CN218972305U - Synchronous regulating mechanism for display screen - Google Patents

Abstract

The utility model relates to a synchronous adjusting mechanism for a display screen, which comprises a machine frame body, a telescopic driver and a sliding and overturning adjusting frame for installing the display screen. The telescopic driver comprises a driver body and a telescopic end; one of the sliding and overturning adjusting frame and the mechanism frame body is provided with an arc-shaped guide structure, and the other one of the sliding and overturning adjusting frame and the mechanism frame body is provided with a matched guide structure capable of sliding along the arc-shaped guide structure; one of the driver body and the telescopic end is hinged with the mechanism frame body, the other one of the driver body and the telescopic end is hinged with the sliding turnover adjusting frame, and the second hinging center line is parallel to the first hinging center line; the sliding and overturning adjusting frame slides and overturns relative to the frame body by means of the sliding of the distribution guide structure along the arc-shaped guide structure under the driving of the telescopic driver, so that the display screen on the sliding and overturning adjusting frame can synchronously adjust the sliding and overturning of the sliding and overturning adjusting frame along with the sliding and overturning adjusting frame; so as to ensure the smoothness and stability of the display screen adjustment.

Description

Synchronous regulating mechanism for display screen

Technical Field

The present utility model relates to a stand for carrying one or more display screens and adjusting the position (e.g., height and angle) of the display screens as desired, and more particularly to a synchronous adjustment mechanism for display screens.

Background

With the continuous development of economy and the continuous progress of society, various substance consumer products are provided for the life of people, and a display screen is one of the substance consumer products.

At present, the display screen is widely applied to daily life of people, such as a display screen in an office computer, a display screen used in a monitoring occasion, a flat-panel television used in a home occasion and the like.

In order to make the position (such as height and angle) of the display screen adjustable, the display screen is generally installed at an adjusting bracket, and the adjusting bracket is fixed by an external object; therefore, when the position of the display screen is adjusted, an operator can adjust the adjusting bracket.

In the multi-screen support device for electrically memorizing angles disclosed in chinese patent application No. 201821500695.X, a first end of a swing arm is hinged with a base body around a first hinge shaft and a second end of the swing arm is formed into a free end, an electric push rod comprises a fixed part and a movable part which slides telescopically relative to the fixed part, the fixed part is hinged with the base body around a second hinge shaft, the movable part extends to the free end and is hinged with the free end around a third hinge shaft, and a mounting support is mounted on the free end, and the first hinge shaft, the second hinge shaft and the third hinge shaft are mutually staggered, so that when a display screen is adjusted, the movable part slides telescopically relative to the fixed part, and the movable part which slides telescopically drives the swing arm and the mounting support to swing around the first hinge shaft together, thereby realizing the functions of electrically adjusting the angles and memorizing of the display screen.

However, the above-mentioned electric angle-memorizing multi-screen bracket device can only realize the angle adjustment of a plurality of display screens, but cannot simultaneously realize the height adjustment of a plurality of display screens; meanwhile, in the angle adjustment process of the display screen, the swing arm and the mounting bracket are required to be driven to pivot around the first hinge shaft together by the telescopic sliding movable part, so that the load bearing load of the electric rod is increased, and the stable reliability of angle adjustment of the plurality of display screens following the mounting bracket is affected.

Therefore, there is a strong need for a synchronous adjustment mechanism for a display screen, which can realize smooth sliding and turning adjustment of one or more display screens, so as to overcome the above-mentioned drawbacks.

Disclosure of Invention

The utility model aims to provide a synchronous adjusting mechanism for a display screen, which can realize smooth sliding and overturning adjustment of one or more display screens.

In order to achieve the above purpose, the synchronous adjusting mechanism for the display screen comprises a machine frame body, a telescopic driver and a sliding and overturning adjusting frame for installing one or more display screens. The telescopic driver comprises a driver body and a telescopic end which stretches and slides on the driver body; one of the sliding and overturning adjusting frame and the mechanism frame body is provided with an arc-shaped guide structure extending along the Z-axis direction, and the other one of the sliding and overturning adjusting frame and the mechanism frame body is provided with a matched guide structure matched with the arc-shaped guide structure and capable of sliding along the arc-shaped guide structure; one of the driver body and the telescopic end is hinged with the mechanism frame body around a first hinge center line arranged along the X-axis direction, the other of the driver body and the telescopic end is hinged with the sliding and overturning adjusting frame around a second hinge center line, and the second hinge center line is parallel to the first hinge center line; the sliding and overturning adjusting frame is driven by the telescopic driver to slide along the arc-shaped guide structure by the aid of the matched guide structure and slides and overturns relative to the mechanism frame body, so that synchronous adjustment of sliding and overturning of the display screen on the sliding and overturning adjusting frame along with the sliding and overturning adjusting frame is realized.

Preferably, the arc-shaped guide structures are arc-shaped guide structures protruding towards a direction away from the sliding overturning adjusting frame, the arc-shaped guide structures are arranged in pairs and are spaced and aligned along the X-axis direction, and each arc-shaped guide structure corresponds to the corresponding guide structure.

Preferably, the number of the distribution and guide structures on the same side is two and the distribution and guide structures are arranged at intervals along the Z-axis direction; the arc-shaped guide structure is a slotted hole structure, the distribution guide structure is a wheel which is arranged in the slotted hole structure in a clearance fit manner, and the wheel is fixedly or rotatably arranged.

Preferably, the mechanism frame body comprises a base and a support body fixedly connected with the base and extending along the Z-axis direction, the arc-shaped guide structure or the distribution guide structure is positioned on the support body, and the base is hinged with the driver body or the telescopic end.

Preferably, the support body is provided with two side plates which are arranged in a spaced manner along the X-axis direction, the sliding overturning adjusting frame is provided with an embedding part which is embedded in a space surrounded by the two side plates, the distribution and guide structure is positioned at the embedding part, the arc-shaped guide structure is positioned at one side of the side plates, which is used for enclosing the space, and the telescopic end is hinged with the embedding part.

Preferably, each side plate is provided with the arc-shaped guide structure, and each arc-shaped guide structure on each side plate is provided with the corresponding guide structure.

Preferably, the embedding part is provided with an avoidance cavity, and the telescopic end stretches into the avoidance cavity and is hinged with two side cavity walls opposite to the avoidance cavity.

Preferably, the sliding and overturning adjusting frame comprises a first arm and a second arm which are arranged together in an included angle and connected together, the first arm is close to the driver body, the second arm is far away from the driver body, and the embedded part is positioned on the second arm and is adjacent to the junction of the first arm and the second arm.

Preferably, the first and second arms together form a "V" shape.

Preferably, the first arm and the second arm are respectively provided with a hanging plate far away from the junction of the first arm and the second arm, the hanging plate is provided with two lugs which are arranged at intervals along the X-axis direction, the hanging plate is respectively clamped on the first arm and the second arm by means of the two lugs, the lugs are respectively connected with the first arm and the second arm in an assembling way through screws, and the display screen is assembled on the hanging plate.

Compared with the prior art, the synchronous adjusting mechanism for the display screen further comprises a sliding and overturning adjusting frame for installing one or more display screens, one of the sliding and overturning adjusting frame and the mechanism frame body is provided with an arc-shaped guide structure extending along the Z-axis direction, the other one of the sliding and overturning adjusting frame and the mechanism frame body is provided with a guiding structure matched with the arc-shaped guide structure and capable of sliding along the arc-shaped guide structure, one of the driver body and the telescopic end is hinged with the mechanism frame body around a first hinge center line arranged along the X-axis direction, the other one of the driver body and the telescopic end is hinged with the sliding and overturning adjusting frame around a second hinge center line, and the second hinge center line is parallel to the first hinge center line; when the sliding and overturning adjusting frame is adjusted, the telescopic end stretches and slides relative to the driver body, so that the sliding and overturning adjusting frame slides and overturns relative to the frame body by means of the sliding of the distribution guide structure along the arc-shaped guide structure, and the display screen on the sliding and overturning adjusting frame synchronously adjusts the sliding and overturning along with the sliding and overturning adjusting frame; the sliding and overturning adjusting frame is controlled by the sliding of the distributing and guiding structure along the arc-shaped guiding structure, so that the adjustment (such as angle and height) of the display screen is stable, smooth and reliable; meanwhile, the machine frame body is matched with the sliding overturning adjusting frame through the arc-shaped guide structure and the matched guide structure, so that the load bearing load of the telescopic driver is shared by the machine frame body.

Drawings

Fig. 1 is a perspective view of a synchronous adjustment mechanism for a display screen according to the present utility model.

Fig. 2 is an exploded perspective view of the synchronization regulating mechanism for a display screen shown in fig. 1.

Fig. 3 is a plan view of fig. 1 with the right side panel hidden and viewed in the opposite direction along the X-axis.

Fig. 4 is a perspective view of the mechanism frame and the telescopic actuator of the synchronous adjusting mechanism for a display screen according to the present utility model.

Fig. 5 is a perspective view of the slip flip adjusting bracket and the hanging plate thereon in the synchronous adjusting mechanism for a display screen of the present utility model.

Fig. 6 is an exploded perspective view of fig. 5.

Fig. 7 is a perspective view of fig. 5 at another angle.

Fig. 8 is a plan view of fig. 3 with a display screen displayed.

Fig. 9 is a plan view of fig. 8 after the display screen has been adjusted upward.

Detailed Description

In order to describe the technical content and constructional features of the present utility model in detail, the following description will be made with reference to the embodiments in conjunction with the accompanying drawings.

Referring to fig. 1, 8 and 9, as an example, the synchronous adjustment mechanism 100 for display screen of the present utility model is used for synchronous adjustment of angles and heights of two display screens 200, and the state during the adjustment can be seen in fig. 8 and 9, so that the user can watch the display screens 200 better, however, according to actual needs, the synchronous adjustment mechanism 100 for display screen of the present utility model can also be used for adjustment of one, three or more display screens 200, so it is not limited to fig. 8 and 9.

Referring to fig. 2 to 4, the synchronous adjustment mechanism 100 for a display screen of the present utility model includes a frame body 10, a telescopic actuator 20, and a sliding/tilting adjustment frame 30 for mounting two display screens 200. The telescopic actuator 20 comprises an actuator body 21 and a telescopic end 22 which is telescopic and slides on the actuator body 21, and in fig. 2, the telescopic actuator 20 is an electric push rod for example, so as to precisely control the telescopic position of the telescopic end 22 on the actuator body 21, thereby preparing for precisely adjusting the sliding and overturning adjusting frame 30; of course, according to actual needs, the telescopic actuator 20 may be an air cylinder or a hydraulic cylinder, and when the telescopic actuator 20 is an air cylinder or a hydraulic cylinder, the telescopic end 22 at this time can only be switched between two extreme positions of the actuator body 21, so the illustration of fig. 2 is omitted; the driver body 21 is hinged with the machine frame body 10 around a first hinging center line C1 arranged along the X-axis direction, so that the driver body 21 can pivot around the first hinging center line C1 in the process of telescopic sliding of the telescopic end 22, the telescopic end 22 is hinged around a second hinging center line C2 parallel to the first hinging center line C1 and the sliding and overturning regulating frame 30, and the telescopic end 22 can also pivot around the second hinging center line C2 in the process of telescopic sliding, thereby meeting the requirement that the telescopic driver 20 drives the sliding and overturning regulating frame 30 to move on the machine frame body 10. The mechanism frame 10 has an arc-shaped guide structure 11 extending in the Z-axis direction, and in fig. 3, 8 and 9, the arc-shaped guide structure 11 is an arc-shaped guide structure, and protrudes in a direction away from the sliding/turning adjusting frame 30, or may be understood to protrude toward the rear of the mechanism frame 10. The sliding and overturning adjusting frame 30 is provided with a matching guide structure 31 which is matched with the arc-shaped guide structure 11 and can slide along the arc-shaped guide structure 11, of course, according to actual needs, the positions of the matching guide structure 31 and the arc-shaped guide structure 11 can be exchanged, namely, the matching guide structure 31 is provided by the mechanism frame body 10, and the arc-shaped guide structure 11 is provided by the sliding and overturning adjusting frame 30, so that the purpose that the matching guide structure 31 slides along the arc-shaped guide structure 11 can be realized, and the sliding and overturning adjusting frame is not limited by fig. 2.

Therefore, under the driving of the telescopic driver 30, the sliding and overturning adjusting frame 30 slides and overturns relative to the frame body 10 by virtue of the sliding of the distribution and guide structure 31 along the arc-shaped guide structure 11, so that the display screen 200 on the sliding and overturning adjusting frame 30 synchronously adjusts the sliding and overturning along with the sliding and overturning adjusting frame 30; for example, in fig. 8, when the telescopic end 22 performs telescopic sliding movement along the Z-axis direction relative to the driver body 21, the telescopic end 22 drives the sliding and overturning adjusting frame 30 to slide upwards and overturn anticlockwise relative to the frame body 10 by means of sliding the guiding structure 31 upwards along the arc-shaped guiding structure 11, so that the display screen 200 on the sliding and overturning adjusting frame 30 performs synchronous adjustment of sliding upwards and overturning anticlockwise along with the sliding and overturning adjusting frame 30, and the state is shown in fig. 9. More specifically, the following is:

as shown in fig. 1 to 4, the frame body 10 includes a base 10a and a support body 10b fixedly connected to the base 10a and extending along the Z-axis direction, the arc-shaped guide structure 11 is located on the support body 10b, and the base 10a is hinged to the driver body 21, so that a sufficient space is provided for adjusting the display screen 200 on the sliding and overturning adjusting frame 30. Specifically, in fig. 2 and 4, as an example, the support body 10b has two side plates 10c arranged at intervals along the X-axis direction, the sliding and overturning adjusting frame 30 has an embedded portion 32 embedded in a space 10d surrounded by the two side plates 10c, the guiding structure 31 is located in the embedded portion 32, the arc guiding structure 11 is located at one side of the side plate 10c for surrounding the space 10d, and the telescopic end 22 is hinged with the embedded portion 32; the design makes the matching between the sliding and overturning adjusting frame 30 and the mechanism frame body 10 tighter, and the supporting of the sliding and overturning adjusting frame 30 by the mechanism frame body 10 is more reliable. More specifically, in fig. 2 and 4, as an example, each side plate 10c is provided with an arc-shaped guiding structure 11, and each arc-shaped guiding structure 11 on each side plate 10c corresponds to an arrangement guiding structure 31, that is, it can be understood that the arc-shaped guiding structures 11 are arranged in pairs and are spaced apart and aligned along the X-axis direction, each arc-shaped guiding structure 11 corresponds to two arrangement guiding structures 31, and two arrangement guiding structures 31 on the same side are spaced apart along the Z-axis direction, so that the objective of the design is to make the sliding and turning adjusting frame 30 cooperate with the mechanism frame body 10 from two sides (i.e., two sides spaced apart by the X-axis direction), and make the sliding and turning adjusting frame 30 on the same side cooperate with the mechanism frame body 10 through the two arrangement guiding structures 31 and one arc-shaped guiding structure 11, thereby further improving smoothness and smoothness of sliding and turning of the sliding and adjusting frame 30 together with the display screen 200 on the machine frame body 10, and further improving the bearing capacity of the sliding and turning adjusting frame body 30 to effectively reduce the load bearing capacity of the telescopic drive 20 through the arrangement guiding structures 31 and the arc-shaped guiding structures 11. For example, in fig. 2 and 4, the arc-shaped guiding structure 11 is a slot structure, such as a slot structure or a hole structure, and the guiding structure 31 is a wheel disposed in the slot structure in a clearance fit manner, wherein the wheel is in a fixed or rotatable arrangement; when the wheels are rotatable, the guiding structure 31 slides along the arc guiding structure 11 more flexibly and smoothly. It can be understood that, according to practical needs, the arc guiding structure 11 may be further designed as an arc guiding structure, and correspondingly, the guiding structure 31 is designed as a sliding block slidingly disposed on the arc guiding structure, so the method is not limited to the method shown in fig. 2 and fig. 4; in addition, the wheel may be formed by a bearing, but is not limited thereto; in addition, each of the arc-shaped guiding structures 11 may correspond to one or three unequal guiding structures 31.

As shown in fig. 3, 6, 7 and 8, the embedding portion 32 is provided with an avoidance cavity 32a, the telescopic end 22 extends into the avoidance cavity 32a and is hinged to two opposite side cavity walls 321 of the avoidance cavity 32a, so that the hinge between the telescopic end 22 and the embedding portion 32 is tighter, and meanwhile, the hinge between the telescopic end 22 and the embedding portion 32 can be further improved due to the fact that the two opposite side cavity walls 321 of the telescopic end 22 and the avoidance cavity 32a are hinged.

As shown in fig. 5 to 7, the sliding and overturning adjusting frame 30 includes a first arm 30a and a second arm 30b which are arranged together at an included angle and connected together, and the first arm 30a and the second arm 30b are formed into a single structure by integral molding, and of course, may be formed into a single structure by assembly (such as welding, riveting or screwing, etc.), for example; the first arm 30a is close to the driver body 21, the second arm 30b is far away from the driver body 21, the embedded part 32 is positioned on the second arm 30b and is adjacent to the junction 30c of the first arm 30a and the second arm 30b, and the first arm 30a and the second arm 30b are respectively provided with a display screen 200, and the state is shown in fig. 8; the embedded portion 32 is located on the second arm 30b, so that the telescopic end 22 is easier and more labor-saving to drive the sliding and overturning adjusting frame 30 to slide and overturn relative to the frame body 10 when the embedded portion 32 is located on the first arm 30a in the telescopic sliding process. Specifically, in fig. 3, 8 and 9, as an example, the first arm 30a and the second arm 30b together form a "V" shape, so that the two display screens 200 are arranged at an included angle, and the two display screens 200 are prevented from being arranged in a straight butt joint manner, so that the occupied size in the Z-axis direction is larger. More specifically, in fig. 5, 6 and 7, the first arm 30a and the second arm 30 are each provided with a hanging plate 40 far from the junction 30c of the first arm 30a and the second arm 30b, the hanging plate 40 is provided with two lugs 41 arranged at intervals along the X-axis direction, the hanging plate 40 is respectively clamped on the first arm 30a and the second arm 30b by the two lugs 41, the lugs 41 are respectively assembled and connected with the first arm 30a and the second arm 30b by screws, and the display screen 200 is assembled on the hanging plate 40, so that the display screen 200 is more reliably assembled on the sliding and overturning adjusting frame 30 by means of the hanging plate 40. Wherein, by means of the two lugs 41 on the hanging plate 40, on one hand, the hanging plate 40 is positioned with the first arm 30a and the second arm 30b quickly in the installation process, and on the other hand, the hanging plate 40 is assembled and connected with the first arm 30a and the second arm 30b from two sides, so that the assembling stability of the hanging plate 40 with the first arm 30a and the second arm 30b respectively is improved. When the hanging plate 40 is provided, the display screen 200 is indirectly assembled with the sliding and overturning adjusting frame 30 through the hanging plate 40, and when the hanging plate 40 is deleted, the display screen 200 is directly assembled with the sliding and overturning adjusting frame 30; the above description of the hanging plate 40 being respectively engaged with the first arm 30a and the second arm 30b by the two lugs 41, the lugs 41 being respectively assembled with the first arm 30a and the second arm 30b by screws means of: for the hanging plate 40 on the first arm 30a, the hanging plate 40 is clamped on the first arm 30a by two lugs 41, and the lugs 41 are assembled and connected with the first arm 30a by screws; for the hanging plate 40 on the second arm 30b, the hanging plate 40 is clamped on the second arm 30b by two lugs 41, and the lugs 41 are assembled and connected with the second arm 30b by screws.

Compared with the prior art, since the synchronous adjusting mechanism 100 for the display screen of the utility model further comprises the sliding and overturning adjusting frame 30 for installing one or more display screens 200, one of the sliding and overturning adjusting frame 30 and the mechanism frame body 10 is provided with the arc-shaped guide structure 11 extending along the Z-axis direction, the other of the sliding and overturning adjusting frame 30 and the mechanism frame body 10 is provided with the distributing structure 31 which is matched with the arc-shaped guide structure 11 and can slide along the arc-shaped guide structure 11, one of the driver body 21 and the telescopic end 22 is hinged with the machine frame body 10 around the first hinging center line C1 arranged along the X-axis direction, the other of the driver body 21 and the telescopic end 22 is hinged with the sliding and overturning adjusting frame 30 around the second hinging center line C2, and the second hinging center line C2 is parallel to the first hinging center line C1; therefore, during adjustment, when the telescopic end 22 stretches out and slides relative to the driver body 21, for example, in fig. 8, when the telescopic end 22 stretches out and slides relative to the driver body 21 along the Z-axis direction, the sliding and overturning adjusting frame 30 slides and overturns relative to the frame body 10 by means of the upward sliding of the guiding structure 31 along the arc guiding structure 11, so that the synchronous adjustment of sliding and overturning of all the display screens 200 on the sliding and overturning adjusting frame 30 along with the sliding and overturning adjusting frame 30 is realized, and the state is shown in fig. 9; the sliding and turning of the sliding and turning adjusting frame 30 relative to the machine frame body 10 is controlled by the sliding of the distributing and guiding structure 31 along the arc-shaped guiding structure 11, so that the adjustment (such as angle and height) of the display screen 200 is smooth and reliable; meanwhile, since the machine frame body 10 is matched with the sliding and overturning adjusting frame 30 through the arc-shaped guide structure 11 and the matching guide structure 31, the machine frame body 10 can share the load bearing load of the telescopic driver 20.

Note that, in the drawing, the Z-axis direction is the up-down direction of the machine frame body 10, the X-axis direction is the left-right direction of the machine frame body 10, and the Y-axis direction is the front-back direction of the machine frame body 10; in addition, according to actual needs, the driver body 21 can be hinged with the sliding and overturning adjusting frame 30 around the second hinging center line C2, and correspondingly, the telescopic end 22 can be hinged with the machine frame body 10 around the first hinging center line C1; in addition, as an example, the driver body 21 is hinged to the base 10a through the hinge seat 50, but not limited thereto.

The foregoing disclosure is only illustrative of the preferred embodiments of the present utility model and is not to be construed as limiting the scope of the utility model, which is defined by the appended claims.

Claims (10)

1. The synchronous regulating mechanism for the display screen comprises a machine frame body and a telescopic driver, wherein the telescopic driver comprises a driver body and a telescopic end which is arranged on the driver body and is used for telescopic sliding, and the synchronous regulating mechanism for the display screen is characterized by further comprising a sliding overturning regulating frame for installing one or more display screens, one of the sliding overturning regulating frame and the machine frame body is provided with an arc-shaped guide structure which is arranged in an extending manner along the Z-axis direction, the other of the sliding overturning regulating frame and the machine frame body is provided with a distributing structure which is matched with the arc-shaped guide structure and can slide along the arc-shaped guide structure, one of the driver body and the telescopic end is hinged with the machine frame body around a first hinge center line which is arranged along the X-axis direction, and the other of the driver body and the telescopic end is hinged with the sliding overturning regulating frame around a second hinge center line which is parallel to the first hinge center line; the sliding and overturning adjusting frame is driven by the telescopic driver to slide along the arc-shaped guide structure by the aid of the matched guide structure and slides and overturns relative to the mechanism frame body, so that synchronous adjustment of sliding and overturning of the display screen on the sliding and overturning adjusting frame along with the sliding and overturning adjusting frame is realized.

2. The synchronous adjusting mechanism for a display screen according to claim 1, wherein the arc-shaped guide structures are arc-shaped guide structures protruding in a direction away from the sliding and overturning adjusting frame, the arc-shaped guide structures are arranged in pairs and are spaced and aligned along the X-axis direction, and each arc-shaped guide structure corresponds to the corresponding guide structure.

3. The synchronous adjusting mechanism for a display screen according to claim 2, wherein the number of the guide structures on the same side is two and the guide structures are arranged at intervals along the Z-axis direction; the arc-shaped guide structure is a slotted hole structure, the distribution guide structure is a wheel which is arranged in the slotted hole structure in a clearance fit manner, and the wheel is fixedly or rotatably arranged.

4. The synchronous adjusting mechanism for a display screen according to claim 1, wherein the mechanism frame comprises a base and a support body fixedly connected with the base and extending along the Z-axis direction, the arc-shaped guide structure or the distribution guide structure is positioned on the support body, and the base is hinged with the driver body or the telescopic end.

5. The synchronous adjusting mechanism for a display screen according to claim 4, wherein the support body is provided with two side plates which are arranged at intervals along the X-axis direction, the sliding turnover adjusting frame is provided with an embedded part embedded in a space surrounded by the two side plates, the guiding structure is positioned at the embedded part, the arc-shaped guiding structure is positioned at one side of the side plate for enclosing the space, and the telescopic end is hinged with the embedded part.

6. The synchronous adjusting mechanism for a display screen according to claim 5, wherein each side plate is provided with the arc-shaped guide structure, and the arc-shaped guide structure on each side plate corresponds to the matching guide structure.

7. The synchronous adjusting mechanism for a display screen according to claim 5, wherein the embedding part is provided with an avoidance cavity, and the telescopic end extends into the avoidance cavity and is hinged with two side cavity walls opposite to the avoidance cavity.

8. The synchronous adjusting mechanism for a display screen according to claim 5, wherein the sliding and overturning adjusting frame comprises a first arm and a second arm which are arranged together at an included angle and are connected together, the first arm is close to the driver body, the second arm is far away from the driver body, the embedded part is positioned on the second arm and is adjacent to the junction of the first arm and the second arm, and the display screen is respectively assembled at the first arm and the second arm.

9. The synchronization regulating mechanism for a display screen according to claim 8, wherein said first arm and said second arm together form a "V" shape.

10. The synchronous adjusting mechanism for a display screen according to claim 8, wherein a hanging plate which is far away from the junction of the first arm and the second arm is arranged on each of the first arm and the second arm, two lugs which are arranged at intervals along the X-axis direction are arranged on the hanging plate, the hanging plate is respectively clamped on the first arm and the second arm by the two lugs, the lugs are respectively assembled and connected with the first arm and the second arm by screws, the display screen is assembled on the hanging plate, and the display screen is assembled on the hanging plate.

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