KR101083636B1 - Clip-on structure for non-contact relay - Google Patents

Abstract

PURPOSE: A non-contacting relay detachable structure is provided to effectively cope with impact and vibration by easily attaching and detaching a non-contacting relay to electrical machinery. CONSTITUTION: A TRIAC(Triode AC switch) is formed on a circuit board(20). An upper case(30) protects the top of the circuit board. A lower case(40) which is combined with the upper case is installed in the lower part of the circuit board. A first rib(41) and a second rib(42) are formed in the lower part of a heat-release structure of the lower case. The first rib and the second rib are combined with a rail(50). A rail combine groove is formed in the first rib. An operation lever(60) is installed in a side direction of the heat-release structure of the lower case. The front end part of the operation lever supports the lower part of a second top part which is combined to the lower part of the second rib. A third rib and a fourth rib are formed in the outer side of the first rib and the second rib. The first rib and the second rib are detachable installed to the rail by the operation lever.

Description

Clip-on structure for non-contact relay}

The present invention relates to a contactless relay detachable structure, and more particularly to a contactless relay detachable structure that can be easily and reliably attached to the contactless relay to the electrical equipment.

In general, solid state relays use semiconductor switching elements such as TRIACs (TRIACs) to compensate for the shortcomings of conventional mechanical magnet relays.They are more reliable, lower noise, faster response, smaller and vibration free than magnet relays. It has excellent features such as.

     Triac is a bi-directional device in which PNPN thyristors are connected in parallel and in parallel. The operation mode is different depending on the applied voltage, and the triac is designed and manufactured to have uniform characteristics in each operation mode. Cool by means.

     1 is a view for explaining a conventional contactless relay.

     As shown in Fig. 1, in the conventional solid-state relay, the lead wire of the triac 1 is fastened to the circuit board 10 by soldering or the like, and then the lead wire is bent at 90 degrees to the triac 1. One surface of is in contact with the lower case 2. One surface that is in close contact with the triac (1) is the surface that generates the most heat, the lower case (2) formed by die casting or the like to form a flat surface in contact with one surface of the triac (1) to perform a heat sink. Specifically, the triac (1) is fixed by applying heat-dissipating powder, grease, or the like to the triac contact portion (3), and after the triac (1) and the lower case (2) are fastened with screws (4), The space 5 between the circuit board 10 and the lower case 2 in which the vice 1 is located is filled with resin such as epoxy having adhesiveness and heat resistance to form a contactless relay.

However, in the conventional solid-state relay, the lifting phenomenon occurs in the triac contact portion 3 when the screw 4 is fastened in the manufacturing process, and the resin filled therein soaks in the triac 1 and the lower case 2. There is a problem that the heat radiation efficiency is lowered because it interferes with the adhesion.

     On the other hand, conventionally, the secondary heat dissipation structure 6 is manufactured and used separately to effectively dissipate heat conducted to the lower case 2. That is, after fixing the contactless relay by applying a heat-dissipating powder or heat-dissipating grease to the attachment surface (7) of the secondary heat dissipation structure (6), by fastening the contactless relay with a screw (9) through the fastening hole (8), In use, it emits heat generated by the triac (1). However, both the lower case 2 and the secondary heat dissipation structure 6 of the contactless relay are metal structures formed by die casting, etc., and the contact surface is inadequate due to the unevenness of the flat plate and the horizontal mismatch. There is a problem that the heat radiation efficiency is lowered.

     In addition, the conventional solid-state relay is assembled by the user and the installer (producer) due to the inflow of foreign matter to the attachment surface (7), poor fastening of the screw (4) when assembling the contactless relay and the secondary heat dissipation structure (6). There is a problem that the adhesiveness is lowered to not properly release the high temperature heat.

     In addition, the conventional solid-state relay conducts high temperature heat generated by the triac 1 to the lower case 2, and conducts heat of the lower case 2 to the secondary heat dissipation structure 6 to discharge to the outside. In this way, the higher the temperature, there is a problem in that the secondary heat dissipation structure 6 having a larger area than the lower case 2 of the contactless relay.

As described above, the conventional solid-state relay does not have high heat dissipation efficiency in structure, and there is a problem in that the heat dissipation efficiency is not maximized, such as a complicated manufacturing process for heat dissipation and a decrease in adhesion in the manufacturing process.

     Therefore, the present applicant has filed a patent application of the contactless relay of Patent Registration No. 10-0972447 in order to solve the above problems, and the gist of the technology is that the circuit board 110 is a resistor, a diode, a triac (TRIAC, A substrate on which circuit elements such as a 111 and a triode AC switch are formed, and opens and closes a circuit between an external power supply and an external load by a triac switching operation. The triac 111 is formed to extend in the vertical direction on the lower surface of the circuit board 110. That is, conventionally, unlike the plate-shaped triac 1 is bent at 90 ° and formed on the circuit board 10 as shown in FIG. 1, the plate-shaped triac 111 according to the first embodiment of the present invention is bent. It is formed perpendicular to the circuit board 110 in a shape extending in the vertical direction. Accordingly, by maximizing the area of the triac 111 inserted into the lower case 130, the high temperature conductive heat dissipation rate generated in the triac is also maximized, so that a heat sink size smaller than the prior art can be used. It is possible to switch at a temperature higher than the ambient temperature when using a solid state relay, so that the cost of the installation area can be reduced.

     The triac 111 inserts the lead wire 112 into the triac fixing hole 113 and fixes the lead wire 112 by soldering to form the circuit board 110. In addition, unlike the conventional resin filled with epoxy and the triac 111 can not be separated, the first embodiment of the present invention does not fill the resin, the triac in the circuit board 110 by the method of removing the solder 111 can be easily removed. As described above, since the triac 111 may be detached from the circuit board 110, when the triac 111 or the circuit board 110 is damaged, only the triac 111 or only the circuit board 110 is separated and replaced. It is possible to reduce the repair cost, and solve the problem of environmental pollution caused by breaking the entire contactless relay separately from the external circuit when the triac 111 or the circuit board 110 is damaged in the related art. Therefore, the contactless relay of the present invention has an environmentally friendly structure. In addition, the replacement of the triac 111 or the circuit board 110 is further facilitated by the fastening slider 136 described later.

     The upper case 120 is made of a polymer resin material and is formed on the upper side of the circuit board 110. In addition, the upper case 120 has an input / output terminal 121 connected to the circuit board 110. An external power source or an external load is connected to the input / output terminal 121. In this way, the upper case 120 connects the circuit board 110 and the external circuit and functions as a cover for protecting the circuit board 110 from the outside.

The lower case 130 is made of a metal material for heat dissipation, and is formed below the circuit board 110. Preferably, aluminum is extruded to form the lower case 130. The lower case 130 is fastened to the upper case 120 to accommodate the circuit board 110 and protect it from the outside.

     The lower case 130 may include a triac insertion hole 131 into which the triac 111 is inserted, and a lifting prevention tool 132 which prevents the triac 111 from being lifted within the triac insertion hole 131. By forming a plurality of heat dissipation ribs 133 extending laterally or downwardly, the heat dissipation ribs 133 are used as heat dissipation means for dissipating heat generated in the triac 111 to the outside.

     The triac insertion hole 131 is formed in a groove shape in accordance with the shape of the triac 111 so that the triac 111 extending in the vertical direction is sufficiently inserted into the upper portion of the lower case 130.

     The lifting prevention tool 132 includes a first lifting prevention plate 132a and a second lifting prevention plate 132b each of which is detached from the triac insertion hole 131. The first lifting plate 132a is in close contact with one surface of the triac 111 (also called the front surface of the triac), and the second lifting plate 132b is the other side of the triac 111 (also referred to as the rear surface of the triac) Close to Specifically, the first lifting plate 132a, the triac 111 and the second lifting plate 132b are inserted together in the triac insertion hole 131, the screw 135 is fastened through the fastening hole 134 ), The first lifting plate 132a is pressed, and the first lifting plate 132a, the triac 111, and the second lifting plate 132b are brought into close contact with each other and fixed.

     Here, the first lifting plate 132a and the second lifting plate 132b are preferably made of aluminum. Since aluminum has ductility, the first lifting plate 132a and the second lifting plate 132b are easily deformed by the pressure of the screw 135. Accordingly, the triac 111, the first lifting prevention plate 132a and the second lifting prevention plate 132b are completely adhered without lifting, the triac insertion hole 131 and the first lifting prevention plate 132a. And the second lifting plate 132b is also completely in contact without lifting. Therefore, the heat radiation efficiency by floating can be prevented from falling. In particular, the other surface of the triac 111 may be the surface where heat is most generated during the switching operation, and the thermal conductivity of the triac 111 to the lower case 130 may be improved by the second lifting plate 132b made of aluminum.

     The plurality of heat dissipation ribs 133 extends laterally or downwardly of the lower case 130. Since heat generated in the triac 111 is conducted to the lower case 130 and released to the outside, the heat dissipation area of the lower case 130 can be widened by the heat dissipation ribs 133, thereby improving heat dissipation efficiency of the contactless relay. Can be improved. In addition, the heat dissipation ribs 133 may be designed and formed to extend in a straight line shape or to extend in a curved manner, in consideration of their heat dissipation efficiency.

     In addition, the lower case 130 forms a fastening means for fastening and fixing the circuit board 110. Preferably, as shown in Figures 3 and 4, by forming the fastening slider 136 on the lower case 130, the circuit board 110 can be easily fastened to the lower case 130, such as repair and disassembly Can be easily removed if needed.

     In addition, the lower case 130 forms at least one of a fastening hole 137 or a fastening ring 138. The solid-state relay is a means for opening and closing an electrical connection between an external power source and an external load. Since the contactless relay is used in a small electric device or the like, a fastening means for mounting is required. Accordingly, in the first embodiment of the present invention, by forming at least one of the fastening hole 137 or the fastening ring 138 in the lower part of the lower case 130, the contactless relay is connected to the electrical device, that is, the external fixture. Can be tightened.

     In addition, the lower case 130 may be formed of an insulator by performing an insulating coating, thereby preventing damage such as static electricity to the triac 111 inserted into the triac insertion hole 131, and receiving the circuit board 110. It can be insulated from the outside.

Meanwhile, in the first embodiment of the present invention, three input / output terminals 121 are formed on each of the left and right sides of the upper case 120 so as to be used when the external power source is a three-phase AC power source. As a single-phase AC solid state relay, two input / output terminals 121 are formed on each of the left and right sides of the upper case 120 so that the external power source can be used as a single phase AC power source. Applicable In addition, the above contactless relays can be used when the external power source is a direct current. That is, the contactless relay of the present invention may be any contactless relay such as direct current, single phase alternating current, or three phase alternating current.

     However, all of the above-mentioned prior arts have a method of fastening a relay to an electric device by drilling a hole in the panel and processing a screw pitch step to assemble a heat sink with an electric device, that is, an external fixture with screws, or to a panel assembly product made of a separate metal. Since the heat sink is assembled by screw or compression assembly, the manufacturing cost is expensive, and the work was complicated and difficult.

Therefore, the present invention has been made to solve the above problems, and to provide a contactless relay detachable structure that can be attached to the contactless relay to the electrical device reliably and easily.

The present invention relates to a contactless relay detachable structure, which is a contactless relay detachable structure for opening and closing a circuit between an external power supply and an external load by a switching operation of a triac (TRIAC), wherein the contactless relay is a circuit in which a triac is formed. The upper case 30 which protects the upper part of the board | substrate 20, the circuit board 20, and the lower case 40 installed in the lower part of the circuit board 20 and couple | bonded with the upper case 30 is comprised, The lower case 40 is a contactless relay detachable structure in which the heat dissipation structure that dissipates the heat of the triac is separated or integrally formed. The lower case 40 is the heat dissipation rib coupled to the rail 50. First and second ribs 41 and 42 are formed, and the first and second ribs 41 and 42 are formed. The third and fourth ribs 43 and 44, which are heat dissipating ribs, are formed on the outer side of the two ribs 41 and 42, and the first and second ribs 41 and 42 are operated by the operating lever 60 to form a rail 50. Removably mounted to) characterized in that.

Therefore, the present invention has a remarkable effect that the contactless relay can be reliably and easily attached and detached to an electric device by only one operation with one hand using the operation lever.

1 is a cross-sectional view of a conventional solid-state relay
Figure 2 is an exploded perspective view of another conventional contactless relay
3 is a perspective view of a contactless relay detachable structure of the present invention
Figure 4 is a front view of a contactless relay detachable structure of the present invention
5 is a right side view of a solid state relay of the present invention.
Figure 6 is a plan view of a solid state relay of the present invention
Figure 7 is a bottom view of a solid state relay of the present invention.
8 is a state in which the solid-state relay of the present invention is mounted on a rail
Figure 9 is an operation of the solid state relay of the present invention mounted on the rail
10 is an operation of the solid-state relay of the present invention is separated from the rail
Figure 11 is a perspective view of a solid state relay rail of the present invention
12 is a perspective view of a solid state relay operating lever of the present invention
Figure 13 is a plan view of a solid state relay operating lever of the present invention
Figure 14 is a side view of a solid state relay operating lever of the present invention
15 is an operation of a contactless relay detachable structure of a second embodiment of the present invention

The present invention relates to a contactless relay detachable structure, which is a contactless relay detachable structure for opening and closing a circuit between an external power supply and an external load by a switching operation of a triac (TRIAC), wherein the contactless relay is a circuit in which a triac is formed. The upper case 30 which protects the upper part of the board | substrate 20, the circuit board 20, and the lower case 40 installed in the lower part of the circuit board 20 and couple | bonded with the upper case 30 is comprised, The lower case 40 is a contactless relay detachable structure in which the heat dissipation structure that dissipates the heat of the triac is separated or integrally formed. The lower case 40 is the heat dissipation rib coupled to the rail 50. First and second ribs 41 and 42 are formed, and the first and second ribs 41 and 42 are formed. The third and fourth ribs 43 and 44, which are heat dissipating ribs, are formed on the outer side of the two ribs 41 and 42, and the first and second ribs 41 and 42 are operated by the operating lever 60 to form a rail 50. Removably mounted to) characterized in that.

     In addition, the rail 50 has a channel-shaped cross section, and a rail coupling groove 45 is formed in the first rib 41 so that the first upper end 51 of the rail 50 is the rail coupling groove 45. Removably coupled to the second rib 42, the second upper end 52 of the rail 50 is detachably coupled by the operating lever 60,

The operation lever 60 is installed in the lateral direction of the heat dissipation structure of the lower case 40, and the operation lever passage hole is formed on the side of the fourth rib, which is a heat dissipation rib formed on the outer side of the second rib and the second rib. When the lever 60 is advanced in the lateral direction of the lower case 40 heat dissipation structure, the lower end of the second upper end 52 of the rail 50, in which the front end portion of the operating lever 60 is coupled to the lower end of the second rib 42. When the control lever 60 is retracted, the front end of the control lever 60 is separated from the second upper end of the rail 50, so that the rail 50 is separated from the heat dissipation structure of the lower case 40. It features.

     In addition, a serrated protrusion 61 is formed at a lower portion of the handle of the operating lever 60, and a sawtooth fixing groove 46 is formed on the upper surface of the fourth rib 44. A plurality of the projections 61 are formed so as to correspond to each other, and the protrusion 61 of the operation lever is detachably fixed to the fixing groove 46 of the fourth rib 44.

     In addition, the rail 50 has a channel-shaped cross section, and a rail coupling groove 45 is formed in the first rib 41 so that the first upper end 51 of the rail 50 is the rail coupling groove 45. Removably coupled to the second rib 42, the second upper end 52 of the rail 50 is detachably coupled by the operating lever 70,

The operating lever 70 has a spiral portion formed in the body, is installed in the lateral direction of the heat dissipation structure of the lower case 40, the operation lever passes through the side of the fourth rib, which is a heat dissipation rib formed on the outer side of the second rib and the second rib. A hole is formed, and when the operation lever is rotated in the operation lever groove 71 to advance along the spiral in the lateral direction of the lower case, the rail of the front end of the operation lever 70 is coupled to the lower end of the second rib 42. The lower end of the second upper end of the support unit 50 is rotated in the opposite direction as when the operating lever 70 moves forward from the operating lever groove 71 and retracts along the helix. The second upper end of the rail 50 is separated, so that the rail 50 is separated from the heat dissipation structure of the lower case 40.

     The present invention will be described in detail with reference to the accompanying drawings. 1 is a sectional view of a conventional contactless relay, FIG. 2 is an exploded perspective view of another conventional contactless relay, FIG. 3 is a perspective view of a contactless relay detachable structure of the present invention, and FIG. 4 is a front view of a contactless relay detachable structure of the present invention. 5 is a right side view of the contactless relay of the present invention, FIG. 6 is a plan view of the contactless relay of the present invention, FIG. 7 is a bottom view of the contactless relay of the present invention, and FIG. 8 is a contactless relay of the present invention mounted on a rail. 9 is an operation diagram in which the contactless relay of the present invention is mounted on the rail, FIG. 10 is an operation view in which the contactless relay of the present invention is separated from the rail, and FIG. 11 is a perspective view of the contactless relay rail of the present invention. 12 is a perspective view of a contactless relay operating lever of the present invention, Figure 13 is a plan view of a contactless relay operating lever of the present invention, Figure 14 is a side view of a contactless relay operating lever of the present invention, Figure 15 is a second embodiment of the present invention Contact relay attachment and detachment structure operation diagram.

     The present invention relates to a contactless relay detachable structure for opening and closing a circuit between an external power supply and an external load by a switching operation of a triac. The contactless relay is a circuit board 20, a triac is formed, the upper case 30 to protect the upper portion of the circuit board 20, and is installed in the lower portion of the circuit board 20 and coupled to the upper case 30 It is composed of a lower case 40. The lower case has a heat dissipation structure formed integrally with or below the lower case.

     In addition, first and second ribs 41 and 42, which are heat dissipating ribs coupled to the rail 50, are formed below the heat dissipation structure of the lower case 40. The first. Outside the two ribs 41 and 42, third and fourth ribs 43 and 44, which are heat dissipating ribs, are formed concentrically. Therefore, the first and second ribs 41 and 42 are detachably mounted to the rail 50 by the operation lever 60.

     The rail 50 has a channel-shaped cross section, and a rail coupling groove 45 is formed in the first rib 41 so that the first upper end of the rail 50 is detachable from the rail coupling groove 45. Combined. In addition, a second upper end of the rail 50 is detachably coupled to the second rib 42 by the operation lever 60. The operation lever 60 is installed in the lateral direction of the lower case 40 heat dissipation structure, the operation lever passage hole is formed on the side of the fourth rib, which is a heat dissipation rib formed on the outside of the second rib and the second rib, When the lever is advanced in the lateral direction of the lower case, the front end of the operating lever 60 supports the lower portion of the second upper end of the rail 50 coupled to the lower end of the second rib 42, the operation lever 60 If the retracted end of the operating lever 60 is separated from the second upper end of the rail 50, the rail 50 is separated from the heat dissipation structure of the lower case 40.

     A serrated protrusion 61 is formed on the lower surface of the handle of the operating lever 60, and the serrated fixing groove 46 corresponds to the serrated protrusion 61 on the upper surface of the fourth rib 44. In this case, a plurality of protrusions 61 of the operating lever are detachably fixed to the fixing groove 46 of the fourth rib 44. Since the operation lever is made of polybutylene terephthalate, the material of the operation lever is elastic, so that it is easily detachable from the toothed projection and the fixing groove. The tip of the control lever is sharply formed so that when the control lever is moved forward or backward, the control lever leading end is easily coupled to or detached from the lower portion of the rail that is the rail.

     On the other hand, as another embodiment of the present invention, the rail 50 has a channel-shaped cross-section, the first rib 41 has a rail coupling groove 45 is formed so that the first upper end of the rail 50 Removably coupled to the rail coupling groove 45, the second upper end of the rail 50 is detachably coupled to the second rib 42 by the operation lever (70). The control lever is bent in one direction so that the handle portion can be caught in the operation lever groove. When the operation lever is rotated, the handle portion is inserted into the operation lever groove to move forward or continue rotation or rotate in another direction. It is caught by the control lever groove and is separated from the control lever groove and retreats backward.

     Therefore, the operating lever 70 has a spiral portion formed in the body, is installed in the lateral direction of the lower case 40, the operating lever passage hole in the side of the fourth rib which is a heat dissipation rib formed on the outer side of the second rib and the second rib. Is formed, the front end of the operating lever 70 is coupled to the lower end of the second rib 42 when the operating lever rotates in the operating lever groove 71 to advance along the spiral in the lateral direction of the lower case heat-radiating structure. The lower portion of the second upper end of the rail 50 is supported. And when the operating lever 70 is rotated in the opposite direction as when moving forward from the operating lever groove 71 and retracted along the spiral, the front end of the operating lever 70 is separated from the second upper end of the rail 50, Rail 50 is separated from the lower case 40 heat dissipation structure.

     Therefore, the present invention can be attached and detached solid-state relay to the electrical equipment reliably and easily by using the operating lever, and can effectively respond to shock and vibration

It is.

20: circuit board 30: upper case
40: lower case 41, 42, 43, 44: first, 2, 3, 4 rib
45: rail coupling groove 46: fixing groove
50: rail 51: first upper end
52: second upper end 60: operation lever
61: turning
70: operation lever 71: operation lever groove
80: triac

Claims (4)

delete A contactless relay detachable structure for opening and closing a circuit between an external power supply and an external load by a triac switching operation, wherein the contactless relay is a circuit board 20 on which a triac is formed, an upper portion of the circuit board 20. The upper case 30 to protect the, and is installed in the lower portion of the circuit board 20 and the lower case 40 is coupled to the upper case 30, the lower case 40 is to dissipate the heat of the triac In the contactless relay detachable structure in which the heat dissipation structure is separated or integrally formed, the lower case 40 has a heat dissipation structure lower portion formed with first and second ribs 41 and 42 which are heat dissipation ribs coupled to the rail 50. And said first. The third and fourth ribs 43 and 44, which are heat dissipating ribs, are formed on the outer side of the two ribs 41 and 42, and the first and second ribs 41 and 42 are operated by the operating lever 60 to form a rail 50. Mounted detachably)
The rail 50 has a channel-shaped cross section, and a rail coupling groove 45 is formed in the first rib 41 so that the first upper end 51 of the rail 50 is connected to the rail coupling groove 45. Removably coupled to the second rib 42, the second upper end 52 of the rail 50 is detachably coupled by the operating lever 60,
The operation lever 60 is installed in the lateral direction of the heat dissipation structure of the lower case 40, and the operation lever passage hole is formed on the side of the fourth rib, which is a heat dissipation rib formed on the outer side of the second rib and the second rib. When the lever 60 is advanced in the lateral direction of the lower case 40 heat dissipation structure, the lower end of the second upper end 52 of the rail 50, in which the front end portion of the operating lever 60 is coupled to the lower end of the second rib 42. When the control lever 60 is retracted, the front end of the control lever 60 is separated from the second upper end of the rail 50, so that the rail 50 is separated from the heat dissipation structure of the lower case 40. Solid state relay detachable structure 3. The serrated protrusion 61 is formed on the lower portion of the handle of the operating lever 60, and the sawtooth fixing groove 46 is formed on the upper surface of the fourth rib 44. Since a plurality of protrusions 61 are formed to correspond to the protrusions 61, the solid state relay detachable structure is characterized in that the protrusions 61 of the operation lever are detachably fixed to the fixing grooves 46 of the fourth ribs 44. A contactless relay detachable structure for opening and closing a circuit between an external power supply and an external load by a triac switching operation, wherein the contactless relay is a circuit board 20 on which a triac is formed, an upper portion of the circuit board 20. The upper case 30 to protect the, and is installed in the lower portion of the circuit board 20 and the lower case 40 is coupled to the upper case 30, the lower case 40 is to dissipate the heat of the triac In the contactless relay detachable structure in which the heat dissipation structure is separated or integrally formed, the lower case 40 has a heat dissipation structure lower portion formed with first and second ribs 41 and 42 which are heat dissipation ribs coupled to the rail 50. And said first. The third and fourth ribs 43 and 44, which are heat dissipating ribs, are formed on the outer side of the two ribs 41 and 42, and the first and second ribs 41 and 42 are operated by the operating lever 60 to form a rail 50. Mounted detachably)
The rail 50 has a channel-shaped cross section, and a rail coupling groove 42 is formed in the first rib 41 so that the first upper end 51 of the rail 50 is connected to the rail coupling groove 42. Removably coupled to the second rib 42, the second upper end 52 of the rail 50 is detachably coupled by the operating lever 70,
The operating lever 70 has a spiral portion formed in the body, is installed in the lateral direction of the heat dissipation structure of the lower case 40, the operation lever passes through the side of the fourth rib which is a heat dissipation rib formed on the outer side of the second rib and the second rib. A hole is formed, and when the operation lever is rotated in the operation lever groove 71 to advance along the spiral in the lateral direction of the lower case, the rail of the front end of the operation lever 70 is coupled to the lower end of the second rib 42. The lower end of the second upper end of the support unit 50 is rotated in the opposite direction as when the operating lever 70 moves forward from the operating lever groove 71 and retracts along the helix. The contactless relay detachable structure, characterized in that separated from the second upper end of the rail 50, the rail 50 is separated from the lower case 40 heat dissipation structure

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