A full-angle display device
By using the support frame mechanism and display components of the omnidirectional display device, the problem of blind spots caused by the display device is solved, enabling omnidirectional display and stable observation of exhibits, and improving the integrity of exhibit information and the visitor experience.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHENZHEN BAIHELONG TECHNOLOGY CO LTD
- Filing Date
- 2025-06-25
- Publication Date
- 2026-06-30
AI Technical Summary
The support frame and structural framework of the display installation can obstruct the exhibits, preventing viewers from observing the complete form or specific details of the exhibits at once without any blind spots, thus weakening the complete transmission of information about the exhibits and the integrity of the artwork.
An all-angle display device was designed, including a support frame mechanism and all-angle display components. Utilizing components such as steel balls, magnetic chucks, transparent hemispherical shells, and rubber balls, the exhibits can be displayed from all angles. Stability is maintained by the rolling of the steel balls and magnetic attraction, while the buffering and rotation of the rubber balls allow for multi-angle observation of the exhibits.
This allows for a full-angle display of the exhibits, enabling visitors to observe them from any angle and in all directions. This improves the completeness and stability of the exhibit information, avoids obstruction by the supporting structure, and enhances the visitor's visual experience.
Smart Images

Figure CN224420587U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of display device technology, specifically a full-angle display device. Background Technology
[0002] Display installations are devices or structures used to display objects, information, or works of art. They are commonly found in exhibitions, museums, shopping malls, and other venues. Their core functions are to attract the attention of visitors, enhance the display effect, protect exhibits, and provide interactive experiences. Through different forms and functions, they effectively display various objects and facilitate information dissemination and exchange.
[0003] Display installations typically have a dedicated structural frame for displaying exhibits and can adjust the angle of the exhibits to dynamically present different dimensions of the exhibits, optimizing the audience's visual experience and thus conveying information more effectively and professionally, enhancing the attractiveness and comprehensibility of the exhibits.
[0004] However, the support frame and display device of the display device are connected by a mechanical structure, which will always obstruct the exhibit to a certain extent. This will prevent the audience from observing the complete form or specific details of the exhibit at one time without any blind spots, thus creating visual blind spots. This weakens the complete transmission of the overall information of the exhibit and the complete presentation of the artwork. Therefore, an all-angle display device is proposed to address the above problems. Utility Model Content
[0005] The purpose of this invention is to provide a full-angle display device to solve the problems mentioned in the background art.
[0006] To achieve the above objectives, this utility model provides the following technical solution:
[0007] A full-angle display device includes a display base, a support frame mechanism fixedly connected to the upper end of the display base, a full-angle display component placed on the upper end of the support frame mechanism, the support frame mechanism including a platform, a bracket fixedly connected to the upper end of the platform, a support column fixedly connected to the bottom end of the platform, steel balls rolled on the inner side of the platform, and a magnetic suction cup fixedly connected to the upper end of the platform. The full-angle display component includes a lower shell assembly, an upper shell assembly snapped onto the upper end of the lower shell assembly, a crystal ball disposed between the lower shell assembly and the upper shell assembly, the lower shell assembly including a first outer transparent hemispherical shell, a downwardly sloping glass short column fixedly connected to the inner side of the first outer transparent hemispherical shell, and one end of the downwardly sloping glass short column being fixed... The upper housing assembly includes a first inner transparent hemispherical shell, with a lower mounting groove on the inner side of the first inner transparent hemispherical shell. A first rubber ball is installed inside the lower mounting groove. A locking head is fixedly connected to the upper end of the first inner transparent hemispherical shell. An annular groove is provided on the upper end of the first outer transparent hemispherical shell. The upper housing assembly includes a second outer transparent hemispherical shell. An upwardly inclined glass column is fixedly connected to the inner side of the second outer transparent hemispherical shell. One end of the upwardly inclined glass column is fixedly connected to the second inner transparent hemispherical shell. An upper mounting groove is provided on the inner side of the second inner transparent hemispherical shell. A second rubber ball is installed inside the upper mounting groove. A locking groove is provided at the bottom end of the second inner transparent hemispherical shell. A sealing ring is fixedly connected to the bottom end of the second outer transparent hemispherical shell.
[0008] As a further optimization of this utility model, the bottom surface of the platform is parallel to the top surface of the display base, the angle between the support column and the display base is 90°, and the height of the bracket is one-third of the height of the full-angle display component.
[0009] As a further optimization of this utility model, multiple steel balls are provided, and the multiple steel balls are arranged in a ring array around the magnetic chuck, with the outer sides of the multiple steel balls simultaneously contacting the all-angle display component.
[0010] As a further optimization of this utility model, the following features are provided: a plurality of downward-sloping glass short columns are provided, and the plurality of downward-sloping glass short columns are arranged in a ring array; a gap is provided between the outer side of the first inner transparent hemispherical shell and the inner side of the first outer transparent hemispherical shell; the clip is engaged in the clip slot; and the upper end face of the first outer transparent hemispherical shell is in close contact with the bottom end face of the second outer transparent hemispherical shell.
[0011] As a further optimization of this utility model, the position of the first rubber ball corresponds one-to-one with the position of the downward inclined glass column, two-thirds of the first rubber ball is set in the lower mounting groove, and the outer side of the first rubber ball is attached to the outer side of the crystal ball.
[0012] As a further optimization of this utility model, the positions of the upwardly inclined glass short columns correspond one-to-one with the positions of the downwardly inclined glass short columns; a gap is provided between the outer side of the second inner transparent hemispherical shell and the inner side of the second outer transparent hemispherical shell; the outer side of the sealing ring is in close contact with the inner side of the annular groove; and the bottom end face of the second inner transparent hemispherical shell is in close contact with the bottom end face of the first inner transparent hemispherical shell.
[0013] As a further optimization of this utility model, the position of the second rubber ball corresponds one-to-one with the position of the upward inclined glass column, two-thirds of the second rubber ball is set in the upper mounting groove, and the outer side of the second rubber ball is attached to the outer side of the crystal ball.
[0014] Compared with the prior art, the beneficial effects of this utility model are:
[0015] In this invention, through the set support frame mechanism and all-angle display components, the device can realize the all-angle display of exhibits, allowing the audience to observe the exhibits inside the crystal ball from any angle. No detail of the exhibits will be missed due to the obstruction of the support structure, which greatly improves the integrity of the information transmission of the exhibits. At the same time, through the innovative anti-drop mechanism, the device has both flexibility and stability, avoiding damage to the exhibits due to shaking or instability of the device. Attached Figure Description
[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0017] Figure 2 This is a schematic diagram of the overall exploded structure of this utility model;
[0018] Figure 3 This is a schematic diagram of the support frame mechanism of this utility model;
[0019] Figure 4 This is a cross-sectional view of the component of this utility model from all angles;
[0020] Figure 5 This is a schematic diagram showing the exploded structure of the component from all angles.
[0021] Figure 6 This is a cross-sectional structural diagram of the lower housing assembly of this utility model;
[0022] Figure 7 for Figure 6 Enlarged structural diagram at point A in the middle;
[0023] Figure 8 This is a cross-sectional structural diagram of the upper housing assembly of this utility model;
[0024] Figure 9 for Figure 8 Enlarged structural diagram at point B.
[0025] In the picture: 1. Display base;
[0026] 2. Support frame mechanism; 21. Platform; 22. Bracket; 23. Support column; 24. Steel ball; 25. Magnetic chuck;
[0027] 3. Display components from all angles;
[0028] 31. Lower housing assembly; 311. First outer transparent hemispherical shell; 312. Downward-sloping glass short column; 313. First inner transparent hemispherical shell; 314. Lower mounting groove; 315. First rubber ball; 316. Clip; 317. Annular groove;
[0029] 32. Upper housing assembly; 321. Second outer transparent hemispherical shell; 322. Upper inclined glass short column; 323. Second inner transparent hemispherical shell; 324. Upper mounting groove; 325. Second rubber ball; 326. Slot; 327. Sealing ring;
[0030] 33. Crystal ball. Detailed Implementation
[0031] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0032] It should be noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the exemplary embodiments according to this application. As used herein, the singular form is intended to include the plural form as well, unless the context clearly indicates otherwise. Furthermore, it should be understood that when the terms "comprising" and / or "including" are used in this specification, they indicate the presence of features, steps, operations, devices, components, and / or combinations thereof.
[0033] Please see Figures 1-9 This utility model provides a technical solution:
[0034] An omnidirectional display device includes a display base 1, a support frame mechanism 2 fixedly connected to the upper end of the display base 1, an omnidirectional display component 3 placed on the upper end of the support frame mechanism 2, the support frame mechanism 2 including a platform 21, a bracket 22 fixedly connected to the upper end of the platform 21, a support column 23 fixedly connected to the bottom end of the platform 21, steel balls 24 rotatably mounted on the inner side of the platform 21, and a magnetic suction cup 25 fixedly connected to the upper end of the platform 21. The omnidirectional display component 3 includes a lower shell component 31, an upper shell component 32 snapped onto the upper end of the lower shell component 31, a crystal ball 33 disposed between the lower shell component 31 and the upper shell component 32, the lower shell component 31 including a first outer transparent hemispherical shell 311, a downwardly sloping glass short column 312 fixedly connected to the inner side of the first outer transparent hemispherical shell 311, and a first inner transparent hemispherical shell 312 fixedly connected to one end of the downwardly sloping glass short column 312. The shell 313 has a lower mounting groove 314 on its inner side, and a first rubber ball 315 is installed inside the lower mounting groove 314. A clip 316 is fixedly connected to the upper end of the first inner transparent hemispherical shell 313. An annular groove 317 is opened at the upper end of the first outer transparent hemispherical shell 311. The upper shell assembly 32 includes a second outer transparent hemispherical shell 321. An upwardly inclined glass column 322 is fixedly connected to the inner side of the second outer transparent hemispherical shell 321. A second inner transparent hemispherical shell 323 is fixedly connected to one end of the upwardly inclined glass column 322. An upper mounting groove 324 is opened inside the second inner transparent hemispherical shell 323, and a second rubber ball 325 is installed inside the upper mounting groove 324. A clip 326 is opened at the bottom end of the second inner transparent hemispherical shell 323. A sealing ring 327 is fixedly connected to the bottom end of the second outer transparent hemispherical shell 321.
[0035] As a further implementation of this solution, the bottom surface of the platform 21 is parallel to the top surface of the display base 1, the angle between the support column 23 and the display base 1 is 90°, and the height of the bracket 22 is one-third of the height of the full-angle display component 3. The design that the bottom surface of the platform 21 is parallel to the top surface of the display base 1 and the support column 23 supports the platform 21, making the platform 21 more stable in space and improving the stability of the device. The bracket 22 can prevent the full-angle display component 3 from being knocked off by accident.
[0036] As a further implementation of this solution, multiple steel balls 24 are provided, and the multiple steel balls 24 are distributed in a ring array around the magnetic chuck 25. The outer sides of the multiple steel balls 24 simultaneously contact the omnidirectional display component 3. The arrangement of the steel balls 24 can support the omnidirectional display component 3 while reducing the friction between it and other components, thereby enabling better rolling.
[0037] As a further implementation of this solution, several inclined glass short columns 312 are provided, and the multiple inclined glass short columns 312 are arranged in a ring array. A gap is provided between the outer side of the first inner transparent hemispherical shell 313 and the inner side of the first outer transparent hemispherical shell 311. The clip 316 is engaged in the clip slot 326. The upper end face of the first outer transparent hemispherical shell 311 is in close contact with the bottom end face of the second outer transparent hemispherical shell 321. The gap provided between the outer side of the first inner transparent hemispherical shell 313 and the inner side of the first outer transparent hemispherical shell 311 can be filled with iron sand. The iron sand is attracted by the magnetic suction cup 25 to prevent the omnidirectional display component 3 from falling out of the bracket 22 when it rolls.
[0038] As a further implementation of this solution, the position of the first rubber ball 315 corresponds one-to-one with the position of the downward inclined glass column 312. Two-thirds of the first rubber ball 315 is set in the lower mounting groove 314. The outer side of the first rubber ball 315 is attached to the outer side of the crystal ball 33. The setting of the first rubber ball 315 can buffer the placement of the crystal ball 33 while also better supporting the crystal ball 33.
[0039] As a further implementation of this solution, the position of the upwardly inclined glass short column 322 corresponds one-to-one with the position of the downwardly inclined glass short column 312. A gap is provided between the outer side of the second inner transparent hemispherical shell 323 and the inner side of the second outer transparent hemispherical shell 321. The outer side of the sealing ring 327 is tightly attached to the inner side of the annular groove 317. The bottom end face of the second inner transparent hemispherical shell 323 is tightly attached to the bottom end face of the first inner transparent hemispherical shell 313. The design that the outer side of the sealing ring 327 is tightly attached to the inner side of the annular groove 317 can prevent iron sand from leaking directly from the first outer transparent hemispherical shell 311 and the second outer transparent hemispherical shell 321.
[0040] As a further implementation of this solution, the position of the second rubber ball 325 corresponds one-to-one with the position of the upward inclined glass column 322. Two-thirds of the second rubber ball 325 is set in the upper mounting groove 324. The outer side of the second rubber ball 325 is attached to the outer side of the crystal ball 33. The second rubber ball 325 enables the crystal ball 33 to rotate, thereby adjusting the angle of the crystal ball 33 for easier viewing.
[0041] Workflow: When using the device, the object to be displayed is first placed inside the crystal ball 33 before it is fully sealed. Then, liquid is injected into the crystal ball 33 to seal it, forming a complete sphere. The surface of the crystal ball 33 is then polished to ensure a smooth, scratch-free surface. Next, the crystal ball 33 is placed inside the first inner transparent hemispherical shell 313, bringing it into contact with the first rubber ball 315. The crystal ball 33 presses against the first rubber ball 315, causing it to contact and rub against the first inner transparent hemispherical shell 313. This allows the multiple first rubber balls 315 to cushion the placement of the crystal ball 33 while better supporting the water. Next, a certain amount of iron sand is poured into the gap between the first inner transparent hemispherical shell 313 and the first outer transparent hemispherical shell 311. Then, the upper shell assembly 32 is placed on top of the lower shell assembly 31, so that the locking head 316 is inserted into the locking groove 326. The upper end face of the first inner transparent hemispherical shell 313 is in close contact with the bottom end face of the second inner transparent hemispherical shell 323. At the same time, the sealing ring 327 is inserted into the annular groove 317, so that the first outer transparent hemispherical shell 311 and the second outer transparent hemispherical shell 321 form a seal to prevent the iron sand from leaking out. At this time, the first outer transparent hemispherical shell 311 and the second outer transparent hemispherical shell 321 are spliced into a sphere, while the first inner transparent hemispherical shell 313 is inserted into the lower shell assembly 311, so that the first outer transparent hemispherical shell 311 and the second outer transparent hemispherical shell 321 form a seal to prevent the iron sand from leaking out. The hemispherical shell 313 and the second inner transparent hemispherical shell 323 are spliced together to form another smaller sphere. Then, the omnidirectional display component 3 is placed in the bracket 22, with the outer side of the omnidirectional display component 3 in contact with the outer side of the steel ball 24. When the two spliced spheres roll, the iron sand, under the influence of gravity, will always slide to the bottom of the sphere formed by the splicing of the first outer transparent hemispherical shell 311 and the second outer transparent hemispherical shell 321. The magnetic suction cup 25's attraction to the iron sand makes it difficult for the omnidirectional display component 3 to fall out of the bracket 22. The steel ball 24 ensures that the omnidirectional display component 3 experiences less friction when rolling in the bracket 22. When it is necessary to display the crystal ball 33... When observing the object from multiple angles, the full-angle display component 3 can be easily rotated. The rotation of the first outer transparent hemispherical shell 311 and the second outer transparent hemispherical shell 321 drives the downward inclined glass column 312 and the upward inclined glass column 322 to move. The movement of the downward inclined glass column 312 and the upward inclined glass column 322 respectively drives the rotation of the fixedly connected first inner transparent hemispherical shell 313 and the second inner transparent hemispherical shell 323, thereby causing the first rubber ball 315 and the clip 316 set in the lower mounting groove 314 and the upper mounting groove 324 to move, and generate friction on the crystal ball 33, causing the crystal ball 33 to rotate, thereby allowing the crystal ball 33 to be observed from all angles.
[0042] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A full angle display device comprising a display base (1), characterized in that: The upper end of the display base (1) is fixedly connected to a support frame mechanism (2), and an all-angle display component (3) is placed on the upper end of the support frame mechanism (2). The support frame mechanism (2) includes a platform (21), a bracket (22) is fixedly connected to the upper end of the platform (21), a support column (23) is fixedly connected to the bottom end of the platform (21), a steel ball (24) is rolled on the inner side of the platform (21), and a magnetic chuck (25) is fixedly connected to the upper end of the platform (21). The omnidirectional display component (3) includes a lower shell component (31), an upper shell component (32) is snapped onto the upper end of the lower shell component (31), and a crystal ball (33) is arranged between the lower shell component (31) and the upper shell component (32). The lower housing assembly (31) includes a first outer transparent hemispherical shell (311), a downward inclined glass column (312) is fixedly connected to the inner side of the first outer transparent hemispherical shell (311), a first inner transparent hemispherical shell (313) is fixedly connected to one end of the downward inclined glass column (312), a lower mounting groove (314) is opened on the inner side of the first inner transparent hemispherical shell (313), a first rubber ball (315) is installed on the inner side of the lower mounting groove (314), a clip (316) is fixedly connected to the upper end of the first inner transparent hemispherical shell (313), and an annular groove (317) is opened on the upper end of the first outer transparent hemispherical shell (311). The upper housing assembly (32) includes a second outer transparent hemispherical shell (321), an upwardly inclined glass short column (322) is fixedly connected to the inner side of the second outer transparent hemispherical shell (321), a second inner transparent hemispherical shell (323) is fixedly connected to one end of the upwardly inclined glass short column (322), an upper mounting groove (324) is opened on the inner side of the second inner transparent hemispherical shell (323), a second rubber ball (325) is installed on the inner side of the upper mounting groove (324), a slot (326) is opened at the bottom end of the second inner transparent hemispherical shell (323), and a sealing ring (327) is fixedly connected to the bottom end of the second outer transparent hemispherical shell (321).
2. A full angle display device according to claim 1, characterized in that: The bottom surface of the platform (21) is parallel to the top surface of the display base (1), the angle between the support column (23) and the display base (1) is 90°, and the height of the bracket (22) is one-third of the height of the full-angle display component (3).
3. A full angle display device according to claim 1, characterized in that: Multiple steel balls (24) are provided, and the multiple steel balls (24) are arranged in a ring array around the magnetic chuck (25). The outer sides of the multiple steel balls (24) simultaneously contact the full-angle display component (3).
4. A full angle display device according to claim 1, characterized in that: The downward-sloping glass short columns (312) are provided in a plurality of them, and the plurality of downward-sloping glass short columns (312) are arranged in a ring array. The outer side of the first inner transparent hemispherical shell (313) and the inner side of the first outer transparent hemispherical shell (311) are provided with a gap. The clip (316) is engaged in the clip groove (326). The upper end surface of the first outer transparent hemispherical shell (311) is in close contact with the bottom end surface of the second outer transparent hemispherical shell (321).
5. A full angle display device according to claim 1, characterized in that: The position of the first rubber ball (315) corresponds one-to-one with the position of the downward inclined glass column (312). Two-thirds of the first rubber ball (315) is set in the lower mounting groove (314). The outer side of the first rubber ball (315) is attached to the outer side of the crystal ball (33).
6. A full angle display device according to claim 1, characterized in that: The position of the upward inclined glass column (322) corresponds one-to-one with the position of the downward inclined glass column (312). The outer side of the second inner transparent hemisphere (323) and the inner side of the second outer transparent hemisphere (321) are spaced apart. The outer side of the sealing ring (327) is in close contact with the inner side of the annular groove (317). The bottom end face of the second inner transparent hemisphere (323) is in close contact with the bottom end face of the first inner transparent hemisphere (313).
7. A full angle display device according to claim 1, characterized in that: The position of the second rubber ball (325) corresponds one-to-one with the position of the upward inclined glass column (322). Two-thirds of the second rubber ball (325) is set in the upper mounting groove (324), and the outer side of the second rubber ball (325) is attached to the outer side of the crystal ball (33).