JP2010257785A - Switch and airtightness inspection method in switch - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To inspect airtightness without breaking a body case. <P>SOLUTION: An inhibitor switch 1 is provided with a movable contact 70 at a movable board 5 turnably supported to the body case 4 inside the body case 4 formed by joining a cover 3 to a peripheral wall 22 of a pole board 2, and configured such that the movable contact 70 and a fixed contact 21 approach and separate according to the turning position of the movable board 5. An end 51a of the movable board 5 abuts on the bottom 23a of a support hole 23 of the pole board 2, and an end 51b includes a shaft part 51 located outside the body case 4 while penetrating the cover 3. The shaft part 51 is provided with an axial hole 54 extending in the axial direction from the end 51b, and a notch 55 serving for communication between the axial hole 54 and an internal space S of the body case 4. An arm 6 for turning the shaft part 51 is joined to the end 51b of the shaft part 51, and an opening in the end 51b of the axial hole 54 is sealed with a base part 61 of the arm 6. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a switch capable of inspecting airtightness of a main body case, and an airtightness inspection method in the switch.

  As a switch that needs to maintain the airtightness of the main body case for protecting the contacts and the like, for example, there is an inhibitor switch that is provided in an automatic transmission for a vehicle and detects a selection range of a shift lever (for example, Patent Document 1).

JP-A-9-306292

The inhibitor switch disclosed in Patent Document 1 includes a main body case formed by joining a cover to a pole board having a fixed contact, and the main body case is rotatably supported by the main body case. A movable contact is provided on the movable platen.
The movable board is configured to rotate in conjunction with the operation of the shift lever, and the fixed contact with which the movable contact contacts is switched according to the rotation position of the movable board, and according to the fixed contact with which it contacts. The signal is output from the inhibitor switch.
The signal output from this inhibitor switch is used for specifying the selection range of the shift lever by a control device (not shown) such as a control device for an automatic transmission, and the automatic transmission is controlled based on the specified selection range. To be implemented.

  Here, for example, an inhibitor switch mounted on a vehicle is often used in an environment where there are many opportunities to come in contact with moisture or dust. There is a risk of poor contact with the fixed contact, short circuit, and deterioration of these contacts.

  For this reason, in the inhibitor switch according to the conventional example disclosed in Patent Document 1, in order to prevent the intrusion of foreign matter, a packing or the like is interposed at the junction between the pole plate and the cover to ensure the airtightness of the main body case. Furthermore, after the inhibitor switch is assembled, the airtightness of the main body case is inspected.

  In this airtight inspection, generally, there is air leakage from the joint between the pole board and the cover by making a hole in the main body case, submerging the inhibitor switch while supplying air into the main body case through the hole. Based on whether or not, it is confirmed whether the airtightness of the main body case is secured.

  However, in the case of this inspection method, the inhibitor switch used for the inspection was discarded because a hole was made in the main body case. Further, since inspection is performed by opening a hole in the main body case, only a sampling inspection can be performed, and an airtight inspection cannot be performed on all assembled inhibitor switches.

  For this reason, in a switch including a main body case that needs to be kept airtight, it is required to perform an airtight inspection without opening a hole in the main body case and destroying it.

  According to the present invention, a movable contact is provided in a movable plate rotatably supported by a main body case inside a main body case formed by joining a cover to an electrode plate having a fixed contact. In the switch in which the movable contact and the fixed contact come in contact with each other according to the moving position, the movable platen includes a shaft portion that passes through the main body case and is located outside the main body case. A shaft hole extending in the axial direction and a communication port communicating the shaft hole with the inside of the main body case were provided, and the opening at one end of the shaft hole was sealed with a sealing member.

According to the present invention, in the main body case before the sealing member is joined to the shaft portion, the inside and the outside of the main body case communicate with each other via the shaft hole and the communication port of the shaft portion.
Therefore, since the shaft hole and the communication port can be used in place of the hole opened in the main body case when the airtightness is inspected with a conventional switch, the airtight inspection can be performed without destroying the main body case.

It is a disassembled perspective view of the switch which concerns on embodiment. It is a top view of the switch concerning an embodiment. It is sectional drawing of the switch concerning embodiment. It is a flowchart explaining the assembly of a switch, and an airtight test | inspection. It is a figure explaining the airtight test | inspection of the main body case at the time of the assembly of a switch. It is a figure explaining the airtight test | inspection of the assembled switch.

  Hereinafter, as an embodiment of a switch according to the present invention, an inhibitor switch mounted on a vehicle and used for detecting a selection range of a shift lever will be described as an example.

  As shown in FIG. 1, the inhibitor switch 1 includes a main body case 4 formed by joining a cover 3 to a peripheral wall 22 surrounding an area of a fixed contact 21 (21 a to 21 e) of a pole board 2. Inside the case 4, a movable contact 70 is provided on the movable platen 5 supported by the main body case 4 so as to be rotatable around the axis X.

  The end 51b side of the shaft portion 51 of the movable platen 5 is connected to the arm 6 that rotates the movable platen 5 in synchronization with the operation of a shift lever (not shown) outside the main body case 4. When the shift lever is rotated in conjunction with the operation of the shift lever, the fixed contact 21 (21a to 21e) with which the movable contact 70 contacts is switched according to the rotation position of the movable platen 5.

  The pole board 2 is integrally formed from a non-conductive resin material having excellent heat resistance. The peripheral wall 22 is provided so as to extend toward the cover 3 so as to surround the region of the fixed contact 21 (21a to 21e), and the extending height of the peripheral wall 22 is the same over the entire circumference. . An upper end 22a of the peripheral wall 22 on the cover 3 side is a joining surface on which the cover 3 is placed and joined.

,
2 is a plan view of the inhibitor switch 1. FIG. 3A is a cross-sectional view taken along line AA in FIG. 2, and FIG. 2B is a cross-sectional view taken along line BB in FIG. .
As shown in FIGS. 1 and 3, in a substantially fan-shaped region surrounded by the peripheral wall 22 of the pole plate 2, a shaft portion 51 of the movable plate 5 described later is provided in the vicinity of a position corresponding to the top of the fan. A support hole 23 that is rotatably supported and a support wall 24 surrounding the support hole 23 are provided, and the support wall 24 extends along the axis X above the cover 3 side.

As shown in FIG. 1, the fixed contacts 21 (21 a to 21 e) have different lengths along the outer periphery of the support wall 24 at positions spaced apart from the rotation axis X of the movable plate 5 by a predetermined distance radially outward. It extends. In the embodiment, the fixed contact 21a and the fixed contact 21b, the fixed contact 21c, and the fixed contact 21d and the fixed contact 21e are provided so as to be positioned on virtual circles having different radii around the rotation axis X, respectively. ing.
These fixed contacts 21 (21 a to 21 e) are connected to terminals (not shown) of the connector portion 25 via conductive plates (not shown) provided inside the pole board 2.

The pole board 2 is formed from a non-conductive resin material having excellent heat resistance.
As shown in FIG. 3, the movable platen 5 has one end 51 b penetrating the cover 3 and positioned outside the main body case 4, and the other end 51 a is in contact with the bottom 23 a of the support hole 23. A shaft portion 51 and an extending portion 52 extending in the radial direction perpendicular to the rotation axis (axis line) X from the shaft portion 51 in the main body case 4 are provided, and these are integrally formed.
In the extension part 52, a holding part 53 that holds the movable contact 70 and the spring 71 is provided on the surface facing the fixed contact 21 (21 a to 21 e) on the tip side.
In the embodiment, the extending portion 52 is provided with two movable contacts 70 arranged in the radial direction as viewed from the shaft portion 51, and these movable contacts 70 are each urged by a spring 71, The platen 2 is in contact with the bottom surface 2a on which the fixed contact 21 is provided.

The shaft portion 51 is a cylindrical member in which a shaft hole 54 extending in the axial direction (axis X direction) is formed. The shaft hole 54 extends from one end 51b of the shaft 51 to the other end 51a. It is formed over the entire length in the axial direction.
The thickness of the cylindrical shaft portion 51 in the radial direction is substantially uniform over the entire length in the axial direction, whereby the strength of the shaft portion 51 is ensured and the shaft portion viewed from the axial direction. The outer peripheral shape of 51 is made into a substantially perfect circle shape.

  As shown in FIG. 3B, a notch 55 that penetrates the shaft portion 51 in the thickness direction (radial direction) is provided on the end portion 51 a side of the shaft portion 51. The portion 51 is provided along the axis X of the shaft portion 51 from the end portion 51a toward the end portion 51b side. As shown in FIG. 3A, the depth h1 of the notch 55 is set to be higher than the height H from the bottom 23a of the support hole 23 to the upper end of the support wall 24. The internal space S of the case 4 communicates with each other through a notch 55.

As shown in FIGS. 1 and 2, the cover 3 is a substantially fan-shaped plate-like member in plan view, and is formed from a non-conductive resin material having excellent heat resistance.
The cover 3 is provided with its peripheral edge placed on the peripheral wall 22 of the pole board 2, and the contact portion between the peripheral edge of the cover 3 and the peripheral wall 22 is joined by laser welding.

As shown in FIG. 3, in the cover 3, a bottomed cylindrical arm mounting portion 31 is provided at a position corresponding to the support hole 23 of the pole board 2 with a bottom 32 protruding toward the bottom surface 2 a side of the pole board 2. It has been.
The arm mounting portion 31 has an inner diameter into which a base portion 61 of the arm 6 to be described later can be inserted, and an insertion hole 32 a through which the shaft portion 51 of the movable platen 5 is inserted is provided at the center of the bottom portion 32.

  On the bottom surface of the bottom plate 32 on the bottom surface 2a side of the pole plate 2, an surrounding wall 33 surrounding the shaft portion 51 of the movable plate 5 inserted through the insertion hole 32a is formed extending from the periphery of the insertion hole 32a to the movable plate 5 side. The front end 33 a of the surrounding wall 33 is in contact with the upper surface of the extending portion 52 of the movable platen 5 on the cover 3 side.

A rubber O-ring 67 is fitted and attached to the bottom 32 of the arm attachment portion 31.
The O-ring 67 closes a gap C between the shaft portion 51 and the insertion hole 32a in a state where the O-ring 67 is externally inserted into the shaft portion 51 of the movable platen 5 penetrating the insertion hole 32a. The communication between the inside (internal space S) of the main body case 4 and the outside is prevented, and the airtightness of the main body case 4 is ensured.

  An arm 6 that transmits rotation to the movable platen 5 is joined to an end 51 b of the shaft 51 that is exposed to the outside of the main body case 4 in the arm attachment portion 31.

The arm 6 is made of a non-conductive resin material having excellent heat resistance.
As shown in FIG. 2, the arm 6 includes a base portion 61 that is substantially circular in plan view and an arm portion 65 that extends in the radial direction from the base portion 61. A long hole 66 extending in the radial direction is provided.

As shown in FIG. 3, the long hole 66 is provided so as to penetrate the arm portion 65 in the thickness direction.
When the inhibitor switch 1 is installed, a lever (not shown) connected via a link to a harness extending from the shift lever is inserted into the slot 66, and when the shift lever is operated, the slot 66 By the lever inserted into the arm 6, the distal end side of the arm 6 rotates around the rotation axis X (see FIG. 2), and the shaft portion 51 of the movable platen 5 connected to the arm 6 rotates around the rotation axis X. It is like that.

In the base portion 61 of the arm 6, a cylindrical outer fitting portion 62 that is fitted on the shaft portion 51 is provided on the surface facing the shaft portion 51. The outer fitting portion 62 has an inner diameter D2 that is slightly larger than the outer diameter D1 of the shaft portion 51, and extends from the outer peripheral edge of the base portion 61 to the shaft portion 51 side along the axis X.
The extension height h <b> 2 of the outer fitting portion 62 is such that the distal end portion 62 a of the outer fitting portion 62 presses the O-ring 67 against the bottom portion 32 of the arm attachment portion 31 in a state where the arm 6 is attached to the shaft portion 51. It is set to be in a state.
Communication between the inside and outside of the main body case 4 via the gap C between the shaft portion 51 and the insertion hole 32a is prevented by the O-ring 67, and in the assembled inhibitor switch 1, the airtightness of the main body case 4 is prevented. This is to ensure.

  In the base 61 of the arm 6, a cylindrical hole 63 is provided on the side opposite to the outer fitting portion 62, and the cylindrical hole 63 is formed with an inner diameter substantially the same as the outer diameter D <b> 1 of the shaft portion 51. It is provided coaxially with the shaft portion 51.

  The surface 61a on the shaft 51 side of the base 61 of the arm 6 is in contact with the end 51b of the shaft 51 from the axial direction, and the contact portion between the surface 61a and the end 51b is joined by laser welding. .

Hereinafter, assembly of the inhibitor switch 1 having such a configuration and an airtight inspection performed at the time of assembly will be described with reference to a flowchart of FIG.
FIG. 5 is a view for explaining an airtight inspection in the semi-finished main body case 4 before the arm 6 is joined to the shaft portion 51.
FIG. 6 is a diagram for explaining an airtight inspection in the inhibitor switch 1 after assembly.

  In step 101, the O-ring 67 is attached to the arm attachment portion 31 of the cover 3, and in step 102, the pole board 2, the cover 3, and the movable board 5 are assembled to assemble the main body case 4.

  Specifically, after the movable contact 70 is attached to the holding portion 53 of the extending portion 52 of the movable platen 5 with the spring 71 interposed, the end portion 51 a of the shaft portion 51 of the movable platen 5 is supported by the pole plate 2. The movable board 5 is assembled to the pole board 2 by being inserted into the holes 23. Then, the cover 3 is assembled to the pole board 2 so that the end 51b side of the shaft part 51 of the movable board 5 is inserted into the insertion hole 32a of the cover 3 in a state where the O-ring 67 is attached. Assemble 4

  In step 103, the contact portion between the peripheral edge of the cover 3 and the peripheral wall 22 is joined by laser welding. Thereby, the contact portion between the peripheral edge of the cover 3 and the peripheral wall 22 is melted to form a semi-finished body case 4 (contact housing) joined together.

In step 104, the airtightness of the main body case 4 is inspected (inspection method 1).
Specifically, as shown in FIG. 5, a joint member 81 in which a hose 80 extending from an air compressor (not shown) is connected to the shaft portion 51 of the movable platen 5 exposed in the arm mounting portion 31 of the cover 3. The O-ring 67 is held in a state in which the O-ring 67 is pressed against the bottom portion 32 of the arm attachment portion 31 at the distal end portion 81 a of the joint member 81.
And while supplying air from the air compressor into the main body case 4 through the shaft hole 54 and the notch 55 (while applying pressure), the main body case 4 is submerged. Air leakage from a portion joined by laser welding to the peripheral wall 22 (laser welding portion) or a sealing portion by the O-ring 67 (a gap C between the shaft portion 51 of the movable platen 5 and the insertion hole 32a of the cover 3). It is visually confirmed whether or not this occurs.

If air leakage is confirmed in step 105, it is confirmed in step 109 whether the air leakage has occurred from either the laser welding portion or the sealing portion by the O-ring 67.
In the case of the embodiment, air leakage may occur in the semifinished main body case 4 because it is one of the laser welding portion and the sealing portion by the O-ring 67.

  If it is confirmed in step 110 that the air leaks from the laser welded portion, laser welding of the contact portion between the peripheral edge of the cover 3 and the peripheral wall 22 is performed again in step 111. Then, the above-described airtight inspection of the main body case 4 in step 104 is performed again.

  On the other hand, when it is confirmed in step 110 that the air leakage from the sealing portion by the O-ring 67 is not the air leakage from the laser welded portion, the O-ring 67 is reattached in step 112. . For example, if the O-ring 67 is attached in a twisted state, air leaks from such a portion. The O-ring 67 may be replaced with another one. Then, the above-described airtight inspection of the main body case 4 in step 104 is performed again.

When the airtight inspection of the main body case 4 in Step 104 is performed and no air leakage is confirmed in Step 105, the arm 6 is joined to the shaft portion 51 of the movable platen 5 by laser welding in Step 106, Inhibitor switch 1 is formed.
Specifically, the base 61 of the arm 6 is attached to the shaft 51 of the movable platen 5 from the axial direction, and the opening of the shaft hole 54 in the end 51b of the shaft 51 is sealed with the surface 61a of the base 61. The contact portion between the surface 61a of the base portion 61 and the end portion 51b of the shaft portion 51 is joined by laser welding.

In step 107, an inspection of the airtightness of the inhibitor switch 1, specifically, an inspection of whether or not the main body case 4 is secured in the formed inhibitor switch 1 is performed (inspection method 2).
This is because when the base 61 of the arm 6 and the shaft 51 of the movable platen 5 are not sufficiently joined by laser welding, the airtightness of the main body case 4 in the inhibitor switch 1 after formation is not ensured.

  Specifically, as shown in FIG. 6, two inspection sealed containers having the same volume are prepared, the inhibitor switch 1 to be inspected is arranged in one container (inspection container A), and the other container (blank inspection). Inhibitor switch 1B, which has been confirmed to have no airtight leakage in container B), is placed as a blank. And the inside of the test container A and the blank test container B is decompressed using the common vacuum pump P. At this time, a pressure difference meter 85 is interposed between the inspection container A and the blank inspection container B and the vacuum pump P, and the pressure difference between the inspection container A and the blank inspection container B is determined by the pressure difference meter 85. Based on whether or not the pressure difference is within a predetermined threshold range, the presence or absence of air leakage from the main body case 4 of the inhibitor switch 1 to be inspected is determined.

  Here, in the embodiment, a differential pressure type leak tester (manufactured by Cosmo Keiki Co., Ltd .: LZ-1500 system) is adopted as the pressure difference meter.

In the inhibitor switch 1 to be inspected, when the base 61 of the arm 6 and the shaft 51 of the movable plate 5 are sufficiently joined by laser welding, the air inside the main body case 4 is also sucked by the vacuum pump P. Thus, air leakage from the main body case 4 occurs.
In such a case, the pressure difference between the inspection container A and the blank inspection container B is increased by the amount of air sucked from the main body case 4.

  Therefore, in the embodiment, the pressure difference (ΔPth) serving as a threshold is determined from the result of measuring the pressure difference by arranging another inhibitor switch that does not leak air from the main body case in the cuvette A. When the pressure difference (ΔP) measured by placing the inhibitor switch 1 to be inspected in the inspection container A is larger than the determined threshold pressure difference (ΔPth) (ΔPth <ΔP), In the inhibitor switch 1 to be inspected, it is determined that there is an air leak from the main body case 4, and when it is not large (ΔPth ≧ ΔP), it is determined that there is no air leak.

If it is determined in step 108 that there is an air leak, laser welding of the contact portion between the shaft portion 51 of the movable platen 5 and the base portion 61 of the arm 6 is performed again in step 113.
The processes in steps 107 and 108 and step 113 are performed until it is determined that there is no air leakage.

  If it is determined in step 108 that there is no air leakage, the air leakage inspection is terminated, and the assembly of the inhibitor switch 1 and the airtight inspection are terminated.

  Here, the arm 6 in the embodiment corresponds to the sealing member in the invention, the notch 55 in the embodiment corresponds to the communication port in the invention, and the O-ring 67 in the embodiment corresponds to the ring in the invention. The outer fitting portion 62 in the embodiment corresponds to a peripheral wall portion in the invention.

As described above, in the embodiment, the movable contact 70 is formed inside the body case 4 formed by joining the peripheral edge of the cover 3 to the upper end 22a of the peripheral wall 22 of the pole board 2 having the fixed contact 21 (21a to 21e). Is provided in the extending portion 52 of the movable platen 5 that is rotatably supported by the main body case 4, and the movable contact 70 and the fixed contact 21 (21 a to 21 e) according to the rotation position of the movable platen 5. In the inhibitor switch 1 that contacts and separates, the movable platen 5 has one end 51b penetrating the cover 3 and positioned outside the main body case 4, and the other end 51a is the bottom of the support hole 23 of the pole plate 2. The shaft portion 51 includes a shaft portion 51 that abuts the shaft portion 54. The shaft portion 51 includes a shaft hole 54 that extends in the axial direction from the end portion 51 b, and a notch 55 that communicates the shaft hole 54 with the internal space S of the main body case 4. The shaft portion 5 is provided on the end portion 51 b of the shaft portion 51. It is joining the arm 6 to rotate and has a structure in which the opening of the shaft hole 54 at the end 51b of the shaft portion 51 is sealed at the base 61 of the arm 6.
Thereby, in the semifinished body case 4 before the arm 6 is joined to the shaft portion 51, the inside and the outside of the body case 4 communicate with each other through the shaft hole 54 and the notch 55 of the shaft portion 51. Therefore, the shaft hole 54 and the notch 55 can be used in place of the holes opened in the main body case when the airtightness is inspected with a conventional switch. Therefore, an airtight inspection can be performed without destroying the main body case.
Further, since it is not necessary to make a hole in the main body case and destroy it for airtight inspection, the yield is improved at least by the amount of the main body case that has been conventionally discarded, and the manufacturing cost can be reduced. Further, since no hole is formed, an airtight inspection can be performed more easily, and the inspection efficiency is improved. Further, since all of the semi-finished main body cases can be subjected to airtight inspection, an inhibitor switch (switch) with a low defective product rate and high reliability can be provided.

Further, an O-ring 67 attached to the arm attachment portion 31 of the cover 3 is extrapolated on the end portion 51 b side of the shaft portion 51 that is located outside the main body case 4 through the insertion hole 32 a of the cover 3. The base portion 61 of the arm 6 has a cylindrical outer fitting portion 62 that is fitted on the shaft portion 51, and the arm 6 is interposed between the outer fitting portion 62 and the bottom portion 32 of the arm attachment portion 31. The O-ring 67 is sandwiched and the gap C between the shaft 51 and the insertion hole 32a is closed by the O-ring 67, and the O-ring 67 is joined to the shaft 51.
Thereby, since the communication between the inside and the outside of the main body case 4 via the gap C is prevented by the O-ring 67, the airtightness in the main body case 4 can be secured in the assembled inhibitor switch 1.

Further, the joining of the peripheral edge of the cover 3 and the peripheral wall 22 of the pole board 2 and the joining of the base 61 of the arm 6 and the end 51b of the shaft 51 are performed by laser welding.
Thereby, in the case of airtight inspection in the semi-finished main body case 4 and the assembled inhibitor switch 1, when air leakage from the joint portion is confirmed, laser welding is performed again to repair the air leakage. Can improve the yield.
Further, in the case of laser welding, it is possible to re-weld a defective joint location any number of times, so that the semi-finished main body case 4 and the inhibitor switch 1 with no airtight leakage can be reliably produced. Therefore, like the conventional switch, the inhibitor switch 1 in which airtightness is not ensured is obtained, and it is not necessary to discard it. Further, when the peripheral edge of the cover 3 and the peripheral wall 22 of the pole board 2 are joined by laser welding, the joining by the laser welding has a high joining strength and can ensure airtightness. There is no need to interpose a member for maintaining airtightness such as packing. Therefore, the packing can be omitted, and in this case, the number of parts is reduced by the amount not using the packing, so that the manufacturing cost of the inhibitor switch 1 can be reduced.

Furthermore, in the embodiment, in the semifinished body case 4 before the arm 6 is joined to the shaft portion 51, from the opening of the shaft hole 54 in the end portion 51 b of the shaft portion 51 located outside the body case 4, Air (air) is supplied to the inside of the main body case 4, and air from the gap (sealed welded portion) between the peripheral edge of the cover 3 and the peripheral wall 22 of the pole board 2 and the gap C sealed by the O-ring 67. A first confirmation step for confirming leakage of air and an inhibitor switch 1 obtained by joining the arm 6 to the shaft portion 51 of the main body case in which air leakage was not confirmed in the first confirmation step, A comparative inhibitor switch 1B having no air leakage is disposed in a container B for comparison having the same volume as the container A for airtightness inspection, and the container A for airtightness inspection is provided in the container A for airtightness inspection. Air and air in the container B for comparison , The pressure difference between the container A for airtightness inspection and the container for comparison B is measured with a pressure difference meter 85 while being discharged using a common vacuum pump P and decompressed, and based on the pressure difference, Inhibitor switch 1 is an airtight inspection method comprising: a second confirmation step for confirming whether or not the gas in main body case 4 of inhibitor switch 1 has leaked from the joint between shaft portion 51 and arm 6. The airtightness of the main body case 4 was inspected.
Thereby, during the assembly of the inhibitor switch 1, there is a possibility that the airtightness of the main body case 4 may not be ensured (joining of the cover 3 and the peripheral wall 22 of the pole plate 2, attachment of the O-ring 67, movable plate 5 After the joining of the shaft portion and the arm 6), an airtight inspection is performed to check whether there is any air leakage from the main body case 4.
If air leakage is confirmed, the problematic process is repeated until no air leakage is confirmed. Therefore, in the conventional case where the airtight inspection is performed after the assembly of the inhibitor switch 1 is completed. In comparison, the failure rate of the inhibitor switch 1 can be reduced, and the number of the inhibitor switch 1 and components to be discarded can be reduced.
In addition, since all of the assembled inhibitor switches are subjected to an airtight inspection at least twice, the reliability of the inhibitor switches is further improved.
In particular, by joining by laser welding, it is not necessary to interpose a packing at the part to be joined as in the case of joining by conventional ultrasonic welding, so that the number of parts can be reduced. Further, laser welding can be performed in a short time without applying vibration, and it is not necessary to interpose an adhesive in the joint portion, so that it is possible to reduce work costs and production costs. And since the part joined by laser welding has high joining strength, it is not necessary to use other fastening parts such as screws in order to join the cover 3 and the peripheral wall 22 of the pole board 2, so the number of parts can be reduced. Is possible.

  In the embodiment, the main body case 4 is submerged while applying air to the main body case 4 of the semi-finished product, and the airtightness is inspected based on the presence or absence of air leakage from the main body case 4. Alternatively, a fluid for inspection (for example, inspection oil) may be injected into the body, and the airtightness may be inspected based on the presence or absence of leakage of the injected fluid from the main body case 4.

  Further, in the embodiment, the O-ring 67 is provided in the arm attachment portion 31 of the cover 3, but any member that can close the gap C between the shaft portion 51 and the insertion hole 32 a and ensure the airtightness of the main body case 4. Other rubber seal members such as an oil seal and an X ring may be provided.

  Further, in the embodiment, the case where the joining between the cover 3 and the peripheral wall 22 of the pole board 2 and the joining between the base portion 61 of the arm 6 and the shaft portion 51 are performed by laser welding is exemplified. Can be secured by vibration welding or ultrasonic welding, or may be joined using screws, rivets, adhesives, or the like.

  Further, in the embodiment, the shaft hole 54 of the shaft portion 51 and the internal space S of the main body case 4 are communicated with each other by the notch 55 provided in the end portion 51 a of the shaft portion 51, but instead of the notch 55. A through hole penetrating the shaft portion 51 in the thickness direction may be provided so that the shaft hole 54 and the internal space S communicate with each other.

  In the embodiment, one end portion 51 b of the shaft portion 51 in the movable platen 5 is positioned outside the main body case 4 through the cover 3, and the other end portion 51 a is a support hole of the pole plate 2. However, one end portion 51b of the shaft portion 51 is provided in contact with the cover 3, and the other end portion 51a serves as the pole board 2. It may be provided so as to penetrate and be located outside the main body case 4. In this case, by providing at least the shaft hole 54 so as to extend in the axial direction from the end portion 51a of the shaft portion 51, the same effect as in the case of the above-described embodiment can be obtained.

Further, one end 51b and the other end 51a of the shaft portion 51 may be provided through the cover 3 and the pole board 2 so as to be positioned outside the main body case 4, respectively. . In such a case, the shaft hole 54 extending in the axial direction of the shaft portion 51 is connected to the end portion (end portion 51b) where the arm 6 is not joined from the end portion (end portion 51a or end portion 51b) where the arm 6 is joined. Alternatively, it is preferably formed toward the end portion 51a) so that the shaft hole 54 is not penetrated to the end portion (end portion 51b or end portion 51a) where the arm 6 is not joined. In addition, when the shaft hole 54 is penetrated to the end portion (the end portion 51b or the end portion 51a) where the arm 6 is not joined, sealing such as a cap for sealing the opening of the shaft hole 54 at the end portion. It is preferable to provide a member.
By doing in this way, the same effect as in the case of the above-described embodiment can be obtained.

  Further, the opening at the end 51b of the shaft 51 does not necessarily need to be sealed with the base 61 of the arm 6, and a sealing member such as a cap prepared separately from the arm 6 is joined / fitted to the end 51b. In combination, the opening may be sealed with a sealing member.

1 Inhibitor switch 2 Polar board 3 Cover 4 Body case 5 Movable board 6 Arm (sealing member)
21 (21a to 21e) Fixed contact 22 Peripheral wall 23 Support hole 24 Support wall 25 Connector part 31 Arm attachment part 32 Bottom part 32a Insertion hole 33 Enclosure wall 51 Shaft part 51a End part 51b End part 52 Extension part 54 Shaft hole 55 Notch (Communication entrance)
61 Base part 62 Outer fitting part 63 Cylindrical hole 65 Arm part 66 Long hole 67 O-ring (ring-shaped elastic member)
70 movable contact 71 spring 80 hose 81 joint member 85 pressure difference meter P vacuum pump

Claims (5)

Inside the body case formed by joining a cover to a pole board having a fixed contact, a movable contact is provided on the movable board supported to be pivotable by the body case, and the pivot position of the movable board In the switch in which the movable contact and the fixed contact are contacted and separated according to
The movable plate includes a shaft portion at least one end penetrating through the main body case and positioned outside the main body case,
The shaft portion is provided with a shaft hole extending in the axial direction from the one end, and a communication port communicating the shaft hole with the inside of the main body case, and the opening at the one end of the shaft hole is sealed with a sealing member. A switch characterized by stopping. A ring-shaped elastic member is extrapolated to the shaft portion outside the main body case,
The sealing member has a peripheral wall portion that is fitted around the shaft portion, and is joined to the shaft portion in a state where the elastic member is sandwiched between the peripheral wall portion and the main body case. The switch according to claim 1.   The switch according to claim 1, wherein the sealing member is an arm that is joined to the shaft portion and rotates the shaft portion.   The switch according to any one of claims 1 to 3, wherein the joining is performed by laser welding. An airtight inspection method for a switch according to any one of claims 1 to 3,
In the main body case before the opening is sealed with the sealing member,
A first confirmation step of supplying a fluid to the inside of the main body case from the opening and confirming whether or not the fluid leaks from the main body case;
In the main body case where leakage of the fluid was not confirmed in the first confirmation step, a switch obtained by sealing the opening with the sealing member is disposed in a container for airtightness inspection,
A comparison switch that does not leak the fluid is disposed in a comparison container having the same volume as the container for airtightness inspection,
While the gas in the airtight inspection container and the gas in the comparative container are exhausted and decompressed using a common pump, the pressure between the airtight inspection container and the comparative container A second confirmation step of measuring a difference and confirming whether or not the gas in the main body case leaks from a joint portion between the shaft portion and the arm based on the pressure difference. Airtight inspection method characterized by.

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