KR200399345Y1 - A Centrifugal force Switch - Google Patents

Abstract

The present invention relates to a centrifugal switch having an overload prevention device integrally provided with an overload protection device in a centrifugal switch installed in a single-phase induction motor. The centrifugal switch having an overload protection device of the present invention includes a housing; A switch device installed at one side of the housing to operate an electric motor and switched by centrifugal force to rotate at a constant speed when the electric motor is operated to reach a predetermined rotation speed; And an overload prevention device provided on the other side of the housing and protecting the electric motor by temporarily disconnecting power of the motor when an overload occurs. Therefore, the centrifugal switch of the present invention, which is integrally provided with the switch device and the overload protection device of the centrifugal switch in one housing, has the effect of reducing the product cost by reducing the number of necessary parts of the product by integrating the overload prevention device. And by arranging the wires installed inside the motor can reduce the short-circuit and short-circuit that can be generated inside it has the effect of extending the product life.

Description

Centrifugal switch with overload protection {A Centrifugal force Switch}

The present invention relates to a centrifugal switch provided with an overload protection device, and more particularly, to a centrifugal switch installed in a single phase induction motor integrally provided with an overload protection device.

In general, an electric motor plays an important role in driving all devices, and is a device that converts electrical energy into kinetic energy (rotational energy). These motors are classified into a DC motor and an AC motor according to a power supply method. AC motors are classified into synchronous motors, induction motors, and commutator motors according to the principle and structure of the motor. Induction motors are classified into single-phase and three-phase motors according to the power supply constant.

Here, single-phase induction motors are widely used because they are relatively easy to supply power in homes, offices and factories. However, single-phase motors, unlike three-phase motors, do not form a magnetic field, and thus cannot operate the motor by itself.

Therefore, the motor has a main winding and an auxiliary winding that is out of phase with the main winding by using a condenser and the like. The motor is connected to the main winding and the auxiliary winding to operate. When a certain rotational speed is reached, the power supply of the auxiliary winding is supplied by centrifugal force. A centrifugal switch to shut off is used.

The centrifugal switch flows in the form of sliding and rotation in the direction of centrifugal force acting by the centrifugal force while the centrifugal weight is interlocked with the rotating shaft such as the rotor of the electric motor, and moves in the axial direction from the shaft by the flow of the centrifugal weight. It is actuated by sliders which are combined as much as possible.

On the other hand, the motor is provided with an overload prevention device to prevent the overload of the motor according to the overcurrent and overvoltage supply. The overload protection device is provided separately from the centrifugal switch and installed on either side of the motor.

Since the centrifugal switch and the overload prevention device are separately provided and assembled, respectively, the number of parts required increases, and the number of assembly processes increases by installing each inside the motor, thereby increasing the product cost.

In addition, since the centrifugal switch and the overload protection device are separately installed inside the motor, the wires connected inside are tangled in and out, resulting in a high defect rate due to short circuits and short circuits, thereby shortening the product life.

Therefore, there is a need for a centrifugal switch that reduces the cost of each product by reducing the number of parts used in the centrifugal switch and the overload protection device and collectively arranges the wires wired inside the motor.

The present invention was conceived in view of the above necessity, and an object of the present invention is to provide a centrifugal switch that can reduce the cost of a product by reducing the number of necessary parts of a centrifugal switch and an overload protection device.

In addition, another object of the present invention is to provide a centrifugal switch that can extend the life of the product by arranging the wires wired inside the motor.

The present invention for achieving the above object is a housing; A switch device installed at one side of the housing to operate an electric motor, installed at one side of the housing to operate an electric motor, and switched by centrifugal force to rotate at a constant speed when the motor is operated to reach a predetermined rotational speed; And an overload prevention device provided on the other side of the housing and protecting the electric motor by temporarily disconnecting power of the motor when an overload occurs.

Here, it is preferable that the housing is provided with an installation portion for installing the overload protection device.

And, it is preferable that the mounting portion is provided with a coupling protrusion at the edge, and to provide a cover to cover and protect the mounting portion.

In addition, the cover is provided with a coupling portion at the edge, it is preferable that the coupling protrusion is inserted and fixed by forming a coupling groove in the coupling portion.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of the present invention, terms defined are defined in consideration of functions in the present invention, it should not be understood as a meaning limiting the technical components of the present invention.

1 is a front view showing the installation state of the centrifugal switch according to the present invention, Figures 2a to 2b is an internal plan view showing the operating state of the centrifugal switch according to the present invention, Figure 3 is a cover of the overload protection device according to the present invention Is a perspective view showing a centrifugal switch in an open state.

Figure 4 is an exploded perspective view showing an overload protection device integrally installed in the centrifugal switch according to the present invention, Figures 5a to 5b is a cross-sectional view showing the operating state of the overload protection device integrally installed in the centrifugal switch according to the present invention.

Centrifugal switch of the present invention as shown in the accompanying drawings, as shown in Figure 1, the centrifugal switch 100 is installed on the housing 10, one side of the housing 10 is a switch device for operating and constant speed rotation according to the centrifugal force of the electric motor 20, provided on the other side of the housing is provided with an overload protection device 30 to protect by temporarily disconnecting the power of the motor when an overload occurs.

The centrifugal switch 100 is installed to operate at a constant speed by operating the electric motor (1). That is, the electric motor (1) is fixed to the rotor (2) rotating in the inside, the shaft (3) in cooperation with the rotor, the shaft (3) is provided to flow by centrifugal force when rotating at a constant speed The centrifugal weight 4 and the slider 5 sliding in the axial direction while contacting the shaft 3 by the flow of the centrifugal weight 4 are provided. Therefore, the centrifugal switch 100 is installed to be operated by a sliding action on the shaft 3 of the slider 5.

The switch device 20 installed on one side of the housing 10 includes a lever 21 installed in contact with the slider 5 of the electric motor 1 as shown in FIGS. 1 and 2, and the lever 21. It is operated by, the contact terminal is formed on both sides of the free end of the cantilever shape, switching terminal 22 for switching and switching, and when the electric motor 1 is operated and is switched to the switching terminal 22, the electric motor (1) It is provided with the auxiliary winding terminal 23 which generate | occur | produces the operating torque to the electric motor 1, and operates the rotor 2 by supplying an electric current.

The rotor 2, the shaft 3, the centrifugal weight 4, the slider 5, the lever 21 of the switch device 20, the switching terminal 22, which are installed inside the electric motor 1, Since the auxiliary winding terminal 23 is a known technique, a detailed description of the operation is omitted.

Meanwhile, as shown in FIGS. 3 to 5, the overload protection device 30 installed on the other side of the housing 10 is exposed to the outside, and is provided with a terminal 31 connected to a power line and the terminal 31. A resistance heating element 32 having one end connected to generate high temperature heat during overcurrent and overvoltage, and a movable terminal 33 spaced apart from the resistance heating element 32 at a predetermined interval to switch on / off a power source; A support terminal 34 connected to the other end of the resistance heating element 32 and supporting the movable terminal 33 in a state spaced apart from the resistance heating element 32, and the resistance heating element 32 and the movable terminal 33. ) Is provided between the bimetal 36 and the fixed terminal 35 that is energized or disconnected from the movable terminal 33.

The other side of the housing 10 is provided with an installation portion 11 is installed the overload protection device 30. In this case, the mounting portion 11 is provided by concave to a predetermined depth. In addition, the installation part 11 may be provided by protruding the inside of the protrusion after protruding to a predetermined width.

The installation portion 11 has a coupling protrusion (11a) is formed at the edge. Herein, the coupling protrusion 11a is formed at least one or four or less along the edge of the installation portion 11. In addition, the installation unit 11 has two stepped portions 11b and 11c so that the resistance heating element 32 and the bimetal 36 of the overload protection device 30 do not come into contact with each other. The inside of the first step 11b is fixed by mounting the resistance heating element 32, and the second step 11c is variable and movable due to the heating of the resistance heating element 32 by seating the edge of the bimetal 36. The terminal 33 is supported to be lifted up.

The installation unit 11 is provided with a cover 12 to cover and protect the inside, the cover 12 is provided with a coupling portion 13 at the edge. Here, the coupling part 13 is formed at least one or four or less along the edge of the cover 12. The coupling portion 13 forms a coupling groove 13a having a constant elastic force, and the coupling groove 13a is inserted into and fixed to the coupling protrusion 11a.

In addition, in another embodiment, the coupling groove is provided at the edge of the installation part 11 to replace the coupling protrusion 11a, and the coupling part 13 of the cover 12 has the coupling groove 13a having a constant elastic force. It may be fixed by forming a coupling protrusion in place of.

The housing 10 has a terminal drawer 14 having a switch device 20 so that the terminals and terminals of the switch device 20 and the overload protection device 30 are drawn out and connected by using a separate connector (not shown). ) And the overload protection device 30 are provided in the adjacent position.

Therefore, the arrangement of the switch device 20 and the terminal lead-out portion 14 of the overload protection device 30 is connected together to facilitate the arrangement of the wires wired inside the electric motor 1. In addition, the terminals can be directly connected to each other or wired in the installation unit 11 or the terminal lead-out unit 14 of the housing 10 to which the switch device 20 and the overload protection device 30 are connected. The number of wires to be wired can be reduced. In addition, the switch device 20 and the overload protection device 30 are integrally formed in one housing 10 to reduce the number of parts required.

Hereinafter, the operation in the state in which the centrifugal switch 100 of the present invention is installed in the electric motor 1 will be described in detail with reference to FIGS. 1 to 5.

When the power is supplied, the supplied power is supplied to the overload protection device 30 to determine the presence of overvoltage and overcurrent. After discrimination, if it is discriminated as a power supply of rated voltage and electric shock current, it is supplied to the resistance heating element 32 through the terminal 31 as shown in FIG. 5A. The power supplied to the resistance heating element 32 is supplied to the movable terminal 33 via the support terminal 34, and the switch device 20 via the movable terminal 33 and the fixed terminal 37 in contact with the contact. Is supplied.

Then, a rotor installed in the electric motor 1 by being supplied to the auxiliary winding terminal 23 having a different phase as shown in FIG. 2A in order to operate the electric motor 1 with the power supplied to the switch device 20. Generate a magnetic field to rotate (2).

After the rotor 2 is operated to reach a constant speed (70-80% of the synchronous speed), the shaft 3 together with the rotor 2 rotates and the centrifugal weight 4 interlocks with the rotor 3. ) Rotates. And the slider 5 is operated along the shaft by the rotation of the centrifugal weight 4. (See Figure 1)

Thereafter, the lever 21 of the switch device 30 is rotated by the operation of the slider 5, and as shown in FIG. 2B, the switching terminal 22 of the auxiliary winding terminal 23 is rotated by the lever 21. It is disconnected from the contact. The contact point is switched through the elastic force of the switching terminal 22 or a separate elastic member. Then, the rotor 2 of the electric motor 1 rotates at a constant speed while increasing to the synchronous speed.

After that, when the power is cut off to the motor 1 due to disconnection or short circuit, or when the user cuts off the power supply, the rotation speed of the rotor 2 is lowered, and the speed is lowered below a certain speed and centrifugal weight ( The centrifugal force of 4) is lowered and the slider 5 is returned to the initial position.

Then, as the slider 5 returns to the initial position, the lever 21 of the switch device 20 is rotated to press the switching terminal 22 to contact the contact of the auxiliary winding terminal 23 as shown in FIG. 2A. The rotation of the rotor 2 is stopped by switching to.

Hereinafter, the operation when overcurrent and overvoltage or high heat is generated during rotation and operation of the motor will be described in detail with reference to FIG. 5.

When the overcurrent flows through the motor 1, the resistance heating element 32 rapidly generates heat in a short time through the terminal 31 of the overload protection device 30. As the temperature of the resistance heating element 32 generated in a short time rises, the bimetal 36 is heated as shown in FIG. 5B, and the heated bimetal 36 is deformed by the coefficient of thermal expansion. That is, the bimetal 36 of the inverted triangular shape is inverted into a triangular shape. The bimetal 36 inverted in a triangular shape pushes up the free end of the movable terminal 33 positioned on the upper side, and the movable terminal 33 is pushed upward, and is separated from the contact point of the fixed terminal 35 at the same time. do. Therefore, the power supplied to the motor is cut off.

At this time, when the power of the electric motor 1 is cut off, the user checks the cause of the abnormality of the electric motor 1 and removes it. Here, the cause of abnormality refers to the cause of the overload of the motor due to a short circuit, a short circuit, and an overvoltage and overcurrent.

Thereafter, when a certain time elapses while the cause of the abnormality is removed or the power is cut off, the temperature of the heated bimetal 36 is lowered and restored to the inverted triangle shape in a triangular shape as shown in FIG. 5A. The restored bimetal 36 is spaced apart from the free end of the movable terminal 33 and the movable terminal 33 is returned to its original position. In other words. The movable terminal 33 is connected to the contact of the fixed terminal 35 so that the power supply of the electric motor 1 is energized.

Although the technical idea of the centrifugal switch with an overload protection device of the present invention has been described with the accompanying drawings, this is illustrative of the best embodiment of the present invention and is not intended to limit the present invention. Therefore, it is apparent that anyone with ordinary skill in the art can make various modifications and imitations such as dimensions, shapes and structures without departing from the scope of the technical idea of the present invention.

As described above, the centrifugal switch of the present invention, which is integrally provided with the switch device and the overload protection device of the centrifugal switch in one housing, has the effect of reducing the product cost by reducing the number of necessary parts of the product by integrating the overload prevention device.

In addition, by arranging the electric wires installed inside the motor, short-circuits and short circuits that can be generated in the interior are reduced, thereby extending the service life of the product.

1 is a front view showing an installation state of the centrifugal switch according to the present invention.

Figure 2a and Figure 2b is an internal plan view showing the operating state of the centrifugal switch according to the present invention.

Figure 3 is a perspective view showing a centrifugal switch in the open state of the cover of the overload protection device according to the present invention.

Figure 4 is an exploded perspective view of the overload protection device integrally installed in the centrifugal switch according to the present invention.

Figures 5a and 5b is a cross-sectional view showing the operating state of the overload prevention device integrally installed in the centrifugal switch according to the present invention.

* Description of the symbols for the main parts of the drawings *

1: electric motor 2: rotor

3: shaft 4: centrifuge

5: slider 10: housing

11: mounting portion 11a: engaging projection

12: cover 13: coupling part

13a: coupling groove 14: terminal outlet

20: switch unit 21: lever

22: switching terminal 23: auxiliary winding terminal

30: overload protection device 31: terminal

32: resistance heating element 33: movable terminal

34: support terminal 35: fixed terminal

36: bimetal

Claims (4)

housing; A switch device installed at one side of the housing to operate an electric motor and switched by centrifugal force to rotate at a constant speed when the electric motor is operated to reach a predetermined rotation speed; And an overload prevention device provided at the other side of the housing and protecting the electric motor by temporarily disconnecting the power of the motor when an overload occurs. The method of claim 1, The housing is a centrifugal switch, characterized in that the installation portion is provided with an overload protection device is installed. The method of claim 2, The installation portion is formed with a coupling protrusion at the edge, Centrifugal switch characterized in that the cover is provided to cover and protect the mounting portion The method of claim 3, wherein The cover is provided with a coupling portion at the edge, Centrifugal switch, characterized in that the coupling protrusion is formed by forming a coupling groove in the coupling portion.