KR20090130549A - Mounting apparatus of display device - Google Patents

Abstract

PURPOSE: A support device of a display device is provided to rotate each sliding unit at both sides of a fixing unit, thereby minimizing installation location restriction of the support device. CONSTITUTION: A fixing unit(10) is fixed to a mounting location. A height controlling unit(20) moves against the fixing unit vertically. A pair of sliding units(30) are pivotally connected to the both sides of the height controlling unit. A pair of device mounting units perform up/down tilting about each sliding unit.

Description

Mounting apparatus of display device

This embodiment relates to a support device for a display device.

A display device is a device for viewing an image, and in recent years, many flat display devices capable of being shaped in an almost two-dimensional plane have been released. These flat display devices are not only provided in a flat structure but also light in weight, so that they are often mounted on a wall and viewed. In view of this situation, various types of support devices for wall-mounted display devices have been introduced.

The support device includes a fixing part fixed to a wall, a device seating part on which a display device is mounted, and a connection unit connecting the fixing part and the device seating part. The connection unit consists of a plurality of links. Therefore, the display device can be moved forward and backward and swiveled with respect to the wall by the operation of a plurality of links.

However, according to the conventional support device, since the front and rear movement of the display device is made by a plurality of links, stress is concentrated on the hinge axis of each link, which may cause the support device to be broken.

In addition, since the plurality of links are configured to overlap, the front and rear widths of the support device become large, which causes a problem in that the distance from the wall surface to the display device becomes large.

An object of the present embodiment is to propose a support device for a display device that can achieve a reduction in product size, no limitation in installation position, and a simple structure.

According to an aspect, a support apparatus of a display apparatus includes a fixing part fixed to a fixed position; A device seating unit in which a display device is installed; And a sliding unit interposed between the fixing part and the device seating part and configured to include a plurality of sliding members so that the device seating part is moved back and forth with respect to the fixing part as the length of the vehicle is changed.

According to another aspect of a display device, a support device includes: a fixing part fixed at a fixed position; A plurality of sliding units rotatable relative to the fixed portion; A device seating unit, which is rotatable with respect to each of the sliding units and moves with the display device, includes a first sliding member rotatable with respect to the fixing unit and a second sliding member with respect to the first sliding member. A sliding member is included.

According to the proposed embodiment, the fixing part is located in the middle of the supporting device, and as the respective sliding units are rotated at both sides of the fixing part, there is an advantage of minimizing the restriction of the installation position of the supporting device. That is, since the fixing part can be fixed to the narrow wall or the indoor column, the installation position of the support device is diversified.

In addition, the device seating portion may move forward by the sliding action of the sliding unit, so that the stress acting on the hinge point of the sliding unit in the process of rotating the sliding unit relative to the height adjustment unit to the respective sliding members. Since it is dispersed, there is an advantage that the fear of breakage of the support device is eliminated.

In addition, since the height adjusting unit is configured to move up and down with respect to the fixing part, the user can easily adjust the height of the display device while the display device is seated on the device seating portion.

In addition, since the minimum moving distance of the height adjusting unit corresponds to the interval between each of the hanging grooves of the frame, the user can finely adjust the vertical height of the display device, the user can be positioned to the display device at the desired height Thus, the user's preferences can be satisfied.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a support apparatus of a display apparatus according to the present embodiment.

Referring to FIG. 1, the support device 1 of the display device according to the present embodiment includes a fixing part 10 fixed to a mounting position such as a wall surface, and a height adjusting unit movable up and down with respect to the fixing part 10. 20, a pair of sliding units 30 rotatably connected to both sides of the height adjustment unit 20, and as long as vertical tilting is performed with respect to each of the sliding units 30, and the display device is seated. A pair of device seating portions 50 and a tilting friction portion 40 are provided between the sliding unit 30 and the device seating portion 50 to provide frictional force to the vertical tilting movement.

The height adjusting unit 20 moves up and down along the fixing part 10 and is fixed to the fixing part 10 at the moved position. The pair of sliding units 30 are each composed of a plurality of sliding members that are slidable to each other, so that the front and rear movement of the device mounting portion 50 by the sliding action of the plurality of sliding members.

The tilting friction part 40 is provided between the sliding unit 30 and the device seating part 50 so that when the device seating part 50 tries to tilt in the vertical direction, the angle selected by the user is selected. Provides the frictional force that the device can maintain its position in.

In detail, the fixing part 10 is formed to extend in the vertical direction and is coupled to the frame 14 for guiding the vertical movement of the height adjusting unit 20, and to the upper and lower sides of the frame 14, and fixed to a wall surface or the like. The installation bracket 11 is included. Each of the mounting brackets 11 is provided with a plurality of holes 12 through which a fastening member such as a screw passes.

The height adjustment unit 20, the movable member 21 to move up and down along the fixing portion 10, and the position of the movable member 21 is fixed at the moved position of the movable member 21 A fixed unit 24 is included.

The pair of sliding units 30 are rotatably coupled to both sides of the height adjustment unit 20. Therefore, in view of the overall structure of the support device 1, the fixing part 10 is located in the middle of the supporting device 1, and the sliding unit 30 with respect to the fixing part 10 is provided. Will rotate.

Thus, as the fixing part 10 is located in the middle of the support device 1, there is an advantage that the constraint of the installation position of the support device 1 is minimized.

That is, since the fixing part 10 can be fixed to a narrow wall or an indoor column, the installation position of the supporting device 1 becomes diverse.

2 is a perspective view illustrating a structure of a sliding unit according to the present embodiment, and FIG. 3 is a cross-sectional view taken along the line A-A of FIG. 2.

2 and 3, the sliding unit 30 according to the present embodiment includes a first sliding member 310 rotatably connected to the height adjusting unit 20, and the first sliding member 310. A second sliding member 330 slidable with respect to) is included. In addition, the second sliding member 330 includes a rotation guide 350 to be coupled to the tilting friction part 40.

A sliding guide 314 for guiding sliding of the second sliding member 330 is formed in the first sliding member 310. The sliding guide 314 is recessed from the outside of the first sliding member 310 toward the inside. The sliding guide 314 is formed in a direction parallel to the sliding direction of the second sliding member 330.

At least a portion of the second sliding member 330 is slid while being drawn in and out of the internal space of the first sliding member 310. In addition, the second sliding member 330 is provided with a guide accommodating portion 332 for accommodating the sliding guide 314. The guide accommodating part 332 is formed by being recessed in one side of the second sliding member 310. The guide accommodating part 332 is formed in a shape and size corresponding to the sliding guide 314.

Inside the first sliding member 310, a first guide member 320 is provided to guide the sliding of the second sliding member 330 while improving the strength of the first sliding member 310. The second guide member 340 interacts with the first guide member 320 on the outer side of the second sliding member 330.

In detail, a plurality of coupling protrusions 322 for coupling to the first sliding member 310 are formed on one side of the first guide member 320. In addition, a protrusion through hole 312 through which the plurality of coupling protrusions 322 penetrates is formed in the first sliding member 310.

In addition, a plurality of guide ribs 324 protrude from the other side surface of the first guide member 320. The plurality of guide ribs 324 are spaced apart from each other in a direction perpendicular to the sliding direction of the second sliding member 320. Each of the guide ribs 324 extends in a direction parallel to the sliding direction of the second sliding member 320. In addition, a plurality of rib insertion grooves 342 into which the guide ribs 324 are inserted are formed in the second guide member 340.

In the present exemplary embodiment, a plurality of guide ribs 324 are formed in the first guide member 320, and a plurality of rib insertion grooves 342 are formed in the second guide member 340. When a plurality of guide ribs 324 are formed in the first guide member 320, grooves are formed between the guide ribs 324, and thus, a plurality of rib insertion grooves are formed in the first guide member 320. It may also be described that a plurality of guide ribs are formed in the second guide member 340.

In addition, in the present exemplary embodiment, a first guide member 320 having a plurality of guide ribs 324 formed on the first sliding member 310 is provided, and a plurality of rib insertion grooves are formed on the second sliding member 330. Although it is described that the second guide member 340 having a 342 is formed, a plurality of guide ribs protrude from the first sliding member 310, and a plurality of ribs are inserted into the second sliding member 330. The groove may be recessed.

Meanwhile, referring to FIG. 3, the sliding limit of the second sliding member 330 is defined on the surface 311 facing the sliding guide 314 of the sliding guide 314 and the first sliding member 310. The limit setting guide 317 for setting is fastened. In addition, a first through hole 315 and a second through hole 316 through which the limit setting guide 317 passes through the sliding guide 314 and one side surface 311 of the first sliding member 310, respectively. Is formed.

In addition, an opening 334 through which the limit setting guide 317 penetrates is formed in the second sliding member 330. The opening 334 is elongated in a direction parallel to the sliding direction of the second sliding member 330. In the state where the limit setting guide 317 penetrates the opening 334, the second sliding member 330 is slid with respect to the first sliding member 310.

The limit setting guide 317 sequentially passes through the first through hole 315, the opening 334, and the second through hole 316. In the limit setting guide 317 penetrating the second through hole 316, the limit setting guide 317 is prevented from being separated from each of the through holes 315 and 316 and the opening 334. The fixing member 318 is combined. In this case, the limit setting guide 317 may be used as a screw, for example, the fixing member 318 may be a nut coupled to the screw, the limit setting guide 317 and the fixing member 318 Note that there is no limit to the structure of).

Accordingly, when the first end 334a of the opening 334 contacts the limit setting guide 317 in the process of moving the second sliding member 330 to the left in FIG. 3, the second sliding member ( 330 no longer slides to the left.

On the contrary, in the process of moving the second sliding member 330 to the right in FIG. 3, when the second end 334b of the opening 334 contacts the limit setting guide 317, the second sliding member 330 does not slide to the right.

That is, the second sliding member 330 may be slid by the length of the opening 334, more precisely by the length of the opening 334 minus the left and right widths of the limit setting guide 317. Therefore, by adjusting the length of the opening 334 according to the type of the display device, it is possible to adjust the front movement distance of the display device.

On the other hand, the rotation guide 350 is rotatably coupled to the tilting friction portion 40. The rotation guide 350 allows the tilting friction part 40 to rotate with respect to the rotation guide 350 when the display device moves forward, thereby maintaining a constant distance between the pair of device seating parts 50. It is possible to move forward in a state.

That is, when the tilting friction part 40 is not rotated with respect to each of the sliding units 30, when the pair of sliding units 30 are operated, the distance between the pair of device seating parts 50 is increased. Since the tilting friction part 40 is rotated with respect to the rotation guide 350 to prevent this, the distance between the pair of device seating parts 50 is kept constant.

Since the pair of device seats 50 are moved back and forth in a state where the display device is mounted on the pair of device seats 50, the left and right sides of the pair of device seats 50 are moved. The distance is kept constant, and the tilting friction portion 40 must be rotated relative to the sliding unit 30 in order to move back and forth while maintaining the distance between the pair of device seats 50.

4 is a perspective view showing the structure of the tilting friction portion according to the present embodiment.

Referring to FIG. 4, the tilting friction part 40 according to the present embodiment includes a first arc member 410 rotatably connected to the rotation guide 350 and the device seating part 50. The second arc member 420 is included.

A plurality of arc-shaped friction grooves 412 and 422 having the same center of rotation at a specific point are formed on the contact surfaces of the arc members 410 and 420, and the friction grooves 412 of the arc members 410 and 420. , 422 are inserted corresponding to each other. That is, each of the arc members 410 and 420 is formed in a concave-convex structure such that the protrusion of the first arc member 410 is inserted into the groove of the second arc member 420, and at the same time, the first arc member 410 The protrusion of the second arc member 420 is inserted into the groove.

By providing a plurality of corresponding friction grooves 412 and 422 in each of the single arc members, it is possible to expect the improvement of the friction force, and to obtain a large force friction force even with a small member. This has a great effect in reducing the size of the components of the support device. Each of the arc members 410 and 420 may be provided using, for example, resin. By such a resin material, noise generated at the contact surfaces of the friction grooves 412 and 422 can be reduced, and improvement in friction force can be expected.

The second arc member 420 is fastened to the device seating part 50 by a fastening member, and the second arc member 420 is provided with a fastening hole 424 for fastening the fastening member.

On the other hand, the rotation guide 350 is formed with a stopper 352 for setting the rotational limit of the tilting friction portion 40 when the device seating portion 50 is moved to the rear. As shown in FIG. 4, the stopper 352 is in close contact with the front surface of the first arc member 410 in a state where the device seating portion 50 and the sliding unit 30 are in a straight line, and thus the first arc The rotation of the member 410 is prevented, thereby preventing movement of the device seat 50 to the rear.

5 is a perspective view showing the structure of the height adjustment unit according to the present embodiment, Figure 6 is a perspective view of the moving member is removed in Figure 5, Figure 7 is a combination of the fixing unit and the frame in the state of Figure 6 A perspective view showing a released state.

5 to 7, the moving member 21 is moved up and down with respect to the frame 14 in a state in which the frame 14 is wrapped. In addition, the fixing unit 24 is rotatably coupled to the inside of the movable member 21 by a hinge and is moved up and down together with the movable member 21.

In addition, the fixing unit 24 is coupled to the frame 14 in a state where the height of the moving member 21 is adjusted so that the position of the moving member 21 is fixed.

In detail, a pair of coupling parts 22 for hinge coupling with each sliding unit 30 are formed at both sides of the movable member 21. In addition, a plurality of fastenings through which fastening members for fastening the fixing unit and the moving member 21 pass through the fixing unit 24 in a state where the fixing unit 24 is fixed to the frame 14 on the front surface of the moving member 21. The hole 23 is formed.

That is, the fixing unit 24 and the frame 14 are selectively coupled by the operation of the fixing unit 24, and the fixing unit 24 is coupled to the frame 14 while the fixing unit 24 is coupled to the frame 14. The 24 is fastened to the movable member 24 to prevent the movement of the fixed unit 24, so that the state in which the fixed unit 24 is fastened to the frame 14 can be stably maintained.

On the other hand, the fixing unit 24 includes a pair of operating lever 240. The pair of operating levers 240 includes a first operating lever 240a and a second operating lever 240b. The pair of operation levers 240 are disposed to face each other.

In addition, coupling guides 141 for selectively coupling the operation lever 240 are formed at both sides of the frame 14, respectively. Each of the coupling guides 141 is formed in the vertical direction of the frame 14.

In addition, a plurality of engaging grooves 142 are formed on surfaces of the coupling guides 141 facing each other. In addition, a plurality of locking protrusions 242 are formed on the outer surface of each of the operation levers 240 to be inserted into some of the plurality of locking grooves 142, respectively.

That is, a plurality of locking protrusions 242 are formed in one operation lever 240, and the plurality of locking protrusions 242 are selectively inserted into some of the plurality of locking grooves 142, respectively.

As the plurality of locking protrusions 242 are inserted into the plurality of locking grooves 142, the operation lever 240 and the frame 14 may be firmly coupled.

An elastic member 248 is provided between the pair of actuating levers 240. One end of the elastic member 248 is coupled to the first actuating lever 240a, and the other end is coupled to the second actuating lever 240b. In addition, the elastic member 248 has an elastic force in each of the operation lever 240 in the direction in which the engaging projection 242 of the operation lever 240 is inserted into the engaging groove 142 of the coupling guide 141. Add.

In addition, a hinge coupling hole 244 for coupling the hinge formed in the movable member 21 is formed in each of the operation levers 240. In addition, the operation levers 240 are rotated in opposite directions to each other.

In addition, each of the operation levers 240 is provided with a plurality of fastening holes 246 through which the fastening members penetrating the fastening holes 23 of the movable member 21 are fastened.

The operation of the height adjustment unit 20 will be described briefly.

A portion at which the elastic member 248 is coupled with respect to the hinge coupling hole 244 in the operating lever 240 is called an upper side, and a portion in which the locking protrusion 242 is formed is called a lower side.

First, referring to FIG. 6, in a state in which no external force is applied to each of the operation levers 240, the plurality of locking protrusions 242 of each of the operation levers 240 are formed by the elastic force of the elastic member 248. The inserted state in the locking grooves 142 is maintained. In this state, the height adjusting unit 20 is fixed to the fixing part 10.

In this state, in order for the user to adjust the height of the display device, the operating lever 240 is operated in a direction away from each other.

That is, referring to FIG. 7, the first operating lever 240a is pushed to the left to rotate in the counterclockwise direction, and the second operating lever 240b is pushed to the right to rotate in the clockwise direction. When the operation levers 240 are rotated, the elastic member 248 is extended, and the locking protrusions 242 of the operation levers 240 are removed from the plurality of locking grooves 142 so that the height adjustment unit is performed. 20 is in a state capable of moving up and down with respect to the fixing part 10.

Then, while maintaining the rotated state of each of the operation lever 240, the height adjustment unit 20 is moved to a desired height. Then, when the force applied to each of the actuating levers 240 is removed, the upper portions of the actuating levers 240 are rotated in a direction closer to each other by the restoring force of the elastic member 248. A plurality of locking projections 242 of the operation lever 240 is inserted into the plurality of locking grooves 142. Finally, the user fastens the fastening members to the respective fastening holes 23 and 246.

8 to 10 are views showing the operation of the support device of the present embodiment, Figure 8 is a view showing the forward movement operation of the support device, Figure 9 is a view illustrating the up and down tilting operation of the support device, Figure 10 The figure which shows the vertical movement of the support apparatus.

First, referring to FIGS. 1 and 8, when the pair of device seating portions 50 are pulled forward in the state of FIG. 1, a pair of sliding units 30 connected to both sides of the height adjusting unit 20 are provided. Is rotated with respect to the height adjustment unit (20). In addition, the pair of device seats 50 are moved forward by the interaction of the pair of sliding members constituting the sliding units 30. That is, each of the second sliding members 330 is slid relative to each of the first sliding members 310.

At this time, the pair of sliding units 30 operate independently of each other. Therefore, the sliding length by the sliding unit connected to one device seating part may be different from the sliding length by the sliding unit connected to another device seating part.

That is, the vertical distance between one device seat and the wall may be the same as or different from the vertical distance between the other device seat and the wall.

In addition, the tilting friction part 40 is rotated with respect to each sliding unit 30 while the device seating part 50 is moved forward. In addition, the independent operation of each of the sliding units 30 enables the left and right swivel operation of the display device installed in the device seating unit 50.

According to the present embodiment as described above, the forward movement of the device seating portion 50 is enabled by the sliding unit 30, as shown in Figure 1 the device seating portion 50 is moved to the rear of the support device The front and rear widths can be minimized. That is, since the second sliding member 330 is drawn in and out of the inner space of the first sliding member 310, the thickness of the sliding unit 30 can be slimmed down, and thus the front and rear widths of the supporting device can be slimmed down. It becomes possible.

In addition, since the device seating portion 50 may move forward by the sliding action of the sliding unit 30, the sliding unit 30 in the process of rotating relative to the height adjustment unit 20, the sliding Since the stress acting on the hinge point of the unit 30 is distributed to each of the sliding members 310 and 330, there is an advantage that the fear of damage of the support device is eliminated.

In addition, since the pair of device seating portion 50 is configured to move back and forth and to move left and right on both sides of the fixing portion 10, since the fixing portion 10 may be installed on a wall or a column having a narrow left and right width, The installation location can be varied.

Meanwhile, referring to FIG. 9, the device seating part 50 is tilted upward or downward with respect to the sliding unit 30. For example, when the device seating part 50 is tilted downward, the second arc member 420 moves along the first arc member 410. In this case, the rotated angle may be maintained by the friction force provided by the tilting friction part 40, that is, the friction force between the first arc member 410 and the second arc member 420.

At this time, if the display device was initially positioned close to the wall, the display device was first moved forward by a predetermined distance, and then tilted up and down, so that the rear surface of the display device collided against the wall during the up and down tilting motion. It is desirable not to.

Referring to FIG. 10, the height adjusting unit 20 is moved downward in the state of FIG. 1. At this time, since the height adjustment unit 20 is configured to move up and down with respect to the fixing part 10, the user can easily raise the height of the display device while the display device is seated on the device seating portion 50. Can be adjusted.

In addition, since the minimum moving distance of the height adjusting unit 20 corresponds to the distance between the engaging grooves 142 of the frame 14, the user may finely adjust the vertical height of the display device, thereby changing the user's preference. It can be satisfied.

In this case, since the up and down tilting, the left and right swivel and the forward movement of the display device are performed separately from each other, the user may eventually perform the up and down tilting, left and right swivel and forward movement independently of each other or overlap each other. The flat panel display can then be viewed by the user at any position and angle.

In the present embodiment, it is described that the sliding unit is composed of a first sliding member and a second sliding member sliding relative to the first sliding member. Alternatively, the sliding unit may be composed of three or more sliding members. For example, the first sliding member is coupled to the height adjusting unit, the second sliding member is configured to be slidable with respect to the first sliding member, and the third sliding member is configured to be slidable with respect to the second sliding member. It may be configured to be coupled to the tilting friction portion.

1 is a perspective view of a supporting device of a display apparatus according to the present embodiment.

2 is a perspective view showing the structure of a sliding unit according to the present embodiment.

3 is a cross-sectional view taken along the line A-A of FIG.

Figure 4 is a perspective view showing the structure of the tilting friction portion according to this embodiment.

5 is a perspective view showing the structure of the height adjustment unit according to the present embodiment.

Figure 6 is a perspective view of a state in which the up and down moving part is removed in FIG.

7 is a perspective view illustrating a state in which the fixing unit and the frame are released from the state of FIG. 6;

8 to 10 are views showing the operation of the support device of the present embodiment, Figure 8 is a view showing the forward movement operation of the support device, Figure 9 is a view illustrating the up and down tilting operation of the support device, Figure 10 Figure showing the vertical movement of the support device.

Claims (12)

A fixing part fixed to a fixed position; A plurality of sliding units rotatable relative to the fixed portion; Rotatable with respect to each of the sliding unit, and includes a device seat moving with the display device, The sliding unit includes a first sliding member rotatable with respect to the fixing unit and a second sliding member sliding with respect to the first sliding member. The method of claim 1, And a sliding unit disposed on both sides of the fixing unit. The method of claim 1, And a part of the second sliding member slides inside the first sliding member. The method of claim 1, The first sliding member is formed with a sliding guide for guiding the sliding of the second sliding member, the second sliding member is a support device of the display device is formed with a guide receiving portion for receiving the sliding guide. The method of claim 1, The sliding unit further includes a limit setting member for setting a sliding limit of the second sliding member. The method of claim 4, wherein The second sliding member is formed with an opening for penetrating the limit setting member, And the opening is formed to be elongated in a direction parallel to the sliding direction of the second sliding member. The method of claim 5, wherein The first sliding member is formed with a through hole for penetrating the limit setting member, And the limit setting member passes through the through hole and the opening at the same time. The method of claim 1, A height adjustment unit that is movable up and down with respect to the fixed portion is further included, And each sliding unit is rotatably coupled to both sides of the height adjusting unit. The method of claim 1, A tilting friction part interposed between the sliding unit and the device seating part to allow the device seating part to tilt up and down with respect to the sliding unit, And the tilting friction portion is rotatable with respect to the sliding unit. The method of claim 9, The tilting friction portion and the first arc member rotatably connected to the sliding unit, And a second arc member tiltable with respect to the first arc member when fastened to the device seating portion. A fixing part fixed to a fixed position; A device seating unit in which a display device is installed; And The display device includes a sliding unit interposed between the fixing part and the device seating part, the sliding unit configured to include a plurality of sliding members so that the device seating part is moved back and forth with respect to the fixing part as the length of the vehicle is changed. Device. The method of claim 11, The sliding unit includes a first sliding unit rotatable with respect to the fixed portion, And a second sliding member rotatable with respect to the device seating portion and sliding with respect to the first sliding member.

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