JP2021026922A - Explosion-proof mat switch - Google Patents

Abstract

To provide an explosion-proof mat switch capable of sufficiently satisfying a standard of an intrinsically safe structure.SOLUTION: The explosion-proof mat switch includes a top plate of a conductive rubber; a bottom plate of the conductive rubber arranged to oppose to the top plate; a detection element arranged between the top plate and the bottom plate and detecting a load of a heavy object; and a connection member electrically and physically connecting the top plate and the bottom plate.SELECTED DRAWING: Figure 3

Description

The present invention relates to an explosion-proof mat switch technique that sufficiently satisfies an explosion-proof standard.

The mat switch is widely used, for example, as a human detection device or a security device in a production line of a chemical factory.

For example, Patent Document 1 proposes a mat switch having a built-in contact element in which an upper electrode and a lower electrode that are partially insulated with a minute interval are opposed to each other between an upper plate and a lower plate.

Utility Model Registration No. 3063415

In the invention described in Patent Document 1, the upper plate and the lower plate are made of urethane material. Urethane material is a kind of rubber having insulating properties. Since the rubber having an insulating property is easily charged, a mat switch using the rubber having an insulating property may generate sparks due to static electricity. Further, in the invention described in Patent Document 1, since a space exists between the upper plate and the lower plate and is sandwiched between the upper plate and the lower plate which are easily charged, electric discharge may occur. Here, for example, it is conceivable that the upper plate and the lower plate are made of conductive rubber, or the upper plate is covered with an antistatic conductive rubber to make the outside of the mat switch conductive and ground the ground. , The charge inside the mat switch cannot be removed. Therefore, considering that flammable gas enters the inside of the mat switch due to damage or the like, the conventional mat switch is insufficient for safe use in an atmosphere of flammable gas.

Therefore, an object of the present invention is to provide an explosion-proof mat switch that can sufficiently satisfy the standard of an intrinsically safe explosion-proof structure.

The explosion-proof mat switch of the present invention is arranged between the upper plate of the conductive rubber, the lower plate of the conductive rubber arranged so as to face the upper plate, and the upper plate and the lower plate, and is a heavy object. It is characterized by including a detecting element for detecting a load and a connecting member for electrically and physically connecting the upper plate and the lower plate.

In this configuration, the upper plate and the lower plate are connected by a connecting member. The connecting member physically fixes the upper plate and the lower plate. The upper plate and the lower plate are made of conductive rubber. Further, the upper plate and the lower plate have the same potential depending on the connecting member. As a result, the explosion-proof mat switch can eliminate the bias of the potential on the upper plate and the lower plate. Therefore, since the explosion-proof mat switch can prevent the generation of sparks only by grounding any of the upper plate, the lower plate, and the connecting member, the standard of the intrinsically safe explosion-proof structure can be sufficiently satisfied.

Further, an adhesive that adheres the upper plate and the lower plate to each other may be provided.

In this configuration, the upper plate and the lower plate are adhered to each other with an adhesive. Therefore, it is difficult for water, dust, etc. to enter between the upper plate and the lower plate. Therefore, the explosion-proof mat switch has improved water resistance and durability. Even when they are adhered with an adhesive, the upper plate and the lower plate are electrically connected by a connecting member, so that the same potential can be maintained.

Further, a conductive rubber frame plate arranged between the upper plate and the lower plate may be further provided.

In this configuration, since the frame plate is also made of conductive rubber, the potentials are the same as those of the upper plate and the lower plate. The frame plate functions as a spacer for the upper plate and the lower plate. Therefore, the frame plate forms a space for arranging the detection element between the upper plate and the lower plate. Therefore, even if the shape of the upper plate and the lower plate is flat, it is possible to secure a space for arranging the detection element.

Further, the connecting member may include an insert nut.

A general purpose insert nut can be used in this configuration. The insert nut makes it easy to connect the ground wire. Therefore, the explosion-proof mat switch can be easily grounded via the ground wire.

The connecting member may be formed with at least one of a female screw on the inner circumference and a male screw on the outer circumference.

In this configuration, when a female screw is formed on the inner circumference of the connecting member, the user can easily connect the ground wire with the male screw. When a male screw is formed on the outer periphery of the connecting member, the thread of the male screw meshes with the upper plate and the lower plate, so that the male screw is firmly connected to the upper plate and the lower plate. Therefore, the connecting member can be made more difficult to peel off from the upper plate and the lower plate.

Further, an insulating member that covers the detection element may be provided.

In this configuration, the detection element is covered with an insulating member. That is, the insulating member exists between the detection element and the upper plate or the lower plate of the conductive rubber surrounding the detection element. Therefore, the space between the detection element and the upper plate or the space between the detection element and the lower plate is insulated. Therefore, the detection element can be used even if a conductive member is arranged on the surface of the detection element.

Further, the detection element may include a tape switch.

In this configuration, the tape switch can easily arrange the detection element of the required length at the required location.

In the method for manufacturing an explosion-proof mat switch of the present invention, a conductive rubber upper plate and a conductive rubber lower plate are prepared, and a load of a heavy object is detected between the upper plate and the lower plate. The detection element is arranged, the upper plate and the lower plate are arranged so as to face each other, and a connecting member for electrically and physically connecting the upper plate and the lower plate is attached.

In this configuration, the upper plate and the lower plate are connected by a connecting member. The connecting member physically fixes the upper plate and the lower plate. The upper plate and the lower plate are made of conductive rubber. Further, the upper plate and the lower plate have the same potential depending on the connecting member. Thereby, the bias of the potential in the upper plate and the lower plate can be eliminated. Therefore, the explosion-proof mat switch can prevent the generation of sparks simply by grounding either the upper plate or the lower plate. Therefore, the manufacturer can obtain an explosion-proof mat switch that sufficiently satisfies the standard of the intrinsically safe explosion-proof structure.

According to the present invention, the standard of the intrinsically safe explosion-proof structure can be sufficiently satisfied.

FIG. 1A is a perspective view of the explosion-proof mat switch 1 according to the first embodiment. FIG. 1B is a plan view of the explosion-proof mat switch 1. FIG. 2 is an exploded perspective view of the explosion-proof mat switch 1. FIG. 3A is a schematic cross-sectional view of the explosion-proof mat switch 1 cut at I-I of FIG. 1B. FIG. 3B is an enlarged cross-sectional view of a region surrounded by a broken line A in FIG. 3A. FIG. 4 is a flowchart showing a manufacturing method of the explosion-proof mat switch 1. 5 (A) and 5 (B) are diagrams for explaining an example of how to use the explosion-proof mat switch 1. 6 (A) to 6 (C) are views for explaining modifications 1 to 3 of the upper plate 11 or the lower plate 12 according to the first embodiment. 7 (A) and 7 (B) are views for explaining the modified examples 4 and 5 of the insert nut 14 according to the first embodiment.

FIG. 1A is a perspective view of the explosion-proof mat switch 1 according to the first embodiment. FIG. 1B is a plan view of the explosion-proof mat switch 1. FIG. 2 is an exploded perspective view of the explosion-proof mat switch 1. FIG. 3A is a schematic cross-sectional view of the explosion-proof mat switch 1 cut at I-I of FIG. 1B. FIG. 3B is an enlarged cross-sectional view of a region surrounded by a broken line A in FIG. 3A. In FIG. 1B, the frame plate 13 and the tape switch 15 are shown by broken lines through the upper plate 11. In addition, each figure shows the wiring of the lead-out cable and the like omitted. Hereinafter, the length direction (horizontal direction) of the explosion-proof mat switch 1 will be the X-axis direction, the width direction (vertical direction) will be the Y-axis direction, and the thickness direction will be the Z-axis direction.

As shown in FIGS. 1 (A), 1 (B), 2 and 3 (A), the explosion-proof mat switch 1 includes an upper plate 11, a lower plate 12, a frame plate 13, and an insert nut. A tape switch 15 and a tape switch 15 are provided. The upper plate 11 and the lower plate 12 are rectangular flat plates. The frame plate 13 is a rectangular flat plate and has a rectangular opening 16 in the center. The frame plate 13 may have an opening 16 formed in one flat plate, may be formed by combining a plurality of members to form the shape of the frame plate 13, or may be an elongated rubber plate. It may be formed in an annular shape by joining the ends of the rubber. The shapes of the upper plate 11, the lower plate 12, and the frame plate 13 are not limited to rectangles, and may be, for example, circular or triangular.

The upper plate 11, the lower plate 12, and the frame plate 13 are laminated in the order of the lower plate 12, the frame plate 13, and the upper plate 11 along the Z-axis direction. The lower plate 12 is arranged so as to face the upper plate 11. The frame plate 13 is arranged between the upper plate 11 and the lower plate 12. The frame plate 13 functions as a spacer that separates the upper plate 11 and the lower plate 12 at predetermined intervals. As a result, a space 17 surrounded by the upper plate 11, the lower plate 12, and the frame plate 13 is formed. Therefore, even if the upper plate 11 and the lower plate 12 have a flat plate shape, the upper plate 11, the lower plate 12, and the frame plate 13 can secure a space 17 for arranging the tape switch 15.

The tape switch 15 is arranged on the main surface of the lower plate 12 on the side facing the upper plate 11 side. As a result, the tape switch 15 is arranged between the upper plate 11 and the lower plate 12. The tape switch can be cut into the required lengths and used. A plurality of tape switches 15 are arranged in parallel in the Y-axis direction so as to cover substantially the entire surface of the space 17. The arrangement of the tape switch 15 is not limited to the example shown in FIG. 2 and the like. The tape switch 15 can be easily arranged at a required location in the space 17 by a required length according to the specifications of the explosion-proof mat switch 1.

Further, the upper plate 11, the lower plate 12, and the frame plate 13 are each made of conductive rubber. Therefore, the upper plate 11, the lower plate 12, or the frame plate 13 can easily release the electric charge to the outside by connecting the ground wire. The conductivity of the conductive rubber can be appropriately redesigned according to the specifications of the explosion-proof mat switch 1. Further, the conductive rubber includes a polymer material such as synthetic rubber or natural rubber (NR). Examples of the synthetic rubber include nitrile butadiene rubber (NBR) and chloroprene rubber (CR).

The tape switch 15 is a tape-shaped switch. The tape switch 15 is turned on when a pressing force is applied to the tape switch 15 by, for example, a person riding on the upper plate 11. The tape switch 15 constitutes a detection element together with a circuit (not shown). That is, the tape switch 15 is a part of the detection element in the present invention. The detection element may be any one capable of detecting the load of a heavy object. Further, as the detection element, for example, a strain gauge or a piezoelectric sensor can be used in addition to the tape switch 15.

The tape switch 15 is covered with a film 18. The film 18 is an example of an insulating member. The film 18 exists between the tape switch 15 and the upper plate 11, and between the tape switch 15 and the lower plate 12. Therefore, the tape switch 15 and the upper plate 11 and the tape switch 15 and the lower plate 12 are insulated from each other. Therefore, the tape switch 15 can be used for the explosion-proof mat switch 1 even if the conductive member is arranged on the surface of the tape switch 15.

A total of eight insert nuts 14 are attached to each of the four corners of the explosion-proof mat switch 1. As shown in FIG. 3A, the insert nut 14 is fitted into the explosion-proof mat switch 1 so as to penetrate the upper plate 11, the lower plate 12, and the frame plate 13 along the Z-axis direction. As a result, the insert nut 14 physically connects the upper plate 11, the lower plate 12, and the frame plate 13.

The insert nut 14 is an example of a connecting member in the present invention. In the present embodiment, the insert nut 14 is a tubular fastening component that can be embedded in the upper plate 11, the lower plate 12, and the frame plate 13. The insert nut 14 has a through hole 19. A female screw 21 is formed on the inner circumference of the through hole 19. The user can easily connect the ground wire simply by inserting the male screw into the female screw 21 and tightening the ground wire with the male screw. Therefore, the explosion-proof mat switch 1 can be easily grounded via the ground wire. The grounding of the ground wire will be described in detail later. Further, as the insert nut 14, a general-purpose insert nut can be used. As a general-purpose insert nut, an engine or the like having threads formed on the inner circumference and the outer circumference as described later can be used.

A male screw 22 is formed on the outer circumference of the insert nut 14. As a result, the threads of the male screw 22 mesh with the upper plate 11, the lower plate 12, and the frame plate 13. Therefore, the male screw 22 can be firmly connected to the upper plate 11, the lower plate 12, and the frame plate 13. Therefore, the insert nut 14 is more difficult to peel off from the upper plate 11, the lower plate 12, and the frame plate 13. The insert nut 14 may be formed when either the female screw 21 on the inner circumference or the male screw 22 on the outer circumference is formed.

The insert nut 14 is not limited to having a thread, and the surface may have an uneven shape other than the thread. In this case, the insert nut 14 can be firmly connected to the upper plate 11, the lower plate 12, and the frame plate 13 due to the uneven shape of the outer circumference.

The insert nut 14 is made of a conductive material. The insert nut 14 is made of a metal such as SUS. As a result, the insert nut 14 electrically connects the upper plate 11, the lower plate 12, and the frame plate 13. The upper plate 11, the lower plate 12, and the frame plate 13 have the same potential due to the insert nut 14. The explosion-proof mat switch 1 can eliminate the bias of the potentials of the upper plate 11, the lower plate 12, and the frame plate 13. Therefore, the explosion-proof mat switch 1 can be used from the upper plate 11, the lower plate 12, the frame plate 13, and the insert nut 14 simply by grounding any one of the upper plate 11, the lower plate 12, the frame plate 13, and the insert nut 14. The electric charge can be quickly released to the outside. As a result, the electric energy of the upper plate 11, the lower plate 12, the frame plate 13 or the insert nut 14 is always close to zero, and the generation of sparks can be prevented. If the surface of the explosion-proof mat switch 1 is grounded as conductive, even if the upper plate 11, the lower plate 12, or the frame plate 13 is made of insulating rubber, discharge on the surface can be prevented. Here, if an explosive gas invades the internal space, an electric discharge may occur in the internal space. However, in the explosion-proof mat switch 1 of the present embodiment, since there is no bias in the potentials of the upper plate 11, the lower plate 12, and the frame plate 13, the inside surrounded by the upper plate 11, the lower plate 12, and the frame plate 13 Discharge in space is prevented. Therefore, the explosion-proof mat switch 1 can be used in a dangerous area such as in a flammable gas atmosphere. As described above, the explosion-proof mat switch 1 sufficiently satisfies the standard of the intrinsically safe explosion-proof structure.

The insert nut 14 may be fitted in a place where the upper plate 11, the lower plate 12, and the frame plate 13 are physically connected, and the number and position of the insert nut 14 are the specifications of the explosion-proof mat switch 1. Can be changed as appropriate. However, since the insert nuts 14 of the present embodiment are arranged at the four corners, the upper plate 11, the lower plate 12, and the frame plate 13 can be prevented from being turned over from the corner portions.

Further, the upper plate 11, the lower plate 12, and the frame plate 13 made of conductive rubber have a certain degree of electrical resistance, and the potential may be different as the distance from the insert nut 14 increases. However, since the insert nuts 14 of the present embodiment are arranged at a plurality of locations, it is possible to suppress the bias of the potential at each location. In particular, since the insert nuts 14 are arranged at the four corners, the upper plate 11, the lower plate 12, and the frame plate 13 can have substantially the same potential. Therefore, even if the ground wire is connected to any one of the insert nuts 14, the electric energy can be suppressed over the entire upper plate 11, lower plate 12, and frame plate 13.

FIG. 4 is a flowchart showing a manufacturing method of the explosion-proof mat switch 1. As shown in FIG. 4, the manufacturer first prepares the upper plate 11, the lower plate 12, and the frame plate 13 (S1). The manufacturer covers the tape switch 15 with the film 18 in advance. As shown in FIG. 2, the manufacturer arranges a plurality of tape switches 15 covered with the film 18 on the lower plate 12 (S2). The tape switch 15 is attached to the lower plate 12 with an adhesive, an adhesive, or the like, and is fixed to the lower plate 12.

The manufacturer stacks the lower plate 12, the frame plate 13, and the upper plate 11 on which the tape switch 15 is arranged in this order. At this time, the manufacturer arranges the upper plate 11 and the lower plate 12 on which the tape switch 15 is arranged so as to face each other with the frame plate 13 interposed therebetween (S3). Here, the manufacturer may form holes for inserting two insert nuts 14 at each of the four corners of the explosion-proof mat switch 1 by a drill or the like. The diameter of the hole for inserting the insert nut 14 is slightly smaller than the diameter of the insert nut 14. As a result, the manufacturer can easily attach the insert nut 14 to the upper plate 11, the lower plate 12, and the frame plate 13 by pushing the insert nut 14 into the hole and rotating it with a screwdriver. In this way, the manufacturer attaches the insert nut 14 to the upper plate 11, the lower plate 12, and the frame plate 13 (S4). Therefore, the manufacturer can manufacture the explosion-proof mat switch 1 that sufficiently satisfies the standard of the intrinsically safe explosion-proof structure.

Further, the explosion-proof mat switch 1 may include an adhesive that adheres the upper plate 11, the lower plate 12, and the frame plate 13 to each other. When an adhesive is used for the explosion-proof mat switch 1, the manufacturer applies the adhesive to the lower plate 12, the frame plate 13, and the upper plate 11, and then attaches the lower plate 12, the frame plate 13, and the upper plate 11. Stack in order. As a result, the entire circumferences of the upper plate 11, the lower plate 12, and the frame plate 13 are adhered to each other with an adhesive. Therefore, water, dust, and the like are less likely to enter between the upper plate 11, the lower plate 12, and the frame plate 13. Therefore, the explosion-proof mat switch 1 has improved water resistance and durability.

Even when the upper plate 11, the lower plate 12, and the frame plate 13 are adhered with an insulating adhesive, the upper plate 11, the lower plate 12, and the frame plate 13 are electrically connected by the insert nut 14. Therefore, the same potential can be maintained. Further, the upper plate 11, the lower plate 12, and the frame plate 13 may be adhered with a conductive adhesive. In this case, the upper plate 11, the lower plate 12, and the frame plate 13 are electrically connected to each other via a conductive adhesive. Therefore, for example, even if the insert nut 14 is removed, the same potential can be maintained between the main surfaces of the upper plate 11, the lower plate 12, and the frame plate 13.

5 (A) and 5 (B) are diagrams for explaining an example of how to use the explosion-proof mat switch 1. Note that FIG. 5B is a partial cross-sectional view taken along the line II-II of FIG. 5A.

As shown in FIGS. 5 (A) and 5 (B), the explosion-proof mat switch 1 may be used in a state of being surrounded by the frame material 50. The frame member 50 includes four corner portions 51 and four side surface portions 52. The corner portion 51 and the side surface portion 52 are assembled to cover the periphery of the explosion-proof mat switch 1 as one frame. The corner portion 51 has a through hole 58. As shown in FIG. 5A, a screw is attached to the through hole 58. The frame material 50 is fixed to the floor or the like by connecting the screws to the floor or the like. Further, since the periphery of the explosion-proof mat switch 1 is covered with the frame material 50, the explosion-proof mat switch 1 can also be fixed to the floor or the like.

The corner portion 51 includes a front portion 54, a support portion 55, and a bottom portion 56. The explosion-proof mat switch 1 is fixed to the frame member 50 in a state of being in contact with a part of the front portion 54 and the support portion 55. The front surface 54 has an opening 59.

The male screw 53 is fastened to one of the insert nuts 14 of the explosion-proof mat switch 1. One end of the ground wire 57 is connected to the lug terminal 31. The male screw 53 is inserted into one of the insert nuts 14 with the lug terminal 31 sandwiched between them. The male screw 53 is tightened so as to sandwich the lug terminal 31. In this way, the insert nut 14 and the male screw 53 connect the ground wire 57 via the lug terminal 31. As a result, the explosion-proof mat switch 1 can be grounded via the insert nut 14, the male screw 53, the lug terminal 31, and the ground wire 57. Further, in this case, the connecting portion of the ground wire 57 is generally covered by the front portion 54. The frame material 50 can prevent the user from stepping on the connecting portion of the ground wire 57. Further, the lug terminal 31 is sandwiched and fixed between the front surface portion 54 and the upper surface of the upper plate 11. Therefore, even if the user hooks his / her foot on the ground wire 57, a load is unlikely to occur at the connection portion of the male screw 53 of the lug terminal 31. Therefore, the ground wire 57 is prevented from coming off.

FIG. 6A is a diagram for explaining a modification 1 of the upper plate 11 or the lower plate 12 according to the first embodiment. FIG. 6B is a diagram for explaining a modification 2 of the upper plate 11 or the lower plate 12 according to the first embodiment. FIG. 6C is a diagram for explaining a modification 3 of the upper plate 11 or the lower plate 12 according to the first embodiment. The description of the modified examples 1 to 3 will be described only in a place different from the upper plate 11 or the lower plate 12 of the explosion-proof mat switch 1, and the rest will be omitted.

As shown in FIG. 6A, the explosion-proof mat switch 61 according to the first modification includes an upper plate 71 instead of the upper plate 11 and the frame plate 13. The upper plate 71 has a substantially rectangular parallelepiped shape with an open lower surface. That is, the upper plate 71 has a shape in which the upper plate 11 and the frame plate 13 according to the first embodiment are integrated. The opening portion of the upper plate 71 is closed by the lower plate 12. As a result, the space 17 can be formed by the upper plate 71 and the lower plate 12. Therefore, the explosion-proof mat switch 61 can be formed with a small number of members.

Further, the insert nut 14 is fitted into the explosion-proof mat switch 61 so as to penetrate the upper plate 71 and the lower plate 12 along the Z-axis direction. As a result, the insert nut 14 can physically and electrically connect the upper plate 71 and the lower plate 12.

As shown in FIG. 6B, the explosion-proof mat switch 62 according to the second modification includes a lower plate 72 instead of the lower plate 12 and the frame plate 13. The lower plate 72 has a substantially rectangular parallelepiped shape with an open upper surface. That is, the lower plate 72 has a shape in which the lower plate 12 and the frame plate 13 according to the first embodiment are integrated. The opening portion of the lower plate 72 is closed by the upper plate 11. As a result, the space 17 can be formed by the upper plate 11 and the lower plate 72. Therefore, the explosion-proof mat switch 62 can be formed with a small number of members.

Further, the insert nut 14 is fitted into the explosion-proof mat switch 61 so as to penetrate the upper plate 11 and the lower plate 72 along the Z-axis direction. As a result, the insert nut 14 can physically and electrically connect the upper plate 11 and the lower plate 72.

As shown in FIG. 6C, the explosion-proof mat switch 63 according to the third modification includes upper and lower plates 73 instead of the upper plate 11, the lower plate 12, and the frame plate 13. The upper and lower plates 73 are flat plates in which a rectangular parallelepiped is unfolded and unfolded before being assembled. When assembled, the upper and lower plates 73 have a rectangular parallelepiped shape having a space 17 inside.

Therefore, the tape switch 15 can be arranged in the space 17 of the explosion-proof mat switch 63 by closing the ends of the upper and lower plates 73 after arranging the tape switch 15 in the space 17. Therefore, the explosion-proof mat switch 63 can be formed with a small number of members.

Further, the insert nut 14 is fitted into the explosion-proof mat switch 61 so as to penetrate the assembled upper and lower plates 73 along the Z-axis direction. As a result, the insert nut 14 can physically and electrically connect the ends of the upper and lower plates 73 to each other.

FIG. 7A is a diagram for explaining a modified example 4 of the insert nut 14 according to the first embodiment. FIG. 7B is a diagram for explaining a modified example 5 of the insert nut 14 according to the first embodiment. The description of the modified examples 4 and 5 will be described only where they differ from the insert nut 14 of the explosion-proof mat switch 1, and the rest will be omitted.

As shown in FIG. 7A, the explosion-proof mat switch 64 according to the fourth modification includes a connecting member 81. The connecting member 81 includes a tubular tubular portion 82 and a flange 83. The tubular portion 82 is attached to the explosion-proof mat switch 64 so as to penetrate the upper plate 11, the lower plate 12, and the frame plate 13. Flange 83 is formed at both ends of the tubular portion 82. The flange 83 can prevent the tubular portion 82 from moving along the Z-axis direction.

Before the connecting member 81 was attached to the explosion-proof mat switch 64, the manufacturer, for example, summed the lengths in the Z-axis direction of the upper plate 11, the lower plate 12, and the frame plate 13 in the Z-axis direction. Prepare something longer than the length. When the connecting member 81 is fitted into the upper plate 11, the lower plate 12, and the frame plate 13, the connecting member 81 partially protrudes from the upper plate 11, the lower plate 12, and the frame plate 13 to the outside. After being fitted into the upper plate 11, the lower plate 12, and the frame plate 13, the connecting member 81 extends in the Z-axis direction from the upper plate 11, the lower plate 12, and the frame plate 13 other than the tubular portion 82 to the outside. By applying pressure from above and below, the flange 83 is formed so as to spread in parallel with the XY plane.

Alternatively, the connecting member 81 may be composed of two parts that are vertically divided in the Z-axis direction by the tubular portion 82 before being assembled. In this case, the two parts are joined after being fitted into the upper plate 11, the lower plate 12, and the frame plate 13 from the vertical direction in the Z-axis direction. As a result, the connecting member 81 can be attached to the upper plate 11, the lower plate 12, and the frame plate 13. Further, the connecting member 81 can electrically and physically connect the upper plate 11, the lower plate 12, and the frame plate 13.

As shown in FIG. 7B, the explosion-proof mat switch 65 according to the modified example 5 includes a connecting member 74 instead of the insert nut 14. The connecting member 74 includes a support portion 75 and a peripheral portion 76. The peripheral portion 76 is attached to the explosion-proof mat switch 65 so as to be in contact with the cross sections of the upper plate 11, the lower plate 12, and the frame plate 13. The support portion 75 bends in parallel with the XY plane on the upper side of the upper plate 11 and the lower side of the lower plate 12 continuously to the peripheral portion 76.

The connecting member 74 is, for example, arranged so as to sandwich the periphery of the upper plate 11, the lower plate 12, and the frame plate 13, and then applies pressure from above and below in the Z-axis direction to form the upper plate 11, It can be attached to the lower plate 12 and the frame plate 13. As a result, the connecting member 74 covers the connecting portions of the upper plate 11, the lower plate 12, and the frame plate 13. Water, dust, etc. do not easily enter between the upper plate 11, the lower plate 12, and the frame plate 13. Therefore, the explosion-proof mat switch 65 has improved water resistance and durability. Further, the formation of holes can be omitted as in the case of arranging the insert nut 14.

The description of the embodiments described above should be considered exemplary in all respects and not restrictive. The scope of the present invention is indicated by the scope of claims, not by the above-described embodiment. Furthermore, the scope of the present invention is intended to include all modifications within the meaning and scope equivalent to the claims.

1 ... Explosion-proof mat switch 11 ... Upper plate 12 ... Lower plate 13 ... Frame plate 14 ... Insert nut (connecting member)
15 ... Tape switch (part of detection element)
21 ... Female screw 22,53 ... Male screw 57 ... Ground wire 61, 62, 63, 64, 65 ... Explosion-proof mat switch 71 ... Upper plate 72 ... Lower plate 73 ... Upper and lower plates (upper plate and lower plate)
74 ... Connecting member 81 ... Connecting member

Claims (8)

With the top plate of conductive rubber,
A conductive rubber lower plate arranged so as to face the upper plate and
A detection element arranged between the upper plate and the lower plate to detect the load of a heavy object, and
A connecting member that electrically and physically connects the upper plate and the lower plate,
To prepare
Explosion-proof mat switch. An adhesive that adheres the upper plate and the lower plate to each other is provided.
The explosion-proof mat switch according to claim 1. A conductive rubber frame plate arranged between the upper plate and the lower plate is further provided.
The explosion-proof mat switch according to claim 1. The connecting member includes an insert nut.
The explosion-proof mat switch according to any one of claims 1 to 3. At least one of a female screw on the inner circumference and a male screw on the outer circumference is formed in the connecting member.
The explosion-proof mat switch according to claim 4. An insulating member that covers the detection element is provided.
The explosion-proof mat switch according to any one of claims 1 to 5. The detection element includes a tape switch.
The explosion-proof mat switch according to any one of claims 1 to 6. Prepare the upper plate of the conductive rubber and the lower plate of the conductive rubber,
A detection element for detecting the load of a heavy object is arranged between the upper plate and the lower plate.
The upper plate and the lower plate are arranged so as to face each other.
Attach a connecting member that electrically and physically connects the upper plate and the lower plate.
How to manufacture explosion-proof mat switches.

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