KR200390541Y1 - Bimetal Relay for Multi-Step Motor Starting - Google Patents

Abstract

The present invention relates to an electromagnetic relay using a bimetal and an induction motor starting device using the electromagnetic relay, and more particularly, an input contact 11 attached to the electromagnetic relay main body 10 and the electromagnetic relay main body 10 and the input. On the bimetal 12 connected to the contact 11 and the operating contact 13 attached to the electromagnetic relay base 10 and the movable contact 14 electrically connected to the operating contact 13 and the movable contact 13. The lower part is connected, and the upper part is a thermostat 15 fixedly attached to the inside of the electromagnetic relay, a fixed contact 16 attached to the electromagnetic relay body 10, and a resistor 17 connected to the fixed contact 16; An electromagnetic relay 10 positioned between the resistor 17 and the bimetal 12 and including a heat carrier 18 for transferring the heat generated by the resistor to the bimetal; (10) multistage at each input It relates to the induction motor start-up device 20, comprising a step of grain to start the motor.

As such, the present invention functions as a simplifier of the starting circuit structure used when starting an induction motor by using an electromagnetic relay using heat generated from a resistor and a bimetal operated using the heat, and is consumed when starting due to a decrease in starting current. It has the effect of reducing the current and extending the life of the motor.

Description

Bimetal Relay for Multi-Step Motor Starting}

The present invention relates to an electromagnetic relay using a bimetal and an induction motor starting device using the electromagnetic relay, and more particularly, to an electromagnetic relay main body 10 and an input contact 11 attached to the electromagnetic relay main body 10. And a bimetal 12 connected to the input contact 11, an operating contact 13 attached to the electromagnetic relay base 10, a movable contact 14 electrically connected to the operating contact 13, and the movable contact ( 13, the lower part is connected, and the upper part is a thermostat 15 fixedly fixed inside the electromagnetic relay, a fixed contact 16 attached to the electromagnetic relay body 10, and a resistor connected to the fixed contact 16 ( 17) and the electromagnetic relay 10, which is located between the resistor 17 and the bimetal 12, and comprises a heat carrier 18 for transferring the heat generated in the resistor to the bimetal, This electromagnetic relay 10 is connected to each input terminal. Connected to stage it relates to the induction motor starting device 20, comprising a step of starting the motor.

Conventional induction motor starting methods include full voltage start, star-delta start, reactor start, primary resistance start and SCR start. The dual full voltage start has a merit that the acceleration torque is large and the starting time is short because the starting voltage is applied to the motor from the beginning, but the starting current is large and causes the voltage drop. On the other hand, the star-delta starting method can reduce the voltage drop caused by the maximum starting current by starting the motor connected in the △ connection and starting the Y connection only to reduce the starting current to 1/3 of full voltage starting. However, since the minimum starting acceleration torque is small, it is difficult to start the vehicle with the load connected, and there is a disadvantage in that electrical and mechanical shock is large because full voltage is applied when switching to operation after starting. The reactor starting method is to put the reactor on the primary side of the motor and start the motor by lowering the voltage of the motor by the voltage drop of the reactor at the start.The maximum starting current and minimum starting torque can be adjusted according to the tap change and the rotation of the motor increases. As a result, the acceleration torque is increased, but there is a disadvantage that the reduction of the starting torque is greater than the starting current. In the primary resistance start method, a resistor is inserted instead of a reactor start reactor and has similar advantages and disadvantages of the reactor start method.

Existing start methods as described above all have their advantages and disadvantages. However, except for the full voltage start method, the circuit configuration is generally complicated, additional devices such as timers are required, and wiring is complicated. there was.

The present invention has been devised to solve the above problems, using the heat generated in the inductor or the resistor by the current passing through the inductor or the resistor during startup in the inductor starting method or primary resistance starting method of the conventional method When the heat is transferred for a certain period of time, the switch conversion by the electromagnetic relay with the bimetal contact is automatically performed, so that it is possible to construct an induction motor starting device having a simple and efficient structure without attaching a separate complicated timer circuit or switch conversion circuit. The main object is to provide a multi-stage starting electromagnetic relay and its starting device.

In order to achieve the above object, the present invention provides an electromagnetic relay main body 10 and an input contact 11 attached to the electromagnetic relay main body 10 and a bimetal 12 connected to the input contact 11 and the electromagnetic relay main body. An operating contact 13 attached to the 10 and a movable contact 14 electrically connected to the operating contact 13 and a lower contact are connected to the movable contact 13, and an upper part is fixedly attached to the electromagnetic relay. Located between a thermostat 15 and a fixed contact 16 attached to the electromagnetic relay body 10 and a resistor 17 connected to the fixed contact 16 and between the resistor 17 and the bimetal 12. And, it characterized in that it comprises a heat transfer body 18 for transferring the heat generated in the resistance to the bimetal.

Hereinafter, a multi-stage starting electromagnetic relay according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1, the bimetal 12, the operating contact 13, the movable contact 14, the thermostat 15, the fixed contact 16, the resistor 17, as shown in FIG. It consists of the heat transfer body 18.

First, the electromagnetic relay body 10 will be described. The electromagnetic relay body 10 serves as a structure and a case for attaching each component constituting the electronic relay of the design. The electromagnetic relay body 10 is preferably made of a material that is resistant to heat and has insulation.

Next, the input contact 11 will be described. The input contact 11 is a portion in which power to drive an induction motor is introduced and is electrically connected to the bimetal 12 to be described later.

Next, the bimetal 12 will be described. The bimetal 12 is formed by bending two metal plates having different thermal expansion coefficients by a rolling method so that the two metal plates bend with an expansion difference, and have a property of bending toward a low-expansion material as the temperature rises. Therefore, it has a function of converting relatively small temperature change into very large displacement. By using this, it is used as a thermometer or as a switch which automatically operates by detecting a temperature change, and is widely used in household electrical equipment and the like. Examples of the material used for the bimetal 12 include an alloy having a very small thermal expansion such as Inba as a low expansion material, and a nickel-chromium-iron alloy, a nickel-manganese-iron alloy, a manganese-copper-nickel alloy, and the like as a high expansion material. In the initial stage of starting the induction motor using the present invention, the starting current flows through the resistor 17, which will be described later, and the heat generated therein is transferred to the bimetal 12 through the heat carrier 18, which will be described later. Once delivered, the bimetal will operate as shown in FIG. In this case, some time is required for the bimetal to operate while heat is transferred to the resistor, and this time interval can be adjusted by adjusting the distance between the bimetal 12 and the movable contact 14 to be described later. In other words, when the distance between the bimetal and the movable contact is close, the bimetal contacts the movable contact after a short time elapses, and when the distance between the bimetal and the movable contact is far, the bimetal is movable contact after a relatively long time elapses. Will come in contact with

Next, the operating contact 13 will be described. The operating contact 12 is a contact electrically connected to the input contact 11 when heat is transferred to the bimetal 12 to bend toward the low-expansion material, and serves as a support for the movable contact 14 to be described later. It is electrically connected to the movable contact 14. In this case, the distance between the working contact 13 and the movable contact 14 to be described later should be as close as possible without affecting the movement of the movable contact, and the gap therebetween is a conductive lubricant such as conductive grease. It is preferable to apply to increase the electrical conductivity.

Next, the movable contact 14 will be described. The movable contact 14 is attached to the operating contact 13 so as to be movable up and down along the machined hole. When the bimetal 12 is bent by heat transfer, the movable contact 14 is in direct contact with the bimetal 12. It serves to let through. On the other hand, the lower portion of the movable contact 14 is connected to the thermostat 15 to be described later, the position of the thermostat 15 is changed up and down depending on the degree of expansion or contraction according to the external temperature so that the bimetal 12 The spacing will change.

Next, the thermostat 15 will be described. The thermostat 15 is used to convert a change in temperature into a change in physical shape by thermal expansion of a material, and has a property of expanding when the outside temperature is high and shrinking when the temperature is low. According to the shape change of the thermostat 15, the movable contact 14 connected thereto is moved up and down with respect to the operating contact 13. As a result, the bimetal 12 and the movable contact are changed. The interval between (14) also changes. That is, when the external temperature is high, the thermostat 15 expands, and as a result, the gap between the movable contact 14 and the bimetal 12 is widened. When the external temperature is low, the thermostat 15 ) Contracts and as a result the gap between the movable contact 14 and the bimetal 12 becomes narrow. On the other hand, when a current equal to a predetermined time flows in the resistor 17 to be described later, the amount of heat transferred to the bimetal 12 is affected by the ambient temperature. Therefore, when the same amount of current flows, when the ambient temperature is high, The bimetal 12 is operated after a relatively short time elapses, and when the ambient temperature is low, a difference in operating time at which the bimetal 12 is operated after a relatively long time elapses occurs. Therefore, if the driving environment of the induction motor is affected by seasons or temperature changes by using the thermostat 15, the change in the operating time of the bimetal 12 is thereby corrected, and the external temperature change Regardless of this, the bimetal 12 can be operated over a relatively constant time. On the other hand, by adjusting the position of mounting the thermostat 15 it is possible to adjust the time interval for the bimetal 12 to operate. That is, if the position of the thermostat 15 is adjusted so that the distance between the movable contact 14 and the bimetal 12 is farther away, the operation time of the bimetal 12 becomes longer, and the thermostat 15 If the position of the movable contact 14 and the bimetal 12 is adjusted to be close to the operation time of the bimetal 12 is shortened. On the other hand, the thermostat 15 is preferably installed as far as possible so as not to be affected by the heat generated by the resistor 17 to be described later or to be installed on the outer side of the electromagnetic relay main body 10.

Next, the fixed contact 16 will be described. The fixed contact 16 is a contact that is in contact with the bimetal 12 when heat is not transferred to the bimetal 12 to maintain its original shape.

Next, the resistor 17 will be described. The resistor 17 serves to reduce the starting current by lowering the starting voltage when starting the induction motor, and serves to operate the bimetal 12 using heat generated in this case. On the other hand, in the case of using an inductor instead of the resistor 17 has the same effect.

Hereinafter will be described the multi-stage starting electromagnetic relay action using a bimetal according to an embodiment of the present invention.

First, in the initial stage of starting the induction motor, the starting current flows through the resistor through the fixed contact at the input contact, as shown in FIG. 3, and a voltage drop occurs, thus reducing the starting current of the motor. In this state, after some time after the motor starts to rotate, the bimetal is operated by the heat generated by the resistance, and it comes out of the fixed contact point and comes into contact with the movable contact point. Therefore, in this case, the driving current is directly transmitted to the electric motor without passing through the resistor as shown in FIG.

On the other hand, as shown in Figure 5, when the electronic relay of the present invention is connected in series to each input terminal of the motor in multiple stages, the operating time of the electronic relay of the input terminal is adjusted the fastest and the electronic relay is gradually By adjusting the operation time longer, it becomes possible to smoothly start the motor in multiple stages, eliminating the shortening of the motor life due to the operating shock or rapid current change without the need for separate complicated wiring or additional circuits and devices. It reduces the errors caused by complicated wiring during installation and use.

As described above, according to the present invention, the bimetal is operated in a simple structure without being influenced by external temperature change, and operated after a certain time has passed after a current flows as previously adjusted without a separate circuit such as a timer. It is possible to implement the electromagnetic relay, and when constituting the starting circuit of the induction motor using the same, eliminating the shortening of the motor life due to the operating shock or rapid current change without the need for additional complicated wiring or additional circuits and devices, It reduces the errors caused by complicated wiring during construction and use, and it is possible to smoothly start the motor in multiple stages.

1 is a structural diagram of a multi-stage starting electromagnetic relay according to an embodiment of the present invention

2 is a structural diagram of the operation of the multi-stage starting electromagnetic relay according to an embodiment of the present invention

3 is a circuit diagram for starting using a multi-stage starting electromagnetic relay according to an embodiment of the present invention

4 is a circuit diagram when driving using a multi-stage starting electromagnetic relay according to an embodiment of the present invention

5 is a circuit diagram of multi-stage starting using a multi-stage starting electromagnetic relay according to an embodiment of the present invention

<Description of Symbols Used in Main Parts of Drawing>

10: electromagnetic relay main body 11: input contact point

12: bimetal 13: operating contact

14: movable contact 15: thermostat

16: fixed contact 17: resistance

18: heat transfer body 20: induction motor starting device

Claims (3)

Main body 10; An input contact 11 attached to the electromagnetic field basic body 10; A bimetal 12 connected to the input contact 11; An operating contact 13 attached to the electromagnetic relay base 10; A movable contact (14) electrically connected to the actuation contact (13); A thermostat (15) having a lower portion connected to the movable contact (13) and fixed to an inner portion of the electromagnetic relay; A fixed contact 16 attached to the electromagnetic relay main body 10; A resistor 17 connected to the fixed contact 16; And a heat transferer (18) located between the resistor (17) and the bimetal (12) and transferring heat generated by the resistor to the bimetal. Main body 10; An input contact 11 attached to the electromagnetic field basic body 10; A bimetal 12 connected to the input contact 11; An operating contact 13 attached to the electromagnetic relay base 10; A movable contact (14) electrically connected to the actuation contact (13); A thermostat (15) having a lower portion connected to the movable contact (13) and fixed to an inner portion of the electromagnetic relay; A fixed contact 16 attached to the electromagnetic relay main body 10; An inductor 17 connected to the fixed contact 16; An electronic relay positioned between the resistor 17 and the bimetal 12 and including a heat carrier 18 transferring heat generated by the resistor to the bimetal. An induction motor starting device (20) characterized in that the motor is started by connecting the electromagnetic relay of claim 1 or 2 to each input terminal in multiple stages.