KR20100003779U - Assemblage structure between release lever andtemperature compensation bimetal in overload thermalrelay - Google Patents

Abstract

The present invention relates to a combined structure of the thermal compensation bimetal and the release lever of a thermal overload relay, and is a form of a temperature compensation bimetal that can satisfy both the curvature and the length compensation of the bimetal without leaving the upper case of the thermal overload relay. The combination structure with the release lever to prevent torsion and external interference of the temperature compensated bimetal, and the bending operation is not interfered with other components during the bending operation of the temperature compensated bimetal corresponding to various temperature changes. It is to provide the combined structure of temperature compensation bimetal and release lever of thermal overload relay.

 After the upper side of the temperature compensation bimetal according to the present invention is bent in a '∩' shape to pivot the upper part of the release lever, one end is fixed to the release lever, and the other end passes through the interference prevention hole formed in the release lever. It is formed extending in the downward direction, characterized in that the separation space is formed between the upper portion of the release lever and the temperature compensation bimetal bent in a '∩' shape.

Thermal overload relay, temperature compensation bimetal, release lever

Description

Assemblage structure between release lever and temperature compensation bimetal in overload thermal relay

The present invention relates to a coupling structure of a temperature compensation bimetal and a release lever of a thermal overload relay, and more specifically, can satisfy both the curvature and the length compensation ratio of a bimetal without leaving the upper case of the thermal overload relay. The present invention relates to a form of a temperature compensated bimetal and a coupling structure of a temperature compensated bimetal and a release lever to prevent torsion and external interference of the temperature compensated bimetal.

In general, the thermal overload relay forms an electromagnetic switch together with a magnetic contactor to prevent the motor from being burned out by tripping the circuit after a predetermined time when the current supplied to the motor exceeds the preset current value. It is an electric device.

Typically, in the case of an AC motor, an alternating current of three phases (R, S, T) flows in the interior thereof. At this time, any one of the three phases is broken so that no current flows (phase). As the current is concentrated or the temperature rises during overload or overcurrent, the winding is burned out. In order to prevent this, the motor is usually overloaded as mentioned above to prevent burnout during overload or phase open. Connect the relay to use.

A detailed configuration of the above-described overload relay will be described with reference to FIGS. 1 to 3.

1 to 3 show a conventional thermal overload relay, FIG. 1 is a perspective view of a conventional thermal overload relay, and FIG. 2 is a longitudinal cross-sectional view of the thermal overload relay along the line II-II of FIG. 1. to be.

1 and 2, the conventional thermal overload relay is largely connected to a circuit between a power supply and a load, that is, a motor, as shown in FIGS. 1 and 2, and a heater unit 11 located under the overload relay that generates heat when an overcurrent or an image occurs. To the opening and closing mechanism part 21 located in the upper part of the overload relay for interlocking the circuit between the power source and the load, interlocking with the curvature of the main bimetal 13 that bends with the heat generated by the heater part 11 in the heater part 11. Can be distinguished.

Here, the lower case (12) inside the main bimetal 13, the main bimetal 13, the heater (14), the main bimetal (13) which is driven and connected to the main bimetal 13 to form a heater portion 11 A shifter 15 and the like which move horizontally in accordance with the curvature are incorporated, and externally, three main terminals 10 (for three-phase alternating current) to which a power supply side wire is connected are provided.

In addition, the upper case 22 connected to the upper portion of the lower case 12 includes a release lever 23, an inversion mechanism 26, a reset button 29, and an auxiliary holder (23) forming the opening / closing mechanism 21. 31) and the like.

Here, the release lever 23 provided in the upper case 22 is provided with a temperature compensation bimetal 24, rotates in conjunction with the rotation of the temperature compensation bimetal 24 to rotate the center of the reversal mechanism 26. A protruding pressing portion 25 to pressurize the portion 27.

The reverse mechanism 26 includes a central portion 27 and a reverse spring 28 fitted between the central portion 27 and the reverse mechanism 26. In the normal energized state, the central portion 27 is the reverse mechanism portion. Lifted up (26) and this state is configured to be held by the reversing spring (28).

Here, a detailed configuration of the temperature compensation bimetal 24 provided at one side of the release lever 23 will be described with reference to FIG. 3.

3 is a front view showing the configuration of the temperature compensation bimetal provided in the conventional thermal overload relay.

The temperature compensation bimetal 24 is provided to compensate for a phenomenon in which the main bimetal 13 is curved in response to the ambient temperature without the heat of the heater 11, and is a constant distance from the shift 15 regardless of the ambient temperature. It is provided to maintain.

As shown in FIG. 3, the temperature compensation bimetal 24 is configured to rotate counterclockwise with reference to the direction of FIG. 2 in conjunction with the shift of the shift ring 16. It is composed of materials of different materials with different coefficients of thermal expansion so that they can bend as the temperature changes.

That is, the temperature compensation bimetal 24 transfers the pressing force transmitted from the shift ring 16 to the release lever 23 as the shift 15 moves in parallel, thereby causing the release lever 23 to be released. It is configured to rotate to open and close the contact provided on the reversal mechanism 26.

However, the temperature compensation bimetal 24 requires a predetermined thickness and length when calculating the amount of curvature proportional to the change in the ambient temperature, and the conventional temperature compensation bimetal 24 has a predetermined position at the release lever 23. Since the length of the temperature compensation bimetal 24 is too long in being attached to the lower side after being attached, one end portion of the temperature compensation bimetal 24 is separated from the upper case 22, and an assembly structure is accommodated in the lower case 12.

At this time, the temperature compensation bimetal 24 having one end housed in the lower case 12 has a problem in that an amount of curvature more than necessary is generated due to heat generated from the heater 11 and the main bimetal 13.

In addition, the conventional temperature compensation bimetal 24 may have a torsional phenomenon during bending due to temperature change, but there is no prevention means for this, and there is a fear that interference may be caused from various peripheral elements. There was also a problem that was not laid.

Accordingly, the present invention has been made to solve the above-described problems of the prior art, and provides a form of temperature compensation bimetal that can satisfy both the curvature and the length compensation of the bimetal without departing from the upper case of the thermal overload relay. There is a purpose of the present invention.

In addition, another object of the present invention is to provide a coupling structure with the release lever that can prevent torsion and external interference of the temperature compensation bimetal.

Another object of the present invention is to provide a coupling structure in which the bending operation is not interrupted by other components during the bending operation of the temperature compensation bimetal corresponding to various temperature changes.

As a technical means for achieving the above object, the present invention is a main bimetal that is curved when an overcurrent occurs in the main circuit, a shift is installed to be horizontally moved by the main bimetal, and the release is rotated by the pressing force transmitted from the shift A lever, and an inverting mechanism part which is kept in a state separated from the corresponding terminal during normal operation and is inverted into contact with the corresponding terminal by the rotational force of the release lever when an overcurrent occurs, and one end thereof is mounted on one side of the release lever. And the other end of which is in contact with the shift and includes a temperature compensating bimetal for transmitting a pressing force generated in the shift to the release lever, wherein the upper side of the temperature compensating bimetal is pivoted so as to pivot the upper part of the release lever. After bending in the shape of '자', one end is fixed to the release lever. The other end is formed to extend downward after passing through the interference prevention hole formed in the release lever, and a separation space is formed between the upper portion of the release lever and the temperature compensation bimetal bent in a '∩' shape. do.

According to the combined structure of the temperature compensation bimetal and the release lever of the thermal overload relay according to the present invention, the following effects are obtained.

First, the temperature compensation bimetal bent by maintaining the length sufficiently in the shape of '∩' has an effect of satisfying the length compensation rate.

Second, the interference prevention hole formed in the release lever so that the temperature compensation bimetal penetrates through, there is also an effect to prevent torsion and external interference of the temperature compensation bimetal.

Third, the separation space formed between the upper part of the release lever and the temperature compensation bimetal bent in a '∩' shape has the effect of providing sufficient free space for the temperature compensation bimetal to respond to various temperature changes.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Figure 4 is a front internal front view showing a thermal overload relay according to an embodiment of the present invention, Figure 5 is a front internal view of the thermal overload relay showing only the main part except the case in Figure 4, Figure 6 is a thermal A perspective view of the main part of a homogeneous overload relay.

4 to 6, the thermal overload relay 1 according to the embodiment of the present invention is horizontal by the main bimetal 13 and the main bimetal 13, which are curved when an overcurrent occurs in the main circuit. The shift 15 is installed to be movable, the release lever 200 rotated by the pressing force transmitted from the shift 15, and the release lever 200 in a state in which it is separated from a corresponding terminal during normal operation, and overcurrent occurs. The reverse mechanism 26 and one end thereof inverted in contact with the corresponding terminal by the rotational force of 200 are mounted on one side of the release lever 200, and the other end thereof is in contact with the shift 15. It is configured to include a temperature compensation bimetal 100 for transmitting the pressing force generated in the shift 15 to the release lever 200.

7 is an assembled perspective view illustrating a coupling structure of a temperature compensation bimetal and a release lever of a thermal overload relay according to an embodiment of the present invention, FIG. 8 is a front sectional view, and FIG. 9 is an exploded perspective view.

The temperature compensation bimetal 100 has a curved shape in a '∩' shape so that the upper side turns the upper portion of the release lever 200 to satisfy the length compensation rate by maintaining the length sufficiently, and the curved temperature compensation bimetal ( One end of the 100 is fixed to the body side of the release lever 200 and the other end is formed extending in the lower direction.

The release lever 200 is a pressing force transmitted from the shift 15 to be transmitted from the temperature compensation bimetal 100 to rotate, and the fixing protrusion 210 protruding so that the temperature compensation bimetal 100 is fixed to an upper side thereof. A fixing snap ring 220 is fitted to the fixing protrusion 210, and the lower side is bent toward the inversion mechanism part 26, but the interference preventing hole 230 is positioned at a predetermined position so that the temperature compensation bimetal 100 can penetrate through the fixing protrusion 210. The bent end is formed in the pressing projection 240 is formed so as to press the inverting mechanism portion 26 during the rotation operation of the release lever 200.

The temperature compensation bimetal 100 is fitted to the fixing protrusion 210 of the release lever 200 by being fixed to the upper side of the release lever 200, the fixing groove 110 is formed at one end, and fixed The temperature compensation bimetal 100 may be coupled to the release lever 200 by the combination of the snap ring 220 and the fixing protrusion 210.

In addition, a predetermined separation space (h) is formed between the upper portion of the release lever 200 and the temperature compensation bimetal 100 bent in a ',' shape, which is a temperature compensation bimetal 100 according to the ambient temperature. It is a configuration in which a free space that can be displaced to compensate for both a temperature higher than the ambient temperature (20 ℃ according to an embodiment of the present invention) and a low temperature as a reference in the curved.

10 to 12 illustrate changes in the separation space of the release lever and the temperature compensation bimetal in the coupling structure of the temperature compensation bimetal and the release lever of the thermal overload relay according to the embodiment of the present invention, and FIG. Figure 11 shows the separation space of the compensation bimetal and the release lever, Figure 11 shows the separation space of the temperature compensation bimetal and release lever at a temperature higher than the reference temperature, Figure 12 shows the temperature compensation bimetal and release at a temperature lower than the reference temperature It shows the separation space of the lever.

As described above, as the temperature compensation bimetal 100 is higher and lower than the reference temperature, its curvature direction is changed, so that the displacement operation of the temperature compensation bimetal 100 is not restricted, the release lever 200 and the temperature compensation bimetal 100 are mutually different. In the predetermined space h is to be formed.

The temperature compensation bimetal 100 is bent in a '∩' shape, but part of which is not fixed to the release lever 200, extends downward through the interference preventing hole 230 of the release lever 200, thereby preventing interference. The temperature compensation bimetal 100 coupled to the ball 230 is prevented from twisting due to temperature change, and such a coupling structure provides a protection function of the temperature compensation bimetal 100 against various external interferences.

As described above, although the technical idea of the present invention has been described with reference to the preferred embodiments, those skilled in the art will appreciate that the present invention is within the scope and spirit of the present invention described in the following Utility Model Registration Claims. It can be modified and changed in various ways.

1 to 3 show a conventional thermal overload relay,

1 is an overall perspective view of a conventional thermal overload relay,

2 is a longitudinal cross-sectional view of the thermal overload relay along the II-II line of FIG.

3 is a front view illustrating a temperature compensation bimetal and a release lever provided in a conventional thermal overload relay.

4 to 6 illustrate a thermal overload relay according to an embodiment of the present invention,

4 is a front internal front view of the thermal overload relay according to the present invention,

FIG. 5 is a front view of the inner part of the thermal overload relay showing only the main parts except the case in FIG. 4;

Figure 6 is a perspective view of the main part of the thermal overload relay according to the present invention.

7 to 9 illustrate a coupling structure of a temperature compensation bimetal and a release lever of a thermal overload relay according to an embodiment of the present invention,

7 is an assembled perspective view illustrating a coupling structure of a temperature compensation bimetal and a release lever according to the present invention,

8 is a front sectional view showing a coupling structure of a temperature compensation bimetal and a release lever according to the present invention,

9 is an exploded perspective view illustrating a coupling structure of a temperature compensation bimetal and a release lever according to the present invention.

10 to 12 illustrate changes in the separation space of the release lever and the temperature compensation bimetal in the coupling structure of the temperature compensation bimetal and the release lever of the thermal overload relay according to the embodiment of the present invention.

FIG. 10 illustrates the separation space between the temperature compensation bimetal and the release lever at a reference temperature.

11 shows the separation space of the temperature compensation bimetal and the release lever at a temperature higher than the reference temperature.

FIG. 12 illustrates the separation space between the temperature compensation bimetal and the release lever at a temperature lower than the reference temperature.

<Description of Symbols for Main Parts of Drawings>

1: thermal overload relay 13: main bimetal

15: shift 26: reverse mechanism

100: temperature compensation bimetal 110: fixing groove

200: release lever 210: fixing protrusion

220: snap ring 230: interference prevention hole

240: pressing projection h: separation space

Claims (1)

A main bimetal 13 that is curved when an overcurrent occurs in the main circuit, a shift 15 installed to be horizontally moved by the main bimetal 13, and a release lever rotated by a pressing force transmitted from the shift 15. 200 and the inversion mechanism part 26 and one end thereof which are kept separated from the corresponding terminals in the normal operation and inverted to contact with the corresponding terminals by the rotational force of the release lever 200 when an overcurrent occurs. It is mounted on one side of the release lever 200 and the other end is in contact with the shift 15 and includes a temperature compensation bimetal 100 for transmitting the pressing force generated in the shift 15 to the release lever 200 In thermal overload relays, The upper side of the temperature compensation bimetal 100 is bent in a '∩' shape to pivot the upper portion of the release lever 200, and then one end is fixed to the release lever 200, and another end of the release lever 200 is fixed. After extending through the interference prevention hole 230 formed in the lower direction, the separation space (h) between the upper portion of the release lever 200 and the temperature compensation bimetal 100 bent in a '∩' shape Combined structure of the temperature compensation bimetal and the release lever of the thermal overload relay.

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