In particular, the rotational shaft 21 is connected to a control handle or to an electric motor (not shown), thereby rotating manually or from an electric drive.

One pair of side panels 9 supports a switching device 2 on both sides.

The drive lever 24 is rotationally supported between the two side panels 9 and rotates by interconnecting with the first lever 29, coaxially mounted with a stop 22 and a rotary shaft 21.

One end of the closing spring 25 is supported by a spring support (not shown), and its other end is supported by a spring support holder (not shown). The spring support is connected to the lower end of the drive arm 24, and the spring support holder is fixedly mounted in the side panels 9. The drive arm 24 rotates when the stop 22 is rotated so that the spring support moves to the left in FIG. 1-3. In this case, the closing spring 25 is compressed using the spring support, which is moved in the left direction, thus being charged by the energy of elastic deformation.

The first latch 27 extends in the upper and lower directions and moves so as to elastically rotate in one direction using a spring (not indicated by a reference position) connected between a finger attached to the side panel 9 and the first latch 27. In order to prevent rotation the stop 22, which occurs when the energy of elastic deformation of the closing spring being charged at the time of charging is discharged, the first latch 27 fixes or closes the stop 22, engaging with it.

The engagement lever 28 is rotationally mounted above the first latch 27 so as to close or release the first latch 27.

The first lever 29 is L-shaped and centered around a main shaft (not shown) fixedly mounted in the side panel 9. The lower horizontal elongated portion of the first lever 29 is connected to the second lever 34. A groove 49 for introducing or disengaging the clip of the roller 30 of the second clip 31 so as to lock or release the first lever 29, is created in the upper edge of the first lever 29.

The second latch 31 is located above the first lever 29 almost V-shaped. The roller retainer 30 is rotationally mounted in the main part of the second retainer 31 in the length direction. The second latch 31 is biased so as to rotate in one direction with an asymmetric spring (not indicated by a reference position) connected between a finger (not indicated by a reference position) attached to the side panel and the second latch 31. Accordingly, when the roller lock 30 is inserted into the groove 49 of the first lever 29, the second latch 31 is locked by the first lever 29. On the contrary, when the latch of the roller 30 is pulled out (removed) from the groove 49 of the first lever 29, the second latch 31 is released so as to rotate with with an asymmetric spring in one direction, i.e. counterclockwise direction in FIG. 1-3.

The shut-off lever 32 is located above the second latch 31 and rotationally centered around the main shaft mounted in the side panel 9. The shut-off lever 32 is rotated to the locked position of the second latch 31 or so as to release the second latch 31 from blocking. As a means for rotating the lever 32 the shutdown key can be used, controlled by pressing the user, and disconnecting the connection created between the shutdown key and the shutdown lever 32 so as to transmit an offset shut-off keys to shut-off lever 32. The disconnect key and disconnect are not shown.

The lower end of the second lever 34 is connected to the drive lever 24 so as to mutually connect with it together with the first lever 29. The second lever 34 comes into contact with the finger 33 provided in the drive lever 24, and one of its side surfaces is pushed by the finger 33.

The third lever 35 is connected to the upper edge of the second lever 34 and rotates together with the second lever according to the offset of the second lever 34.

The drive shaft 3 is elongated for passage through the side panel 9. The lever 40 of the drive shaft is connected to the third lever 35 and mounted on the drive shaft 3 so as to rotate with the drive shaft 3. Accordingly, since the third lever 35 rotates clockwise or counterclockwise clockwise, the drive shaft lever 40 rotates counterclockwise or clockwise, and thus the drive shaft 3 rotates counterclockwise or clockwise.

The contact axis 36 is used to connect the third lever 35 with the drive shaft 3 for mutual connection between them.

One end of the opening spring 37 is supported by a contact axis 36, and its other end is supported by one locking finger (not indicated by a reference numeral) mounted on the side panel 9. As shown in FIG. 3, the drive shaft lever 40 rotates counterclockwise in the closed position of the air circuit breaker, and thus the contact axis 36 moves to the left side when removed (i.e., toward the fixed contact 39). Accordingly, the opening spring 37 is elongated for charging with energy of elastic deformation. In this state, when the shut-off key is pressed by the user, the shut-off lever 32 rotates clockwise, as shown in FIG. 1 to release the second latch 31. Accordingly, the second latch 31 rotates counterclockwise when removed, and the roller latch 30 is removed from the groove 49 of the first lever 29. In this document, the drive shaft lever 40 and the drive shaft 3 are rotated counterclockwise by discharging from the energy of elastic deformation of the opening spring 37, and thus the third lever 35 and the second lever rotate clockwise.

The drive shaft lever 40 is coaxially connected to the drive shaft 3 so as to rotate with it, and is connected to the movable contact 38. When the drive shaft lever 40 rotates counterclockwise, the movable contact is separated from the stationary contact 39, following the drive shaft lever 40 for open circuit implementations. Conversely, when the drive shaft lever 40 rotates clockwise when removed, the movable contact 38 moves to interact with the fixed contact 39, following the drive shaft lever 40. Accordingly, a closed circuit is created between the power source and the load so as to supply electric current.

The lower assembly 39-1 is connected to the movable contact 38 using an electric cable (not shown) and is electrically connected to a load or power source. Accordingly, when the movable contact 38 comes into contact with the fixed contact 39, a closed circuit is realized between the power source and the load so as to supply electric current. Conversely, when the movable contact 38 is separated from the fixed contact 39, an open circuit is implemented between the power source and the load to prevent the flow of electric current.

The levers of the knee-lever mechanism of the switching device for the air circuit breaker according to the present invention are explained in more detail with reference to FIG. four.

As shown in FIG. 4, the levers of the knee-lever mechanism of the switching device for the air circuit breaker according to the present invention perform a switching operation in order to withstand the repulsive load that occurs at the time of the closing operation. The levers of the knee link mechanism include a first lever 29, a second lever 34, and a third lever 35.

The first and second levers 29 and 34 are connected to each other by the first connecting pin 41, and the second and third levers 34 and 35 are connected to each other by the second connecting pin 42 mounted with the third lever 35. As shown in FIG. 1-3, the first connecting pin 41 extends to connect to the drive lever 24, thereby connecting the first and second levers 29 and 34 with the drive lever 24 for interconnection with the drive lever 24.

In order to prevent the collision of the first and second levers 29 and 34 with each other when grazing at the time of the closing operation and the opening operation of the air circuit breaker, the second lever 34 includes a first plate part 34a and a second plate part 34b. In addition, the first plate portion 34a and the second plate portion 34b are located separately from each other at a predetermined distance. In addition, the first lever 29 is located between the first plate part 34a and the second plate part 34b. Reference numeral 52 denotes the side surface of the first lever 29 facing the second lever 34 in the thickness direction.

Despite the above configuration, the first and second levers 29 and 34 can collide with each other during operation of the air circuit breaker, for example, for the following reasons: connection error and uneven load at the time of charging for the closing spring during the closing operation or opening operation.

To prevent the collision of the first and second levers 29 and 34 with each other when grazing at the moment of charging for the closing spring, the closing operation or the opening operation, the second lever 34 has an elongated part 55 extending to the first lever 29 and ensuring the location of the first lever between the first plate part 34a and the second plate portion 34b. The extension portion is composed of the extension portion 55a of the first plate portion 34a and the extension portion 55b of the second plate portion 34b.

The elongated portion 55 of the second lever 34 maintains the inter-component state of the first lever 29 between the first and second levers 34a and 34b when the air circuit breaker operates in charging, closing and opening, thereby preventing contact or collision between the first and second levers 29 and 34.

The switching device 2 for the air circuit breaker according to the present invention performs charging, closing operation and opening operations. More specifically, the switching device 2 performs a charging operation for charging elastic strain energy in the closing spring 25, a closing operation for interacting the movable contact 38 with the stationary contact 39, using the elastic strain energy charged in the closing spring 25, and an opening operation for separating the movable contact 38 from the fixed contact 39, using the energy of elastic deformation, charged in the opening spring 37.

As shown in FIG. 2, the operation for charging the closing spring 25 of the air circuit breaker is performed such that a closing operation is performed in a state in which the movable contact 38 is separated from the fixed contact 39. As shown in FIG. 2, the rotary shaft 21 is rotated counterclockwise by manually controlling a handle (not shown) provided with the rotational shaft 21 to the user, or by automatically controlling the rotational shaft 21 by an electric motor (not shown) connected to it. Accordingly, the stop 22 rotates counterclockwise, the first lever 29 is coaxially connected to the stop 22, and the rotational shaft 21 rotates. In this state, the drive lever 24, connected to one end of the first lever 29, compresses the closing spring 25 by means of a spring support (not shown) during rotation. Accordingly, the closing spring 25 is charged with elastic strain energy for the closing operation.

Hereinafter, the operation of closing the air circuit breaker is explained with reference to FIG. 3.

When the user presses the lock key (not shown), the locking device of the power lever 28 connected to the lock key rotates counterclockwise. Accordingly, the first latch is released and rotated in one direction by an asymmetric spring supported in the side panel 9. As a result, the lock state of the stop 22 is released by the first latch 27. By discharging the elastic strain energy of the closing spring 25, the drive lever 24 rotates counterclockwise. Accordingly, the first lever 29, one end of which is connected to the drive lever 24, rotates counterclockwise, and thus, the second and third levers 34 and 35 rotate counterclockwise. In this state, the drive shaft lever 40 rotates clockwise, and thus, the movable contact 38 connected to the drive shaft lever 40 comes into contact with the fixed contact 39. As a result, the closing operation of the air circuit breaker is completed.

Upon closure, the closing spring 37 lengthens, while the contact axis 36 provided in the drive shaft arm 40 moves to the left, thereby charging elastic strain energy for the closure operation.

Next, the operation of opening the air circuit breaker is explained with reference to FIG. one.

When the user presses the shutdown key, the shutdown lever 32 rotates clockwise, as shown in FIG. 1 to release the second latch 31. Accordingly, the second latch 31 rotates counterclockwise and the roller latch 30 extends from the groove 49 of the first lever 29. In this case, the drive shaft lever 40 and the drive shaft 3 are rotated counterclockwise by discharging elastic energy deformations of the opening spring 37, and thus the second and third levers 34 and 35 rotate clockwise. Accordingly, the movable contact 38 connected to the lever 40 of the drive shaft is separated from the fixed contact 39, thereby realizing a closed circuit between the power source and the load.

When charging, closing operations and opening operations, the first, second and third levers 29, 34 and 35 perform a switching operation. Since the elongated portions 55a and 55b of the second lever 34 are positioned so as to accommodate the first lever 29 between them, an improperly installed state is avoided among the levers 29, 34 and 35 of the knee-lever mechanism and the impact or collision between the first and second levers 29 and 34 when operating the air circuit breaker.

In the air circuit breaker according to the present invention, the second lever 34 comprises a pair of plate parts and elongated parts located at each end of the plate parts and elongated to position the first lever 29 between the plate parts. Accordingly, when the air circuit breaker is operating, grazing or collision between the first and second levers 29 and 34 is avoided in such a way as to avoid deformation or destruction of the levers of the knee-lever mechanism. As a result, the air circuit breaker has improved reliability and a long service life.

The above embodiments and advantages are only exemplary and should not be construed as limiting the present disclosure. Real ideas can be easily applied to other types of devices. This description should be considered illustrative, and not limiting the scope of the claims. Many alternatives, modifications, and changes will be apparent to those skilled in the art. The distinguishing features, designs, methods and other characteristics of the exemplary embodiments described herein may be combined in various ways to provide and / or alternative embodiments of the invention.

Since the present distinguishing features can be implemented in several forms without deviating from their characteristics, it should also be understood that the foregoing embodiments are not limited to any of the details of the foregoing description, unless otherwise specified, and should rather be understood broadly within its scope, as defined in the attached claims, and therefore, all changes and modifications that fall within the scope of the attached claims, or their equivalents are considered covered by the attached f the claims of the invention.

Claims (3)

1. A switching device for an air circuit breaker, comprising:
a fixed contact connected to a power source of the main circuit or load circuit for each phase and provided according to each phase;
a movable contact located in accordance with the fixed contact and moved to the closed position to interact with the fixed contact or the opening position to separate from the fixed contact;
a drive shaft made rotatable to provide a driving force for moving the movable contact to the closed position or the open position;
a drive shaft lever coaxially located on the drive shaft, one end of which is connected to a movable contact;
a closing spring to provide motive energy to move the movable contact to the closed position;
a drive lever connected to the closing spring and rotated by a driving force generated by the closing spring;
a first lever made rotatable, one end of which is connected to a drive lever for engagement with it;
a second lever rotated by connecting to the first lever, having two plate parts, and having a part elongated in the direction of the first lever to prevent grazing of the first lever by holding the first lever located between the two plate parts; moreover, the elongated part is separated from the first lever; and
a third lever, one end of which is connected to the second lever, and the other end is connected to the lever of the drive shaft and rotates with the second lever to move the movable contact to the closed position for rotation of the lever of the drive shaft. 2. Levers of the knee-lever mechanism of a switching device for an air circuit breaker, comprising:
a first lever made rotatable;
a second lever, connected at one end to the first lever, rotated by the output energy of elastic deformation of the closing spring and having a pair of elongated parts extending to the first lever so as to prevent grazing of the first lever by holding the first lever located between them; moreover, the elongated part is separated from the first lever; and
the third lever, one end of which is connected to the second lever and rotates together with the second lever to move the movable contact to the closed position. 3. The levers according to claim 2, in which the first lever is one plate part, and the second lever includes a pair of plate parts spaced apart by a predetermined distance.

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