KR101037777B1 - Thermal overload relay having test button device - Google Patents

Abstract

The present invention relates to a thermal overload relay in which a test button is formed, the open position of the main circuit first contact and the main circuit second contact, and the inverting mechanism first contact and the inverting mechanism second contact in the thermal overload relay. It is to provide a test button which can be operated by pressing and drawing the test button of the closing position.

In addition, the present invention is that the entire configuration of the test button is injection-molded in a single configuration, the elastic support bar is formed in the transverse direction is coupled to the housing inner wall coupled to support the elastic force to return to the original position without using a spring To provide.

Thermal overload relay, test button, elastic means

Description

Thermal overload relay having test button device}

The present invention relates to a thermal overload relay having a test button. More specifically, the thermal overload relay includes a means for testing whether the main circuit contact operation and the inverting mechanism contact operation are normal in the thermal overload relay. It is about relay.

In general, the thermal overload relay is composed of a heater unit that generates heat by an overcurrent and an opening / closing mechanism unit that operates mechanically according to the heat generated by the heater unit to trip a contact. When the current of the motor reaches a predetermined current value or more, It is an electric device that plays an important role in preventing the burnout of the motor by tripping the circuit after a designated time.

Normally, a current of three phases (R phase, S phase, T phase) flows to the motor, but if any one of the three phases is cut off and no current flows, an overload occurs as the current is concentrated in the remaining phases. Accordingly, problems such as damage to the winding insulation due to the temperature rise due to the overload occurs. In order to prevent this, in general, the overload relay as described above is connected to the motor in order to prevent burnout during overload or phase loss.

For this overload relay, Figure 1 is a perspective view of a conventional thermal overload relay, Figure 2 is a longitudinal cross-sectional view of the thermal overload relay taken along the line (II-II) of Figure 1, Figure 3 (a) Fig. 3B shows a case where the switch mechanism part 2 is in a normal energized state, and Fig. 3B shows a case where the switch mechanism part of Fig. 2 is in a tripped state.

The overload relay may be classified into a heater part 11 that detects an overcurrent or an image phase and a switch mechanism part 21 that opens and closes the converter in conjunction with deformation of the main bimetal 13 in the heater part 11.

The heater case 12 includes a main bimetal 13, a heater 14, a shifter 15, and the like, which constitute the heater unit 11, and a main terminal through which a current of the motor is input to the outside. Three (10) is common (it is common that it is the same as the number of the main bimetals 13).

In the opening / closing case 22 connected to the upper portion of the heater case 12, a release lever 23, an inversion mechanism 26, a reset button 29, an auxiliary holder 31, etc. constituting the opening / closing mechanism part 21 are embedded.

The release lever 23 is a temperature compensation bimetal 24 that rotates counterclockwise on the drawing in conjunction with movement of the shifter 15, more specifically, the shifter ring 16, and of the on-walk bimetal 24. Center portion 27 of reversal mechanism 26 by rotating in conjunction with rotation

It includes a protruding faucet 25 to press down.

The reversal mechanism 26 includes a central portion 27 and a reversal spring 28 fitted between the central portion 27 and the reversal mechanism 26, and in the normal state as shown in FIG. 27 is lifted above the reversal mechanism 26, and this state is maintained by the reversal spring 28.

The reset button 29 serves to return the trip state as shown in FIG. 3 (b) to the normal state as shown in FIG. 3 (a). This trip state will be described in more detail below along with the normal energized state. In addition to the reset button 29, the upper cover 30 is arranged with an adjustment dial 29 'that can adjust the capacitance of the relay.

The auxiliary holder 31 is provided with a projection 36 located directly below the main circuit movable contact 91 and a reversal mechanism 26 so as to move the main circuit movable contact 91 to the open position. Insertion groove 35 is formed between the upper and lower protrusions in the middle portion in the longitudinal direction. The upper end of the auxiliary holder 31 is in a closed state in a state change of the reversal mechanism 26, that is, an end to which the main circuit movable contact 91 is attached as shown in FIG. The upper cover 30 is raised to the upper cover 30 by the transfer of the vertical driving force according to the reverse change of the furnace, that is, the reverse change to the state in which the end is flipped upward, or vice versa, as shown in FIG. 3B. (30) It is concealed to the bottom. This allows the user to visually determine the trip state.

The inversion mechanism 26 is provided with the inversion mechanism movable contact 93 at the front-end | tip, and is provided in the position which the inversion mechanism fixed contact 94 corresponding to the inversion mechanism movable contact 93 opposes, and operates these inversion mechanisms. The contact 93 and the inverting mechanism fixed contact 94 are spaced apart (opened) from each other in normal opening. The main circuit movable contact 91 and the main circuit fixed contact 92 are also paired with each other and are in contact with each other (closed) in a normal energized state. The tip end of the reversing mechanism 26 with the reversing mechanism movable contact 93 is fitted into the insertion groove 35 of the subsidiary holder 31, and the main circuit movable contact 91 is the protrusion 36 of the subsidiary holder 31. Put on). The inverting mechanism fixed contact 94 is mounted below the reset button 29. An auxiliary terminal 10 ′ electrically connecting each of the contacts 91 to 94 and a motor controller (not shown) is installed outside the upper case 22. Since it is connected to the contacts 91 to 94, the auxiliary terminal 10 'is composed of a total of four.

Referring to Figures 3 (a) and 3 (b) will be described in detail the normal energized state and trip state of the conventional thermal overload relay as follows.

When an overcurrent flows or an image formation occurs in the electric circuit, it is transmitted through the main terminal 10 (see FIG. 1), and accordingly, a coil-shaped heater 14 wound on the main bimetal 13 in the heater case 12. Will generate heat. When the main bimetal 13 causes the shape displacement by the heat, and the shifter 15 moves to the right in FIG. 3, the shifter ring 16 counterclocks the temperature compensation bimetal 24 of the release lever 23. Rotate in the direction.

By this rotational movement, the tap 25 of the release lever 23 presses the center portion 27 of the reversing mechanism 26 downward in the drawing. Accordingly, when the reversal mechanism 26 and the central portion 27 cross the horizontal critical point, the tip portion of the reversal mechanism 26 is flipped upward and the central portion 27 is reversed as opposed to the normal opening as shown in FIG. Will come down. At this time, as in normal energization, this state is maintained by the reverse spring 28. This state is further referred to as a "trip state", which is illustrated by way of example in FIG.

In this trip state, the auxiliary holder 31 rises upward, and accordingly, the main circuit movable contact 91 rises due to the upward pressure of the lower protrusion 36 of the auxiliary holder 31, thereby causing the main circuit movable contact 91 to rise. The main circuit fixed contact 92 is separated from each other to make a trip in which the circuit is opened. Accordingly, the current applied to the motor is cut off to prevent burnout of the motor.

When the cause of overcurrent or phase loss in the circuit is eliminated and the user presses the reset button 29, the inverting mechanism fixed contact 94 and the inverting mechanism 26 in which the inverting mechanism movable contact 93 is attached to each other are simultaneously lowered. When the reversal mechanism 26 reverses the aforementioned threshold point, the tip portion of the reversal mechanism 26 is flipped down and is reversed to a "normal open state" in which the central portion 27 rises relatively. In addition, the reset button 29 returns to its original position by the elastic force of the inverting mechanism fixed contact 94.

Whether the transition from the trip state to the normal state or vice versa is stable is one of the important factors regarding the reliability of the relay. More specifically, it is important whether the main circuit movable contact and the main circuit fixed contacts 91 and 92 are properly separated (opened). Therefore, it is necessary to test whether such operation is performed properly before installing and operating the relay.

To this end, a test method of pulling up the exposed portion 33 of the auxiliary holder 31 seated in the groove formed in the relay upper cover 30 using a nail or a small driver is generally used. That is, by using a mechanism in which the exposed portion 33 protrudes out of the relay in the trip state and is exposed, the relay in the normal state is forcibly tripped. The return to the normal state may be performed by using the reset button 29.

However, the above-described conventional test method is not simple in its implementation. That is, as described above, it is a method of pulling up the exposed part 33 seated in the groove of the upper cover 30 by using a nail or a screwdriver, which may not be easy.

Further, although the main concern in this test is whether the main circuit movable contact 91 and the main circuit fixed contact 92 are normally opened, changing the relay to a trip state can be an excessive test. In particular, excessive force tripping of the relay deforms important components such as the auxiliary holder 31, the main circuit movable contact 91, and the inverting mechanism movable contact 93, or changes the alignment between the components, thereby causing a failure of the relay and Problems that cause malfunctions occur.

The prior art proposed to solve the above problems, there is a Korean Patent No. 10-0689321, which is further provided with a means for testing the normal operation of the main circuit operating contact in the thermal overload relay .

As shown in FIG. 4 to FIG. 6, the test features composed of the test button 41, the test link 51, and the spring 43 are thermally-type as shown in FIGS. 4 to 6. It is accommodated inside the overload relay and converts the opening and closing positions with respect to the main circuit movable contact 91 and the main circuit fixed contact 92 according to whether the test button 41 is pressed or not, and the test button 41 In accordance with whether or not the drawing operation of the auxiliary holder 31 is to drive the interlocking operation of the inverted position and the closing position for the inverting mechanism movable contact 93 and the inverting mechanism fixed contact 94.

However, the test means for the Korean Patent No. 10-0689321 is to provide a mutually organic operation configuration by combining a plurality of components, the productivity is reduced according to the assembly process, alignment between the assembled components during use There was also a problem that causes the malfunction.

In addition, the injection cost is increased due to the production of a large number of components, there was also a problem in the production and maintenance aspects due to excessive assembly labor.

Accordingly, the present invention has been made to solve the above-mentioned problems of the prior art, the main circuit first contact and the main circuit second contact, and the inverting mechanism first contact and the inverting mechanism second contact inside the thermal overload relay. It is an object of the present invention to provide a test button that can be operated by the opening and closing positions of the open and closed position by pressing and pulling the test button.

In addition, the test button is another object of the present invention that the entire configuration is made of a single configuration.

As a technical means for achieving the above object, the present invention provides a thermal overload relay, comprising: a head portion protruding to an upper portion of the thermal overload relay to be pressed and drawn from a user; A body portion extending downward from the head portion; An elastic support bar extending in the horizontal direction from the body portion and having an end portion inserted into and fixed to an elastic support groove formed on an inner wall of the housing to provide an elastic force to return to its original position during the raising and lowering of the test button; A main circuit test lever which is branched from the body in one direction to drive the main circuit movable contact when the head is pressed; And a test button having a forcible trip lever branched from the body in one direction and configured to pull out the trip display holder together during the drawing operation of the head, wherein the test button having the configuration is integrally formed by a synthetic resin material. It is characterized by being injection molded.

Preferably, the main circuit movable contact is located below the main circuit fixed contact and moves downward. When the tip portion of the main circuit test lever transmits a pressing force to the main circuit movable contact, the main circuit movable contact and the main circuit fixed contact It is characterized in that the opening position of the main circuit is formed as the contact state is released.

Preferably, the anti-separation stopper is formed on both sides of the body of the test button, and the anti-separation support is formed at a predetermined position on the inner upper side of the housing to provide an anti-separation function when the test button is pulled upward. The bottom of the body portion of the test button is formed by the separation prevention groove on the inner bottom of the receiving housing, the upper surface of the housing formed by the separation prevention hole is formed through the configuration that the head of the test button through the configuration is fixedly supported Thermal overload relay.

Preferably, the distal end of the main circuit test lever forms a first engaging portion bent toward the main circuit movable contact, and the distal end of the forced trip lever forms a second engaging portion bent toward the tripping side of the trip display holder. It is done.

According to the thermal overload relay in which the test button is formed according to the present invention, the entire configuration of the test button is injection molded into a single configuration, thereby improving productivity according to the assembling process, providing a robust assembly structure, and increasing production costs. There is a saving effect.

In addition, since the spring is not used, there is an effect of not having to consider concerns such as elastic force reduction and spring failure.

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

7 (a) and 7 (b) is an internal front view showing a thermal overload relay having a test button formed according to an embodiment of the present invention, Figure 7 (a) is an internal front view including a test button, Figure 7 (b) is a front view of the inner main part with the test button removed.

In addition, Figure 8 (a) and Figure 8 (b) is an internal perspective view showing a thermal overload relay having a test button formed in accordance with an embodiment of the present invention, Figure 8 (a) is an internal perspective view including a test button, Figure 8 (b) is a perspective view of the inner main parts with the test button removed.

The thermal overload relay according to the present invention has the same configuration as the prior art, and is electrically connected to these power supplies and the loads for the opening and closing of the circuit between the power supply and the load, respectively, and is in the closed position when the normal current is energized on the circuit. It is attached to the main circuit second contact 96 and the inverting mechanism 26 fixedly installed corresponding to the main circuit first contact 95 and the main circuit first contact 95 displaced to the open position at the time of phase overcurrent energization. Inverting mechanism first contact 97 and inverting mechanism first contact which are in the open position by the inverting mechanism 26 when energizing the circuit on the circuit, and are displaced to the closed position by the inverting mechanism 26 when the overcurrent is energizing on the circuit. A power transmission so as to be drive-connected with the inverting mechanism second contact 98 and the one end of the inverting mechanism first contact 97 fixedly installed corresponding to (97), and to displace the main circuit first contact 95 in the open position. It is possible to over current flow in the circuit When the display reversal mechanism first contact point 97 is displaced to the closed position, the trip display holder 60 for driving the main circuit first contact point 95 to the open position, and an outer housing accommodating the above components ( 80).

The thermal overload relay having the configuration as described above is provided with a test button 70, the main circuit first contact 95 and the main circuit second contact 96, according to the pressing and drawing operation of the test button 70, And the opening position and the closing position with respect to the inversion mechanism 1st contact 97 and the inversion mechanism 2nd contact 98 can be operated.

9 is a perspective view showing a test button according to an embodiment of the present invention, as described above, the test button 70 of the present invention, the head is formed to protrude to the upper portion of the thermal overload relay to be pressed and drawn from the user The portion 71, the body portion 72 extending downward from the head portion 71, and divided into two up and down in one direction from the lower portion of the body portion 72, The main circuit test lever 73 and the forced trip lever 74 formed on the upper side, and the elastic support bar 75 formed extending in the horizontal direction from the body portion 72, the test according to the above configuration The button 70 is injection molded integrally by a synthetic resin material.

The head portion 71 is formed in a form that is easy for the user's operation, preferably, further formed by recessed recessed recesses 71a recessed along the outer circumferential surface of the head portion 71 test button 70 It is to provide a form that is easy for the user to manipulate when drawing.

In addition, the head portion 71 is coupled to the separation prevention hole (83) formed in the housing 80 through the test button 70 is to be fixed without being separated.

In the above body portion 72 is formed to extend downward from the head portion 71, the anti-separation stop projections 76 are formed on both sides to the release preventing support 84 of the housing 80 when drawn upwards It is formed so as to be hooked, the lower end is coupled to the escape prevention groove 81 formed in the inner bottom of the housing 80, to provide a configuration that the test button 70 is fixed without fixing the position.

The main circuit test lever 73 tests the open position and the closed position of the main circuit first contact 95 and the main circuit second contact 96, and is branched from the body portion 72 in one direction. In other words, the tip portion is located above the first contact point 95 of the main circuit.

The main circuit first contact 95 according to the present invention is located below the main circuit second contact 96 and moves downward, and according to the pressing operation of the head 71, the main circuit test lever 73 When the tip portion transmits the pressing force to the main circuit first contact point 95, the main circuit first contact point 95 moves downward, thus contacting the main circuit first contact point 95 and the main circuit second contact point 96. As the state clears, the position of the main circuit can be tested.

In addition, when the pressing force transmitted in the downward direction is removed by stopping the pressing operation of the head 71, the main circuit first contact point 95 becomes the main circuit second contact as the main circuit test lever 73 returns to its original position. By forming a contact state with the contact 96 again, the closed position of the main circuit is formed.

Preferably, the tip portion of the main circuit test lever 73 forms a first catching portion 73a that is bent toward the first contact point 95 of the main circuit, so that a portion of the main circuit test lever 73 is interlocked with the first contact point 95 of the main circuit. Clearly improved the effect of motion transfer.

In the above, the forced trip lever 74 transmits the upward pull force of the test button 70 to the trip display holder 60 side, and is branched from the body portion 72 in one direction, and the tip portion of the test button 70 has a trip display holder ( 60 is located at the bottom of the tripping protrusion 61.

That is, when the test button 70 is pulled upward, the forced trip lever 74 is caught by the trip protrusion 61 of the trip display holder 60 to pull out the trip display holder 60 together upward. Accordingly, the front end portion of the reversal mechanism 26 coupled to the trip display holder 60 is pulled together to perform a trip operation.

Preferably, the tip portion of the forced trip lever 74 forms a second catching portion 74a that is bent toward the tripping protrusion 61 side of the trip display holder 60 to clarify the portion interposed with the tripping protrusion 61. To improve the effectiveness of motion transfer.

The elastic support bar 75 is to provide an elastic force so that the test button 70 can be returned to its original position after the lowering and raising operation of the test button 70 according to the pressing and drawing operation of the head portion 71. It is formed in a horizontal direction in one direction from the body portion 72, the end is inserted into the elastic support groove 82 formed on the inner wall surface of the housing (80).

That is, the elastic support bar 75 inserted into the elastic support groove 82 side of the housing 80 supports the test button 70 fixedly at the current position, but is supported by the predetermined elastic force of the synthetic resin during pressing and drawing operation. You can return to position.

Hereinafter, the configuration of the trip display holder and the housing will be described.

10 is a perspective view illustrating a trip display holder according to an exemplary embodiment of the present invention, and FIG. 11 is a perspective view illustrating a housing.

The trip display holder 60 forms a forced trip state that drives the main circuit first contact 95 to the open position accordingly when the inverting mechanism first contact 97 is displaced to the closed position during overcurrent energization on the circuit. The configuration is as shown in FIG.

As described above, the trip display holder 60 forms a reversing mechanism insertion groove 62 so that the distal end portion of the reversing mechanism 26 can be coupled to the inner central portion, and the forced trip lever 74 may be caught on one side during the drawing operation. The tripping protrusion 61 is formed, and the upper portion includes a protruding display portion 63 protruding to an upper end of the thermal overload relay during the tripping operation to check the trip state.

That is, the forced trip lever 74 is caught by the tripping protrusion 61 to pull out the trip display holder 60 together during the raising operation of the test button 70 according to the drawing operation of the head 71. In the drawing operation of the 60, the tip portion of the reversing mechanism 26 coupled to the reversing mechanism inserting groove 62 is pulled out together, thereby inverting the reversing mechanism 26, thereby inverting the first contact point 97. Is a forced trip state in which the displacement is in the closed position and the main circuit first contact point 95 is in the open position.

The housing 80 corresponds to an external shape which accommodates each component of the thermal overload relay, and the configuration thereof is as shown in FIG.

As described above, the separation prevention groove 81 is formed on the inner bottom surface of the housing 80 so that the lower end of the body portion 72 of the test button 70 is accommodated and the separation prevention hole 83 is formed on the upper surface of the housing 80. The head portion 71 is penetrated and coupled to the upper portion, and a release preventing support 84 is formed at a predetermined position on the upper side, so that the release preventing stop 76 is caught in the upward drawing operation of the test button 70. By limiting further upward drawing operation, the test button 70 can be fixed without being released.

In addition, an elastic support groove 82 is formed at one inner wall of the housing 80 so that the front end portion of the elastic support bar 75 is coupled and supported so that the test button 70 can be returned to its original position by its elasticity.

The test button operation of the thermal overload relay having the above-described configuration is performed as follows.

12 (a) and 12 (b) is a front view showing a state of use of the test button according to an embodiment of the present invention, Figure 12 (a) is an internal state of use including the test button, Figure 12 (b) is a front view of the internal use state with the test button removed.

13 (a) and 13 (b) are perspective views showing the pressed state of the test button according to the embodiment of the present invention, and FIG. 13 (a) is a perspective view of the internal use state including the test button. Figure 13 (b) is a perspective view of the internal use state with the test button removed.

As described above, when the pressing force is transmitted in the downward direction during the pressing operation of the head 71, the main circuit test lever 73 branched from the body portion 72 of the test button 70 is connected to the main circuit first contact point 95. ) To the lower side to release the contact state with the second contact 96 of the main circuit is the opening position of the main circuit is formed, stop the pressing operation of the head 71 to remove the pressing force transmitted in the downward direction As the main circuit test lever 73 returns to its original position, the main circuit first contact 95 is in contact with the main circuit second contact 96 again to form a closed position of the main circuit.

14 (a) and 14 (b) is a front view showing a state of use of the test button in accordance with an embodiment of the present invention, Figure 14 (a) is a front view of the internal use state including the test button, Figure 14 (b) is a front view of the internal use state with the test button removed.

15 (a) and 15 (b) are perspective views illustrating a drawing state of a test button according to an embodiment of the present invention, and FIG. 15 (a) is a perspective view of an internal use state including a test button. Figure 15 (b) is a perspective view of the internal use state with the test button removed.

As described above, when the test button 70 is pulled out, the trip display holder 60 is pulled upward by the forced trip lever 74 branched from the body portion 72 of the test button 70. Accordingly, the tip of the reversing mechanism 26 coupled to the trip display holder 60 is drawn together to operate the reversing mechanism so that the reversing mechanism first contact 97 and the reversing mechanism second contact 98 are in contact with each other. To form.

The trip display holder 60 drawn upward according to the trip operation is a part projecting on the upper part of the thermal overload relay to transmit a current trip state, and when the projecting portion is pressed, the trip display holder 60 moves downward. At this time, the reversal mechanism is reversed again to terminate the trip state.

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 be able to vary the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. Can be modified and changed.

1 is a perspective view showing a conventional thermal overload relay,

2 is a longitudinal cross-sectional view of a thermal overload relay taken along line II-II of FIG. 1,

3 (a) shows a case in which the opening and closing mechanism of FIG. 2 is in a normal energized state,

Figure 3 (b) shows a case in which the opening and closing mechanism of Figure 2 is in a trip state,

Figure 4 is an internal front view showing another conventional thermal overload relay,

Figure 5 (a) is a perspective view of the test button of Figure 4,

5 (b) is a perspective view of a test link in conjunction with the test button of FIG.

6 is a perspective view illustrating the auxiliary holder of FIG. 4;

Figure 7 (a) is an internal front view including a test button in the thermal overload relay with a test button formed in accordance with an embodiment of the present invention,

Figure 7 (b) is a front view of the inner major parts removed from the test button in the thermal overload relay is formed test button according to an embodiment of the present invention,

Figure 8 (a) is an internal perspective view including a test button in the thermal overload relay with a test button formed in accordance with an embodiment of the present invention,

Figure 8 (b) is a perspective view of the inner main parts removed from the test button in the thermal overload relay is formed test button according to an embodiment of the present invention,

9 is a perspective view showing a test button according to an embodiment of the present invention,

10 is a perspective view illustrating a trip display holder according to an embodiment of the present invention;

11 is a perspective view of a housing according to an embodiment of the present invention;

Figure 12 (a) is a front view of the internal use state including the test button showing the pressed state of the test button according to an embodiment of the present invention,

Figure 12 (b) is a front view showing the state of use of the internal major parts to remove the test button showing the pressed state of the test button according to an embodiment of the present invention,

Figure 13 (a) is a perspective view of the internal use state including the test button showing the pressed state of the test button according to an embodiment of the present invention,

Figure 13 (b) is a perspective view showing the state of use of the main parts inside the test button is removed, showing the pressed state of the test button according to an embodiment of the present invention,

Figure 14 (a) is a front view of the internal use state including a test button showing the drawn state of the test button according to an embodiment of the present invention,

Figure 14 (b) is a front view showing a state of use of the internal major parts removed the test button showing the drawing state of the test button according to an embodiment of the present invention,

Figure 15 (a) is a perspective view of the internal use state including a test button showing the drawing state of the test button according to an embodiment of the present invention,

Figure 15 (b) is a perspective view showing the internal state of the main portion removed using the test button showing the state of the test button according to an embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

26: inversion mechanism 60: trip display holder

61: engaging projection 62: reversing mechanism insertion groove

63: protrusion display 70: test button

71: head portion 71a: concave groove

72: body 73: main circuit test lever

73a: first locking portion 74: forced trip lever

74a: second locking portion 75: elastic support bar

76: release prevention stop projections 80: housing

81: departure prevention groove 82: elastic support groove

83: departure prevention hole 84: departure prevention support

95: main circuit contact 1 96: main circuit contact 2

97: Inverting mechanism first contact 98: Inverting mechanism second contact

Claims (4)

The first contact of the main circuit which is electrically connected to the power and the load for opening and closing of the circuit between the power and the load, and is in the closed position when the normal current is energized in the circuit and is displaced to the open position when the overcurrent is energized in the circuit. And the main circuit second contact 96 fixedly installed corresponding to the main circuit first contact 95 and the inverting mechanism 26, and are opened by the inverting mechanism 26 when energizing the normal current on the circuit. And a reversing mechanism second contact 98 fixedly installed in correspondence with the reversing mechanism first contact 97 and the reversing mechanism first contact 97 which are displaced to the closed position by the reversing mechanism 26 when the overcurrent is energized in the circuit. And a power transmission to drive one end of the first contact point 97 of the inverting mechanism and to displace the main circuit first contact point 95 in the open position. ) Is displaced to the closed position accordingly In a thermal overload relay, including a trip display holder 60 to drive the point (95) to the open position, the housing 80, A head portion 71 protruding to an upper portion of the thermal overload relay to be pressed and drawn from the user; A body portion 72 extending downward from the head portion 71; Is formed extending in the horizontal direction from the body portion 72, the front end is fixed to the elastic support groove 82 formed in the inner wall surface of the housing 80 to return to the original position during the lifting and lowering operation of the test button 70 An elastic support bar 75 for providing an elastic force to be provided; A main circuit test lever 73 which is branched from the body 72 in one direction to drive the main circuit first contact 95 during the pressing operation of the head 71; And a test button 70 having a forced trip lever 74 formed to branch from the body 72 in one direction to draw out the trip display holder 60 together during the drawing operation of the head 71. However, the test button 70 is a thermal overload relay having a test button, characterized in that the injection molding integrally by a synthetic resin material. The method of claim 1, The main circuit first contact point 95 is positioned below the main circuit second contact point 96 and moves downward. A tip portion of the main circuit test lever 73 applies a pressing force to the main circuit contact point 95. The thermal overload relay having a test button, characterized in that the opening position of the main circuit is formed as the contact state between the main circuit first contact (95) and the main circuit second contact (96) is terminated. The method of claim 1, On both sides of the body portion 72 of the test button 70 is formed a release preventing stop projection 76, and the release prevention support 84 is formed at a predetermined position on the inner upper side of the housing 80 to form a test button 70 ) Provides a separation prevention function during the upward pull operation of the upper side, and forming a separation prevention groove 81 on the inner bottom surface of the housing 80 to accommodate the lower end of the body portion 72 of the test button 70, the housing (80) The thermal overload relay, characterized in that the position of the test button is fixedly supported through the configuration in which the separation prevention hole (83) through the head portion 71 is coupled through. The method of claim 1, The front end of the main circuit test lever 73 forms a first catching portion 73a that is bent toward the main circuit first contact point 95, and the front end of the forced trip lever 74 has a trip display holder 60. The thermal overload relay with a test button, characterized in that the second locking portion (74a) formed to be bent to the tripping projection 61 of the.

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