JP5239911B2 - Indicator device - Google Patents

Description

  The present invention relates to an indicating instrument device including a display such as a liquid crystal display.

Conventionally, various in-vehicle instruments have been proposed and disclosed in, for example, Patent Document 1. Such an in-vehicle instrument displays predetermined information on a display and moves an indicating instrument based on the information. However, such an in-vehicle instrument simply moves the substantial meter in the horizontal direction or the vertical direction, and requires a space for movement corresponding to each direction. In addition, the exterior parts (steering, instrument panel) around the meter have arcs and curved surfaces, and if the movement direction of the physical meter is specified as one direction, the shape of the exterior part is damaged. Yes.
Therefore, the applicant of the present application has proposed an indicating instrument device that minimizes the space for movement of the substantial meter and does not impair the shape of the exterior part (Japanese Patent Application No. 2008-232136).

German Patent Application No. 10331131

However, in such an indicating instrument device, when the indicator unit displayed on the display unit and the actual meter are displayed in a consistent manner, the display unit and the actual meter are used to display in harmony. There was a problem that the freshness to the display that combined the vessel and the physical meter faded away. In addition, due to long-term use of the indicating instrument device, the moving mechanism for moving the actual meter deteriorates, and the actual meter moved by the moving mechanism does not slightly match the indicator portion displayed on the display. There is a possibility that the display quality of the indicating instrument device is lowered.
The present invention makes it possible to realize an indicator instrument device that makes it possible to maintain a freshness and to reduce the display quality of the indicator instrument device, making it conscious that the display and the meter are combined. It is to provide.

  In order to solve the above problems, the present invention moves the indicator 13 that displays the indicator portion 12 in the first region S1 or the second region S2, the pointer 13 that indicates the indicator portion 12, and the pointer 13 And the indicator unit 12 is displayed on the display 11 so that the indicator unit 12 moves from the first region S1 to the second region S2, and the indicator unit 12 corresponds to the indicator unit 12. Control means 30 for moving the pointer 13 from the first position to the second position as described above, wherein the control means 30 is the indicator section displayed on the display 11 The pointer 13 is moved from the first position to the second position so as to be accompanied by time differences D1, D2, D3, D4, D5, and D6.

  Further, according to the present invention, the control means 30 moves the indicator portion 12 from the first region S1 to the second region S2 so that the moving speed of the indicator portion 12 and the moving speed of the pointer 13 are different. And the pointer 13 is moved from the first position to the second position.

  Further, according to the present invention, the control means 30 moves the pointer 13 so that the pointer 13 reaches the second position substantially at the same time as the indicator portion 12 reaches the second region S2. It is moved from the first position to the second position.

  Further, according to the present invention, the control means 30 moves the index unit 12 and the pointer 13 during the period in which the index unit 12 is moved from the first area S1 to the second area S2. The pointer 13 is moved from the first position to the second position so as to reverse.

  Further, in the present invention, the control means 30 starts the movement of the pointer 13 from the first position substantially simultaneously with the movement of the indicator section 12 from the first area S1. .

  By moving the pointer so that there is a time difference with respect to the movement of the indicator portion displayed on the display device, it is possible to make it aware that the indicator portion is displayed on the display device and to maintain freshness.

The front view which shows 1st embodiment of this invention. The side view which shows embodiment same as the above. The front view of the liquid crystal display which shows embodiment same as the above. The block diagram which shows embodiment same as the above. The front view which shows embodiment same as the above. The front view which shows embodiment same as the above. The timing diagram which shows embodiment same as the above. The timing diagram which shows 2nd embodiment of this invention. The timing diagram which shows 3rd embodiment of this invention. The timing diagram which shows 4th embodiment of this invention. The timing diagram which shows 5th embodiment of this invention. The timing diagram which shows 6th embodiment of this invention.

  Hereinafter, an embodiment in which the present invention is applied to a vehicle-mounted instrument 10 will be described with reference to the accompanying drawings. 1 to 7 are diagrams showing a first embodiment.

  Reference numeral 11 denotes a liquid crystal display (display), and the liquid crystal display 1 includes a TFT (Thin Film Transistor) type liquid crystal display panel, and displays an index portion 12 and character information. The liquid crystal display 11 has a hexagonal shape when viewed from the front, but the peripheral portion of the liquid crystal display 11 is covered with a turn 40 so that the liquid crystal display 11 is not visually recognized. Reference numeral 13 denotes a pointer. The pointer 13 includes a substantially cylindrical base portion 13a and an instruction portion 13b extending from the base portion 13a in the radial direction. The instruction unit 13 b of the pointer 13 instructs the indicator unit 12 that is an image displayed on the liquid crystal display 11.

  Reference numeral 14 denotes a support body. The support body 14 includes a disk portion 15, an annular portion 16, an arm portion 17, and a shaft portion 18, and supports the pointer 13 in a rotatable manner. The pointer 13 is fixed to the disk portion 15 of the support 4, and the pointer 13 fixed to the disk portion 15 is rotated by the electric motor 20 through the gear 19. The vehicle-mounted instrument 10 displays the speedometer 25 and the tachometer 26 by instructing the indicator part 12 displayed on the liquid crystal display 11 with the instruction part 13 b of the pointer 13.

  Reference numeral 21 denotes an electric motor, and the support body 14 is rotated by the electric motor 21. The electric motor 21 moves the pointer 13 and the support 14 in an arc shape around the shaft portion 18. Reference numeral 23 denotes a moving mechanism, and the moving mechanism 23 includes a support 14 and an electric motor 21. The pointer 13 is moved in a circular arc shape within a range of a predetermined angle θ (for example, 25 °) by the moving mechanism 23.

  FIG. 4 is a block diagram showing the electrical configuration of the vehicle-mounted instrument 10 and various sensors. Reference numeral 30 denotes a microcomputer (control means). The microcomputer 30 includes a CPU, a ROM, a RAM, an input / output interface, and the like. Reference numeral 31 denotes a speed sensor. The speed sensor 31 detects the vehicle speed and outputs vehicle speed data to the microcomputer 30. Reference numeral 32 denotes a rotation sensor. The rotation sensor 32 detects the engine rotation speed and outputs the rotation speed data to the microcomputer 30.

  33 is a seat belt detector, and this seat belt detector 33 detects whether or not the vehicle driver is wearing the seat belt. The microcomputer 30 inputs vehicle speed data and rotation speed data from the speed sensor 31 and the rotation sensor 32, and drives the liquid crystal display 11 and the electric motor 21 based on the vehicle speed data and rotation speed data. Is displayed.

  The vehicle-mounted instrument 10 has a first display form (see FIG. 1) in which the speedometer 25 and the tachometer 26 are arranged close to each other, and a second display form in which the speedometer 25 and the tachometer 26 are arranged on both sides (see FIG. 5). ) And are possible. The vehicle-mounted instrument 10 normally displays the speedometer 25 and the tachometer 26 in the first display form. When the seatbelt detector 33 detects that the seatbelt is detached, the microcomputer 30 While shifting to the second display mode, warning information “Please fasten the seat belt” is displayed in the center of the screen of the liquid crystal display 11.

  When shifting from the first display mode to the second display mode, the microcomputer 30 delays the movement P of the pointer 13 and the support body 14 from the movement M of the indicator portion 12 displayed on the liquid crystal display 11 (see FIG. 6 and FIG. 6). (See FIG. 7). The movement M of the indicator portion 12 displayed on the liquid crystal display 11 starts at timing T1 and is completed at timing T2. The movement P of the pointer 13 and the support 14 starts simultaneously with the timing T2 when the movement M of the indicator 12 is completed, and is completed at the timing T3.

  The moving speed of the indicator 12 displayed on the liquid crystal display 11 is the same as the moving speed of the pointer 13 and the support 14. There is a time difference D1 between the timing when the indicator portion 12 passes the predetermined angular position θ2 and the timing when the pointer 13 and the support 14 pass the predetermined angular position θ2. FIG. 6 shows the state of the vehicle-mounted meter 10 at the timing T2, and the indicator 12 displayed on the liquid crystal display 11, the pointer 13 and the support 14 are displaced by a predetermined angle θ. .

  FIG. 8 shows a second embodiment. The movement P of the pointer 13 and the support body 14 starts at timing T4, and the movement M of the indicator 12 displayed on the liquid crystal display 11 starts at timing T5. Since the movement M of the indicator portion 12 displayed on the liquid crystal display 11 is fast, the movement M of the indicator portion 12 displayed on the liquid crystal display 11 is completed at the timing T6, and then the movement P of the pointer 13 and the support 14 is performed. Is completed at timing T7. There is a time difference D2 between the timing at which the pointer 13 and the support 14 pass through the predetermined angular position θ2 and the timing at which the indicator portion 12 passes through the predetermined angular position θ2.

  FIG. 9 shows a third embodiment. The movement M of the indicator portion 12 displayed on the liquid crystal display 11 and the movement P of the pointer 13 and the support 14 simultaneously start at timing T8. Since the movement M of the indicator 12 displayed on the liquid crystal display 11 is fast and the movement P of the pointer 13 and the support 14 is slow, the movement M of the indicator 12 displayed on the liquid crystal display 11 is completed at timing T9. Thereafter, the movement P of the pointer 13 and the support 14 is completed at timing T10. There is a time difference D3 between the timing when the indicator 12 passes the predetermined angular position θ2 and the timing when the pointer 13 and the support 14 pass the predetermined angular position θ2.

  FIG. 10 shows a fourth embodiment. The movement P of the pointer 13 and the support 14 starts at timing T11, and thereafter the movement M of the indicator 12 displayed on the liquid crystal display 11 starts at timing T12. The moving speed of the indicator 12 displayed on the liquid crystal display 11 is the same as the moving speed of the pointer 13 and the support 14, and the movement P of the pointer 13 and the support 14 is completed at timing T13. The movement M of the indicator 12 displayed on the display 11 is completed at timing T14. There is a time difference D4 between the timing at which the pointer 13 and the support 14 pass through the predetermined angular position θ2 and the timing at which the indicator portion 12 passes through the predetermined angular position θ2.

  FIG. 11 shows a fifth embodiment. The movement P of the pointer 13 and the support 14 and the movement M of the indicator portion 12 displayed on the liquid crystal display 11 start at the same time T15. Until the timing T16, the movement M of the indicator portion 12 displayed on the liquid crystal display 11 is slow, and the movement P of the pointer 13 and the support 14 is fast. Therefore, the movement M of the indicator portion 12 displayed on the liquid crystal display 11 is faster. Also, the movement P of the pointer 13 and the support 14 precedes.

  From timing T16, the moving speed is reversed, the movement M of the indicator 12 displayed on the liquid crystal display 11 is fast, the movement P of the pointer 13 and the support 14 is slow, and the movement P of the pointer 13 and the support 14 is slow. The movement M of the indicator portion 12 displayed on the liquid crystal display 11 is preceded. The movement P of the pointer 13 and the support 14 and the movement M of the indicator portion 12 displayed on the liquid crystal display 11 are simultaneously completed at timing T17. There is a time difference D5 between the timing at which the pointer 13 and the support 14 pass the predetermined angular position θ2 and the timing at which the indicator portion 12 passes the predetermined angular position θ2.

  FIG. 12 shows a sixth embodiment. The movement M of the indicator 12 displayed on the liquid crystal display 11 starts at timing T18, and thereafter the movement P of the pointer 13 and the support 14 starts at timing T19, but the movement P of the pointer 13 and the support 14 is fast. The movement M of the indicator 12 displayed on the liquid crystal display 11 is completed at the same time as the movement P of the pointer 13 and the support 14 and at timing T20. There is a time difference D6 between the timing at which the indicator 12 passes the predetermined angular position θ2 and the timing at which the pointer 13 and the support 14 pass the predetermined angular position θ2.

  According to each embodiment, when shifting from the first display mode to the second display mode, a positional deviation occurs between the indicator portion 12 displayed on the liquid crystal display 11, the pointer 13 and the support 14. The indicator portion 21 displayed on the liquid crystal display 11 is a novel effect that does not coincide with the annular portion 16 of the support 14, and the indicator portion 12 is an image of the liquid crystal display 11 for the vehicle driver. You can be aware of this and maintain freshness.

  Further, even if the moving mechanism 23 for moving the pointer 13 deteriorates due to long-term use of the vehicle-mounted meter 10 and the pointer 13 does not move smoothly, the indicator portion displayed on the liquid crystal display 11 12 and the pointer 13 and the support 14 are produced so that the display quality of the in-vehicle instrument 10 is not lowered.

  In addition, this invention is not limited to each embodiment, A various deformation | transformation is possible, for example, you may display navigation information in the screen center of the liquid crystal display 11 in a 2nd display form. In each of the embodiments, the pointer 13, the index portion 12, and the like are moved in an arc shape. For example, the pointer 13, the index portion 12 and the like may be moved in parallel.

11 Liquid crystal display (display)
12 Indicator part 13 Pointer 23 Movement mechanism 30 Microcomputer (control means)
S1 first area S2 second area

Claims (5)

A display that displays an indicator in the first region or the second region, a pointer that points to the indicator, a moving mechanism that moves the pointer, and the indicator that moves from the first region to the second region Control means for causing the indicator to be displayed on the display so as to move to the area of the indicator and to move the pointer from the first position to the second position so as to correspond to the indicator. An instrument device,
The control means moves the pointer from the first position to the second position so that a time difference is caused with respect to the movement of the indicator portion displayed on the indicator. apparatus.   The control means moves the indicator portion from the first region to the second region so that the moving speed of the indicator portion and the moving speed of the pointer are different, and moves the pointer to the first region. The indicating instrument device according to claim 1, wherein the indicating instrument device is moved from a position to the second position.   The control means moves the pointer from the first position to the second position so that the pointer reaches the second position substantially simultaneously with the indicator portion reaching the second region. 2. The indicating instrument device according to claim 1, wherein the indicating instrument device is moved.   The control means moves the indicator so that the moving speed of the indicator and the moving speed of the pointer are reversed during a period in which the indicator is moved from the first area to the second area. The indicating instrument device according to claim 1, wherein the indicating instrument device is moved from one position to the second position. 2. The indicating instrument according to claim 1, wherein the control unit starts the movement of the pointer from the first position substantially simultaneously with the movement of the indicator unit from the first region. apparatus.

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