CN215869245U - Shunt release - Google Patents

Abstract

The utility model discloses a shunt release, which comprises a shell, a load loop and a coil, wherein the coil is arranged on the shell; the coil terminal and the coil contact unit are both arranged on the shell; the coil contact unit, the coil and the coil terminal are connected to form a coil loop independent of the load loop. The shunt release has the advantages that the load loop and the coil loop are respectively powered by the independent power supply through the structural arrangement, an auxiliary contact is not required to be arranged outside, the cost is reduced, the safety is high, and the installation space is saved.

Description

Shunt release

Technical Field

The utility model relates to the technical field of electrical control, in particular to a shunt release.

Background

Shunt release is commonly used in remote control requiring forced cut-off of power supply, such as fire control to cut off non-fire power supply.

The shunt release comprises a coil loop and a load loop, the load loop and the coil loop of the existing common shunt release share one group of power supplies, but in practical application, in some specific environments, the coil loop part does not interfere with the requirement of the load loop, the structure has larger potential safety hazard, so that the coil loop and the load loop are required to use different power supplies, and at the moment, an independent auxiliary contact needs to be assembled beside the shunt release, so that the cost is increased, and the space of a distribution box is occupied.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a shunt release, which has the advantages that the load loop and the coil loop are respectively supplied with power by adopting independent power supplies due to the structural arrangement of the shunt release, no auxiliary contact is required to be arranged outside, the cost is reduced, the safety is high, and the installation space is saved.

In order to solve the technical problem, the utility model provides a shunt release, which comprises a shell, a load loop and a coil, wherein the coil is arranged on the shell; the coil terminal and the coil contact unit are both arranged on the shell; the coil contact unit, the coil and the coil terminal are connected to form a coil loop independent of the load loop.

According to the shunt release provided by the utility model, the coil binding post and the coil contact unit are additionally arranged in the shell, so that the coil, the coil binding post and the coil contact unit are connected to form a coil loop independent from a load loop, namely, the coil is not connected with a related binding post of the load loop any more, namely, the coil forms an independent loop and the load loop adopts an independent power supply to supply power, therefore, the coil cannot influence the load loop, the situation that an auxiliary contact is assembled at the side of the shunt release is avoided, and on the basis that the coil loop and the load loop adopt independent power supplies, the shunt release reduces the user cost, is high in safety and saves the installation space.

According to the shunt release, the coil contact unit comprises the coil fixed contact, the coil moving contact and two elastic sheets, and the coil fixed contact and the coil moving contact are respectively fixed at the end parts of the two elastic sheets; the coil is characterized in that the number of the coil binding posts is two, the two spring plates are respectively and electrically connected with one wiring point of the coil and one coil binding post, and the other wiring point of the coil is electrically connected with the other coil binding post.

The installation structure of the coil static contact and the coil moving contact is simple and reliable and is easy to implement.

In the shunt release, the shell is provided with two mounting seats for mounting the two spring plates respectively; the mounting base is provided with a clamping groove, and the elastic sheet is clamped and embedded in the clamping groove.

The elastic mounting piece is simple and reliable in structure, and the positions of the coil fixed contact or the movable contact can be conveniently replaced and adjusted according to needs.

As described above, the clamping groove includes two opposite groove walls, at least one of the two groove walls is provided with a convex portion, and the elastic piece is in interference fit with the clamping groove.

The structure can ensure the reliability of the installation of the elastic sheet.

According to the shunt release, the elastic sheet comprises a first section and a second section which are bent, and the contact is fixedly connected to one end of the first section, which is far away from the second section; the clamping groove is of a bent structure, and the joint of the first section and the second section is arranged in the clamping groove.

The structure can ensure the installation firmness of the elastic sheet and the installation seat and prevent the elastic sheet from separating from the installation seat.

In the shunt release, the elastic sheet fixedly connected with the coil fixed contact is a first elastic sheet, the elastic sheet fixedly connected with the coil movable contact is a second elastic sheet, and the first elastic sheet and the second elastic sheet are installed in a staggered manner.

The structure can ensure the action reliability of the second elastic sheet and ensure that the movable contact and the fixed contact of the coil which are arranged on the second elastic sheet can be reliably contacted or separated.

In the shunt release, the movable section of the elastic sheet fixedly connected with the coil moving contact has a bending structure.

The bending structure is arranged on the movable section of the elastic sheet fixedly connected with the coil moving contact, so that the flexibility of the elastic sheet can be improved, and the fatigue strength of the elastic sheet is improved.

In the shunt release, the curved structure is an arc-shaped arch bridge structure that is arched toward one side of the elastic piece.

The arch bridge structure bending structure is convenient to form, the flexibility of the elastic sheet can be effectively improved, and the fatigue strength of the elastic sheet is further improved.

The shunt release comprises a load terminal and a load contact unit connected with the load terminal; the load contact unit comprises two load static contacts and a load moving contact; the shunt release also comprises a transmission mechanism, and the transmission mechanism can synchronously drive the load moving contact and the coil moving contact to move so as to realize the conduction or the cut-off of the circuit.

Therefore, the load moving contact and the coil moving contact are synchronously pushed to act through the transmission mechanism, the additional arrangement of a transmission structure can be avoided, and the structure can be simplified.

The shunt release comprises a supporting piece, wherein the supporting piece is positioned between the load moving contact and the coil contact unit, one surface of the supporting piece is provided with two first columns, the other surface of the supporting piece is provided with a second column, and the two first columns clamp the elastic carrier of the load moving contact; the transmission mechanism drives the supporting piece to rotate during transmission, so that the first column pushes the load moving contact to move between the two load fixed contacts, and the second column pushes the elastic sheet provided with the coil moving contact to move towards the direction of the coil fixed contact or the second column is far away from the elastic sheet provided with the coil moving contact.

Drawings

Fig. 1 is a schematic structural diagram of a shunt release in a first state according to an embodiment of the present invention;

fig. 2 is a partially enlarged view of the coil contact unit of fig. 1;

fig. 3 is a schematic structural diagram of the shunt release in the second state according to the embodiment of the present invention;

fig. 4 is a schematic structural diagram of a housing of a shunt release in an embodiment of the present invention;

FIG. 5 is a partial enlarged view of portion A of FIG. 4;

FIG. 6 is a schematic structural diagram of a support member in an embodiment.

Description of reference numerals:

the housing 10, the first mounting seat 11A, the second mounting seat 11B, the card slot 111, and the convex portion 112;

the load terminal 21, the first load static contact 221, the second load static contact 222, the load moving contact 23, and the elastic carrier 231;

the coil 31, the coil terminal 32, the coil contact unit 33, the coil fixed contact 331, the coil movable contact 332, the first elastic sheet 333, the second elastic sheet 334, the arch bridge structure 3341 and the return spring 34;

the transmission mechanism 40, the supporting piece 41, the first column 411, the second column 412, the lock catch 42, the jump buckle 43 and the connecting rod 44;

a handle 50.

Detailed Description

In order that those skilled in the art will better understand the disclosure, the utility model will be described in further detail with reference to the accompanying drawings and specific embodiments.

Referring to fig. 1 to 3, fig. 1 is a schematic structural diagram of a shunt release in a first state according to an embodiment of the present invention; fig. 2 is a partially enlarged view of the coil contact unit of fig. 1; fig. 3 is a schematic structural diagram of the shunt release in the second state according to the embodiment of the present invention.

In this embodiment, the shunt release includes a housing 10, a load circuit and a coil circuit, wherein, a coil 31, a coil terminal 32 and a coil contact unit 33 are installed on the housing 10, and the coil 31, the coil terminal 32 and the coil contact unit 33 are connected to form a coil circuit independent of the load circuit, so that the coil circuit is irrelevant to the load circuit, and the coil 31 is no longer relevant to the terminal of the load circuit, that is, the coil circuit and the load circuit are respectively powered by two independent power supplies, so that the coil 31 does not affect the load circuit, and the condition that an auxiliary contact is assembled beside the shunt release to realize the respective power supply of the coil 31 and the load is avoided.

In this embodiment, the load circuit of the shunt release includes a load terminal 21, two load static contacts and a load moving contact 23, for convenience of description, the two load static contacts are referred to as a first load static contact 221 and a second load static contact 222, each component of the load circuit is disposed near one side of the housing 10 to facilitate line connection, and in the illustrated orientation, each component of the load circuit is disposed near the left side of the housing 10.

To utilize the existing space of the housing 10 and avoid enlarging the structure of the housing 10, the coil terminal 32 of the coil loop may be disposed opposite the load terminal 21, i.e., in the illustrated orientation, near the right side of the housing 10, and also facilitate the line connection with the coil 31 and the coil contact unit 33, avoiding interference with the load loop.

It can be understood that, because the coil 31 is no longer connected with the load terminal 21 by a line, compared with the existing shunt release, the number of the load terminals 21 of the shunt release can be reduced, and only the connection requirement of the load loop needs to be met, and the specific number and arrangement are subject to the requirement of the load loop.

The line connections between the components of the load circuit and the coil circuit are illustrated by thin solid lines in fig. 1, thick black solid lines in fig. 3, and thick gray solid lines in fig. 3, as can be understood. In practical applications, how to connect the lines of the loops can be determined according to practical application requirements.

In this embodiment, the coil contact unit 33 includes a coil fixed contact 331, a coil moving contact 332, and two spring pieces, the coil fixed contact 331 and the coil moving contact 332 are respectively fixed on the two spring pieces, and for convenience of description, the spring piece to which the coil fixed contact 331 is fixed is referred to as a first spring piece 333, the spring piece to which the coil moving contact 332 is fixed is referred to as a second spring piece 334, and the coil fixed contact 331 and the coil moving contact 332 are respectively mounted on the housing 10 through the first spring piece 333 and the second spring piece 334.

In the illustrated embodiment, the first elastic sheet 333 is electrically connected to one terminal of the coil 31, the other terminal of the coil 31 is electrically connected to the coil terminal 32, and the second elastic sheet 334 is electrically connected to the coil terminal 32, so as to form a loop. In practice, the specific connection mode of the loop can be adjusted according to the requirement.

In order to facilitate the closing and separating of the coil fixed contact 331 and the coil movable contact 332, the two contacts are respectively and fixedly connected to the ends of the two elastic sheets, and specifically, the contacts may be fixed to the elastic sheets in a riveting manner.

The shunt release further comprises a transmission mechanism 40 and a handle 50, wherein the transmission mechanism 40 is connected between the handle 50 and the coil 31, and normally, in normal operation, the coil 31 is not electrified, the coil fixed contact 331 and the coil movable contact 332 of the coil loop are closed, and the load movable contact 23 and the first load fixed contact 221 in the load loop are closed, as shown in fig. 1; when an abnormal condition occurs, the coil 31 is electrified, the armature is attracted, the transmission mechanism 40 operates under the action of the armature to drive the load moving contact 23 to operate to separate from the first load fixed contact 221 and close with the second load fixed contact 222, and the coil moving contact 332 is driven to operate to separate from the coil fixed contact 331 simultaneously, as shown in fig. 3. The rotatable handle 50 then returns the components through the transmission 40.

After the coil loops are independently arranged, in order to simplify the structure and avoid increasing the cost due to additional components, the shunt release may still use the original transmission mechanism 40, as shown in fig. 1, the transmission mechanism 40 includes a supporting member 41, a latch 42, a trip 43, and a connecting rod 44, the connection relationship between the components is the same as that of the existing one, and details are not repeated here, in order to enable the transmission mechanism 40 to synchronously move the coil moving contact 332 and the load moving contact 23, in this embodiment, the supporting member 41 of the transmission mechanism 40 is improved, other components of the transmission mechanism 40 are not changed, and only the improved structure of the supporting member 41 is described below.

Referring to fig. 6, fig. 6 is a schematic structural diagram of a supporting member in an embodiment.

It can be understood that, in order to enable the supporting member 41 to achieve the above effect during the operation, the coil contact unit 33 is disposed close to the contact in the load loop, the supporting member 41 is disposed between the elastic carrier 231 of the load moving contact 23 and the coil contact unit 33, specifically, the coil contact unit 33 is disposed below the supporting member 41, the elastic carrier 231 is disposed above the supporting member 41, two first columns 411 are disposed above the supporting member 41, and a second column 412 is disposed below the supporting member 41, that is, the first columns 411 and the second column 412 are disposed on two opposite surfaces of the supporting member 41, the two first columns 411 clamp the elastic carrier 231 of the load moving contact 23, and the second column 412 is disposed on the side of the second elastic sheet 334 away from the first elastic sheet 333.

In the view shown in fig. 1 to 3, the coil contact unit 33 is at least partially shielded by the support member 41, but for the sake of clarity of the synchronous driving action of the support member 41, the shielded portion is illustrated by a dotted line in fig. 1 and 2, and the coil contact 332 shielded by the support member 41 and the structure of the second column 412 below the support member 41 are illustrated by a relatively shallow line in fig. 3.

As shown in fig. 1 and fig. 2, in this state, one first column 411 of the supporting member 41 (i.e., the first column 411 close to the lower side of the paper surface in the drawing) pushes the load moving contact 23 and the first load fixed contact 221 to be closed, and the second column 412 of the supporting member 41 pushes the second elastic sheet 334 toward the first elastic sheet 333, so that the coil moving contact 332 and the coil fixed contact 331 are closed.

When an abnormal condition occurs, the coil 31 is energized, and the armature attracts and drives the transmission mechanism 40 to act, the support member 41 rotates counterclockwise (in the direction shown in the figure), the second column 412 moves in the direction away from the first elastic sheet 333 to separate from the second elastic sheet 334, the second elastic sheet 334 drives the coil moving contact 332 to move in the direction away from the coil stationary contact 331 under the action of the elastic force of the second elastic sheet 334, so as to achieve separation, meanwhile, the elastic carrier 231 drives the load moving contact 23 to move in the direction of the second load stationary contact 222 and close with the second load stationary contact 222 under the pushing of the first column 411 close to the upper side of the paper surface, as can be understood by combining fig. 1 and fig. 3, under the transmission action of the transmission mechanism 40, the handle 50 rotates counterclockwise.

After de-energizing coil 31, its armature can be reset by return spring 34.

Referring to fig. 4 and 5 together, fig. 4 is a schematic structural diagram of a housing of a shunt release according to an embodiment of the present invention; fig. 5 is a partially enlarged view of a portion a in fig. 4.

In this embodiment, the housing 10 is provided with two mounting seats at corresponding positions, respectively for mounting two spring pieces of the coil contact unit 33, for convenience of description, the two mounting seats are respectively referred to as a first mounting seat 11A and a second mounting seat 11B, the first mounting seat 11A is used for mounting the first spring piece 333, and the second mounting seat 11B is used for mounting the second spring piece 334. The first elastic sheet 333 and the second elastic sheet 334 are installed in a staggered manner, that is, a set distance is provided between the first elastic sheet and the second elastic sheet, so that a sufficient electrical gap is ensured, and voltage breakdown is avoided.

Specifically, first mount pad 11A and second mount pad 11B all are equipped with draw-in groove 111, and first shell fragment 333 and second shell fragment 334 inlay in draw-in groove 111 of first mount pad 11A draw-in groove 111 and second mount pad 11B respectively, set up like this, convenient equipment and change, also be convenient for adjust the position of two shell fragments, and then adjust the relative position of coil stationary contact 331 and coil movable contact 332, ensure that both can be closed.

In order to ensure that the elastic sheet is firmly installed, a convex part 112 protruding towards the other groove wall is arranged on at least one groove wall of the clamping groove 111, so that the elastic sheet can be installed in the clamping groove 111 in an interference manner.

The convex portions 112 of the locking grooves 111 may be provided in plural at intervals along the extending direction of the groove wall.

In this embodiment, in order to further improve the mounting firmness of the elastic pieces, the first elastic piece 333 and the second elastic piece 334 are both of a bent structure, and both include a bent first section and a bent second section, which can be understood as being substantially L-shaped structures or 7-shaped structures; referring to fig. 2, the coil fixed contact 331 is fixedly connected to an end of the longer first section of the first elastic sheet 333, the coil movable contact 332 is fixedly connected to an end of the longer first section of the second elastic sheet 334, a bent portion of the first elastic sheet 333 (i.e., a junction between the first section and the second section of the first elastic sheet 333) is installed in the slot 111 of the first installation seat 11A, and a bent portion of the second elastic sheet 334 (i.e., a junction between the first section and the second section of the second elastic sheet 334) is installed in the slot 111 of the second installation seat 11B.

In this way, the first elastic sheet 333 is not affected by the actions of other components, and generally the position of the first elastic sheet 333 is not changed, and the longer first section of the second elastic sheet 334 is equivalent to being in a suspended state, and can approach the first elastic sheet 333 under the pushing of the second column 412 of the supporting member 41, and can be reset under the action of the elastic force of the first elastic sheet after the pushing disappears.

In this embodiment, the movable section, i.e., the suspended portion, of the second elastic piece 334 has a bending structure, so that the flexibility of the second elastic piece 334 can be increased, the fatigue strength thereof can be improved, and the service life thereof can be prolonged.

Specifically, as shown in fig. 3, the curved structure is specifically an arch bridge structure 3341 in the shape of an arc that is arched to one side, and it is understood that the arch bridge structure 3341 may have other shapes when actually installed. In other embodiments, the curved structure may also be in the form of a wavy line that bends back and forth or in other forms as long as the flexibility of the second elastic piece 334 can be improved.

The shunt release provided by the utility model is described in detail above. The principles and embodiments of the present invention are explained herein using specific examples, which are presented only to assist in understanding the method and its core concepts. It should be noted that, for those skilled in the art, it is possible to make various improvements and modifications to the present invention without departing from the principle of the present invention, and those improvements and modifications also fall within the scope of the claims of the present invention.

Claims (10)

1. The shunt release comprises a shell, a load loop and a coil, wherein the coil is arranged on the shell; the coil connector is characterized by further comprising a coil wiring terminal and a coil contact unit, wherein the coil wiring terminal and the coil contact unit are both arranged on the shell; the coil contact unit, the coil and the coil terminal are connected to form a coil loop independent of the load loop.

2. The shunt release of claim 1, wherein said coil contact unit comprises a coil stationary contact, a coil moving contact and two resilient pieces, said coil stationary contact and said coil moving contact being fixed to ends of said two resilient pieces, respectively; the two spring plates are respectively and electrically connected with one wiring point of the coil and the coil wiring terminal, and the other wiring point of the coil is electrically connected with the coil wiring terminal.

3. The shunt release of claim 2, wherein the housing has two mounting seats for mounting the two resilient pieces; the mounting base is provided with a clamping groove, and the elastic sheet is clamped and embedded in the clamping groove.

4. The shunt release of claim 3, wherein the locking groove comprises two opposing groove walls, at least one of the two groove walls having a protrusion, the spring plate having an interference fit with the locking groove.

5. The shunt release of claim 3, wherein the spring plate comprises a first bent section and a second bent section, and the contact is fixedly connected to one end of the first section, which is far away from the second section; the clamping groove is of a bent structure, and the joint of the first section and the second section is arranged in the clamping groove.

6. The shunt release of claim 5, wherein the spring plate to which the coil fixed contact is fixed is a first spring plate, the spring plate to which the coil movable contact is fixed is a second spring plate, and the first spring plate and the second spring plate are installed in a staggered manner.

7. The shunt release of claim 2, wherein the movable section of the spring plate to which the moving coil contact is fixed has a bent structure.

8. The shunt release of claim 7, wherein said flexure structure is an arched bridge structure that arches a circular arc to one side of said leaf spring.

9. The shunt release of any one of claims 2 to 8, wherein the load circuit comprises a load terminal and a load contact unit connected to the load terminal; the load contact unit comprises two load static contacts and a load moving contact; the shunt release also comprises a transmission mechanism, and the transmission mechanism can synchronously drive the load moving contact and the coil moving contact to move so as to realize the conduction or the cut-off of the circuit.

10. The shunt release of claim 9, wherein said actuator comprises a support member, said support member being disposed between said load moving contact and said coil contact unit, said support member having two first posts on one side thereof and a second post on the other side thereof, said two first posts sandwiching said resilient carrier of said load moving contact; the transmission mechanism drives the supporting piece to rotate during transmission, so that the first column pushes the load moving contact to move between the two load fixed contacts, and the second column pushes the elastic sheet provided with the coil moving contact to move towards the direction of the coil fixed contact or the second column is far away from the elastic sheet provided with the coil moving contact.

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