JP2010070122A - Display device and drive control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display device capable of opening/closing smoothly. <P>SOLUTION: An engaging means is provided with an elongated hole 30 arranged in either one of a lid 26 and a display 24, and an engaging pin 27 arranged in the other of the lid 26 and the display 24 so as to be movable within the elongated hole 30, the elongated hole 30 includes a first groove for rotating the lid 26 by cooperating with open/close motion of the display 24 and a second groove 33 for opening/closing the display only in a state rotation of the lid is stopped, and a drive control means controls so as to apply a predetermined drive voltage to a first and second motor 41 when the display 24 is opened from a storage position to a use position and to gradually lower a drive voltage applied to the second motor before the engaging pin 27 moves from the first groove to the second groove 33. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present application belongs to a technical field of a display device such as an in-vehicle display device such as a car navigation device that is mounted on a dashboard of a vehicle, for example, and in which audio and visual functions and a navigation function are integrated.

  Generally, there are inventions disclosed in Patent Documents 1 and 2, for example, in-vehicle display devices mounted on a dashboard or the like of a vehicle.

  The invention disclosed in Patent Document 1 includes a display that can be moved between a storage position stored in a storage portion of a vehicle and a use position protruding from the storage portion, and the display includes the storage position and the use position. A vehicle-mounted monitor device configured to cover the storage portion with a vehicle-side cover member when the display is in a storage position. A separate body is configured such that when the display moves from the storage position toward the use position, a part of the display comes into contact with the lid member to push open the lid member.

  Further, in the invention disclosed in Patent Document 2, the coupling means causes a non-uniform connection between the movement of the display unit and the movement of the cover. Over the complete course of movement, the relative proportion of the driving movement already progressed by the display unit relative to the driving movement that the display unit wants to make progress, and the cover, relative to the driving movement that you want to make progress overall, The ratio between the relative proportion of the running movements already advanced by the cover is adapted to change.

Japanese Patent Laid-Open No. 10-147185 JP 2007-126135 A

  In the display devices disclosed in Patent Documents 1 and 2 described above, the storage position in which the display is stored in the storage portion of the vehicle by the relationship between the cam groove provided on the device main body side and the cam follower provided in the display, and the storage portion It is possible to move between the use position protruding from. Such a display device simply performs a switching operation by applying a constant voltage to the drive motor. Such a display device has a low texture because it is opened and closed while the display is loose.

  The present application has been made in consideration of the above circumstances, and an example of the problem is to provide a display device in which a display can be smoothly opened and closed between a storage position and a use position.

  In order to solve the above-described problem, a display device according to claim 1 includes a base, a display unit rotatably attached via a first shaft provided at one end of the base, and the display unit. A first motor that opens and closes between a storage position and a use position, and one end of which is rotatably attached via a second shaft provided at the other end of the base, and the other end of the display unit. A lid connected to the display unit via an engaging means that is relatively movable with respect to the display, a second motor that rotates the lid, and drive control of the first and second motors And a drive control means for performing the operation, wherein the engagement means is configured to be able to move in a long hole portion provided in one of the lid portion and the display portion and in the long hole portion. An engagement pin provided on the other of the lid and the display. The elongated hole portion includes a first groove portion for rotating the lid portion in cooperation with the opening / closing operation of the display portion, and only the display portion in a state where the rotation operation of the lid portion is stopped. A second groove portion that opens and closes, and the drive control means applies a predetermined drive voltage to the first and second motors when the display portion is opened from a storage position to a use position. In addition, the guide pin is controlled so as to gradually decrease the drive voltage applied to the second motor before the guide pin shifts from the first groove portion to the second groove portion.

  According to a second aspect of the present invention, there is provided a drive control method using a base, a display unit rotatably attached via a first shaft provided at one end of the base, and using the display unit as a storage position. A first motor that opens and closes between positions, and one end rotatably attached via a second shaft provided at the other end of the base, and the other end relative to the display A lid connected to the display unit via a movable engagement means, a second motor for rotating the lid, and drive control for driving and controlling the first and second motors And the engagement means is either a long hole provided in one of the lid or the display, and either the lid or the display so as to be movable in the long hole. An engagement pin provided on the other side, and the elongated hole portion cooperates with the opening / closing operation of the display portion. A drive control method for a display device, comprising: a first groove portion for rotating the portion; and a second groove portion for opening and closing only the display portion in a state where the rotation operation of the lid portion is stopped. The drive control means applies a predetermined drive voltage to the first and second motors when the display unit is opened from the storage position to the use position, and the guide pin is connected to the first groove portion. Before the transition to the second groove, the drive voltage applied to the second motor is controlled so as to gradually decrease.

  Hereinafter, the best embodiment of the present application will be described with reference to the accompanying drawings. In addition, embodiment described below is embodiment at the time of applying this application with respect to vehicle-mounted display apparatuses, such as a car navigation which integrated the audio, visual function, and the navigation function as a display apparatus, for example. Further, in the following description, the direction in which the display plate or the cover plate is opened is referred to as “open direction”, and the direction in which the display plate or the cover plate is closed is referred to as “closed direction”.

  FIG. 1 is a schematic view showing the inside of a vehicle on which the in-vehicle display device of one embodiment of the present application is mounted.

  As shown in FIG. 1, the in-vehicle display device 1 of the present embodiment as a display device is attached to an opening 2 a formed in a dashboard 2 of a vehicle. In FIG. 1, a steering wheel 3, a meter panel 4, a windshield 5, a rearview mirror 6, a shift knob 7, a left door 8, and a right door 9 are disposed around the in-vehicle display device 1.

  Here, the in-vehicle display device 1 of the present embodiment closes the cover when not in use and is completely stored in the same plane as the dashboard 2, while opening the cover when in use and the position where the display can be viewed. To protrude.

  2 is a perspective view showing an in-vehicle display device according to an embodiment of the present application, FIG. 3 is a perspective view showing a cover of the in-vehicle display device in FIG. 2, and FIG. 4 is a perspective view showing a case of the in-vehicle display device in FIG. 5 is a perspective view showing a use state in which a cover and a case are removed from the in-vehicle display device of FIG. 2, FIG. 6 is a right side view of FIG. 5, and FIG. 7 is a perspective view showing a storage state of FIG. 8 is a right side view of FIG. 7, and FIG. 9 is a plan view showing the arrangement of the drive motor, gears and the like of FIG. In the following description, the display side is defined as the front (front) side, the cover side is defined as the back (rear) side, and the direction in which the display and the cover open and protrudes is described as upward.

  As shown in FIGS. 2 to 5, the in-vehicle display device 1 of the present embodiment includes a device body 10, a synthetic resin cover 11 attached to the device body 10, and a synthetic resin housing the device body 10. The case 12 is roughly constituted.

  As shown in FIGS. 2 and 3, the cover 11 is formed so that the flange portion 11 a protrudes from the apparatus main body 10 long. The cover 11 can block the direct sunlight irradiated on the display by forming the flange portion 11a long.

  As shown in FIGS. 2 and 4, the case 12 has a plurality of openings 12 a formed on the front and side surfaces. Thereby, when the vehicle passenger collides with the case 12 due to an accident or the like, the case 12 can be easily crushed and the impact can be absorbed.

  As shown in FIGS. 5 to 8, the apparatus main body 10 is rotatably attached via a sheet metal chassis 21 as a base portion and a rotation shaft 22 provided on the chassis 21, and the display 23 is set to a storage position. A display plate 24 made of sheet metal as a display unit that can be opened and closed with respect to a use position, and a chassis 21 that is rotatably attached via a rotation shaft 25 that is parallel to the rotation shaft 22 of the display plate 24. A cover plate 26 made of sheet metal is provided as a cover for holding the cover 11 so that it can be opened and closed between the storage position and the use position.

  The display board 24 is formed in a substantially box shape and is mounted so that a display 23 made of an LCD (Liquid Crystal Display) or the like is accommodated therein, and guide pins 27 serving as cam followers protrude from the upper ends of both side surfaces at the use position. It is fixed.

  The lid plate 26 is connected to the display plate 24 through engagement means that can move relative to the display plate 24. The engaging means includes a guide groove 30 and a guide pin 27 that can move in the guide groove 30.

  As shown in FIG. 6, the guide groove 30 is formed in a guide plate 28 that is formed by bending the upper side surfaces of the lid plate 26. The guide groove 30 is formed in a straight line, and a linear portion 32 for opening and closing the cover plate 26 in cooperation with the opening and closing operation of the display plate 24, and the display in a state where the opening and closing operation of the cover plate 26 is stopped. A curved portion 33 for opening and closing only the plate 24 is continuously formed. Further, a locking portion 31 for locking the guide pin 27 in the guide groove 30 is formed at the front end portion of the bending portion 33 at the use position. Three locking grooves 31 a to 31 c including the front end in the longitudinal direction of the guide groove 30 are formed in the locking portion 31 at regular intervals. Thereby, the angle of the use position of the display 23 can be changed in three steps. The three locking grooves 31a to 31c are each formed into a tapered groove, thereby making it easy to guide the guide pin 27. The guide groove 30 functions as a long hole portion of the present application, and the guide pin 27 functions as an engagement pin of the present application.

  When the guide pin 27 is locked to the rear end of the guide groove 30 in the guide plate 28, the display plate 24 and the cover plate 26 are in the closed storage position as shown in FIGS. When the guide pin 27 is locked in the locking groove 31a which is the front end in the guide groove 30, the display plate 24 and the cover plate 26 are in a use position where they open and project as shown in FIGS. A triangular truss structure is formed together with the chassis 21.

  As shown in FIG. 5, the cover plate 26 is always urged in the closing direction by attaching torsion coil springs 33, 33 as urging means in the vicinity of the shaft support portion of the rotating shaft 25 provided in the chassis 21. Similarly, as shown in FIG. 9, torsion coil springs 34, 34 are attached to the display plate 24 in the vicinity of the shaft support portion of the rotating shaft 22, and the cover plate 26 and the display are displayed by these coil springs 33, 33, 34, 34. The plate 24 is always urged in the closing direction.

  Each of the display plate 24 and the cover plate 26 includes an angle sensor (not shown) for detecting the angle of the opened use position. Further, the display plate 24 and the lid plate 26 are opened by, for example, pressing an open switch (not shown) and closed by pressing a close switch (not shown).

  Furthermore, the display plate 24 and the cover plate 26 can adjust the angle of the use position, that is, the tilt angle in three stages by the guide pin 27 being locked in the three locking grooves 31a to 31c. In order to adjust the tilt angle, for example, by pushing a tilt switch (not shown), the guide pins 27 are sequentially switched so as to be locked in the three locking grooves 31a to 31c. In the present embodiment, the guide pin 27 is set to be locked in the locking groove 31a when the open switch is pressed. In order to operate in this way, for example, an angle detection signal of the display plate 24 and the cover plate 26 detected by the angle sensor is obtained by the control unit 100 described later, and the control unit 100 turns on the drive motors 41 and 61, Control off.

  Here, in this embodiment, when the switch for opening is pushed, the guide pin 27 is locked to the locking groove 31a which is the front end in the guide groove 30, but this is not restrictive. You may make it latch to 31b and can change suitably.

  Next, the drive part of the display board 24 is demonstrated. FIG. 10 is a layout view showing the drive unit of the display panel of the present embodiment.

  As shown in FIGS. 9 and 10, the drive unit 40 of the display board 24 has a drive motor 41 attached to the lower end of the display board 24, and the first shaft is connected to the output shaft of the drive motor 41. The gear 42a is fixed. The second helical gear 42b made of nylon meshing with the first helical gear 42a meshes with a pinion 44 using a metal sintered gear through a spur gear train 43 constituting a reduction gear train. Has been. The pinion 44 meshes with one rack member 45 fixed to the chassis 21. One spur gear train 43 meshes with one of connection gears 47, 47 attached in the vicinity of both ends of the connection shaft 46, and the other of the connection gears 47, 47 meshes with the transmission gear train 48. The transmission gear train 48 meshes with the other rack member 50 fixed to the chassis 21 via a pinion 49 using a metal sintered gear.

  The second helical gear 42 b is a two-stage gear integrated with one of the spur gear trains 43. The first helical gear 42a is made of, for example, polyacetal, and the second helical gear 42b is made of nylon as described above. In this way, quietness can be achieved by engaging gears of materials having different hardnesses. However, even when both the first helical gear 42a and the second helical gear 42b are made of nylon, it is possible to achieve calmness. In short, if at least one of the first helical gear 42a and the second helical gear 42b is made of nylon, quietness can be achieved.

  Here, as shown in FIGS. 5 and 7, two brackets 51a and 51b and 52a and 52b which are paired with each other are fixed to the lower end of the display plate 24. The rotation shafts of the spur gear train 43 and the pinion 44 are respectively attached to the brackets 51a and 51b, and these rotation shafts rotatably support the spur gear train 43 and the pinion 44, respectively. The rotation shafts of the transmission gear train 48 and the pinion 49 are respectively attached to the brackets 52a and 52b, and these rotation shafts support the transmission gear train 48 and the pinion 49 so as to be rotatable. The connecting shaft 46 is attached to the bracket 51a and the bracket 52b.

  Therefore, when the drive motor 41 is rotationally driven in the opening direction, the first helical gear 42a and the second helical gear 42b are rotated, and the rotation is decelerated via the spur gear train 43 and via the pinion 44. It moves relative to one rack member 45. At the same time, the connecting gears 47 and 47 are rotated, and the rotational force is moved with respect to the other rack member 50 by rotating the pinion 49 via the transmission gear train 48. Thereby, as shown in FIG.5 and FIG.6, it becomes the use position which the display board 24 opens and protrudes. On the other hand, when the drive motor 41 is rotationally driven in the closing direction, the first helical gear 42a, the second helical gear 42b, etc. rotate in the opposite direction to the above, and the display as shown in FIGS. The plate 24 is closed to the storage position. Note that the drive motor 41 of the present embodiment functions as the first motor of the present application.

  Next, the drive part of the cover plate 26 will be described. FIG. 11 is a layout view showing the drive unit of the lid plate of the present embodiment.

  As shown in FIGS. 9 and 11, the drive unit 60 of the lid plate 26 has a drive motor 61 attached to the upright wall 21 a of the chassis 21, and an output shaft of the drive motor 61 has a first screw. The gear 62a is fixed. The second helical gear 62b made of nylon that meshes with the first helical gear 62a is attached to the lower end of the cover plate 26 via a spur gear train 63 and a sintered gear 63a that constitute a reduction gear train. One sector gear 64 is engaged. Further, one spur gear train 63 meshes with one of connection gears 66 and 66 attached in the vicinity of both ends of the connection shaft 65, and the other of the connection gears 66 and 66 has a transmission gear train 67 and a sintered gear 67a. Via the other sector gear 68.

  The second helical gear 62b is a two-stage gear integrated with one of the spur gear trains 63, like the second helical gear 42b. The first helical gear 62a is made of, for example, polyacetal, and the second helical gear 62b is made of nylon as described above. Further, both the first helical gear 62a and the second helical gear 62b may be made of nylon. In short, as with the first helical gear 42a and the second helical gear 42b, quietness can be achieved if at least one of the first helical gear 62a and the second helical gear 62b is made of nylon. It will be.

  Further, a rotating shaft of a spur gear train 63 is attached to the standing walls 21a and 21b of the chassis 21 as shown in FIG. A rotating shaft of a sintered gear 63a (shown in FIG. 11) is attached to a standing wall (not shown) of the chassis 21. These rotary shafts rotatably support the spur gear train 63 and the gear 63a. As shown in FIG. 9, upright walls 21c and 21d are fixed to the chassis 21, and a rotating shaft of a transmission gear train 67 and a sintered gear 67a (shown in FIG. 11) is attached to the upright walls 21c and 21d. These rotation shafts rotatably support the transmission gear train 67 and the sintered gear 67a. The connecting shaft 65 is attached to the standing walls 21a and 21d.

  Therefore, when the drive motor 61 is rotationally driven in the opening direction, the first helical gear 62a and the second helical gear 62b are rotationally driven, the rotational speed thereof is reduced via the spur gear train 63, and the rotational force Moves one sector gear 64 attached to the lower end of the cover plate 26 in one direction. At the same time, the connecting gears 66 and 66 rotate, and the rotational force moves the other sector gear 68 in one direction via the transmission gear train 67. Thereby, as shown in FIG.5 and FIG.6, the cover plate 26 opens and it becomes a use position. On the other hand, when the drive motor 61 is rotationally driven in the closing direction, the first helical gear 62a, the second helical gear 62b, etc. rotate in the opposite direction to the above, and as shown in FIGS. The plate 26 is closed to the storage position. In addition, the drive motor 61 of this embodiment functions as the 2nd motor of this application.

  Further, the drive motors 41 and 61 that function as drive units for the display plate 24 and the cover plate 26 are driven and controlled by the control unit 100 as shown in FIG. FIG. 12 is an example of a system configuration diagram for driving the display plate and the cover plate in the display device.

  As shown in FIG. 12, the display device 1 includes a control unit 100. Although not shown, the control unit 100 includes a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), and the like, and the CPU executes various programs stored in the ROM, for example. The display device 1 as a whole is controlled and functions as drive control means of the present application. Specifically, the control unit 100 drives and opens the display board 24 based on an instruction to open and close the display board 24 by the user (hereinafter referred to as “display board drive motor 41”), and A motor driver for rotationally driving a drive motor 61 for opening and closing the lid plate 26 (hereinafter referred to as “lid plate drive motor 61”) is controlled. More specifically, the control unit 100 monitors the information detected by a plurality of detection units 101 (for example, angle sensors) in the opening / closing operation of the display plate 24 and the cover plate 26, and controls the drive motors 41 and 61. The rotation direction and rotation speed are sequentially driven and controlled. Also, predetermined information is displayed on the display 105 under the control of the display microcomputer 103 based on the opening operation of the display board 24.

  Hereinafter, a control operation for opening and closing the display plate 24 and the cover plate 26 will be described with the control unit 100 as a main component.

  First, the operation when opening the display plate 24 and the cover plate 26 will be described with reference to FIG. FIG. 13 is a timing chart showing a control state of the display plate drive motor and the cover plate drive motor when the display plate is opened, and an operation state of the display plate and the cover plate.

  13 shows a control example of a signal between two terminals for applying a driving voltage to the cover plate drive motor, and B region shows a control example of the applied voltage to the cover plate drive motor. Indicates. A region C shows an example of control of a signal between two terminals for applying a driving voltage to the display panel drive motor, and a region D shows an example of control of the applied voltage to the display plate drive motor. In the A and C regions, the vertical axis indicates the ON / OFF state of the signal, and the horizontal axis indicates the time axis. In the B and D regions, the vertical axis represents the applied voltage, and the horizontal axis represents the time axis. An E area indicates an operation angle in the opening / closing operation of the display plate and the cover plate. The vertical axis in the E region indicates the operating angle when the storage position is 0 °, and the horizontal axis indicates the time axis.

  In the following description, a control method for rotating the drive motors 41 and 61 to drive the display plate 24 and the cover plate 26 in the closing direction is referred to as “close control”, and the display plate 24 and the cover plate 26 are opened. A control method in which the drive motors 41 and 61 are driven to rotate in the direction is referred to as “open control”. A control method for short-circuiting two terminals for supplying voltage to the drive motors 41 and 61 is referred to as “brake control”. Further, a control method for performing brake control at predetermined intervals during the close control is referred to as “pumping control”.

  As shown in FIG. 13, first, the control unit 100 controls the display plate drive motor 41 and the cover plate drive motor 61 to be closed at the storage position (see FIG. 8) where the display plate 24 and the cover plate 26 are closed. To do. (Refer to state “◯ 1”). In this way, the cover 11 is driven in the closing direction to position the cover 11 in the case 12, while the display plate 24 is driven in the closing direction to guide the rear end surface in the guide groove 30 of the lid plate 26. The pin 27 is abutted and positioned. By continuing to drive the cover plate 26 and the display plate 24 in the closing direction, the cover 11 is pressed against the case 12, and the guide pin 27 is pressed against the lower end surface in the guide groove 30, so that the positioned state is maintained. Thus, it is possible to suppress the rattling caused by the vibration of the vehicle.

  Next, when opening the display plate 24 and the cover plate 26 so that the display plate 24 and the cover plate 26 are moved from the storage position (see FIG. 8) to the use position (see FIG. 6), the control unit 100 The drive motor 41 and the cover plate drive motor 61 are brake controlled. (Refer to state “状態 2”). Thus, when the drive directions of the display plate drive motor 41 and the lid plate drive motor 61 are reversed, both the drive motors 41 and 61 are once brake-controlled. As a result, the load on the motor can be reduced, and abnormal noise generated from the motor can be prevented by sudden reverse rotation control. The display plate 24 and the cover plate 26 can be operated (opened) smoothly.

  Next, the control unit 100 controls the voltage applied to the terminals for driving the display plate drive motor 41 and the cover plate drive motor 61 to open-control both the drive motors 41 and 61 (state “ ○ See 3 ”). At that time, both the display plate drive motor 41 and the cover plate drive motor 61 are gradually approached (increase gradually) as shown in Z of FIG. The voltage applied to the drive motors 41 and 61 is controlled. Thereby, generation | occurrence | production of unusual noises, such as a contact sound of the guide groove 30 and the guide pin 27 by rapid operation | movement, is prevented, and the display board 24 and the cover board 26 can be opened smoothly.

  Here, the operation at the boundary (connecting portion) (hereinafter referred to as “inflection point”) where the display plate 24 and the cover plate 26 are opened and the guide pin 27 moves from the straight portion 32 to the curved portion 33 will be described. While the guide pin 27 moves along the linear portion 32, the display plate 24 and the lid plate 26 are both opened, and when the guide pin 27 moves along the curved portion 33 after the inflection point, the lid plate 26 The operation of stopping and opening only the display panel 24 is continued. In order to smoothly stop the cover plate 26 at the inflection point in this way, as shown in Y of FIG. 13, the control unit 100 allows the cover plate before the guide pin 27 reaches the inflection point. The voltage applied to the drive motor 61 is started to be lowered, and then gradually lowered until the inflection point is passed (see state “◯ 3”). As a result, the lid plate 26 can be stopped smoothly, and abnormal noise such as contact sound between the guide groove 30 and the guide pin 27 at the inflection point can be prevented. Further, since the guide pin 27 can be moved in sliding contact with the inner end face of the guide groove 30, the generation of abnormal noise such as rattling noise can be prevented and the display plate 24 and the cover plate 26 can be operated smoothly. .

  Further, when the guide pin 27 moves through the inflection point and moves the bending portion 33, the cover plate 26 keeps the fully opened state and operates so that the opening angle of only the display plate 24 increases (state “◯”). 4 "). At this time, since the lid plate drive motor 61 is controlled to open, the guide pin 27 operates by sliding on the lower end surface of the guide groove 30. In this way, the drive motors 41 and 61 are both open controlled until the display plate 24 is fully opened (use position).

  Next, the control unit 100 performs brake control on the display plate drive motor 41 and the lid plate drive motor 61. (Refer to state “◯ 5”). Thereby, the cover plate 26 is moved in the closing direction by its own weight, and the guide pin 27 is locked in the predetermined locking groove 31a. In addition, since the display board 24 will be in the state near perpendicular | vertical in a use position, it can be independent by brake control, without moving to a closing direction with dead weight.

  Next, in the use position, the control unit 100 performs the close control on the cover plate drive motor 61 while keeping the brake control on the display plate drive motor 41 (refer to the state “◯ 6”). As a result, the inner end face of the guide groove 30 is pressed against the guide pin 27 and a load is applied, and the upper portions of the display plate 24 and the cover plate 26 are fixed, and the display plate 24 and the cover plate 26 due to vehicle vibrations or the like. Can be prevented.

  Next, the operation when closing the display plate 24 and the cover plate 26 will be described.

  First, in order to suppress the occurrence of mechanical abnormal noise such as contact noise between the guide pin 27 and the guide groove 30 in the operation of closing the display plate 24 and the cover plate 26, in this embodiment, either the upper or lower side of the guide groove 30. For the display plate and the lid, the guide pin 27 is pressed against one end face to apply a load, and the guide pin 27 is moved along one of the upper and lower end faces to close the display board 24 and the cover board 26. The plate drive motors 41 and 61 are controlled.

  Further, in the operation of closing the display plate 24 and the cover plate 26, in particular, the display is performed in the direction of closing by its own weight separately from the operations of the display plate and cover plate drive motors 41 and 61 after the guide pin 27 exceeds the inflection point. Since the plate 24 and the cover plate 26 are operated, when the display plate 24 and the cover plate 26 are slowly closed, the display plate and the cover plate drive motors 41 and 61 can be operated smoothly only by closing control. Is difficult. Thus, in the present embodiment, the display plate and cover plate drive motors 41 and 61 are controlled using pumping control to control the operation of the display plate 24 and the cover plate 26 in the closing direction.

  Further, in the operation of closing the display plate 24 and the cover plate 26, in this embodiment, in order to suppress the generation of mechanical noise that occurs when the guide pin 27 passes near the inflection point, Before and after the inflection point arrives, the lid plate drive motor 61 is brake controlled while the display plate drive motor 41 is pumping controlled.

  By controlling the respective drive motors 41 and 61 in this way, in this embodiment, the display plate 24 and the cover plate 26 can be closed slowly and smoothly, and the texture can be easily improved. .

  Hereinafter, a specific operation of closing the display plate 24 and the cover plate 26 according to the present embodiment will be described with reference to FIG. FIG. 14 is a timing chart showing a control state of the display plate drive motor and the cover plate drive motor when the display plate is closed, and an operation state of the display plate and the cover plate.

  14 shows a control example of a signal between two terminals for applying a drive voltage to the cover plate drive motor, and B region shows a control example of the applied voltage to the cover plate drive motor. Indicates. A region C shows an example of control of a signal between two terminals for applying a driving voltage to the display panel drive motor, and a region D shows an example of control of the applied voltage to the display plate drive motor. In the A and C regions, the vertical axis indicates the ON / OFF state of the signal, and the horizontal axis indicates the time axis. In the B and D regions, the vertical axis represents the applied voltage, and the horizontal axis represents the time axis. An E area indicates an operation angle in the opening / closing operation of the display plate and the cover plate. The vertical axis in the E region indicates the operating angle when the storage position is 0 °, and the horizontal axis indicates the time axis.

  First, the outline | summary of operation | movement of the display board 24 and the cover board 26 is demonstrated.

  As shown in FIG. 14, for example, the display plate 24 is held in an open state of about 41 degrees with respect to the storage position, and after a predetermined time elapses, the display plate 24 and the lid plate 26 are closed. It is gradually closed at a speed of 1. The display board 24 is gradually closed at a second speed that is first slower than the speed from a short time before the guide pin 27 reaches the inflection point, and a short time before the display board 24 is completely closed. It is gradually closed at a third speed that is slower than the second speed.

  On the other hand, the lid plate 26 is held in an opened state of about 26 degrees with respect to the storage position, and is lifted about twice and held in an opened state as the operation of closing the display plate 24 and the lid plate 26 is started. The Then, after the guide pin 27 exceeds the inflection point, the cover plate 26 is gradually closed at the first speed, and a second lower than the first speed slightly before the cover plate 26 is completely closed. It is gradually closed at a speed of.

  Next, the control operation of the display plate and cover plate drive motors 41 and 61 for operating the display plate 24 and the cover plate 26 will be described.

  As shown in FIG. 14, first, the control unit 100 controls the cover plate drive motor 61 to be closed at the use position (see FIG. 6) where the display plate 24 and the cover plate 26 are opened, and also the display plate drive motor. 41 is brake-controlled (refer to state “◯ 1”). As a result, the inner end face of the guide groove 30 is pressed against the guide pin 27 and a load is applied, and the upper portions of the display plate 24 and the cover plate 26 are fixed, and the display plate 24 and the cover plate 26 due to vehicle vibrations or the like. Can be prevented.

  Next, the control unit 100 loads the motor when closing the display plate 24 and the cover plate 26 so that the display plate 24 and the cover plate 26 are moved from the use position (see FIG. 6) to the storage position (see FIG. 8). In consideration of the above, the lid plate drive motor 61 is brake-controlled while the display plate drive motor 41 is brake-controlled (see state ““ 2 ”).

  Then, in order to smoothly release the guide pin 27 from the locking grooves 31a to 31c without causing abnormal noise, the lid plate drive motor 61 is subjected to open control while the display plate drive motor 41 is brake-controlled ( (Refer to state “○ 3”). Further, at that time, as shown by X in FIG. 14, the lid plate drive motor 61 is applied to the lid plate drive motor 61 so as to gradually approach (increase gradually) a predetermined voltage. Voltage is controlled. Thereby, generation | occurrence | production of unusual noises, such as a contact sound with the locking grooves 31a-31c and the guide pin 27 by rapid operation | movement, can be prevented, and the guide pin 27 can be released from the locking grooves 31a-31c.

  Next, the control unit 100 performs pumping control of the display plate drive motor 41 while keeping the lid plate drive motor 61 open. Specifically, the controller 100 controls the lid plate drive motor 61 to be opened. On the other hand, the control unit 100 controls the display plate drive motor 41 to be closed during the open control, and performs the brake control at a predetermined interval during the close control (see state “◯ 4”). As a result, when the guide pin 27 moves along the curved portion 33, the display plate 24 can be operated slowly and smoothly. Therefore, the texture seen from the user can be easily enhanced.

  Next, when the display plate 24 is gradually closed and the guide pin 27 reaches an inflection point where the curved portion 33 moves to the straight portion 32, an abnormal noise due to rattling between the guide groove 30 and the guide pin 27 is generated. As shown in FIG. 14, the control unit 100 performs the pumping control of the display plate drive motor 41 before and after the guide pin 27 reaches the inflection point. Brake control is performed on the cover plate drive motor 61 (see state “◯ 5”). As a result, the lid plate 26 is slowly closed by its own weight. Accordingly, the display plate 24 and the cover plate 26 are moved slowly and smoothly before and after the guide pin 27 moves at the inflection point while preventing the generation of abnormal noise such as contact sound between the guide pin 27 and the guide groove 30. Can be operated. Therefore, the texture seen from the user can be easily enhanced.

  Next, while the guide pin 27 reaches the inflection point and moves to the retracted position, the display plate drive motor 41 and the cover plate drive motor 61 are controlled to be pumped (states ““ 6 ”to“ ○ 8 ”). reference).

  If the operation speeds of the display plate 24 and the cover plate 26 by the rotation control of the display plate drive motor 41 and the cover plate drive motor 61 are substantially the same, the ratio of the brake control performed during the close control of the display plate 24 is set. The closing speed of the cover plate 26 can be easily made slower than the closing speed of the display plate 24 by making it smaller than the ratio of the brake control performed during the closing control of the cover plate 26. Similarly, the ratio of the brake control performed during the closing control of the cover plate 26 may be larger than the ratio of the brake control performed during the closing control of the display board 24. As a result, the operations of the display plate 24 and the cover plate 26 are restricted, and the cover plate 26 operates as if the display plate 24 is closed while being suspended.

  Here, regarding the movement of the display plate 24 and the cover plate 26 from the use position to the storage position, the display plate 24 and the cover plate 26 have an angle closer to the horizontal in the storage position than in the use position. As the display plate 24 and the cover plate 26 become horizontal, the rotational moment due to their own weights about the respective rotation shafts 22 and 25 increases, so that each of the display plate 24 and the cover plate 26 moves to the storage position. It becomes easy and the speed naturally increases, and in the operation of closing the display plate 24 and the cover plate 26, the operation speed is not constant and the appearance is poor. Further, when the operation of the display plate 24 and the cover plate 26 suddenly stops when they reach the storage position, a collision sound between members is generated.

  Therefore, in the present embodiment, in the pumping control of the display plate 24 and the cover plate 26, the ratio of the brake control performed during the close control is gradually increased while the display plate 24 and the cover plate 26 are moved from the use position to the storage position. Immediately before the position 26 reaches the storage position, the ratio of the brake control performed during the close control is further increased. By operating the display plate 24 and the cover plate 26 in this way, the operation speed of the display plate 24 and the cover plate 26 from the use position to the storage position does not increase, and the operation speed can be kept substantially constant, and the storage position Immediately before reaching the state (refer to the state “” 8 ”), the display plate 24 and the cover plate 26 are operated while the operation speeds of the display plate 24 and the cover plate 26 are further lowered to suppress the collision sound between the members. Can be stopped smoothly.

  The operation speed of the display plate 24 and the cover plate 26 due to its own weight varies depending on the weight of the display plate 24 and the cover plate 26. Therefore, the ratio of the brake control performed during the closing control is appropriately determined in consideration of the weight and the like. Is done.

  When the display plate 24 and the cover plate 26 reach the retracted position from the use position, the control unit 100 performs brake control on the display plate drive motor 41 and the cover plate drive motor 61 (see state “◯ 9”). Thereafter, the display plate drive motor 41 and the cover plate drive motor 61 are controlled to be closed (see state ““ 10 ”).

  The cover 11 is thus positioned in the case 12 by driving the lid plate 26 in the closing direction, while being guided to the lower end surface in the guide groove 30 of the lid plate 26 by driving the display plate 24 in the closing direction. The pin 27 is abutted and positioned. By continuing to drive the cover plate 26 and the display plate 24 in the closing direction, the cover 11 is pressed against the case 12, and the guide pin 27 is pressed against the lower end surface in the guide groove 30, so that the positioned state is maintained. Thus, it is possible to suppress the rattling caused by the vibration of the vehicle.

  Next, the operation of the in-vehicle display device 1 of this embodiment will be described.

  First, the in-vehicle display device 1 according to the present embodiment includes a display plate 24 that holds the display 23 and a cover plate that holds the cover 11 shown in FIG. 2 in the storage position when not in use as shown in FIGS. 26 is in a closed state, and the case 12, that is, the cover 11 is substantially flush with the dashboard 2 and is completely stored. At this time, the guide pin 27 is locked to the rear end of the guide groove 30 in the guide plate 28. Further, the display plate 24 and the cover plate 26 are urged by the torsion coil springs 33 and 33 and the torsion coil springs 34 and 34, respectively, in the normally closed direction, that is, the direction for holding the storage position. Further, both the display plate drive motor 41 and the lid plate drive motor 61 are driven in the closing direction by the control unit 100. Thereby, since the display plate 24 and the cover plate 26 are held in a state of being pressed against the case side, even if vibrations occur in the vehicle, the display plate 24 and the cover plate 26 can be prevented from rattling.

  Next, in order to open the in-vehicle display device 1 of the present embodiment to the use position, the control unit 100 activates the drive motors 41 and 61 of the display plate 24 and the cover plate 26 based on a pressing operation of an opening switch (not shown). Open control. At this time, the control unit 100 performs brake control on the display plate drive motor 41 and the cover plate drive motor 61, and then performs open control on the display plate drive motor 41 and the cover plate drive motor 61.

  When the display plate drive motor 41 is controlled to open, the first helical gear 42a and the second helical gear 42b rotate as shown in FIGS. It is decelerated and moves relative to one rack member 45 via the pinion 44. At the same time, the connecting gears 47 and 47 are rotated, and the rotational force is moved with respect to the other rack member 50 by rotating the pinion 49 via the transmission gear train 48. On the other hand, when the lid plate drive motor 61 is controlled to open, as shown in FIGS. 9 and 11, the first helical gear 62a and the second helical gear 62b rotate, and the rotational speed thereof is the spur gear train 63. , And the rotational force moves one sector gear 64 attached to the lower end of the cover plate 26 in one direction. At the same time, the connecting gears 66 and 66 rotate, and the rotational force moves the other sector gear 68 in one direction via the transmission gear train 67.

  At the start of the open control, the control unit 100 controls the voltage applied to the display plate drive motor 41 and the cover plate drive motor 61 so as to gradually approach a predetermined voltage. The voltage applied to the cover plate drive motor 61 is gradually lowered before the guide pin 27 passes through the straight portion 32 of the guide groove 30 and the guide pin 27 reaches the inflection point of the guide groove 30.

  As a result, as shown in FIG. 15, the guide pin 27 that protrudes and is fixed to the upper end of both side surfaces of the display plate 24 moves from the rear end side of the guide groove 30 of the lid plate 26 through the linear portion 32 and the locking portion 31. It is locked in the locking groove 31a at the front end. As a result, as shown in FIGS. 5 and 6, the display plate 24 and the cover plate 26 are opened to the use position, and the display 23 can be projected to a position where it can be visually recognized.

  At this time, the display plate 24 and the cover plate 26 are gradually biased against the biasing force while being biased in the closing direction by the torsion coil springs 33 and 33 and the torsion coil springs 34 and 34, respectively. The opening operation can be smoothly performed without rattling, improving the reliability of the operation and obtaining a high-class feeling. The guide pins 27 protrude and are fixed to the upper ends of both side surfaces of the display plate 24, and the guide plates 28 are formed on both upper side surfaces of the lid plate 26. The guide pins 27 move to these guide plates 28, respectively. Since the guide groove 30 is formed, the guide pin 27 moves in the guide groove 30 at the upper end portions of the display plate 24 and the cover plate 26, respectively. For this reason, since the front end portions of the members that rotate about the rotation shafts 22 and 25 are regulated with respect to each other, the opening operation can be smoothly performed without rattling even while the vehicle is running.

  Further, in the use position where the display plate 24 and the cover plate 26 are opened, the control unit 100 performs the close control on the cover plate drive motor 61 and the brake control on the display drive motor 41. As a result, the display plate 24 and the cover plate 26, together with the torsion coil springs 33 and 33 and the torsion coil springs 34 and 34, can always be locked so that the guide pin 27 is bitten into the locking groove 31a. Therefore, the vibration of the display 23 can be prevented in advance, and the display 23 can be easily viewed.

  Further, in order to close the in-vehicle display device 1 of the present embodiment from the use position to the storage position, the control unit 100 drives each of the display plate 24 and the cover plate 26 based on a pressing operation of a closing switch (not shown). 41 and 61 are controlled.

  First, the display plate drive motor 41 is brake-controlled and the lid plate drive motor 61 is open-controlled. Thereby, the guide pin 27 is released from the locking groove 31a.

  Next, the display plate drive motor 41 is pumped in the closing direction while maintaining the open control of the cover plate drive motor 61. When the guide pin 27 passes through the bending portion 33 and near the inflection point, the lid plate drive motor 61 is brake-controlled while maintaining the pumping control of the display plate drive motor 41. Further, after the guide pin 27 passes the inflection point, the display plate drive motor 41 and the cover plate drive motor 61 are pumped in the closing direction.

  Here, when the display panel drive motor 41 is driven in the closing direction, as shown in FIGS. 9 and 10, the first helical gear 42a and the second helical gear 42b are reversely rotated, and the rotation of the first helical gear 42a and the second helical gear 42b is reversed. The gear is decelerated via the spur gear train 43 and moves relative to one rack member 45 via the pinion 44. At the same time, the connecting gears 47 and 47 are rotated in the reverse direction, and the rotational force moves the other rack member 50 by rotating the pinion 49 in the reverse direction via the transmission gear train 48. On the other hand, when the cover plate drive motor 61 is driven in the closing direction, as shown in FIGS. 9 and 11, the first helical gear 62a and the second helical gear 62b are rotated in reverse, and the rotation speed is The speed is reduced through the spur gear train 63, and the rotational force thereof moves one sector gear 64 attached to the lower end of the cover plate 26 in the other direction. At the same time, the connecting gears 66 and 66 rotate in reverse, and the rotational force moves the other sector gear 68 in the other direction via the transmission gear train 67.

  By operating the display plate and cover plate drive motor in this way, the bending portion 33 is moved from the position where the guide pin 27 is locked to the locking groove 31a formed at the front end of the guide groove 30 as shown in FIG. It moves through the straight part 32 and is locked near the rear end of the guide groove 30. As a result, as shown in FIGS. 7 and 8, the display plate 24 and the cover plate 26 are closed to the storage position. In this storage position, the display plate 24 that holds the display 23 and the lid plate 26 that holds the cover 11 shown in FIG. 2 are closed as described above, and the inside of the case 12, that is, the cover 11 is substantially the same as the dashboard 2. It becomes a plane and is completely stored.

  Next, the case where the inclination angle of the display plate 24 is changed in the in-vehicle display device 1 of the present embodiment will be described. 16 is a perspective view showing a state in which the inclination angle of the display panel of the present embodiment is changed, and FIG. 17 is a side view of FIG.

  First, as shown in FIGS. 16 and 17, the guide pin 27 of the display plate 24 is guided as shown in FIGS. 16 and 17 from the position where the guide pin 27 is locked in the locking groove 31a of the guide groove 30 of the lid plate 26 as shown in FIGS. When the inclination angle of the display plate 24 is changed by being engaged with the engagement groove 31b of the groove 30, the guide pin 27 is engaged with the engagement groove 31b from the engagement groove 31a by pressing the tilt switch. It switches as follows.

  That is, when the tilt switch is pressed, the control unit 100 obtains, for example, the angle detection signals of the display plate 24 and the cover plate 26 detected by the angle sensor, and the drive motors 41 and 61 are turned on based on the angle detection signals. The guide pin 27 is moved from the locking groove 31a to the locking groove 31b by turning off, and the inclination angle of the display plate 24 is changed.

  Next, when the tilt switch is pressed again, the control unit 100 obtains the angle detection signals of the display plate 24 and the lid plate 26 detected by the angle sensor, and based on the angle detection signals, the control motors 100 and 61 The guide pin 27 is moved from the locking groove 31b to the locking groove 31c by controlling on and off to change the inclination angle of the display plate 24. Note that this switching order is merely an example and may be reversed.

  As described above, in the present embodiment, the inclination angle of the display 23 can be changed by changing the inclination angle of the display plate 24. Therefore, the display 23 can be adjusted to an angle that is always easy for the passenger to see.

  Further, according to the present embodiment, the chassis 21 is attached to the chassis 21 so as to be rotatable via the rotation shaft 22, and holds the display 23 so that it can be opened and closed between the storage position and the use position. A lid plate 26 that is rotatably attached via a rotation shaft 25 parallel to the rotation shaft 22 of the display plate 24 and holds the cover 11 so as to be openable and closable between a storage position and a use position, and a guide groove 30 When the guide pin 27 is locked in the locking groove 31a at the front end of the frame, the display plate 24 and the cover plate 26 are in an open use position, and the truss structure is formed together with the chassis 21, thereby increasing the structural strength. In addition to being robust, it is less susceptible to vibration during vehicle travel, and the display 23 can be maintained in an easily viewable state.

  Further, according to the present embodiment, in the use position where the display plate 24 and the cover plate 26 are opened and protruded, the display plate 24 and the torsion coil springs 33 and 33 and the torsion coil springs 34 and 34 of the cover plate 26 are used. The 24 guide pins 27 are locked so as to bite into the locking grooves 31a to 31c at the front end of the guide groove 30. In addition to the above, the structural strength is further increased, and further robustness can be achieved. Thus, the display 23 can be maintained in an easily viewable state.

  The present application is not limited to the above embodiment, and various modifications can be made. For example, in the above-described embodiment, the guide pins 27 protrude from the upper ends of both side surfaces of the display plate 24 and the guide plates 28 are formed on both upper side surfaces of the cover plate 26. However, the present invention is not limited to this. While providing the guide plate 28, the guide pin 27 may be attached to the lid plate 26.

  In the present embodiment, the display plate drive motor 41 and the cover plate drive motor 61 are driven and controlled so that the display plate 24 and the cover plate 26 are stably fixed without rattling. Considering that it is necessary to change the voltage applied to the display plate drive motor 41 and the cover plate drive motor 61 according to the vibration state of the vehicle, the control unit detects the vehicle tilt angle, the moving speed, or the vibration. The voltage applied to the first motor or the second motor may be variably controlled based on the detection value detected by the detection unit.

  Further, in the present embodiment, the display device having a structure in which the display plate 24 and the lid plate 26 are cooperatively controlled to be opened and closed is an object. However, the display device is provided with a display plate that is rotatably attached to a base portion via a shaft. It can also be applied to a portable display device.

  Further, in the present embodiment, as shown in FIG. 14, the pumping control is performed by performing the brake control at predetermined intervals during the closing control, but the display plate 24 and the cover plate 26 having structures having different sizes and weights. Is used to perform brake control at predetermined intervals during release control (close operation by its own weight) for opening the two terminals for supplying voltage to the drive motors 41 and 61 for the display plate or the lid plate. It is also possible to perform control similar to pumping control.

  Further, in the present embodiment, in the use position, the display plate drive motor 41 is brake controlled and the lid plate drive motor 61 is closed to improve the earthquake resistance, but in order to further improve the earthquake resistance, Both drive motors 41 and 61 may be closed. Alternatively, the lid plate drive motor 61 may be brake controlled and the display plate drive motor may be closed.

  In the present embodiment, the cover plate drive motor 61 and the display plate drive motor 41 are closed in the retracted position. However, when the seismic resistance is not so required, either one of the drives is driven. Only the motor may be closed and the other drive motor may be brake controlled.

  Moreover, although the said embodiment demonstrated the example which applied this application to the vehicle-mounted display apparatus, it is not limited to this, The display board 24 and the cover board 26 are comprised so that opening and closing is possible between a storing position and a use position. Any electronic device can be applied as long as it is.

It is the schematic which shows the vehicle interior by which the vehicle-mounted display apparatus of one Embodiment of this application is mounted. It is a perspective view which shows the vehicle-mounted display apparatus of one Embodiment of this application. It is a perspective view which shows the cover of the vehicle-mounted display apparatus of FIG. It is a perspective view which shows the case of the vehicle-mounted display apparatus of FIG. It is a perspective view which shows the use condition which removed the cover and the case from the vehicle-mounted display apparatus of FIG. FIG. 6 is a right side view of FIG. 5. FIG. 6 is a perspective view showing the storage state of FIG. 5. FIG. 8 is a right side view of FIG. 7. FIG. 8 is a plan view showing an arrangement of drive motors, gears, and the like in FIG. 7. It is an arrangement view showing a drive part of a display board of this embodiment. It is an arrangement drawing showing a drive part of a lid plate of this embodiment. It is an example of the system block diagram for driving a display board and a cover board in a display apparatus. It is a timing chart which shows the control state of the drive motor for display boards and the drive motor for lid boards when opening a display board, and the operation state of a display board and a lid plate. It is a timing chart which shows the control state of the drive motor for display boards and the drive motor for lid plates when a display board is closed, and the operation state of a display board and a lid plate. It is a side view which shows the open / close state of the display board of this embodiment, and a cover board. It is a perspective view which shows the state which changed the inclination angle of the display board of this embodiment. FIG. 17 is a side view of FIG. 16.

Explanation of symbols

1: Vehicle display device 2: Dashboard 10: Device main body 11: Cover 12: Case 21: Chassis 22: Rotating shaft 23: Display 24: Display plate 25: Rotating shaft 26: Cover plate 27: Guide pin 28: Guide plate 30: Guide groove 31: Locking portion 31a, 31b, 31c: Locking groove 40: Drive portion 41: Display plate drive motor 60: Drive portion 61: Cover plate drive motor

Claims (2)

The base,
A display unit rotatably attached via a first shaft provided at one end of the base;
A first motor for opening and closing the display unit between a storage position and a use position;
One end is rotatably attached via a second shaft provided at the other end of the base portion, and the other end is attached to the display portion via engagement means movable relative to the display portion. A connected lid,
A second motor for rotating the lid,
Drive control means for driving and controlling the first and second motors;
A display device comprising:
The engaging means includes
An elongated hole provided in one of the lid and the display, and an engagement pin provided in the other of the lid and the display so as to be movable in the elongated hole,
The elongated hole portion opens and closes only the display portion in a state in which the lid portion is stopped and the first groove portion that rotates the lid portion in cooperation with the opening and closing operation of the display portion is stopped. A second groove to be operated,
The drive control means applies a predetermined drive voltage to the first and second motors when the display unit is opened from the storage position to the use position, and the guide pin is connected to the first groove from the first groove. The display device is controlled so as to gradually lower the drive voltage applied to the second motor before shifting to the second groove. The base,
A display unit rotatably attached via a first shaft provided at one end of the base;
A first motor for opening and closing the display unit between a storage position and a use position;
One end is rotatably attached via a second shaft provided at the other end of the base portion, and the other end is attached to the display portion via engagement means movable relative to the display portion. A connected lid,
A second motor for rotating the lid,
Drive control means for driving and controlling the first and second motors;
Comprising
The engaging means includes
An elongated hole provided in one of the lid and the display, and an engagement pin provided in the other of the lid and the display so as to be movable in the elongated hole,
The elongated hole portion opens and closes only the display portion in a state in which the lid portion is stopped and the first groove portion that rotates the lid portion in cooperation with the opening and closing operation of the display portion is stopped. A drive control method in a display device comprising a second groove to be operated,
The drive control means applies a predetermined drive voltage to the first and second motors when the display unit is opened from the storage position to the use position, and the guide pin is connected to the first groove from the first groove. A drive control method comprising: controlling the drive voltage applied to the second motor to be gradually lowered before shifting to the second groove.

Images