JP4319918B2 - Contact plate and switch using the same - Google Patents

Description

  The present invention relates to a contact plate used as a movable contact of a pushbutton switch, and more particularly to a disk-shaped contact plate press-molded in a dome shape and a switch structure using the same.

  As a structure of a movable contact of a conventional push button switch, a skirt portion rising from an outer peripheral portion at a predetermined angle and a dome portion having a dome-shaped bulging portion continuous with the skirt portion are provided, and the dome portion is pressed. Thus, a movable contact is known in which the dome portion is reversed and comes into contact with a fixed contact disposed oppositely (see, for example, Patent Document 1).

Hereinafter, the structure of a movable contact of a conventional push button switch will be described with reference to the drawings.
13 is a sectional view of a conventional push button switch, FIGS. 14A and 14B are perspective views and sectional views of movable contacts used in the conventional push button switch, and FIGS. 15A and 15B are movable contacts. FIG.

  In FIG. 13, reference numeral 51 denotes an insulating resin box-shaped case in which outer fixed contacts 53A and 53B and a central fixed contact 55 are planted by insert molding on the inner bottom surface, and an elastic metal thin plate is formed on the outer fixed contacts 53A and 53B. The dome-shaped movable contact 60 is mounted to form a switch contact in which the outer fixed contacts 53A, 53B and the central fixed contact 55 are contacted and separated via the dome-shaped movable contact 60. The operation body 57 is mounted so as to be movable up and down so that the pressing portion 57A is in contact with the upper surface of the operation body 57. It protrudes into the operation part.

As shown in FIG. 14, the shape of the dome-shaped movable contact 60 is a substantially spherical shape in which the outer peripheral portion 60A has a truncated cone shape and the inner central portion 60B slightly bulges upward, and the boundary between the two is a smooth curve. The elastic metal thin plate is drawn so as to have a shape connected with each other.
In other words, the movable contact of the conventional pushbutton switch has a dome shape in which the outer peripheral portion 60A constitutes a skirt portion rising from the outer peripheral portion at a predetermined angle, and a substantially spherical central portion 60B bulging upward is continuous with the skirt portion. The dome part which has the bulging part of this is comprised.

  Then, when the substantially spherical central portion 60B (dome portion) is pressed by the pressing portion 57A of the operating body 57, the central portion 60B is reversed downward, and the central fixed contact disposed oppositely. 55, the outer fixed contacts 53A and 53B and the central fixed contact 55 come into contact with each other via the dome-shaped movable contact 60, and the switch contact is turned on.

Japanese Patent Laid-Open No. 11-67002

However, in the structure of the movable contact of the conventional pushbutton switch described above, a click feeling is generated by pressing and reversing the dome 60B. However, as shown in FIGS. When the pressing position of 70 is deviated from the central portion of the dome portion 60B toward the peripheral side, the central portion of the dome portion 60B is not reversed and the pressing is completed, so that a desired click feeling cannot be obtained. There was a problem.
For this reason, the positioning with the operation push button on the electronic device side mounted so as to press within a predetermined range (sweet spot: range where the click feeling is good) from the center (top) of the dome 60B is enhanced. It was necessary to carry out with accuracy, and the work became complicated and became a factor hindering assembly.

  Accordingly, an object of the present invention is to solve the above-mentioned problems and to provide a contact plate capable of forming a wide pressing range in which a desired click feeling of the dome portion can be formed, and a switch using the contact plate. To do.

  In order to solve the above-mentioned problems, the present invention includes, as a first solving means, a skirt portion that rises at a predetermined angle, and a reversible dome portion that is continuous through a connection portion with the skirt portion, First and second hinge portions that are bent inward in stages are formed at the connection portion with the dome portion, and are generated in the first and second hinge portions when the dome peripheral edge is pressed. The center of the dome portion is inverted to a predetermined position by the elastic force.

Further, as a second solution, the first and second hinge portions formed at the connection portion between the skirt portion and the dome portion are each formed at a bending angle of less than 180 degrees.
Further, as a third solving means, the first hinge part is connected to the skirt part, the second hinge part is connected to the dome part, and the second hinge is used when the dome part is repeatedly inverted. The connection position of the part is formed to be higher than the connection position of the first hinge part.

Further, as a fourth solving means, the outer surface of the contact plate made of any of the first to third solving means is attached to the adhesive layer of the insulating sheet having the adhesive layer on the back surface, and the back surface of the insulating sheet. Was used as an adhesive attachment part.
Further, as a fifth solving means, a configuration in which a contact plate made of the fourth solving means is attached to a circuit board on which a fixed contact is disposed by an adhesive layer of the insulating sheet so as to face the fixed contact. It was.

  Further, as a sixth solution means, a contact plate comprising any one of the first to third solution means, a housing having a storage portion, and a fixed contact disposed on the inner bottom surface of the storage portion, And a pressing member fitted in the storage portion so as to be movable up and down, and the contact plate is arranged to face the fixed contact so as to be pressed by the pressing member.

  As described above, the contact plate of the present invention includes a skirt portion that rises at a predetermined angle, and a reversible dome portion that is continuous via a connection portion with the skirt portion, and the connection portion between the skirt portion and the dome portion. The first and second hinge portions that are bent inward in stages are formed, and the center of the dome portion is determined by the elastic force generated in the first and second hinge portions when the dome peripheral edge is pressed. Since it is reversed to the position, the first and second hinges connecting the dome and the skirt can efficiently transmit the pressing force to the center of the dome, and the center of the dome is predetermined. Since it can be reversed to the position, the pressing range in which a desired click feeling can be obtained can be extended to the peripheral edge of the dome part provided with each hinge part.

In addition, since the first and second hinge portions formed at the connection portion between the skirt portion and the dome portion are formed at bending angles of less than 180 degrees, the arch effect by each hinge portion works strongly. The elastic force generated in the first and second hinge portions can be efficiently transmitted to the dome portion.
Further, the first hinge part is connected to the skirt part, the second hinge part is connected to the dome part, and the connection position of the second hinge part is the connection position of the first hinge part when the dome part is repeatedly inverted. Since the arch effect by the second hinge portion works strongly when pressing the dome peripheral edge, the pressing force can be efficiently transmitted to the center of the dome, and the dome is inverted. be able to.

Moreover, while sticking the outer surface of the contact plate which consists of either of the 1st thru | or 3rd solution to the adhesive layer of the insulating sheet which has an adhesive layer in the back surface, the back surface of the insulating sheet was used as the adhesive attachment part. The contact plate can be easily incorporated into the switch.
Further, since the contact plate comprising the fourth solution means is adhered to the circuit board on which the fixed contact is disposed by the adhesive layer of the insulating sheet so as to face the fixed contact, at the time of operating the push button of the switch, It is possible to provide a sheet type switch that can provide a wide pressing range in which a desired click feeling can be obtained.

  Further, the contact plate comprising any one of the first to third solving means, a housing having a storage portion, and a fixed contact is disposed on the inner bottom surface of the storage portion, and the housing portion are fitted to be movable up and down. Since the contact plate is disposed so as to face the fixed contact so that it can be pressed by the pressing member, the pressing range in which a desired click feeling can be obtained when operating the push button of the switch is widened. A push button type switch that can be provided can be provided.

  1 to 8 show an embodiment of a contact plate and a switch using the contact plate according to the present invention. 1 is a sectional view of a contact plate of the present invention, FIG. 2 is an exploded perspective view showing a sheet type switch using the contact plate of the present invention, and FIG. 3 shows a sheet type switch using the contact plate of the present invention. FIG. 4 is a cross-sectional view showing a push button type switch using the contact plate of the present invention, FIG. 5 is an explanatory diagram for explaining the operation during the pressing operation of the dome portion peripheral portion of the contact plate of the present invention, FIG. 6 is an explanatory view showing the relationship between the operating force of the contact plate and the amount of pushing, FIG. 7 is an explanatory view explaining the operation during the pressing operation of a different dome peripheral portion of the contact plate of the present invention, and FIG. It is explanatory drawing which shows the relationship between the operating force of a board, and the pushing amount.

  In FIG. 1, the contact plate 1 is a thin metal plate formed in a disc shape. The contact plate 1 is formed of a skirt portion 1a that rises from the outer peripheral portion toward the center at a predetermined angle, and a dome portion 1b that can be repeatedly reversed, and the skirt portion 1a and the dome portion. The part 1b is connected in multiple stages via a first hinge part 1c bent inward in stages and a second hinge part 1d.

  In this case, for example, the rising angle of the skirt portion 1a is formed at about 30 degrees, and the first hinge portion 1c connected to the skirt portion 1a bends inward at about 157.5 degrees. Further, the second hinge portion 1d connected to the dome portion 1b is bent inward at about 174.5 degrees. Thus, each of the first and second hinge portions 1c and 1d is formed at a bending angle of less than 180 degrees, and the skirt portion 1a and the dome portion 1b are the first and second hinge portions 1c. It is formed by being bent and connected in stages by 1d.

  As described above, since the first and second hinge portions 1c and 1d formed at the connection portion between the skirt portion 1a and the dome portion 1b are formed at bending angles of less than 180 degrees, Since the arch effect works strongly, the elastic force generated in the first and second hinge portions 1c and 1d can be efficiently transmitted to the dome portion 1b.

  The skirt portion 1a is connected to a first hinge portion 1c, and the dome portion 1b is connected to a second hinge portion 1d. The connecting position of the hinge portion 1d is formed to be higher than the connecting position of the first hinge portion 1c. For this reason, even when pressed as shown in FIG. 7, the dome portion 1 b can be repeatedly reversed before the presser 11 hits the second hinge portion 1 c.

2 and 3 show a structure of a sheet type switch using the contact plate 1.
In the figure, the circuit board 2 is formed of a laminated plate such as phenol resin, and a plurality of central fixed contacts 3a and peripheral fixed contacts 3b made of conductive copper foil or the like are disposed on the surface of the circuit board 2. ing.

The insulating sheet 4 is formed of a film-like insulating material, and an adhesive layer is formed on one surface on the lower surface side, and the upper surface side of the dome portion 1b of the contact plate 1 is attached to the adhesive layer, and the insulating sheet 4 A plurality of contact plates 1 are integrated.
Then, the insulating sheet 4 to which the contact plate 1 is attached is attached on the circuit board 2 so that the contact plate 1 faces the central fixed contact 3a and the peripheral fixed contact 3b. A switch is formed.

  At this time, the contact plate 1 faces the contact portion 1e on the inner surface side of the top of the dome portion 1b in a state of being separated from the central fixed contact 3a, and the outer peripheral end 1f of the skirt portion 1a is connected to the peripheral fixed contact 3b. Always in contact.

  The operation plate 5 is formed of a plate-shaped insulating material, and includes a thin plate-like substrate portion 5a and a plurality of operation keys 5b arranged in the vertical and horizontal directions of the substrate portion 5a. Further, a pressing portion 5c protrudes from the lower surface side of the operation key 5b. The operation plate 5 is disposed on the upper surface side of the insulating sheet 4, and the pressing portion 5 c is disposed on the upper surface side of the top portion of the dome portion 1 b of the contact plate 1.

  Thus, while sticking the outer surface of the said contact plate 1 to the adhesion layer of the said insulating sheet 4 which has an adhesion layer in a back surface, as an attachment part which can adhere | attach the back surface of the said insulation sheet 4 on the said circuit board 2 Therefore, since the sheet-type switch can be formed by sticking the contact plate 1 on the circuit board 2, it can be easily incorporated into the switch.

  Further, the contact plate 1 is attached to the circuit board 2 on which the central fixed contact 3a and the peripheral fixed contact 3b are disposed by the adhesive layer of the insulating sheet 4 so as to face the fixed contacts 3a and 3b. As a result, a sheet-type switch that can provide a wide pressing range in which a desired click feeling can be obtained during the operation of the push button of the switch can be provided.

  In the above-described embodiment, a structure in which a plurality of contact plates 1 are attached to a film-like insulating sheet 4 and integrated into a sheet shape is attached to the circuit board 2. A plurality of layers each having a single contact plate 1 bonded to each insulating sheet (not shown) on which layers are formed may be formed and individually bonded onto the circuit board 2. .

FIG. 4 shows the structure of a push button type switch based on an insulating resin housing using the contact plate 1.
In the figure, the housing 6 is formed in a box shape having an opening on the top surface by an insulating material such as synthetic resin. A central fixed contact 7a and a peripheral fixed contact 7b made of a conductive metal plate are disposed on the inner surface of the storage portion 6a formed in the opening of the housing 6, respectively.

  On the central fixed contact 7a and the peripheral fixed contact 7b, the contact plate 1 is disposed so as to oppose, and in this case, the dome portion 1b is opposed to the central fixed contact 7a, The outer peripheral end 1f of the skirt 1a is always in contact with the peripheral fixed contact 7b.

  The stem 8 which is a pressing member is also formed of an insulating material such as synthetic resin, and presses the pressing operation portion 8a protruding from the opening of the housing 6, the flange portion 8b, and the dome portion 1b of the contact plate 1. An operating projection 8c is provided.

  The cover 9 is formed of a flat metal plate or the like, covers the opening of the housing 6, and prevents the stem 8 from popping out by the flange portion 8 b of the stem 8 coming into contact with the inner surface of the cover 9.

  A pushbutton based on an insulating resin housing by inserting the contact plate 1 and the stem 8 into the opening of the housing 6, covering the opening of the housing 6 with the cover 9, and fixing the cover 6 by caulking or the like. A type of switch is formed.

  As described above, the contact plate 1 is stored in the housing 6 in which the central fixed contact 7a and the peripheral fixed contact 7b are arranged on the inner bottom surface of the storage portion 6a, and is inserted into the storage portion 6a so as to be movable up and down. Since the stem 8 is disposed so as to be opposed to the fixed contacts 7a and 7b so as to be pressed by the stem 8, it is possible to provide a wide pressing range in which a desired click feeling can be obtained when the push button of the switch is operated. A type of switch can be provided.

  FIG. 5 is an explanatory diagram for explaining the operation during the pressing operation of the peripheral edge of the dome portion 1b of the contact plate 1 of the present invention, and FIG. 6 is an explanatory diagram showing the relationship between the operating force of the contact plate 1 and the pushing amount. is there.

  5A shows a state before the contact plate 1 is pressed, and FIG. 5B shows a pressing element 10 (the pressing portion 5c provided on the lower surface side of the operation key 5b of the operating body 5 or the FIG. 5C shows a state immediately before the dome portion 1b is reversed while the dome portion 1b peripheral portion of the contact plate 1 is being pressed by the stem 8 operating protrusion 8c). FIG. 1 shows a state in which the dome portion 1b of 1 is inverted.

  In FIG. 5B, the pressing element 10 presses on the second hinge part 1d connecting the skirt part 1a and the dome part 1b of the contact plate 1, and the second hinge part is accompanied by this pressing. Due to the arch effect of 1d, the pressing force is efficiently transmitted to the central portion of the dome portion 1b. When the contact plate 1 is further pressed, as shown in FIG. 5 (c), the pressing force is transmitted to the central portion of the dome portion 1b as the second hinge portion 1d is lowered, and the center of the dome portion 1b. The part is inverted downward.

In FIG. 6, the relationship between the operating force F (vertical axis) and the pushing amount L (horizontal axis) when the contact plate 1 is reversed is shown by a curve.
In this case, in the state before pressing the contact plate 1 shown in FIG. 5 (a), the operating force Fa and the pushing amount La are both zero, and in the state shown in FIG. 5 (b), the operating force Fb is a contact point when pressed. The maximum value of the operating force applied until the dome portion 1b of the plate 1 is reversed is shown, and this point is the reversal point indicated by the pushing amount Lb.

  After the reversal point, the contact plate 1 is reversed downward by the reversing force of the dome portion 1b itself, and the reversing force decreases the operating force and reaches the position of the pushing amount Lc by the operating force Fc. This state indicates a state where the reversal operation of the contact plate 1 is completed, that is, a value where the contact plate 1 is reversed and the operating force F is reduced to a minimum, and the switch is turned on (the contact plate 1 and the center fixed state). The contact 3a or 7a is in contact).

  FIG. 7 is an explanatory view for explaining the operation at the time of pressing operation of the peripheral portion of a different dome portion 1b of the contact plate 1 of the present invention, and FIG. 8 is an explanatory view showing the relationship between the operating force of the contact plate 1 and the pushing amount. FIG.

  7A shows the state before the contact plate 1 is pressed, and FIG. 7B shows the presser 11 (the pressing portion 5c provided on the lower surface side of the operation key 5b of the operating body 5 or the stem. FIG. 7C shows a state immediately before the dome portion 1b is reversed while the peripheral edge of the dome portion 1b of the contact plate 1 is being pressed by the operation protrusion 8c of FIG. Indicates a reversed state.

  In FIG.7 (b), the presser 11 is pressing the substantially intermediate position of the 1st hinge part 1c which has connected the skirt part 1a of the contact plate 1, and the dome part 1b, and the 2nd hinge part 1d. . Even in this case, the pressing force is efficiently transmitted to the central portion of the dome portion 1b by the arch effect of the second hinge portion 1d along with the pressing. When the contact plate 1 is further pressed, as shown in FIG. 7 (c), the pressing force is transmitted to the central portion of the dome portion 1b as the second hinge portion 1d is lowered, and the center of the dome portion 1b. The part is inverted downward.

  In this case, the second hinge portion 1d is formed at a position closer to the dome portion 1b than the first hinge portion 1c, and is formed at a higher position above the first hinge portion 1c. Thus, the dome portion 1b can be reversed by the arch effect of the second hinge portion 1d before the pressing element 11 hits the first hinge portion 1c.

In FIG. 8, the relationship between the operating force F (vertical axis) and the pushing amount L (horizontal axis) when the contact plate 1 is reversed is shown by a curve.
Also in this case, in the state shown in FIG. 7B, the operating force Fb indicates the maximum value of the operating force applied until the dome 1b of the contact plate 1 is reversed at the time of pressing, and this point is the pushing amount Lb. It is the reversal point indicated by.

  After the reversal point, the contact plate 1 is reversed downward by the reversing force of the dome portion 1b itself, and the reversing force decreases the operating force and reaches the position of the pushing amount Lc by the operating force Fc. This state indicates a state where the reversal operation of the contact plate 1 is completed, that is, a value where the contact plate 1 is reversed and the operating force F is reduced to a minimum, and the switch is turned on (the contact plate 1 and the center fixed state). The contact 3a or 7a is in contact).

  FIG. 9 shows a configuration of a contact plate 12 as a comparative example with respect to the contact plate 1 of the present invention. In the figure, the contact plate 12 is partially different in configuration of the second hinge portion 12d, and the second hinge portion 12d is formed by bending outward with respect to the first hinge portion 12c. The bending angle is, for example, about 181 degrees.

  That is, in the contact plate 1 of the present invention, the first and second hinge portions 1c and 1d are each formed at a bending angle of less than 180 degrees, and the skirt portion 1a and the dome portion 1b Whereas the second hinge portions 1c and 1d are formed to be bent and connected inward in stages, the contact plate 12 of the comparative example has a first hinge portion 12c of about 156 degrees, for example. The second hinge portion 12d is formed to be bent outward at, for example, about 181 degrees, although it is formed to be bent inward at a bending angle of less than 180 degrees.

  Thus, the contact plate 1 according to the present invention, when the peripheral portion of the dome portion 1b is pressed, the pressing force is applied to the center of the dome portion 1b by the arch effect of the second hinge portion 1d bent inward. However, the contact plate 12 of the comparative example is not able to exhibit the arch effect because the second hinge portion 12d is bent outward, and the pressing force can be transmitted to the center of the dome portion 12b. Therefore, it is difficult to efficiently reverse the dome portion 12b.

10 to 12 are explanatory diagrams showing the click rate (%) of the contact plate, FIG. 10 is the click rate (%) of the contact plate 1 of the present invention, and FIG. 11 is the click rate (%) of the contact plate 12 of the comparative example. 12) and FIG. 12 show the click rate (%) of the conventional contact plate (dome-shaped movable contact shown in FIG. 14) 60, respectively.
The click rate (%) is represented by a curve showing the relationship between the actuation force F and the push-in amount L shown in FIG. 6 or FIG. 8, and is represented by the click rate (%) = (Fb−Fc) / Fb × 100. It is. In this case, Fb represents the maximum value of the operating force applied until each contact plate is reversed, and Fc represents the value at which each contact plate is reversed and the operating force is reduced to the minimum.
In general, a good click rate (%) of the contact plate is preferably 30% or more.

As a measuring method of this click rate (%), the center of the dome portion of each contact plate (0 mm) is centered (0 mm), and 7 × 7 = 49 points at a pitch of 0.2 mm in the left-right-up-down direction (XY direction). Each point was set, and at each point, measurement was performed by aligning the centers of cylindrical measuring elements having a diameter of 1.5 mm and pressing in the vertical direction. In this case, the outer diameter of each contact plate was about 4 mm, and the peripheral edge diameter of the dome was about 2.5 to 3.22 mm.
The shape measuring instrument used in this case was a surface shape measuring system “LMS-3D SYSTEM Ver. 3.6” manufactured by Sigma Koki Co., Ltd.

  As a result, as shown in FIG. 12, in the conventional contact plate (dome-shaped movable contact) 60, the click rate is as good as 40-50% in the vicinity of 0.2 mm from the center of the dome to the left-right direction. However, the click rate is 30 to 40% at a position 0.2 to 0.4 mm away from the dome center in the horizontal and vertical directions, and the click rate is further 0.4 to 0.6 mm at a position away from 0.4 to 0.6 mm. It is 20 to 30%, which is a result of dividing 30% or more, which is a good click rate.

  Further, as shown in FIG. 11, in the contact plate 12 of the comparative example, the click rate is as good as 50 to 60% in the vicinity of 0.2 mm from the center of the dome portion in the left-right-up / down direction. The click rate is 40 to 50% at a position 0.2 to 0.4 mm away from the center in the horizontal and vertical directions, and the click rate is 20 to 40% at a position 0.4 to 0.6 mm away from the center. In this case as well, the result is that it is 30% or more, which is a good click rate.

  Thus, with the conventional contact plate (dome-shaped movable contact) 60 and the contact plate 12 of the comparative example, a good click rate of 30% or more is obtained in the vicinity of 0.4 mm from the center of the dome to the left-right-up-down direction. However, if the distance is further than that, the click rate is less than 30% even inside the dome, and a good click feeling cannot be obtained.

  In addition, the curve of the click rate curve drops rapidly as it goes from the center of the dome part to the peripheral part, and the difference in the value of the click rate between the points away from the dome part center in the left-right-up / down direction increases. Yes. For this reason, when the peripheral part of a dome part is pressed, a dome part may not reverse and it cannot obtain a desired click feeling.

On the other hand, in the contact plate 1 of the present invention, as shown in FIG. 10, the click rate shows a good value of 30 to 60% in the range of 0.6 mm from the center of the dome to the left and right direction. In all points, a good click rate of 30% or more is shown. In addition, the curve of the click rate curve gradually changes from the center of the dome toward the periphery, and the difference in the click rate between the points away from the dome center in the left-right-up / down direction becomes minute. Yes.
For this reason, the contact plate 1 of the present invention can obtain a good click rate regardless of where the dome part center and the peripheral part are pressed, and the dome part can be reliably reversed, so that a desired click feeling can be obtained. It is possible.

  According to the embodiment described above, the skirt portion 1a and the dome portion 1b of the contact plate 1 having the skirt portion 1a rising at a predetermined angle and the invertible dome portion 1b connected via the connecting portion with the skirt portion 1a. The first and second hinge portions 1c and 1d that are bent inward in stages are formed at the connection portion with the first and second hinge portions 1c when the peripheral edge of the dome portion 1b is pressed. Since the center of the dome portion 1b is reversed to a predetermined position by the elastic force generated in 1d, the first and second hinges connecting the dome portion 1b and the skirt portion 1a. The portions 1c and 1d can efficiently transmit the pressing force to the center of the dome portion 1b, and the center of the dome portion 1b can be inverted to a predetermined position, so that a desired click feeling can be obtained. Range, the first and second hinge portions 1c, it is possible to widen up to the periphery of the dome portion 1b provided 1d.

It is sectional drawing which shows the contact plate which is one Example of this invention. It is a disassembled perspective view which shows the sheet type switch which uses the contact plate of this invention. It is principal part sectional drawing which shows the sheet-type switch using the contact plate of this invention. It is sectional drawing which shows the pushbutton type switch using the contact plate of this invention. It is explanatory drawing explaining the operation | movement at the time of pressing operation of the dome part peripheral part of the contact plate of this invention. It is explanatory drawing which shows the relationship between the operating force of the contact plate of this invention, and the pushing amount. It is explanatory drawing explaining the operation | movement at the time of pressing operation of the dome part peripheral part which differs further of the contact plate of this invention. It is explanatory drawing which shows the relationship between the operating force of the contact plate of this invention, and the pushing amount. It is sectional drawing which shows the structure of the contact plate as a comparative example with respect to the contact plate of this invention. It is explanatory drawing which shows the click rate (%) of the contact plate of this invention. It is explanatory drawing which shows the click rate (%) of the contact plate of the comparative example of this invention. It is explanatory drawing which shows the click rate (%) of the conventional movable contact. It is sectional drawing which shows the conventional pushbutton switch. It is the perspective view and sectional drawing which show the movable contact used for the conventional pushbutton switch. It is explanatory drawing explaining the operation | movement at the time of pressing operation of the dome part peripheral part of the conventional movable contact.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1: Contact board 1a: Skirt part 1b: Dome part 1c: 1st hinge part 1d: 2nd hinge part 1e: Contact part 1f: Peripheral edge part 2: Circuit board 3a: Center fixed contact 3b: Peripheral fixed contact 4 : Insulating sheet 5: Operation plate 5a: Substrate part 5b: Operation key 5c: Pressing part 6: Housing 6a: Storage part 7a: Center fixed contact 7b: Peripheral fixed contact 8: Stem (pressing member)
8a: Press operation part 8b: Eaves part 8c: Actuation protrusion 9: Cover 10: Presser 11: Presser 12: Contact plate 12a: Skirt part 12b: Dome part 12c: First hinge part 12d: Second hinge Part

Claims (6)

  A skirt portion that rises at a predetermined angle and a reversible dome portion that is continuous through a connection portion with the skirt portion, and bends inward in a stepwise manner at the connection portion between the skirt portion and the dome portion. First and second hinge portions are formed, and when the peripheral edge of the dome portion is pressed, the center of the dome portion is reversed to a predetermined position by the elastic force generated in the first and second hinge portions. A contact plate characterized by that.   2. The contact plate according to claim 1, wherein the first and second hinge portions formed at a connection portion between the skirt portion and the dome portion are each formed at a bending angle of less than 180 degrees.   The first hinge portion is connected to the skirt portion, the second hinge portion is connected to the dome portion, and when the dome portion is repeatedly inverted, the connection position of the second hinge portion is the first hinge portion. The contact plate according to claim 1, wherein the contact plate is formed to be higher than a connection position of the hinge portion.   A contact point, wherein the outer surface of the contact plate according to any one of claims 1 to 3 is adhered to an adhesive layer of an insulating sheet having an adhesive layer on the back surface, and the back surface of the insulating sheet is used as an adhesive mounting portion. Board.   A switch comprising: a contact plate comprising the insulating sheet adhered to a circuit board on which a fixed contact is disposed so as to face the fixed contact. A contact plate comprising any one of claims 1 to 3, a housing having a storage portion, a fixed contact disposed on an inner bottom surface of the storage portion, and a pressing member fitted in the storage portion so as to be movable up and down. And the contact plate is disposed to face the fixed contact so as to be pressed by the pressing member.

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