JP7314850B2 - Operating device - Google Patents

Description

The present invention relates to an operating device having a push button switch.

As a conventional operating device, one described in Patent Document 1 is known. The operation device (push button switch device) disclosed in Patent Document 1 has a push button switch on a printed circuit board arranged in a case. The printed circuit board is arranged in a direction perpendicular (horizontal) to the operation surface along the vertical direction of the case, and the pressing direction of the push button switch is set to be perpendicular (up and down) to the surface of the printed circuit board.

Further, an operating portion having a U-shaped cross section is provided in the case. Of the three sides of the U-shape in the operation part, the tip of the first side on one end side is fixed to the upper inner surface of the case. Of the three sides, the middle second side is arranged along the operation surface. Of the three sides, the third side, which is the other end, is arranged along the lower inner surface of the case. A first sloped portion is provided at the tip of the third side portion of the operating portion, and a second sloped portion that contacts the first sloped portion is provided integrally with the case on the lower inner surface of the case.

When the second side portion of the operation portion is pushed in the direction perpendicular to the operation surface (horizontal direction), the first slope portion moves along the second slope portion, and the third side portion of the operation portion bends and moves toward the upper side of the case to push (turn on) the push button switch.

Japanese Patent No. 4524618

However, when the operating portion (second side) is pressed, the third side bends and moves upward (deforms), so that, for example, excessive force (stress) acts on the base of the third side on the second side, which leaves a problem of durability. In addition, since the third side moves upward in a flexed manner, the pressing direction becomes oblique with respect to the push button switch, and the direction also changes gradually.

SUMMARY OF THE INVENTION An object of the present invention is to provide an operating device that is excellent in durability and operability in operating a push button switch.

The present invention adopts the following technical means in order to achieve the above objects.

In the first invention, an operation knob (120) provided on an operation surface (113) of a housing (110) and operated for input operation in a first plane perpendicular direction orthogonal to the operation surface;
a substrate (130) arranged in the housing such that the plate surface direction of the operation surface is along the first perpendicular direction;
a push button switch (140) provided on the substrate and having a depression axis direction set in a second perpendicular direction perpendicular to the substrate;
An operation device for turning on and off a push button switch by an input operation to an operation knob,
a tip portion (123) of an operation knob or a first slope portion (124, 112d) provided on a housing;
a sliding member (150) formed separately from the housing and the operation knob, having a second slope portion (151) in contact with the first slope portion, and slidable in the push-down axial direction;
The second slope portion moves along the first slope portion by an input operation to the operation knob, so that the sliding member slides in the direction of the push-down axis to turn on and off the push button switch.
The first slope portion (112d) is characterized by being formed on the housing .
In addition, in the second invention, in contrast to the first invention, the first slope portion (124) is formed at the tip of the operation knob,
The sliding member is positionally regulated with respect to the first perpendicular direction,
The center position (124a) of the region where the first sloped portion of the operation knob contacts the second sloped portion of the sliding member is set so as to straddle the depression shaft of the push button switch and move from the operation front side to the operation back side during input operation.
The third invention is characterized in that the operation knob is of a seesaw type in contrast to the first invention.

According to the present invention, the sliding member (150) is moved in the push-down axis direction to turn on/off the push button switch (140) by the input operation of the operation knob (120), so that the operation knob (120) is not bent, the durability is excellent, and a good operability feeling is obtained.

It should be noted that the reference numerals in parentheses of the above means indicate the corresponding relationship with specific means described in the embodiments to be described later.

It is a sectional view showing the operating device in a 1st embodiment. It is a sectional view showing an operating device in a 2nd embodiment. It is a sectional view showing an operating device in a 3rd embodiment. FIG. 5 is an explanatory diagram for explaining the possibility of rotational behavior of a sliding member; It is a sectional view showing the operation of the operating device in a 4th embodiment. It is a sectional view showing the operating device in a 5th embodiment. It is a side view which shows the operating device in 6th Embodiment (Example 1). It is a side view which shows the operating device in 6th Embodiment (Example 2). FIG. 9 is an arrow view as seen from the IX direction in FIG. 8 ; It is explanatory drawing which shows the movement amount of an operation knob, and the movement amount of a sliding member. FIG. 10 is an explanatory diagram showing the amount of movement of the sliding member according to the shape of the second slope portion;

A plurality of modes for carrying out the present invention will be described below with reference to the drawings. In each form, the same reference numerals may be given to the parts corresponding to the matters described in the preceding form, and overlapping explanations may be omitted. When only a part of the configuration is described in each form, the previously described other forms can be applied to other parts of the configuration. It is possible to combine not only the parts that are specifically indicated in each embodiment to be combinable, but also the embodiments to be partially combined even if they are not explicitly stated unless there is a particular problem with the combination.

(First embodiment)
100 A of operating devices of 1st Embodiment are demonstrated using FIG. The operating device 100A is applied, for example, to an air conditioner for a vehicle. The operation device 100A is a device for changing (inputting) the setting state, setting value, etc. of a predetermined control item. The main body of the operation device 100A is arranged in the instrument panel, and the operation surface 113 is formed so as to be flush with the instrument panel.

A plurality of operation knobs 120 are arranged on the operation surface 113, and by performing an input operation (pressing operation) on one of the operation knobs 120, for example, the on/off setting of the air conditioner, the selection setting of the outside air introduction mode, the selection setting of the blowing mode, etc. are possible.

The operation device 100A includes a housing 110, an operation knob 120, a substrate 130, a push button switch 140, a sliding member 150, and the like.

The housing 110 is a case body that accommodates the operation knob 120, the substrate 130, the push button switch 140, the sliding member 150, etc., and is made of, for example, a resin material. The housing 110 is a vertically flat case body, and includes an upper case 111, a guide case 112, an operation surface 113, and the like.

The upper case 111 is a plate-like portion that forms the upper portion of the housing 110 .

The guide case 112 is a block-shaped portion that forms the lower portion of the housing 110 . In the guide case 112, on the operation surface 113 side, a through hole 112a through which the rod-shaped portion 122 of the operation knob 120 penetrates in the horizontal direction, and on the counter operation surface side of the through hole 112a (the side opposite to the operation surface 113), a housing portion 112b (a downward recessed space portion) in which the sliding member 150 is housed is formed. A guide portion 112c that guides the movement of the sliding member 150 in the sliding direction (vertical direction) is formed on the vertical wall of the accommodation portion 112b on the side opposite to the operation surface. The guide portion 112c is formed, for example, as a rail portion into which a projecting portion provided on the sliding member 150 side and extending in the vertical direction is inserted.

The operation surface 113 is a wall surface erected on the user side of the housing 110 . An opening 113a through which the head portion 121 of the operation knob 120 is inserted is formed in a region of the operation surface 113 facing the through hole 112a.

The operation knob 120 is provided on the operation surface 113 and is a member that is input-operated (pressed) by the user in a first plane perpendicular direction perpendicular to the operation surface 113 . The operation knob 120 has a head portion 121 inserted through the opening 113a and a rod-like portion 122 inserted through the through hole 112a, and is integrally formed of, for example, a resin material. The widthwise dimension of the bar-shaped portion 122 is set smaller (thinner) than the widthwise dimension of the head portion 121 . It should be noted that the first perpendicular direction is not necessarily limited to a direction perpendicular (90 degrees) to the operation surface 113, and a certain amount of inclination is allowed.

A first slope portion 124 is formed at the tip portion 123 of the bar-shaped portion 122 opposite to the operation surface. The first slope portion 124 is formed as a surface that slopes from the lower end side of the distal end portion 123 toward the operation surface 113 side and reaches the upper end side. The first slope portion 124 has an inclination of about 45 degrees, for example.

The substrate 130 is, for example, a plate member (printed circuit board) formed by arranging wiring made of metal foil or the like on a base material formed using an electrically insulating material such as resin. The substrate 130 is arranged in the housing 110 so that the plate surface direction of the operation surface 113 is along the first surface perpendicular direction (here, the horizontal direction). The substrate 130 is arranged above the accommodation portion 112 b of the guide case 112 and assembled to the guide case 112 . An upper case 111 is assembled on the upper side of the substrate 130 .

The push button switch 140 is a switch that forms an ON state or an OFF state by pressing a projecting portion in response to an input operation of the operation knob 120, and is fixed to the lower surface of the substrate 130 so that the projecting portion faces downward. The pressing axis direction of the push button switch 140 is set in the second perpendicular direction orthogonal to the substrate 130 . The push button switch 140 is connected to wiring on the substrate 130 . The push button switch 140 faces the sliding member 150 in the housing portion 112b. It should be noted that the second perpendicular direction is not necessarily limited to a direction perpendicular to the substrate 130 (90 degrees), and a certain degree of inclination is allowed.

The sliding member 150 is a block-shaped member formed separately from the housing 110 and the operation knob 120 . The sliding member 150 is made of, for example, a resin material. The sliding member 150 is housed in the housing portion 112b. A surface of the sliding member 150 facing the first slope portion 124 is formed as a second slope portion 151 along the slope of the first slope portion 124 . The second slope portion 151 has an inclination of about 45 degrees, for example.

The first slope portion 124 and the second slope portion 151 are in contact with each other. The wall surface of the sliding member 150 opposite to the operation surface is guided by the guide portion 112c of the accommodating portion 112b as described above, so that the position of the sliding member 150 is restricted in the first perpendicular direction. Further, the sliding member 150 is a member that can slide in the pressing axis direction (second perpendicular direction) of the push button switch 140 in the accommodating portion 112b. The surface (upper surface) of the sliding member 150 facing the pushbutton switch 140 is in contact with the projecting portion of the pushbutton switch 140 .

The operation device 100A of the present embodiment is configured as described above, and the operation and effects of the operation device 100A will be described below.

When the user performs an input operation (pressing operation) on the operation knob 120 (head 121), the rod-shaped portion 122 and the first slope portion 124 move along the first perpendicular direction toward the sliding member 150, as indicated by the arrow in FIG. At this time, the second slope portion 151 moves along the first slope portion 124 . Here, the position of the sliding member 150 is restricted in the first perpendicular direction by the guide portion 112c, and the inclination of the first slope portion 124 and the second slope portion 151 is inclined toward the operation surface 113 as it goes from the bottom to the top as shown in FIG. As a result, the sliding member 150 pushes the projecting portion of the push button switch 140, so that the push button switch 140 is turned on (or off).

In this way, the sliding member 150 moves in the push-down axis direction (second perpendicular direction) by input operation of the operation knob 120 in the first perpendicular direction to turn on/off the push button switch 140. Therefore, unlike the prior art, the operation knob 120 is not bent, and excellent durability and good operability feeling can be obtained.

Further, since the position of the sliding member 150 is restricted in the first perpendicular direction, the sliding member 150 can be reliably slid in the second perpendicular direction.

Further, since the housing 110 (the guide case 112) is provided with the guide portion 112c, the sliding member 150 can slide smoothly.

In addition, since the plate surface direction of the substrate 130 is arranged along the first perpendicular direction (horizontal direction), the dimension of the second perpendicular direction (vertical direction) can be suppressed as the operating device 100A, and the thickness of the operating device 100A in the second perpendicular direction can be reduced. Therefore, it is possible to reduce the required vertical dimension of the instrument panel (the surface facing the user) of the vehicle and expand the foot space for the user.

(Second embodiment)
FIG. 2 shows an operating device 100B of the second embodiment. The operating device 100B of the second embodiment is obtained by changing the first slope portion 124 from the operating device 100A of the first embodiment.

The rod-shaped portion 122 (tip portion 123) of the operation knob 120 is a vertical surface without the first slope portion 124 provided. In this embodiment, the wall surface of the accommodation portion 112b on the side opposite to the operation surface is formed as the first slope portion 112d. The guide portion 112c is abolished. Thus, the first slope portion 112 d is formed on the housing 110 instead of the operation knob 120 . The first slope portion 112d is a slope that slopes from the lower end side to the upper end side of the wall surface toward the side opposite to the operation surface. The first slope portion 112d has an inclination of about 45 degrees, for example.

In addition, the sliding member 150 has a second slope portion 152 on the wall opposite to the operation surface, and the second slope portion 152 is in contact with the first slope portion 112d. The wall surface of the sliding member 150 on the operation surface 113 side is a vertical surface so as to come into contact with the tip portion 123 of the operation knob 120 .

Also in this embodiment, the input operation of the operation knob 120 causes the second slope portion 152 to move along the first slope portion 112d, so that the sliding member 150 moves in the pressing axial direction (second perpendicular direction), and the push button switch 140 can be turned on (off).

(Third embodiment)
FIG. 3 shows an operating device 100C of the third embodiment. 100 C of operating devices of 3rd Embodiment add the moving member 160 with respect to the operating device 100B of the said 2nd Embodiment.

The moving member 160 is a plate-like member whose plate surface direction is along the first perpendicular direction, and is interposed between the projecting portion of the push button switch 140 and the upper side surface of the sliding member 150 . The end portion of the moving member 160 on the side opposite to the operation surface abuts against the wall portion on the side opposite to the operation surface of the housing portion 112b, and the position of the moving member 160 is restricted with respect to the input operation direction of the operation knob 120 (first perpendicular direction). Further, the moving member 160 is movable together with the sliding member 150 in the pressing axis direction (second perpendicular direction).

In the second embodiment, the sliding member 150 is moved in the first perpendicular direction in addition to the pressing axis direction (second perpendicular direction) by the input operation of the operation knob 120 . Due to this movement in the first perpendicular direction, there is a possibility that the protrusion of the push button switch 140 will generate a force in the first perpendicular direction due to friction.

However, in the present embodiment, when the operation knob 120 is operated for input, the moving member 160 moves only in the push-down axis direction, and unnecessary force (force in the first perpendicular direction) is not applied to the push button switch 140.

(Fourth embodiment)
FIG. 5 shows an operating device 100D of the fourth embodiment. The operation device 100D of the fourth embodiment is different from the operation device 100A of the first embodiment in that tilting (rotation) of the sliding member 150 during input operation is suppressed.

In the operating device 100A, depending on the position of the bar-shaped portion 122 of the operation knob 120 relative to the sliding member 150 as shown in FIG. 4A, there is a possibility that the sliding member 150 is tilted (the lower side of the sliding member 150 is tilted away from the guide portion 112c) due to the first slope portion 124 acting as a force and the projecting portion of the push button switch 140 acting as a fulcrum, as shown in FIG. 4B. . When the sliding member 150 is tilted, the slidability of the sliding member 150 is deteriorated, and the operation feeling of the operation knob 120 is deteriorated, the operability is deteriorated, and the like.

In the present embodiment, as shown in FIG. 5, in the first slope portion 124 of the operation knob 120, the center position 124a of the region that contacts the second slope portion 151 of the sliding member 150 is set to move from the operation front side to the operation back side so as to straddle the depression shaft of the push button switch 140 during input operation.

That is, at the start of the operation, the center position 124a is positioned closer to the operation surface 113 than the depression axis (Fig. 5(a)), during the operation, the center position 124a passes through the depression axis (Fig. 5(b)), and at the end of the operation, the center position 124a is positioned on the opposite side of the operation surface than the depression axis (Fig. 5(c)).

As a result, the operation knob 120 (bar-shaped portion 122) can be configured to press mainly below the center position of the sliding member 150, so that the occurrence of tilting of the sliding member 150 as described with reference to FIG. 4 can be suppressed.

(Fifth embodiment)
FIG. 6 shows an operating device 100E of the fifth embodiment. The operating device 100E of the fifth embodiment is different from the operating device 100A of the first embodiment by adding an inclination suppressing member 170 to suppress the inclination (rotation) of the sliding member 150 during input operation.

The tilt suppressing member 170 is provided, for example, on the upper side of the sliding member 150 at the end on the operation surface 113 side, and serves as a member that restricts the position of the sliding member 150 in the direction perpendicular to the first plane. The tilt suppressing member 170 can be formed, for example, as a rib integrally protruding toward the sliding member 150 from an upright wall on the operation surface 113 side of the accommodating portion 112 b of the guide case 112 . In addition, the inclination suppressing member 170 may be formed by a member separate from the guide case 112 .

As a result, it is possible to restrict the movement of the sliding member 150 in the direction perpendicular to the first plane during the input operation, so that the tilting of the sliding member 150 can be suppressed.

(Sixth embodiment)
Operating devices 100F and 100G of the sixth embodiment are shown in FIGS. 7 to 9. FIG. The operating devices 100F and 100G of the sixth embodiment use seesaw-type operating knobs 120A and 120B in contrast to the operating devices 100A to 100E of the first to fifth embodiments.

The seesaw-type operation knobs 120A and 120B allow input operation to one side or the other side, as indicated by the white arrows in FIGS. The operation knob 120A (FIG. 7) has two rod-shaped portions 122 at both ends of the head 121, and the operation knob 120B (FIG. 8) has one rod-shaped portion 122 at the center of the head 121.

A first slope portion 124 is provided at the tip portion 123 of each bar-shaped portion 122 along the direction of the rotation locus 121b during input operation, and the sliding member 150 is provided with a second slope portion 151 so as to correspond to the first slope portion 124.

As a result, the seesaw type operation knobs 120A and 120B can be handled in the same manner as in the first to fifth embodiments.

(Seventh embodiment)
FIG. 11 shows an operating device 100H of the seventh embodiment. In the operating device 100H of the seventh embodiment, for example, by setting various shapes of the second slope portion 151, different operation feeling can be obtained.

As shown in FIG. 10, the relationship between the amount of movement of the operation knob 120 and the amount of movement of the sliding member 150 during an input operation is determined based on the shapes of the first slope portion 124 and the second slope portion 151 .

For example, as shown in FIG. 11A, by increasing the inclination of the first slope portion 124 and the second slope portion 151, the amount of movement of the sliding member 150 relative to the amount of movement of the operation knob 120 can be increased. Further, as shown in FIG. 11B, by reducing the inclination of the first slope portion 124 and the second slope portion 151, the amount of movement of the sliding member 150 relative to the amount of movement of the operation knob 120 can be reduced.

Furthermore, as shown in FIGS. 11(c) and 11(d), for example, a curved surface or an uneven surface can be added to the second slope portion 151 . In the case where the curved surface (convex curved surface) is added to the second slope portion 151 (FIG. 11(c)), the degree of change in the amount of movement of the sliding member 150 relative to the amount of movement of the operation knob 120 can be changed. Further, in the second slope portion 151 with an uneven surface (FIG. 11(d)), the degree of change in the amount of movement of the sliding member 150 with respect to the amount of movement of the operation knob 120 can be changed in a complicated manner. The load during operation changes according to the amount of movement of the sliding member 150 .

As a result, the operation feeling in the input operation can be changed (improved) simply by presetting the shape of the second slope portion 151 to a predetermined shape without changing the structure of the push button switch 140 or the like.

(Other embodiments)
The disclosure in this specification, drawings, etc. is not limited to the illustrated embodiments. The disclosure encompasses the illustrated embodiments and variations thereon by those skilled in the art. For example, the disclosure is not limited to the combinations of parts and/or elements shown in the embodiments. The disclosure can be implemented in various combinations. The disclosure can have additional parts that can be added to the embodiments. The disclosure encompasses omitting parts and/or elements of the embodiments. The disclosure encompasses permutations or combinations of parts and/or elements between one embodiment and another. The disclosed technical scope is not limited to the description of the embodiments. The disclosed technical scope is indicated by the description of the claims, and should be understood to include all changes within the meaning and range of equivalents to the description of the claims.

In each of the above-described embodiments, the operation devices 100A to 100H are described as the operation devices 100A to 100H for vehicle air conditioners, but the devices to be operated are not limited to air conditioners, other audio devices, head-up display devices, etc. It is possible to correspond to various devices. In addition, the present invention is not limited to vehicles, and may be applicable to devices for households and facilities.

Further, in the first embodiment described above, the guide portion 112c is provided in the housing portion 112b, but the guide portion 112c may be eliminated according to the sliding state of the sliding member 150. FIG.

100A to 100H Operating device 110 Housing 112c Guide portion 112c First slope portion 113 Operation surface 120 Operation knob 123 Tip portion 124 First slope portion 124a Center position 130 Board 140 Push button switch 150 Sliding member 151 Second slope portion 160 Moving member 170 Tilt suppressing member

Claims (7)

an operation knob (120) provided on an operation surface (113) of a housing (110) and operated for input operation in a direction perpendicular to a first plane orthogonal to the operation surface;
a substrate (130) arranged in the housing such that the plate surface direction of the operation surface is along the direction perpendicular to the first surface;
a push button switch (140) provided on the substrate and having a pressing axis direction set in a second perpendicular direction perpendicular to the substrate;
An operation device for turning on and off the push button switch by the input operation to the operation knob,
a tip portion (123) of the operation knob or a first slope portion (124, 112d) provided on the housing;
a sliding member (150) that is formed separately from the housing and the operation knob, has a second slope portion (151) that contacts the first slope portion, and is slidable in the push-down axis direction;
By the input operation on the operation knob, the second slope portion moves along the first slope portion, so that the sliding member slides in the push-down shaft direction to turn on and off the push button switch,
The first slope portion (112d) is an operating device formed on the housing . 2. The operating device according to claim 1 , wherein a moving member (160) is provided between the push button switch and the sliding member, the moving member (160) being positionally regulated with respect to the direction of the input operation of the operation knob and moving in the pressing axis direction together with the sliding member. an operation knob (120) provided on an operation surface (113) of a housing (110) and operated for input operation in a direction perpendicular to a first plane orthogonal to the operation surface;
a substrate (130) arranged in the housing such that the plate surface direction of the operation surface is along the direction perpendicular to the first surface;
a push button switch (140) provided on the substrate and having a pressing axis direction set in a second perpendicular direction perpendicular to the substrate;
An operation device for turning on and off the push button switch by the input operation to the operation knob,
a tip portion (123) of the operation knob or a first slope portion (124, 112d) provided on the housing;
a sliding member (150) that is formed separately from the housing and the operation knob, has a second slope portion (151) that contacts the first slope portion, and is slidable in the push-down axis direction;
By the input operation on the operation knob, the second slope portion moves along the first slope portion, so that the sliding member slides in the push-down shaft direction to turn on and off the push button switch,
The first slope portion (124) is formed at the tip portion of the operation knob,
The sliding member is positionally regulated with respect to the first perpendicular direction,
An operating device in which a center position (124a) of a region where the first slope portion of the operation knob contacts the second slope portion of the sliding member is set to move from the operation front side to the operation back side so as to straddle the depression shaft of the push button switch in the input operation. 4. The operating device according to claim 3 , wherein the housing is provided with a guide portion (112c) for guiding movement of the sliding member in the sliding direction. an operation knob (120) provided on an operation surface (113) of a housing (110) and operated for input operation in a direction perpendicular to a first plane orthogonal to the operation surface;
a substrate (130) arranged in the housing such that the plate surface direction of the operation surface is along the direction perpendicular to the first surface;
a push button switch (140) provided on the substrate and having a pressing axis direction set in a second perpendicular direction perpendicular to the substrate;
An operation device for turning on and off the push button switch by the input operation to the operation knob,
a tip portion (123) of the operation knob or a first slope portion (124, 112d) provided on the housing;
a sliding member (150) that is formed separately from the housing and the operation knob, has a second slope portion (151) that contacts the first slope portion, and is slidable in the push-down axis direction;
By the input operation on the operation knob, the second slope portion moves along the first slope portion, so that the sliding member slides in the push-down shaft direction to turn on and off the push button switch,
The operating device , wherein the operating knob is a seesaw type . The operating device according to any one of claims 1 to 4, wherein the operating knob is a seesaw type. The operating device according to any one of claims 1 to 6 , wherein the second slope portion includes a curved surface or an uneven surface.

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