CN113217776A - Display device and chassis mechanism thereof - Google Patents

Abstract

The invention provides a display device which comprises a display screen, a supporting vertical arm and a chassis mechanism. The supporting vertical arm is connected with the display screen. The chassis mechanism comprises a supporting chassis, a telescopic chassis and a first friction member. The supporting chassis is connected with the supporting vertical arm, and a concave cavity is formed on the bottom surface of the supporting chassis. The telescopic chassis is telescopically arranged in the concave cavity. The first friction member is attached under the telescopic chassis. When the chassis mechanism supports the display screen on the bearing surface through the supporting vertical arm, the first friction member provides friction force to position the telescopic chassis on the bearing surface, so that the supporting chassis can slide relative to the telescopic chassis to a position where the telescopic chassis extends out of the concave cavity or retracts into the concave cavity.

Description

Display device and chassis mechanism thereof

Technical Field

The present invention relates to a display device and a chassis mechanism thereof, and more particularly, to a display device and a chassis mechanism thereof, in which a support chassis can slide relative to a telescopic chassis to extend out of the support chassis or retract into the support chassis.

Background

Generally, a display screen is stably placed on a supporting surface (such as an office desk) by a supporting mechanism composed of a supporting vertical arm and a chassis, so that a user can view images. However, this design often results in the problem that the chassis occupies too much space, which causes many restrictions on the user's planning of the remaining space of the carrying surface and causes inconvenience in the operation of manually adjusting the placement position of the chassis.

Disclosure of Invention

Therefore, an object of the present invention is to provide a display device and a chassis mechanism thereof, in which a support chassis can slide relative to a telescopic chassis to extend or retract the telescopic chassis out of or into the support chassis, so as to solve the above-mentioned problems.

To achieve the above object, the present invention provides a chassis mechanism for connecting to a supporting arm to jointly support a display screen on a supporting surface, the chassis mechanism comprising: the supporting chassis is connected with the supporting vertical arm, and a concave cavity is formed on the bottom surface of the supporting chassis; the telescopic chassis is arranged in the concave cavity in a telescopic manner; and at least one first friction member attached under the telescopic chassis, when the chassis mechanism supports the display screen on the bearing surface through the supporting vertical arm, the at least one first friction member provides friction force to position the telescopic chassis on the bearing surface, so that the supporting chassis can slide relative to the telescopic chassis to a position where the telescopic chassis extends out of the recessed cavity or retracts into the recessed cavity.

Preferably, the at least one first friction member is a strip-shaped gasket and the at least one first friction member is attached to at least one bottom side of the telescopic chassis.

Preferably, the chassis mechanism further comprises: and the at least one second friction member is attached below the supporting chassis, and the friction coefficient of the at least one second friction member is smaller than that of the at least one first friction member.

Preferably, the at least one second friction member is a circular pad and the at least one second friction member is attached under the support chassis.

Preferably, the chassis mechanism further comprises: at least one slide rail component arranged on one side of the concave cavity and one side of the telescopic chassis; and the sliding component is arranged at one side of the other one of the sunken cavity and the telescopic chassis corresponding to the at least one slide rail component, and the sliding component can be slidably inserted into the at least one slide rail component to guide the support chassis to slide relative to the telescopic chassis.

Preferably, the chassis mechanism further comprises: the first positioning structure is arranged at the rear end of the telescopic chassis; and the second positioning structure is arranged in the concave cavity and opposite to the first positioning structure, and the second positioning structure can be clamped in the first positioning structure in a release and locking manner so as to position the telescopic chassis in the concave cavity.

Preferably, when the supporting chassis is pushed to push the first positioning structure to push the second positioning structure again, the second positioning structure is not clamped with the first positioning structure, and the telescopic chassis extends out of the concave cavity; or when the supporting chassis is moved, the second positioning structure is separated from the first positioning structure, and the supporting chassis can be continuously pulled to enable the telescopic chassis to extend out of the concave cavity.

Preferably, the first positioning structure is an arrow-shaped hook, and the second positioning structure is a Y-shaped hook and slides between a locking position and a releasing position; when the supporting chassis slides relative to the telescopic chassis to a position where the telescopic chassis is retracted in the recessed cavity, the first positioning structure pushes the second positioning structure to the locking position, so that the second positioning structure clamps the first positioning structure to position the supporting chassis at the position where the supporting chassis is retracted in the recessed cavity.

Preferably, when the telescopic chassis is retracted to the position in the recessed cavity, the chassis mechanism has a first supporting area, and when the telescopic chassis extends out of the recessed cavity, the chassis mechanism has a second supporting area, and the second supporting area is larger than the first supporting area; the first supporting area and the second supporting area are projection areas projected onto the bearing surface by the chassis mechanism in a direction perpendicular to the bearing surface when the chassis mechanism is connected and supports the display screen on the bearing surface by the supporting vertical arm.

To achieve the above object, the present invention further provides a display device, comprising: the chassis mechanism of any one of above-mentioned display screen, the support grudging post, this support grudging post is connected to this display screen.

Compared with the prior art, the invention adopts the chassis telescopic design that the supporting chassis can slide relative to the telescopic chassis to extend out of the supporting chassis or retract into the supporting chassis, so as to allow a user to elastically adjust the supporting area of the chassis mechanism according to the actual use requirement.

The advantages and spirit of the present invention can be further understood by the following detailed description of the invention and the accompanying drawings.

Drawings

Fig. 1 is a schematic perspective view of a display device placed on a supporting surface according to an embodiment of the present invention.

Fig. 2 is an exploded schematic view of the chassis mechanism of fig. 1.

Fig. 3 is a schematic cross-sectional view of the chassis mechanism of fig. 1 along section line a-a in a direction parallel to the chassis surface.

Fig. 4 is a schematic cross-sectional view of the telescopic base plate of fig. 3 retracted into the cavity.

Fig. 5 is a perspective view of the chassis mechanism of fig. 1 from another perspective when the retractable chassis extends out of the recessed cavity.

Fig. 6 is a schematic perspective view of the telescopic base plate of fig. 5 retracted into the recessed cavity.

Detailed Description

In order to further understand the objects, structures, features and functions of the present invention, the following embodiments are described in detail.

Referring to fig. 1, fig. 1 is a schematic perspective view of a display device 10 disposed on a supporting surface 11 according to an embodiment of the present invention, wherein a display screen 12 is only schematically shown by a dotted line in fig. 1, and the related screen design is common in the prior art and is not described herein again. As shown in fig. 1, the display device 10 includes a display screen 12, a supporting arm 14, and a chassis mechanism 16, wherein the display screen 12 may be a commonly-used display device (such as, but not limited to, a liquid crystal display), and the supporting arm 14 may be preferably connected to a backside S of the display screen 12 (but not limited to) and the chassis mechanism 16, so that the chassis mechanism 16 can support the display screen 12 on a supporting surface 11 (such as, but not limited to, a desk top) via the supporting arm 14 for a user to view images.

Referring to fig. 1 and 2, fig. 2 is an exploded view of the chassis mechanism 16 shown in fig. 1, and as can be seen from fig. 1 and 2, the chassis mechanism 16 includes a supporting chassis 18, a telescopic chassis 20, and at least one first friction member 22 (three are shown in fig. 2, but not limited thereto, and the number, arrangement and arrangement thereof may vary according to the practical application of the display device 10). The supporting base plate 18 is connected to the supporting upright arm 14, a recessed cavity 24 is formed under the supporting base plate 18 for accommodating the telescopic base plate 20, the telescopic base plate 20 is telescopically disposed in the recessed cavity 24, and further, in order to allow the retractable chassis 20 to extend out of the recessed cavity 24 or retract into the recessed cavity 24 more smoothly, the chassis mechanism 16 may preferably be designed with a sliding rail (but not limited thereto), for example, as shown in fig. 2, the chassis mechanism 16 may further include at least one sliding rail member 26 (two are shown in fig. 2 to be respectively disposed on two sides of the telescopic chassis 20, but not limited thereto, in another embodiment, the invention may also adopt a single-side sliding rail design), and a sliding member 28, wherein the sliding member 28 is disposed on one side of the recessed cavity 24 corresponding to the sliding rail member 26, and the sliding member 28 is slidably inserted into the sliding rail member 26 to guide the sliding of the support chassis 18 relative to the telescopic chassis 20. It should be noted that, in another embodiment, the invention may also adopt a design that the sliding rail member is disposed on one side of the recessed cavity instead of the sliding member, and the sliding member is disposed on one side of the telescopic chassis corresponding to the sliding rail member instead of the recessed cavity, and the related description can be analogized with reference to fig. 2, and the description thereof is omitted.

As for the configuration of the friction member, as shown in fig. 2, the first friction member 22 may preferably be a rubber strip pad (but the shape and material of the friction member that can be used in the present invention are not limited thereto) and is disposed under the retractable chassis 20 in a manner of being attached along the bottom side of the retractable chassis 20 (but not limited thereto), so as to provide friction force to the retractable chassis 20, thereby firmly positioning the retractable chassis 20 on the carrying surface 11. In practical applications, in order to further enhance the anti-slip effect of the chassis mechanism 16, as shown in fig. 2, the chassis mechanism 16 may further include at least one second friction member 30 (four friction members are shown in fig. 2, but not limited thereto, the number, configuration and arrangement thereof may vary according to the practical application of the display device 10), and the second friction member 30 may be a circular pad (but not limited thereto) preferably made of wool felt material, and is disposed under the supporting chassis 18 in a manner of being attached to the corner position of the supporting chassis 18, so as to provide a friction force to the supporting chassis 18 when the telescopic chassis 20 extends out of the recessed cavity 24 to support the display screen 12 together with the supporting chassis 18 via the supporting standing arm 14 to provide a friction positioning effect. It should be noted that in this embodiment, the coefficient of friction of the second friction member 30 is preferably smaller than the coefficient of friction of the first friction member 22, so as to ensure that the user can pull the support chassis 18 (with relatively small friction) to slide relative to the telescopic chassis 20 (with relatively large friction) to smoothly complete the telescopic chassis extension operation.

In addition, referring to fig. 2, fig. 3, and fig. 4, fig. 3 is a cross-sectional view of the chassis mechanism 16 of fig. 1 along a cross-sectional dashed line a-a along a direction parallel to a base surface (when placed on a supporting surface, the base surface is parallel to the supporting surface) and viewed in a direction of an arrow shown, and fig. 4 is a cross-sectional view of the retractable chassis 20 of fig. 3 retracted into the recessed cavity 24, as can be seen from fig. 2, fig. 3, and fig. 4, the chassis mechanism 16 may further include a first positioning structure 32 and a second positioning structure 34, the first positioning structure 32 may be disposed at a rear end P of the retractable chassis 20, and the second positioning structure 34 may be disposed in the recessed cavity 24 at a position opposite to the first positioning structure 32, whereby the second positioning structure 34 may be releasably engaged with the first positioning structure 32 to position the retractable chassis 20 in the recessed cavity 24.

More specifically, in this embodiment, the first positioning structure 32 is preferably an arrow-shaped hook, and the second positioning structure 34 is preferably a Y-shaped hook and slides between a locking position shown in fig. 4 and a releasing position shown in fig. 3, where the Y-shaped hook adopts a design of pressing, clamping, and then releasing (the related description of the design of the pressing, clamping, and releasing mechanism for the Y-shaped hook is common in the prior art and is not repeated herein). In this way, when the supporting chassis 18 slides relative to the telescopic chassis 20 to the position shown in fig. 4, which makes the telescopic chassis 20 retract into the recessed cavity 24, the first positioning structure 32 can push the second positioning structure 34 to the locking position shown in fig. 4, so that the second positioning structure 34 clamps the first positioning structure 32 to firmly position the telescopic chassis 20 in the position retracted into the recessed cavity 24. On the other hand, when the user wants to release the locking between the first positioning structure 32 and the second positioning structure 34, the user only needs to push the telescopic chassis 20 to push the first positioning structure 32 to push the second positioning structure 34 again, and at this time, the second positioning structure 34 can no longer be locked to the first positioning structure 32 by the above-mentioned design of releasing the locking by the Y-shaped hook, so that the user can push the support chassis 18 smoothly to extend the telescopic chassis 20 out of the recessed cavity 24.

It should be noted that the positioning and engaging design between the first positioning structure and the second positioning structure is not limited to the above embodiments, and other engaging designs, such as a structural concave-convex engaging design, may be adopted instead. For example, in another embodiment, the first positioning structure may be an elastic arm extending from the retractable chassis to the supporting chassis and having a snap-fit protrusion, and the second positioning structure may be a positioning recess hole structure formed on the supporting chassis and opposite to the first positioning structure, such that when the supporting chassis slides relative to the retractable chassis to a position where the retractable chassis retracts into the recessed cavity, the snap-fit protrusion on the elastic arm can be snapped into the positioning recess hole structure in a concave-convex manner, so as to stably position the retractable chassis at the position where the retractable chassis retracts into the recessed cavity. On the other hand, when the user wants to unlock the clamping state of the first positioning structure and the second positioning structure, the user only needs to move (pull or push) the support chassis relative to the telescopic chassis to make the clamping salient points on the elastic arms separate from the positioning concave hole structure, so that the user can continue to move the support chassis relative to the telescopic chassis to make the telescopic chassis extend out of the concave cavity.

Referring to fig. 1, 3, 4, 5 and 6, fig. 5 is a perspective view of the chassis mechanism 16 of fig. 1 from another perspective when the retractable chassis 20 is extended out of the recessed cavity 24, fig. 6 is a perspective view of the retractable chassis 20 of fig. 5 retracted into the recessed cavity 24, as can be seen from fig. 1, 3, 4, 5 and 6, when a user wants to reduce the supporting area of the chassis mechanism 16, the user only needs to push the supporting chassis 18 backwards from the position shown in fig. 1 to move the supporting chassis 18 relative to the retractable chassis 20 (in a direction parallel to the carrying surface 11), at this time, since the retractable chassis 20 can be stably positioned on the carrying surface 11 due to the larger friction force provided by the first friction member 22 and the second friction member 30 has a relatively smaller friction force, therefore, the user can push the supporting chassis 18 from the position shown in fig. 3 to the position shown in fig. 4 relative to the telescopic chassis 20 without moving the telescopic chassis 20 (meanwhile, as can be seen from fig. 4, the first positioning structure 32 pushes the second positioning structure 34 to the locking position, so that the second positioning structure 34 clamps the first positioning structure 32 to fix the relative position between the supporting chassis 18 and the telescopic chassis 20), in this process, the telescopic chassis 20 can be retracted into the recessed cavity 24 along with the sliding of the supporting chassis 18 through the sliding guide design of the sliding rail members 26 and the sliding members 28, so that the user can smoothly retract the telescopic chassis 20 into the supporting chassis 18, thereby reducing the supporting area of the chassis mechanism 16 from the supporting area shown in fig. 5 to the supporting area shown in fig. 6, and effectively reducing the space occupied by the chassis mechanism 16 on the supporting surface 11 to facilitate the remaining space on the subsequent supporting surface 11 And (6) planning.

On the other hand, when the user wants to increase the supporting area of the chassis mechanism 16, the user only needs to push the supporting chassis 18 backward from the position shown in fig. 6 to release the engagement between the first positioning structure 32 and the second positioning structure 34 by the above-mentioned design of Y-shaped hook and then release the lock, and at this time, since the telescopic chassis 20 can be stably positioned on the carrying surface 11 by the larger friction force provided by the first friction member 22 and the second friction member 30 has a relatively smaller friction force, the user can pull the supporting chassis 18 from the position shown in fig. 4 to the position shown in fig. 3 with respect to the telescopic chassis 20 without moving the telescopic chassis 20, in this process, the telescopic chassis 20 can extend out of the recessed cavity 24 along with the sliding of the supporting chassis 18 by the sliding guide design of the sliding rail member 26 and the sliding member 28, in this way, the user can smoothly expand the chassis mechanism 16 from the supporting area (i.e., the first supporting area) shown in fig. 6 to the supporting area (i.e., the second supporting area) shown in fig. 5, where the supporting areas (the first supporting area and the second supporting area) are the projection areas of the chassis mechanism 16 projected onto the supporting surface 11 in the direction perpendicular to the supporting surface 11 when the chassis mechanism 16 is connected and the display screen 12 is supported on the supporting surface 11 by the supporting upright arms 14 (i.e., when the display device 10 is placed on the supporting surface 11 to be in a use state), so that the display device 10 can be stably disposed on the supporting surface 11 (as shown in fig. 1), thereby effectively avoiding the situation that the display device 10 is toppled and damaged due to external impact during use.

In summary, the present invention adopts the chassis telescoping design that the supporting chassis can slide relative to the telescopic chassis to extend the telescopic chassis out of the supporting chassis or retract the telescopic chassis into the supporting chassis, so as to allow a user to elastically adjust the supporting area of the chassis mechanism according to the actual use requirement, and thus, compared with the design that the chassis supporting area is enlarged in the prior art, the present invention can effectively solve the problem that the chassis occupies too much space in the prior art, thereby greatly improving the configuration elasticity and the operation convenience of the display device in adjusting the placing position of the chassis.

The present invention has been described in relation to the above embodiments, which are only exemplary of the implementation of the present invention. It should be noted that the disclosed embodiments do not limit the scope of the invention. Rather, it is intended that all such modifications and variations be included within the spirit and scope of this invention.

Claims (10)

1. A chassis mechanism for coupling to a support arm to cooperatively support a display screen on a support surface, the chassis mechanism comprising:

the supporting chassis is connected with the supporting vertical arm, and a concave cavity is formed on the bottom surface of the supporting chassis;

the telescopic chassis is arranged in the concave cavity in a telescopic manner; and

the telescopic chassis is provided with a bearing surface, a support vertical arm and a telescopic cavity, wherein the telescopic cavity is provided with a plurality of concave cavities, the support vertical arm is arranged on the bearing surface, and the support vertical arm is arranged on the support vertical arm and is used for supporting the display screen.

2. The chassis mechanism of claim 1, wherein the at least one first friction member is a strip-shaped pad and the at least one first friction member is attached to at least one bottom side of the retractable chassis.

3. The chassis mechanism of claim 1, further comprising:

and the at least one second friction member is attached below the supporting chassis, and the friction coefficient of the at least one second friction member is smaller than that of the at least one first friction member.

4. The chassis mechanism of claim 3, wherein the at least one second friction member is a circular pad and the at least one second friction member is affixed under the support chassis.

5. The chassis mechanism of claim 1, further comprising:

at least one slide rail component arranged on one side of the concave cavity and one side of the telescopic chassis; and

the sliding component is arranged at one side of the other side of the sunken cavity and the telescopic chassis corresponding to the at least one slide rail component, and the sliding component can be slidably inserted into the at least one slide rail component to guide the supporting chassis to slide relative to the telescopic chassis.

6. The chassis mechanism of claim 1, further comprising:

the first positioning structure is arranged at the rear end of the telescopic chassis; and

the second positioning structure is arranged in the concave cavity and opposite to the first positioning structure, and the second positioning structure can be clamped in the first positioning structure in a locking and unlocking way so as to position the telescopic chassis in the concave cavity.

7. The chassis structure of claim 6, wherein when the supporting chassis is pushed to push the first positioning structure against the second positioning structure again, the second positioning structure no longer clamps the first positioning structure, and the retractable chassis extends out of the recessed cavity; or

When the supporting chassis is moved, the second positioning structure is separated from the first positioning structure, and the supporting chassis can be continuously pulled to enable the telescopic chassis to extend out of the concave cavity.

8. The chassis mechanism of claim 6, wherein the first positioning structure is an arrow-shaped hook and the second positioning structure is a Y-shaped hook and slides between a locked position and an unlocked position; when the supporting chassis slides relative to the telescopic chassis to a position where the telescopic chassis is retracted in the recessed cavity, the first positioning structure pushes the second positioning structure to the locking position, so that the second positioning structure clamps the first positioning structure to position the supporting chassis at the position where the supporting chassis is retracted in the recessed cavity.

9. The chassis mechanism of claim 1, wherein the chassis mechanism has a first support area when the retractable chassis is retracted into position within the recessed cavity, and a second support area when the retractable chassis is extended out of the recessed cavity, the second support area being greater than the first support area; the first supporting area and the second supporting area are projection areas projected onto the bearing surface by the chassis mechanism in a direction perpendicular to the bearing surface when the chassis mechanism is connected and supports the display screen on the bearing surface by the supporting vertical arm.

10. A display device, comprising: a display screen, a supporting upright arm attached to the display screen, and the chassis mechanism of any one of claims 1 to 9.

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