RU2797696C2 - Electrical switching device with shared contacts - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to an electrical switching device with separable contacts. The electrical switching device (2) with separable contacts comprises a switching device, which includes a fixed (6) and a movable (8) electrical contact, a control lever (18) mechanically connected to the movable electrical contact, the control lever being rotatable around the first axis (X18) rotation, between the first position and the second position; an anti-bounce lever (26) positioned so as to move from the initial position to the open position when the control lever reaches the second position. The anti-bounce lever engages the stop (24) when it is in the open position and when the control lever is in the second position so as to prevent the control lever from leaving the second position.

EFFECT: prevention of re-closing of contacts in the process of switching contacts from a closed state to an open one.

7 cl, 4 dwg

Description

The present invention relates to an electrical switching device with separable contacts.

Electrical switching devices with separable contacts, such as low voltage circuit breakers, generally include, for each pole, a fixed electrical contact and a movable electrical contact that can move relative to each other due to the switching mechanism to interrupt the flow of electrical current. Patent EP-2801099-B1 describes an example of a switching device.

A disadvantage of the known switching devices is that when the switching mechanism is actuated to separate the fixed and moving contacts in order to interrupt the electrical current, the moving contact may inadvertently close again as soon as it reaches the end of the opening stroke, for example due to uncontrolled rebound. one or more moving parts of the switching mechanism.

If the contacts are inadvertently closed again, electrical current may flow again while the device is presumably in the open state. This situation should be excluded for security reasons.

More specifically, it is precisely this disadvantage that the invention aims to overcome by providing an electrical switching device with separable contacts, in which the risk of accidental closing of the electrical contacts is reduced.

To this end, the invention relates to an electrical switching device with separable contacts, containing a switching device, including:

- a fixed electrical contact and a movable electrical contact that can move between a closed position and an open position;

- a control lever mechanically connected to a movable electrical contact, the control lever being rotatable, about a first axis of rotation, between a first position and a second position, wherein movement of the control lever from the first position to the second position causes the movable contact to move from a closed position to an open position;

- anti-rebound lever, which is mounted on the control lever by means of a pivot link and can rotate, thanks to the pivot link, about a second axis of rotation, parallel to the first axis of rotation, between the initial position and the open position.

The anti-rebound lever is positioned to move from the initial position to the open position when the control lever reaches the second position, and the anti-rebound lever is configured to engage the stop of the switching device when the anti-rebound lever is in the open position and when the control lever is in second position so as to prevent the control lever from moving out of the second position.

By positioning the center of gravity when the control arm is to stop in the second position during movement aimed at opening the moving contact, the angular momentum of the control arm is at least partially transferred to the anti-bounce arm, which then moves to the open position. Once fully released, the anti-bounce lever prevents the control lever from moving out of the second position, even if the control lever bounces off the stop. In this way, the risk of accidental closing of the moving contact is controlled. The operation of the device is therefore more reliable.

According to advantageous but optional aspects of the invention, such a switching device may include one or more of the following features, considered alone or in any technically acceptable combination:

the center of gravity of the anti-bounce arm is displaced relative to the pivot link in a direction outside the control arm relative to the path traveled by the pivot link when the control arm is moved to the second position from the first position;

- the center of gravity is aligned with the first straight line passing through the first axis of rotation and perpendicular to the second coplanar straight line passing through the rotary link, and the center of gravity is shifted in a direction outside the control lever relative to the second straight line;

the anti-bounce arm extends substantially in a geometric plane perpendicular to the first and second axes of rotation;

the anti-bounce arm includes one or more cavities;

the anti-bounce arm includes a first tab and a second tab that are mutually engaged by a central portion, wherein a pivot link between the anti-bounce arm and the control arm is formed in one of the tabs of the anti-bounce arm;

the control arm includes a first arm on which a pivot link for the anti-bounce arm is formed, and a second arm on which another pivot link is formed for a connecting part connected to the moving contact to provide a connection between the control arm and the moving contact, the first the arm and the second arm are perpendicular to the first axis of rotation and are rigidly connected to the control shaft of the device, running along the first axis of rotation;

- the stop is configured to limit the movement of the movement of the control lever between the first position and the second position;

- the stop is in contact with the second arm when the control lever is in the second position, and in contact with the first arm when the control lever is in the first position;

- the device is a multi-pole device including one or more additional switching devices similar to said switching device, and the device also includes a control shaft common to the switching devices to simultaneously control the movement of the corresponding control levers of the switching devices.

The invention should be better understood and other advantages should become more apparent on reading the following description of an embodiment of a switching device, given by way of example only and with reference to the accompanying drawings, in which:

Fig. 1 schematically shows a cross-sectional view of an electrical switching device according to embodiments of the invention, in which separable contacts are closed;

Fig. 2 schematically shows the device of FIG. 1, in which the shared contacts open;

Fig. 3 schematically shows the device of FIG. 1 in which the contacts to be shared are opened and in which the anti-rebound lever is moved to the open position;

Fig. 4 schematically shows an enlargement of FIG. 2.

Fig. 1-4 show an electrical switching device 2, such as a contactor or automatic circuit breaker, or a relay, for example, intended to be connected to a power distribution plant.

The device 2 includes a switching fixture 4 with shared contacts and a switching mechanism connected to the shared contacts of the fixture 4 to switch between open and closed states, for example in response to a trip command sent from the trip unit or from a control module.

In this example, only one pole of the device 2 is described. However, according to the implementation modes, the device 2 is a multi-pole device and includes several poles, including a device 4 similar to the device described. In this case, the description of device 4 can be projected onto the other poles of device 2.

For example, device 2 includes three or four poles, for connection to a three-phase installation. In other cases, device 2 may include one pole.

Device 4 includes a fixed electrical contact 6 and a movable electrical contact 8, which are connected to the corresponding connecting terminals of the device 2.

The moving contact 8 can move between a closed position and an open position with respect to the fixed contact 6 to permit and prevent, respectively, the flow of electric current between contacts 6 and 8.

For example, the movable contact 8 is rotatably mounted relative to the fixed support 10 of the tool 4 and moves between the open and closed positions by rotating about the rotation axis X8.

The moving contact 8 is illustrated in the closed position in FIG. 1 and in the open position in FIG. 2 and 3.

According to the examples, as illustrated in FIG. 2, fixture 4 includes electrically conductive pads 12 and 14 mounted on fixed contact 6 and moving contact 8, respectively.

For example, the movable contact 8 comprises one or more contact taps 16 pivotally mounted relative to the contact 8, with each contact tap 16 carrying one of the pads 14.

Device 4 additionally includes a setting lever 18 mechanically connected to a movable electrical contact 8.

The control lever 18 is rotatable about a rotation axis X18 parallel to the axis X8 between the first position and the second position.

The control lever 18 is in the first position in FIG. 1 and in the second position in FIG. 2, 3 and 4.

For example, moving the control lever 18 from the first position to the second position causes the moving contact 8 to move from the closed position to the open position.

On the other hand, moving the control lever 18 from the second position to the first position causes the moving contact 8 to move from the open position to the closed position.

In the illustrated example, the control arm 18 is movable with respect to the frame 20 of the device 2. The control arm 18 is mechanically connected to the movable contact 8 via a connecting piece 22, in this case having a rectilinear shape.

According to the examples, the connecting piece 22 is pivotally mounted with respect to the moving contact 8 by means of a first pivot link with axis X22 of rotation, and is also pivotally mounted relative to the control lever 18 by means of a second pivot link with axis X23. Axes X22 and X23 are parallel.

Other arrangements may be used to mechanically connect the control lever 18 to the moving contact 8.

The fixture 4 also includes a fixed stop 24, for example fixedly mounted on the frame 20, the role of which is explained below. For example, stop 24 includes a rigid protrusion or bar protruding from frame 20 by extending parallel to axis X18.

The fixture 4 also includes an anti-kickback arm 26 mounted to the control arm 18 via a pivot link. The anti-bounce arm 26 can be rotated, relative to the control arm 18, by the pivot link, around the rotation axis X26, between the home position, also called the retracted position, and the open position.

The axis X26 is integral with the control arm 18 and is parallel to the axis X18. In other words, the axis X26 and the corresponding swivel link move together with the control arm 18.

In the initial position, the anti-rebound arm 26 does not impede the movement of the control arm 18. For example, the anti-rebound arm 26 is then folded onto the body of the control arm 18.

The anti-kickback lever 26 is configured to engage the anvil 24 when the anti-kickback lever is in the open position and when the control lever 18 is in the second position, for example, to prevent the control lever 18 from moving out of the second position.

The anti-bounce lever 26 is further configured to move from the initial position to the open position when the control lever 18 reaches the second position at the end of the movement from the first position.

To this end, the fixture 4 is positioned such that the control arm 18 imparts at least a portion of the angular momentum to the anti-bounce arm 26 when the control arm 18 comes to the end of its stroke in the second position, such as when it hits the stop 24. Thus Thus, the anti-rebound lever 26 is opened in an automatic and rapid manner.

An example of the anti-bounce arm 26 will be described in more detail below with reference to FIG. 4.

Reference C1 denotes a circle that is superimposed on the path traveled by the pivot link with axis X26 between the anti-bounce arm 26 and the control arm 18 when the control arm 18 is moved between the first position and the second position.

Reference C2 indicates a circle that is superimposed on the path traversed by the center of gravity G26 of the anti-rebound lever 26 when the control lever 18 is moved between the first position and the second position and the anti-rebound lever 26 remains in its original position.

The paths associated with circles C1 and C2 have a circular arc shape. Circles C1 and C2 are concentric and coplanar.

According to embodiments, the center of gravity G26 of the anti-bounce arm 26 is displaced, relative to the pivot link with axis X26, in a direction outside the control arm 18.

More specifically, the center of gravity G26 is displaced in a direction outside the control arm 18 relative to the path traversed by the pivot link with the axis X26, this path being associated with the circle C1.

In other words, the center of gravity G26 is located outside the circumference C1. The radius of circle C2 is strictly greater than the radius of circle C1.

Outside of the control lever 18 in this case is given with respect to the axis X18. For example, an element described as being "outside" of the actuating arm 18 is further away from axis X18 than an element which is described as being placed "inside" of the control arm 18.

For example, the stop 24 is located outside the control lever 18.

In the illustrated example, the center of gravity G26 is aligned with the first straight line L1 passing through the axis X18 and perpendicular to the second coplanar straight line L2 passing through the pivot link with the axis X26. The center of gravity G26 is displaced in a direction outside the control lever 18 relative to the second straight line L2.

For example, the distance d between the second straight line L2 and the center of gravity G26, measured in parallel with the first straight line L1, is not equal to zero, for example, greater than or equal to 5% of the radius of the circle C1.

Preferably, the distance d2 (not illustrated) between the center of gravity G26 and the path C1, measured along the straight line L1, is non-zero, such as greater than or equal to 5% of the radius of the circle C1. The distance d2 corresponds to the difference between the radii of the circles C2 and C1.

According to the modes of implementation, the anti-bounce arm 26 extends substantially in a geometric plane perpendicular to the axes X18 and X26. For example, the anti-bounce arm 26 is flat. Alternatively, the anti-bounce arm 26 may have other shapes that are not necessarily flat, such as a rod connected to a weight.

In the illustrated example, the anti-bounce arm 26 has a flat and rounded shape and includes a first tab 40 and a second tab 42 interconnected by a central portion.

A pivot link with axis X26 between the anti-bounce arm 26 and the control arm 18 is, for example, formed in one of the blades of the anti-bounce arm 26, in this case the second blade 42.

Preferably, the anti-bounce arm 26 includes one or more cavities 44, 46. The cavities allow, in the manufacture of the anti-bounce arm 26, to precisely select the location of the center of gravity G26.

There are two illustrated petals 40, 42 in this case, and each of them has a round shape and different sizes. Alternatively, a different number of petals 40, 42 may be chosen and this is applicable to their shape and/or their dimensions and/or their location, depending on the intended location for the center of gravity G26.

In embodiments, the anti-bounce arm 26 is formed from a metallic material or from a polymeric material such as a thermosetting plastic material.

As a purely illustrative and not necessarily limiting example, the anti-bounce arm 26 weighs between 10 g and 30 g inclusive, for example 12 g.

According to the implementation modes, the control arm 18 forms part of a control shaft, also called a pole shaft, which is aligned with the X18 axis and can wrap around the X18 axis. The control shaft, for example, is connected to the release mechanism of fixture 2.

The control lever 18 is limited in such a way that it rotates with the shaft about the axis X18.

For example, the control arm 18 is formed by one or more control shaft cams.

In the illustrated example, control arm 18 includes two arms 30 and 32 perpendicular to axis X18 and rigidly connected to control shaft 34. Arms 30 and 32 protrude from shaft 34 in a direction outside of shaft 34.

The arms 30 and 32 in this case are substantially flat in shape and run in a geometric plane identical to that of the anti-bounce arm 26. In other words, the anti-bounce arm 26 and arms 30, 32 are flat in shape and are parallel to each other.

In the examples, the stop 24 limits the movement of the control arm 18 between the first position and the second position by coming into contact with the arms 30 and 32, for example, to block the rotation of the shaft 34.

More precisely, the stop 24 in this case is in contact with the shoulder 30 when the control lever 18 is in the second position to prevent the control lever 18 from continuing to move beyond the second position. The stop 24 is in contact with the shoulder 32 when the control lever 18 is in the first position to prevent the control lever 18 from rotating, in the opposite direction, beyond the first position. Alternatively, in the first position, the edge of the shoulder 32 may be extremely close to the anvil 24 without actually being in direct contact with the anvil 24.

Thus, in this example, the stop 24 is configured to limit the travel of the control lever 18 both between the first position and between the second position.

In the examples described, when the control lever 18 is in the second position and the anti-bounce lever 26 is fully disengaged, the arm 30 and the anti-bounce lever 26 are located on either side of the stop 24 in close proximity to the stop 24, or even in direct contact with the stop 24. Thus, movement of the control arm 18 (and thus the shaft 34) becomes impossible while the anti-bounce arm 26 remains in the open position.

In practice, the arm 30 and the anti-bounce arm 26 are not necessarily in direct contact with the stop 24 at all times, such that a slight travel movement near the second position may then be allowed for the control arm 18.

According to the modes of implementation, the pivot link engaging the part 22 to the control arm 18 is mounted on the arm 30. The pivot link engaging the control arm 18 to the anti-bounce arm 26 is mounted on the arm 32.

The arms 30 and 32 are in this case interlocked by means of a rounded section in the form of a circular arc centered on the axis X18. In the stowed position, the anti-bounce lever 26 overlaps the rounded portion, and the upper edge of the anti-bounce lever 26 is aligned with the outer edge of the rounded portion. The anti-rebound lever 26 then does not protrude from the rounded area, for example, so as not to impede the movement of the control lever 18 and the shaft 34.

According to alternatives, when the device 2 includes several poles, the control shaft is preferably common to the switching devices 4 of different poles, for example, to be able to simultaneously control the movement of the respective control levers 18 of these elements of the device 4.

For example, each pole of device 2 is associated with a dedicated compartment in the housing of device 2. The compartments are aligned side by side along axis X18. The control shaft passes through the transverse walls separating two adjacent compartments through dedicated through holes.

The following describes an example of the operation of the fixture 4 with reference to FIG. 1-3.

Initially, fixture 4 is in a closed state, as illustrated in FIG. 1. The conductive parts of pins 6 and 8 touch each other and electric current can flow.

The control lever 18 is in the first position. For example, the edge of the shoulder 32 is in contact with the stop 24 or extremely close to the stop 24, such as less than five millimeters from the stop 24. The anti-bounce arm 26 is in its rest position.

The switching mechanism is then disengaged to open the tool 4, i. e. separate pins 6 and 8 and interrupt the current.

To this end, the control arm 18 is rotated about the axis X18, for example by rotating the shaft 34 in the first direction of rotation, illustrated by the arrow F1 in FIG. 2. This movement is transmitted by means of the part 22 to the moving contact 8, which then wraps around the axis X8 in the second direction of rotation, illustrated by the arrow F2. At this stage, the anti-rebound lever 26 remains in its original position.

The rotary movement of the control lever 18 continues until the setting lever 18 reaches the second position, i.e. it does not arrive at the end of the stroke corresponding in this case to the position at which the shoulder 30 comes into contact with the stop 24, as illustrated in FIG. 2.

In practice, when the control lever 18 enters the second position at the end of the stroke, it can rebound due to its speed and then move in the opposite direction to the first position.

In the illustrated example, the arm 30 strikes the stop 24 as it enters the end of the stroke. In addition, in FIG. 3, the control lever 18 begins to move out of the second position, and the arm 30 begins to move slightly away from the stop 24.

However, the anti-return lever 26 simultaneously moves to the open position, in contact with the stop 24, and this prevents the control lever 18 from continuing to move away from the second position.

In fact, by positioning the center of gravity G26 of the anti-rebound lever 26 when the control lever 18 is to stop in the second position, the angular momentum of the control lever 18 is at least partially transferred to the anti-rebound lever 26, for example, when the control lever 18 collides with the stop 24 The anti-rebound lever 26 then moves to the open position.

For example, when the control arm 18 arrives at the end of the stroke, a moment proportional to the distance d is applied to the center of gravity G26 of the anti-bounce arm 26, as illustrated by arrow E26 in FIG. 4.

Once deployed, the anti-bounce lever 26 prevents the control lever 18 from leaving the second position by engaging the stop 24, even if the control lever 18 bounces off the stop and begins to move away from it, as in this case. The control lever 18 then remains near the second position. Contact 8 therefore cannot close by accident.

Thus, the risk of accidental closing of the moving contact 8 is reduced. The operation of the device 2 is therefore more reliable.

In particular, the movement of the anti-bounce lever 26 is independent of the rotation speed of the control lever 18. The risk of reopening of the contact 8 is thereby reduced, regardless of the circumstances in which the trip occurs, even when the control lever 18 is slowly moved.

In addition, the anti-bounce arm 26 can be integrated during the construction of the device 2 without having to completely modify the architecture of the device 4.

In practice, the anti-bounce lever 26 can then be moved back to its original position, for example, as soon as the control lever 18 stops in the second position. The return to the starting position can be achieved manually either through gravity or through an elastic return device such as a spring coupled to the anti-bounce lever 26.

The embodiments and alternatives provided above may be combined with each other to form new embodiments.

Claims (17)

1. Electric switching device (2) with separable contacts, containing a switching device (4), including: - a fixed electrical contact (6) and a movable electrical contact (8) which can move between a closed position and an open position; - a control lever (18) mechanically connected to a movable electrical contact (8), moreover, the control lever is rotatable, around the first axis (X18) of rotation, between the first position and the second position, and the movement of the control lever (18) from the first position to the second the position causes the moving contact (8) to move from the closed position to the open position; - anti-rebound lever (26), which is mounted on the control lever (18) by means of a swivel joint and can be rotated by means of a swivel joint about a second axis of rotation (X26) parallel to the first axis (X18) of rotation, between the initial position and the open position; moreover, anti-rebound lever (26) is placed so as to move from the original position to the open position when the control lever (18) reaches the second position; the anti-bounce lever (26) is configured to mate with the stop (24) of the switching device (4) when the anti-bounce lever (26) is in its open position and when the control lever (18) is in the second position, so as to prevent exit control lever (18) from the second position; the control lever (18) has a first arm (32) on which is formed a swivel connection with an anti-bounce lever (26), and a second arm (30) on which is formed another swivel connection with a connecting piece (22) attached to the moving contact ( 8) to provide a connection between the control lever (18) and the movable contact (8), wherein the first arm (32) and the second arm (30) are perpendicular to the first axis (X18) of rotation and are integral with the control shaft (34) of the device, running along the first axis (X18) of rotation; the first arm (30) and the second arm (32) are connected by a rounded section in the form of a circular arc, centered on the axis (X18) of rotation; in the initial folded position, the anti-kickback lever (26) overlaps the rounded area, and the top edge of the anti-kickback lever (26) is aligned with the outer edge of the rounded area so that the anti-kickback lever (26) does not protrude from the rounded area so as not to hinder the movement of the control lever (18) and control shaft (34); characterized in that the center of gravity (G26) of the anti-bounce arm (26) is displaced relative to the pivot link (X26) in a direction outside the control arm relative to the path (02) traversed by the pivot link (X26) when the control arm (18) moves into its the second position from the first position; and the fact that the center (G26) of gravity is aligned with the first straight line (L1) passing through the first axis (X18) of rotation and perpendicular to the second (30) straight line (L2), coplanar with the swivel joint (X26) and passing through the swivel joint (X26), wherein the center of gravity (G26) is displaced in a direction outside the control lever relative to the second straight line (L2). 2. Device according to any of the preceding claims, characterized in that the anti-bounce arm (26) extends substantially in a geometric plane perpendicular to the first and second axes (X18, X26) of rotation. 3. A device according to any one of the preceding claims, characterized in that the anti-bounce arm (26) comprises one or more cavities (44, 46). 4. Device according to any one of the preceding claims, characterized in that the anti-rebound lever (26) comprises a first protrusion (40) and a second protrusion (42), which are connected to each other by means of a central part, wherein the swivel connection between the anti-rebound lever and the control lever is formed in one of the protrusions of the anti-bounce lever. 5. Device according to any one of the preceding claims, characterized in that the stop (24) is adapted to limit the movement of the control lever (18) between the first position and the second position. 6. The device according to claim 5, characterized in that the stop (24) is in contact with the second arm (30) when the control lever (18) is in the second position, and in contact with the first arm (32) when the control lever (18) is in the first position. 7. The device according to any one of the preceding claims, characterized in that the device (2) is a multi-pole device containing one or more additional switching devices similar to said switching device (4), and the device also contains a control shaft (34) common to switching devices in order to simultaneously control the movement of the respective control levers (18) of the switching devices (4).

Images