KR102182822B1 - Display apparatus - Google Patents

Abstract

A display device according to an embodiment of the present invention includes: a display panel on which an image is output; A bezel in the form of a square frame surrounding an edge of the display panel; And a calibration device disposed between a front surface of the display panel and a rear surface of the bezel, and having an imaging unit for photographing a calibration screen displayed on the display panel, The imaging unit may be positioned in front of the display panel by sliding from the rear of the bezel toward the center of the display panel.

Description

Display apparatus

The present invention relates to a display device.

In a display device such as a TV, a high-speed digital interface exists between a main chip and a memory for system driving, video processing, and audio processing. In addition, in order to optimize the operation of the memory, a calibration process is performed according to temperature and application.

The calibration of the display device is generally performed at the time of product production at the factory, and the display device is produced with a specific register setting value determined.

A conventional technique for calibration used in TVs and the like is disclosed in Korean Patent No. 10-0775889.

In the case of a conventional calibration device, the calibration device rotates at a corner of the bezel and is exposed to the outside of the bezel. In addition, when the calibration device is not operated, it is located behind the bezel and is not exposed to the outside.

However, the display device provided with the calibration device disclosed in the registered patent has the following problems.

In detail, in order for the calibration device to rotate and be exposed to the front of the display panel, a portion of the inner edge of the bezel corresponding to the rotation trajectory of the calibration device must be cut. Accordingly, various foreign substances including dust are introduced into the display device through the cut space, causing electrical problems in the display panel and internal electronic components as well as the driving means for driving the calibration device, or due to foreign substances. There may be a problem that the drive means is not smoothly operated.

The present invention has been proposed to improve the above problems.

A display device according to an embodiment of the present invention having the above configuration includes: a display panel on which an image is output; A bezel in the form of a square frame surrounding an edge of the display panel; And a calibration device disposed between a front surface of the display panel and a rear surface of the bezel, and having an imaging unit for photographing a calibration screen displayed on the display panel, The imaging unit may be positioned in front of the display panel by sliding from the rear of the bezel toward the center of the display panel.

The calibration device may include a housing fixed to a rear surface of the bezel; A transfer module mounted on the housing; A moving member horizontally moving along the transfer module while being connected to the transfer module; And a slider mounted on a rear surface of the imaging unit, placed on an upper surface of the moving member, and slid to a certain area of the front surface of the display panel outside the inner rim of the bezel and exposed to the outside.

The bezel may include a front portion covering a front edge of the display panel; An inner portion bent rearward at an inner end of the front portion; And an outer portion bent rearward at an outer end of the front portion, wherein the inner portion includes a horizontal inner portion; And a vertical inner portion orthogonal to the horizontal inner portion, wherein at least a portion of a corner region where the horizontal inner portion and the vertical inner portion meet is cut off, and the slider moves horizontally along the cut-out inner space.

The slider, a seating portion; A support part extending upward from the front end of the seating part; A bent portion extending upward from the rear end of the seating portion; A guide protrusion protruding from an outer surface of the support portion and an outer surface of the bent portion; And a bezel joint forming a part of an inner portion of the bezel in a basic state in which the slider is positioned behind the bezel.

The bezel joint may include a horizontal joint extending horizontally from the side of the support and forming the same plane as the horizontal inner part in the basic state; And a vertical joint defined by a portion of a side surface of the support portion on which the horizontal joint is formed, and forming the same plane as the vertical inner portion in the basic state.

The slider may further include a pair of guide holes extending in the left-right direction of the seating portion in regions of a front end and a rear end of the seating portion.

The transfer module, a drive motor; A lead screw connected to the rotation shaft of the drive motor; And one or more transfer guide bars supporting the movable member and guiding the sliding movement of the movable member, wherein the transfer guide bar passes through the movable member or is in close contact with the bottom surface of the movable member. It is characterized in that to support.

The moving member may include a main body horizontally moving in a horizontal direction along the transfer guide bar; A lead screw holder formed on a bottom surface of the main body and coupled to an outer peripheral surface of the lead screw; A support protrusion protruding from the upper surface of the lead screw; A pair of transfer protrusions leading to the upper surface of the lead screw and formed at points facing each other in a front-rear direction at a point separated from the support protrusion; And a pair of guide bosses protruding from the upper surface of the lead screw and respectively inserted into the pair of guide holes.

The support protrusion and the pair of transfer protrusions include an inclined surface inclined upward; And

It may include a flat surface extending horizontally from the end of the inclined surface.

The housing includes a bottom portion; A front wall extending upward from a front end portion of the bottom portion; A rear wall extending upward from a rear end of the bottom portion; And a motor housing formed on a side surface of the bottom portion to receive at least a portion of the driving motor, and a moving member guide hole for inserting the guide protrusion into the front wall and the rear wall is formed, respectively.

The moving member guide hole may include a vertical hole; And a horizontal hole extending in a horizontal direction from a lower end of the vertical hole.

A locking groove into which the transfer protrusion is inserted is formed in the lower surface of the seating portion, and the locking groove is recessed in the same shape as the transfer protrusion.

When the drive motor rotates in a first direction, the lead screw also rotates in the first direction, and when the lead screw rotates, the lead screw holder moves along the lead screw, and the moving member moves the transfer guide bar. Accordingly, it is characterized in that it slides in a direction closer to the drive motor.

When the moving member moves in a direction closer to the drive motor, the guide boss moves from one end to the other end of the guide hole, the transfer protrusion is seated in the locking groove, and the guide protrusion is from the upper end to the lower end of the vertical hole. It is characterized in that it descends.

When the guide boss is in contact with the other end of the guide hole, the transfer protrusion is seated in the locking groove, and the guide protrusion is in contact with the lower end of the vertical hole, the slider and the moving member move to one body, and the imaging It is characterized in that the addition is located in front of the display panel outside the inner portion of the bezel.

In a state in which the guide protrusion is in contact with the lower end of the vertical hole, the horizontal joint is located below the horizontal inner part.

When the guide protrusion moves to the end of the horizontal hole, the slider is stopped, and the image pickup unit is operated.

The display device according to the embodiment of the present invention having the above configuration has the following advantages.

Since the calibration device is provided at the rear of the bezel, there is an advantage that the calibration device is not exposed to the outside when the calibration operation is not performed.

In addition, a part of the calibration device may form a part of the inner rim of the bezel, so that foreign matter may be prevented from flowing into the calibration device through the bezel.

By miniaturizing the calibration device to a size corresponding to the width of the bezel, there is an advantage in that the display panel can be enlarged due to the formation of a space for accommodating the calibration device.

1 is a front view of a display device and a calibration device provided with a calibration device according to an embodiment of the present invention.
2 is a partial front view of a display device in an operating state of a calibration device according to an embodiment of the present invention.
Fig. 3 is a partial rear view of the display device in which the calibration device is in an operating state.
4 is a front perspective view of a calibration device according to an embodiment of the present invention.
5 is an exploded perspective view of the calibration device.
6 is a perspective view of a housing constituting a calibration device according to an embodiment of the present invention.
7 is a perspective view of a slider constituting a calibration device according to an embodiment of the present invention.
8 is a perspective view showing a state in which a moving member constituting a calibration device according to an embodiment of the present invention is mounted on a transfer module.
9 is a partial perspective view as viewed from the bottom of the moving member.
Fig. 10 is a rear view of a calibration device according to an embodiment of the present invention in a basic state.
11 is a rear perspective view of a bezel showing the position of the calibration device in a basic state.
12 is a side view of a calibration device according to an embodiment of the present invention showing an operation start state.
13 is a rear perspective view of a bezel showing the position of the calibration device in an operation start state.
14 is a rear view of a calibration apparatus according to an embodiment of the present invention in a state in which the slider is moved to its maximum.
15 is a rear perspective view of the bezel showing the position of the calibration device in a state in which it is moved to its maximum.
16 is a rear view of a calibration apparatus according to an embodiment of the present invention showing a state in which it begins to move to an original position.
17 is a rear view of a calibration apparatus according to an embodiment of the present invention in which the horizontal joint of the slider is located outside the inner horizontal portion of the bezel.
18 is a rear view of a calibration apparatus according to an embodiment of the present invention showing a state returned to its original position.

Hereinafter, a configuration and operation of a display device including a calibration device and a calibration device according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a front view of a display device and a calibration device including a calibration device according to an exemplary embodiment of the present invention.

Referring to FIG. 1, a display device 10 according to an embodiment of the present invention includes a display panel 12 on which an image is output, and a bezel 13 surrounding and protecting an edge of the display panel 12. And, it includes a stand 11 for supporting the display panel 12.

FIG. 2 is a partial front view of a display device in which a calibration device is in an operating state according to an exemplary embodiment of the present invention, and FIG. 3 is a partial rear view of the display device in which the calibration device is in an operating state.

2 and 3, the calibration apparatus 40 according to an exemplary embodiment of the present invention is mounted on the rear edge of the display panel 12 and is located behind the bezel 13.

In detail, when the calibration device 40 is not operated, it is hidden by the bezel 13 and is not recognized by the user's eyes. In addition, when entering the calibration mode, the calibration device 40 slides in a horizontal direction and is exposed to the outside outside the inner edge of the bezel 13. In addition, the calibration device 40 is positioned on one side of the front side of the display panel 12 to perform a calibration operation.

4 is a front perspective view of a calibration device according to an embodiment of the present invention, and FIG. 5 is an exploded perspective view of the calibration device.

4 and 5, the calibration device 40 according to the embodiment of the present invention includes a housing 41 fixed to the rear surface of the bezel 13, and a transfer provided on the inside of the housing 41. The module 44 and the moving member 43 that slides in the left and right direction by the operation of the transfer module 44, and the moving member 43 is seated on the upper surface of the moving member 43 and slides together with the moving member 43 And a slider 42 and an imaging unit 421 mounted on the front surface of the slider 42.

Here, the surface on which the imaging unit 421 is mounted is defined as the front surface of the calibration device 40, and the opposite surface is defined as the rear surface. In addition, the calibration device 40 is mounted on the rear surface of the bezel 13 so that the imaging unit 421 faces the front surface of the display panel 12. In other words, when the slider 42 slides and moves away from the rear surface of the bezel 13 for a calibration operation, the rear surface of the slider 42 faces the front of the display device 10, and the user's eyes At, the rear surface of the slider 42 is recognized.

Hereinafter, each of the components constituting the calibration device 40 will be described in detail with reference to the drawings.

6 is a perspective view of a housing constituting a calibration device according to an embodiment of the present invention.

6, the housing 41 constituting the calibration device 40 according to an embodiment of the present invention includes a bottom portion 411 and a front wall extending vertically from the front edge of the bottom portion 411 412, a rear wall 413 extending vertically from a rear edge of the bottom portion 411, and a motor housing 414 formed at a lateral edge of the bottom portion 411. In addition, a side wall may extend vertically to a lateral edge of the bottom portion 411 corresponding to the opposite side of the motor housing 414.

In addition, a moving member guide hole 415 may be formed in the front wall 412 and the rear wall 413. In detail, the moving member guide hole 415 is composed of a vertical hole 416 extending vertically and a horizontal hole 417 extending horizontally from the lower end of the vertical hole 416, so that the overall L shape can be achieved. have. By the moving member guide hole 415, the slider 42 moves vertically and horizontally to move from the rear side of the bezel 13 to the front side of the display panel 12.

7 is a perspective view of a slider constituting a calibration device according to an embodiment of the present invention.

Referring to FIG. 7, the slider 42 constituting the calibration device 40 according to the embodiment of the present invention includes a seating portion 422 that is seated on the upper surface of the moving member 43, and the seating portion 422. ) May include a support part 423 extending vertically from the front end of) and a jaw-shaped bent part 427 extending vertically from the rear end of the seating part 422.

In detail, in the seating portion 422, a pair of guide holes 426 are formed to extend a predetermined length in the left and right directions at positions facing each other. In addition, a pair of guide protrusions 428 are formed on the outer surface of the support part 423 and the outer surface of the bent part 427 at the same height, respectively. In addition, the pair of guide protrusions 428 are respectively inserted into the moving member guide holes 415 formed in the front wall 412 and the rear wall 413 of the housing 421. In addition, when the slider 42 moves, the pair of guide protrusions 428 move vertically and horizontally along the guide hole 415 of the moving member. In addition, a locking groove 429 is formed in each of the front and rear ends of the bottom surface of the mounting portion 422, and the locking groove 429 is a transfer protrusion 436 (see FIG. 8) to be described later. Part.

In addition, a mounting plate 424 is mounted on an inner side (or rear surface) of the support part 423, and an imaging unit 421 is mounted at a point above the mounting plate 424. The imaging unit 421 may be defined as a calibration sensor, and transmits an image of an inspection screen displayed on the display panel 12 to a control unit (not shown) that performs a calibration operation.

In addition, a bezel joint 425 is formed on the support part 423. In detail, the bezel joint 425 is a portion forming a part of the inner edge of the bezel 13, and in a state in which the calibration device 40 is located at the rear of the bezel 13, the bezel ( 13) to define a part of the inner edge. In more detail, among the four corner portions of the bezel 13, an inner edge portion corresponding to an inner corner of the bezel 13 on which the calibration device 40 is mounted is the slider constituting the calibration device 40 ( 42) is cut for smooth movement. That is, along the cut-out portion of the bezel 13, the slider 42 is slidable from the rear of the bezel 13 toward the center of the lower end of the display panel 12. In addition, in the cut inner rim portion, when the slider 42 moves to the rear of the bezel 13, the cut inner rim portion of the bezel 13 is not cut by the bezel joint 425. It is continuously connected to the inner rim portion, and is recognized by the user's eyes as a bezel in the form of a complete square band.

The bezel joint 425 includes a vertical joint 425a that connects a vertical rim of the cut inner rim of the bezel 13 and a horizontal joint 425b that connects the horizontal rim of the bezel 13. Include. Further, the vertical joint 425a may be a part of a side surface of the support part 423, and the horizontal joint 425b may extend horizontally from the side surface of the support part 423. In addition, the vertical joint 425a and the horizontal joint 425b may have the same width as the width of the inner edge portion of the bezel 13.

8 is a perspective view showing a state in which a moving member constituting a calibration device according to an embodiment of the present invention is mounted on a transfer module, and FIG. 9 is a partial perspective view as viewed from the bottom of the moving member.

8 and 9, the moving member 43 according to the embodiment of the present invention includes a body portion 431, a pair of guide bosses 432 protruding from the upper surface of the body portion 431, and , A pair of transfer protrusions 436 protruding from an upper front end and a rear end of the main body 431, respectively, a support protrusion 433 protruding from an upper side end of the main body 431, and the main body It includes a lead screw holder 439 formed on the bottom surface of the portion 431.

In detail, the guide boss 432 is inserted into a pair of guide holes 426 formed in the seating portion 422 of the slider 42, respectively, to transport the slider 42.

In addition, each of the pair of transfer protrusions 436 may include an inclined surface 437 that is inclined upward and a planar surface 438 that extends flat from an end of the inclined surface 437. In addition, the transfer protrusion 436 is inserted into a locking groove 429 formed on the bottom surface of the slider 42.

In addition, the support protrusion 433 may protrude upward from the side end of the main body 431 and may be formed at a point where the distance between the pair of transfer protrusions 426 is bisected. In addition, the support protrusion 433 may be formed of an inclined surface 434 and a flat surface 435 like the transfer protrusion 436.

In addition, the lead screw holder 439 may be formed in a tunnel shape on the bottom of the main body 431, and a protrusion 439a is formed on the inner circumferential surface of the lead screw holder 439. In addition, a lead screw 442 to be described later is inserted into the lead screw holder 439.

Meanwhile, the transfer module 44 includes a base plate 440 placed on the bottom surface of the housing 41, a drive motor 441 placed on a side edge of the base plate 440, and the drive motor 441 ) And a pair of transfer guide bars 443 connected to the main body 431 of the moving member 43 and the lead screw 442 connected to the rotation axis of the ). It should be noted that only one transfer guide bar 443 may be mounted, or three or more may be mounted.

In detail, the lead screw 442 is inserted through the inside of the screw holder 439, and the protrusion 439a is engaged with a spiral screw groove formed on the outer circumferential surface of the lead screw 442. In addition, as the lead screw 442 rotates, the protrusion 439a moves along the helical screw groove, so that the moving member 43 moves along the lead screw 442 and the driving motor 441 ) Move in a direction closer to or farther away. In addition, the drive motor 441 may be accommodated in a motor housing 414 provided in the housing 41.

In addition, the transfer guide bar 443 includes a first transfer guide bar inserted through the body portion 431 of the moving member 43 and a second transfer guide bar provided in close contact with the bottom surface of the body portion 431. It may include a transfer guide bar. The pair of transfer guide bars 443 may be disposed at the front and rear ends of the main body 431, respectively.

In detail, the first transfer guide bar may be connected to the main body 431 in a form penetrating from the left end to the right end of the main body 431 at a point close to the front end of the main body 431. . In addition, a step portion may be formed on a bottom surface of the rear end portion of the main body portion 431, and the step portion may be placed on the second transfer guide bar. However, it is not limited to the presented embodiment, and both the first and second transfer guide bars penetrate the main body 431 in the lateral direction of the main body 431, or the front end of the main body 431 and It should be noted that a stepped portion is formed on the bottom of the rear end, and the stepped portion is seated on the first and second transfer guide bars.

The operating mechanism of the calibration device 40 constituting the above configuration will be described in detail below with reference to the drawings.

10 is a rear view of a calibration device according to an embodiment of the present invention in a basic state, and FIG. 11 is a rear perspective view of a bezel showing the position of the calibration device in a basic state.

Referring to FIGS. 10 and 11, in a default state in which the calibration device 40 is not operated, the calibration device 40 is kept completely hidden behind the bezel 13. In this state, the bezel joint 425 provided on the slider 42 is placed on the cut-out inner rim of the bezel 13 to form the same plane as the inner rim of the bezel 13.

In detail, the bezel 13 has a front portion 131 formed in the shape of a square strip to define a front edge of the display device 10, and an inner horizontal portion bent rearward from an inner edge of the front portion 131 (132) and an inner vertical portion 135, and an outer horizontal portion 133 and an outer vertical portion 135 that are bent rearward from an outer edge of the front portion 131. Accordingly, a pair of facing inner horizontal portions 132 and a pair of facing inner vertical portions 135 are connected to each other to define an inner edge of the bezel 13. In addition, an outer edge of the bezel 13 to which a pair of outer horizontal portions 133 and a pair of opposite outer vertical portions 134 are connected to each other is defined. And, the point where the adjacent inner horizontal portion 132 and the inner vertical portion 135 meet is defined as an inner edge of the bezel 13, and the adjacent outer horizontal portion 133 and the outer vertical portion 134 meet. A point is defined as an outer edge of the bezel 13.

And, when the slider 42 is in the basic state, the horizontal joint 425b of the slider 42 forms the same plane as the inner horizontal portion 132 of the bezel 13, and the vertical joint ( 425a forms the same plane as the inner vertical portion 135 of the bezel 13. Accordingly, there is an effect that the cut-off inner edge portion of the bezel 13 is not recognized by the user.

In the basic state, the bottom portion of the slider 42 is maintained in a state placed on the transfer protrusion 436 and the support protrusion 433 protruding from the upper surface of the moving member 43. That is, the bottom surface of the seating portion 422 constituting the slider 42 remains seated on the flat surface 438 of the transfer protrusion 436 and the flat surface 435 of the support protrusion 433 do. In addition, the guide protrusions 428 protruding from the front and rear surfaces of the slider 42 are in the moving member guide holes 415 formed in the front wall 412 and the rear wall 413 of the housing 41. The inserted state, in detail, is maintained in close contact with the upper end of the vertical hole (416).

12 is a side view of a calibration device according to an embodiment of the present invention showing an operation start state, and FIG. 13 is a rear perspective view of a bezel showing a position of the calibration device in an operation start state.

12 and 13, when power is applied to the drive motor 441 of the transfer module 44 after entering the calibration mode, the lead screw 442 rotates in the first direction. Then, the lead screw holder 439 engaged with the lead screw 442 moves along the lead screw 442 in a direction closer to the driving motor 441. And, as the lead screw holder 439 moves, the main body 431 of the moving member 43 also moves, and the transfer protrusion 436 protruding from the upper surface of the main body 431 is also driven. It moves in the direction approaching the motor 441.

And, the transfer protrusion 436 is inserted into the locking groove 429 formed on the bottom surface of the slider 42, and as a result, the slider 42 descends by a distance corresponding to the height of the transfer protrusion 436 Is done. As the slider 42 descends, the upper surface of the support portion 423 of the slider 42 is spaced downward from the inner vertical portion 135 of the bezel 13. And, the horizontal joint 425b of the slider 42 is lower than the inner horizontal portion 132 of the bezel 13, so that the upper surface of the horizontal joint 425b is on the bottom surface of the inner horizontal portion 132 Located.

In addition, the guide protrusion 428 protruding from the front and rear surfaces of the slider 42 also descends, leaving the vertical hole 416 of the moving member guide hole 415 and being placed at one end of the horizontal hole 417 . Accordingly, the slider 42 is in a state in which it is movable in a direction closer to the drive motor 441.

14 is a rear view of a calibration device according to an embodiment of the present invention in a state in which the slider is moved to the maximum, and FIG. 15 is a rear perspective view of a bezel showing the position of the calibration device in a state in which the slider is moved to the maximum.

Referring to FIGS. 14 and 15, as the driving motor 441 further rotates in the first direction in the state of FIG. 13, the moving member 43 moves the driving motor along the moving guide bar 443. It moves in the direction that approaches (441).

In detail, while the transfer protrusion 436 is caught in the locking groove 429, the moving member 43 and the slider 42 move as one body. Further, the moving member 43 moves along the moving guide bar 443 until the guide protrusion 428 reaches the other end of the horizontal hole 317.

And, when the guide protrusion 428 reaches the other end of the horizontal hole 317, the vertical joint 425a of the slider 42 touches the inner horizontal portion 132 of the bezel 13 or It is in a state just before reaching. In this state, a calibration screen is displayed in an area of the display panel 12 corresponding to a point where the imaging unit 421 is located. In addition, the imaging unit 421 photographs the calibration screen and transmits it to the controller, and the controller performs a calibration operation using image information transmitted from the imaging unit 421.

16 is a rear view of a calibration apparatus according to an embodiment of the present invention showing a state in which it starts moving to an original position.

Referring to FIG. 16, when the calibration operation is completed, the drive motor 441 rotates in a second direction opposite to the first direction, so that the slider 42 moves to its original position.

In detail, when the slider 42 starts moving in a direction away from the drive motor 441, the slider 42 presses the inclined surface of the transfer protrusion 436 to the inclined surface defining the locking groove 429 Push up. Then, as the slider 42 rises, the flat surface 438 of the transfer protrusion 436 is separated from the upper surface defining the locking groove 429.

Here, as the transfer protrusion 436 moves in a direction away from the drive motor 441, the slider 42 is pushed up, but the top surface of the horizontal joint 425b is the inner horizontal side of the bezel 13. It is caught on the bottom of the part 132 and cannot be raised any more. Thus, the transfer protrusion 436 is held in the locking groove 429 until the horizontal joint 425b leaves the inner horizontal portion 132 of the bezel 13, while the moving member 43 ) And the slider 42 move in one body.

17 is a rear view of a calibration apparatus according to an embodiment of the present invention in which the horizontal joint of the slider is located outside the inner horizontal portion of the bezel.

Referring to FIG. 17, when the horizontal joint 425b of the slider 42 is out of the inner horizontal portion 132 of the bezel 13, the transfer protrusion 436 of the moving member 43 is shown in FIG. 16 Maintains the state of, or moves while maintaining the state of pushing the slider 42 further. However, due to the load of the slider 42, the transfer protrusion 436 cannot be completely separated from the locking groove 429. Therefore, even if the horizontal joint 425b deviates from the inner horizontal portion 132 of the bezel 13, the transfer protrusion 436 maintains a state caught in the locking groove 429, while the slider 42 ) And the moving member 43 move in one body.

18 is a rear view of a calibration apparatus according to an embodiment of the present invention showing a state returned to its original position.

Referring to FIG. 18, when the slider 42 returns to its original position, the guide protrusion 428 is positioned at one end of the horizontal hole 417. In a state in which the guide protrusion 428 is located at one end of the horizontal hole 417, the end of the horizontal joint 425b is lower than the inner horizontal portion 132 of the bezel 13 and the inner horizontal portion It is located on the vertical line passing through the end of (132). In this state, the slider 42 can no longer move in the horizontal direction, and the vertical joint portion 425a and the inner vertical portion 135 form the same plane.

In detail, when the guide protrusion 428 is positioned at one end of the horizontal hole 417, the drive motor 441 further rotates in a second direction to further move the transfer protrusion 436, the transfer protrusion (436) is out of the locking groove 429. Further, the transfer protrusion 436 pushes the slider 42 while moving along the inclined surface of the locking groove 429. And, when the flat surface 438 of the transfer protrusion 436 and the flat surface 435 of the support protrusion 433 are located on the bottom surface of the seating portion 422 of the slider 42, the guide protrusion 428 is It is located at the top of the vertical hole 416. In this state, the upper surface of the horizontal joint 425b forms the same plane as the inner horizontal part 132, and the upper end of the vertical joint 425a contacts the lower end of the inner vertical part 135 , The inner edge portion of the bezel 13 has a smooth L-shape. In addition, the imaging unit 421 of the calibration device 40 is completely hidden behind the bezel 13.

Meanwhile, the calibration apparatus according to the exemplary embodiments presented above may be commonly operated in the following cases.

First, a calibration process may be automatically performed before a specific content is played on the display panel 12 or when an event occurs.

Specifically, a calibration process may be automatically performed before an Ultra High Definition image, content with a lot of motion, a movie, or a natural documentary is played.

In addition, when entering a gallery site or folder with high-resolution photos, when entering a specific website, when an application requiring high resolution is executed, or when referring to additional broadcast information, a calibration process may be automatically performed.

In addition, when the display device is not turned on for a long time, when the average image quality falls below a certain value, or when a temperature change occurs, the calibration process is automatically performed or a notification pop-up window recommending the user to perform the calibration process is displayed. You may.

In addition, when a section in which a new mode is required for a set time period is started, such as when a scene changes during content playback, the calibration process may be automatically started.

In addition, when it is determined that a calibration process is necessary because of any of the above cases, the calibration process is automatically performed when the display device is turned off, or automatically performed when the display device is turned on again, and then the image is displayed. Can be printed.

In addition, when a calibration process starts during content playback, playback of the corresponding content may be stopped until the calibration process ends.

Claims (17)

A display panel on which an image is output;
A bezel in the shape of a rectangular frame surrounding an edge of the display panel; And
An imaging unit disposed between the front surface of the display panel and the rear surface of the bezel to photograph a calibration screen displayed on the display panel, and the imaging unit mounted on the rear surface, and the front surface of the display panel beyond the inner edge of the bezel It includes a calibration device having a slider that is exposed to the outside by sliding to a certain area of the part,
The imaging unit,
It slides from the rear of the bezel in the direction of the center of the display panel, and is located in front of the display panel,
The slider is
A display device, characterized in that the display device moves horizontally along an inner space cut out in a corner region where a horizontal inner portion and a vertical inner portion of the bezel meet. The method of claim 1,
The calibration device,
A housing fixed to the rear surface of the bezel;
A transfer module mounted on the housing; And
Further comprising a; moving member horizontally moving along the transfer module while connected to the transfer module,
The slider is a display device that is raised on the upper surface of the moving member. The method of claim 2,
The bezel,
A front portion covering the front edge of the display panel;
An inner portion bent rearward at an inner end of the front portion; And
It includes an outer portion bent rearward at the outer end of the front portion,
The inner part,
The horizontal inner part; And
Including the vertical inner portion orthogonal to the horizontal inner portion
Display device. The method of claim 3,
The slider,
Seating part;
A support part extending upward from the front end of the seating part;
A bent portion extending upward from the rear end of the seating portion;
A guide protrusion protruding from an outer surface of the support portion and an outer surface of the bent portion; And
A display device comprising: a bezel joint forming a part of an inner portion of the bezel in a basic state in which the slider is positioned behind the bezel. The method of claim 4,
The bezel joint,
A horizontal joint extending horizontally from the side of the support and forming the same plane as the horizontal inner portion in the basic state; And
A display device comprising a vertical joint defined by a portion of a side surface of the support portion on which the horizontal joint is formed, and forming the same plane as the vertical inner portion in the basic state. The method of claim 5,
The slider,
A display device further comprising a pair of guide holes extending in a left-right direction of the seating portion in regions of a front end and a rear end of the seating portion. The method of claim 6,
The transfer module,
Drive motor;
A lead screw connected to the rotation shaft of the drive motor; And
One or more transfer guide bars supporting the moving member and guiding the sliding movement of the moving member,
The transfer guide bar is a display device characterized in that to support the moving member by penetrating the moving member or in close contact with the bottom surface of the moving member. The method of claim 7,
The moving member,
A main body horizontally moving in a horizontal direction along the transfer guide bar;
A lead screw holder formed on a bottom surface of the main body and coupled to an outer peripheral surface of the lead screw;
A support protrusion protruding from the upper surface of the lead screw;
A pair of transfer protrusions leading to the upper surface of the lead screw and formed at points facing each other in a front-rear direction at a point spaced apart from the support protrusion; And
A display device including a pair of guide bosses protruding from an upper surface of the lead screw and respectively inserted into the pair of guide holes. The method of claim 8,
The support protrusion and the pair of transfer protrusions,
An inclined surface inclined upward; And
A display device including a flat surface horizontally extending from an end of the inclined surface. The method of claim 9,
The housing,
Bottom;
A front wall extending upward from a front end portion of the bottom portion;
A rear wall extending upward from a rear end of the bottom portion;
And a motor housing formed on a side of the bottom portion to accommodate at least a portion of the driving motor,
The display device, wherein the front wall and the rear wall are each formed with a moving member guide hole through which the guide protrusion is inserted. The method of claim 10,
The moving member guide hole,
Vertical hole; And
A display device comprising a horizontal hole extending in a horizontal direction from a lower end of the vertical hole. The method of claim 11,
A locking groove into which the transfer protrusion is inserted is recessed in the bottom surface of the seating portion,
The display device, characterized in that the locking groove is recessed in the same shape as the transfer protrusion. The method of claim 12,
When the drive motor rotates in the first direction, the lead screw also rotates in the first direction,
When the lead screw rotates, the lead screw holder moves along the lead screw,
The display device, wherein the moving member slides along the transfer guide bar in a direction closer to the drive motor. The method of claim 13,
When the moving member moves in a direction closer to the drive motor, the guide boss moves from one end of the guide hole to the other end,
The transfer protrusion is seated in the locking groove,
The display device, wherein the guide protrusion descends from an upper end to a lower end of the vertical hole. The method of claim 14,
When the guide boss is in contact with the other end of the guide hole, the transfer protrusion is seated in the locking groove, and the guide protrusion is in contact with the lower end of the vertical hole, the slider and the moving member move to one body, and the imaging A display device, characterized in that the additional portion is positioned in front of the display panel outside the inner portion of the bezel. The method of claim 15,
When the guide protrusion is in contact with the lower end of the vertical hole, the horizontal joint portion is located below the horizontal inner portion. The method of claim 15,
When the guide protrusion moves to the end of the horizontal hole, the slider stops, and the image pickup unit operates.

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