The present invention relates to a switch device having a rubber sheet which is elastically deformed by receiving an operating force.
Usually, as a switch device used in a vehicle, for instance, a switch device is known that includes a base board having a fixed contact on one surface and a rubber sheet formed with an elastic material to cover the surface of the fixed contact side of the base board. The rubber sheet has a contact dome part that covers the fixed contact on the base board. A movable contact is provided in the base board side of the contact dome part. In this case, the contact dome part of the rubber sheet forms a contact chamber as a hollow space between the base board and the contact dome part. The contact chamber is allowed to communicate with an air accumulating chamber whose volume is larger than that of the contact chamber.
In the switch device having such a structure, when an operating force is applied to the contact dome part of the rubber sheet, the contact dome part is elastically deformed. Thus, the movable contact provided in the contact dome part comes into contact with the fixed contact provided on the base board. At this time, air in the contact chamber is compressed by the contact dome part of the rubber sheet to be pushed out to the air accumulating chamber. Then, when the operating force is released, the contact dome part in the rubber sheet is restored so that the movable contact of the contact dome part is disengaged from the fixed contact on the base board. Thus, the air pushed out to the air accumulating chamber is sucked to the contact chamber. As described above, during an operation of the switch device, the air in the contact chamber enters the air accumulating chamber and the air exits from the air accumulating chamber, what is called, the switch device breathes. Thus, a reaction of the air due to the compression of the air during the operation is prevented to make the operation easy.
However, in the above-described structure, the air accumulating chamber needs to ensure the volume larger than that of the contact chamber. Accordingly, the air accumulating chamber is frequently provided over a part on which, for instance a terminal of a connector or electronic parts are mounted on the base board. In this case, there is a fear that the contact chamber may possibly suck foreign materials such as solder chips remaining in the air accumulating chamber by breathing. Thus, the foreign materials are occasionally sandwiched between the fixed contact and the movable contact to cause an imperfect contact of these contacts.
Under the above-described circumstance, a structure is disclosed that a foreign material accumulating chamber is provided between a contact chamber and an air accumulating chamber (for instance, patent literature 1). In such a structure, the contact chamber does not directly communicate with the air accumulating chamber. Accordingly, when the contact chamber breathes by an operation, foreign materials present in the air accumulating chamber are temporarily sucked to the foreign material accumulating chamber. Thus, the foreign materials present in the air accumulating chamber are prevented from directly entering the contact chamber.
However, the foreign material accumulating chamber directly communicates with the contact chamber. Accordingly, there is a fear that the contact chamber may possibly suck the foreign materials temporarily collected to the foreign material accumulating chamber.
Thus, the present invention is devised by considering the above-described circumstances, and it is an object of the present invention to provide a switch device having a structure that foreign materials in an air accumulating chamber are hardly sucked to a contact chamber to reduce an imperfect contact due to the foreign materials.
In order to achieve the above-described object, a switch device of the present invention, comprising:
a base board having a face on which a fixed contact is provided; and
an elastic sheet that covers the face of the base board,
wherein the elastic sheet includes:
Preferably, the vent groove is connected to the guide groove at a position nearer to the second recessed part than to the first recessed part.
Preferably, an angle formed by the guide groove and the vent groove at the connecting part is set to an acute angle.
Preferably, the nonreturn part is a straight inner wall of the foreign material accumulating chamber which defines a width of an inlet port of the foreign material accumulating chamber, and the straight inner wall of the foreign material accumulating chamber extends in substantially parallel with an extending direction of the straight part.
Here, it is preferable that, the foreign material accumulating chamber is formed by a semicircular inner wall and the straight inner wall.
Preferably, the nonreturn part is a straight inner wall of the foreign material accumulating chamber which extends in substantially parallel with an extending direction of the straight part, and the foreign material accumulating chamber is formed by a first semicircular inner wall, a second semicircular inner wall provided in substantially parallel with the first semicircular inner wall, and the straight inner wall connecting the first semicircular inner wall and the second semicircular inner wall.
According to the above-described structure, when the operating force is released and the elastically deformed contact dome part is restored to an original form, air in the air accumulating chamber is sucked to the contact chamber through the vent passage from the guide passage. At this time, foreign materials in the air accumulating chamber are occasionally sucked to the guide passage together with the air in the air accumulating chamber. Here, the guide passage is formed in the shape of a circular arc from the shape of a straight line and connected to the foreign material accumulating chamber. Therefore, the foreign materials sucked to the guide passage are easily guided to the foreign material accumulating chamber along the straight part of the guide passage. Accordingly, the foreign materials sucked to the guide passage hardly enter the contact chamber through the vent passage connected to the guide passage. Then, the foreign materials entering the foreign material accumulating chamber are prevented from flowing out from the foreign material accumulating chamber by the nonreturn part. In such a way, the switch device has a structure that the foreign materials in the air accumulating chamber are hardly sucked to the contact chamber. As a result, an imperfect contact due to the foreign materials is reduced.
The above objects and advantages of the present invention will become more apparent by describing in detail preferred exemplary embodiments thereof with reference to the accompanying drawings, wherein:
Now, switch devices according to a plurality of exemplary embodiments will be described below by referring to the drawings. In each of the exemplary embodiments, the same components are designated by the same reference numerals and an explanation thereof will be omitted.
(First Exemplary Embodiment)
As shown in
The base board 12 is provided in an upper side of the support part 112 of the base 11. The base board 12 is formed in the shape of a rectangular plate by, for instance, a printed wiring board. On one surface of the base board 12, specifically, on an opposite surface to the base 11, that is, on an upper side surface, a fixed contact 16 and an electronic parts 17 are provided. As shown in
The base board 12 has a terminal 18 in the vicinity of the electronic parts 17. The terminal 18 is formed with a metal rod having an electrical conductivity. The terminal 18 passes through the base board 12 in the direction of thickness and has one end part protruding on the surface of the base board 12 of the fixed contact 16 side. The terminal 18 has one end part soldered and fixed to the base board 12. In this case, in the periphery of the terminal 18, a solder part 181 is formed. Further, the fixed contact 16, the electronic parts 17 and the terminal 18 are electrically connected by a wiring pattern not shown in the drawing to form a circuit not shown in the drawing.
Further, the terminal 18 passes through the main body part 111 of the base 11 and has the other end part protruding to the connector part 113. In this case, the connector part 113 and the terminal 18 form a male type connector. To the connector part 113, what is called a female type connector, whose detail is not shown, is fitted. Thus, the switch device 10 is connected to a controller not shown in the drawing that controls the defogger. Then, a signal that supplies an electric current or does not supply an electric current to the fixed contact 16 is transmitted to the controller from the switch device 10.
The rubber sheet 13 is provided on the upper surface of the base board 12, namely, on the surface of the base board 12 of the base board 12 of the fixed contact 16 side. The rubber sheet 13 is formed with a material having elasticity, for instance, silicone rubber. As shown in
As shown in
The pressed part 192 of the contact dome part 19 is provided in a central part of the deformed part 191. The pressed part 192 is formed in a cylindrical shape and passes through the deformed part 191 substantially vertically to the attaching surface 131 of the rubber sheet 13. In this case, the pressed part 192 has one end part protruding to the base board 12 side of the deformed part 191 and the other end part protruding to an opposite side of the deformed part 191 to the base board 12.
The movable contact 20 is provided in one end part of the pressed part 192. The movable contact 20 is formed with a material having an electrical conductivity, for instance, a metal film or an electrically conductive resin. When an operating force is applied to the pressed part 192 to elastically deform the deformed part 191, the movable contact 20 is engaged with or disengaged from the fixed contact 16 on the base board 12. Thus, a state of the fixed contact 16 is switched that an electric current is supplied or an electric current is not supplied.
As shown in
Further, as shown in
As shown in
As shown in
Specifically, as shown in
As shown in
As shown in
In the present exemplary embodiment, as shown in
As shown in
In the case 14, the operating member 15 is provided in the upper case part 142. Specifically, as shown in
Now, an operation of the above-described structure will be described below.
In the switch device 10, when a user presses the operating member 15, the operating member 15 is moved downward. Then, the pressed part 192 of the contact dome part 19 formed in the rubber sheet 13 is pressed downward by the transmitting part 151 of the operating member 15. At this time, the deformed part 191 of the contact dome part 19 formed in the rubber sheet 13 is collapsed downward and elastically deformed. Then, when the deformed part 191 of the contact dome part 19 is collapsed and elastically deformed, the movable contact 20 provided in a lower surface of the pressed part 192 comes into contact with the fixed contact 16 on the base board 12. Thus, in the fixed contact 16, one pair of contacts which are electrically disconnected is electrically conducted to each other.
In this case, the switch device 10 is turned on and a turning on signal processed by the electronic parts 17 of the base board 12 is transmitted to a controller of the defogger not shown in the drawing through the terminal 18. As a result, the defogger is driven. After that, when the user releases a pressing operation of the operating member 15, the deformed part 191 of the contact dome part 19 which is elastically deformed is restored to the shape of the bowl before the deformation. In this case, the movable contact 20 provided in the lower surface of the pressed part 192 is disengaged from the fixed contact 16 on the base board 12 in accordance with the restoration of the deformed part 191 of the contact dome part 19. Then, in accordance with the restoration of the deformed part 191, the operation member 15 is pressed upward and returned to an initial position before the operation.
During the above-described operation, between spaces formed between the base board 12 and the rubber sheet 13, that is, the contact chamber 26, the air accumulating chamber 27, the foreign material accumulating chambers 28, the guide passages 29 and the vent passages 30, a flow of air is generated. Now, the flow of the air during the operation will be described by mainly referring to
In the contact dome part 19 of the rubber sheet 13, when the pressed part 192 is pressed downward by the transmitting part 151 of the operating member 15, the deformed part 191 is collapsed and elastically deformed. Thus, the content volume of the contact chamber 26 is reduced in accordance with the elastic deformation of the deformed part 191 of the contact dome part 19. Therefore, the air in the contact chamber 26 is pushed out. The air pushed out from the contact chamber 26 is supplied to the guide passages 29 through the vent passages 30. In this case, while the guide passages 29 are connected to the air accumulating chamber 27 and the foreign material accumulating chambers 28, the air accumulating chamber 27 has a content volume sufficiently larger than that of the foreign material accumulating chamber 28. Accordingly, most of the air supplied to the guide passages 29 is supplied to the air accumulating chamber 27.
Then, when the pressing operation of the operating member 15 is released, the deformed part 191 in the contact dome part 19 of the rubber sheet 13 is restored to the shape of an original bowl by its elasticity. Then, the content volume of the contact chamber 26 is increased in accordance with the restoration of the deformed part 191 of the contact dome part 19. Therefore, the contact chamber 26 sucks therein the air in the periphery thereof, that is, the air in the air accumulating chamber 27, the foreign material accumulating chambers 28, the guide passages 29 and the vent passages 30. In this case, the deformed part 191 of the contact dome part 19 is restored during a short time. Accordingly, the air in the periphery of the contact chamber 26 is sucked to the contact chamber 26 during the short time when the deformed part 191 is restored.
At this time, the air in the air accumulating chamber 27 is sucked to the guide passages 29. When foreign materials such as dust or solder chips remain in the air accumulating chamber 27, the foreign materials are occasionally sucked to the guide passages 29 together with the air. In this case, the foreign materials sucked to the guide passages 29 advance linearly along the straight parts 231 in the guide passages 29. Then, the foreign materials pass connecting parts of the guide passages 29 and the vent passages 30, advance along the circular arc parts 232 due to an inertia as shown by arrow marks B and further enter the foreign material accumulating chambers 28 along the guide walls 221 of the second recessed parts 22 forming the foreign material accumulating chambers 28.
Here, in the case of the present exemplary embodiment, the diametrically outer walls of the circular arc parts 232 forming the guide passages 29 and the guide walls 221 of the second recessed parts 22 forming the foreign material accumulating chambers 28 are set so as to have substantially the same radius of curvature. Accordingly, the foreign materials are smoothly guided to the foreign material accumulating chambers 28 along the walls of the circular arc parts 232 and the guide walls 221. Further, in the guide passages 29 and the vent passages 30, angles formed by the guide passages 29 of the air accumulating chamber 27 side and the vent passages 30 are set to be smaller than angles formed by the guide passages 29 of the foreign material accumulating chamber 28 side and the vent passages 30. Therefore, the foreign materials sucked to the guide passages 29 hardly enter the vent passages 30.
Then, when the switch device 10 is further operated, the flow of the air is generated again between the contact chamber 26, the air accumulating chamber 27, the foreign material accumulating chambers 28, the guide passages 29 and the vent passages 30. In this case, the foreign material entering the foreign material accumulating chambers 28 are apt to enter the guide passages 29 by the flow of the air, however, a backflow of the foreign materials to the guide passages 29 is stopped by the nonreturn parts 24. Accordingly, after the foreign materials are once collected to the foreign material accumulating chambers 28, the foreign materials hardly flow backward from the foreign material accumulating chambers 28.
Further, in the case of the present exemplary embodiment, the content volumes of the foreign material accumulating chambers 28 are sufficiently smaller than the content volume of the air accumulating chamber 27. Further, since the walls forming the peripheries of the foreign material accumulating chambers 28 are hardly elastically deformed, the content volumes of the foreign material accumulating chambers 28 are hardly changed. Accordingly, the air pushed out from the contact chamber 26 hardly enters the foreign material accumulating chambers 28. Thus, the flow of air is hardly generated therein. As a result, the foreign materials entering the foreign material accumulating chambers 28 are hardly agitated by the flow of the air and the backflow of the foreign materials to the guide passages 29 can be more effectively prevented.
As described above, according to the present exemplary embodiment, when the operating member 15 is pressed, since the deformed part 191 of the contact dome part 19 is elastically deformed, the air in the contact chamber 26 is pushed out to the air accumulating chamber 27. Then, the operating force is released so that the deformed part 191 of the contact dome part 19 is restored, the contact chamber 26 sucks the air in the air accumulating chamber 27. In such a way, since the switch device 10 carries out what is called a breathing operation, a reaction of the air due to a compression of the air in the contact chamber 26 during the operation is prevented to make the operation easy.
In this case, the foreign materials sucked to the guide passages 29 from the air accumulating chamber 27 due to breathing hardly enter the vent passages 30 branching from the guide passages 29. Namely, the foreign materials sucked to the guide passages 29 pass the guide passages 29 and are guided to the foreign material accumulating chambers 28 due to the inertia. Then, the foreign materials entering the foreign accumulating chambers 28 are prevented from flowing out from the foreign material accumulating chambers 28 by the nonreturn parts 24. In such a way, the switch device 10 has a structure that the foreign materials remaining in the air accumulating chamber 27 are hardly sucked to the contact chamber 26. As a result, an imperfect contact is reduced that is caused by the foreign materials entering between the fixed contact 16 and the movable contact 20.
Further, according to the present exemplary embodiment, the vent passages 30 through which the contact chamber 26 communicates with the guide passages 29 are connected to the guide passages 29 at positions nearer to the foreign material accumulating chambers 28 than to the air accumulating chamber 27. Accordingly, the foreign materials entering the guide passages 29 from the air accumulating chamber 27 are guided to the foreign material accumulating chambers 28 without stopping in the vicinity of the connecting parts of the guide passages 29 and the vent passages 30. Therefore, the foreign materials entering the guide passages 29 from the air accumulating chamber 27 are more assuredly guided to the foreign material accumulating chambers 28. As a result, the imperfect contact due to the foreign materials is more effectively reduced.
Here, the contact chamber 26 sucks the air in the periphery thereof during the short time when the operating force to the operating member 15 is released so that the deformed part 191 of the contact dome part 19 is restored. Namely, a suction force that the contact chamber 26 sucks the air in the periphery is weakened during the short time after the operating force to the operating member 15 is released. Therefore, as a moving distance, that is, a moving time to the connecting parts of the guide passages 29 and the vent passages 30 is more increased, the foreign materials entering the guide passages 29 from the air accumulating chamber 27 are the more hardly sucked to the contact chamber 26 from the connecting parts. In the present exemplary embodiment, the vent passages 30 are connected to the guide passages 29 at the positions nearer to the foreign material accumulating chambers 28 than to the air accumulating chamber 27. Therefore, the distance can be ensured until the foreign materials pass the connecting parts of the guide passages 29 and the vent passages 30. As a result, the switch device 10 has the structure that the foreign materials are more hardly sucked to the contact chamber 26.
(Second Exemplary Embodiment)
As shown in
(Third Exemplary Embodiment)
As shown in
In the above-described exemplary embodiments respectively, the rubber sheet 13 includes the two second recessed parts 22 or the two second recessed parts 31, the two guide grooves 23, the two nonreturn parts 24 or the two nonreturn parts 32 and the two vent grooves 25 relative to the one contact dome part 19. However, the present invention is not limited thereto, and the number of the second recessed parts 22 or the second recessed parts 31, the guide grooves 23, the nonreturn parts 24 or the nonreturn parts 32 and the vent grooves 25 relative to the contact dome part 19 may be suitably increased or decreased. Further, a plurality of first recessed parts 21 whose volumes are respectively smaller than the volume of the contact dome part 19 may be allowed to mutually communicate. Further, the rubber sheet 13 may include a plurality of contact dome parts 19. In this case, the plurality of contact dome parts 19 may be allowed to communicate with one first recessed part 21.
In the above-described exemplary embodiments, the switch device is shown that is used in the defogger of the vehicle, however, the present invention is not limited thereto, the switch device of the present invention may be widely applied to switch devices used for other units than the vehicle.
In addition, the present invention is not limited to the above-described exemplary embodiments shown in the drawings and may be suitably changed and embodied within a range that does not deviate from a gist of the invention.
Although the invention has been illustrated and described for the particular preferred embodiments, it is apparent to a person skilled in the art that various changes and modifications can be made on the basis of the teachings of the invention. It is apparent that such changes and modifications are within the spirit, scope, and intention of the invention as defined by the appended claims.
The present application is based on Japanese Patent Application No. 2010-292713 filed on Dec. 28, 2010, the contents of which are incorporated herein by reference.
Number | Date | Country | Kind |
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2010-292713 | Dec 2010 | JP | national |
Number | Name | Date | Kind |
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4931601 | Lavender | Jun 1990 | A |
20110247926 | Osborn et al. | Oct 2011 | A1 |
20120138443 | Wang et al. | Jun 2012 | A1 |
Number | Date | Country |
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2010-040490 | Feb 2010 | JP |
Number | Date | Country | |
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20120160655 A1 | Jun 2012 | US |