CN218039075U - Plug-in circuit breaker - Google Patents

Abstract

The utility model provides a plug-in circuit breaker, which comprises an empty shell, a PCB circuit board, an MCU singlechip, a transmission plate, a reset torsion spring, a static contact, a contact system, a first connecting rod, a micro switch and a solid-state switch; the transmission plate is positioned in the shell; the transmission plate is sleeved outside the shaft rod and can rotate around the shaft rod under the action of external force; the reset torsion spring is sleeved outside the shaft lever; the static contact is arranged in the shell and positioned on the right side of the sliding chute; the contact system is arranged in the shell and can do linear motion in the shell, so that the contact system is contacted with or separated from the static contact; two ends of the first connecting rod are respectively and rotatably connected to the transmission plate and the contact system; the micro switch is arranged on the PCB and linked with the contact system; the solid state switch is mounted within the housing. The utility model discloses a switching mechanism divide-shut brake is different with the mechanism of traditional switch, does not have traditional switching mechanism's hasp, jumps the fastener, and mechanism structure is simple, and the wearing and tearing of mechanism divide-shut brake, dropout are minimum or do not have, and the mechanical life of switch is better, and whole mechanism performance is more reliable.

Description

Plug-in circuit breaker

Technical Field

The utility model belongs to the technical field of low-voltage apparatus, concretely relates to plug-in circuit breaker.

Background

The traditional plug-in circuit breaker is complex in mechanism, many in related parts, high in requirements on the size and process of the parts, large in required internal space, easy to break down and low in reliability. And the traditional breaker is broken under the condition of larger short-circuit current, has larger electric arc and is limited in application scene. Therefore, in order to solve the existing situation, a new circuit breaker needs to be designed, the energy generated by connection and disconnection is carried through the solid-state switch, and the mechanical switch of the circuit breaker body is only used for isolation and does not need to carry the energy generated by connection and disconnection.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model aims to provide a plug-in circuit breaker with simple structure, longer service life and more reliable performance.

The utility model aims at realizing through the following technical scheme:

a plug-in circuit breaker comprises a hollow shell serving as a bearing base body, a transmission plate, a reset torsion spring, a static contact, a contact system and a first connecting rod; a sliding groove which is transversely arranged and a shaft lever which is vertically arranged in the shell are arranged in the shell; the shaft lever is positioned on the left side of the sliding groove; the transmission plate is positioned in the shell, a first through hole and a second through hole are formed in the transmission plate, and the second through hole is positioned on the right side of the first through hole; the transmission plate is sleeved outside the shaft rod through the first through hole and can rotate around the shaft rod under the action of external force; the reset torsion spring is sleeved outside the shaft lever and is provided with two rotating arms, the rotating arm on the left side of the reset torsion spring is clamped on the inner wall of the shell, and the rotating arm on the right side of the reset torsion spring is clamped on the transmission plate; the static contact is arranged in the shell and positioned on the right side of the sliding chute; the contact system is arranged in the chute and can do linear motion along the chute, so that the contact system is contacted with or separated from the fixed contact; the left end of the first connecting rod is rotatably connected in the second through hole, and the right end of the first connecting rod is rotatably connected to the contact system; when the contact system is contacted with the fixed contact, the right rotating arm of the reset torsion spring approaches to the left rotating arm of the reset torsion spring, and the reset torsion spring stores energy; when the contact system is separated from the static contact, the reset torsion spring releases energy, and the right rotating arm of the reset torsion spring opens rightwards and pushes the transmission plate to rotate clockwise.

Further, the device also comprises a PCB circuit board arranged in the shell, an MCU singlechip arranged on the PCB circuit board, a microswitch and a solid-state switch; the micro switch is arranged on the PCB and positioned on the right side of the contact system, and is linked with the contact system and used for sending a switching-on/off signal to the MCU singlechip; and the solid-state switch is arranged in the shell and used for being switched on or switched off under the control of the MCU singlechip, so that the plug-in circuit breaker is switched on or switched off.

Further, the first through hole (or shaft) is collinear with the sliding groove.

Furthermore, the contact system comprises a contact support, a moving contact, a contact spring and a poke rod; the contact support is slidably arranged in the sliding groove and can do linear motion along the sliding groove, the bottom of the contact support is concave upwards to form a transverse installation groove, and a connecting hole is formed in the left side of the contact support; the connecting hole is rotatably connected with the right end of the first connecting rod; the moving contact is arranged in the mounting groove in a sliding manner, the right end of the moving contact extends out of the mounting groove, and the moving contact can move linearly towards the direction close to or far away from the static contact under the driving of the contact support, so that the moving contact is attached to or separated from the static contact; the contact spring is arranged in the mounting groove and sleeved on the left end of the moving contact, the left end of the contact spring is propped against the contact support, and the right end of the contact spring is propped against the left side of the moving contact; the left end of the poke rod is fixed on the contact support, and the right end of the poke rod is linked with the microswitch; when the contact support slides along the sliding groove, the poke rod is driven to slide left and right, the poke rod is enabled to touch the contact of the micro switch, the micro switch sends a brake-separating signal or a switch-on signal to the MCU singlechip, and the MCU singlechip controls the solid-state switch to be switched on or switched off.

Further, when the first through hole, the second through hole, the first connecting rod and the moving contact are collinear, the moving contact and the static contact are in mutual contact, the reset torsion spring and the contact spring are in an energy storage state, at the moment, if the driving plate continues to rotate anticlockwise under the action of external force, the first connecting rod contact is pulled to support and slide towards the direction far away from the static contact, the second through hole is made to move to the position above the first through hole and the chute, the reset torsion spring and the contact spring are still in a compression state at the moment, meanwhile, the reset torsion spring and the contact spring both apply a pushing force to the driving plate, the direction of a moment applied to the driving plate by the contact spring is opposite to the direction of a moment applied to the driving plate by the reset torsion spring, the moment applied to the driving plate by the contact spring is larger than the moment applied to the driving plate by the reset torsion spring, after the external force disappears, the driving plate continues to rotate anticlockwise under the action of the contact spring, and meanwhile, the moving contact continues to be in contact with the static contact under the action of the contact spring.

Further, be equipped with in the shell with the driving plate locking in order to prevent that the driving plate from excessively carrying out anticlockwise pivoted protruding muscle under the contact spring promotes.

Furthermore, a limiting groove is symmetrically arranged on the front side and the rear side of the mounting groove supported by the contact; and the movable contact is provided with a limiting bulge which can slide left and right in the limiting groove corresponding to the two limiting grooves.

Furthermore, in order to ensure that the MCU singlechip can control the opening of the circuit breaker under the conditions of overload, short circuit, overvoltage, undervoltage and the like, the plug-in circuit breaker further comprises a release, wherein the release comprises a shell, a movable iron core, a static iron core, a coil, an ejector rod and a reset spring; the shell is arranged in the shell, the left end of the shell is opened, the opening faces to the transmission plate (the right lower end), and the shell is cylindrical; the static iron core is a cylinder fixed on the left side in the shell and communicated with the opening of the shell; the movable iron core is a cylinder body which is arranged on the right side in the shell and can slide in the shell; the coil is wound outside the shell and can be powered on or powered off under the control of the MCU singlechip. Two ends of the coil are connected to the relay, the relay is installed in the shell and is switched on and off under the MCU, so that the coil is powered on or off; the ejector rod is positioned in the shell, two ends of the ejector rod are respectively sleeved in the movable iron core and the static iron core and can move left and right in the static iron core, and the right end of the ejector rod is fixed in the movable iron core and can move back and forth under the driving of the movable iron core; the reset spring is sleeved outside the ejector rod and positioned between the movable iron core and the static iron core, and the diameter of the reset spring is larger than the inner diameter of the movable iron core; after the coil is electrified, the movable iron core and the static iron core generate magnetic force which is mutually attracted, the movable iron core overcomes the elasticity of the reset spring and moves towards the direction of the static iron core and pushes the ejector rod to extend out of the shell leftwards, and then the transmission plate is pushed to rotate clockwise, so that the plug-in circuit breaker is tripped and opened; after the coil is powered off, the movable iron core and the static iron core lose magnetic force, and the movable iron core can move towards the direction away from the static iron core under the action of the reset spring and drive the ejector rod to retract into the shell again.

Further, the structure of driving the transmission plate to switch on or switch off is as follows: the plug-in circuit breaker further comprises a handle and a second connecting rod; the left end of the handle is positioned outside the shell, and the right end of the handle is slidably arranged in the shell and can do linear motion in the shell; and two ends of the second connecting rod are respectively and rotatably connected to the right lower part of the handle and the left lower part of the transmission plate.

Furthermore, the mistaken closing of the plug-in type circuit breaker before the plug-in type circuit breaker is inserted into the cabinet is prevented; the plug-in circuit breaker further comprises an anti-false switching-on mechanism, wherein the anti-false switching-on mechanism comprises a through hole, a pin rod, a connecting rod, a buckle, a first locking hook, a second locking hook and a locking torsion spring; the through hole is arranged on the shell and is positioned above the shaft lever; the pin rod is vertically arranged in the shell and is positioned at the left side of the through hole; the left end of the connecting rod is rotatably arranged outside the pin rod; the buckle is fixed at the right end of the connecting rod and extends out of the shell from the through hole, and the left side surface of the buckle is an inclined surface and can be pressed into the shell under the action of external force to drive the connecting rod to rotate clockwise; the first lock hook is fixed at the left end of the connecting rod, and the hook surface of the first lock hook faces upwards; the second lock hook is fixed on the transmission plate, the hook surface of the second lock hook faces downwards, and the second lock hook is positioned on the upper side of the first lock hook and matched with the first lock hook; the locking torsion spring is sleeved on the pin rod and is also provided with two rotating arms, the left rotating arm of the locking torsion spring is clamped on the shell, and the right rotating arm of the locking torsion spring is clamped on the buckle; before the plug-in circuit breaker is not inserted into the cabinet, the buckle extends out of the through hole, the connecting rod is tightly attached to the inner side surface of the shell under the action of the locking torsion spring, the second lock hook and the first lock hook are mutually buckled, and the driving plate is difficult to rotate anticlockwise under the action of external force and drives the moving contact system to move rightwards through the first connecting rod to be switched on; after the plug-in circuit breaker is inserted into the cabinet, the buckle is pressed into the shell by the cabinet and drives the connecting rod to rotate clockwise, the first lock hook is driven to rotate clockwise and is separated from the buckle with the second lock hook, and the transmission plate is in a state capable of rotating freely.

The utility model has the advantages that:

the utility model discloses a switching mechanism divide-shut brake is different with the mechanism of traditional switch, does not have traditional switching mechanism's hasp, jumps the fastener, and mechanism structure is simple, and the wearing and tearing of mechanism divide-shut brake, dropout are minimum or do not have, and the mechanical life of switch is better, and whole mechanism performance is more reliable.

Drawings

The present invention will be described in further detail with reference to the accompanying drawings.

Fig. 1 is a schematic structural view of the plug-in circuit breaker of the present invention in an open state;

fig. 2 is a schematic structural view of the plug-in circuit breaker of the present invention in which the first through hole, the second through hole and the contact system are collinear;

fig. 3 is a schematic structural diagram of the plug-in circuit breaker of the present invention in a closing state;

fig. 4 is a partial structural view of a housing of the plug-in circuit breaker of the present invention;

fig. 5 is a diagram illustrating an installation state of a connection board in a housing of the plug-in circuit breaker according to the present invention;

fig. 6 is a schematic structural diagram of a connecting plate in the plug-in circuit breaker of the present invention;

fig. 7 is a schematic structural diagram of a contact system in the plug-in circuit breaker according to the present invention;

fig. 8 is a schematic structural diagram of a release in the plug-in circuit breaker according to the present invention;

FIG. 9 isbase:Sub>A cross-sectional view taken along line A-A of FIG. 8;

fig. 10 is an installation schematic diagram of the mis-closing prevention structure in the plug-in circuit breaker according to the present invention;

FIG. 11 is an enlarged view of a portion of FIG. 10 at B;

shown in the figure: the device comprises a shell 1, a handle 2, a second connecting rod 3, an anti-misoperation closing mechanism 4, a transmission plate 5, a first connecting rod 6, a release 7, a contact system 8, a static contact 9, a microswitch 10 and a reset torsion spring 11.

Detailed Description

The following description is provided for illustrative purposes, and other advantages and features of the present invention will become apparent to those skilled in the art from the following detailed description.

It should be understood that the drawings of the present application are only used to match the contents disclosed in the specification, so as to be known and read by those skilled in the art, and not to limit the practical limitations of the present invention, so that the present application does not have any technical significance, and any modification of the structure, change of the ratio relationship, or adjustment of the size should still fall within the scope of the present application without affecting the function and the achievable purpose of the present application. Meanwhile, the terms such as "upper", "lower", "left", "right", "middle", and the like used in the present specification are for convenience of description, and are not intended to limit the scope of the present invention, and changes or adjustments of the relative relationship thereof may be considered as the scope of the present invention without substantial changes in the technical content.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" should be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The first embodiment is as follows:

as shown in fig. 1-7, the utility model discloses a plug-in circuit breaker, including shell 1, PCB circuit board, MCU singlechip, driving plate 5, reset torsion spring 11, static contact 9, contact system 8, first connecting rod 6, micro-gap switch 10, solid state switch, handle 2, second connecting rod 3.

As shown in fig. 1-4, the housing 1 is a carrying base for each component inside the circuit breaker, and the inside of the housing is hollow, and a sliding groove 1a transversely arranged and a shaft rod 5a vertically arranged in the housing 1 are arranged in the housing 1; the shaft 5a is located on the left side of the chute 1a (and is arranged on the same straight line of the inner wall of the housing 1 together with the chute 1 a). As shown in fig. 5, a rib 1b for locking the transmission plate 5 to prevent the transmission plate 5 from excessively rotating counterclockwise by being pushed by the contact spring 8c is provided in the housing 1.

The PCB is arranged in the shell 1 and is used as a carrier of each control circuit and electrical appliance element.

The MCU singlechip is arranged on the PCB circuit board and used as a control core, and a conventional singlechip is selected.

As shown in fig. 1-3 and fig. 6, the transmission plate 5 is located in the housing 1, the transmission plate 5 is provided with a first through hole 5c, a second through hole 5d, and a third through hole 5e (as shown in fig. 6), the first through hole 5c is located on the upper left side of the transmission plate 5, the second through hole 5d is located on the right side of the first through hole 5c, and the third through hole 5e is located on the lower left side of the transmission plate 5; the transmission plate 5e is sleeved outside the shaft rod 5a through the first through hole 5c and can rotate around the shaft rod 5a under the action of external force (as shown in figures 1-3, when the breaker is switched on, the transmission plate 5 rotates anticlockwise, and when the breaker is switched off, the transmission plate 5 rotates clockwise); said first through hole 5c (or shaft 5 a) is collinear with the chute 1 a.

As shown in fig. 1 and 5, the reset torsion spring 11 is sleeved outside the shaft rod 5a and has two rotating arms, the rotating arm on the left side (the side close to the handle 2) is clamped on the inner wall of the housing 1, and the rotating arm on the right side (the side close to the contact system 8) is clamped on the transmission plate 5; the moment applied to the driving plate 5 by the reset torsion spring 11 always faces the opening direction of the circuit breaker.

As shown in fig. 1 and 3, the stationary contact 9 is disposed in the housing 1 and located at the right side of the sliding chute 1a, and the contact point of the left side wall thereof is collinear with the sliding chute 1 a.

As shown in fig. 2, the contact system 8 is installed in the chute 1a and can move linearly along the chute 1a, so that the contact system 8 is in contact with or separated from the fixed contact 9; as shown in fig. 7, the contact system 8 includes a contact support 8a, a movable contact 8b, a contact spring 8c, and a poker rod 8d.

The contact support 8a is slidably mounted in the chute 1a and can move linearly along the chute 1a (the contact support 8a is a strip-shaped plate), the bottom of the contact support 8a is concave to form a mounting groove 8e which is transversely arranged (arranged along the connecting line direction of the contact point of the shaft rod 5a and the static contact 9), and the left side of the contact support 8a is provided with a connecting hole; the connecting hole is rotatably connected with the right end of the first connecting rod 6. A limiting groove 8f is symmetrically arranged at the front side and the rear side of the mounting groove 8e of the contact support 8a respectively.

The movable contact 8b is slidably mounted in the mounting groove 8e, and the right end of the movable contact extends out of the mounting groove 8e (the right side of the movable contact is in sliding fit with the mounting groove 8e, and the left side of the movable contact is thinned into a long strip shape or a rod shape), and the movable contact 8b can move linearly towards a direction close to or far away from the static contact 9 under the driving of the contact support 8a, so that the movable contact can be attached to or detached from the static contact. A limit bulge 8g which can slide left and right in the limit groove 8f is respectively arranged on the moving contact 8a (right side) corresponding to the two limit grooves 8f, when the moving contact 8b is in contact with the static contact 9 before the moving contact is contacted, the limit bulge 8g is kept in contact with the right side of the limit groove 8f under the action of the contact spring 8c, and when the contact support 8a continuously moves over the distance to the right, the left side of the limit groove 8f also continuously moves towards the limit bulge 8 g. Definition of over travel: that is, when the switch is closed, since the reliability of the contact of the mechanical contact (the movable contact 8b and the fixed contact 9) is ensured, the contact support 8a continues to move rightward by a proper distance, and the mechanical contact can be reliably contacted even if the contact is worn.

The contact spring 8c is installed in the installation groove 8e and sleeved on the rod-shaped body at the left end of the moving contact 8b, the left end of the contact spring 8c is propped against the contact support 8a, the right end of the contact spring is propped against the left side of the moving contact 8b, when the moving contact 8b is contacted with the static contact 9, the contact support 8a moves rightwards continuously, the contact support 8a and the static contact 9 act together to push the moving contact 8b to compress the contact spring 8c, and the contact spring 8c stores energy.

The left end of the poke rod 8d is fixed on the contact support 8a (fixed on the right side of the top of the contact support 8a and corresponding to the position of the microswitch 10), and the right end thereof is linked with the microswitch 10; when the contact support 8a slides along the sliding groove 1a, the contact support 8a drives the poke rod 8d to slide left and right, so that the poke rod 8d touches the contact of the micro switch 10, the micro switch 10 further sends a brake-separating signal or a switch-on signal to the MCU singlechip, and the MCU singlechip controls the solid-state switch to be switched on or switched off.

As shown in fig. 1-3, the first link 6 is pivotally connected at its left end to the second through hole 5d of the connecting plate 5 and at its right end to the connecting hole of the contact support 8 a.

As shown in fig. 1 and 3, the micro switch 10 is mounted on the PCB and located on the right side of the contact system 8, and the micro switch 10 is linked with the contact system 8 and used for sending the switching-on/off signal to the MCU single chip.

The solid-state switch (such as a relay) is arranged in the shell 1 (two connection positions of the solid-state switch are respectively connected with the wire inlet end and the wire outlet end of the circuit breaker) and is used for switching on or off the wire inlet end and the wire outlet end of the circuit breaker under the control of the MCU singlechip so as to switch on or switch off the plug-in circuit breaker.

When the moving contact 8b of the contact system 8 is contacted with the static contact 9, the right rotating arm of the reset torsion spring 11 approaches to the left rotating arm thereof, and the reset torsion spring 11 stores energy; when the contact system 8 is separated from the static contact 9, the reset torsion spring 11 releases energy, and the right rotating arm of the reset torsion spring 11 opens rightwards and pushes the transmission plate 5 to rotate clockwise.

As shown in fig. 1-3, the left end of the handle 2 is located outside the housing 1, and the right end thereof is slidably mounted in the housing 1 and can move linearly in the housing 1, and the driving plate 5 can be pushed to rotate counterclockwise or clockwise by pushing and pulling the handle 2.

As shown in fig. 1-3, two ends of the second connecting rod 3 are respectively rotatably connected to the right lower portion of the handle 2 and the third through hole 5e at the left lower portion of the transmission plate 5. The first connecting rod 6 and the second connecting rod 3 are both U-shaped rods.

When the first through hole 5c, the second through hole 5d, the first connecting rod 6 and the moving contact 8b are collinear, the moving contact 8b and the static contact 9 are in mutual contact, the reset torsion spring 11 and the contact spring 8c are in an energy storage state, at this time, if the driving plate 5 continues to rotate anticlockwise under the action of external force, the contact support 8a of the first connecting rod 6 is pulled to slide towards the direction away from the static contact 9, the second through hole 8d is moved to the position above the first through hole 8c and the sliding groove 1a, the reset torsion spring 11 and the contact spring 8c are still in a compression state, meanwhile, the reset torsion spring 11 (compression) and the contact spring 8c (reset torsion spring 11) both apply a pushing force to the driving plate 5, the torque applied to the driving plate 5 by the contact spring 8c is opposite to the torque applied to the driving plate 5 by the reset torsion spring 11, the torque applied to the driving plate 6 by the contact spring 8c is larger than the torque applied to the driving plate 5 by the reset torsion spring 11, and after the external force disappears, the moving contact plate 5 continues to rotate under the action of the contact spring 8b and the static contact 9 c continue to contact.

The working principle is as follows:

manual closing:

as shown in fig. 1, the circuit breaker is in an open state, and the handle 2 is pressed down at the moment to link the second connecting rod 3, the transmission plate 5, the first connecting rod 6 and the contact system 8, and the contact system 8 moves linearly to the right in the chute 1a of the housing 1, so that the circuit breaker is switched on.

The method comprises the following specific steps: starting from the opening state shown in fig. 1, the handle 2 is pressed to slide rightwards, the transmission plate 5 is pushed to rotate anticlockwise around the shaft rod 5a through the second connecting rod 3, the transmission plate 5 rotates and drives the contact system 8 to move rightwards through the first connecting rod 6, and when the transmission plate 5 moves to the first through hole 5c (or the shaft rod 5 a), the second through hole 5d, the first connecting rod 6 and the contact system 8 are collinear (as shown in fig. 2), the movable contact 8b and the static contact 9 are closed (contacted) and are in a compressed state at the moment, but the mechanism is not locked; the handle 2 is continuously pressed down, so that the transmission plate 5 continuously rotates anticlockwise and drives the left end of the first connecting rod 6 to move upwards, the contact support 8a is pulled to move leftwards (the movable contact 8b does not move any more at the contact spring 8c and is kept in contact with the fixed contact 9), the contact spring 8c releases energy and extends (a leftward thrust is applied to the transmission plate 5), the reset torsion spring 11 compresses and stores energy, after the transmission plate 5 rotates to a certain position (at the moment, the second through hole 8d is higher than the first through hole 8c and the contact system 8), the moment applied to the transmission plate 5 by the contact spring 8c is larger than the moment applied to the transmission plate 5 by the reset torsion spring 11 (the directions of the two moments are opposite), at the moment, the force application by the handle 2 is not required to be pressed again in the closing process, the handle 2 is stopped to be pressed, the contact spring 8c further releases energy and extends, the contact support 8a is pushed to further move leftwards, the transmission plate 5 is further pushed by the first connecting rod 6 to rotate anticlockwise until the transmission plate 5 is locked on the convex rib 1b of the shell 1, and the movable contact 8c is also pushed rightwards to be kept in reliable contact with the fixed contact, and the circuit breaker 9 (at the moment, as shown in a reliable closing diagram 3).

In addition, before the moving contact 8b is closed (contacted) with the static contact 9, the poke rod 8d already pokes the micro switch 10 (as shown in fig. 3), the micro switch 10 sends a closing signal to the MCU singlechip, and the MCU singlechip delays to control the solid-state switch to be turned on until the moving contact 8b is closed (contacted) with the static contact 9, and then triggers the electronic solid-state switch to be turned on.

Manual brake opening:

as shown in fig. 3, the circuit breaker is in a closing state, and at this time, the handle 2 is pulled to link the second connecting rod 3, the transmission plate 5, the first connecting rod 6 and the contact system 8, and the contact system 8 linearly moves leftwards in the chute 1a of the housing 1, so that the circuit breaker is opened.

The method comprises the following specific steps: starting from the closing state shown in fig. 3, the handle 2 is pulled to slide left, the transmission plate 5 is pulled to rotate clockwise around the shaft 5a through the second connecting rod 3, the transmission plate 5 rotates while pushing the contact system 8 to move right through the first connecting rod 6, when the transmission plate 5 moves to the first through hole 5c (or the shaft 5 a), the second through hole 5d, the first connecting rod 6 and the contact system 8 are collinear, the moving contact 8b keeps in contact with the fixed contact 9, the reset torsion spring 11 and the contact spring 8c are still in a compressed state, but the moment exerted on the transmission plate 5 by the contact spring 8c is smaller than the moment exerted on the transmission plate 5 by the reset torsion spring 11 (the two moments are opposite in direction), the moment exerted on the transmission plate 5 by the contact spring 8c does not have an effect of stopping the transmission plate 5 from moving, as the moment exerted on the transmission plate 5 by the reset torsion spring 11 is always a moment in the opening direction, the handle 2 is pulled continuously, and the moment exerted on the reset torsion spring 11 further acts on the transmission plate 5 to further push the transmission plate 5 to rotate clockwise (the transmission plate 6 moves down and pulls the contact system 8 to move, so that the contact system 8 is separated from the opening contact with the left contact 9 b, as shown in the breaker (as shown in fig. 1).

In addition, before the moving contact 8b is separated from the static contact 9, the poke rod 8d already pokes the microswitch 10, the microswitch 10 sends a brake-separating signal to the MCU singlechip, the MCU singlechip controls the solid-state switch to be disconnected, and after the electronic solid-state switch is triggered to be disconnected, the moving contact 8b is completely separated from the static contact 9.

Example two:

the difference between this embodiment and the first embodiment is:

in order to ensure that the plug-in circuit breaker can automatically open when in overload, short circuit, overvoltage and undervoltage conditions, the plug-in circuit breaker further comprises a release 7 as shown in fig. 1-3. As shown in fig. 8 and 9, the trip unit 7 includes a housing 7a, a movable iron core 7b, a stationary iron core 7e, a coil 7d, a push rod 7f, a return spring 7c, and the stationary iron core 7e, which are all made of soft iron or silicon steel.

The housing 7a is installed in the housing 1, and the left end of the housing 7a is open and faces the transmission plate 5 (right lower end), and is cylindrical.

The static iron core 7e is a cylinder fixed on the left side inside the shell 7a and communicated with the opening of the shell 7a.

The movable iron core 7b is a cylinder body which is arranged at the right side inside the shell 7a and can slide in the shell 7a.

The coil 7d is wound outside the shell 7a, and the coil 7d can be powered on or powered off under the control of the MCU singlechip. Two ends of the coil 7d are connected to a preset relay, and the relay is installed in the shell 1 and is switched on and off under the MCU, so that the coil 7d is powered on or powered off.

The ejector rod 7f is located in the shell 7a, two ends of the ejector rod are respectively sleeved in the movable iron core 7b and the static iron core 7e and can move left and right in the static iron core 7e, and the right end of the ejector rod 7f is fixed in the movable iron core 7b and can move back and forth under the driving of the movable iron core 7 b.

The reset spring 7c is sleeved outside the ejector rod 7f and is positioned between the movable iron core 7b and the static iron core 7e, and the diameter of the reset spring is larger than the inner diameter of the movable iron core 7 b.

When emergency conditions such as overload, short circuit, overvoltage and undervoltage occur, the MCU singlechip sends a tripping signal to control the relay to switch on the coil 7d, after the coil 7d is electrified, the coil 7d generates a magnetic field, the movable iron core 7b and the static iron core 7e generate magnetic force attracting each other, the movable iron core 7b overcomes the elasticity of the reset spring 7c under the attraction of the static iron core 7e to move towards the direction of the static iron core 7e and push the ejector rod 7f to penetrate the static iron core 7e leftwards and then extend out of the shell 7a, so that the ejector rod 7f pushes the transmission plate 5 to rotate clockwise, when the transmission plate 5 moves to the second through hole 5d and is collinear with the first through hole 5c, the movable iron core still has a movement stroke, the movement stroke is a design margin, because the moment applied to the transmission plate 5 by the contact spring 8c is smaller than the moment applied to the transmission plate 5 by the reset torsion spring 11, the transmission plate 5 automatically rotates clockwise and pulls the contact system 8 to be separated from the contact with the plug-in 9 under the action of the reset torsion spring 11, so that the breaker is tripped without the break-off by the switch mechanism 7.

After the coil 7c is powered off, the movable iron core 7b and the static iron core 7e lose magnetic force, and the movable iron core 7b moves towards the direction away from the static iron core 7e under the action of the return spring 7c and drives the ejector rod 7f to retract back into the shell 7a.

Example three:

the difference between this embodiment and the first or second embodiment is:

in order to avoid the mistaken closing of the circuit breaker before the circuit breaker is inserted into the cabinet, as shown in fig. 1-3, the plug-in circuit breaker further comprises a mistaken closing prevention mechanism, as shown in fig. 10 and 11, the mistaken closing prevention mechanism comprises a through hole 1c, a pin rod 4a, a connecting rod 4b, a buckle 4c, a first locking hook 4d, a second locking hook 5b and a locking torsion spring 4e.

The through hole 1c is arranged on the housing 1 and above the shaft 5a, and is used as an access passage for the buckle 4 c.

The pin rod 4a is vertically arranged in the shell a and positioned on the left side of the through hole 1c, and is used for installing the connecting rod 4b and the locking torsion spring 4e.

The left end of the connecting rod 4b is rotatably arranged outside the pin rod 4 a.

Buckle 4c is fixed at connecting rod 4b right-hand member and stretches out outside shell 1 from through-hole 1c (and can rotate along with connecting rod 4 b), and buckle 4c left surface is the inclined plane and can be impressed in shell 1 under the exogenic action, drives connecting rod 4b clockwise turning.

The first lock hook 4d is fixed to the left end (lower side) of the connecting rod 4b with its hook surface facing upward.

The second locking hook 5b is fixed on the transmission plate 5 with the hook surface facing downward, and the second locking hook 5b is located on the upper side of the first locking hook 4d and is matched with the first locking hook 4 d.

The locking torsion spring 4e is sleeved on the pin rod 4a and also provided with two rotating arms, wherein the left rotating arm is clamped on the shell 1, and the right rotating arm is clamped on the buckle 4 c.

Before the plug-in circuit breaker is not inserted into the cabinet, the buckle 4c extends out of the through hole 1c, the connecting rod 4b is tightly attached to the inner side surface of the shell z under the action of the locking torsion spring 4e, the second lock hook 5b and the first lock hook 4a are mutually buckled, and the transmission plate 5 is difficult to rotate anticlockwise under the action of external force and drives the contact system 8 to move rightwards to be switched on through the first connecting rod 6.

After the plug-in circuit breaker is inserted into the cabinet, the buckle 4c is pressed into the housing 1 by the cabinet and drives the connecting rod 4b to rotate clockwise (two rotating arms of the locking torsion spring 4e are close to each other, and the locking torsion spring 4e compresses for energy storage), the first locking hook 4d is driven to rotate clockwise and is separated from the buckle with the second locking hook 5b, and the transmission plate 5 is in a state of free rotation.

After the plug-in circuit breaker is pulled out of the cabinet, the buckle 4c is not blocked by the cabinet any more, moves upwards under the action of the locking torsion spring 4e and extends out of the shell 1 from the through hole 1c until the connecting rod 4b is attached to the inner side surface of the shell 1 again; meanwhile, the locking torsion spring 4e drives the connecting rod 4b to rotate anticlockwise and drives the first locking hook 4d to rotate anticlockwise and the second locking hook 5b to be buckled again, so that the transmission plate 5 is locked again, the anticlockwise rotation is difficult to be performed under the action of external force, and the contact system 8 is driven to move rightwards and be switched on through the first connecting rod 6.

It is to be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The protection scope of the present invention is not limited to the technical solution disclosed in the specific embodiment, and all the modifications, equivalent replacements, improvements, etc. made by the technical entity of the present invention to the above embodiments all fall into the protection scope of the present invention.

Claims (10)

1. A plug-in circuit breaker comprising a hollow housing as a load-bearing base, characterized in that: the device also comprises a transmission plate, a reset torsion spring, a static contact, a contact system and a first connecting rod;

a sliding groove which is transversely arranged and a shaft lever which is vertically arranged in the shell are arranged in the shell; the shaft lever is positioned on the left side of the sliding groove;

the transmission plate is positioned in the shell, a first through hole and a second through hole are formed in the transmission plate, and the second through hole is positioned on the right side of the first through hole; the transmission plate is sleeved outside the shaft rod through the first through hole and can rotate around the shaft rod under the action of external force;

the reset torsion spring is sleeved outside the shaft lever and is provided with two rotating arms, the rotating arm on the left side of the reset torsion spring is clamped on the inner wall of the shell, and the rotating arm on the right side of the reset torsion spring is clamped on the transmission plate;

the static contact is arranged in the shell and positioned on the right side of the sliding chute;

the contact system is arranged in the chute and can do linear motion along the chute, so that the contact system is contacted with or separated from the static contact;

the left end of the first connecting rod is rotatably connected in the second through hole, and the right end of the first connecting rod is rotatably connected to the contact system;

when the contact system is contacted with the fixed contact, the right rotating arm of the reset torsion spring approaches to the left rotating arm of the reset torsion spring, and the reset torsion spring stores energy; when the contact system is separated from the static contact, the reset torsion spring releases energy, and the right rotating arm of the reset torsion spring opens rightwards and pushes the transmission plate to rotate clockwise.

2. Plug-in circuit breaker according to claim 1, characterized in that: the micro-control switch also comprises a PCB circuit board arranged in the shell, an MCU singlechip arranged on the PCB circuit board, a micro-switch and a solid-state switch; the micro switch is arranged on the PCB and positioned on the right side of the contact system, and is linked with the contact system and used for sending the opening and closing signals to the MCU singlechip; the solid-state switch is arranged in the shell and used for being switched on or switched off under the control of the MCU singlechip, so that the plug-in circuit breaker is switched on or switched off.

3. The plug-in circuit breaker according to claim 2, characterized in that: the first through hole is collinear with the chute.

4. A plug-in circuit breaker according to claim 3, characterized in that: the contact system comprises a contact support, a moving contact, a contact spring and a poke rod;

the contact support is slidably arranged in the sliding groove and can do linear motion along the sliding groove, the bottom of the contact support is concave upwards to form a transverse installation groove, and a connecting hole is formed in the left side of the contact support; the connecting hole is rotatably connected with the right end of the first connecting rod;

the moving contact is arranged in the mounting groove in a sliding manner, the right end of the moving contact extends out of the mounting groove, and the moving contact can move linearly towards the direction close to or far away from the static contact under the driving of the contact support, so that the moving contact is attached to or detached from the static contact;

the contact spring is arranged in the mounting groove and sleeved on the left end of the moving contact, the left end of the contact spring is propped against the contact support, and the right end of the contact spring is propped against the left side of the moving contact;

the left end of the poke rod is fixed on the contact support, and the right end of the poke rod is linked with the microswitch; when the contact support slides along the sliding groove, the poke rod is driven to slide left and right, so that the poke rod touches the contact of the micro switch, the micro switch sends a brake opening signal or a brake closing signal to the MCU singlechip, and the MCU singlechip controls the solid-state switch to be switched on or switched off.

5. Plug-in circuit breaker according to claim 4, characterized in that: when the first through hole, the second through hole, the first connecting rod and the moving contact are collinear, the moving contact and the static contact are in mutual contact, the reset torsion spring and the contact spring are both in an energy storage state, at the moment, if the driving plate continues to rotate anticlockwise under the action of external force, the first connecting rod contact support is pulled to slide towards the direction away from the static contact, the second through hole is made to move above the first through hole and the sliding chute, the reset torsion spring and the contact spring are still in a compression state, meanwhile, the reset torsion spring and the contact spring both apply a pushing force to the driving plate, the direction of a torque applied to the driving plate by the contact spring is opposite to the direction of a torque applied to the driving plate by the reset torsion spring, the torque applied to the driving plate by the contact spring is larger than the torque applied to the driving plate by the reset torsion spring, after the external force disappears, the driving plate continues to rotate anticlockwise under the action of the contact spring, and meanwhile, the moving contact is continuously kept in contact with the static contact under the action of the contact spring.

6. Plug-in circuit breaker according to claim 5, characterized in that: a rib is provided in the housing to lock the drive plate to prevent the drive plate from excessively rotating counterclockwise under the urging of the contact spring.

7. Plug-in circuit breaker according to claim 4, characterized in that: a limiting groove is symmetrically arranged on the front side and the rear side of the mounting groove supported by the contact; and a limiting bulge which can slide left and right in the limiting groove is respectively arranged on the movable contact corresponding to the two limiting grooves.

8. The plug-in circuit breaker according to claim 1, characterized in that: the tripper also comprises a tripper body, a movable iron core, a static iron core, a coil, a top rod and a reset spring;

the shell is arranged in the shell, the left end of the shell is opened, and the opening faces the transmission plate;

the static iron core is a cylinder fixed on the left side in the shell and communicated with the opening of the shell;

the movable iron core is a cylinder body which is arranged on the right side in the shell and can slide in the shell;

the coil is wound outside the shell and can be powered on or powered off under the control of the MCU singlechip;

the ejector rod is positioned in the shell, two ends of the ejector rod are respectively sleeved in the movable iron core and the static iron core and can move left and right in the static iron core, and the right end of the ejector rod is fixed in the movable iron core and can move back and forth under the driving of the movable iron core;

the reset spring is sleeved outside the ejector rod and positioned between the movable iron core and the static iron core, and the diameter of the reset spring is larger than the inner diameter of the movable iron core;

after the coil is electrified, the movable iron core and the static iron core generate magnetic force which is mutually attracted, the movable iron core overcomes the elasticity of the reset spring and moves towards the direction of the static iron core and pushes the ejector rod to extend out of the shell leftwards, and then the transmission plate is pushed to rotate clockwise, so that the plug-in circuit breaker is tripped and opened;

after the coil is powered off, the movable iron core and the static iron core lose magnetic force, and the movable iron core moves towards the direction away from the static iron core under the action of the reset spring and drives the ejector rod to retract into the shell again.

9. Plug-in circuit breaker according to claim 1, characterized in that: the handle and the second connecting rod are further included; the left end of the handle is positioned outside the shell, and the right end of the handle is arranged in the shell in a sliding manner and can do linear motion in the shell; and two ends of the second connecting rod are respectively and rotatably connected to the right lower part of the handle and the left lower part of the transmission plate.

10. A plug-in circuit breaker as claimed in any one of claims 1 to 9, characterized in that: the anti-misoperation closing mechanism comprises a through hole, a pin rod, a connecting rod, a buckle, a first locking hook, a second locking hook and a locking torsion spring;

the through hole is arranged on the shell and is positioned above the shaft lever;

the pin rod is vertically arranged in the shell and is positioned on the left side of the through hole;

the left end of the connecting rod is rotatably arranged outside the pin rod;

the buckle is fixed at the right end of the connecting rod and extends out of the shell from the through hole, and the left side surface of the buckle is an inclined surface and can be pressed into the shell under the action of external force to drive the connecting rod to rotate clockwise;

the first lock hook is fixed at the left end of the connecting rod, and the hook surface of the first lock hook faces upwards;

the second lock hook is fixed on the transmission plate, the hook surface of the second lock hook faces downwards, and the second lock hook is positioned on the upper side of the first lock hook and matched with the first lock hook;

the locking torsion spring is sleeved on the pin rod and is also provided with two rotating arms, the left rotating arm of the locking torsion spring is clamped on the shell, and the right rotating arm of the locking torsion spring is clamped on the buckle;

before the plug-in circuit breaker is not inserted into the cabinet, the buckle extends out of the through hole, the connecting rod is attached to the inner side surface of the shell under the action of the locking torsion spring, the second locking hook and the first locking hook are mutually buckled, and the driving plate is difficult to rotate anticlockwise under the action of external force and drives the moving contact system to move right to close a switch through the first connecting rod; after the plug-in circuit breaker is inserted into the cabinet, the buckle is pressed into the shell by the cabinet and drives the connecting rod to rotate clockwise, the first lock hook is driven to rotate clockwise and is separated from the buckle with the second lock hook, and the transmission plate is in a state capable of rotating freely.

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