RU2716012C2 - Miniature circuit breaker operating mechanism - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to the electrical equipment. Miniature switch comprises: a handle, a drive connecting rod, fixed and movable contacts, a tension spring and a disconnecting lever. One end of drive connecting rod is pivotally connected to handle, and other end is conjugated with movable contact. One end of tension spring is fixed on housing, and other end is connected to movable contact, which is driven by tension spring and drive connecting bar to create contact pressure and force of elastic expansion for closing contacts, and tension spring creates elastic force of accumulated energy for opening contacts. Switching lever is arranged on the movable contact and is used to control the locking and unlocking interaction between the drive connecting rod and the movable contact. At automatic disconnection, the disengaging lever disconnects the drive connecting rod from the movable contact for automatic disengagement of the working mechanism.

EFFECT: technical result consists in simplification of design, reduction of costs for production, increased efficiency of production and optimization of mechanical parameters of operation.

11 cl, 4 dwg

Description

Technical field

The present invention relates to the operating mechanism of a miniature circuit breaker, in particular, to the operating mechanism used for a modular miniature circuit breaker in a plastic housing, which relates to low-voltage electrical devices.

State of the art

As you know, the operating mechanism of a miniature circuit breaker is used to bring the movable contact and the stationary contact into the open / close state, and by means of the open / close control the closing, opening and tripping of the switch is controlled. The most typical and widely used scheme of the existing operating mechanism of a miniature circuit breaker is a four-link articulated mechanism, which includes a handle connected to a drive connecting rod, whereby a knee-lever mechanism is formed: the movable contact support has a rotary plate mounted on the hinge for rotation; in addition, there is a mechanical connection (also called a locking device), which can be disconnected under the action of the pressure plate, and a bimetal plate is connected to the pressure plate through a rotary connecting rod with a one-way drive. The aforementioned mechanical connection is jointly formed by a pressure plate limiter and a latch (also commonly referred to as a lever) mounted rotatably on the plate spindle, the connecting rod is directly connected to the latch, and the resulting assembly forms a lowering step to reduce the operating force of the operating mechanism. A feature of this type of mechanism is that the movable contact and the contact support are two separate components, and to obtain the necessary tension function, it is also necessary to provide a tension mechanism between the movable contact and the contact support. For this, two methods are usually used to provide a connection between a movable contact and a contact-based rotary plate: one of such methods is bonding or welding (where there are disadvantages such as complexity and unreliability of the joint); another method is that the movable contact is mounted on the contact support not by fixing the working mechanism on the rotary shaft, but by using a spring button (the disadvantage of this method is the lengthening of the rotary contact lever and the slowing down of the mechanism’s response speed, which is unfavorable for the tripping ability of the switch ) In addition, the contact support in the four-link articulated mechanism is usually fixed by the spring and the rotary plate, and the contact support and the rotary plate can be rotated within narrow limits to provide contact pressure and the circuit breaker tension. Obviously, the common problem of the existing implementation method is that the contact is welded or fixed by a spring on the contact support: this means the presence of a large number of parts, the complexity of the design of the drive circuit and difficulties in installation and debugging; in addition, the assembly efficiency is reduced, which affects miniaturization and affects the cost of the circuit breaker. Finally, the mechanical coupling design in the existing operating mechanism of the miniature circuit breaker is based on a drive chain between the latch and the pressure plate; in this case, gearing is usually used (usually referred to as a lock, etc.). The disadvantage of the gear design is that the teeth wear out quickly, which negatively affects the reliability and durability of the product.

In conditions when the requirements for miniaturization and versatility are constantly increasing, and the need to improve new technologies with respect to the operating mechanism of a miniature circuit breaker is becoming more and more urgent, the main areas of technological improvement can be reduced to miniaturization, cost reduction and optimization of performance, including reliability and durability, and the main technical solutions associated with these areas are to simplify the design and reduce to the number of parts, while ensuring the ability to overcome the limitations associated with the influence of external conditions.

Summary of the invention

The above problems of the prior art are solved by the present invention by creating a working mechanism of a miniature circuit breaker, ensuring the reliability of the working mechanism of the circuit breaker, ease of assembly and improving production efficiency, while simplifying the design and reducing the number of parts.

To achieve the above objectives in the present invention adopted the following technical solutions:

The working mechanism of the miniature circuit breaker includes a handle 2, pivotally mounted on the housing 1, a drive connecting rod 3, a fixed contact 10 and a movable contact 4 placed in the housing 1, as well as a tension spring 13 and a switching lever 5, one end of the drive connecting rod 3 is pivotally connected to the handle 2, and the other end of the drive connecting rod 3 is mated to the movable contact 4, one end of the tension spring 13 is fixed to the housing 1, and the other end of the tension spring 13 is connected to the movable contact volume 4: the movable contact 4 is driven by the tension spring 13 together with the drive connecting rod 3 to create the contact pressure and elastic tensile forces necessary to ensure the reliability of the electrical contact to close the movable contact 4 and the stationary contact 10, and the tension spring 13 creates an elastic force the accumulated energy necessary to return the mechanism for uncoupling the movable contact 4 from the fixed contact 10; at the same time, the switching lever 5 is placed on the movable contact 4 and is used to control the locking and unlocking interaction between the drive connecting rod 3 and the movable contact 4; with automatic shutdown, the switching lever 5 disconnects the drive connecting rod 3 from the movable contact 4 for automatic release of the working mechanism.

In a preferred case, a rotation shaft 6 of the mechanism and a restriction shaft 7 are provided in the housing 1, a movable contact 4 is pivotally mounted on the rotation shaft 6 of the mechanism and is fixed on the rotation shaft 6 of the mechanism and the restriction shaft 7 by a tension spring 13.

In the preferred case, the movable contact 4 is mounted to rotate on the rotation shaft 6 of the mechanism through the arcuate hole 41 provided on the movable contact 4, the installation and interaction between the arcuate hole 41 of the movable contact 4 and the rotation shaft 6 of the mechanism provide that the tension clearance h has such a value, in which the movable contact 4 and the fixed contact 10 are closed.

In the preferred case, the movable contact 4 is provided with an arcuate hole 41, a drive groove 42, a hinge hole 43, a restrictive groove 44, a spring hook 45 and a touch point 40 of the movable contact, where: the arcuate hole interacts with the rotation shaft 6 of the housing mechanism 1; the restrictive groove 44 interacts with the restrictive shaft 7 of the housing 1; the drive groove 42 on the movable contact 4 interacts in a drive manner with the drive end 32 of the drive connecting rod 3, and the hinge hole 43 on the movable contact 4 interacts with the axis 52 on the switch lever 5.

In the preferred case, the movable contact 4 is provided with an arcuate hole 41 and the hinge hole 43, one end is provided with a concave drive groove 42, and the other end is provided with a touch point 40 of the movable contact, a spring hook 45 is located between the arcuate hole 41 and the drive groove 42, a restrictive groove 44 is located between the arcuate hole 41 and the movable contact 4, the hinge hole 43 is located between the restrictive groove 44 and the arcuate hole 41, the arcuate hole 41 is located in the movable part contact 4, closest to the spring hook 45, and the hinge hole 43 is located in the part of the movable contact 4, closest to the restrictive groove 44.

In the preferred case, one end of the movable contact 4 is provided with a drive groove 42 that interacts with the drive end 32 of the drive connecting rod 3, the switch-off lever 5 is pivotally mounted on the movable contact 4 and is equipped with a trip portion 53 and a locking surface 51 for realizing a locking and unlocking interaction between the drive connecting rod 3 and the movable contact 4.

In a preferred case, the locking interaction consists in the fact that the locking surface 51 on the switch lever 5 abuts against the drive end 32 of the drive connecting rod 3, the drive end 32 is locked into the drive groove 42 of the movable contact 4, and the drive end 32 of the drive connecting rod 3 and the locking surface 51 of the switching lever 5 create a locking force, acting together on the drive groove 42; and the unlocking interaction is that the locking surface 51 on the switch lever 5 is separated from the drive end 32 of the drive connecting rod 3, and the drive end 32 extends into the drive groove 42 of the movable contact 4.

In the preferred case, the switch lever 5 is additionally equipped with a return device for rotation around the axis 52, the return rotation of the switch lever 5 brings the locking surface 51 on the switch lever 5 into a stop position against the drive end 32 of the drive connecting rod 3, as a result of which the drive end 32 is locked in the drive the groove 42 of the movable contact 4 so that the drive connecting rod 3 and the movable contact 4 are mutually locked.

Preferably, the release portion 53 of the release lever 5 rotates about an axis 52 and causes the locking surface 51 of the release lever 5 to separate from the drive end 32 of the drive connecting rod 3, and this release allows the drive end 32 to enter the drive groove 42 of the movable contact 4 in this way so that the drive connecting rod 3 and the movable contact 4 are unlocked.

In a preferred case, the continuation of the line connecting the ends 31 and 32 of the drive connecting rod 3 is stabilized below the center of rotation “O” of the handle 2 in a position in which the movable contact 4 and the fixed contact 10 are closed; the continuation of the line connecting the ends 31 and 32 of the drive connecting rod 3 is stabilized above the center of rotation “O” of the handle 2 in a position in which the movable contact 4 and the fixed contact 10 are open; and in the process of shutdown, the continuation of the line connecting the ends 31 and 32 of the drive connecting rod 3 moves from a position below the center of rotation “O” of the handle 2 to a position above the center of rotation “O”.

In a preferred case, in a state where the movable contact 4 and the fixed contact 10 are closed, the force acting on the movable contact 4 is composed of the pulling force of the tension spring 13, the contact pressure of the stationary contact 10 acting on the touch point 40 of the movable contact 4, and the locking forces the drive end 32 of the drive connecting rod 3 and the locking surface 51 of the switch lever 5, acting together on the drive groove 42 of the movable contact 4, where the resulting force of the contact pressure and the locking force Iya is balanced by the pulling force of the tension spring 13; and in a state where the movable contact 4 and the fixed contact 10 are open, the force acting on the movable contact 4 is composed of the pulling force of the tension spring 13, the restraining force of the shaft 6 of the rotation of the mechanism acting on the arcuate hole 41, and the contact force of the restrictive shaft 7, acting on the restrictive groove 44 of the movable contact 4, where the resulting contact force and the pulling force of the tension spring 13 is balanced by the restraining force of the rotation shaft 6 of the mechanism acting on the arcuate from ERSTU 41.

In the operating mechanism of the miniature circuit breaker of the present invention, a three-link hinge scheme is adopted to implement the design of providing a “close / open” transition, which eliminates the need for welding or a spring connection between the movable contact and the contact support, reduce the number of parts, effectively simplify the design and reduce costs production. In addition, when making a three-link hinge system and optimal structural solutions in the design of the new system of forces, locking structure, tensile structure and the design of the transition "closure / opening", the working mechanism can perform the necessary tensile function and can simplify the design, reduce production costs , increase production efficiency and optimize mechanical work parameters. Brief Description of the Drawings

The advantages and features of the present invention are more clearly shown in the description of the embodiments depicted in the accompanying drawings, where:

FIG. 1 is a schematic structural view of the operating mechanism of the miniature circuit breaker of the present invention when the movable contact 4 and the fixed contact 10 are in a stable open state.

FIG. 2 is a schematic view of the structure of the operating mechanism of the miniature circuit breaker of the present invention, assembled at the time the movable contact 4 transitions from the open state to the closed state.

FIG. 3 is a schematic structural view of the operating mechanism of the miniature circuit breaker of the present invention when the movable contact 4 and the stationary contact 10 are in a stable closed state.

FIG. 4 is an isometric view of the movable contact 4 in the operating mechanism shown in FIG. 1.

Detailed Description of Preferred Embodiments

Detailed embodiments of the operating mechanism of the miniature circuit breaker of the present invention are described with reference to the embodiments shown in FIG. 1-4.

In the embodiment shown in FIG. 1-3, the operating mechanism of the miniature circuit breaker of the present invention includes a housing 1, a fixed contact 10 (shown schematically in the drawing), a handle 2, pivotally mounted on the housing 1, and a drive rotary rod 3, pivotally connected to the handle 2. In addition, the working mechanism of the present invention includes a tension spring 13, a movable contact 4, driven jointly by a drive connecting rod 3 and a tension spring 13, and a disengaging lever 5 for controlling the locking and unlocking interaction viem drive between connecting rod 3 and the movable contact 4. One end of a drive connecting rod 3 is pivotally connected with the handle 2, and an opposite driving end 32 mates with the movable contact 4; one end of the tension spring 13 is fixed to the housing 1, and the other end thereof is connected to the movable contact 4 so that the movable contact 4 is driven by the tension spring 13 together with the drive connecting rod 3 to create contact pressure and elastic tensile forces necessary to provide the reliability of the electrical contact for closing the movable contact 4 and the stationary contact 10, and the tension spring 13 creates the elastic force of the stored energy necessary to return the mechanism for uncoupling another contact 4 from the fixed contact 10; at the same time, the switching lever 5 is placed on the movable contact 4 and is used to control the locking and unlocking interaction between the drive connecting rod 3 and the movable contact 4; and with automatic shutdown, the switching lever 5 disconnects the drive connecting rod 3 from the movable contact 4 for automatic uncoupling of the working mechanism, which is completely independent of the action of the handle 2.

In the embodiment shown in FIG. 1-3, three shafts are installed in the switch housing 1, which are, respectively, a shaft for attaching one end of the tension spring 13, a rotation shaft 6 of the mechanism and a restriction shaft 7, where the movable contact 4 is pivotally mounted on the rotation shaft 6 of the mechanism of the housing 1, movable contact 4 is fixed on the rotation shaft 6 of the mechanism and the restriction shaft 7 of the housing 1 by the tension spring 13, the tension spring 13 and the restriction shaft 7, respectively, are located on both sides on opposite sides of the movable contact 4, and the restriction shaft 7 determines Yedelev the movable contact 4.

As shown in FIG. 4, the movable contact 4 is provided with an arcuate hole 41, a drive groove 42, a hinge hole 43, a restrictive groove 44, a spring hook 45 and a touch point 40 of the movable contact, where: the arcuate hole interacts with the rotation shaft 6 of the housing mechanism 1; the restrictive groove 44 interacts with the restrictive shaft 7 of the housing 1; the drive groove 42 on the movable contact 4 interacts in a drive manner with the drive end 32 of the drive connecting rod 3, and the hinge hole 43 on the movable contact 4 interacts with the axis 52 on the switch lever 5. One end of the tension spring 13 is connected to the housing 1, and the other end of the tension spring the spring 13 is connected to the spring hook 45 on the movable contact 4 so that the movable contact 4 is fixed on the rotation shaft 6 and the restrictive shaft 7 of the housing 1 by the tension spring 13, and the tension spring 13 creates the contact pressure required dimoe to ensure the reliability of electrical contact for closing movable and stationary contacts. The drive connecting rod 3 can go into the concave drive groove 42 of the movable contact 4 and push the movable contact 4, turning it; the movable contact 4 can be rotated around the rotation shaft 6 of the mechanism to achieve a contact position between the movable and fixed contacts, and when the working mechanism is again locked, a change occurs in the position of the point of application of the force of the movable contact 4, at which the movable contact 4 moves away from the rotation shaft 6 . In one of the preferred embodiments of the present invention depicted in FIG. 4, the movable contact 4 is provided with an arcuate hole 41 and the hinge hole 43, one end is provided with a concave drive groove 42, and the other end is provided with a touch point 40 of the movable contact, the spring hook 45 and the restrictive groove 44, respectively, are located in different parts of the movable contact 4, a spring hook 45 is located between the arcuate hole 41 and the drive groove 42, the restriction groove 44 is located between the arcuate hole 41 and the movable contact 4, the hinge hole 43 is located between the restriction groove 44 and ugoobraznym hole 41 arcuate aperture 41 is disposed on the side of the movable contact 4, near to the spring hook 45, a pivot hole 43 located on the side of the movable contact 4, the proximal groove 44 to the restrictive.

Thus, it is seen that one of the advantages of the operating mechanism of the miniature circuit breaker of the present invention is that at the same time three structural solutions are provided that are different from the prior art: in the first of these solutions, a three-link hinge mechanism is proposed, which consists of a drive connecting rod 3, a movable contact 4 and an off lever 5, and in which there is no traditional latch lever; the second solution proposes the design of the movable contact 4, in which there is no traditional rotary plate supported by the contact, and a tension mechanism or transmission mechanism located between the contact support and the movable contact; and the third solution proposes a spring structure that is capable of simultaneously providing elastic energy of stored energy, contact pressure and elastic tensile force — that is, tension spring 13, which provides the functions of energy storage of elastic force, elastic contact and elastic tension, and is absent traditional tension spring. The essence of the present invention not only changes the whole structural solution of the working mechanism and the principle of its operation, but also makes changes to individual structural solutions of the working mechanism - such as the design of the force system, the locking structure, the tensile structure, the design of the transition "closing / opening" and others decisions in the mechanism. It is obvious that the design is simple and consists of a small number of parts, which can significantly reduce production costs and increase production efficiency. At the same time, the optimization of the parameters of the mechanism.

The design of the force system of the present invention relates mainly to the configuration of ensuring equilibrium of the system of forces of the structure of the drive of the elastic force and the main element. The drive design of the elastic force may have various particular ways of implementation; however, the preferred implementation method adopted in the present invention is as follows: the tension spring 13 not only provides an elastic force of energy storage to open the movable contact 4 and the fixed contact 10, but also provides contact pressure and elastic tensile force to close the movable contact 4 and fixed contact 10. In the traditional four-link articulated mechanism, the design of the drive of the elastic force involves the use of an energy storage spring and a tension spring, where each of these springs performs its function: the energy storage spring provides an elastic energy storage force to open the movable contact and the stationary contact (i.e., the energy storage of the elastic force), and the tension spring provides contact pressure (i.e., elastic contact ) and elastic tensile force (i.e., elastic tension) to close the movable contact and the stationary contact; in this case, if one of the springs is missing, respectively, one of the functions is not performed. In the described invention adopted a tension spring 13, which implements three functions of the drive of the elastic force - the accumulation of energy of the elastic force, elastic contact and elastic tension. The balance system design of the force system of the present invention may have various particular implementation methods; however, the preferred implementation method adopted in the present invention provides for the following situations. In the first situation: in a state where the movable contact 4 and the fixed contact 10 are closed (as shown in Fig. 3), the force acting on the movable contact 4 is the sum of the pulling force of the spring hook of the tension spring 13, the contact pressure of the fixed contact 10, acting to the touch point

40 of the movable contact, and the locking forces of the drive end 32 of the drive connecting rod 3 and the locking surface 51 of the switch lever 5, acting together on the drive groove 42 of the movable contact 4 (i.e., the drive interaction between the drive end 32 of the drive connecting rod 3 and the drive groove 42 on the moving contact 4 is in a state of transfer of force; between the drive end 32 and the drive groove 42 there must be a mutual drive force), where the resulting contact pressure force and the locking force It is suspended by the pulling force of the tension spring 13. In the first situation shown in FIG. 3: the rotation shaft 6 of the mechanism of the housing 1 does not exert a restraining force on the arcuate hole 41 on the movable contact 4, and therefore the placement and interaction between the rotation shaft 6 of the mechanism and the arcuate hole 41 are carried out in a disconnected state; and the restriction shaft 7 of the housing 1 does not exert contact force on the restriction groove 44 on the movable contact 4, and therefore the contact between the restriction groove 44 and the restriction shaft 7 of the housing 1 occurs in a disconnected state. In the second situation: in a state where the movable contact 4 and the fixed contact 10 are open (as shown in Fig. 1), the force acting on the movable contact 4 is the sum of the pulling force of the spring hook 45 of the tension spring 13, which restrains the forces of the rotation shaft 6 housing 1, acting on an arcuate hole 41 on the movable contact 4, and the contact force of the restrictive shaft 7 of the housing 1, acting on the restrictive groove 44 of the movable contact 4, where the resulting contact force and the pulling force of the tension spring 13 us balanced restraining force of the arcuate hole 41. In the second situation shown in Fig. 1, the drive interaction between the drive end 32 of the drive connecting rod 3 and the drive groove on the movable contact 4 is in a state where no transfer of force occurs, and although the locking surface of the switch lever 5 is in the locking state, between the drive end 32 of the drive connecting rod 3 and a drive groove 42 on the movable contact 4 does not require (and does not actually exist) mutual drive force. In the state where the movable contact 4 and the fixed contact 10 are closed, the force acting on the movable contact 4 is the sum of the pulling force of the tension spring 13 acting on the spring hook 45, the contact pressure of the stationary contact 10 acting on the touch point 40 of the movable contact, and the locking forces of the drive end 32 of the drive connecting rod 3 and the locking surface 51 of the switch lever 5, acting together on the drive groove 42 of the movable contact 4, where the resulting contact pressure force and the locking about the effort is balanced by the pulling force of the tension spring 13; and in the state when the movable contact 4 and the fixed contact 10 are open, the force acting on the movable contact 4 is the sum of the pulling force of the tension spring 13 acting on the spring hook 45, the restraining force of the rotation shaft 6 of the mechanism on the housing 1 acting on the arcuate hole 41, and the contact force of the restriction shaft 7 on the housing 1, acting on the restriction groove 44, where the resulting force of the contact force and the pulling force of the tension spring 13 is balanced by the restraining force of the arcuate hole I 41. It should be understood that the design of ensuring the equilibrium of the system of forces is crucial for providing control and functioning parameters of the operating mechanism of the miniature circuit breaker, the configuration of the system of forces of the present invention is relatively simple and reasonable, and it becomes possible to avoid unnecessary power losses and mutual interference between the forces, which allows for stability and reliability of the balance of forces, quick and sensitive action of the working mechanism.

The locking structure may have various particular implementation methods; however, the preferred implementation method adopted in the present invention includes the following: the switch lever 5 is provided with a locking surface 51, an axis 52 and an uncoupling part 53, the locking surface 51 and the drive end 32 of the drive connecting rod 3 are locked and unlocked, and the axis 52 is installed and engages with the hinge hole 43 on the movable contact 4. The locking and unlocking interaction between the drive connecting rod 3 and the movable contact 4 is as follows: one end of the movable contact 4 with is fitted with a drive groove 42, which in a drive manner interacts with the drive end 32 of the drive connecting rod 3, the switch-off lever 5 is pivotally mounted on the movable contact 4, provided with a trip portion 53 and a locking surface 51 for realizing a locking and unlocking interaction between the drive connecting rod 3 and the movable contact 4. At the same time, the locking interaction consists in the fact that the locking surface 51 on the turning lever 5 abuts against the drive end 32 of the drive connecting rod 3, p the drive end 32 of the drive connecting rod 3 is locked in the drive groove 42 on the movable contact 4, and the drive end 32 of the drive connecting rod 3 and the locking surface 51 of the switch lever 5 create a locking force, acting together on the drive groove 42; and the unlocking interaction is that the locking surface 51 on the switch lever 5 is separated from the drive end 32 of the drive connecting rod 3, and the drive end 32 extends into the drive groove 42. Obviously, the design advantage is that the locking and unlocking interaction is between the locking surface 51 on the switch lever 5 and the drive end 32 of the drive connecting rod (rod type structure); Compared to traditional gears, this interaction has the obvious advantage of increased wear resistance, provides a more powerful locking force and significantly better locking reliability. As shown in FIG. 1-3, related to a particular preferred embodiment of the release lever 5 of the present invention, the release lever 5 comprises interlocked locking arm and a driving arm, an end portion of the locking arm is provided with a locking surface 51, the driving arm is provided with an releasing part 53, between the locking arm and a V-groove is made in the drive arm, the locking arm is provided with an axis 52 conjugated to rotate with a movable contact 4, the disengaging lever 5 is mounted on the hinge hole 4 3 of the movable contact 43 through the axis 52, and the V-shaped groove of the switching lever 5 is suitably located relative to the restriction shaft 7.

Said locking structure with locking and unlocking interaction structures may have various particular implementation methods, and the preferred implementation method adopted in the present invention provides for the following two situations. In the first situation: the switch lever 5 is also equipped with a return device (not shown in the drawing) for turning the switch lever 5 around the axis 52, the return rotation of the switch lever 5 brings the locking surface 51 on the switch lever 5 to the stop position on the drive end 32 of the drive connecting rod 3 as a result of which the drive end 32 is locked in the drive groove 42 on the movable contact 4 so that the drive connecting rod 3 and the movable contact 4 are in a state of locking interaction. In the return device, a return spring (not shown in the drawing) can be used, the two ends of which are connected, respectively, with the switching lever 5 and the movable contact 4. An elastic corner device (not shown in the drawing) located on the switching lever 5, where the angular end of such an elastic angular element creates a frictional force and / or restricts communication with the movable contact 4 or the housing 1. In the second situation: the switching device of the miniature switch rotates the trip unit 53 on the release lever 5 around the axis 52, as a result of which the locking surface 51 is separated from the drive end 32 of the drive connecting rod 3 so that the drive end 32 can fit into the drive groove 42, i.e., the locking surface 51 and the drive end 32 of the drive connecting rod 3 are in a state of unlocking interaction. Typically, the circuit breaker of the miniature circuit breaker contains two types of releases, one of which is an electromagnetic release, where the state of electromagnetic tripping is created in the circuit, a hammer 12 connected via a clutch to the support spring 11 of the electromagnetic release strikes the release part 53 on the release lever 5, as a result, the release lever 5 rotates around axis 52. Another type of release is a thermal release, where a heat release state is generated in the circuit a, the heat-sensitive device 9 (such as a bimetallic strip) is bent, and the drive shaft 8 pulls the release part 53 on the shut-off lever so that the shut-off lever 5 is rotated around the axis 52. It should be noted especially that the unlocking interaction occurs only when the shut-off the device drives the switching lever 5, or only in the process of turning off the miniature switch, and the unlocking interaction cannot occur during normal closure or normal opening . In the normally closed state (shown in Fig. 3) and in the normally open state (shown in Fig. 1), during the normal closing operation (during the transition from the state shown in Fig. 1 to the state shown in Fig. 3) and during the normal opening operation (upon transition from the state shown in Fig. 3 to the state shown in Fig. 1), since the switching device does not drive the switching lever 5, the latter remains permanently locked. In particular, in connection with the action of the return device, provided that the switch-off device excludes the actuation of the switch-off lever 5, the latter can automatically return to the state of the locking interaction, regardless of position, which ensures the reliability of normal closure and normal opening.

The tensile structure may have various particular implementation methods, and the preferred implementation method adopted in the present invention is shown in FIG. 3: the movable contact 4 is rotatably mounted on the rotation shaft 6 of the mechanism through the arcuate hole 41 of the movable contact 4; in a state where the movable contact 4 and the fixed contact 10 are closed, a tension gap h is provided between the arcuate hole 41 of the movable contact 4 and the rotation shaft 6 of the housing mechanism 1, which is achieved through the use of an elongated (rather than round) hole 41. The tension gap is realized for due to the installation and interaction of the arcuate hole 41 and the rotation shaft 6 of the mechanism of the housing 1, where such installation and interaction allow the arcuate hole 41 provided on the rotation shaft 6 of the mechanism to be the state of the sliding interaction with the rotation shaft 6 of the mechanism in such a way that the tension gap h can be formed in the process of bringing the movable contact 4 and the fixed contact 10 into the closed state (i.e., when changing from the open state shown in Fig. 1 to the closed the state shown in Fig. 3), where the tension of the movable contact is compensated by the tension gap h. The principle of tensile compensation consists in particular in the following: in the open state shown in FIG. 1, the handle 2 is rotated in a clockwise direction, the movable contact 5 is rotated by the drive connecting rod 3 counterclockwise around the rotation shaft 6 of the mechanism and touches the stationary contact 10, whereby the instantaneous state shown in FIG. 2; in this state, before it, the movable contact 5 rotates with the rotation shaft 6 of the mechanism, where the latter acts as a fulcrum; at the same time, the tension gap h between the oblong hole 41 and the rotation shaft 6 of the mechanism of the housing 1 is 0. When the handle 2 continues to rotate, the pivot point of the movable contact 5 is transferred from the rotation shaft 6 of the mechanism to the fixed contact 10; at this moment, the movable contact 4 is rotated so that the contact point of the fixed contact 10 is in the center of the circle, and the movable contact 4 is separated from the rotation shaft 6 of the housing mechanism 1 due to the tension clearance h until the normal closure operation is completed with reaching the position shown in FIG. 3. Of course, from the closed state shown in FIG. 3 can be returned to the open state shown in FIG. 1, by turning said handle in the opposite direction; the normal opening operation and the arrangement of the parts involved in it occur in the reverse order described above.

The closure / open transition design can have various particular implementation methods, and the preferred implementation method adopted in the present invention is as follows: in a position in which the movable contact 4 and the fixed contact 10 are closed, the extension of the line connecting the two ends 31 and 32 of the drive connecting rod 3, is stabilized below the center of rotation "O" of the handle 2 (as shown in Fig. 3), due to which the working mechanism is stabilized in the closed state; in the position in which the movable contact 4 and the fixed contact 10 are open, the continuation of this line is stabilized above the center of rotation “O” of the handle 2 (as shown in Fig. 3), due to which the operating mechanism is stabilized in the open state; and in the process of shutdown, the continuation of the named line goes from a position below the center of rotation “O” of the handle 2 to a position above the center of rotation “O”. It is easy to imagine that in the process of switching off, the transition of the extension of the said line from a position below the center of rotation to a position above the center of rotation is caused by the unlocking action of the switching lever 5, and that when the switching device turns the switching lever around axis 52, the locking surface 51 located on it is separated from the drive end 32 of the drive connecting rod 3 and is able to go into the drive groove 42. This location allows the drive end 32 of the drive connecting rod 3 to move in bottom, and this movement leads to the rotation of the continuation of the named line in a clockwise direction around one end 31 of the drive connecting rod 3, which ultimately leads to the fact that the continuation of the line passes the inflection point (center of rotation "O" of the handle 2) from the position below this point, and as soon as the inflection point is passed, the elastic force of the tension spring 13 rotates the movable contact 4 in the opening direction (counterclockwise) until the movable contact 4 is in a stable open the state shown in FIG. 1, which will mean the completion of the shutdown operation.

The foregoing is a detailed description of the present invention with reference to particular preferred embodiments; however, it is not intended that a particular implementation of the present invention be limited to these descriptions. Specialists in the field of the invention can make a number of simple abbreviations or replacements without departing from the idea of the present invention, and all of them will be considered falling within the scope of protection of the present invention.

Claims (11)

1. The operating mechanism of the miniature circuit breaker, comprising a handle (2) pivotally mounted on the housing (1), a drive connecting rod (3), a fixed contact (10) and a movable contact (4) placed in the housing (1), as well as a tension a spring (13) and a disengaging lever (5), one end of the drive connecting rod (3) pivotally connected to the handle (2), and the other end of the drive connecting rod (3) mating with the movable contact (4), one end of the tension spring ( 13) is mounted on the housing (1), and the other end of the tension spring (13) is connected to the zhnym contact (4); the movable contact (4) is driven by the tension spring (13) together with the drive connecting rod (3) to create the contact pressure and elastic tensile forces necessary to ensure the reliability of the electrical contact to close the movable contact (4) and the fixed contact (10), and the tension spring (13) creates the elastic force of the stored energy necessary to return the mechanism for uncoupling the movable contact (4) from the stationary contact (10); in this case, the switching lever (5) is placed on the movable contact (4), and is used to control the locking and unlocking interaction between the drive connecting rod (3) and the movable contact (4); during automatic shutdown, the switching lever (5) disconnects the drive connecting rod (3) from the movable contact (4) to automatically disengage the working mechanism. 2. The working mechanism according to claim 1, characterized in that the shaft (6) of the rotation of the mechanism and the restrictive shaft (7) are provided in the housing (1), while the movable contact (4) is pivotally mounted on the rotation shaft (6) of the mechanism, movable contact (4) is fixed on the rotation shaft (6) of the mechanism and the restrictive shaft (7) with a tension spring (13). 3. The working mechanism according to claim 2, characterized in that the movable contact (4) is mounted to rotate on the shaft (6) of rotation of the mechanism through the arcuate hole (41) provided on it, the installation and interaction between the arcuate hole (41) of the movable contact (4) and the rotation shaft (6) of the mechanism provide that the tension gap h has a value such that the movable contact (4) and the fixed contact (10) are closed. 4. The operating mechanism according to claim 2, characterized in that the movable contact (4) is provided with an arcuate hole (41), a drive groove (42), a hinge hole (43), a restrictive groove (44), a spring hook (45) and a point touch (40) of the movable contact, and the arcuate hole interacts with the rotation shaft (6) of the housing mechanism (1); restrictive groove (44) interacts with the restrictive shaft (7) of the housing (1); the drive groove (42) on the movable contact (4) interacts in a drive manner with the drive end (32) of the drive connecting rod (3), and the hinge hole (43) on the movable contact (4) interacts with the axis (52) on the switch lever (5) ) 5. The working mechanism according to claim 4, characterized in that the movable contact (4) is provided with an arcuate hole (41) and a hinge hole (43), one end is provided with a concave drive groove (42), and the other end is provided with a touch point ( 40) a movable contact, a spring hook (45) is located between the arcuate hole (41) and the drive groove (42), a restrictive groove (44) is located between the arcuate hole (41) and the movable contact (4), the hinge hole (43) is located between restrictive groove (44) and arcuate hole (41), arcuate opening s (41) disposed in the movable contact part 4, near to the spring hook (45), and pivot hole (43) disposed in the movable contact portion (4), proximal to the confining groove (44). 6. The operating mechanism according to claim 1, characterized in that one end of the movable contact (4) is provided with a drive groove (42), which interacts with the drive end (32) of the drive connecting rod (3), which pivots the lever (5) pivotally mounted on a movable contact (4), provided with a trip part (53) and a locking surface (51) for realizing a locking and unlocking interaction between the drive connecting rod (3) and the movable contact (4). 7. The operating mechanism according to claim 6, characterized in that the locking interaction consists in the fact that the locking surface (51) on the switching lever (5) abuts against the drive end (32) of the drive connecting rod (3), the drive end (32) it is locked in the drive groove (42) on the movable contact (4), and the drive end (32) of the drive connecting rod (3) and the locking surface (51) of the switch lever (5) create a locking force acting together on the drive groove (42); and the unlocking interaction consists in the fact that the locking surface (51) on the switching lever (5) is separated from the drive end (32) of the drive connecting rod (3), and the drive end (32) extends into the drive groove (42) on the movable contact ( 4). 8. The operating mechanism according to claim 1, characterized in that the switch-off lever (5) is additionally equipped with a return device for turning the switch-off lever (5) about an axis (52), which brings the locking surface (51) on the switch-off lever (5) to stop on the drive end (32) of the drive connecting rod (3), as a result of which the drive end (32) is locked in the drive groove (42) on the movable contact (4) so that the drive connecting rod (3) and the movable contact (4 ) are mutually locked. 9. The operating mechanism according to claim 1, characterized in that the trip part (53) on the shut-off lever (5) is rotated by the trip device of the miniature switch around the axis (52) and brings the locking surface (51) of the shut-off lever (5) into a state of separation from the drive end (32) of the drive connecting rod (3), which allows the drive end (32) to enter the drive groove (42) on the movable contact (4) so that the drive connecting rod (3) and the movable contact (4) are unlocked. 10. The working mechanism according to claim 1, characterized in that the continuation of the line connecting the two ends (31) and (32) of the drive connecting rod (3) is stabilized below the center of rotation “O” of the handle (2) in the position in which the movable contact (4) and fixed contact (10) are closed; the continuation of the line connecting the two ends (31) and (32) of the drive connecting rod (3) is stabilized above the center of rotation “O” of the handle (2) in a position in which the movable contact (4) and the fixed contact (10) are open; and in the process of shutdown, the continuation of the line connecting the two ends (31) and (32) of the drive connecting rod (3) moves from a position below the center of rotation “O” of the handle (2) to a position above the center of rotation “O”. 11. The working mechanism according to p. 3, characterized in that in the state when the movable contact (4) and the fixed contact (10) are closed, the force acting on the movable contact (4) is the sum of the pulling force of the tension spring (13), contact pressure of the fixed contact (10) acting on the contact point (40) of the movable contact, and the locking forces of the drive end (32) of the drive connecting rod (3) and the locking surface (51) of the switch lever (5) acting together on the drive groove ( 42) movable contact (4), where the resulting contact force pressure and closing force is balanced by the pulling force of the tension spring (13); and in the state when the movable contact (4) and the stationary contact (10) are open, the force acting on the movable contact (4) is the sum of the pulling force of the tension spring (13), the restraining force of the shaft (6) of rotation of the mechanism on the housing (1 ) acting on the arcuate hole (41) and the contact force of the restrictive shaft (7) of the housing (1) acting on the restrictive groove (44) of the movable contact (4), where the resulting contact force and the pulling force of the tension spring (13) are balanced restraining force of the shaft (6) Ma acting on the arcuate aperture (41).

Images