JP4529711B2 - Switch device - Google Patents

Description

  The present invention relates to a switch device. The switch device according to the present invention is applied to a switch device having a seesaw structure.

  Conventionally, there has been a switch device having a seesaw structure. FIG. 4 is a cross-sectional view showing a schematic configuration of a switch device in the prior art.

  The switch device 100 in the prior art includes a substrate 10, a detection switch 20, a seesaw rod 30, a fulcrum 30a, a push rod 40, a case 50, and the like. These substrate 10, detection switch 20, seesaw rod 30, fulcrum 30 a, and push rod 40 are accommodated in a case 50.

  The substrate 10 includes a wiring electrically connected to the fixed contact 20a of the detection switch 20, a connector for transmitting a detection signal (on / off signal) from the detection switch 20 to the outside, and the like. The detection switch 20 includes a fixed contact 20a and a movable contact 20b. When the movable contact 20b is pressed by the seesaw rod 30, the fixed contact 20a and the movable contact 20b are electrically connected. Moreover, as for the detection switch 20, the movable contact 20b leaves | separates from the fixed contact 20a as the press from the seesaw rod 30 with respect to the movable contact 20b reduces.

  The seesaw rod 30 is supported by a fulcrum 30a so that the seesaw can be operated. The seesaw rod 30 performs a seesaw operation by being pressed by the push rod 40. The push rod 40 includes a force point portion 40c that is a contact point with the seesaw rod 30, and the seesaw rod 30 is operated as a seesaw by an external force from the opposite direction (the lower side in the drawing) of the force point portion 40c.

  However, since the switch device 100 according to the related art is composed of a plurality of parts, variations may occur between the parts when the parts are assembled. Depending on this variation and the detection range of the detection switch 20, there may be a problem that the detection switch 20 does not turn on when it should be turned on, or does not turn off when the detection switch 20 should turn off. .

  In order to ensure that the switching device 100 is turned on without being affected by variations, it is desirable to position the power point as far as possible from the fulcrum. Conversely, in order to ensure that the switching device 100 is turned off, it is desirable to place the force point as close to the fulcrum as possible or to increase the amount of movement of the push rod 40 as much as possible.

  However, since the ratio of the distance from the fulcrum 30a to the force point portion 40c and the distance from the fulcrum 30a to the movable electrode 20b in the seesaw rod 30 is fixed at X1 vs. Y, the switch device 100 in the prior art is affected by variations. It has been difficult to reliably turn on or off the switch device 100 (detection switch 20) without any problems.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a switch device that can improve the on / off switching accuracy without being affected by assembly variations.

In order to achieve the above object, a switch device according to claim 1 is provided with a seesaw rod capable of seesaw operation with a fulcrum as an axis, detection means for detecting contact / separation of one end of the seesaw rod, and detection in the seesaw rod. Pushing the end opposite to the side in contact with the means, provided on at least one of the seesaw rod and the push rod, which is operated by an external force applied from the outside to operate the seesaw rod. A plurality of force point portions where the force point with respect to the seesaw rod is switched in the fulcrum direction as the seesaw rod performs a seesaw operation by pressing the push rod ,
When the seesaw rod is not pressed by the push rod, the seesaw rod and the push rod contact only at the far end in the direction of the fulcrum. emphasis by the push rod are in contact only at closer to the fulcrum direction and is characterized in Rukoto switch to pivot direction.

  Thus, as the seesaw rod moves to the fulcrum as the seesaw operation is performed by pressing the push rod, the force point closes to the fulcrum as the seesaw moves. Can do. Therefore, even if the initial position of the push rod with respect to the seesaw rod varies depending on the component crossing and the assembling accuracy, the force point is away from the fulcrum, so that the influence on the displacement of the seesaw rod can be suppressed. Further, when the push rod is pressed and moved, the power point approaches the fulcrum, so that the ratio of the movement amount of the seesaw rod to the movement amount of the push rod can be increased. As a result, it is possible to improve the on / off switching accuracy without being affected by assembly variation.

  In addition, as shown in claim 2 and claim 3, the force point portion may be formed of an inclined surface whose height decreases as it goes in the fulcrum direction, or the height decreases as it goes in the fulcrum direction. You may make it consist of a some protrusion.

  According to a fourth aspect of the present invention, the push rod is provided with a pressing portion that presses the seesaw rod so that the detection means detects contact in a state where an external force is not applied to the push rod. When the external force from the outside is not applied, the switch unit can be reliably turned on. Moreover, as shown in claim 5, the seesaw rod can be pressed against the pressing portion by a spring member.

  According to a sixth aspect of the present invention, the switch device detects the opening / closing of an open / close type operation panel mounted on the vehicle, and is mounted on either the vehicle or the operation panel. is there.

  In this way, by being mounted on either the vehicle or the operation panel, the present invention can be applied to a switch device that detects opening and closing of an openable operation panel mounted on the vehicle.

  Further, when detecting opening / closing of an open / close type operation panel mounted on the vehicle, as shown in claim 7, the detection means detects contact when the operation panel is in an open state. The push rod is operated by an external force from the operation panel or a predetermined part of the vehicle when the operation panel is closed, and the seesaw rod is operated as a seesaw, and the detecting means detects opening and closing of the operation panel by detecting separation. be able to.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
First, the first embodiment will be described. FIG. 1 is a cross-sectional view showing a schematic configuration of a switch device according to a first embodiment of the present invention, (a) is a cross-sectional view showing a case where a detection switch is in an ON state, and (b) is a detection. It is sectional drawing which shows the case where a switch is an OFF state. FIG. 2 is an image diagram in which the switch device according to the first embodiment of the present invention is applied to an open / close-type operation panel. FIG. 2 (a) is an image diagram illustrating a case where the operation panel is in use. FIG. 4 is an image diagram showing a case where an operation panel is in a stored state.

  As shown in FIG. 1, the switch device 100 in the present embodiment includes a substrate 10, a detection switch 20, a seesaw rod 30, a fulcrum 30a, a push rod 40, a case 50, and the like. These substrate 10, detection switch 20, seesaw rod 30, fulcrum 30 a, and push rod 40 are accommodated in a case 50.

  The substrate 10 includes wiring electrically connected to the fixed contact 20a of the detection switch 20 (detection means), a connector for transmitting a detection signal (on / off signal) from the detection switch 20 to the outside, and the like.

  The detection switch 20 includes a fixed contact 20a and a movable contact 20b. The fixed contact 20a and the movable contact 20b are separated from each other by an elastic member such as a spring. When an external force is applied to the movable contact 20b, the fixed contact 20a and the movable contact 20b are electrically connected. That is, the detection switch 20 is in an ON state (hereinafter, initial stage) in which the fixed contact 20a and the movable contact 20b are electrically connected as shown in FIG. 1A when the movable contact 20b is pressed by the seesaw rod 30. (Also referred to as a state). Further, as shown in FIG. 1 (b), the detection switch 20 is in an off state (hereinafter also referred to as an input state) in which the movable contact 20b moves away from the fixed contact 20a as the pressure from the seesaw rod 30 on the movable contact 20b decreases. Called).

  The seesaw rod 30 is supported by a fulcrum 30a so that the seesaw can be operated. The seesaw rod 30 performs a seesaw operation by being pressed by the push rod 40. In the state where there is almost no external force applied by the push rod 40, the seesaw rod 30 is supported by a first force point portion 40a, which will be described later, and the other end portion of the movable contact 20b. Press. As described above, when the movable contact 20b is pressed by the seesaw rod 30, the fixed contact 20a and the movable contact 20b are electrically connected as described above.

  The push rod 40 includes a first force point portion 40a and a second force point portion 40b which are force points with the seesaw rod 30, and an external force from the opposite direction (the lower side of the drawing) of the first force point portion 40a and the second force point portion 40b. The seesaw rod 30 is operated as a seesaw. The first force point portion 40a and the second force point portion 40b provided on the push rod 40 have different heights. The first force point portion 40a which is a force point portion corresponding to the end of the seesaw rod 30 is formed higher than the second force point portion 40b provided on the fulcrum 30a side with respect to the first force point portion 40a.

  This is because the force point of the push rod 40 against the seesaw rod 30 changes from the initial state shown in FIG. 1A to the input state shown in FIG. This is for switching from the portion 40a to the second force point portion 40b. Conversely, as the detection switch 20 (switch device 100) changes from the input state shown in FIG. 1 (b) to the initial state shown in FIG. 1 (a), the force point of the push rod 40 against the seesaw rod 30 becomes the second force point. This is for switching from the portion 40b to the first force point portion 40a.

  Here, the operation of the switch device 100 of the present embodiment will be described in more detail. First, the initial state will be described. In the initial state, almost no external force is applied to the push rod 40, or no external force is applied to the seesaw rod 30 in the input state as shown in FIG. is there. Therefore, almost no external force is applied to the seesaw rod 30 from the push rod 40.

  The force point of the push rod 40 with respect to the seesaw rod 30 in this initial state is a force point portion 40 a disposed at a position corresponding to the end of the seesaw rod 30. Thus, by setting the force point of the push rod 40 with respect to the seesaw rod 30 as the force point portion 40a, even if the initial position of the push rod 40 with respect to the seesaw rod 30 varies due to the assembly variation of each component of the switch device 100, the force point portion. Since 40a is away from the fulcrum 30a, the influence on the displacement of the seesaw rod 30 can be kept small. Therefore, it becomes easy to press the movable contact 20b by the seesaw rod 30, and the detection switch 20 (switch device 100) is easily turned on.

  Next, a case where the initial state changes to the input state will be described. In the initial state as described above, when an external force is applied to the push rod 40 from the direction opposite to the first force point portion 40a and the second force point portion 40b, the push rod 40 is moved to the seesaw rod by the first force point portion 40a for a predetermined period. 30 is pressed. The seesaw rod 30 pressed by the first force point portion 40a performs a seesaw operation to move away from the movable contact 20b.

  Then, when a predetermined period elapses after the seesaw rod 30 starts to be pressed by the push rod 40 (first force point portion 40a), that is, when the push rod 40 and the seesaw rod 30 move by a predetermined distance, the push rod 40 is moved relative to the seesaw rod 30. The force points are the first force point portion 40a and the second force point portion 40b.

  Further, the force point of the push rod 40 with respect to the seesaw rod 30 becomes the first force point portion 40a and the second force point portion 40b, and then the seesaw rod 30 is pressed by the push rod 40 (first force point portion 40a, second force point portion 40b). Then, the force point of the push rod 40 with respect to the seesaw rod 30 is switched to the second force point portion 40b disposed at a position close to the fulcrum 30a of the seesaw rod 30.

  In the first force point portion 40a and the second force point portion 40b, the movement amount of the seesaw rod 30 with respect to the movement amount of the push rod 40 also changes. That is, as shown in FIG. 1A, the ratio of the distance from the fulcrum 30a to the first force point part 40a and the distance from the fulcrum 30a to the movable electrode 20b in the seesaw rod 30 by switching the power point X1 to Y The ratio of the distance from the fulcrum 30a to the second force point portion 40b and the distance from the fulcrum 30a to the movable electrode 20b in the seesaw rod 30 changes to X2 to Y. Therefore, the amount of movement of the seesaw rod 30 with respect to the amount of movement of the push rod 40 increases when the power point is the second force point part 40b, compared to when the power point is the first force point part 40a.

  In this way, as the seesaw rod 30 performs a seesaw operation by pressing by the push rod 40, the force point of the push rod 40 with respect to the seesaw rod 30 is switched in the direction of the fulcrum 30a without increasing the amount of movement of the push rod 40. The amount of movement of the seesaw rod 30 can be increased. Therefore, the detection switch 20 (the fixed contact 20a and the movable contact 20b) can be easily turned off without being affected by the variation in assembly of the constituent members of the switch device 100.

  Such a switch device 100 can be applied as a switch device that detects opening and closing of an openable operation panel 200 mounted on a vehicle as shown in FIG. The operation panel 200 includes a cover 200a, an operation unit 200b, the switch device 100, and the like. A rod receiver (not shown) that receives the push rod 40 of the switch device 100 is provided on the vehicle side.

  FIG. 2A is an image diagram when the operation unit 200b is in an open state, that is, the operation unit 200b is in a use state. In this use state, in the switch device 100, the force point of the push rod 40 with respect to the seesaw rod 30 as shown in FIG. 1A is the first force point portion 40a, and almost no external force is applied to the push rod 40. Or the seesaw rod 30 is not applied with an external force as shown in FIG. 1B, and the fixed contact 20a and the movable contact 20b of the detection switch 20 are electrically connected. Is the initial state.

  FIG. 2B is an image diagram when the operation unit 200b is in a closed state, that is, the operation unit 200b is in a stored state. In this stored state, in the switch device 100, the force point of the push rod 40 with respect to the seesaw rod 30 as shown in FIG. 1B is the second force point portion 40b, and the detection switch 20 includes the movable contact 20b, the seesaw rod 30, Is an input state in which is completely separated and turned off.

  In such a storage state from the use state, the push rod 40 of the switch device 100 comes into contact with the rod receiver when the operation unit 200b is closed, and the push rod 40 is applied to the force point portion (first force point portion 40a, first force point portion). It is pressed from the opposite direction of the two force points 40b).

  By applying the switch device 100 to the operation panel 200 in this way, when the operation panel 200 is in the retracted state when the operation unit 200b is closed from the use state, the switch device 100 changes from the initial state to the input state, and the detection switch Since 20 is switched from on to off, the opening / closing of the operation unit 200b can be detected.

  Further, as the push rod 40 moves in accordance with the closing operation of the operation portion 200b, the power point is switched from the first force point portion 40a to the second force point portion 40b, and even if the movement of the push rod 40 is reduced, the detection switch Since it becomes easy to turn off 20, the space at the time of mounting the operation panel 200 in a vehicle can be made small.

  In the present embodiment, the switch device 100 is provided on the operation panel 200 side. However, the present invention is not limited to this. The switch device 100 may be provided on the vehicle side.

  In the present embodiment, the switch device 100 is applied as a switch for detecting the opening / closing of the open / close operation panel 200 mounted on the vehicle, but the present invention is not limited to this. Any device that detects a state by pressing can be applied.

(Second Embodiment)
Next, a second embodiment of the present invention will be described. FIG. 3 is a cross-sectional view showing a schematic configuration of the switch device according to the second embodiment of the present invention, (a) is a cross-sectional view showing a case where the detection switch is in an ON state, and (b) is a detection. It is sectional drawing which shows the case where a switch is an OFF state.

  Since the switch device 100 according to the second embodiment is often in common with that according to the first embodiment described above, a detailed description of common portions will be omitted, and different portions will be described mainly. The second embodiment differs from the first embodiment described above in that a force point portion (first force point portion 40a, second force point portion 40b) is provided on the seesaw rod 30, and the seesaw rod 30 is pressed. The spring 30b is provided.

  As shown in FIG. 2, the switch device 100 in the present embodiment includes a substrate 10, a detection switch 20, a seesaw rod 30, a fulcrum 30a, a spring 30b, a push rod 40, a case 50, and the like. These substrate 10, detection switch 20, seesaw rod 30, fulcrum 30 a, and push rod 40 are accommodated in a case 50.

  The seesaw rod 30 includes a first force point part 40a and a second force point part 40b, and is supported by the fulcrum 30a so that the seesaw can be operated. The seesaw rod 30 performs a seesaw operation by being pressed by the push rod 40. Further, the seesaw rod 30 is pressed by the spring 30b and presses the movable contact 20b of the detection switch 20 in a state where there is almost no external force applied by the push rod 40 as shown in FIG. By pressing the seesaw rod 40 with the spring 30b in this way, the detection switch 20 can be reliably turned on when the switch device 100 is in the initial state.

  Further, the first force point portion 40a and the second force point portion 40b provided on the seesaw rod 30 have different heights. The first force point portion 40a which is a force point portion corresponding to the end of the seesaw rod 30 is formed higher than the second force point portion 40b provided on the fulcrum 30a side with respect to the first force point portion 40a.

  This is because the force point of the push rod 40 against the seesaw rod 30 changes from the initial state shown in FIG. 3A to the input state shown in FIG. This is for switching from the portion 40a to the second force point portion 40b. Conversely, as the detection switch 20 (switch device 100) changes from the input state shown in FIG. 3B to the initial state shown in FIG. 3A, the force point of the push rod 40 with respect to the seesaw rod 30 is changed to the second force point. This is for switching from the portion 40b to the first force point portion 40a.

  Although the first and second embodiments have been described using the example in which the two force point portions are the first force point portion 40a and the second force point portion 40b, the present invention is not limited to this. is not. The object of the present invention can be achieved by reducing the height of the force point portion from the end of the seesaw rod 30 toward the fulcrum 30a. Therefore, three or more power point portions may be provided. Moreover, it is good also as an inclined surface so that a power point part may be made to go from the edge part of the seesaw rod 30 toward the fulcrum 30a direction, and height may become low. Furthermore, it is good also as a level | step-difference part so that a power point part may go to the fulcrum 30a direction from the edge part of the seesaw rod 30, and may become low.

  In the first and second embodiments, when an external force is applied to the push rod 40 from the opposite direction of the first force point portion 40a and the second force point portion 40b, the seesaw rod 30 is moved from the movable contact 20b. Although the description has been given using the example in which the seesaw operation is performed to move away, the present invention is not limited to this. When an external force is applied to the push rod 40 from the opposite direction of the first force point portion 40a and the second force point portion 40b, the seesaw rod 30 may perform a seesaw operation to press the movable contact 20b.

It is sectional drawing which shows schematic structure of the switch apparatus in the 1st Embodiment of this invention, (a) is sectional drawing which shows the case where a detection switch is an ON state, (b) is a detection switch being an OFF state It is sectional drawing which shows the case where it is. It is an image figure which applied the switch device in a 1st embodiment of the present invention to an opening-and-closing operation panel, (a) is an image figure showing a case where an operation panel is in use, and (b) is an operation panel. It is an image figure which shows the case where it is a storage state. It is sectional drawing which shows schematic structure of the switch apparatus in the 2nd Embodiment of this invention, (a) is sectional drawing which shows the case where a detection switch is an ON state, (b) is a detection switch being an OFF state It is sectional drawing which shows the case where it is. It is sectional drawing which shows schematic structure of the switch apparatus in a prior art.

Explanation of symbols

10 substrate, 20 detection switch, 20a fixed contact, 20b movable contact, 30 seesaw rod, 30a fulcrum, 30b spring, 40 push rod, 40a first force point, 40b second force point, 40c force point, 50 case, 100 switch Device, 200 operation panel, 200a cover, 200b operation unit

Claims (7)

A seesaw rod capable of seesaw operation around a fulcrum;
Detecting means for detecting contact / separation of one end of the seesaw rod;
A push rod that presses an end of the seesaw rod that is opposite to the side in contact with the detection means, and operates by an external force applied from the outside to cause the seesaw rod to perform a seesaw operation;
A plurality of force point portions provided on at least one of the seesaw rod and the push rod, wherein the force point with respect to the seesaw rod switches in the fulcrum direction as the seesaw rod performs a seesaw operation by pressing the push rod. , equipped with a,
When the seesaw rod is not pressed by the push rod, the seesaw rod and the push rod are in contact with each other only in the direction far from the fulcrum, and the seesaw rod is pressed by the push rod. as the work, switch device emphasis by said seesaw rod and the push rod are in contact only at closer to the fulcrum direction and wherein Rukoto switch to the fulcrum direction.   2. The switch device according to claim 1, wherein the force point portion includes an inclined surface having a height that decreases in a direction toward the fulcrum.   2. The switch device according to claim 1, wherein the force point portion includes a plurality of protrusions having a height that decreases toward the fulcrum direction.   4. The press rod according to claim 1, further comprising: a pressing portion that presses the seesaw rod so that the detection unit detects contact in a state where an external force is not applied to the push rod. 5. The switch apparatus in any one.   The switch device according to claim 4, wherein the pressing portion includes a spring member.   The opening / closing operation panel mounted on the vehicle is detected, and is mounted on either the vehicle or the operation panel. Switch device.   When the operation panel is in an open state, the switch unit detects the contact, and the push rod is connected to the operation panel or the vehicle when the operation panel is closed. The switch device according to claim 6, wherein the seesaw rod is operated by an external force by a predetermined part to cause the seesaw rod to perform a seesaw operation, and the detection unit detects separation.

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