JP2015093570A - Display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To compactly provide a display device which has multiple display boards (display parts).SOLUTION: An on-vehicle audiovisual device 10 includes: one monitor 12R and the other monitor 12L; a base member 13 for supporting the monitor 12R and the other monitor 12L; a motor 20 for moving the monitor 12R and the other monitor 12L; and a conversion mechanism 35 for converting drive force of the motor 20 to force that moves the monitor 12R and the other monitor 12L in a sliding manner on the base member 13, and causing the slide movement. The monitor 12R and the other monitor 12L move in the sliding manner via the conversion mechanism 35 from a state of being mutually superposed and closed to be opened sideways and aligned.

Description

  The present invention relates to a display device.

  2. Description of the Related Art Conventionally, a display device that displays information on a single display board is known (see, for example, Patent Document 1).

JP 2007-237906 A

By the way, in the conventional display device, when it is desired to increase the amount of information to be displayed, it is conceivable to add a display plate and use a plurality of display plates. However, when the number of display boards is increased, there is a problem that the installation space is increased by the increase of the display boards, and the display boards become an obstacle when the display device is not used.
The present invention has been made in view of the above-described circumstances, and an object of the present invention is to enable a compact display device provided with a plurality of display boards (display units).

  To achieve the above object, the present invention provides a plurality of display boards, a base member that supports the display boards, a motor that moves the plurality of display boards, and a driving force of the motors. A plurality of display plates that are slid and moved sideways through the conversion mechanism from a state of being overlapped and closed. Provided is a display device characterized by being opened and arranged.

Further, in the above-described configuration, a box-shaped housing that accommodates the plurality of display plates that are overlapped and closed together with the base member is provided, and when the plurality of display plates display information, the housing It is good also as a structure which is pulled out from the said base member integrally and is stood up.
The plurality of display boards may be configured such that the display surfaces thereof are substantially flush with each other when opened at the end of the slide position of the conversion mechanism.

  Further, the display plates are provided in a pair, and the conversion mechanism includes one transport member coupled to one display plate of the pair of display plates and the other display plate of the pair of display plates. And a cam gear disposed on the back side of the pair of display plates and connected to the one conveyance member and the other conveyance member, and the cam gear is driven by the motor. The cam gear is formed in a disk shape and includes a pair of protrusions on the plate surface, and the one conveying member includes one cam groove into which one of the protrusions is fitted, The other conveying member includes the other cam groove into which the other of the protrusions fits, and the pair of display plates is moved by the pair of protrusions moving in the circumferential direction by the rotation of the cam gear. Through the groove and the other cam groove. It may be configured to be allowed to id moved.

  Furthermore, the base member includes a guide groove extending in the sliding direction of the display plate, the guide groove includes a front and rear guide groove portion substantially orthogonal to the sliding direction, and the one display plate is formed in the vertical direction. A guide portion that protrudes and fits into the guide groove is provided, and the one conveying member is provided with an inclined groove into which the guide portion is fitted, and the inclined groove is inclined in a direction intersecting a sliding direction of the one display plate The one display plate is slid along the guide groove so that the guide portion is pushed by the one conveying member via the inclined groove, and the one display plate is The guide portion may be configured to slide back and forth by being pushed by the inclined groove and moving along the front and rear guide groove portion.

The other cam groove of the other conveying member includes an arcuate cam groove along the other rotation trajectory of the protrusion, and when the one display plate slides back and forth, the protrusion The other part may be configured to move in the arcuate cam groove.
The one display plate is supported on the front side of the cam gear via the one conveying member, the other conveying member is disposed on the rear side of the cam gear, and the other display plate is arranged on the one side. It is good also as a structure arrange | positioned at the front side of this display board, and being connected to the extension part extended around the said cam gear and the one display board from the said other conveyance member.

Further, the base member includes a lower surface support portion that supports the pair of display plates from below, the other display plate is supported from below by contacting the lower surface support portion, and the one transport member is It is good also as a structure provided with the lower surface support plate part which supports the lower surface of said one display board, and the said lower surface support part was equipped with the step part hollow only by the plate | board thickness of the said lower surface support plate part.
In addition, the present invention includes a base member that is housed by sliding in a housing and is erected at a viewing position outside the housing. The base member includes a plurality of display units, and at least the plurality of viewing portions at the viewing position. Provided is a display device characterized in that a display unit is developed sideways.
Further, in the above configuration, the plurality of display units may be developed laterally and arranged in the same plane.

  ADVANTAGE OF THE INVENTION According to this invention, the display apparatus provided with the some display board (display part) can be provided compactly.

It is a perspective view which shows the vehicle-mounted audio visual apparatus which concerns on embodiment of this invention. It is a perspective view of the vehicle-mounted audio visual apparatus in a state where one monitor and the other monitor are housed in a casing. It is a perspective view which shows the operation | movement of accommodation of the vehicle-mounted audio visual apparatus. It is a front view which shows the vehicle-mounted audio visual apparatus of the state which one monitor and the other monitor opened. It is a disassembled perspective view of the vehicle-mounted audio visual apparatus. It is a perspective view of a base member. It is VII-VII sectional drawing of FIG. It is the figure which looked at the conversion mechanism from the rear wall part side of the base member, (a) is a perspective view, (b) is a front view. It is a perspective view which shows arrangement | positioning of the wiring of one monitor and the other monitor. It is a figure which shows the state which advanced in the closing direction rather than FIG. 8, (a) is a perspective view, (b) is a front view. It is a figure which shows the state which advanced in the closing direction rather than FIG. 10, (a) is a perspective view, (b) is a front view. It is a figure which shows the state which advanced in the closing direction rather than FIG. 11, (a) is a perspective view, (b) is a front view. It is a figure which shows the state which one monitor and the other monitor closed, (a) is a perspective view, (b) is a front view. It is a figure which shows the positional relationship of the front-back guide groove part, one guide part, and an inclination groove | channel in the front-back slide process.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a perspective view showing an in-vehicle audio visual apparatus according to an embodiment of the present invention.
The in-vehicle audio visual apparatus 10 includes a box-shaped casing 11, a pair of left and right monitors 12R (one display board, display unit) and the other monitor 12L (the other display board, display unit), And a base member 13 that supports one monitor 12R and the other monitor 12L. One monitor 12R and the other monitor 12L are monitors of the same size.
The in-vehicle audio visual apparatus 10 is installed such that a housing 11 is embedded in a dashboard of a vehicle, and one monitor 12R and the other monitor 12L are housed in the housing 11 when not in use, and one when in use. This is a so-called in-dash type display device in which the other monitor 12R and the other monitor 12L protrude outside the housing 11. The in-vehicle audio visual apparatus 10 includes a control unit (not shown) in the housing 11 that controls the operation of the monitor 12R and the other monitor 12L by driving a motor or the like.

FIG. 2 is a perspective view of the in-vehicle audio visual apparatus 10 in a state where one monitor 12R and the other monitor 12L are housed in the casing 11. As shown in FIG.
The in-vehicle audio visual apparatus 10 includes a front panel 14 that closes an opening provided on the front surface of the housing 11. The front panel 14 includes a horizontally long opening 14a for taking in and out the one monitor 12R and the other monitor 12L. The front panel 14 is a panel provided facing the user, and the front panel 14 can be provided with a power button, an operation button, and the like of the in-vehicle audio visual apparatus 10. In the present embodiment, the front panel 14 side facing the user is the front side of the in-vehicle audio visual apparatus 10, and the left-right direction viewed from the user side is the left-right direction of the in-vehicle audio visual apparatus 10.

FIGS. 3A and 3B are perspective views showing the storing operation of the in-vehicle audio visual apparatus 10, wherein FIG. 3A shows a state in which one monitor 12R and the other monitor 12L are pulled out, and FIG. 3B shows one monitor 12R. And (c) and (d) show a state in which one monitor 12R and the other monitor 12L have moved left and right.
In the housed state shown in FIG. 2, one monitor 12R and the other monitor 12L overlap with each other in the thickness direction and are supported by the base member 13 with the display surfaces 15R and 15L facing downward. positioned.

  The in-vehicle audio visual apparatus 10 includes a slide mechanism (not shown) that slides the base member 13 back and forth. This slide mechanism section slides the base member 13 substantially horizontally by the driving force of a motor (not shown), and as shown in FIG. 3A, one monitor 12R and the other monitor 12L in the stored state. Is protruded together with the base member 13 from the opening 14a to the user side.

As shown in FIG. 3B, the in-vehicle audio visual apparatus 10 includes a tilt mechanism unit 16 that rotates the base member 13 to raise one monitor 12R and the other monitor 12L. The tilt mechanism portion 16 includes a pair of arms 16 a that can move back and forth from the left and right ends of the opening portion 14 a, a rotation shaft 16 b that is provided on the arm 16 a and extends to the left and right, a motor, and gears. And a drive unit (not shown) for rotating the. The rotation shaft 16 b is connected to the left and right side surfaces of the lower portion of the base member 13. The base member 13 is pivoted about the pivot shaft 16b and is in a substantially horizontal state or a standing state.
As shown in FIG. 3B to FIG. 3D and FIG. 1, in the in-vehicle audio visual apparatus 10, one monitor 12R and the other monitor 12L that overlap each other are slid left and right, The monitor 12R and the other monitor 12L can be opened sideways and arranged side by side.

Hereinafter, a structure for opening and closing the one monitor 12R and the other monitor 12L by sliding left and right will be described in detail.
FIG. 4 is a front view showing the in-vehicle audio visual apparatus 10 in a state where one monitor 12R and the other monitor 12L are opened. FIG. 5 is an exploded perspective view of the in-vehicle audio visual apparatus 10. Here, in FIG. 5, the peripheral structure of one monitor 12R, the other monitor 12L, and the base member 13 is shown in an exploded manner.

4 and 5, the in-vehicle audio visual apparatus 10 includes a motor 20 that is a driving source of a force for sliding one monitor 12 </ b> R and the other monitor 12 </ b> L left and right, and a circle rotated by the motor 20. And a plate-like cam gear 21.
The in-vehicle audio visual apparatus 10 is connected to a disk-shaped cam gear 21 and is connected to one carrier 22R (one transport member) that supports one monitor 12R and the disk-shaped cam gear 21. And the other carrier 22L (the other transport member) connected to the other monitor 12L.

FIG. 6 is a perspective view of the base member 13.
As shown in FIGS. 4 to 6, the base member 13 has the lower surface support portion 23 that supports one monitor 12 </ b> R and the other monitor 12 </ b> L from below and the rear edge portion of the lower surface support portion 23 upward from the upright state. The rear wall portion 24 is erected, and the upper wall portion 25 protrudes forward substantially horizontally from the upper end of the rear wall portion 24.
The left and right lengths of the lower surface support portion 23, the rear wall portion 24, and the upper wall portion 25 are substantially equal to the left and right lengths of the one monitor 12R and the other monitor 12L.

The lower surface support part 23 is formed in a substantially rectangular parallelepiped box shape that is longer in the left-right direction than in the front-rear direction, and has a space S (FIG. 9) inside. The upper surface of the lower surface support portion 23 constitutes a lower wall portion 26 that extends substantially horizontally facing the lower surfaces of the one monitor 12R and the other monitor 12L.
A pair of guide grooves 27 a and 27 b extending in the left and right directions along the rear wall portion 24 are formed in the middle portion of the lower wall portion 26 before and after.
In the front portion of the lower wall portion 26, the other guide groove 28 is formed that extends linearly from side to side along the rear wall portion 24.

One guide groove 27a, 27b and the other guide groove 28 are slit-like holes penetrating to the space S.
One guide groove 27a, 27b includes left and right guide groove portions 29, 29 extending linearly in the left-right direction, and front and rear guide groove portions 30, 30 extending forward from the right end of the left and right guide groove portions 29, 29. Prepare. The one guide groove 27a, 27b has the same shape, but the one guide groove 27b is disposed on the rear side and the outer side (right side) of the one guide groove 27a. One guide groove 27a, 27b is provided in a lower wall step portion 34 formed one step lower than the portion where the other guide groove 28 is provided.

7 is a cross-sectional view taken along the line VII-VII in FIG.
As shown in FIG. 7, one guide groove 37a, 37b having the same shape as the one guide groove 27a, 27b is formed on the inner surface of the upper wall portion 25 facing the lower wall portion 26. Further, an upper wall step (not shown) that is recessed one step upward is formed on the inner surface of the upper wall 25, and one guide groove 37a, 37b is provided in the upper wall step. The upper wall step portion has substantially the same shape as the lower wall step portion 34. One guide groove 37 a, 37 b is a groove that does not penetrate the upper wall portion 25. One guide groove 37a, 37b includes left and right guide groove portions 29, 29 and front and rear guide groove portions 30, 30. In plan view, the one guide groove 27a, 27b and the one guide groove 37a, 37b are provided at the same position, and when viewed from above, the one guide groove 27a, 27b and the one guide groove 37a, It overlaps with 37b.
The other guide groove 38 having the same shape as the other guide groove 28 is formed on the inner surface of the upper wall portion 25. The other guide groove 38 is a groove that does not penetrate the upper wall portion 25. In plan view, the other guide groove 28 and the other guide groove 38 are provided at the same position, and when viewed from above, the other guide groove 28 and the other guide groove 38 overlap each other.

As shown in FIG. 6, an escape groove portion 31 that extends linearly from side to side along the rear wall portion 24 is formed in the rear portion of the lower wall portion 26. The escape groove 31 is a slit-like hole that penetrates to the space S.
At the left and right ends of the rear portion of the lower wall portion 26, shaft coupling portions 32, 32 to which the rotation shaft 16b of the tilt mechanism portion 16 is fitted are provided.
The length in the depth direction of the lower surface support portion 23 is formed to be larger than the thickness in which the one monitor 12R, the other monitor 12L, the cam gear 21 and the like are overlapped.

The height of the rear wall portion 24 in the vertical direction is such that one monitor 12R and the other monitor 12L are stowed so that one monitor 12R and the other monitor 12L can be stood between the lower wall portion 26 and the upper wall portion 25. It is formed larger than the height of 12L.
A shaft support portion 33 to which a cam gear support shaft (not shown) that supports the cam gear 21 is fixed is provided at the upper and lower and left and right intermediate portions of the rear wall portion 24.
The base member 13, the cam gear 21, one carrier 22R, and the other carrier 22L convert the driving force of the motor 20 into a force that causes the one monitor 12R and the other monitor 12L to slide on the base member 13, and slides. A conversion mechanism 35 is configured.

8A and 8B are views of the conversion mechanism 35 viewed from the rear wall portion 24 side of the base member 13, wherein FIG. 8A is a perspective view and FIG. 8B is a front view. Here, FIG. 8 shows a state in which one monitor 12R and the other monitor 12L are completely opened to the left and right.
As shown in FIGS. 4 to 6 and 8, one monitor 12 </ b> R and the other monitor 12 </ b> L are plate-like liquid crystal monitors and have substantially the same screen size and outer shape. One monitor 12R has a substantially rectangular plate-shaped monitor body 40 and a display surface 15R. The other monitor 12L has a substantially rectangular plate-shaped monitor main body 41 and a display surface 15L.
One monitor 12 </ b> R and the other monitor 12 </ b> L are wide-type monitors having a horizontally long aspect ratio of, for example, 16: 9.

  One monitor 12 </ b> R includes a pair of rod-shaped guide portions 43, 43 that extend straight in the height direction of the one monitor 12 </ b> R on the back side of the monitor body 40. One of the guide portions 43, 43 is supported by a guide portion support portion 44 (FIG. 8) provided so as to protrude from the back side of the monitor main body 40 and extends up and down. It protrudes above and below the upper and lower edges, respectively. The one guide portions 43, 43 are arranged close to the inner edge 40a in the left-right direction of one monitor 12R in a state where one monitor 12R and the other monitor 12L are opened left and right.

One monitor 12R has an upper wall portion in a state where the upper and lower ends of one guide portion 43, 43 are fitted in one guide groove 37a, 37b and one guide groove 27a, 27b of the base member 13, respectively. 25 and the lower wall portion 26.
The one monitor 12R slides along the one guide groove 37a, 37b, 27a, 27b when the one guide portion 43, 43 is guided by the one guide groove 37a, 37b, 27a, 27b.

  The other monitor 12L includes a pair of rod-shaped guide portions 45, 45 extending straight in the height direction of the other monitor 12L. The other guide portions 45, 45 are provided so as to protrude upward and downward from the upper and lower edges of the monitor body 41. The other guide portions 45, 45 are arranged close to the left and right inner edge 41a side of the other monitor 12L in a state where the one monitor 12R and the other monitor 12L are opened to the left and right. Further, of the pair of other guide portions 45, 45, the guide portion 45 on the side close to the inner edge 41 a includes a downward extending portion 45 a that extends downward from the lower end of the far-side guide portion 45.

The other monitor 12L has the upper wall portion 25 and the lower wall in a state where the upper and lower ends of the other guide portions 45, 45 are fitted in the other guide groove 38 and the other guide groove 28 of the base member 13, respectively. It arrange | positions between the parts 26. FIG.
The other monitor 12 </ b> L slides along the other guide grooves 38, 28 as the other guide portions 45, 45 are guided by the other guide grooves 38, 28.

The cam gear 21 is a single disc-shaped gear, and has a diameter larger than the length of one monitor 12R in the height direction.
The cam gear 21 includes a disc-shaped gear body 21a and a support hole 21b formed at the center of the gear body 21a and supported by the cam gear support shaft, and rotates around the cam gear support shaft. The cam gear 21 has a gear portion 21c provided on the entire outer periphery of the gear body portion 21a, and a plurality of lightening holes 21d formed in a plate portion between the gear portion 21c and the support hole 21b. The cam gear 21 is provided substantially parallel to the rear wall portion 24, and has a gear surface 21 e that faces the back surface of one monitor 12 </ b> R and the other monitor 12 </ b> L, and a gear back surface that faces the rear wall portion 24 of the base member 13. 21f.
The lower part of the cam gear 21 during rotation passes through the escape groove 31 of the base member 13 and is positioned in the space S.

As shown in FIG. 8, the cam gear 21 is erected on the gear surface 21 e and is erected on one protrusion 46 </ b> R (one of the protrusions) that protrudes toward the back side of one monitor 12 </ b> R and the gear back surface 21 f. The other protrusion 46L (the other of the protrusion) that protrudes toward the rear wall 24 of the base member 13 is provided.
One protrusion 46R and the other protrusion 46L are provided close to the outer peripheral side of the cam gear 21 in the radial direction, and are positioned in the vicinity of the gear part 21c. Further, the one projecting portion 46R and the other projecting portion 46L are arranged at positions that differ by approximately 180 ° in the circumferential direction of the cam gear 21. Specifically, when viewed in the rotation direction (closing direction CL) of the cam gear 21 when closing one monitor 12R and the other monitor 12L, which will be described later, the one protrusion 46R and the other protrusion 46L are in the circumferential direction. They are arranged at different positions by an angle slightly larger than 180 °. One protrusion 46R and the other protrusion 46L are constituted by pins that are erected on the gear body 21a, for example.

The motor 20 includes a columnar main body portion 20a that is laid down and a worm gear 20b that is provided on a motor shaft that protrudes in the axial direction from the end of the main body portion 20a.
The motor 20 is disposed in the space S of the lower surface support portion 23. Specifically, the motor 20 is positioned at one end portion on the other monitor 12L side in the space S that is long to the left and right, and the worm gear 20b is disposed in a direction facing the other end portion side in the space S.
An intermediate gear 47 that transmits the driving force of the worm gear 20b to the cam gear 21 is disposed between the worm gear 20b and the cam gear 21.
The intermediate gear 47 is a gear that integrally includes a small-diameter gear portion 47a (FIG. 5) that meshes with the worm gear 20b and a large-diameter gear portion 47b that meshes with the gear portion 21c of the cam gear 21. The intermediate gear 47 is pivotally supported on the rear wall portion 24.

As shown in FIGS. 5 and 8, one carrier 22 </ b> R has a vertical plate portion 50 extending vertically along the back surface of one monitor 12 </ b> R and forward from the upper edge of the vertical plate portion 50 to the one monitor 12 </ b> R side. An upper plate portion 51 that extends and a lower plate portion 52 that extends forward from the lower edge of the vertical plate portion 50 toward the one monitor 12R side are provided. The width in the left-right direction of one carrier 22R is smaller than the radius of the cam gear 21.
The upper plate portion 51 and the lower plate portion 52 are arranged to face each other and are provided substantially parallel to the upper surface and the lower surface of one monitor 12R.
The upper plate portion 51 and the lower plate portion 52 are inclined obliquely to the left and right sliding directions of the one monitor 12R, that is, the extending directions of the left and right guide groove portions 29 and 29 of the one guide groove 27a and 27b. Grooves 53 and 54 are formed, respectively. Specifically, the inclined grooves 53 and 54 are inclined so as to be farther in the front-rear direction with respect to the one monitor 12R as it goes in the sliding direction of the one monitor 12R when the one monitor 12R is opened. ing. The inclined grooves 53, 54 have left and right groove portions 53a, 54a extending in the left-right direction at the front end.

A pair of the inclined grooves 53 are provided on the upper plate portion 51 side by side in the left-right direction. A pair of inclined grooves 54 are provided in the lower plate portion 52 side by side in the left-right direction. The inclined grooves 53 and 54 are slit-like holes having the same shape that penetrate the upper plate portion 51 and the lower plate portion 52.
In a plan view, the inclined groove 53 and the inclined groove 54 are provided at the same position, and the inclined groove 53 and the inclined groove 54 overlap when viewed from above.
One carrier 22R has its lower plate portion 52 fitted into the lower wall step portion 34 of the base member 13 and the upper plate portion 51 fitted into the upper wall step portion, so that sliding in the front-rear direction is restricted. Slide left and right in the state.

  The vertical plate portion 50 of one carrier 22R has one cam groove 55 into which one protrusion 46R of the cam gear 21 is fitted. One cam groove 55 is a slit-like hole extending linearly in the vertical direction, and is provided from the upper part of the vertical plate part 50 to the upper and lower intermediate parts. Further, one cam groove 55 is provided at an outer end portion in the left-right direction of the vertical plate portion 50 in a state where one monitor 12R is opened in the left-right direction as shown in FIG.

One carrier 22R is attached to the back side of one monitor 12R by fitting the inclined grooves 53, 54 to the upper and lower ends of one guide portion 43, 43, respectively.
One carrier 22R and one monitor 12R can be moved relative to each other by moving one guide portion 43, 43 in the inclined grooves 53, 54. In a state where one monitor 12 </ b> R moves in a direction approaching the vertical plate portion 50, one monitor 12 </ b> R is sandwiched between the upper plate portion 51 and the lower plate portion 52.

The upper and lower ends of one of the guide portions 43 and 43 extend further upward and downward through the inclined grooves 53 and 54, and the upper and lower ends are connected to one guide groove 37 a and 37 b of the base member 13 and one of them. The guide grooves 27a and 27b are respectively fitted. That is, one monitor 12R is provided to be slidable left and right along one guide groove 27a, 27b, 37a, 37b with one carrier 22R interposed between the base member 13 and one monitor 12R.
One carrier 22 </ b> R is disposed between one monitor 12 </ b> R and the cam gear 21, and is connected to the cam gear 21 when one protrusion 46 </ b> R of the cam gear 21 is fitted in one cam groove 55. . That is, one monitor 12R is connected to the cam gear 21 via one carrier 22R.

  The other carrier 22L includes a plate portion 60 that extends vertically along the gear back surface 21f, and an extension portion 61 that extends downward from the lower edge of the plate portion 60 and extends forward. The width in the left-right direction of the other carrier 22L is smaller than the radius of the cam gear 21. The plate part 60 extends from the lower part of the cam gear 21 to the upper part of the other monitor 12L.

The other cam groove 62 into which the other protrusion 46L of the cam gear 21 is fitted is formed in the plate portion 60 of the other carrier 22L so as to extend vertically. The other cam groove 62 includes an arc-shaped escape groove portion 62a formed in an arc shape, an arc-shaped cam groove portion 62b formed in an arc shape, and a linear cam groove portion 62c extending linearly in the vertical direction.
The arc-shaped escape groove portion 62a extends from the upper end portion of the plate portion 60 to the upper and lower intermediate portions, and the arc-shaped cam groove portion 62b extends to the lower portion of the plate portion 60 continuously to the lower end of the arc-shaped escape groove portion 62a. The groove part 62c extends to the lower end part of the plate part 60 continuously to the lower end of the arcuate cam groove part 62b.

When the one monitor 12R and the other monitor 12L are changed from the opened state to the closed state to the closed state, the cam gear 21 rotates in the closing direction CL as shown in FIG. The arcuate cam groove 62b is formed in an arc shape along the trajectory of rotation of the other protrusion 46L when the cam gear 21 rotates in the closing direction CL.
When one monitor 12R and the other monitor 12L are changed from the closed state to the opened state, the cam gear 21 rotates in the opening direction OP opposite to the closing direction CL as shown in FIG. . The arc-shaped escape groove 62a is formed in an arc shape along the locus of rotation of the other protrusion 46L when the cam gear 21 rotates in the opening direction OP.

  The other carrier 22L is connected to the other monitor 12L by engaging the lower extension 45a of the guide 45 with the tip of the extension 61 (FIG. 13). The other carrier 22 </ b> L is connected to the cam gear 21 by fitting the other protrusion 46 </ b> L of the cam gear 21 into the other cam groove 62. That is, the other monitor 12L is connected to the cam gear 21 via the other carrier 22L.

FIG. 9 is a perspective view showing the wiring arrangement of one monitor 12R and the other monitor 12L. In FIG. 9, a part of the in-vehicle audio visual apparatus 10 is cut away so that the space S can be seen.
One monitor 12R and the other monitor 12L are connected to a control unit or the like in the casing 11 by belt-like FPCs (flexible printed circuit boards) 65 and 66, and through the FPCs 65 and 66, video signals, power supplies, and the like. Is supplied to one monitor 12R and the other monitor 12L.

  The FPC 65 connected to one monitor 12R is routed along the lower wall portion 26 on the back side of one monitor 12R and the other monitor 12L. The FPC 65 is routed from the other monitor 12L side to the one monitor 12R side in a state where the one monitor 12R and the other monitor 12L are open, folded back in the vicinity of the inner edge 40a, and connected to the lower part of the rear surface of the one monitor 12R. Is done.

The FPC 66 connected to the other monitor 12L is routed in the space S. The FPC 65 is drawn from the one monitor 12R side to the other monitor 12L side in a state where the one monitor 12R and the other monitor 12L are opened, and is connected to the lower part of the other monitor 12L in the vicinity of the inner edge 41a. Specifically, the FPC 66 is connected to the other monitor 12 </ b> L from below through the guide groove 28.
Thus, since the FPC 65 is provided along the upper surface of the lower wall portion 26 and the FPC 66 is provided in the space S, the FPCs 65 and 66 do not interfere with each other, and the one monitor 12R and the other monitor 12L slide. However, wiring for monitoring can be provided.

Next, the opening / closing operation of one monitor 12R and the other monitor 12L will be described. First, the closing operation until the one monitor 12R and the other monitor 12L are changed from the opened state to the closed state will be described.
10A and 10B are diagrams showing a state of proceeding in the closing direction as compared with FIG. 8, in which FIG. 10A is a perspective view and FIG. 10B is a front view. 11A and 11B are diagrams showing a state of proceeding in the closing direction as compared with FIG. 10, in which FIG. 11A is a perspective view and FIG. 11B is a front view. FIGS. 12A and 12B are views showing a state of proceeding in the closing direction as compared with FIG. 11, wherein FIG. 12A is a perspective view and FIG. 12B is a front view. FIG. 13 is a diagram showing a state in which one monitor 12R and the other monitor 12L are closed, (a) is a perspective view, and (b) is a front view.

  As shown in FIGS. 7 and 8, when one monitor 12R and the other monitor 12L are completely opened to the left and right sides (hereinafter, this state is referred to as an open state), one monitor 12R and the other monitor 12L The monitor 12L is arranged side by side on the left and right. In the open state, the inner edge 40a and the inner edge 40a are in contact with each other, the front and rear positions of the one monitor 12R and the other monitor 12L are aligned, and the display surface 15R and the display surface 15L are disposed substantially flush with each other. .

  In the open state, the cam gear 21 has one protrusion 46R positioned below the one cam groove 55 and the other protrusion 46L positioned above the arcuate cam groove 62b of the other cam groove 62. In the pivot position. By rotating the cam gear 21 in this way, one carrier 22R is disposed at the right end (one end of the slide position) of the left and right slide positions of one carrier 22R, and the other carrier 22L is The carrier 22L is disposed at the left end (the other end on the slide position) of the left and right slide positions.

In the open state, the one guide portion 43, 43 is located at the front end (FIG. 7) of the front and rear guide groove portions 30, 30 at the right end of the one guide groove 27a, 27b, and the left and right groove portions 53a, 53b of the inclined grooves 53, 54. 54a. That is, in the open state, one monitor 12R is arranged at the front end of the front and rear guide groove portions 30, 30 such that one guide portion 43, 43 is pushed by the rear edges of the left and right groove portions 53a, 54a. It is slid to the front and right end positions. Further, in the open state, since one of the guide portions 43, 43 is supported by the rear edges of the left and right groove portions 53a, 54a, even if an external force that moves the one monitor 12R rearward is applied, the external force is applied to the left and right groove portions. 53a, 54a can be received, and one monitor 12R can be prevented from moving backward.
In the open state, the other guide portions 45, 45 are located on the left end side of the other guide grooves 28, 38, whereby the other monitor 12L is located at the left end in the slide position.

When an instruction to close one monitor 12R and the other monitor 12L is issued by a user or the like, the control unit drives the motor 20 and rotates the cam gear 21 in the closing direction CL.
When the cam gear 21 starts to rotate in the closing direction CL from the open state, as shown in FIG. 10, one protrusion 46 </ b> R moves along an arcuate locus in the upper left direction, Then, it moves upward in the cam groove 55. Thereby, one carrier 22R is slid to the left end side, and one monitor 12R starts to slide backward. In this way, the process in which one monitor 12R slides back and forth is referred to as a front / rear slide process.

FIG. 14 is a diagram showing the positional relationship between the front and rear guide groove portions 30 and 30, the one guide portions 43 and 43, and the inclined grooves 53 and 54 in the front and rear sliding step.
In the front-rear sliding step, one guide portion 43, 43 is moved from the left and right groove portions 53a, 54a at the front ends of the inclined grooves 53, 54 shown in FIG. 8 to the inclined groove 53, shown in FIG. 54 to the rear end.

  Specifically, as shown in FIG. 14, in the front / rear slide process, one of the guide portions 43, 43 is formed in the inclined groove 53 as the inclined grooves 53, 54 slide to the left side as the one carrier 22 </ b> R slides. , 54 is pushed backward by the front edges of the front and rear guide grooves 30 and 30 and slides backward. Accordingly, one monitor 12R slides backward by the length of the front and rear guide groove portions 30 and 30. Here, the slide amount before and after one monitor 12R is set larger than the thickness of the other monitor 12L so that one monitor 12R can slide to the left and right behind the other monitor 12L.

Further, in the front / rear slide process, as shown in FIG. 10, the other protrusion 46 </ b> L moves along the arcuate locus in the lower right direction within one cam groove 55. Specifically, in the front / rear slide process, the other protrusion 46L only moves from the upper end to the lower end in the arcuate cam groove 62b formed in the same shape as the rotation trajectory of the other protrusion 46L. Therefore, in the front / rear slide process, the other carrier 22L does not move, and the other monitor 12L does not move.
That is, the front / rear slide step is a step of sliding only one monitor 12R back and forth while the movement of the other monitor 12L is stopped. In the present embodiment, the movement of the other monitor 12L can be stopped by providing the arc-shaped cam groove 62b, and the front-rear slide process can be realized with a simple configuration.

When the front / rear slide process is completed and the cam gear 21 is further rotated in the closing direction CL, the one monitor 12R and the other monitor 12L slide in the left / right direction along the left / right guide groove portions 29, 29 and the other guide groove 28. Moving.
FIG. 11 shows a state in which the cam gear 21 is rotated in the closing direction CL as compared with FIG. 10, and the one carrier 22R and the other carrier 22L are moved along with the movement of the one protrusion 46R and the other protrusion 46L. Slide in the closing direction. One guide portion 43, 43 slides along the left and right guide groove portions 29, 29 so as to be pushed by the inclined grooves 53, 54 of one carrier 22R.
In the state of FIG. 11, one protrusion 46R is located at the upper end of one cam groove 55, and the other protrusion 46L is located at the lower end of the linear cam groove 62c. In the section in which the other protrusion 46L moves in the linear cam groove 62c, the other protrusion 46L and one protrusion 46R both move in the vertical groove, so that one monitor 12R and the other monitor 12L The slide speed is substantially the same.

  FIG. 12 shows a state in which the cam gear 21 is rotated in the closing direction CL as compared with FIG. 11, and one carrier 22R and the other carrier 22L are moved along with the movement of the one protrusion 46R and the other protrusion 46L. Slide in the closing direction. In the state of FIG. 12, the other protrusion 46L moves upward in the arcuate cam groove 62b, and one protrusion 46R moves downward in one cam groove 55. In the section where the other protrusion 46L moves upward in the arc-shaped cam groove 62b, the other monitor 12L slides in the closing direction faster than the section of the linear cam groove 62c.

As shown in FIG. 13, in the state where one monitor 12R and the other monitor 12L overlap each other and are completely closed (hereinafter, this state is referred to as a closed state), the other protrusion 46L has an arc-shaped escape groove portion. One projecting portion 46 </ b> R is located at the lower end portion of one cam groove 55.
Since the arc-shaped escape groove 62a is formed in the same shape as the trajectory of rotation of the other protrusion 46L, when the other protrusion 46L is positioned in the arc-shaped escape groove 62a, the other monitor 12L The slide movement is stopped. That is, the other monitor 12L reaches the left end of the slide position when the other protrusion 46L moves upward from the state of FIG. 12 and enters the lower end of the arc-shaped escape groove 62a, and the slide movement is stopped. The Further, the other protrusion 46L moves upward even after the sliding movement of the other monitor 12L stops, and finally moves to the upper and lower intermediate portions of the arc-shaped escape groove 62a.

On the other hand, the one protrusion 46R moves downward in one cam groove 55 even after the slide movement of the other monitor 12L stops, and slides one monitor 12R. Eventually, one protrusion 46R moves to the lower end of one cam groove 55, and correspondingly, the sliding movement of one monitor 12R is also stopped.
As shown in FIGS. 8 and 13, the amount of rotation of the cam gear 21 from the open state to the closed state is approximately a half rotation, specifically, a rotation angle slightly smaller than 180 °.
The in-vehicle audio visual apparatus 10 can display information on the display surface in both the open state and the closed state. Specifically, the control unit displays information on both the display surfaces 15R and 15L in the open state, but stops the one monitor 12R and displays the information only on the other monitor 12L in the closed state.

Next, the opening operation from the closed state to the open state will be described.
When an instruction to use the in-vehicle audio visual apparatus 10 is issued by a user or the like, the control unit drives the slide mechanism unit to project one monitor 12R and the other monitor 12L together with the base member 13 forward. Let Next, the control unit drives the tilt mechanism unit 16 to erect the base member 13. As a result, the other monitor 12L is in a visual recognition position facing the user. In a state where the base member 13 is raised by the tilt mechanism unit 16, one monitor 12R and the other monitor 12L are in a closed state, and only the other monitor 12L is visually recognized by the user. The in-vehicle audio visual apparatus 10 can also display information in the closed state as described above.

When the standing up is completed, the control unit drives the motor 20 to rotate the cam gear 21 in the opening direction OP, and starts an opening operation from the closed state to the open state. The opening operation is the reverse of the closing operation described above.
When the cam gear 21 starts to rotate in the opening direction OP from the closed state shown in FIG. 13, the one protrusion 46 </ b> R moves along an arcuate locus in the upper right direction, and the cam groove 55 Move upward in 55. Thereby, one carrier 22R is slid to the right end side, and one monitor 12R starts sliding to the right end side in the opening direction.
On the other hand, when the cam gear 21 starts to rotate in the opening direction OP, the other protrusion 46L moves to the lower left with an arcuate locus and moves within the arcuate escape groove 62a. In the section in which the other protrusion 46L moves in the arc-shaped escape groove 62a, the other monitor 12L has not yet started to slide.

When the other projection 46L passes through the arcuate cam groove 62b in the opening direction from the state of FIG. 13 to the state of FIG. 12, the other monitor 12L slides in the opening direction to the left end side. Further, in the state of FIG. 12, one monitor 12R continues sliding to the right end side.
In the state of FIG. 11 further advanced from FIG. 12 in the opening direction, one monitor 12R and the other monitor 12L slide in the opening direction at substantially the same speed.

  When proceeding further in the opening direction from the state of FIG. 11, the front / rear slide process is started, and the one monitor 12R and the other monitor 12L are changed from the state of FIG. 10 to the state of FIG. Specifically, in the front / rear slide process, as shown in FIG. 14, as the inclined grooves 53, 54 slide to the right side of the one carrier 22 </ b> R, the one guide portions 43, 43 become inclined grooves 53. , 54 is pushed forward by the rear edges, and slides forward in the front and rear guide groove portions 30, 30. As a result, one monitor 12R slides forward by the length of the front and rear guide groove portions 30, 30, and the one monitor 12R and the other monitor 12L are arranged side by side to the left and right, and the display surface 15R, 15L come to be located in the same plane mutually.

As shown in FIG. 10, when the other protrusion 46L reaches the upper end of the linear cam groove 62c, the sliding movement of the other monitor 12L in the opening direction is completed. In the subsequent back-and-forth slide process, one protrusion 46R slides one carrier 22R, but the other protrusion 46L moves upward in the arc-shaped cam groove 62b and moves to the upper end of the arc-shaped cam groove 62b. Just do it. As described above, the sliding movement of the other monitor 12L in the opening direction is completed before the front / rear slide process, so that the other monitor 12L does not interfere with the front / rear slide of the one monitor 12R.
Further, since the lower wall step portion 34 (FIG. 6) is provided corresponding to the thickness of the lower plate portion 52 of one carrier 22R, and the lower plate portion 52 is disposed on the lower wall step portion 34, one carrier 22R Even if the lower surface of the monitor 12R is supported, the upper and lower positions of one monitor 12R and the other monitor 12L are aligned.

  As described above, according to the embodiment to which the present invention is applied, the in-vehicle audio visual apparatus 10 includes the base that supports the one monitor 12R and the other monitor 12L, and the one monitor 12R and the other monitor 12L. The member 13, the motor 20 that moves one monitor 12R and the other monitor 12L, and the driving force of the motor 20 are converted into a force that slides the one monitor 12R and the other monitor 12L on the base member 13. The one monitor 12R and the other monitor 12L are slid from the closed state through the conversion mechanism 35 and are opened and arranged sideways. Thereby, one monitor 12R and the other monitor 12L in a state of being overlapped and closed can be slid by the driving force of the motor 20 via the conversion mechanism 35 and opened to the left and right sides when necessary. Since one monitor 12R and the other monitor 12L can be arranged in the vehicle, the in-vehicle audiovisual apparatus 10 including the one monitor 12R and the other monitor 12L can be provided in a compact manner.

In addition, a box-shaped housing 11 that houses one monitor 12R and the other monitor 12L that are overlapped and closed together with the base member 13 is provided. When the one monitor 12R and the other monitor 12L display information, Is pulled out integrally with the base member 13 from the housing 11 and is raised. For this reason, the one monitor 12R and the other monitor 12L in a closed state can be compactly accommodated in the casing 11, and when necessary, the one monitor 12R and the other monitor 12L are erected. And can be arranged side by side.
Further, when the one monitor 12R and the other monitor 12L are opened at the end of the left and right sliding positions of the conversion mechanism 35, the display surfaces 15R and 15L are substantially flush with each other. 15R and 15L can be easily seen.

  One monitor 12R and the other monitor 12L are provided as a pair, and the conversion mechanism 35 includes one carrier 22R connected to one monitor 12R and the other carrier 22L connected to the other monitor 12L. The cam gear 21 is disposed on the back side of one monitor 12R and the other monitor 12L, and is connected to one carrier 22R and the other carrier 22L. The cam gear 21 is driven and rotated by the motor 20, and the cam gear 21 is And a pair of one protrusion 46R and the other protrusion 46L on the plate surface, and one carrier 22R has one cam groove 55 into which one protrusion 46R fits. The other carrier 22L includes the other cam groove 62 into which the other protrusion 46L is fitted, and the one monitor 12R and the other monitor 12L By one of protrusions 46R and the other projections 46L to move in the circumferential direction by the rotation of the gear 21 is caused to slide through one of the cam grooves 55 and the other of the cam groove 62. As a result, the rotation of the cam gear 21 driven by the motor 20 is converted into a lateral sliding force, and the one monitor 12R and the other monitor 12L are moved sideways via the one carrier 22R and the other carrier 22L. One monitor 12R and the other monitor 12L can be arranged with a simple configuration.

  Furthermore, the base member 13 includes one guide groove 27a, 27b, 37a, 37b extending in the sliding direction of one monitor 12R, and the one guide groove 27a, 27b, 37a, 37b is a front and rear that is substantially orthogonal to the sliding direction. Each monitor 12R is provided with a guide groove portion 30 at the end, and one monitor 12R is provided with one guide portion 43, 43 that protrudes in the vertical direction and fits into one guide groove 27a, 27b, 37a, 37b. The inclined grooves 53 and 54 into which the one guide portions 43 and 43 are fitted are provided, and the inclined grooves 53 and 54 extend obliquely in a direction intersecting the sliding direction of the one monitor 12R, and the one monitor 12R is inclined. One guide groove 27a, 27b, 37 so that one guide portion 43, 43 is pushed by one carrier 22R through the groove 53, 54. , 37b, and the one monitor 12R slides back and forth as one guide portion 43, 43 is pushed by the inclined grooves 53, 54 and moves along the front and rear guide groove portions 30, 30. . For this reason, the force of moving the one carrier 22R in the sliding direction at the end of the one monitor 12R in the sliding direction can be converted into the force of sliding the one monitor 12R back and forth by the inclined grooves 53 and 54. With the configuration, one of the monitors 12R can be slid back and forth to make the display surfaces 15R and 15L substantially flush.

Further, the other cam groove 62 of the other carrier 22L includes an arcuate cam groove portion 62b along the trajectory of rotation of the other protrusion 46L, and when one monitor 12R slides back and forth, the other protrusion The portion 46L moves in the arcuate cam groove 62b. Thus, when one monitor 12R slides back and forth, the other monitor 12L can be prevented from sliding, and the other monitor 12L can be prevented from interfering with the display surfaces 15R and 15L. A structure that can be made flush can be realized with a simple structure.
One monitor 12R is supported on the front side of the cam gear 21 via one carrier 22R, the other carrier 22L is disposed on the rear side of the cam gear 21, and the other monitor 12L is the front side of the one monitor 12R. It is arranged on the side, and is connected to an extension portion 61 that extends from the other carrier 22L and extends below the cam gear 21 and one monitor 12R. Therefore, even if one monitor 12R and the other monitor 12L overlap each other in a compact arrangement, the one carrier 22R and the other carrier 22L can be connected to the one monitor 12R and the other monitor 12L. With a simple configuration, one monitor 12R and the other monitor 12L can be opened sideways.

  Furthermore, the base member 13 includes a lower surface support portion 23 that supports one monitor 12R and the other monitor 12L from below, and the other monitor 12L is supported from below by contacting the lower surface support portion 23, and one carrier. 22R includes a lower plate portion 52 that supports the lower surface of one monitor 12R, and the lower surface support portion 23 includes a lower wall step portion 34 that is recessed by at least the thickness of the lower plate portion 52. Accordingly, the lower plate portion 52 can be disposed on the lower wall step portion 34 and the position of one carrier 22R can be lowered, so that one monitor 12R is supported by the one carrier 22R, The height positions of the monitor 12R and the other monitor 12L can be matched.

The in-vehicle audio visual apparatus 10 includes a base member 13 that is housed by sliding in the housing 11 and stands up at a visual recognition position outside the housing 11, and includes one monitor 12R and the other on the base member 13. A monitor 12L is provided, and at least in the visual recognition position, one monitor 12R and the other monitor 12L are deployed sideways. Thereby, one monitor 12R and the other monitor 12L can be compactly accommodated in the casing 11 together with the base member 13, and the base member 13 is erected at a visual recognition position outside the casing 11, so that one monitor 12R and the other monitor 12L can be expanded to the side. For this reason, the vehicle-mounted audio visual apparatus 10 provided with one monitor 12R and the other monitor 12L can be provided compactly.
In addition, since the one monitor 12R and the other monitor 12L are developed laterally and arranged in the same plane, the one monitor 12R and the other monitor 12L can be easily seen.

In addition, the said embodiment shows the one aspect | mode which applied this invention, Comprising: This invention is not limited to the said embodiment.
In the above-described embodiment, the configuration in which one monitor 12R that electrically displays information and the other monitor 12L are opened and closed in the in-vehicle audio visual apparatus 10 has been described as an example, but the present invention is limited to this. It is not a thing. For example, the present invention may be applied to a whiteboard used for a lecture or the like. In this case, by providing the conversion mechanism 35 on the back side of the pair of whiteboards on which the user writes information with a pen or the like, the pair of whiteboards can be opened and closed to the left and right sides with a simple configuration. In the in-vehicle audio visual apparatus 10, one or both of the one monitor 12R and the other monitor 12L may be a white board or the like.
In the above-described embodiment, a pair of one monitor 12R and the other monitor 12L are described as examples of the plurality of display boards. However, the present invention is not limited to this, and three or more sheets are used. The display board may be accommodated in the housing 11 and may be configured such that a plurality of display boards are arranged side by side by being opened to the side by a sliding opening / closing mechanism using a motor.

10 In-vehicle audio visual device (display device)
11 Housing 12L The other monitor (the other display panel, display unit)
12R One monitor (one display board, display unit)
13 Base member 15L, 15R Display surface 20 Motor 21 Cam gear 22L The other carrier (the other conveying member)
22R One carrier (One transport member)
23 Lower surface support part 27a, 27b, 37a, 37b One guide groove (guide groove extending in the sliding direction)
30 Front / rear guide groove 34 Lower wall step (step)
35 Conversion mechanism 28, 38 The other guide groove 43, 43 One guide part 45, 45 The other guide part 45a Downward extension part 46L The other protrusion (the other of the protrusion)
46R One protrusion (one of the protrusions)
52 Lower plate (lower support plate)
53, 54 Inclined groove 55 One cam groove 61 Extension portion 62 Other cam groove 62b Arc-shaped cam groove portion

Claims (10)

A plurality of display boards, a base member that supports the display boards, a motor that moves the plurality of display boards, and a driving force of the motors to a force that slides the plurality of display boards on the base member A conversion mechanism that converts and slides,
The display device, wherein the plurality of display boards are slid and moved sideways through the conversion mechanism from a state of being overlapped and closed, and are arranged side by side. A box-shaped housing for accommodating the plurality of display plates in a closed state together with the base member;
The display device according to claim 1, wherein when displaying information, the plurality of display boards are pulled out integrally with the base member from the housing and are erected.   3. The display device according to claim 1, wherein a plurality of the display boards are substantially flush with each other in a state where the display boards are opened at the end of the slide position of the conversion mechanism. . The display board is provided in a pair,
The conversion mechanism includes: one transport member coupled to one display board of the pair of display boards; the other transport member coupled to the other display board of the pair of display boards; And a cam gear connected to the one transport member and the other transport member, the cam gear being driven by the motor and rotated,
The cam gear is formed in a disc shape and includes a pair of protrusions on the plate surface,
The one conveying member includes one cam groove into which one of the protrusions is fitted, and the other conveying member includes the other cam groove into which the other of the protruding parts is fitted,
2. The pair of display plates are slidably moved through the one cam groove and the other cam groove by a pair of protrusions that move in the circumferential direction by rotation of the cam gear. 4. The display device according to any one of 3. The base member includes a guide groove that extends in the sliding direction of the display plate, and the guide groove includes a front and rear guide groove portion that is substantially orthogonal to the sliding direction at the end,
The one display plate includes a guide portion that protrudes in the vertical direction and fits into the guide groove,
The one conveying member includes an inclined groove into which the guide portion is fitted, and the inclined groove extends obliquely in a direction intersecting the sliding direction of the one display panel.
The one display plate is slid along the guide groove so that the guide portion is pushed by the one conveying member through the inclined groove,
5. The display device according to claim 4, wherein the one display panel slides back and forth by the guide portion being pushed by the inclined groove and moving along the front and rear guide groove portion. 6.   The other cam groove of the other conveying member includes an arcuate cam groove along the other rotation locus of the protrusion, and when the one display plate slides back and forth, the protrusion of the protrusion 6. The display device according to claim 5, wherein the other moves in the arcuate cam groove. The one display plate is supported on the front side of the cam gear via the one conveyance member, and the other conveyance member is disposed on the rear side of the cam gear,
The other display panel is disposed on the front side of the one display panel, and is connected to an extension portion that extends from the other transport member and extends below the cam gear and the one display panel. The display device according to claim 4, wherein the display device is a display device. The base member includes a lower surface support portion that supports the pair of display plates from below.
The other display plate is supported from below by contacting the lower surface support portion,
The one conveying member includes a lower surface support plate portion that supports a lower surface of the one display plate,
The display device according to claim 7, wherein the lower surface support portion includes a step portion that is recessed at least by a thickness of the lower surface support plate portion.   The base member includes a base member that is housed by sliding inside the housing and is erected at a viewing position outside the housing. The base member includes a plurality of display portions, and at least the viewing portions are laterally disposed at the viewing position. A display device that is developed.   The display device according to claim 9, wherein the plurality of display units are developed laterally and arranged in the same plane.

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