KR20240013467A - Display device - Google Patents

Abstract

A stand, a display device, and a lighting device are disclosed. The display device of the present disclosure includes: a display panel; a back cover that covers the rear of the display panel, to which the display panel is coupled, and has a coupling hole; In addition, it may be provided with a mount coupled to the back cover, and may include a stand supporting the back cover, and the mount may be located in the coupling hole, and one of the mount and the back cover may include, It may include a locking protrusion, and the other one of the mount and the back cover may include a locking groove, and the locking protrusion may include a first direction inserted into the locking groove or a locking protrusion opposite to the first direction. It may be possible to move in two directions.

Description

Display device {DISPLAY DEVICE}

This disclosure relates to display devices.

As the information society develops, the demand for display devices in various forms is increasing, and in response to this, in recent years, LCD (Liquid Crystal Display Device), PDP (Plasma Display Panel), ELD (Electro luminescent display), and VFD (Vacuum Fluorescent) have been developed. Various display devices such as OLED (Organic Light Emitting Diode) and OLED (Organic Light Emitting Diode) are being researched and used.

Among these, the LCD panel has a TFT substrate and a color substrate that face each other with a liquid crystal layer in between, and can display images using light provided from a backlight unit. Additionally, OLED panels can display images by depositing an organic material layer capable of emitting light on its own on a substrate on which transparent electrodes are formed.

Recently, much research has been conducted on structures that freely adjust the angle or position of the display panel.

The present disclosure aims to solve the above-described problems and other problems.

Another object may be to provide a display device with a stand supporting the head.

Another purpose may be to provide a structure that can freely adjust the angle or height of the head.

Another purpose may be to provide a structure in which the position of the stand supporting the head can be freely changed.

Another purpose may be to provide a structure that allows the stand to be coupled to or separated from the head.

Another purpose may be to provide a structure that allows the user to easily and safely attach or detach the stand from the head.

Another purpose may be to provide a structure that can prevent the stand from being unintentionally separated from the head.

Another purpose may be to provide various examples of the combined structure of a stand and a head.

Another purpose may be to provide a stand to which devices such as a head or lighting unit having a display panel are detachably coupled.

According to one aspect of the present disclosure for achieving the above or other objects, a display device includes: a display panel; a back cover that covers the rear of the display panel, to which the display panel is coupled, and has a coupling hole; In addition, it may be provided with a mount coupled to the back cover, and may include a stand supporting the back cover, the mount may be located in the coupling hole, and one of the mount and the back cover may include, It may include a locking protrusion, and the other one of the mount and the back cover may include a locking groove, and the locking protrusion may include a first direction inserted into the locking groove or a locking protrusion opposite to the first direction. It may be possible to move in two directions.

According to another aspect of the present disclosure, the stand includes: a base; a pole extending from the base and having a variable length; a support arm extending in a direction intersecting the pole and tiltably coupled to the pole; Additionally, it may include a rotatable connector that is tiltably coupled to the support arm and rotatable about at least two axes. The rotatable connector may be detachably coupled to a head provided with a display panel, and the head and the stand may be collectively referred to as a display device. The rotatable connector may be detachably coupled to a lighting unit including a light source. The lighting unit and the stand may be collectively referred to as a lighting device.

The effects of the stand, display device, and lighting device according to the present disclosure will be described as follows.

According to at least one of the embodiments of the present disclosure, a display device including a stand supporting a head can be provided.

According to at least one of the embodiments of the present disclosure, a structure capable of freely adjusting the angle or height of the head can be provided.

According to at least one of the embodiments of the present disclosure, a structure in which the position of the stand supporting the head can be freely changed can be provided.

According to at least one of the embodiments of the present disclosure, a structure capable of coupling the stand to or separating the stand from the head can be provided.

According to at least one of the embodiments of the present disclosure, a structure can be provided that allows a user to easily and safely couple the stand to or separate from the head.

According to at least one of the embodiments of the present disclosure, a structure that can prevent the stand from being unintentionally separated from the head can be provided.

According to at least one of the embodiments of the present disclosure, various examples of the coupling structure of the stand and the head can be provided.

According to at least one of the embodiments of the present disclosure, a stand on which a device such as a head or lighting unit having a display panel is detachably coupled can be provided.

Additional scope of applicability of the present disclosure will become apparent from the detailed description that follows. However, since various changes and modifications within the spirit and scope of the present disclosure may be clearly understood by those skilled in the art, the detailed description and specific embodiments such as preferred embodiments of the present disclosure should be understood as being given only as examples.

1 to 51 are diagrams showing examples of a stand, a display device, and a lighting device according to embodiments of the present disclosure.

Hereinafter, embodiments disclosed in the present specification will be described in detail with reference to the attached drawings. However, identical or similar components will be assigned the same reference numbers regardless of reference numerals, and duplicate descriptions thereof will be omitted.

The suffixes “module” and “part” for components used in the following description are given or used interchangeably only for the ease of preparing the specification, and do not have distinct meanings or roles in themselves.

Additionally, in describing the embodiments disclosed in this specification, if it is determined that detailed descriptions of related known technologies may obscure the gist of the embodiments disclosed in this specification, the detailed descriptions will be omitted. In addition, the attached drawings are only for easy understanding of the embodiments disclosed in this specification, and the technical idea disclosed in this specification is not limited by the attached drawings, and all changes included in the spirit and technical scope of the present disclosure are not limited. , should be understood to include equivalents or substitutes.

Terms containing ordinal numbers, such as first, second, etc., may be used to describe various components, but the components are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another.

When a component is said to be "connected" or "connected" to another component, it is understood that it may be directly connected to or connected to the other component, but that other components may exist in between. It should be. On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between.

Singular expressions include plural expressions unless the context clearly dictates otherwise.

In this application, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

The direction indications of up (U), down (D), left (Le), right (Ri), front (F), and back (R) shown in the drawings are only for convenience of explanation, and are hereby used in this specification. The disclosed technical idea is not limited.

1 and 2, the display device 1 may include a head 10. The head 10 can display images. The head 10 may be referred to as a display 10 or a display unit (10).

The head 10 is located on the first long side (LS1), the second long side (LS2) opposite the first long side (LS1), the first long side (LS1), and the second long side (LS2). It may include an adjacent first short side (SS1) and a second short side (SS2) opposite the first short side (SS1). Meanwhile, for convenience of explanation, the lengths of the first and second long sides LS1 and LS2 are shown and described as being longer than the lengths of the first and second short sides SS1 and SS2. It may be possible that the length of (LS1, LS2) is approximately the same as the length of the first and second short sides (SS1, SS2).

The direction parallel to the short sides (SS1, SS2) of the head 10 may be referred to as the first direction (DR1) or the vertical direction. The direction parallel to the long sides (LS1, LS2) of the head 10 may be referred to as the second direction (DR2) or the left and right direction. The direction perpendicular to the long sides (LS1, LS2) and short sides (SS1, SS2) of the head 10 may be referred to as the third direction DR3 or the front-back direction.

The direction in which the head 10 displays an image may be referred to as the front (F, z), and the opposite direction may be referred to as the rear (R). The first short side (SS1) can be called the left side (Le, x). The second short side (SS2) can be called the right side (Ri). The first long side (LS1) can be called the upper side (U, y). The second long side (LS2) can be called the bottom (D).

The first long side (LS1), the second long side (LS2), the first short side (SS1), and the second short side (SS2) may be referred to as edges of the head 10. Additionally, the point where the first long side (LS1), the second long side (LS2), the first short side (SS1), and the second short side (SS2) meet each other may be called a corner.

The point where the first short side (SS1) and the first long side (LS1) meet may be the first corner (C1). The point where the first short side (SS1) and the second long side (LS2) meet may be the second corner (C2). The point where the second short side (SS2) and the second long side (LS2) meet may be the third corner (C3). The point where the second short side (SS2) and the first long side (LS1) meet may be the fourth corner (C4).

The display device 1 may include a base 20, a pole 30, and a motion module MM.

The base 20 may have an overall flat cylinder shape. Base 20 may be placed on the ground.

The pole 30 may extend in a vertical direction. The lower end of the pole 30 may be coupled to the base 20. Pole 30 may be adjacent to the periphery of base 20.

The motion module MM may extend in a direction intersecting the pole 30. One side of the motion module (MM) may be coupled to the top of the pole 30. The other side of the motion module (MM) may be coupled to the rear side of the head (10). A rotatable connector (40) can be coupled to the rear of the head (10), and a support arm (50) can connect the head (10) and the pole (30). The rotary connector 40 may be referred to as connector 40. The base 20, pole 30, support arm 50, and rotary connector 40 may be collectively referred to as stands 20, 30, 50, and 40.

Accordingly, the head 10 may be supported by the motion module MM, the pole 30, and the base 20, and may be spaced upward from the ground.

Meanwhile, the power cable (CW) can be connected to an external power source. The plug (CWa) of the power cable (CW) may be connected to an outlet (concentric plug), and the jack (CWb) of the power cable (CW) may be connected to the base 20. A battery (not shown) may be installed in the base 20, pole 30, and/or head 10, and may be charged or discharged by power supplied through a power cable (CW). The display device receives power from the battery and can be operated while disconnected from the power cable (CW).

Referring to FIGS. 2 and 3, the head 10 may include a display panel 11, a middle cabinet 12, a frame 13, an end frame 14, and a back cover 15.

The display panel 11 may form the front of the head 10. For example, display panel 11 may be an OLED panel, an LCD panel, or an LED panel. The display panel 11 can divide an image into a plurality of pixels and output an image with color, brightness, and saturation for each pixel. The display panel 11 may be divided into an active area where images are displayed and a de-active area where images are not displayed. The display panel 11 may generate light corresponding to the colors of red, green, or blue depending on the control signal.

The middle cabinet 12 may extend along the perimeter of the display panel 11. The horizontal portion 12H may be located in front of the display panel 11. The vertical portion 12V may intersect the horizontal portion 12H and cover the side of the display panel 11. For example, the middle cabinet 12 may include metal or plastic. The middle cabinet 12 may be referred to as a side frame or guide panel.

The frame 13 may be located behind the display panel 11. Electronic components such as a printed circuit board (PCB) may be coupled to the rear of the frame 13. For example, the frame 13 may include a metal material. The frame 13 may be referred to as a mount plate or module cover.

The end frame 14 may form a perimeter of the head 10. The horizontal portion 14H may be located in front of the horizontal portion 12H of the middle cabinet 12. The vertical portion 14V may cover the side of the vertical portion 12V of the middle cabinet 12. For example, the end frame 14 may include metal or plastic.

The back cover 15 may form the rear of the head 10. The back cover 15 may cover the rear of the frame 13 and may be coupled to the frame 13.

Referring to FIGS. 3 and 4 , the backlight unit 110 may be located between the display panel 11 and the frame 13 and may be coupled to the frame 13. At this time, the display panel 11 may be referred to as an LCD panel. The backlight unit 110 may include an optical layer 111 and an optical sheet 112. The optical layer 111 may include a substrate 111a, at least one light source 111b, a reflective sheet 111c, and a diffusion plate 111d.

The substrate 111a may be coupled to the front of the frame 13. The substrate 111a may have a plate shape or may be composed of a plurality of straps spaced apart from each other in the vertical direction. At least one light source 111b may be mounted on the substrate 111a. For example, the light source 111b may include a light emitting diode (LED). An electrode pattern for connecting the adapter and the light source 111b may be formed on the substrate 111a. The reflective sheet 111c may be located in front of the substrate 111a. The reflective sheet 111c may have a hole 111h where the light source 111b is located. The diffusion plate 111d may be located in front of the reflective sheet 111c. The spacer 111s may support the rear side of the diffuser plate 111d between the reflective sheet 111c and the diffuser plate 111d.

The optical sheet 112 may be located in front of the diffusion plate 111d. The back of the optical sheet 112 may be in close contact with the diffusion plate 111d, and the front of the optical sheet 112 may be in close contact with or adjacent to the back of the display panel 11. The optical sheet 112 may include at least one of a diffusion sheet or a prism sheet. The coupling portion 112d may be formed on at least one edge of the optical sheet 112.

Accordingly, light from the light source 111b may be provided to the display panel 11 through the diffusion plate 111d and the optical sheet 112. Meanwhile, the display panel 11 of the present disclosure may be an OLED panel or another type of panel that does not require the backlight unit 110 described above.

Referring to FIGS. 3 and 5, the backlight unit 110' may be located between the display panel 11 and the frame 13 and may be coupled to the frame 13. At this time, the display panel 11 may be referred to as an LCD panel. The backlight unit 110' may include an optical layer 111' and an optical sheet 112. The optical layer 111' may include a substrate 111a', at least one light source 111b', a reflective sheet 111f, and a light guide plate 111e. The light guide plate 111e may be located between the frame 13 and the optical sheet 112 and may be supported by the frame 13.

The substrate 111a' may be adjacent to the periphery of the light guide plate 111e and may be coupled to the frame 13. At least one light source 111b' may be mounted on the substrate 111a'. For example, the light source 111b' may include a light emitting diode (LED). An electrode pattern for connecting the adapter and the light source 111b' may be formed on the substrate 111a'. The reflective sheet 111f may be positioned between the frame 13 and the light guide plate 111e and may be supported by the frame 13.

Accordingly, light from the light source 111b' may be provided to the display panel 11 through the light guide plate 111e and the optical sheet 112. Meanwhile, the display panel 11 of the present disclosure may be an OLED panel or another type of panel that does not require the above-described backlight unit 110'.

Referring to FIG. 6, the gas springs 51 and 52 may include a cylinder 51 and a piston rod 52 connected to the cylinder 51. The cylinder 51 may be blocked at both ends. The piston rod 52 may extend in the longitudinal direction of the cylinder 51 and may have a smaller diameter than the cylinder 51. A portion of the piston rod 52 may be inserted into the cylinder 51.

These gas springs 51 and 52 may adopt a conventional gas spring structure in which compressed gas (for example, compressed nitrogen) is filled. Compressed gas may be charged inside the cylinder 51. The piston rod 52 may penetrate one surface of the cylinder 51, and a piston may be fixed to the end. The piston may be located inside the cylinder 51, and the internal space of the cylinder 51 may be divided into two spaces. The two spaces may communicate with each other through an orifice formed in the piston. The area of one surface of the piston connected to the piston rod 52 may be smaller than the area of the other surface of the piston opposite to the one surface. Accordingly, by controlling the flow of gas passing through the orifice, the overall length of the gas springs 51 and 52 can be adjusted by tensioning or compressing the gas springs 51 and 52. Gas springs 51 and 52 may be referred to as supports 51 and 52.

The first end fitting (51a) may protrude from the end of the cylinder (51). A first pin hole (51ah) may be formed in the first end fitting (51a). The first pin hole 51ah may be referred to as a first eyelet (51ah, first eyelet).

The second end fitting 52a may protrude from the end of the piston rod 52. A second pin hole (52ah) may be formed in the second end fitting (52a). The second pin hole 52ah may be referred to as a second eyelet (52ah, second eyelet).

The clip 53 may include a first clip 53a and a second clip 53b. The second end fitting (52a) may be sandwiched between the first clip (53a) and the second clip (53b). The first clip 53a may have an overall disk shape. The first clip 53a may have grooves 532 and 533 corresponding to the movement trajectory of the second end fitting 52a. The first groove 532 may be depressed in one surface 531 of the first clip 53a facing the second end fitting 51a, and the second end fitting 52a may be seated thereon. The second groove 533 may be recessed in the first groove 532 and may be spaced apart from the second end fitting 52a. The rear pin 534 may protrude from the first groove 532 and may be inserted into the second pin hole 52ah. The second clip 53b and the first clip 53a may be left and right symmetrical or may have shapes corresponding to each other.

At this time, a fastening member such as a screw may pass through the hole 53hb of the second clip 53b and be fastened to the hole 53ha of the first clip 53a. Accordingly, the second clip 53b can be coupled to the first clip 53a. Additionally, the gas springs 51 and 52 can rotate around the rear pin 534.

Meanwhile, the second upper hole 53P and the second lower hole 53Q may be formed by penetrating the clip 53 in the thickness direction of the clip 53 and may be located behind the rear pin 534. . The second upper hole 53P may be located above the second lower hole 53Q.

Referring to FIG. 7, the pole cap 39 may include a hemispherical head 391 and a rectangular parallelepiped-shaped body 392. The lower part of the clip 53 may be inserted into the groove 39G formed in the head 391. A fastening member such as a screw may pass through the hole 39Fh of the body 392 and be fastened to the hole 53Fh formed in the lower portion of the clip 53. Accordingly, the clip 53 can be fixed to the pole cap 39.

Referring to FIG. 8, the joints 42 and 43 of the rotatable connector 40 may be next to the first end fitting 51a. The joints 42 and 43 may have an overall shape of a ping-pong club. The joints 42 and 43 may include an upper part 421 and a rear part 422.

The upper part 421 may have a circular plate shape. The rear part 422 may protrude rearward from the upper part 421. The groove 423 may be depressed on one side facing the first end fitting 51a of the rear part 422. The front pin 424 may protrude from the groove 423 and may be inserted into the first pin hole 51ah. Accordingly, the gas springs 51 and 52 can rotate around the front pin 424.

Meanwhile, the first upper hole 42R and the first lower hole 42S may be formed by penetrating the rear part 422 in the thickness direction of the rear part 422 and may be located in front of the front fin 424. You can. The first upper hole 42R may be located above the first lower hole 42S.

Referring to FIG. 9, the lower arm 54 may be located above the gas springs 51 and 52. The lower arm 54 may include a first lower bar 541, a second lower bar 542, and a lower bridge 543. The first lower bar 541 and the second lower bar 542 may extend long and may be spaced apart from each other. The longitudinal direction of the lower bars 541 and 542 may correspond to a straight line connecting the first lower hole 42S and the second lower hole 53Q. The lower bridge 543 may connect the upper side of the first lower bar 541 and the upper side of the second lower bar 542.

The first lower pin (Fs) is the first hole (542a) of the second lower bar 542, the first lower hole (42S) of the rear part 422, and the first hole (542a) of the first lower bar (541). 541a) can be penetrated in sequence. One end of the lower arm 54 may be coupled to the rear part 422 by the first lower pin (Fs). The lower arm 54 can rotate around the first lower pin (Fs).

The second lower pin (Fq) is the second hole 542b of the second lower bar 542, the second lower hole 53Q of the clip 53, and the second hole 541b of the first lower bar 541. ) can be penetrated one after another. The other end of the lower arm 54 may be coupled to the clip 53 by a second lower pin (Fq). The lower arm 54 can rotate around the second lower pin (Fq).

Accordingly, the lower arm 54 can connect the clip 53 and the joints 42 and 43. The lower arm 54 may surround a portion of the gas springs 51 and 52.

Referring to FIG. 10, the upper arm 55 may be located above the lower arm 54. The upper arm 55 may include a first upper bar 551, a second upper bar 552, and an upper bridge 553. The first upper bar 551 and the second upper bar 552 may extend long and be spaced apart from each other. The longitudinal direction of the upper bars 551 and 552 may correspond to a straight line connecting the first upper hole 42R and the second upper hole 53P. The upper bridge 553 may connect the upper side of the first upper bar 551 and the upper side of the second upper bar 552.

The first upper pin (Fr) includes the first hole 552a of the second upper bar 552, the first upper hole 42R of the rear part 422, and the first hole of the first upper bar 551 ( 551a) can be penetrated in sequence. One end of the upper arm 55 may be coupled to the rear part 422 by a first upper pin (Fr). The upper arm 55 may rotate around the first upper pin (Fr).

The second upper pin (Fp) includes the second hole 552b of the second upper bar 552, the second upper hole 53P of the clip 53, and the second hole 551b of the first upper bar 551. ) can be penetrated one after another. The other end of the upper arm 55 may be coupled to the clip 53 by a second upper pin (Fp). The upper arm 55 may rotate around the second upper pin (Fp).

Accordingly, the upper arm 55 can connect the clip 53 and the joints 42 and 43. The upper arm 55 may surround a portion of the lower arm 54.

Referring to FIGS. 11 and 12, the upper protrusion 42ST may protrude downward from the lower surface of the upper part 421 and may extend in the circumferential direction of the upper part 421. The upper protrusion 42ST may extend along the arc of the upper part 421. The upper groove 42g may be formed in the central portion of the lower surface of the upper part 421. The vertical pin 42P may protrude downward from the central portion of the upper groove 42g.

The ball hinge 41 may be located below the upper part 421. The ball hinge 41 may include a body 410, a ring 41R, and a ball 41S. The ring 41R may be seated in the upper groove 42g, and the vertical pin 42P may penetrate the ring 41R. The body 410 may protrude from a side surface of the ring 41R in the radial direction of the ring 41R. The spherical ball 41S may be coupled to the end of the body 410 and may be located outside the joints 42 and 43. For example, the protrusion 41T may be formed on the surface of the ball 41S and may form the end of the ball hinge 41.

The lower part 43 may have a circular plate shape. The lower part 43 may oppose the upper part 421 with respect to the ball hinge 41. The lower part 43 and the upper part 421 may be symmetrical up and down, or may have shapes that correspond to each other. The lower protrusion 43ST may protrude upward from the upper surface of the lower part 43 and may extend in the circumferential direction of the lower part 43. The lower protrusion 43ST may extend along an arc of the lower part 43. The upper surface of the lower protrusion 43ST may contact the lower surface of the upper protrusion 42ST. A fastening member such as a screw may pass through the hole 43h of the lower part 43 and be fastened to the hole 42h of the upper part 421.

Accordingly, the lower part 43 may be coupled to the upper part 421, and the ball hinge 41 may be sandwiched between the lower part 43 and the upper part 421. The ball hinge 41 can rotate around the vertical pin 42P.

Meanwhile, a portion of the rear part 422 may be located in a cut-out (see 43e of FIG. 12, cut-out) of the lower part 43 and the upper part 421.

Referring to FIG. 13, the mount 45 may have an overall disk shape with a hole in the center. The mount body 451 may form the outer peripheral surface of the mount 45, and the engaging grooves 45a, 45b, and latch grooves may be formed on the outer peripheral surface of the mount 45. The first groove 452 may be formed by recessing from the front of the mount body 451 to the rear. The second groove 453 may be formed by recessing backward from the center of the first groove 452, and may have a smaller width than the first groove 452. The third groove 454 may be formed by recessing backward from the center of the second groove 453, and may have a smaller width than the second groove 453. The mount hole 450h may be formed through the central portion of the third groove 454 and may have a diameter equal to or larger than that of the ball 41S. Each of the first groove 452, the second groove 453, and the third groove 454 may have a ring shape.

More than half of the balls 41S may be located in front of the third groove 454. In other words, the ball 41S may penetrate the mount hole 450h, and more than half of the ball 41S may be located inside the grooves 452, 453, and 454.

The friction member 44 may be located in front of the third groove 454 and may contact the surface of the ball 41S. The inner surface of the friction member 44 may be formed along the surface of the ball 41S. For example, the friction member 44 may include materials such as rubber, silicon, and resin. For example, two friction members 44 may be provided. The first friction member 441 may be seated in the third groove 454 and may contact a stepped portion between the third groove 454 and the second groove 453. The second friction member 442 may be located in front of the first friction member 441 and may be spaced apart from a stepped portion between the first groove 452 and the second groove 453. The contact area between the second friction member 442 and the ball 41S may be larger than the contact area between the first friction member 441 and the ball 41S. The friction member 44 may be referred to as a friction washer (44).

14 and 15, the pusher 46 may be seated in the first groove 452. A fastening member such as a screw may pass through the hole 46h of the pusher 46 and be fastened to the hole 452h formed in the first groove 452. Accordingly, the pusher 46 can be fastened to the mount 45.

The rib 460C may protrude rearward from the rear of the pusher 460 and may surround the side of the friction member 44. The rib 460C may contact or be adjacent to the second groove 453 (see FIG. 13). A portion of the rear surface of the pusher 46 and the rib 460C may contact the surface of the second friction member 44 (see contact surface 460CL in FIG. 15). Accordingly, the pusher 46 can press the friction member 44 to the surface of the ball 41S. Additionally, the frictional force of the friction member 44 with respect to the ball 41S can be adjusted using the fastening member that fastens the pusher 46 to the mount 45. In other words, the more strongly the pusher 46 is fastened to the mount 45 with the fastening member, the greater the friction force can be.

15 and 16, the guide hole 46D may be formed in the center of the pusher 46, and the protrusion 41T may be located. The boundary of the guide hole 46D may be formed around the protrusion 41T and may limit the rotational trajectory of the ball 41S, that is, the movement trajectory of the protrusion 41T. The boundary of the guide hole 46D may be referred to as a guide wall or stopper. The guide hole 46D may be a square-shaped hole.

Rotation of the mount 45 and the pusher 46 relative to the ball hinge 41 may be restricted as the boundary of the guide hole 46D hits the protrusion 41T. Meanwhile, depending on the embodiment, the protrusion 41T may be omitted.

The cap 47 may be coupled to or contact the front of the pusher 46. The cap 47 may cover the front of the pusher 46 and may be spaced apart from the protrusion 41T.

Referring to FIG. 17, the upper cover 40C1 may be located on the rear part 422, and a fastening member such as a screw penetrates the upper cover 40C1 to form the upper hole 42ha of the rear part 422, as shown in FIG. 10). The lower cover 40C2 may be located below the rear part 422, and a fastening member such as a screw penetrates the lower cover 40C2 and is fastened to the lower hole 40hb (see FIG. 11) of the rear part 422. It can be.

The first inner cover 56a and the second inner cover 56b may oppose each other with respect to the upper arm 55, and a fastening member such as a screw penetrates the hole 55Fh of the upper arm 55. Thus, it can be fastened to the inner covers 56a and 56b.

The first outer cover 57a and the second outer cover 57b may be opposite to each other with respect to the inner covers 56a and 56b, and may be coupled or attached to the inner covers 56a and 56b.

Referring to FIG. 18, the gas springs 31 and 32 may include a cylinder 31 and a piston rod 32 connected to the cylinder 31. The cylinder 31 may be blocked at both ends. The piston rod 32 may extend in the longitudinal direction of the cylinder 31 and may have a smaller diameter than the cylinder 31. A portion of the piston rod 32 may be inserted into the interior of the cylinder 31.

These gas springs 31 and 32 may adopt a conventional gas spring structure in which compressed gas (for example, compressed nitrogen) is filled. Compressed gas may be charged inside the cylinder 31. The piston rod 32 may penetrate the lower surface of the cylinder 31, and the piston may be fixed to the end. The piston may be located inside the cylinder 31, and the internal space of the cylinder 31 may be divided into two spaces. The two spaces may communicate with each other through an orifice formed in the piston. The area of the lower surface of the piston connected to the piston rod 32 may be smaller than the area of the upper surface of the piston. Accordingly, by controlling the flow of gas passing through the orifice, the overall length of the gas springs 31 and 32 can be adjusted by tensioning or compressing the gas springs 31 and 32. The gas springs 31 and 32 may be referred to as supports 31 and 32.

The first end fitting (31a) may protrude from the end of the cylinder (31). A first pin hole (31ah) may be formed in the first end fitting (31a). The first pin hole 31ah may be referred to as a first eyelet (31ah, first eyelet).

The second end fitting (32a) may protrude from the end of the piston rod (32). A second pin hole (32ah) may be formed in the second end fitting (32a). The second pin hole 32ah may be referred to as a second eyelet (32ah).

The block 37 may include a first block 37a and a second block 37b. The first end fitting 31a may be sandwiched between the first block 37a and the second block 37b. The first block 37a may have a semi-cylindrical shape. The first groove 37g may be formed on one surface of the first block 37a facing the first end fitting 31a, and the first end fitting 31a may be seated thereon. The first pin 37P may protrude from the first groove 37g and may be inserted into the first pin hole 31ah. The second block 37b may be left and right symmetrical with the first block 37a, or may have shapes corresponding to each other. The block 37 may be referred to as a clip (37). A fastening member such as a screw may pass through the hole 370b of the second block 37b and be fastened to the hole 370a of the first block 37a. Accordingly, the second block 37b can be coupled to the first block 37a.

Holder 38 may be located between block 37 and pole cap 39. The insertion space 38g may be formed on the upper surface of the holder 38. A fastening member such as a screw may pass through the hole 38Fh formed in the holder 38 through the insertion space 38g and be fastened to the hole 37Fh of the block 37. Accordingly, the holder 38 can be coupled to the block 37. The body 392 of the pole cap 39 may be inserted into the insertion space 38g. Fastening members Ba and Bb, such as screws, may pass through the hole 38ha formed on the side of the pole cap 39 and be fastened to the hole 39h formed on the side of the body 392. Accordingly, the holder 38 can be coupled to the pole cap 39.

Referring to FIG. 19, the stopper 33S may be adjacent to the lower end of the cylinder 31 and may be fixed to the outer peripheral surface of the cylinder 31. The upper ring 33U may be located between the stopper 33S and the block 37, and the cylinder 31 may penetrate therethrough. There may be a plurality of upper rings (33U).

The spacer 35 may be adjacent to the second end fitting 32a and may be fixed to the outer peripheral surface of the piston rod 32. The thickness of the spacer 35 may be equal to the minimum gap between the second end fitting 32a and the cylinder 31.

The stem 34 may include a first stem 34a and a second stem 34b. The second end fitting 32a may be sandwiched between the first stem 34a and the second stem 34b. The first stem 34a may have a semi-cylindrical shape that is long vertically. The seating portion 34S may be formed on one surface of the first stem 34a facing the cylinder 31, and a portion of the spacer 35 may be seated thereon. The groove 34g may be formed on one surface of the cylinder 31, and a portion of the piston rod 32 may be located therein. The second end fitting 32a may be seated on one surface of the cylinder 31. The second pin 34P may protrude from the one surface of the cylinder 31 and may be inserted into the second pin hole 32ah. The second stem 34b may be left and right symmetrical with the first stem 34a, or may have shapes corresponding to each other. A fastening member such as a screw may pass through the hole 341bh of the second stem 34b and be fastened to the hole 341ah of the first stem 34a. Accordingly, the second stem 34b may be coupled to the first stem 34a.

Referring to FIG. 20, the stem 34 may include a first part 341 surrounding a portion of the gas springs 31 and 32 described above, and a second part 342 connected to the first part 341. You can. The diameter of the first part 341 may be larger than the diameter of the second part 342.

The lower ring 33D may be adjacent to the first part 341 and the second part 342 may penetrate therethrough. That is, the lower ring 33D may surround a portion of the side surface of the second part 342. A plurality of lower rings 33D may be provided.

20 and 21, the inner sleeve 36 may be located below the lower ring 33D and may surround the side of the second part 342 of the stem 34. A fastening member such as a screw may pass through the hole 36h of the inner sleeve 36 and be fastened to the stem 34. Accordingly, the inner sleeve 36 can be coupled to the stem 34. Meanwhile, the diameter of the lower ring 33D may be larger than the diameter of the inner sleeve 36.

21 and 22, the inner sleeve 36 may include a cover portion 361 and an insertion portion 362. The cover portion 361 may extend long in the vertical direction and cover most of the stem 34 (see FIG. 20). The insertion portion 362 may extend downward from the bottom of the cover portion 361 and cover the remaining portion of the stem 34. The diameter of the insertion part 362 may be larger than the diameter of the cover part 361. The hole 36h may be formed on the side of the insertion portion 362.

The depression 20P may be formed on the upper surface of the base 20. The depression 20P may be located around the base 20. The shape and diameter of the recessed portion 20P may correspond to the shape and diameter of the insertion portion 362.

The outer sleeve (30M) may be located between the insertion portion 362 and the head 391 of the pole cap 39, and may form the outer surface of the pole 30. The upper part of the outer sleeve 30M may be coupled to the holder 38 through fastening members (Ba, Bb, see FIG. 18). For example, the fastening members Ba and Bb may penetrate the outer sleeve 30M and be coupled to the holder 38, and the heads of the fastening members Ba and Bb may be caught on the surface of the outer sleeve 30M. there is.

Referring to FIGS. 22 and 23, the first hole 34h may be formed at the bottom of the stem 34. The second hole 20Ph may be formed in the depression 20P and may be aligned with the first hole 34h. The insertion portion 362 may be inserted into the recessed portion 20P, and a fastening member such as a screw may penetrate the second hole 20Ph from below the recessed portion 20P and be fastened to the first hole 34h. there is. Accordingly, the pole 30 can be coupled to the base 20.

Meanwhile, depending on the embodiment, one of the first hole 34h and the second hole 20Ph may be a pin hole, and a pin inserted into the pin hole may be located in the other one. The pin and the pin hole may be electrically connected by contacting each other. In this case, through the electrical connection between the pin and the pin hole, the electronic components installed on the base 20 and the electronic components installed on the pole 30, support arm 50, and/or head 10 are electrically connected to each other. You can.

A plurality of wheels 20W1, 20W2, 20W3, 20W4, and 20W5 may be mounted on the lower surface of the base 20. Accordingly, the user can freely move the display device placed on the ground.

Referring to FIGS. 24 and 25 , a plurality of electronic components M1, M2, and M3 may be located between the display panel 11 and the back cover 15. For example, a plurality of electronic components M1, M2, and M3 may be mounted on the front of the back cover 15. For another example, the plurality of electronic components M1, M2, and M3 may be mounted on the front or back of the frame 13 (see FIG. 3) located in front of the back cover 15. Examples of a plurality of electronic components (M1, M2, M3) are as follows.

The power supply board (M1) can provide power to each component of the display device. For example, a rechargeable battery may be mounted on the head 10, pole 30, and/or base 20, and may be connected to the power supply board M1. The main board (M2) can control the display device. A timing controller board (TC) may be electrically connected to the display panel 11 through a cable (not shown) and may provide an image signal to the display panel 11.

The coupling hole 15H may be formed in the center of the back cover 15 and may be aligned with the rotatable connector 40. A portion of the rotatable connector 40 may pass through the coupling hole 15H.

The first latch projection 15F may be formed on a portion of the back cover 15 that forms a boundary of the coupling hole 15H. The second latch projection 16F may be opposite the first latch projection 15F with respect to the rotary connector 40.

The first latch groove 45a may be formed in the mount 45 and may be caught on the first latch protrusion 15F. A second latch groove 45b may be formed in the mount 45 and may be caught on the second latch protrusion 16F.

Accordingly, the rotatable connector 40 can be detachably coupled to the back cover 15. Alternatively, the rotary connector 40 may be coupled to the back cover 15 by a fastening member such as a screw penetrating the cap 47 and fastening to the coupling plate 15PL. Alternatively, the rotary connector 40 may be coupled to the back cover 15 by magnetically coupling the magnet provided in the cap 47 to the coupling plate 15PL (including iron (Fe) material).

Referring to FIG. 26, the rotatable connector 40 can be coupled to the head 10, and the support arm 50 can connect the rotatable connector 40 and the pole 30.

The piston rods 32 of the gas springs 31 and 32 may be fixed to the stems 341 and 342, and the cylinders 31 of the gas springs 31 and 32 may move up and down (see Mv). Accordingly, the height of the head 10 relative to the ground can be adjusted.

6 and 27, a stepped portion (TL) of the clip 53 may be formed between one surface 531 and the first groove 532. The step portion TL may extend along a parabola. The first straight portion TL1 of the step portion TL may extend along the first straight line LN1. The second straight portion TL2 of the step portion TL may extend along the second straight line LN2. The curved portion TL3 of the step portion TL may connect the first straight portion TL1 and the second straight portion TL2. The angle between the first straight portion TL1 and the second straight portion TL2 may be an acute angle.

The end of the second end fitting 52a may contact the curved portion TL3. The curvature of the curved portion TL3 may correspond to the curvature of the distal end of the second end fitting 52a. The gas springs 51 and 52 may rotate about the second tilt axis F2 between the first straight part TL1 and the second straight part TL2 (see T11 and T12 in FIG. 27). The second tilt axis F2 may be the central axis of the rear fin 534. When the second end fitting 52a contacts the first straight part TL1 or the second straight part TL2, rotation of the gas springs 51 and 52 may be restricted. For example, in response to the tilting of the gas springs 51 and 52, the height of the head 10 may be raised by 90 mm upward or lowered by 90 mm from the state in which the support arm 50 is parallel to the horizontal line.

Meanwhile, the second upper fin (Fp) and the second lower fin (Fq) may be located behind the second tilt axis (F2). The second lower pin (Fq) may be located above the second tilt axis (F2), and the second upper pin (Fp) may be spaced upward from the second lower pin (Fq). The second upper fin (Fp) and the second lower fin (Fq) may be located on a vertical line.

9 and 27, a stepped portion (TR) may be formed between the rear part 422 and the groove 423. The step portion (TR) may extend along the swoosh. The step portion TR may include a straight portion TR1 and a curved portion TR2.

The peripheral surface of the first end fitting 51a may include a first straight part 51a1, a second straight part 51a2, and a round part 51a3. The first straight part 51a1 and the second straight part 51a2 may extend in the longitudinal direction of the gas springs 51 and 52. The round part 51a3 can connect the first straight part 51a1 and the second straight part 51a2 and contact the curved part TR2. The curvature of the round part 51a3 may correspond to the curvature of the curved part TR2. The gas springs 51 and 52 may rotate about the first tilt axis F1. The first tilt axis F1 may be the central axis of the front fin 424. When the curved portion TR2 contacts the first straight portion 51a1 or the second straight portion 51a2, rotation of the gas springs 51 and 52 may be restricted.

Meanwhile, the first upper fin (Fr) and the first lower fin (Fs) may be located in front of the first tilt axis (F1). The first upper fin (Fr) may be located parallel to or below the first tilt axis (F1), and the first lower fin (Fs) may be spaced downward from the first upper fin (Fr). The first upper fin (Fr) and the first lower fin (Fs) may be located on a vertical line.

27 and 28, the load W10 of the head 10 may act as a reaction force W11 on the ball hinge 41, and the reaction force W11 may act as a reaction force W12 on the rear part 422. You can.

For example, the weight of the head 10 may be 4.5 kg, and the horizontal distance D40 between the first upper pin (Fr) and the second upper pin (Fp) may be 215.5 mm. At this time, the moment to lower the rear part 422 due to the load of the head 10 may be about 969.75 kgf·mm, which is the product of the reaction force (W12) and the horizontal distance (D40). For example, the horizontal distance D50 between the first tilt axis F1 and the second upper pin Fp may be 201.8 mm. At this time, the moment to raise the rear part 422 by the gas springs 51 and 52 may be the product of F (Gas), Sin (theta), and the horizontal distance (D50), and this moment to raise is the above-mentioned lowering moment. When is equal to the moment (969.75kgf·mm), the head 10 can maintain equilibrium without sagging. Here, theta may be an angle (acute angle) between the longitudinal direction of the gas springs 51 and 52 of the support arm 50 parallel to the horizontal line and the horizontal line. That is, F(Gas) is the longitudinal force of the gas springs 51 and 52, and can be 4.806kgf·mm/Sin(theta) for the above equilibrium. As theta is greater than 0, the gas springs 51 and 52 may be advantageous in maintaining the above equilibrium.

For example, the angle (theta 50) between the gas springs (51, 52) and the horizontal line may be 4.6 degrees, and the horizontal distance (D50) between the first tilt axis (F1) and the second upper pin (Fp) may be It could be 201.8mm. At this time, the moment to raise the rear part 422 by the gas springs 51 and 52 is the product of F (Gas), Sin (4.6 degrees), and horizontal distance (D50), that is, 16.2 × F (Gas) kgf · It can be mm. Here, F (Gas) may be the force of the gas springs 51 and 52, and when it corresponds to about 60 kg (≒ 969.75/16.2), the moment to lower and the moment to raise the rear part 422 can be balanced. .

Accordingly, the support arm 50 is a gas spring inclined with respect to the longitudinal direction of the support arm 50, that is, the horizontal direction, in a state parallel to the horizontal line (see the support arm 50 located in the center of T11 and T12 in FIG. 27). The head 10 can be supported by (51, 52).

Referring to FIG. 29, the support arm 50 may be tilted downward by 25 degrees (T11, see FIG. 27) from the horizontal line around the second tilt axis F2.

For example, the weight of the head 10 may be 4.5 kg, and the horizontal distance D41 between the first upper pin (Fr) and the second upper pin (Fp) may be 202.3 mm. At this time, the moment to lower the rear part 422 due to the load of the head 10 may be about 910.3 kgf·mm, which is the product of the reaction force (W12) and the horizontal distance (D41).

For example, the angle theta 51 between the gas springs 51 and 52 and the horizontal line may be 16.5 degrees, and the horizontal distance D51 between the first tilt axis F1 and the second upper pin Fp is It may be 188.7 mm, and the vertical distance (H51) between the first tilt axis (F1) and the second upper pin (Fp) may be 71.6 mm. At this time, the moment to lower the rear part 422 by the gas springs 51 and 52 is the product of F (Gas), Sin (16.5 degrees), and horizontal distance (D51), that is, 53.6 × F (Gas) kgf · It can be mm. In addition, the moment to raise the rear part 422 by the gas springs 51 and 52 is the product of F (Gas), Cos (16.5 degrees), and vertical distance (H51), that is, 68.6 × F (Gas) kgf · It can be mm. Here, F (Gas) may be the force of the gas springs 51 and 52, and when 910.3 + 53.6 × F (Gas) < 68.6 × F (Gas), that is, F (Gas) > 60 kg, the rear part (422 ) The moment to lower and the moment to raise can be in equilibrium. At this time, the length L51 of the gas springs 51 and 52 may be smaller than the length L50 of the gas springs 51 and 52 of the support arm 50 parallel to the horizontal line (see FIG. 28).

Accordingly, the support arm 50 can support the head 10 in a state inclined 25 degrees downward from the horizontal line (see the support arm 50 located at T11 in FIG. 27).

Referring to FIG. 30, the support arm 50 may be tilted upward by 25 degrees (T12, see FIG. 27) from the horizontal line around the second tilt axis F2.

For example, the weight of the head 10 may be 4.5 kg, and the horizontal distance D42 between the first upper pin (Fr) and the second upper pin (Fp) may be 202.3 mm. At this time, the moment to lower the rear part 422 due to the load of the head 10 may be about 910.3 kgf·mm, which is the product of the reaction force (W12) and the horizontal distance (D42).

For example, the angle (theta 52) between the gas springs (51, 52) and the horizontal line may be 26.9 degrees, and the horizontal distance (D52) between the first tilt axis (F1) and the second upper pin (Fp) may be It may be 188.7 mm, and the vertical distance (H52) between the first tilt axis (F1) and the second upper pin (Fp) may be 75.3 mm. At this time, the moment to lower the rear part 422 by the gas springs 51 and 52 is the product of F (Gas), Cos (26.9 degrees), and vertical distance (H52), that is, 67.1 × F (Gas) kgf · It can be mm. In addition, the moment to raise the rear part 422 by the gas springs 51 and 52 is the product of F (Gas), Sin (26.9 degrees), and horizontal distance (D52), that is, 85.3 × F (Gas) kgf · It can be mm. Here, F (Gas) may be the force of the gas springs 51 and 52, and when 910.3 + 67.1 × F (Gas) < 85.3 × F (Gas), that is, F (Gas) > 50 kg, the rear part (422 ) The moment to lower and the moment to raise can be in equilibrium. At this time, the length L52 of the gas springs 51 and 52 may be greater than the length L50 of the gas springs 51 and 52 of the support arm 50 parallel to the horizontal line (see FIG. 28).

Accordingly, the support arm 50 can support the head 10 in a state inclined 25 degrees upward from the horizontal line (see the support arm 50 located at T12 in FIG. 27).

Referring to FIG. 31, the head 10 may be spaced upward from the base 20. The user can pivot the head 10. The pivot axis may pass through the center of the head 10 and be perpendicular to the head 10, and may be defined by the ball 41S (see FIG. 15). Referring to the left picture of FIG. 31, the head 10 can be placed in landscape mode. Referring to the picture on the right of FIG. 32, the head 10 can be placed in portrait mode.

Referring to FIG. 32, the user can tilt the head 10. The tilt axis of the head 10 is a tilt axis (Axs) defined by the ball 41S (see FIG. 15), a first tilt axis (Ax1, F1, see FIG. 27), or a second tilt axis (Ax2, F2, (see FIG. 27).

The user can swivel the head 10. The swivel axis of the head 10 may be the swivel axis Ays defined by the ball 41S (see FIG. 15) or the swivel axis Ay defined by the vertical pin 42P (see FIG. 16).

The user can pivot the head 10. The pivot axis of the head 10 may be the pivot axis Azs defined by the ball 41S (see FIG. 15).

The user can adjust the height of the head 10 by adjusting the length of the pole 30.

Referring to FIG. 33, the back cover 15 may include an upper side (15U), a lower side (15D), a left side (15L), and a right side (15R). The pressed portions 151 and 152 may be formed by pressing the flat portion 150 of the back cover 15 from the rear to the front.

The first press portion 151 may be formed in the central portion of the back cover 15. The coupling hole 15H may be formed to penetrate the first press unit 151 back and forth. The first catching protrusion 15F may protrude from the inside of the first press unit 151 toward the coupling hole 15H. The opening 151FH may be opposite the first locking protrusion 15F and may be formed to penetrate the first press portion 151 up and down. The first locking protrusion 15F and the opening 151FH may be aligned vertically through the coupling hole 15H. Meanwhile, the above-described coupling plate 15PL may be coupled to the front of the first press unit 151.

The second press unit 152 may be located around the first press unit 151. The second press unit 152 may be spaced apart from the first press unit 151.

The lower boss 155 may be located between the first press unit 151 and the second press unit 152 and may be adjacent to the opening 151FH. The upper boss 156 may be located between the first press part 151 and the second press part 152, and is opposite to the lower boss 155 with respect to the first press part 151. can do.

33 and 34, the slider 16 may include a body 161 and ribs 162. The body 161 may have a square frame shape. The ribs 162 may protrude forward from the front of the body 161 and may extend along the inner circumference of the body 161. The slider 16 may be referred to as a moving frame 16 or a guide frame 16.

The hole 161H of the body 161 may be a square-shaped hole. The width W16 of the hole 161H may be equal to or larger than the width W15 of the first press unit 151. The height H16 of the hole 161H may be greater than the height H15 of the first press unit 151. Accordingly, the slider 16 may be located between the first press unit 151 and the second press unit 152. At this time, the upper side of the inner circumference of the body 161 may be spaced apart from the upper side of the first press unit 151 (see G15 in FIG. 34).

The second locking protrusion 16F may protrude from the inside of the body 161 toward the hole 161H. The second locking protrusion 16F may be located in the opening 151FH and may be vertically aligned with the first locking protrusion 15F through the coupling hole 15H. The first locking protrusion 15F and the second locking protrusion 16F may be referred to as hooks 15F and 16F.

The lower wall 165 may be formed on the rib 162 and may have a hole where the lower boss 155 is located. The lower wall 165 may surround the side of the lower boss 155. The height of the hole in the lower wall 165 may be greater than the height of the lower boss 155. That is, the lower wall 165 into which the lower boss 155 is inserted can move in the vertical direction. The rise or fall of the lower wall 165 may be limited as the lower wall 165 collides with the lower boss 155.

For example, the first lower boss 155a and the second lower boss 155b may be spaced apart from each other in the left and right directions. The first lower boss 155a may be inserted into the lower wall 165. The second lower boss 155b may be inserted into or moved away from the lower hole 165h formed in the rib 162. The slider 16 may not cover the lower side of the second lower boss 155b.

The upper wall 166 may be formed on the rib 162 and may have a hole where the upper boss 156 is located. The upper wall 166 may surround the side of the upper boss 156. The height of the hole in the upper wall 166 may be greater than the height of the upper boss 156. That is, the upper wall 166 into which the upper boss 156 is inserted can move in the vertical direction. The rise or fall of the upper wall 166 may be limited as the upper wall 166 collides with the upper boss 156.

For example, the first upper boss 156a and the second upper boss 156b may be spaced apart from each other in the left and right directions. The first upper boss 156a may be inserted into the first upper wall 166a. The second upper boss 156b may be inserted into the second upper wall 166b.

The coupling portion 163 may be formed on the rib 162 and may be adjacent to the upper side of the body 161. The seating portion 164 may be formed on the rib 162 and may be adjacent to the coupling portion 163. The coupling portion 163 and the seating portion 164 may be formed by collapsing the front surface of the rib 162 toward the rear.

For example, the first seating portion 164a and the second seating portion 164b may be spaced apart from each other in the left and right directions. The first seating part 164a may be adjacent to the right side of the body 161, and the second seating part 164b may be adjacent to the left side of the body 161. For example, the first coupling portion 163a and the second coupling portion 163b may be spaced apart from each other in the left and right directions. The first coupling portion 163a may be located between the first upper wall 166a and the first seating portion 164a, and the second coupling portion 163b may be located between the second upper wall 166b and the second seating portion. It may be located between (164b).

The seating groove 153 may be formed on the front surface of the second press unit 152 and may extend in the vertical direction. The seating groove 153 may be connected to the coupling portion 163. For example, the first seating groove 153a may be connected to the first coupling portion 163a, and the second seating groove 153b may be connected to the second coupling portion 163b.

The ground 154 may be formed by pressing the flat plate portion 150 from the rear to the front. The ground 154 may be pressed lower than the second press portion 152 and may be surrounded by the second press portion 152. The ground 154 may oppose the slider 16 with respect to the second press unit 152. The slot 15C1 may be formed to penetrate the upper part of the ground 154 back and forth and may extend left and right. The first notch 15C1a and the second notch 15C1b may be formed in a portion of the ground 154 that forms the boundary of the slot 15C1. The first shaft hole 15P1 may be formed to penetrate the second press unit 152 from side to side and may face the slot 15C1. The second axial hole 15P2 may be formed to penetrate the second press unit 152 from side to side, and may be opposite to the first axial hole 15P1 with respect to the slot 15C1.

34 and 35, hinge assembly 17 may be located in slot 15C1. The hinge assembly 17 may include a handle 171, an axis holder 173, a shaft 17P, links 172 and 174, and a bar 175. The shaft 17P may be referred to as a hinge shaft 17P, and the links 172 and 174 may be referred to as joints 172 and 174.

The handle 171 (see FIG. 37) may extend in the longitudinal direction of the slot 15C1 and may be located behind the rear of the ground 154. The height of the ground 154 may be greater than the height of the handle 171. Accordingly, the user can rotate the handle 171 while holding the bottom of the handle 171 at the rear of the ground 154.

The shaft holder 173 may protrude from the front of the handle 171 toward the slot 15C1. The shaft holder 173 may be adjacent to the upper side of the handle 171. The shaft 17P may extend in the left and right directions and may penetrate the shaft holder 173. One end of the shaft 17P may be coupled to the first shaft hole 15P1, and the other end of the shaft 17P may be coupled to the second shaft hole 15P2. The shaft holder 173 may be rotatably coupled to the shaft 17P. The first shaft holder 173a may be adjacent to the one end of the shaft 17P, and the second shaft holder 173b may be adjacent to the other end of the shaft 17P.

The links 172 and 174 may be located between the first shaft holder 173a and the second shaft holder 173b, and the shaft 17P may pass through them. Links 172 and 174 may be rotatably coupled to the shaft 17P. Links 172 and 174 may include an upper arm 172 and a lower arm 174.

The upper arm 172 may protrude from the front of the handle 171 toward the slot 15C1. The upper arm 172 may be adjacent to the upper side of the handle 171. The shaft 17P may penetrate the first hole 172h of the upper arm 172, and the upper arm 172 may be rotatably coupled to the shaft 17P. The first upper arm 172a may be adjacent to the first shaft holder 173a, and the second upper arm 172b may be adjacent to the second shaft holder 173b.

Lower arm 174 may be pivotably coupled to upper arm 172. The pivot axis may pass through the second hole 172r of the upper arm 172 and the lower arm 174. The first lower arm 174a may be pivotably coupled to the first upper arm 172a, and the second lower arm 174b may be pivotably coupled to the second upper arm 172b. The first links 172a and 174a may be located at or adjacent to the first notch 15C1a. The second links 172b and 174b may be located in or adjacent to the second notch 15C1b.

The bar 175 may extend in a vertical direction and may be located in the seating groove 153. The bar 175 may be coupled to the coupling portion 163, and the lower arm 174 may be pivotably coupled to the bar 175. A fastening member such as a screw may pass through the hole 175s of the bar 175 and be fastened to the coupling portion 163. The pivot axis may pass through the hole 175r of the bar 175 and the lower arm 174. The first bar 175a may be located in the first seating groove 153a and may connect the first lower arm 174a and the first coupling portion 163a. The second bar 175b may be located in the second seating groove 153b and may connect the second lower arm 174b and the second coupling portion 163b.

The upper stopper 179a may be located in front of the bar 175 and may be coupled to the second press unit 152. The bar 175 may be sandwiched between the ground 154 and the upper stopper 179a. That is, the upper stopper 179a may limit the forward movement of the bar 175.

The lower stopper 179b may be located in front of the slider 16 and may be coupled to the upper boss 156. That is, the lower stopper 179b may limit the forward movement of the slider 16.

The upper block 177 may be located in the front of the seating portion 164 and may be coupled to the seating portion 164 through a fastening member such as a screw. The lower block 178 may be spaced downward from the upper block 177, and the lower end of the lower block 178 is between the first press part 151 and the slider 16 and the chin of the first press part 151. (Unsigned) may be caught. The rod 176 may be positioned between the upper block 177 and the lower block 178, the upper end of the rod 176 may be fixed to the upper block 177, and the lower end of the rod 176 may be fixed to the lower block. (178) can be penetrated. An elastic member 176s, such as a spring, may surround the outer circumference of the rod 176. The first rod 176a may be fixed to the first upper block 177a and may be movably coupled to the first lower block 178a in the vertical direction. The second rod 176b may be fixed to the second upper block 177b and may be movably coupled to the second lower block 178b in the vertical direction.

The lock 18 may be located below the lower wall 165 and can be moved in the left and right directions in the guide groove 158 formed between the first press part 151 and the second press part 152. can be located The button slot 15c2 may be formed through the back cover 15, and the protrusion 182 (see FIG. 37) of the lock 18 may be located. The width of the button slot 15c2 may be larger than the width of the button 182, and the button 182 may move left and right along the button slot 15c2. The body 181 of the lock 18 may support the lower wall 165 and limit the descent of the slider 16.

Referring to FIGS. 36 and 37, the user can move the button 182 of the lock 18 to the left end of the button slot 15c2. In this case, the body 181 of the lock 18 may fall from the lower end of the lower wall 165, and the slider 16 may be placed in a state where it can be lowered. The elastic member 176s may be located between the upper block 177 and the lower block 178, and the elastic force of the elastic member 176s can support the upper block 177 and the slider 16 fixed thereto. .

The user can rotate the handle 171 around the shaft 17P in a direction away from the ground 154 (see dotted arrow in FIG. 37). In response to the rotation of the handle 171, the lower arm 174 can pivot relative to the upper arm 172 and the bar 175, and the bar 175 and the slider 16 fixed thereto are lowered. can do. At this time, the elastic member 176s can be compressed, and the second locking protrusion 16F of the slider 16 can move below the coupling hole 15H. In other words, in response to the lowering of the second locking protrusion 16F, the vertical distance between the first locking protrusion 15F and the second locking protrusion 16F may increase. The slider 16 may descend until the top of the lower boss 155 or the top of the upper boss 156 contacts the inside of the lower wall 165 or the inside of the upper wall 166.

In this case, the vertical distance between the first locking protrusion 15F and the second locking protrusion 16F may be greater than the vertical distance between the first locking groove 45a and the second locking groove 45b. The mount 45 can be inserted into the coupling hole 15H, and the first locking groove 45a can be caught on the first locking protrusion 15F. The second locking protrusion 16F may be spaced apart from the second locking groove 45b.

Referring to FIGS. 35 and 38, the user can rotate the handle 171 around the shaft 17P in a direction closer to the ground 154. In response to the rotation of the handle 171, the lower arm 174 can pivot relative to the upper arm 172 and the bar 175, and the bar 175 and the slider 16 fixed thereto rise. can do. At this time, the elastic force of the elastic member 176s can support the upper block 177 and the slider 16 fixed thereto, and the second locking protrusion 16F of the slider 16 can move toward the coupling hole 15H. there is. In other words, in response to the rise of the second locking protrusion 16F, the vertical distance between the first locking protrusion 15F and the second locking protrusion 16F may decrease. The slider 16 may rise until the lower end of the lower boss 155 or the lower end of the upper boss 156 contacts the inside of the lower wall 165 or the inside of the upper wall 166.

The user can move the button 182 of the lock 18 to the right end of the button slot 15c2. In this case, the body 181 of the lock 18 can support the lower end of the lower wall 165 and limit the descent of the slider 16.

In this case, the vertical distance between the first locking protrusion 15F and the second locking protrusion 16F may be equal to the vertical distance between the first locking groove 45a and the second locking groove 45b. The mount 45 can be inserted into the coupling hole 15H, and the first locking groove 45a can be caught on the first locking protrusion 15F. The second locking groove 45b may be caught on the second locking protrusion 16F.

Accordingly, the mount 45 can be coupled to the back cover 15 (see FIGS. 37 and 38 in that order). Additionally, the mount 45 can be separated from the back cover 15 (see FIGS. 37 and 38 in reverse order). To this end, the user can move the button 182 of the lock 18 to the left end of the button slot 15c2 and rotate the handle 171 around the shaft 17P in a direction away from the ground 154. You can do it. Accordingly, the second locking protrusion 16F can come out of the second locking groove 45b, and the user can separate the mount 45 from the back cover 15 (see Mv in FIG. 37).

39 and 40, the locking grooves 15F1, 15F2, and 15F3 may be formed in a portion of the back cover 15 that defines the boundary of the coupling hole 15H. The plurality of locking grooves 15F1, 15F2, and 15F3 may be spaced apart from each other in the circumferential direction of the coupling hole 15H. The first locking groove 15F1, the second locking groove 15F2, and the third locking groove 15F3 may be spaced apart from each other at intervals of 120 degrees.

The mount 491 may have an overall circular plate shape. The mount hole 49H may be formed in the center of the mount 491. The mount 491 and the mount hole 49H may correspond to the mount 45 and the mount hole 450H described above with reference to FIG. 16 and the like. That is, more than half of the balls 41S (see FIG. 16) of the ball hinge 41 may pass through the mount hole 49H.

The inner rib 493 may protrude from the front of the mount 491 and extend along the mount hole 49H. The inside of the inner rib 493 may contact the friction member 44 (see FIG. 16), and the friction member 44 may be pressed against the surface of the ball 41S (see FIG. 16).

The outer ribs 492a, 492b, and 492c may protrude from the front of the mount 491 and extend along the circumference of the mount 491. The plurality of outer ribs 492a, 492b, and 492c may be spaced apart from each other in the circumferential direction of the mount 491. The rigid rib 492r may be formed inside the outer ribs 492a, 492b, and 492c.

The first guide protrusion 491a may protrude from the front of the mount 491. The first guide protrusion 491a may be located between the first outer rib 492a and the third outer rib 492c. For example, the first guide protrusions 491a may be provided as a pair.

The second guide protrusion 491b may protrude from the mount 491 to the front. The second guide protrusion 491b may be located between the second outer rib 492b and the third outer rib 492c. For example, the second guide protrusions 491b may be provided as a pair.

The first pin SP1 may protrude from the front of the mount 491 and may be located between the inner rib 493 and the first outer rib 492a. The second pin SP2 may protrude from the front of the mount 491 and may be located between the inner rib 493 and the second outer rib 492b. In the circumferential direction of the mount 491, the angle between the first pin SP1 and the second pin SP2 may be an obtuse angle.

The first elastic member (SPa) may have elasticity and may be wound around the first pin (SP1). One end of the first elastic member (SPa) may be fixed to the first pin (SP1), and a portion of the first elastic member (SPa) may be spaced apart from the first elastic member (SPa) wound around the first pin (SP1). It may be dry. The rolled portion of the first elastic member (SPa) may be referred to as a curly tail. The first elastic member SPa may be a rotation spring, a torsion spring, or a spiral torsion spring.

The second elastic member (SPb) may have elasticity and may be wound around the second pin (SP2). One end of the second elastic member (SPb) may be fixed to the second elastic member (SPb), and a portion of the second elastic member (SPb) is spaced apart from the second elastic member (SPb) wound around the second pin (SP2). It may remain dried. The rolled portion of the second elastic member (SPb) may be referred to as a curly tail. The second elastic member SPb may be a rotation spring, torsion spring, or spiral torsion spring.

The opening 49P may be formed through the mount 491 and may be located between the first outer rib 492a and the second outer rib 492b.

The first slider 496 may be caught on the front of the mount 491. The handle 496a of the first slider 496 may be inserted into the opening 49P. The width of the handle 496a of the first slider 496 may be equal to or smaller than the width of the opening 49P, and the height of the handle 496a of the first slider 496 may be smaller than the height of the opening 49P. there is. Accordingly, the handle 496a can move up and down along the opening 49P. The first pin 49P1 may protrude from the front of the first slider 496.

The second slider 494 may contact the front of the mount 491 and may be located between the first outer rib 492a and the third outer rib 492c. The first slot 494h may be formed through the second slider 494 and may extend in the radial direction of the mount 491 or in a direction corresponding thereto. The first guide protrusion 491a may be inserted into the first slot 494h. For example, the first slots 494h may be provided as a pair. The second pin 49P2 may protrude from the front of the second slider 494.

The third slider 495 may contact the front of the mount 491 and may be located between the second outer rib 492b and the third outer rib 492c. The second slot 495h may be formed through the third slider 495 and may extend in the radial direction of the mount 491 or in a direction corresponding thereto. The second guide protrusion 491b may be inserted into the second slot 495h. For example, the second slots 495h may be provided as a pair. The third pin 49P3 may protrude from the front of the third slider 495.

The first locking protrusion 49a may be located between the first outer rib 492a and the second outer rib 492b and may protrude from the mount 491 in the radial direction of the mount 491. The shape of the first locking protrusion 49a may correspond to the first locking groove 15F1. The second locking protrusion 49b may protrude forward from the end of the second slider 494. The shape of the second locking protrusion 49b may correspond to the second locking groove 15F2. The third locking protrusion 49c may protrude forward from the end of the third slider 495. The shape of the third locking protrusion 49c may correspond to the third locking groove 15F3.

Referring to FIGS. 41 and 42 , the ring plate 497 may be located in front of the mount 491. The ring plate 497 may be located between the inner rib 493 and the outer ribs 492a, 492b, and 492c. The ring plate 497 may include protrusions 497P1 and 497P2 and guide slots SL1, SL2, and SL3.

The protrusions 497P1 and 497P2 may protrude rearward from the back of the ring plate 497. The first protrusion 497P1 may be inserted into the curly tail of the first elastic member SPa. The curly tail of the first elastic member SPa may be fixed to the first protrusion 497P1. The second protrusion 497P2 may be inserted into the curly tail of the second elastic member SPb. The curly tail of the second elastic member SPb may be fixed to the second protrusion 497P2.

Guide slots SL1, SL2, and SL3 may be formed through the ring plate 497. The guide slots SL1, SL2, and SL3 may extend in a direction intersecting the radial direction of the ring plate 497. The first pin 49P1 can be inserted into the first guide slot SL1 and can move along the first guide slot SL1. The second pin 49P2 can be inserted into the second guide slot SL2 and can move along the second guide slot SL2. The third pin 49P3 can be inserted into the third guide slot SL3 and can move along the third guide slot SL3.

Meanwhile, a cap (not shown) may cover the front of the ring plate 497 and may be detachably coupled to the mount 491. The cap may form the front of the mount assembly 49. The mount assembly 49 may be referred to as a mount 49.

43 and 44, the second locking protrusion 49b and the third locking protrusion 49c may be located outside or inside the mount 491 depending on the position of the handle 496a in the opening 49P. there is.

Referring to the left picture of FIG. 43 and the left picture of FIG. 44, when the handle 496a is located at the top of the opening 49P, the first pin 49P1 is located at the first end of the first slot SL1. It can be adjacent to the outer periphery of the ring plate 497. The second pin 49P2 may be located at the first end of the second slot SL2 and may be adjacent to the outer periphery of the ring plate 497. The third pin 49P3 may be located at the first end of the third slot SL3 and may be adjacent to the outer periphery of the ring plate 497. In this case, the second locking protrusion 49b and the third locking protrusion 49c may be located outside the mount 491 (see G4b, G4c). The first locking protrusion 49a may be located outside the mount 491 (see G4a).

Referring to the right picture of FIG. 43 and the right picture of FIG. 44, when the handle 496a is located at the bottom of the opening 49P, the first pin 49P1 is opposite to the first end of the first slot SL1. It may be located at the second end and adjacent to the inner periphery of the ring plate 497. The second pin 49P2 may be located at a second end of the second slot SL2 opposite to the first end and may be adjacent to the inner periphery of the ring plate 497. The third pin 49P3 may be located at a second end of the third slot SL3 opposite to the first end and may be adjacent to the inner periphery of the ring plate 497. In this case, the second locking protrusion 49b and the third locking protrusion 49c may be located inside the mount 491 (see arrow in the right picture of FIG. 43). The first locking protrusion 49a may be located outside the mount 491 (see G4a).

That is, as the handle 496a moves downward in the opening 49P, the ring plate 497 can rotate clockwise, and the second locking protrusion 49b and the third locking protrusion 49c are slotted ( It can be moved in the longitudinal direction (see 494h, 495h, FIG. 42), that is, in the direction toward the center of the mount 491. In response to this rotation of the ring plate 497, the protrusions 497P1 and 497P2 of the ring plate 497 (see Figure 41) can pull the curly tail of the spring (SPa, SPb, see Figure 40), and the spring (SPa, SPb) can be tightly wound around pins (SP1, SP2). In other words, when the user raises the handle 496a while lowering the handle 496a, the ring plate 497 can rotate counterclockwise due to the elastic force of the springs SPa and SPb, and the second jamming occurs. The protrusion 49b and the third locking protrusion 49c can move to the outside of the mount 491, and the handle 496a can move upward.

The user can position the mount assembly 49 in the coupling hole 15H while lowering the handle 496a, and hang the first locking protrusion 49a in the first locking groove 15F1. Afterwards, the user can raise the handle 496a and hook each of the second and third locking protrusions 49b and 49c into the second and third locking grooves 15F2 and 15F3, respectively. there is.

Accordingly, the mount assembly 49 can be coupled to the back cover 15. In addition, the user can separate each of the second and third locking protrusions (49b) and 49c from the second and third locking grooves (15F2) and 15F3 by lowering the handle (496a). There is, and this allows the mount assembly 49 to be separated from the back cover 15.

Referring to FIG. 45, the mount 45 or 49 of the rotatable connector 40 may be detachably coupled to the coupling hole 15H of the back cover 15.

Referring to FIG. 46, the housing 71 may be opened forward. The housing 71 may include a rear part 711, a side part 712, and a center part 713. The rear part 711 may have a circular plate shape. The side part 712 may protrude forward from the circumference of the rear part 711 and extend in the circumferential direction of the rear part 711. The opening 712a may be formed through a portion of the rear part 711. The center part 713 may be formed by pressing forward from the center of the back of the rear part 711.

The pair of fixing parts 714 may protrude forward from the front of the rear part 711 and may be located between the center part 713 and the side part 712. The pair of fixing parts 714 may be spaced apart from each other in the circumferential direction of the rear part 711.

The elastic member 73 may have an overall inverted hanger or bow shape. The grip 731 may be formed at the center of the elastic member 73. The first limb 732 may extend curvedly from one side of the grip 731. The first curve 732a can be rolled from the end of the first rim 732 toward the center part 713, and can be inserted and fixed to one of the pair of fixing parts 713. The second limb 733 may extend curvedly from the other side of the grip 731. The second curve 733a may be rolled from the end of the second rim 733 toward the center part 713, and may be inserted and fixed to the remaining one of the pair of fixing parts 713.

The slider 72 may include a body 721, a lower part 722, an upper part 723, and a button 724. The body 721 may be located between a pair of fixing parts 713 and may contact the front of the rear part 711. The lower part 722 and the upper part 723 may protrude forward from the body 721 and may oppose each other with respect to the grip 731. The grip 731 may be sandwiched between the lower part 722 and the upper part 723, and a fastening member such as a screw may penetrate the grip 731 and be fastened to the body 721. The button 724 may protrude rearward from the rear of the body 721 and may be inserted into a slot 711P to be formed on the rear of the rear part 711. The height of the button 724 may be smaller than the height of the slot 711P, and a gap G7 may be formed between the lower part 722 and the side part 712.

Accordingly, the slider 72 and the elastic member 73 fixed thereto can move up and down along the slot 711P. As the button 724 moves from the top to the bottom of the slot 711P, the elastic member 73 may be further deformed. That is, the restoring force of the elastic member 73 may act in the direction in which the button 724 moves from the bottom to the top of the slot 711P.

Referring to FIG. 47, the plate 74 may cover the front of the pair of fixing parts 714, the slider 72, and the elastic member 73. A fastening member such as a screw may pass through the hole 74h of the plate 74 and be fastened to the hole 714h of the pair of fixing parts 714. Accordingly, the plate 74 can be coupled to a pair of fixing parts 714.

The handle 79 may be coupled to the rear of the rear part 711 to enable hinge movement. The hinge axes 79H1 and 79H2 of the handle 79 may be provided inside the rear part 711 and may extend in the left and right directions. Groove 711g may be formed in rear part 711 and adjacent to handle 79.

Referring to FIG. 48, the optical assembly may be located in front of the center part 713 and may be coupled to the center part 713 through a screw coupling method or the like. The optical assembly may include a substrate 75, a light source 75L, and a switch 75B. The board 75 may be a disk-shaped PCB, and electronic components 75E, such as integrated elements, capacitors, or connectors that receive power and provide it to the light source 75L, may be mounted on the back of the board 75. there is. The light source 75L may be mounted on the front of the substrate 75 and may provide light toward the front of the substrate 75. For example, the light source 75L may be an LED or a lamp. The cover 76 may be spaced forward from the substrate 75 and may be seated and fixed to the end of the side frame 712. An air gap or buffer may be formed between the light source 75L and the cover 76, and the light of the light source 75L may spread widely in the air gap. The cover 76 is made of a light-transmitting material. For example, the cover 76 may be a diffusion plate. Accordingly, the cover 76 may emit light from the light source 75L.

Referring to FIGS. 49 to 51 , the first locking protrusion 71F may protrude from the inner peripheral surface of the center part 713. The second locking protrusion 72F may protrude upward from the upper surface of the upper part 723 and may be located in the hole 713h formed in the center part 713. In the circumferential direction of the center part 173, the first locking protrusion 71F and the second locking protrusion 72F may be spaced apart from each other at an interval of 180 degrees.

The mount 45 of the rotatable connector 40 may be coupled to a lighting unit 70. Specifically, when the user lowers the button 724 to the bottom of the slot 711P, the distance between the first locking protrusion 71F and the second locking protrusion 72F becomes the first locking groove 45a and the second locking groove. (45b) can be larger than the distance between them. The first locking groove 45a of the mount 45 can be caught on the first locking protrusion 71F and can be seated on the rear side of the center part 713. When the user releases the button 724, the button 742 can rise to the top of the slot 711P by the elastic force of the elastic member 73 (see FIG. 46), and the second locking protrusion 72F is connected to the second locking protrusion 72F. It may be caught in the catching groove (45b). Accordingly, the mount 45 can be coupled to the lighting unit 70.

The mount 45 of the rotatable connector 40 may be separated from the lighting unit 70. Specifically, when the user lowers the button 724 to the bottom of the slot 711P, the second locking protrusion 72F may fall out of the second locking groove 45b. Accordingly, the user can separate the mount 45 from the lighting unit 70 by pulling out the first locking groove 45a from the first locking protrusion 71F.

The user can turn on/off the light source 75L (see FIG. 54) using the switch 75B. In addition, the user can freely adjust the angle, height, and position of the lighting unit 70 coupled to the stand (30, 40, 50, see FIG. 2) instead of the head 10 with the stand (30, 40, 50). You can.

1 to 51, a display device according to one aspect of the present disclosure includes: a display panel; a back cover that covers the rear of the display panel, to which the display panel is coupled, and has a coupling hole; In addition, it may be provided with a mount coupled to the back cover, and may include a stand supporting the back cover, the mount may be located in the coupling hole, and one of the mount and the back cover may include, It may include a locking protrusion, and the other one of the mount and the back cover may include a locking groove, and the locking protrusion may include a first direction inserted into the locking groove or a locking protrusion opposite to the first direction. It may be possible to move in two directions.

The display device may further include an elastic member connected to the locking protrusion, and the elastic member may be elastically deformed when the locking protrusion moves in the second direction.

The locking protrusion may include: a first locking protrusion fixed to the mount or the back cover; Additionally, it may include a second locking protrusion movably coupled to the mount or the back cover in the first direction or the second direction.

The back cover includes: a slider coupled to the back cover between the back cover and the display panel; And, it may include a hinge assembly that moves the slider in the first direction or the second direction, wherein the locking protrusion: protrudes toward the coupling hole from a portion of the back cover that defines a boundary of the coupling hole. first engaging projection; Additionally, it may include a second engaging protrusion formed on the slider and opposing the first engaging protrusion with respect to the coupling hole.

The locking groove includes: a first locking groove formed on the mount and caught on the first locking protrusion; Additionally, it may include a second locking groove formed on the mount and caught by the second locking protrusion.

The distance between the first locking protrusion and the second locking protrusion may be greater than the distance between the first locking groove and the second locking groove when the second locking protrusion moves in the second direction.

The hinge assembly includes: a handle located at the rear of the back cover; a shaft extending in a direction perpendicular to the first direction and rotatably coupled to the handle; a bar extending in the first direction and fixed to the slider; And, it may include a link pivotably connected to the handle and the bar and rotatably coupled to the shaft.

The link includes: an upper arm that protrudes from the handle and is rotatably coupled to the shaft; And, it may include a lower arm having one end pivotably coupled to the upper arm and the other end pivotably coupled to the bar.

The display device may further include an elastic member supporting the slider, and the elastic member may be elastically deformed when the slider moves in the second direction.

The display device may further include a lock adjacent to the slider and movably coupled to the back cover, wherein the lock restricts movement of the slider in the second direction at a specific position. You can.

The locking groove may include: a first locking groove, a second locking groove, and a third locking groove formed in a portion of the back cover that defines a boundary of the coupling hole, and the locking protrusion is: a first locking protrusion that protrudes to the outside of the mount and is caught in the first locking groove; a second locking protrusion movably coupled to the mount and caught in the second locking groove; In addition, it may be movably coupled to the mount and include a third locking protrusion that is caught in the third locking groove.

The display device includes: a ring plate positioned between the mount and the back cover; a first slider that rotates the ring plate; a second slider movably coupled to the ring plate and on which the second locking protrusion is formed; In addition, it may further include a third slider movably coupled to the ring plate and on which the third locking protrusion is formed.

The mount includes: a pair of first guide protrusions protruding from the mount; In addition, it may include a pair of second guide protrusions protruding from the mount, and the second slider includes: a pair of first guide protrusions into which the pair of first guide protrusions are movably inserted and extending in a moving direction of the second slider. may include a first slot, and the third slider may include a pair of second slots into which the pair of second guide protrusions are movably inserted, and extending in the direction of movement of the third slider. .

Each of the second slider and the third slider may include a pin, and the ring plate may include a guide slot extending in a direction intersecting the radial direction of the ring plate and into which the pin is movably inserted. It can be included.

The display device may further include: an elastic member located between the ring plate and the mount and fixed to the mount, wherein the ring plate: protrudes from the ring plate toward the mount and is fixed to the elastic member. The elastic member may be elastically deformed when the ring plate rotates in the first rotation direction.

According to another aspect of the present disclosure, the stand includes: a base; a pole extending from the base and having a variable length; a support arm extending in a direction intersecting the pole and tiltably coupled to the pole; Additionally, it may include a rotatable connector that is tiltably coupled to the support arm and rotatable about at least two axes. The rotatable connector may be detachably coupled to a head provided with a display panel, and the head and the stand may be collectively referred to as a display device. The rotatable connector can be detachably coupled to a lighting unit including a light source. The lighting unit and the stand may be collectively referred to as a lighting device. Alternatively, the rotatable connector may be detachably coupled to a speaker, dryer, mirror, etc.

Any or other embodiments of the present disclosure described above are not exclusive or distinct from each other. In certain embodiments or other embodiments of the present disclosure described above, each configuration or function may be used in combination or combined.

For example, this means that configuration A described in a particular embodiment and/or drawing may be combined with configuration B described in other embodiments and/or drawings. In other words, even if the combination between components is not directly explained, it means that combination is possible, except in cases where it is explained that combination is impossible.

The above detailed description should not be construed as restrictive in any respect and should be considered illustrative. The scope of the present invention should be determined by reasonable interpretation of the appended claims, and all changes within the equivalent scope of the present invention are included in the scope of the present invention.

Claims (15)

display panel;
a back cover that covers the rear of the display panel, to which the display panel is coupled, and has a coupling hole; and,
It has a mount coupled to the back cover, and includes a stand supporting the back cover,
The mount is located in the coupling hole,
One of the mount and the back cover includes a locking protrusion,
The other one of the mount and the back cover includes a locking groove,
The locking protrusion is,
A display device movable in a first direction inserted into the locking groove or in a second direction opposite to the first direction. According to claim 1,
Further comprising an elastic member connected to the locking protrusion,
The elastic member is,
A display device that is elastically deformed when the locking protrusion moves in the second direction. According to claim 1,
The locking protrusion is,
a first locking protrusion fixed to the mount or the back cover; and,
A display device comprising a second locking protrusion coupled to the mount or the back cover to be movable in the first direction or the second direction. According to claim 1,
The back cover:
a slider coupled to the back cover between the back cover and the display panel; and,
A hinge assembly that moves the slider in the first direction or the second direction,
The locking protrusions are:
a first locking protrusion protruding toward the coupling hole from a portion of the back cover defining a boundary of the coupling hole; and,
A display device comprising a second engaging protrusion formed on the slider and opposing the first engaging protrusion with respect to the coupling hole. According to clause 4,
The locking groove is:
a first locking groove formed on the mount and caught on the first locking protrusion; and,
A display device comprising a second locking groove formed on the mount and caught by the second locking protrusion. According to clause 5,
The distance between the first locking protrusion and the second locking protrusion is,
When the second locking protrusion moves in the second direction, the display device is greater than the distance between the first locking groove and the second locking groove. According to clause 4,
The hinge assembly:
a handle located at the rear of the back cover;
a shaft extending in a direction perpendicular to the first direction and rotatably coupled to the handle;
a bar extending in the first direction and fixed to the slider; and,
A display device comprising a link pivotably connected to the handle and the bar and rotatably coupled to the shaft. According to clause 7,
The above link is:
an upper arm that protrudes from the handle and is rotatably coupled to the shaft; and,
A display device comprising a lower arm having one end pivotably coupled to the upper arm and the other end pivotably coupled to the bar. According to clause 4,
Further comprising an elastic member supporting the slider,
The elastic member is,
A display device that is elastically deformed when the slider moves in the second direction. According to clause 4,
Further comprising a lock adjacent to the slider and movably coupled to the back cover,
The lock is,
A display device that limits movement of the slider in the second direction at a specific location. According to claim 1,
The locking groove is:
A first locking groove, a second locking groove, and a third locking groove formed on a portion of the back cover defining a boundary of the coupling hole,
The locking protrusions are:
a first locking protrusion that protrudes from the mount to the outside of the mount and is caught in the first locking groove;
a second locking protrusion movably coupled to the mount and caught in the second locking groove; and,
A display device comprising a third locking protrusion movably coupled to the mount and caught in the third locking groove. According to claim 11,
a ring plate located between the mount and the back cover;
a first slider that rotates the ring plate;
a second slider movably coupled to the ring plate and on which the second locking protrusion is formed; and,
A display device further comprising a third slider movably coupled to the ring plate and on which the third locking protrusion is formed. According to claim 12,
The mount is:
a pair of first guide protrusions protruding from the mount; and,
It includes a pair of second guide protrusions protruding from the mount,
The second slider:
The pair of first guide protrusions are movably inserted and include a pair of first slots extending in a moving direction of the second slider,
The third slider is:
A display device including a pair of second guide protrusions into which the pair of second guide protrusions are movably inserted, and a pair of second slots extending in a moving direction of the third slider. According to claim 12,
Each of the second slider and the third slider:
Contains pins,
The ring plate:
A display device extending in a direction intersecting the radial direction of the ring plate and including a guide slot into which the pin is movably inserted. According to claim 12,
Further comprising an elastic member located between the ring plate and the mount and fixed to the mount,
The ring plate:
A protrusion protrudes from the ring plate toward the mount and is fixed to the elastic member,
The elastic member is,
A display device that is elastically deformed when the ring plate rotates in a first rotation direction.

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