JP6627087B2 - Input device - Google Patents

Description

  The present disclosure relates to an input device that operates, for example, an in-vehicle device mounted on a vehicle.

  Conventionally, in order to maintain operability of the operation input unit well and prevent erroneous operation, there has been proposed an input device in which a plate-shaped palm rest body having a curved surface and extending above the operation input unit is arranged ( See, for example, Patent Document 1.

JP 2013-98133 A

  An object of the present disclosure is to provide an input device that further reduces the possibility that a user performs an erroneous operation.

  The input device according to an aspect of the present disclosure includes an operation input unit, a palm rest unit arranged across the operation input unit, and a fixed unit that holds the operation input unit and the palm rest unit. , A straddle straddling the operation input unit, and a first leg and a second leg respectively formed at both ends of the straddle and joined to the fixed part.

  In the input device of the present disclosure, since the palm rest portion is disposed across the operation input portion, even if the user approaches the hand while trying to operate the operation input portion by blind touch while gazing forward, the user does not operate unintentionally. It is possible to further reduce the possibility of occurrence.

FIG. 1 is a perspective view of the input device according to the embodiment. FIG. 2 is a top view of the input device according to the embodiment. FIG. 3 is a side view of the input device according to the embodiment. FIG. 4 is a top view illustrating the operation direction of the operation input unit of the input device according to the embodiment. FIG. 5 is a cross-sectional view of the input device according to the embodiment. FIG. 6 is a perspective view of the input device 100. FIG. 7 is a top view of the input device 100. FIG. 8 is a side view of the input device 100. FIG. 9 is a perspective view of another input device 100.

  Prior to the description of the embodiments of the present disclosure, problems in a conventional input device will be briefly described. The input device described in Patent Literature 1 has many exposed portions of the operation input unit that are not covered with the palm rest body. Therefore, particularly when the user attempts to operate the operation input unit by blind touch, the operation is performed against the user's intention. There is a possibility that the input unit may be erroneously operated.

  Hereinafter, embodiments will be specifically described with reference to the drawings. In the following, the same or corresponding elements will be denoted by the same reference symbols throughout the drawings, and redundant description will be omitted. Each of the embodiments described below shows a comprehensive or specific example.

(Knowledge underlying the present disclosure)
The inventor has found that the following problems occur with respect to the input device described in the section of “Background Art”.

  2. Description of the Related Art In recent years, with the advancement of computerization of vehicles, input devices for vehicles having multiple functions have been put to practical use in order to operate various in-vehicle devices in a small space. In this input device, there is disclosed an input device in which a plate-shaped palm rest body having a curved surface and extending above the operation input unit is arranged in order to maintain good operability of the operation input unit and prevent erroneous operation. (For example, Patent Document 1).

  However, the input device described in Patent Literature 1 has a configuration in which the operation input unit has many exposed portions that are not covered with the palm rest body in order to maintain good operability. Therefore, when the user of the vehicle tries to operate the operation input unit by blind touch while gazing forward, there is a problem that the fingertip may touch the operation input unit and operate unintentionally. .

  In order to solve such a problem, an input device according to an aspect of the present disclosure includes an operation input unit, a palm rest unit that is arranged across the operation input unit, and a fixed unit that holds the operation input unit and the palm rest unit. And a palm rest portion having a straddling portion straddling the operation input portion, and first and second leg portions respectively formed at both ends of the straddling portion and joined to the fixing portion. It is characterized by.

  According to this, in the input device, since the palm rest portion is arranged across the operation input portion, the exposed portion of the operation input portion is reduced. As a result, even if the user approaches the hand while trying to operate the operation input unit with blind touch while staring ahead, erroneous operation due to the fingertip touching the operation input unit and operating unintentionally is possible. Properties can be further reduced.

  In the input device, for example, the minimum width of the straddle may be smaller than the maximum width of the operation input unit.

  According to this, since the user can bring the fingertip into contact with the operation input unit from both sides of the straddle, the operation of the operation input unit is further improved.

  In the input device, for example, the minimum width of the straddle may be smaller than the maximum width of the first leg and the maximum width of the second leg.

  According to this, the first leg and the second leg can be joined to the fixing portion with sufficient strength.

  Further, the input device may have a configuration in which at least a part of the palm rest has a curved surface, for example.

  According to this, since the user can place at least a part of the palm along the curved surface of the palm rest, the contact area of the palm with the palm rest can be increased. Therefore, the user can satisfactorily operate the operation input unit with the fingertip while the palm is fixed to the palm rest.

  In addition, the input device may have a configuration in which a switch is arranged on the second leg of the palm rest, for example.

  According to this, since the fingertip is guided to the switch only by the user placing the palm on the palm rest, the user can satisfactorily operate the switch with the fingertip.

  Further, the input device may include, for example, a control unit electrically connected to the operation input unit, and the operation input unit may have a configuration capable of performing a rotation operation and a multidirectional movement operation. Then, when one of the rotation operation and the multi-directional movement operation is operated, the control unit of the input device may ignore the other operation.

  According to this, even if the user erroneously moves the operation input unit while, for example, rotating the operation input unit, the control unit ignores the other operation that is operated later, that is, the movement operation. In addition, erroneous operation can be reduced. Similarly, if the user accidentally rotates the operation input unit while moving the operation input unit, for example, the control unit ignores the other operation that has been operated later, that is, the rotation operation. Can be reduced.

  Further, the operation input unit of the input device may have, for example, a configuration in which a rotation operation and a multidirectional movement operation are possible, and the magnitudes of operation forces of the rotation operation and the multidirectional movement operation are different from each other. Good.

  According to this, it is possible to increase the magnitude of the operating force of the rotation operation and the multi-directional movement operation, whichever is more likely to be erroneously operated, so that the possibility of erroneous operation can be further reduced.

  Further, the operation input unit of the input device can further perform, for example, a pressing operation in addition to the rotating operation and the multidirectional moving operation, and the magnitude of the operating force of the rotating operation, the multidirectional moving operation, and the pressing operation. May have different configurations.

  According to this, among the rotation operation, the multi-directional movement operation, and the pressing operation, the magnitude of the operation force of the one that is most likely to be erroneously operated is maximized, and the magnitude of the operation force of the one that is most easily misoperated is the second largest. However, since the magnitude of the operation force of the hardest erroneous operation can be minimized, the possibility of erroneous operation can be further reduced.

  Hereinafter, embodiments will be specifically described with reference to the drawings. Each of the embodiments described below shows a comprehensive or specific example. Numerical values, shapes, materials, constituent elements, arrangement positions and connection forms of constituent elements, steps, order of steps, and the like shown in the following embodiments are merely examples, and do not limit the present disclosure. Further, among the components in the following embodiments, components not described in the independent claims indicating the highest concept are described as arbitrary components.

(First embodiment)
1 to 5 show the configuration of the input device 1 according to the first embodiment. As shown in each figure, the width direction of the input device is defined as an X-axis direction, the longitudinal direction is defined as a Y-axis direction, and the height direction is defined as a Z-axis direction. The direction indicated by the arrow in FIG. 1 is defined as the positive direction of the X axis, Y axis, and Z axis.

  The input device 1 is for operating a navigation device, an air conditioner, an audio device (none of which are shown), which are on-vehicle devices, and is installed on, for example, a center console in a vehicle compartment.

  FIG. 1 is a perspective view of the input device 1. The input device 1 includes an operation input unit 10, a palm rest unit 20, a fixing unit 30, a switch 40, a fingerprint authentication unit 50, and a touch panel 60. The operation input unit 10 is provided with a columnar dial 11, and the user operates the operation input unit 10 by pinching and moving the dial 11. In addition, the switch 40, the fingerprint authentication unit 50, and the touch panel 60 may not be particularly provided.

  The operation input unit 10 performs operations of the on-vehicle device, and has a configuration capable of performing a rotation operation, a multi-directional movement operation, and a pressing operation. As will be described later in detail, the rotation operation is an operation of turning the dial 11 in the rotation direction, and the multi-directional movement operation is an operation of moving the dial 11 in the positive and negative directions of the X axis and the positive and negative directions of the Y axis. The pressing operation is an operation of pressing the dial 11 in the negative direction of the Z axis. In addition, the operation input unit 10 is not limited to a configuration in which all of the rotation operation, the multi-directional movement operation, and the pressing operation can be performed, and may be a configuration in which at least one of these operations can be performed. . In addition, the multi-directional movement operation is not limited to the above-described operation in the positive and negative directions of the X axis and the operation in the positive and negative directions of the Y axis, that is, the four-directional operation. May be operated in any direction. Further, the multi-directional movement operation may be configured to allow a slide operation in any direction in the XY plane, or may be configured to allow a tilt operation. Further, the operation input unit 10 is not limited to the pressing operation in the negative direction of the Z axis, and may be configured to be capable of performing a pulling operation in the positive direction of the Z axis.

  The palm rest section 20 is for the user to place the palm on, and is arranged across the operation input section 10 as shown in FIG. That is, the palm rest portion 20 has the straddle portion 22 straddling the operation input portion 10 and the first leg portion 24 and the second leg portion 26 formed at both ends of the straddle portion 22, respectively. Here, the palm rest portion 20 is formed by integrally forming the straddle portion 22, the first leg portion 24, and the second leg portion 26 with resin. Note that the palm rest portion 20 is not limited to the integrally formed structure, and at least one of the straddling portion 22, the first leg portion 24, and the second leg portion 26 is a separate body, and these are screwed and fitted. It may be configured to be joined by bonding or the like.

  The fixing part 30 has a rectangular parallelepiped shape, and is installed in the center console. The operation input unit 10 and the palm rest unit 20 are held by the fixing unit 30. The operation input unit 10 is arranged so as to protrude in the positive direction of the Z-axis through an opening 32 formed in the fixing unit 30. The portion of the operation input unit 10 protruding from the opening 32 is formed with a dial 11 that can be pinched and moved by a user with a finger. The dial 11 has a cylindrical shape as described above, but is not limited thereto, and may have a polygonal column shape or a column shape having a concave portion on a side surface. On the other hand, in the palm rest portion 20, the first leg portion 24 and the second leg portion 26 are joined to the fixing portion 30. Specifically, the first leg 24 and the second leg 26 are joined to the fixing portion 30 by fitting. As a result, the palm rest portion 20 is firmly joined to the fixing portion 30 at two locations. The means for joining the first leg portion 24 and the second leg portion 26 to the fixing portion 30 is not limited to fitting, but may be screwing, bonding, or a combination of these. .

  The switch 40 is disposed on a portion of the second leg 26 of the palm rest 20 where the user's finger is located. The switch 40 has a configuration capable of, for example, assigning an operation that is frequently used, and allows the user to perform the operation quickly and easily.

  The fingerprint authentication unit 50 has a security function of authenticating a user's fingerprint. Accordingly, it is possible to set so that an ignition switch (not shown), the operation input unit 10, the switch 40, and the like cannot be operated by a user other than the user. The fingerprint authentication unit 50 is provided on the bottom surface of the concave portion provided on the top surface of the palm rest unit 20. Thereby, when the user places his / her hand on the palm rest section 20, the possibility that the fingerprint authentication section 50 malfunctions can be reduced.

  The touch panel 60 is for the user to perform operations that cannot be performed by the operation input unit 10, such as a swipe operation and a direct input operation of characters. As shown in FIG. 1, the touch panel 60 is juxtaposed with the second leg 26 on the upper surface of the fixing unit 30 where the palm rest 20 is installed. Specifically, the touch panel 60 is installed such that the end on the second leg 26 side of the palm rest portion 20 faces one side of the touch panel 60. The touch panel 60 may be configured to operate in response to a screen of a navigation device or the like (not shown), or may be configured to arrange the screen directly below the touch panel 60 (in the negative direction of the Z axis). In the first embodiment, in any configuration, the operation of the driving user while looking at the screen (such as the operation of directly inputting characters) is restricted. Therefore, as shown in FIG. 1, the touch panel 60 is disposed further ahead (in the positive direction of the Y axis) of the switch 40 provided on the palm rest 20. As a result, even if the user places the palm on the palm rest portion 20 with a blind touch while driving, the fingertips do not easily reach the touch panel 60, and thus the possibility of the user touching the touch panel 60 and performing an erroneous operation is reduced. can do.

  When the user operates the touch panel 60 while the vehicle is stopped, the user may place his / her wrist directly above the second leg 26. This makes it easier for the user's finger to reach the touch panel 60, so that good operability of the touch panel 60 can be ensured.

  FIG. 2 is a top view of the input device 1. As shown in FIG. 2, the palm rest portion 20 is held by the fixed portion 30 across the operation input unit 10 so that the straddle portion 22 is disposed above the operation input unit 10 (in the positive direction of the Z axis). . With this configuration, when the user attempts to operate the operation input unit 10 by blind touch, the palm rest unit 20, particularly the second leg unit 26, prevents the finger input from touching the operation input unit 10, so that the fingertip is not intended. The possibility of erroneous operation by touching the dial 11 of the operation input unit 10 can be reduced.

  However, since the palm rest unit 20 is disposed over the operation input unit 10, the operability of the operation input unit 10 may be reduced. Therefore, in order to improve the operability of the operation input unit 10, the palm rest unit 20 has the following shape.

  That is, as shown in FIG. 2, the operation input unit 10 and the dial 11 determine the shape of the straddle portion 22 in the palm rest unit 20 such that a part thereof is exposed in the positive and negative directions of the X axis when viewed from above. . Specifically, the minimum width Ws of the straddling portion 22 of the palm rest 20 is smaller than the maximum width Dd of the operation input unit 10 (here, the diameter of the dial 11). Thereby, the user can make the fingertips contact the dial 11 of the operation input unit 10 from both sides of the straddle 22, so that the operation of the operation input unit 10 is further improved.

  Further, the minimum width Ws of the straddle 22 is smaller than the maximum width W1 of the first leg 24 and the maximum width W2 of the second leg 26. Thereby, the first leg 24 and the second leg 26 can be fixed to the fixing portion 30 with sufficient strength, so that the palm can be stably placed on the palm rest portion 20 and the fingertips are almost not shaken. The dial 11 of the operation input unit 10 can be operated.

  Further, a portion of the palm rest portion 20 on which the palm is placed, specifically, at least a part of a portion from the straddle portion 22 to the first leg portion 24 has a shape having a curved surface. This allows the user to place at least a part of the palm along the curved surface of the palm rest 20, and thus it is possible to increase the contact area of the palm with the palm rest 20. Therefore, the user can satisfactorily operate the dial 11 of the operation input unit 10 with a fingertip while the palm is fixed to the palm rest unit 20.

  FIG. 3 is a side view of the input device 1. As shown in FIG. 3, the operation input unit 10 is held by the fixed unit 30. The palm rest 20 has an arch shape that straddles the operation input unit 10 and the dial 11, and the first leg 24 and the second leg 26 are fixed to the fixing unit 30.

  Here, the length in the Y-axis direction of the first leg portion 24 of the palm rest portion 20, that is, the depth D <b> 1 is larger than the depth D <b> 2 of the second leg portion 26. This is because a greater stress is applied to the first leg 24 than to the second leg 26 when the user places the palm on the palm rest 20. Therefore, with the above-described shape, the palm rest portion 20 is fixed to the fixing portion 30 with sufficient strength even when the palm is placed.

  Next, the operation direction of the operation input unit 10 will be described in detail with reference to FIG. FIG. 4 is a top view illustrating the operation direction of the operation input unit 10. Here, for simplicity, the palm rest section 20 straddling the operation input section 10 is omitted.

  The dial 11 of the operation input unit 10 is formed in a circular shape when viewed from above. The user touches the fingertip to the dial 11 and rotates clockwise around the axis L (a virtual line in the Z-axis direction passing through the center of the circular shape of the dial 11) as shown by the arc-shaped arrow in FIG. Alternatively, a rotation operation can be performed in a counterclockwise direction.

  Further, the user can slide and move the dial 11 in the positive and negative directions in the X-axis direction and the positive and negative directions in the Y-axis direction with a fingertip. Therefore, the operation input unit 10 has a configuration capable of performing a sliding operation in four directions in the XY plane.

  Further, the user can perform a pressing operation in which a fingertip is brought into contact with the dial 11 and the dial 11 of the operation input unit 10 is pressed in the negative direction of the Z axis.

  Next, a cross-sectional structure of the input device 1 will be described with reference to FIG. FIG. 5 is a cross-sectional view of the input device. FIG. 5 is a sectional view taken along line AA in FIG.

  In the input device 1, the operation input unit 10 includes components such as a dial 11, a sliding body 12, an encoder 13, a sliding plate 14, a spring 15, a pressing switch 16, a printed board 17, a detector switch 18, and a control unit 19. The details of the dial 11 are as described above.

  The sliding body 12 is a component that transmits an operation when the dial 11 is pressed to the pressing switch 16. The encoder 13 is a component that detects an operation when the dial 11 is rotated. The sliding plate 14 is a component that transmits the movement when the dial 11 is moved in multiple directions (sliding operation in this case) to the detector switch 18. The spring 15 is a component for returning the dial 11 to its original position when the dial 11 is slid. The pressing switch 16 is a component that detects a pressing operation of the dial 11 by being pressed by the sliding body 12. The printed board 17 is a component on which various electronic components such as the press switch 16 and the control unit 19 are mounted. The detector switch 18 is a component that detects a sliding operation of the dial 11 by moving the sliding plate 14, and is engaged with the sliding plate 14. The control unit 19 is configured by a microcomputer and is mounted on the printed circuit board 17. Thus, the control unit 19 is electrically connected to various electronic components including the push switch 16.

  Next, the operation of each component when a pressing operation, a rotating operation, and a sliding operation in the operation input unit 10 are performed will be described.

  First, the pressing operation will be described. When the user grips the dial 11 with, for example, the thumb, middle finger, and ring finger, and pushes the dial 11 in the negative direction of the Z axis in FIG. 5, the sliding body 12 moves in the negative direction of the Z axis. As a result, the sliding body 12 presses the pressing switch 16 mounted on the printed circuit board 17. Thereby, the control unit 19 determines that the dial 11 has been pressed. The pressing switch 16 has a built-in elastic member, and the user can obtain a pressing operation feeling by using the elastic member.

  Next, the rotation operation will be described. The user picks up the dial 11 with the thumb, the middle finger, and the ring finger, for example, and rotates the dial 11 clockwise or counterclockwise. The operation of the dial 11 is detected by the encoder 13. The control unit 19 determines a rotation operation based on a signal from the encoder 13.

  Next, the slide operation will be described. The user grips the dial 11 with, for example, the thumb, middle finger, and ring finger, and slides the dial 11 in the positive / negative direction of the X axis or in the positive / negative direction of the Y axis. The sliding plate 14 also moves according to the sliding movement. As a result, the detector switch 18 engaged with the sliding plate 14 detects the movement of the dial 11. The control unit 19 determines a slide operation based on a signal from the detector switch 18. The operation input unit 10 has a spring 15, and the restoring force of the spring 15 causes the dial 11 to return to its original position, and provides a user with a sliding operation feeling. Further, the spring 15 may be an elastic body made of a rubber material.

  Next, the operation of the control unit 19 will be described. The control unit 19 determines the pressing operation, the rotating operation, and the sliding operation of the dial 11 as described above. Then, the operation of the in-vehicle device (not shown) is performed based on the determined result. When making this determination, the control unit 19 performs the following operation.

  When one of the rotation operation and the multidirectional movement operation (here, the slide operation) is operated, the control unit 19 ignores the other operation. Thus, even if the user erroneously slides the operation input unit 10 while rotating the operation input unit 10, for example, the control unit 19 ignores the other operation that has been operated later, that is, the slide operation. Therefore, erroneous operation can be reduced. Similarly, if the user accidentally rotates the operation input unit 10 while sliding the operation input unit 10, for example, the control unit 19 ignores the other operation that has been operated later, that is, the rotation operation. Therefore, erroneous operation can be reduced.

  Note that a similar operation may be extended to a pressing operation. In this case, when any one of the pressing operation, the rotating operation, and the sliding operation of the operation input unit 10 is performed, the control unit 19 ignores the other two operations. . Thereby, it is possible to further reduce erroneous operations.

  Next, the magnitude of the operating force in the pressing operation, the rotating operation, and the sliding operation of the operation input unit 10 will be described.

  First, the magnitude of the operation force in the rotation operation and the slide operation will be described. This is because both the rotation operation and the slide operation are performed in the XY plane, and there is a high possibility that they will be erroneously operated.

  The operation input unit 10 has a configuration in which the magnitudes of the operation forces of the rotation operation and the multidirectional movement operation (here, the slide operation) are different from each other. The magnitude of the operating force is determined by the magnitude of the elastic force of the elastic body incorporated in the click feeling generating mechanism (not shown) for the rotating operation, and the magnitude of the elastic force of the spring 15 for the sliding operation. Therefore, it is possible to adopt a configuration in which the magnitudes of the operation forces are different from each other by determining the magnitudes of the elastic forces to be different from each other.

  This makes it possible to increase the magnitude of the operation force of the rotation operation and the slide operation that is more likely to cause an erroneous operation, thereby further reducing the possibility of the erroneous operation. Specifically, especially when the driving user performs the rotation operation, the user may unintentionally perform the slide operation which is an operation in the same XY plane. Is determined to be larger than the size of the operation force of the rotation operation. This makes the slide operation heavy, so that when the user has no intention to perform the slide operation, it is possible to reduce the possibility of performing the slide operation by mistake.

  Note that a similar configuration may be extended to a pressing operation. That is, the operation input unit 10 may have a configuration in which the magnitudes of the operation forces of the rotation operation, the multidirectional movement operation (here, the slide operation), and the pressing operation are different from each other. The magnitude of the operation force of the pressing operation is determined by the magnitude of the elastic force of the elastic member incorporated in the press switch 16. Therefore, by determining the magnitudes of the elastic forces in the pressing operation, the rotating operation, and the sliding operation to be different from each other, it is possible to have a configuration in which the magnitudes of the operating forces are different from each other.

  As a result, of the rotation operation, the slide operation, and the pressing operation, the magnitude of the operating force of the one that is most likely to be erroneously operated is maximized, and the magnitude of the operation force of the one that is most easily erroneously operated is secondarily increased, and Although it is difficult to do so, the magnitude of the operation force can be minimized, so that the possibility of erroneous operation can be further reduced. Specifically, for the reasons described above, the magnitude of the operation force of the slide operation is determined to be larger than the magnitude of the operation force of the rotation operation, and the magnitude of the operation force of the pressing operation is determined to be larger than them. That is, when the driving user attempts to operate the operation input unit 10 by blind touch, the hand is lowered toward the operation input unit 10 from the positive direction of the Z axis. At this time, the possibility that the thumb touches the top surface of the operation input unit 10 that is not covered by the straddle 22 and performs the pressing operation unintentionally increases. Therefore, the size of the operation force of the pressing operation that is most likely to be erroneously operated is maximized. Next, for the above-described reason, the magnitude of the operation force of the slide operation is made the second largest, and the magnitude of the operation force of the rotation operation that is least likely to be erroneously operated is minimized. As a result, the possibility of erroneous operation is further reduced.

  Note that the magnitude relationship between the magnitudes of the operation forces described above is merely an example, and the order of operations that are likely to be erroneously operated may differ depending on the design of the input device 1 and the mounting location. In this case, the magnitude of each operation force may be determined such that the magnitude of the operation force of the operation that is most likely to be erroneously operated is maximized, and the magnitude of the operation force of the operation that is least likely to be mistakenly operated is minimized.

  Further, for operations with the same degree of erroneous operation, the magnitude of the operation force may be determined to be equal.

  Further, the magnitude of the operation force may be made variable by an electromagnetic force or the like. Thus, the magnitude of the operation force can be adjusted according to the user's habit and preference, so that erroneous operations can be further reduced.

  With the above-described configuration and operation, the input device 1 has the palm rest unit 20 disposed so as to straddle the operation input unit 10. Therefore, when the user operates the operation input unit 10 with a blind touch, erroneous operations can be reduced. it can.

  In the first embodiment, the palm rest portion 20 is arranged so that the longitudinal direction is the Y-axis direction. However, the present invention is not limited to this. May be arranged in such a direction. In addition, the input device 1 may be arranged so as to be inclined at a more operable angle with respect to the user in the XZ plane and the YZ plane.

(Second embodiment)
Hereinafter, the second embodiment will be specifically described with reference to the drawings. In the following, elements that are the same as or correspond to those in the first embodiment are denoted by the same reference numerals throughout all the drawings, and redundant description is omitted.

  6 to 8 show the configuration of the input device 100 according to the second embodiment. As shown in each figure, the width direction of the input device 100 is defined as an X-axis direction, the longitudinal direction is defined as a Y-axis direction, and the height direction is defined as a Z-axis direction. The direction indicated by the arrow in FIG. 6 is defined as the positive direction of the X axis, the Y axis, and the Z axis.

  The input device 100 is also for operating a navigation device, an air conditioner, an audio device (all not shown), which are on-vehicle devices, and is installed on, for example, a center console in a vehicle compartment.

  FIG. 6 is a perspective view of the input device 100. The input device 100 includes an operation input unit 70, a palm rest unit 80, a fixing unit 30, and a touch panel 60. The operation input unit 70 is provided with a columnar dial 71, and the user operates the operation input unit 70 by pinching and moving the dial 71. Further, the fingerprint authentication unit 50 of the first embodiment may or may not be provided.

  The operation input unit 70 operates the in-vehicle device in the same manner as the operation input unit 10 of the first embodiment, and has a configuration capable of performing a rotation operation, a multi-directional movement operation, and a pressing operation. The multidirectional movement operation restricts the operation of the dial 71 in the positive direction of the Y axis in the XY plane among the four-directional operations described in the first embodiment. Therefore, in the second embodiment, the multidirectional movement operation is a three-way operation. The operation input unit 70 is not limited to a configuration capable of performing all of the rotation operation, the multi-directional movement operation, and the pressing operation, and may be a configuration capable of performing at least one of these operations. Further, the multi-directional movement operation is not limited to the above-described three-directional operation, and may be configured to allow four-directional operation, or any direction in the XY plane formed by the X axis and the Y axis. The configuration may be such that the operation can be performed at any time. Further, the multi-directional movement operation may be configured to allow a slide operation in any direction in the XY plane, or may be configured to allow a tilt operation. Further, the operation input unit 70 is not limited to the pressing operation in the negative direction of the Z axis, and may be configured to be capable of performing a pulling operation in the positive direction of the Z axis.

  The palm rest section 80 is for the user to place the palm on, and is arranged across the operation input section 70 as shown in FIG. That is, the palm rest section 80 has a straddle section 82 straddling the operation input section 70, and a first leg section 84, a second leg section 86, and a third leg section 88 formed on the straddle section 82. Here, the palm rest portion 80 is configured by integrally forming the straddling portion 82, the first leg portion 84, the second leg portion 86, and the third leg portion 88 with resin. Note that the palm rest portion 80 is not limited to the integrally formed structure, and at least one of the straddle portion 82, the first leg portion 84, the second leg portion 86, and the third leg portion 88 is a separate body. It is good also as a structure joined by screwing, fitting, adhesion, etc.

  The fixing part 30 has a rectangular parallelepiped shape, and is installed in the center console. An operation input unit 70 and a palm rest unit 80 are held by the fixing unit 30. The operation input unit 70 is arranged so as to protrude in the positive direction of the Z axis through an opening 92 formed in the fixing unit 30. A dial 71 that can be picked and moved by a user with a finger is formed in a portion of the operation input unit 70 protruding from the opening 92. The dial 71 has a cylindrical shape as described above, but is not limited to this, and may have a polygonal column shape or a column shape having a concave portion on a side surface. On the other hand, in the palm rest portion 80, the first leg portion 84, the second leg portion 86, and the third leg portion 88 are joined to the fixing portion 30. Specifically, the first leg portion 84, the second leg portion 86, and the third leg portion 88 are joined to the fixed portion 30 by fitting. Thus, the palm rest portion 80 is firmly joined to the fixing portion 30 at three places. Further, the end on the second leg 86 side and the end on the third leg 88 side are joined to the fixing portion 30 so as to face one side of the touch panel 60, respectively. The means for joining the first leg portion 84, the second leg portion 86, and the third leg portion 88 to the fixing portion 30 is not limited to fitting, but may be screwing, bonding, or a combination thereof. May be joined together.

  In the second embodiment, the touch panel 60 has a function of determining the number of touches of the user's finger or the number of touches in addition to operations such as a swipe operation and a direct input operation of characters. The touch panel 60 may be configured to operate in accordance with a screen of a navigation device or the like (not shown), or may be configured to arrange the screen directly below the touch panel 60 (in the negative direction of the Z axis). As shown in FIG. 6, the touch panel 60 is disposed further ahead (in the positive direction of the Y axis) of the second leg 86 and the third leg 88 provided on the palm rest 80. With such a configuration, in the second embodiment, since the switch 40 of the first embodiment is not provided, when the user places the palm on the palm rest 80, the fingertip reaches the touch panel 60. Therefore, while the user is driving, for example, an input operation according to the number of touched fingers or the number of touches, specifically, an operation to call a screen defined in advance corresponding to the number of touched fingers or the number of touches, or the like can be performed. it can. In order to reduce erroneous operations on the touch panel 60 during driving, for example, the input device 100 determines that the touch panel 60 has only one finger touch or only one touch on the touch panel 60 during driving. In such a case, the operation may be ignored and the operation may be ignored.

  FIG. 7 is a top view of the input device 100. As shown in FIG. 7, the palm rest portion 80 is held by the fixed portion 30 across the operation input unit 70 so that the straddle portion 82 is disposed above the operation input unit 70 (in the positive direction of the Z axis). . With this configuration, the possibility of an erroneous operation can be reduced as in the first embodiment.

  However, since the palm rest unit 80 is arranged over the operation input unit 70, the operability of the operation input unit 70 may be reduced. Therefore, in order to improve the operability of the operation input unit 70, the palm rest unit 80 has the following shape.

  That is, as shown in FIG. 7, the operation input unit 70 and the dial 71 are formed so that a part thereof is exposed in the positive and negative directions of the X-axis and the positive direction of the Y-axis in a top view, The shape is determined. Specifically, the minimum width Ws1 of the straddling portion 82 of the palm rest portion 80 is smaller than the maximum width Dd1 of the operation input unit 70 (here, the diameter of the dial 71). Thereby, the user can make the fingertips contact the dial 71 of the operation input unit 70 from both sides of the straddle 82, so that the operation of the operation input unit 70 is further improved.

  Further, the minimum width Ws1 of the straddle 82 is smaller than the maximum width W3 of the first leg 84 and the maximum width W4 formed by the second leg 86 and the third leg 88. Thereby, the palm rest 80 can be fixed to the fixing portion 30 with sufficient strength at the three positions of the first leg 84, the second leg 86, and the third leg 88. The dial 71 of the operation input unit 70 can be operated stably, and the fingertip hardly shakes.

  Further, a portion of the palm rest portion 80 on which the palm is placed, specifically, at least a part of a portion from the straddling portion 82 to the first leg portion 84 has a shape having a curved surface. This allows the user to place at least a part of the palm along the curved surface of the palm rest 80, so that the contact area of the palm with the palm rest 80 can be increased. On the surface of the first leg portion 84, a mounting portion 85 having a curved surface along the shape of the wrist is provided so that the wrist can be mounted. Therefore, the user can satisfactorily operate the dial 71 of the operation input unit 70 with a fingertip while the palm is fixed to the palm rest unit 80.

  FIG. 8 is a side view of the input device 100. As shown in FIG. 8, the operation input unit 70 is held by the fixed unit 30. The palm rest 80 has an arch shape that straddles the operation input unit 70 and the dial 71, and the first leg 84, the second leg 86, and the third leg 88 are fixed to the fixing unit 30.

  Here, the length in the Y-axis direction of the first leg portion 84 of the palm rest portion 80, that is, the depth D3 is larger than the depth D4 of the second leg portion 86 and the third leg portion 88. This is because a greater stress is applied to the first leg 84 than the second leg 86 and the third leg 88 when the user places the palm on the palm rest 80. Therefore, with the above shape, the palm rest portion 80 is fixed to the fixing portion 30 with sufficient strength even when the palm is placed.

  Further, the curved surface forming the mounting portion 85 has a portion where the inclination is steep toward the fixing portion 30 and a portion where the inclination is gentle. For this reason, the user places the wrist on the placing portion 85 and, with the palm fixed to the straddling portion 82, moves the both legs (the X-axis positive / negative direction) of the straddling portion 82 to the second leg portion 86 and the third leg portion 88. The dial 71 of the operation input unit 70 can be held at three points by fingertips from three places between (in the Y-axis positive direction). As a result, the dial 71 can be operated well.

  Here, the maximum height H1 from the fixed portion 30 between the second leg portion 86 and the third leg portion 88 is higher than the maximum height H2 of the operation input portion 70 from the fixed portion 30. With such a configuration, the gap is narrower than both sides of the straddle 82 (between the first leg 84 and the second leg 86 and between the first leg 84 and the third leg 88). The dial 71 can be easily picked up with a fingertip from between the second leg 86 and the third leg 88.

  The second leg portion 86 and the third leg portion 88 may have a shape in which the second leg portion 86 described in the first embodiment is forked.

  Next, details of the operation direction of the operation input unit 70 are the same as those of the first embodiment except for the following points. That is, the operation of the dial 71 in the positive direction of the Y axis in the XY plane is restricted. Thereby, the depth D4 of the second leg portion 86 and the third leg portion 88 can be reduced, so that the touch panel 60 can be brought closer to the dial 71.

  The control unit 19 is the same as in the first embodiment. Therefore, detailed description is omitted.

  In the second embodiment as well, the palm rest portion 80 is arranged so that the longitudinal direction is the Y-axis direction. However, the present invention is not limited to this, and the longitudinal direction is within the XY plane depending on the mounting location. They may be arranged in any direction. Further, the input device 100 may be arranged so as to be inclined at an angle that is easier for the user to operate in the XZ plane and the YZ plane.

  Further, the second embodiment has a configuration in which the switch 40 of the first embodiment is not provided. Therefore, a configuration in which the slide operation of the operation input unit 70 corresponds to the input operation of the switch 40 may be adopted. That is, for example, the switch 40 at the left end in FIG. 2 is a slide operation of the operation input unit 70 in the positive direction of the X axis, the middle switch 40 is a slide operation of the operation input unit 70 in the non-Y direction, and the switch 40 at the right end. Correspond to the sliding operation of the operation input unit 70 in the negative direction of the X axis. Thereby, also in the second embodiment, a function equivalent to that of the switch 40 can be provided. Note that icons corresponding to the above-described three slide operations are displayed on the top surface of the straddle portion 82 in FIGS. 6 and 7.

  FIG. 9 is a perspective view of another input device 100. Here, instead of the second leg portion 86 and the third leg portion 88, the second leg portion 86 is provided between the portion connected to the fixing portion 30 and the portion connected to the straddle portion 82 so as to open the leg. A portion 89 is provided. Therefore, the user can operate the dial 71 from the opening 89 in the leg. In the configuration of FIG. 9 as well, as described in FIG. 8, the maximum height H1 of the opening 89 in the leg from the fixing portion 30 is higher than the maximum height H2 of the operation input portion 70 from the fixing portion 30. . Thus, the dial 71 can be easily picked with a fingertip. Further, with the configuration in FIG. 9, the lower end surface of the second leg 86 is joined to the fixing unit 30, so that a wall can be provided between the touch panel 60 and the dial 71. As a result, the possibility of operating the operation input unit 70 while operating the touch panel 60 or conversely, reducing the possibility of erroneous operation caused by operating the touch panel 60 while operating the operation input unit 70 is reduced. can do.

  With the configuration described above, in the input device 100, the palm rest portion 80 is disposed so as to straddle the operation input unit 70, so that erroneous operations by the user can be reduced. Further, since the input device 100 can operate the dial 71 also from the Y-axis direction, the user can hold the dial 71 at three points, and can easily perform a rotating operation, a multidirectional moving operation, and a pressing operation. Become.

  Since the input device according to the present disclosure can reduce erroneous operations, it is useful as an in-vehicle input device or the like.

1,100 Input device 10,70 Operation input unit 11,71 Dial 12 Sliding body 13 Encoder 14 Sliding plate 15 Spring 16 Press switch 17 Printed circuit board 18 Detector switch 19 Control unit 20,80 Palm rest unit 22,82 Bridge unit 24, 84 first leg 26, 86 second leg 30 fixing part 32, 92 opening 40 switch 50 fingerprint authentication part 60 touch panel 85 mounting part 88 third leg 89 opening in leg

Claims (13)

An operation input unit;
A palm rest portion straddling the operation input portion,
A fixing unit that holds the operation input unit and the palm rest unit,
The palm rest unit, possess said operation input unit straddle straddle portion, respectively formed at both ends of the straddle portion, a first leg and a second leg which is joined to the fixing portion,
Wherein said palm rest portion of the fixed portion is provided to the holding surface, further comprising Ru input device a touch panel that is aligned with the second leg. 2. The input device according to claim 1, wherein an end of the palm rest where the second leg is located faces one side of the touch panel. 3.   An operation input unit;
A palm rest portion arranged to straddle the operation input portion,
A fixing unit that holds the operation input unit and the palm rest unit,
The palm rest portion includes a straddle that straddles the operation input unit, and a first leg and a second leg that are respectively formed at both ends of the straddle and that are joined to the fixed portion.
The input device, wherein the palm rest unit further includes a third leg unit joined to the fixing unit. 4. The input device according to claim 3 , wherein a maximum height of the portion between the second leg and the third leg from the fixed portion is higher than a maximum height of the operation input portion from the fixed portion. 5.   An operation input unit;
A palm rest portion arranged to straddle the operation input portion,
A fixing unit that holds the operation input unit and the palm rest unit,
The palm rest portion includes a straddle that straddles the operation input unit, and a first leg and a second leg that are respectively formed at both ends of the straddle and that are joined to the fixed portion.
The input device, wherein the second leg has an opening in the leg. The input device according to claim 5 , wherein a maximum height of the opening in the leg from the fixed portion is higher than a maximum height of the operation input portion from the fixed portion.   An operation input unit;
A palm rest portion arranged to straddle the operation input portion,
A fixing unit that holds the operation input unit and the palm rest unit,
The palm rest portion includes a straddle that straddles the operation input unit, and a first leg and a second leg that are respectively formed at both ends of the straddle and that are joined to the fixed portion.
An input device having a configuration in which the operation input unit is capable of performing a rotation operation and a multi-directional movement operation, and has different operation forces between the rotation operation and the multi-directional movement operation.   8. The input device according to claim 7, wherein the operation input unit is further configured to be capable of performing a pressing operation, and that the rotational operations, the multidirectional movement operations, and the pressing operations have different magnitudes of operating forces. The input device according to claim 1, wherein a minimum width of the straddling portion is smaller than a maximum width of the operation input unit. The input device according to claim 9, wherein a minimum width of the straddle is smaller than a maximum width of the first leg and a maximum width of the second leg. The input device according to claim 1, wherein at least a part of the palm rest has a curved surface. The input device according to any one of claims 1, 3, 5, and 7, further comprising a switch provided on the second leg of the palm rest. A control unit electrically connected to the operation input unit;
The operation input unit has a configuration that allows a rotation operation and a multi-directional movement operation,
8. The control unit according to claim 1, wherein when the operation input unit is operated in one of the rotation operation and the multidirectional movement operation, the other operation is ignored. 9. The input device according to the item.

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