Tiled display apparatus
By setting support areas at the edges of the splicing display device cabinets and utilizing magnetic and adjustment components, the problems of step differences and gaps between adjacent cabinets were solved, thereby improving the flatness of the display panel and the splicing effect.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- BOE TECHNOLOGY GROUP CO LTD
- Filing Date
- 2025-04-17
- Publication Date
- 2026-07-14
AI Technical Summary
In splicing display devices, the step difference and gap between adjacent cabinets are difficult to control, affecting the flatness of the display panel and the splicing effect.
By setting a support area at the edge of the splicing unit's cabinet, configuring the support surface to support adjacent display components, and using magnetic components and adjustment components to adjust the position of the display components, the step difference and gap are reduced, and the flatness of the splicing display device is improved.
It effectively reduces the step difference and gap between adjacent display components, improves the flatness and dark consistency of the splicing display device, and enhances the splicing effect.
Smart Images

Figure CN224501434U_ABST
Abstract
Description
Technical Field
[0001] This disclosure relates to the field of display technology, and more specifically to a splicing display device. Background Technology
[0002] In a video wall display device, a support cabinet is used to support at least one display component. Multiple support cabinets are spliced together to form a video wall display. During the splicing process of the video wall display device, there are high requirements for the step difference and gap between the splicing units. Utility Model Content
[0003] This disclosure provides a splicing display device, including multiple splicing units spliced together, wherein each splicing unit includes:
[0004] Display components;
[0005] The housing is located on the non-display side of the display component;
[0006] A support area is provided at the edge of the housing, and the support area has a support surface facing the display component. The support surface is configured to support at least the display component in the splicing unit.
[0007] In this configuration, the support areas in different splicing units are spaced apart, and the support surface of the support area in at least one splicing unit is also configured to support the display components in adjacent splicing units.
[0008] In some embodiments, in every two adjacent splicing units, the support surface of at least one support area of one splicing unit is configured to support the display components in the two adjacent splicing units.
[0009] In some embodiments, the outline of the housing projected onto the reference plane is a polygon, and the reference plane is a plane perpendicular to the thickness direction of the display component; the support area is located in the interior corner region of the polygon.
[0010] In some embodiments, the distance between the support areas in any two adjacent splicing units is greater than or equal to 60 mm.
[0011] In some embodiments, the display components of two adjacent splicing units are spaced apart; at least one support area has a groove, the orthographic projection of the groove on the reference surface overlaps with the orthographic projection of the spaced apart on the reference surface, and a light-absorbing material is disposed in the groove; the reference surface is a plane perpendicular to the thickness direction of the display component.
[0012] In some embodiments, each pair of adjacent enclosures is a first enclosure and a second enclosure, both the first enclosure and the second enclosure include a main structure, the first enclosure further includes a first eaves structure disposed on the main structure, the first eaves structure is configured to cover part of the edge area of the main structure of the second enclosure, and the support surface is located on the surface of the first eaves structure facing the display component.
[0013] In some embodiments, the first housing further includes a second eaves structure disposed on the main structure. Along the thickness direction of the display component, the main structure is located between the first eaves structure and the second eaves structure, and the second eaves structure, the first eaves structure, and the main structure of the first housing define a limiting groove, a portion of the main structure of the second housing being located in the limiting groove.
[0014] In some embodiments, the second housing further includes a limiting post disposed on the main structure, and the first eaves structure has an avoidance gap, with a portion of the limiting post located in the avoidance gap.
[0015] In some embodiments, any two adjacent enclosures are detachably connected by fasteners.
[0016] In some embodiments, the housing includes a cutout portion that extends through the housing along the thickness direction of the display component, and the splicing unit further includes:
[0017] A first magnetic component, comprising a first part and a second part capable of magnetic attraction, wherein the first part is disposed on the display component and the second part is disposed on the housing;
[0018] A magnetic adsorption sheet is configured to be rotatably connected to the display assembly so that the magnetic adsorption sheet is in one of a first state and a second state.
[0019] In the first state, the magnetic adsorption sheet is positioned opposite the surface of the display component facing the housing;
[0020] In the second state, the magnetic adsorption sheet is magnetically attracted to the auxiliary component located on the side of the hollowed-out portion, or the magnetic adsorption sheet is magnetically attracted to the magnetic adsorption sheet in the adjacent splicing unit.
[0021] In some embodiments, the splicing unit further includes:
[0022] The mounting component includes a movable part, a fixed part, and a rotating shaft. The movable part is fixedly connected to the display component, and the movable part is rotatably connected to the fixed part via the rotating shaft. The rotating shaft extends along the surface of the display component toward the housing.
[0023] The magnetic adsorption sheet is fixed to the movable part.
[0024] In some embodiments, the plurality of splicing units are arranged sequentially in a first direction, and the display component includes a first edge and a second edge disposed opposite to each other in the first direction. The mounting members are disposed at positions near the first edge and near the second edge. The rotation axis of the mounting member near the first edge is in the same direction as the extension of the first edge, and the rotation axis of the mounting member near the second edge is in the same direction as the extension of the second edge.
[0025] In some embodiments, the splicing unit further includes:
[0026] A first magnetic component, comprising a first part and a second part capable of magnetic attraction, wherein the first part is disposed on the display component;
[0027] Mounting base, the mounting base is disposed on the housing and configured to move relative to the housing along the thickness direction of the housing;
[0028] The second component is fixed to the mounting base.
[0029] In some embodiments, the housing has a threaded hole, the mounting base includes a mounting portion and a screw portion, at least a portion of the screw portion is located in the threaded hole, and the mounting portion is fixedly connected to one end of the screw portion; the second component is fixed on the mounting portion.
[0030] In some embodiments, the housings of the plurality of splicing units form a load-bearing structure, and the load-bearing structure is provided with an adjustment component, which is configured to connect the load-bearing structure to the mounting base and adjust the mounting position of the load-bearing structure on the mounting base.
[0031] In some embodiments, the adjustment component includes:
[0032] Multiple connectors, each connector including a first connecting portion and a second connecting portion, the second connecting portion being configured to connect to a mounting base, the first connecting portion having a first guide groove; wherein, a portion of the first guide grooves on the connectors extend along a first direction, and another portion of the first guide grooves on the connectors extend along a second direction, the first direction and the second direction intersecting and both being perpendicular to the thickness direction of the display component;
[0033] A sliding member corresponding to each of the first guide grooves is slidably disposed in the corresponding first guide groove and fixedly connected to the bearing structure.
[0034] In some embodiments, the support structure includes two third edges disposed opposite to each other in the first direction and two fourth edges disposed opposite to each other in the second direction, each of the third edges and each of the fourth edges being provided with the connector, the guide groove on the connector of the third edge extending along the first direction, and the first guide groove on the connector of the fourth edge extending along the second direction.
[0035] In some embodiments, a second guide groove is provided on the second connecting portion, and the second guide groove extends along the thickness direction of the display component.
[0036] This disclosure also provides a splicing display device, including multiple splicing units spliced together, wherein the splicing unit includes:
[0037] Display components;
[0038] A cabinet is disposed on the backlight side of the display component, the cabinet including a cutout portion that penetrates the cabinet along the thickness direction of the display component;
[0039] A first magnetic component, comprising a first part and a second part capable of magnetic attraction, wherein the first part is disposed on the display component and the second part is disposed on the housing;
[0040] A magnetic adsorption sheet is configured to be rotatably connected to the display assembly so that the magnetic adsorption sheet is in one of a first state and a second state.
[0041] In the first state, the magnetic adsorption sheet is positioned opposite the surface of the display component facing the housing;
[0042] In the second state, the magnetic adsorption sheet is magnetically attracted to the auxiliary component located on the side of the hollowed-out portion, or the magnetic adsorption sheet is magnetically attracted to the magnetic adsorption sheet in the adjacent splicing unit.
[0043] In some embodiments, the splicing unit further includes:
[0044] The mounting component includes a movable part, a fixed part, and a rotating shaft. The movable part is fixedly connected to the display component, and the movable part is rotatably connected to the fixed part via the rotating shaft. The rotating shaft extends along the surface of the display component toward the housing.
[0045] The magnetic adsorption sheet is fixed to the movable part.
[0046] In some embodiments, the plurality of splicing units are arranged sequentially in a first direction, and the display component includes a first edge and a second edge disposed opposite to each other in the first direction. The mounting members are disposed at positions near the first edge and near the second edge. The rotation axis of the mounting member near the first edge is in the same direction as the extension of the first edge, and the rotation axis of the mounting member near the second edge is in the same direction as the extension of the second edge.
[0047] In some embodiments, the splicing unit further includes:
[0048] A first magnetic component, comprising a first part and a second part capable of magnetic attraction, wherein the first part is disposed on the display component;
[0049] Mounting base, the mounting base being disposed on the housing and configured to move relative to the housing along the thickness direction of the display component;
[0050] The second component is fixed to the mounting base.
[0051] In some embodiments, the housings of the plurality of splicing units form a load-bearing structure, and the load-bearing structure is provided with an adjustment component, which is configured to connect the load-bearing structure to the mounting base and adjust the mounting position of the load-bearing structure on the mounting base.
[0052] In some embodiments, the adjustment component includes:
[0053] Multiple connectors, each connector including a first connecting portion and a second connecting portion, the second connecting portion being configured to connect to a mounting base, the first connecting portion having a first guide groove; wherein, a portion of the first guide grooves on the connectors extend along a first direction, and another portion of the first guide grooves on the connectors extend along a second direction, the first direction and the second direction intersecting and both being perpendicular to the thickness direction of the display component;
[0054] A sliding member corresponding to each of the first guide grooves is slidably disposed in the corresponding first guide groove and fixedly connected to the bearing structure.
[0055] In some embodiments, the support structure includes two third edges disposed opposite to each other in the first direction and two fourth edges disposed opposite to each other in the second direction, each of the third edges and each of the fourth edges being provided with the connector, the guide groove on the connector of the third edge extending along the first direction, and the first guide groove on the connector of the fourth edge extending along the second direction.
[0056] In some embodiments, a second guide groove is provided on the second connecting portion, and the second guide groove extends along the thickness direction of the display component. Attached Figure Description
[0057] The accompanying drawings are provided to further illustrate the present disclosure and form part of the specification. They are used together with the following detailed description to explain the present disclosure, but do not constitute a limitation thereof. In the drawings:
[0058] Figure 1 This is a schematic diagram of a splicing display device provided in some embodiments.
[0059] Figure 2 This is an exploded view of a splicing display device provided in some embodiments of this disclosure.
[0060] Figure 3 This is an exploded view of a splicing unit in a splicing display device provided in some embodiments of this disclosure.
[0061] Figure 4 This is a side view of two adjacent splicing units provided in some embodiments of this disclosure.
[0062] Figure 5 This is a top view of four splicing units provided in some embodiments of this disclosure.
[0063] Figure 6 This is a perspective view of the four splicing units provided in some embodiments of this disclosure at their splicing positions.
[0064] Figure 7 This is a perspective view of the four boxes provided in some embodiments of this disclosure at their splicing positions.
[0065] Figure 8 This is a partial perspective view of the four boxes provided in some embodiments of this disclosure when they are not assembled.
[0066] Figure 9 This is a perspective view of the lower right corner of the housing provided in some embodiments of this disclosure.
[0067] Figure 10 This is a schematic diagram showing the position of the upper left corner of the splicing unit provided in some embodiments of this disclosure.
[0068] Figure 11 This is a schematic diagram of the first mounting portion and the second mounting portion on the housing provided in some embodiments of this disclosure.
[0069] Figure 12A for Figure 6 A sectional view obtained along the cutting line AA'.
[0070] Figure 12BThis is a schematic diagram of a positioning structure provided in some embodiments of this disclosure.
[0071] Figure 13 This is a schematic diagram showing the second component provided in some embodiments of this disclosure mounted on a mounting base.
[0072] Figure 14 This is a plan view of a plurality of boxes provided in other embodiments of this disclosure.
[0073] Figure 15 This is a schematic diagram of two adjacent boxes in a close proximity position provided in other embodiments of this disclosure.
[0074] Figure 16 This is a schematic diagram of two adjacent boxes spliced together, as provided in some other embodiments of this disclosure.
[0075] Figure 17 This is a plan view of a plurality of boxes provided in some embodiments of the present disclosure.
[0076] Figure 18 for Figure 17 A 3D view of a single box.
[0077] Figure 19 This is a partial schematic diagram of four adjacent boxes provided in some embodiments of this disclosure.
[0078] Figure 20 This is a schematic diagram of four adjacent boxes spliced together in some embodiments of this disclosure.
[0079] Figure 21 This is a schematic diagram of a display component provided in some embodiments of this disclosure.
[0080] Figure 22 This is a schematic diagram showing the magnetic adsorption element provided in some embodiments of this disclosure in a first state.
[0081] Figure 23 This is a schematic diagram showing the magnetic adsorption element in a second state in some embodiments of this disclosure.
[0082] Figure 24 This is a schematic diagram of the housing provided in some embodiments of this disclosure.
[0083] Figure 25 This is a schematic diagram of two adjacent display components spliced together in some embodiments of this disclosure.
[0084] Figure 26 This is a schematic diagram showing the force direction of multiple display components provided in some embodiments of this disclosure during the splicing process.
[0085] Figure 27This is a schematic diagram of the housing and adjustment components provided in some embodiments of this disclosure.
[0086] Figure 28 for Figure 27 A magnified view of region M. Detailed Implementation
[0087] The specific embodiments of this disclosure will be described in detail below with reference to the accompanying drawings. It should be understood that the specific embodiments described herein are for illustration and explanation only and are not intended to limit this disclosure.
[0088] To make the objectives, technical solutions, and advantages of the embodiments of this disclosure clearer, the technical solutions of the embodiments of this disclosure will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some, not all, of the embodiments of this disclosure. All other embodiments obtained by those skilled in the art based on the described embodiments of this disclosure without creative effort are within the scope of protection of this disclosure.
[0089] Unless otherwise defined, the technical or scientific terms used in the embodiments of this disclosure should have the ordinary meaning understood by one of ordinary skill in the art to which this disclosure pertains. The terms "first," "second," and similar terms used in this disclosure do not indicate any order, quantity, or importance, but are merely used to distinguish different components. Similarly, terms such as "comprising" or "including" mean that the element or object preceding the word encompasses the elements or objects listed following the word and their equivalents, without excluding other elements or objects. Terms such as "connected" or "linked" are not limited to physical or mechanical connections, but can include electrical connections, whether direct or indirect. Terms such as "upper," "lower," "left," and "right" are used only to indicate relative positional relationships; when the absolute position of the described object changes, the relative positional relationship may also change accordingly.
[0090] As used herein, “parallel” and “perpendicular” include the described situation and situations that are similar to the described situation, within an acceptable range of deviation, which is determined by those skilled in the art taking into account the measurement under discussion and the error associated with the measurement of a particular quantity (i.e., the limitations of the measurement system). For example, “parallel” includes absolute parallelism and approximate parallelism, where an acceptable range of deviation for approximate parallelism may be, for example, within 5°; “perpendicular” includes absolute perpendicularity and approximate perpendicularity, where an acceptable range of deviation for approximate perpendicularity may also be, for example, within 5°.
[0091] It should be understood that when a layer or element is referred to as being on another layer or substrate, it can mean that the layer or element is directly on the other layer or substrate, or that there is an intermediate layer between the layer or element and the other layer or substrate.
[0092] This document describes exemplary embodiments with reference to sectional views and / or plan views, which are idealized exemplary drawings. In the drawings, the thickness of layers and regions is enlarged for clarity. Therefore, variations in shape relative to the drawings are contemplated due to, for example, manufacturing techniques and / or tolerances. Therefore, exemplary embodiments should not be construed as limited to the shapes of the regions shown herein, but rather include shape deviations due to, for example, manufacturing processes. Thus, the regions shown in the drawings are schematic in nature, and their shapes are not intended to show the actual shapes of the regions of the device, nor are they intended to limit the scope of the exemplary embodiments.
[0093] Figure 1 These are schematic diagrams of splicing display devices provided in some embodiments, such as... Figure 1 As shown, in some splicing display devices, multiple splicing units 1 are spliced together. Each splicing unit 1 includes a housing and at least one display component supported on the housing. In one example, the display component may include a carrier plate and a display substrate supported thereon. The carrier plate is fixed to a corresponding housing, and the display substrate is fixed to the side of the carrier plate away from the housing. The display substrate may include a substrate and a light-emitting element disposed on the substrate. The substrate may be a glass substrate, and the light-emitting element may include a miniature inorganic light-emitting diode.
[0094] During the assembly of the splicing display device, due to limitations in process conditions and the flatness of the cabinet surface itself, it is inevitable that there will be a step difference between adjacent cabinets. This results in a step difference on the display surface of the entire splicing display device at the splicing position of adjacent splicing units 1, which in turn affects the flatness.
[0095] In this embodiment of the disclosure, "segment difference" refers to the height difference in the thickness direction of the display component (hereinafter referred to as the Z direction).
[0096] Figure 2 This is an exploded view of the splicing display device provided in some embodiments of this disclosure. Figure 3 This is an exploded view of a splicing unit in a splicing display device provided in some embodiments of this disclosure. Figure 4 This is a side view of two adjacent splicing units provided in some embodiments of this disclosure. Figure 5 This is a top view of four splicing units provided in some embodiments of this disclosure. Figure 6 This is a perspective view of the four splicing units provided in some embodiments of this disclosure at their splicing positions. Figure 7 This is a perspective view of the four boxes provided in some embodiments of this disclosure at their splicing positions. Figure 8 This is a partial perspective view of the four boxes provided in some embodiments of this disclosure when they are not assembled. For example... Figures 2 to 8 As shown, the splicing display device in this embodiment includes multiple splicing units 1 spliced together, wherein each splicing unit 1 includes a display component 10 and a housing 20.
[0097] For example, the display assembly 10 may include a display substrate 11 and a driving circuit board (not shown) for providing signals to the display substrate 11. The display substrate 11 may include a substrate and a light-emitting element located on the substrate. The light-emitting element may include a miniature inorganic light-emitting diode, such as a Mini-LED or Micro-LED. The driving circuit board is located on the non-display side of the display substrate 11 and is electrically connected to the display substrate 11 via a flexible circuit board 13. In an optional example, the display assembly 10 may further include a carrier 12 for supporting the display substrate 11, with the driving circuit board located on the side of the carrier 12 away from the display substrate 11. In one example, the carrier 12 is a plate-like structure, and the carrier 12 may be provided with clearance holes, through which the flexible circuit board 13 passes. A protective shell 14 and the carrier 12 form a protective space, in which the driving circuit board is located. In another example, the carrier 12 may be a frame structure.
[0098] For example, the cabinet 20 is disposed on the non-display side of the display component 10; a support area 30a is provided at the edge of the cabinet 20, the support area 30a has a support surface 30 facing away from the cabinet 20, and the support surface 30 is configured to support at least the display component 10 in the splicing unit 1 to which the support area 30a belongs.
[0099] It is understood that a display assembly may include multiple display panels and driver circuit boards for providing signals to the multiple display panels, with the housing supporting the multiple display panels within the display assembly. For example... Figure 2 As shown, the display assembly 10 includes two display panels 11, and the housing 20 is used to support the two display panels 11.
[0100] In this arrangement, the support areas 30a in different splicing units 1 are spaced apart, and the support surface 30 of the support area 30a in at least one splicing unit 1 is also configured to support the display components 10 in adjacent splicing units 1.
[0101] In this embodiment of the present disclosure, at least one support area 30a in the splicing unit 1 can simultaneously support the display components 10 in the adjacent splicing unit 1. In this case, even if there is a step difference between two adjacent cabinets 20 during splicing, it can prevent the two adjacent display components 10 from having an obvious step difference at the splicing position.
[0102] For example, in each pair of adjacent splicing units 1, the support surface 30 of at least one support area 30a of one splicing unit 1 is configured to support the display components 10 in the two adjacent splicing units 1, thereby helping to reduce the step difference between the display components 10 of each pair of adjacent splicing units 1.
[0103] Among them, multiple splicing units 1 can be arranged in an array. In this embodiment of the present disclosure, "two adjacent units" can be two adjacent units in the same row or two adjacent units in the same column.
[0104] For example, in any two adjacent splicing units 1, the edges of the two display components 10 that are close to each other are supported on the same support area 30a, which helps to reduce the step difference between the display components 10 of each two adjacent splicing units 1.
[0105] For example, multiple splicing units 1 are arranged in multiple rows and columns, and each display component 10 is a rectangular structure, such as... Figure 6 As shown, in the four splicing units 1 located in two adjacent rows and two adjacent columns, the corners of each display component 10 that are close to each other are supported on the support surface 30 of the same support area 30a, so as to prevent step difference from occurring at the splicing position of the four adjacent display components 10 and improve the flatness of the splicing display device.
[0106] For example, combining Figures 5 to 8 As shown, the four splicing units 1 located in two adjacent rows and two adjacent columns are respectively denoted as: upper left splicing unit, upper right splicing unit, lower left splicing unit, and lower right splicing unit. The lower right corner of the housing 20 of the upper left splicing unit is provided with a support area 30a, and the support surface 30 of the support area 30a can simultaneously support the corners of the display components 10 of the four splicing units 1.
[0107] For example, the cabinet 20 has a cutout 20v. During the application of the splicing display device, signal transmission lines can pass through the cutout 20v to provide the drive signals provided by the system motherboard to the drive circuit board. The cabinet 20 has a frame-shaped structure, and the outline of the cabinet 20 projected onto the reference plane (here, "outline" refers to the outer outline) is a polygon. The reference plane is a plane perpendicular to the Z direction. The support area 30a is located in the interior corner region of the polygon, that is, the region located inside the polygon and adjacent to the corner. For example, each cabinet 20 is provided with a support area 30a. Each support area 30a supports the display component 10 in its own splicing unit 1, and also supports the display components 10 in adjacent splicing units 1, so that the positions of every two adjacent display components 10 overlap on the same support area 30a, improving the flatness of the splicing display device.
[0108] For example, all boxes 20 have the same structure to facilitate standardized production. For example, such as Figure 5 As shown, each box 20 has a support area 30a at its right edge and lower edge. The support area 30a at the right edge and the support area 30a at the lower edge can be connected to form an L-shaped integrated structure.
[0109] For example, there is a gap between the display components 10 of two adjacent splicing units 1; such as Figure 7 As shown, at least one support area 30 has a groove 30v, which overlaps with the orthographic projection of the aforementioned interval on the reference plane. A light-absorbing material (not shown) is disposed in the groove 30v. By providing a light-absorbing material, light leakage at the splicing gap can be reduced, and the dark state consistency of the splicing display device can be improved.
[0110] For example, in Figures 5 to 8 In the upper left splicing unit, an L-shaped support area 30a is provided at the lower right corner of the housing 20. This support area 30a can simultaneously support the corners of the display components 10 of the four splicing units 1. In addition, an L-shaped groove 30v is formed on the L-shaped support area 30a. The intervals between the display components 10 of the upper left and upper right splicing units, and between the display components 10 of the upper left and lower left splicing units, overlap with the orthographic projection of the L-shaped groove 30v on the reference plane.
[0111] For example, the recess 30v includes a first recess extending along the row direction. The spacing between two adjacent display components 10 in the same column overlaps with the orthographic projection of the first recess on the reference plane. The width of the first recess is greater than the spacing width between two adjacent display components 10 in the same column, and the length of the first recess is less than the spacing length between two adjacent display components 10 in the same column. For example, the recess 30v includes a second recess extending along the column direction. The spacing between two adjacent display components 10 in the same row overlaps with the orthographic projection of the second recess on the reference plane. The width of the second recess is greater than the spacing width between two adjacent display components 10 in the same row, and the length of the second recess is less than the spacing length between two adjacent display components 10 in the same row.
[0112] For example, the distance between the support areas 30a of any two adjacent splicing units 1 (e.g. Figure 5 The D1 and D2 indicated in the figure are greater than or equal to 60mm. In this case, when the display component 10 is simultaneously attached to the support area 30a of multiple splicing units 1, even if there is a step difference between the support surfaces 30 of the support areas 30a in different splicing units 1, it can be ensured that different positions of the display component 10 form a smooth transition without any abrupt height changes.
[0113] For example, such as Figures 7 to 9As shown, one of every two adjacent cabinets 20 is designated as the first cabinet and the other as the second cabinet. Both the first and second cabinets include a main structure 21. The first cabinet also includes a first eaves structure 22 disposed on the main structure 21. The first eaves structure 22 is configured to cover part of the edge area of the main structure 21 of the second cabinet. The support surface 30 is located on the surface of the first eaves structure 22 facing the display component 10. During the assembly of the splicing display device, multiple cabinets 20 can be assembled first, such that the first eaves structure 22 of one of every two adjacent cabinets 20 overlaps the main structure 21 of the other cabinet 20, thereby facilitating the overlap of adjacent positions of two adjacent display components 10 on the same support area 30a.
[0114] For example, the surface of the first eaves structure 22 facing the display component 10 is a concave-convex surface, which includes a connected convex surface and a concave surface. The convex surface is located on the side of the concave surface extending towards the display component 10, and the area where the convex surface is located serves as the support area 30a. The convex surface is the aforementioned support surface 30. In one example, there is a height difference between the convex surface and the concave surface extending (e.g., Figure 4 As shown in h), the height difference h is in the range of 1 to 1.5 mm. When a part of the display component 10 overlaps the support surface 30 (i.e., the convex surface) and another part overlaps the concave surface, a smooth transition can be made between different positions of the display component 10, improving the flatness of the splicing display device.
[0115] For example, multiple splicing units 1 are arranged in multiple rows along the height direction of the splicing display device, with each row including multiple splicing units 1. Each cabinet 20 has a first eaves structure 22 provided on its right and lower edges. Figure 9 The image shows a perspective view of the lower right corner of the box 20. Among the multiple splicing units 1, except for the bottom row of splicing units 1 and the rightmost column of splicing units 1, in each of the other splicing units 1, the first eaves structure 22 of the right edge of the box 20 overlaps with the main structure 21 of the right side of the box 20; the first eaves structure 22 of the lower edge overlaps with the main structure 21 of the lower side of the box 20.
[0116] Figure 10 This is a schematic diagram showing the upper left corner position of the splicing unit 1 provided in some embodiments of this disclosure, such as... Figure 10 As shown, the edge of each display component 10 extends beyond the edge of the housing 20. That is, a portion of the orthographic projection of the display component 10 on the reference plane extends beyond the orthographic projection of the housing 20 on the reference plane. The width of the extended portion is between 1 and 2 mm to prevent the display component 10 from being damaged due to excessive extension.
[0117] For example, such as Figure 8 As shown, the second housing also includes a limiting post 24 disposed on the main structure 21. Figure 8 , Figure 9 As shown, the first eaves structure 22 has a clearance notch 22v, and part of the limiting post 24 is located in the clearance notch 22v. During the assembly of multiple boxes 20, for any two adjacent boxes 20, the two boxes 20 can be aligned first, so that the limiting post 24 of one box 20 is located in the clearance notch 22v of the first extension platform of the other box 20, thereby preventing the two boxes 20 from moving relative to each other in the X and Y directions. Then, the two adjacent boxes 20 are fixedly connected to improve the accuracy of the relative position of the adjacent boxes 20. The X direction is perpendicular to the Y direction, and both the X and Y directions are perpendicular to the Z direction.
[0118] For example, any two adjacent housings 20 are detachably connected by fasteners. For instance, there may be multiple fasteners, which may include a first screw, such as... Figure 8 and Figure 9 As shown, in any two adjacent housings 20, one housing 20 has a first screw hole V1, and the other housing 20 has a second screw hole V2 corresponding to the first screw hole V1. A first screw extends parallel to the X direction, passes through the first screw hole V1, and is screwed into the second screw hole V2, thereby connecting the two adjacent housings 20. For example, two adjacent housings 20 arranged along the X direction are connected by a first screw extending along the X direction, and two adjacent housings 20 arranged along the Y direction are connected by a first screw extending along the Y direction.
[0119] In addition, multiple fasteners may also include a second screw, such as Figure 11 As shown, in any two adjacent housings 20, one housing 20 is provided with a first mounting part 71, and the first mounting part 71 has a third screw hole V3. The other housing 20 is provided with a second mounting part 72, and the second mounting part 72 has a fourth screw hole V4. The first mounting part 71 and the second mounting part 72 are arranged in the Z direction. The second screw extends along the Z direction, passes through the fourth screw hole V4 and is screwed into the third screw hole V3, thereby connecting the two adjacent housings 20.
[0120] Figure 12A for Figure 6 A cross-sectional view obtained along the cutting line AA', for example, as shown below. Figure 3 , Figure 6 , Figure 7 and Figure 12AAs shown, the splicing unit 1 also includes a first magnetic component 50, which includes a first component 51 and a second component 52 that are magnetically attracted to each other. The first component 51 is disposed on the display component 10, for example, it can be disposed on the carrier plate 12 of the display component 10. The second component 52 is disposed on the housing 20. In one example, one of the first component 51 and the second component 52 is a magnet, and the other is made of a ferromagnetic material, such as iron, so that the first component 51 and the second component 52 can approach each other or even attract each other. In another example, both the first component 51 and the second component 52 are magnets, and the magnetic poles of their two ends that are close to each other are opposite, which can also make the first component 51 and the second component 52 approach each other or even attract each other.
[0121] like Figure 12A As shown, the splicing unit 1 also includes a mounting base 53, which is disposed on the housing 20 and configured to move relative to the housing 20 along the Z direction; wherein, the second component 52 is fixed on the mounting base 53. In this embodiment of the present disclosure, by controlling the movement of the mounting base 53 relative to the housing 20 in the Z direction, the display component 10 can be adjusted in the Z direction, thereby further improving the flatness of the display surface of the splicing display device.
[0122] For example, such as Figure 12A As shown, the housing 20 has a threaded hole V0. The mounting base 53 includes a mounting part 531 and a screw part 532. At least a portion of the screw part 532 is located in the threaded hole V0. The mounting part 531 is fixedly connected to one end of the screw part. The second component 52 is fixed on the mounting part 531. By rotating the mounting base 53, the mounting base 53 can be moved relative to the housing 20 in the Z direction.
[0123] For example, such as Figure 6 , Figure 8 as well as Figure 12A As shown, the housing 20 may include a positioning structure 54 integrally formed with the main structure 21. The positioning structure 54 has a positioning groove 54v, and a threaded hole V0 may be formed at the bottom of the positioning groove 54v. The mounting part 531 of the mounting base 53 and the second component 52 are located in the positioning groove 54v. For example, a positioning structure 542 is provided at two diagonal positions (such as the upper left corner and the lower right corner) of each housing 20; at the other two diagonal positions (such as the upper right corner and the lower left corner) of each housing 20, the mounting base 53 is directly threaded to the main structure 21 of the housing 20, that is, no positioning structure 54 is provided on the outer periphery of the mounting base 53.
[0124] For example, when the central axis of the positioning groove 54v is collinear with the central axis of the corresponding first component 51, there is a certain distance between the two ends of the first component 51 in the X direction and the inner surface of the positioning groove 54v (e.g., Figure 6and Figure 12A As shown in the diagram, d1 and d2, where (d1+d2) ranges from 3mm to 5mm, and the surface of the positioning structure 54 facing the display component 10 is higher than the surface of the second component 52 facing the display component 10 and the surface of the mounting part 531 facing the display component 10 in the positioning groove 54v. In this case, during the splicing of two adjacent splicing units along the X direction, the presence of the positioning structure 54 and the positioning groove 54v can prevent them from being squeezed and bumped, providing space redundancy during splicing; correspondingly, when two display components are supported on the housing and are arranged adjacently along the X direction, the presence of the positioning structure 54 and the positioning groove 54v can prevent them from being squeezed and bumped, providing space redundancy during the placement of the two display components.
[0125] for Figure 6 and Figure 12A The positioning structure 54 shown can also have a certain gap between the two ends of the first component 51 in the Y direction and the inner side of the positioning groove 54v when the central axis of the positioning groove 54v is collinear with the central axis of the corresponding first component 51, thereby preventing two adjacent display components from colliding in the Y direction during the splicing process.
[0126] It should be noted that, in Figure 6 and Figure 12A The illustration uses a cylindrical positioning structure 54 as an example. However, the positioning structure 54 can be configured in other shapes, as long as it can effectively limit the positioning of the first component 51 in the X direction. For example, ... Figure 12B As shown, the positioning structure 54 is a V-shaped retaining wall, surrounding the mounting base 53 and the second component 52. The threaded hole V0 is opened on the main structure 21 of the housing 20, eliminating the need for the aforementioned positioning groove 54v. Furthermore, the distance between the positioning structure 54 and the corresponding first component 51 in the X direction can be within the range of 3mm to 5mm.
[0127] It should also be noted that, in the embodiments of this disclosure, the magnetic attraction between the first component 51 and the second component 52 means that there is a mutual magnetic force between the first component 51 and the second component 52, and it is not necessarily required that the first component 51 and the second component 52 be in contact. For example, in practical applications, such as Figure 12A As shown, a gap may exist between the first component 51 and the second component 52, with the gap ranging from 0.2 mm to 0.45 mm.
[0128] Figure 13This is a schematic diagram illustrating the second component 52 disposed on the mounting base 53 in some embodiments of this disclosure. For example, the mounting portion 531 is provided with a mounting groove, and the second component 52 is fixed in the mounting groove; for example, the second component 52 is engaged in the mounting groove. For example, as shown... Figure 13 As shown, the mounting base 53 also has at least two oppositely arranged notches 53v, which are connected to the mounting groove, so as to facilitate the removal of the second component 52 from the mounting groove using the clamping member, thereby facilitating product maintenance.
[0129] Figure 14 This is a plan view of a plurality of housings 20 provided in other embodiments of this disclosure. Figure 15 This is a schematic diagram showing two adjacent boxes 20 in a close-to-each-other position as provided in other embodiments of this disclosure. Figure 16 This is a schematic diagram showing the splicing of two adjacent boxes 20 as provided in other embodiments of this disclosure. Figures 11 to 13 In the illustrated embodiment, the splicing display device is configured similarly to that in the aforementioned embodiments, the only difference being that... Figures 14 to 16 In the illustrated embodiment, each housing 20 has a plurality of support areas 30a at at least one edge position. For example, each housing 20 has a plurality of support areas 30a at the edges of adjacent sides. Each support area 30a has a linear groove 30v.
[0130] Figure 17 This is a plan view of a plurality of housings 20 provided in some embodiments of the present disclosure. Figure 18 for Figure 17 A three-dimensional view of a single box 20. Figure 19 This is a partial schematic diagram of four adjacent boxes 20 provided in some embodiments of this disclosure. Figure 20 This is a schematic diagram of four adjacent boxes 20 spliced together in some embodiments of this disclosure. Figure 20 The dashed lines L1 and L2 in the diagram represent the spacing between four adjacent display components 10. Figures 17 to 20 The illustrated embodiments and Figures 4 to 13 Similar to the illustrated embodiment, in any two adjacent splicing units 1, the edges of the two display components 10 that are close to each other are supported on the same support area 30a; and in the four splicing units 1 located in two adjacent rows and two adjacent columns, the corners of each display component 10 that are close to each other are supported on the support surface 30 of the same support area 30a; any two adjacent boxes 20 are respectively a first box and a second box, both of which include a main structure 21, and the first box also includes a first eaves structure 22. The first eaves structure 22 is located on the side of the main structure 21 of the second box facing the display component 10, and the support area 30a is provided on the side of the first eaves structure 22 facing the display component 10.
[0131] Figures 17 to 20 The illustrated embodiments and Figures 4 to 13 The difference lies only in that, in addition to the main structure 21 and the first eaves structure 22, the first housing also includes a second eaves structure 23. The first eaves structure 22 and the second eaves structure 23 are arranged opposite each other in the Z-direction, with the second eaves structure 23 located on the side of the first eaves structure 22 away from the display component 10. In the Z-direction, the main structure 21 is located between the first eaves structure 22 and the second eaves structure 23. The second eaves structure 23, the first eaves structure 22, and the main structure 21 of the first housing define a limiting groove V5, with a portion of the main structure 21 of the second housing located within the limiting groove V5. The arrangement of the first eaves structure 22 and the second eaves structure 23 allows for limiting the movement of two adjacent housings 20 in the Z-direction.
[0132] For example, a first eaves structure 22 and a second eaves structure 23 are provided at the edges of adjacent sides of each box 20. In addition, a support area 30a is provided at the edges of adjacent sides of each box 20, and the support area 30a is located on the first eaves structure 22.
[0133] In addition, with Figures 4 to 13 The difference in the illustrated embodiment is that, in Figures 17 to 20 In the middle, the first eaves structure 22 may not have an avoidance gap. The support area 30a may also not have a groove.
[0134] exist Figures 17 to 20 In the middle, two adjacent boxes 20 can be detachably connected by fasteners. For specific connection methods, please refer to [reference needed]. Figures 4 to 13 The description will not be repeated here.
[0135] Currently, in the splicing process of splicing display devices, each display component 10 is usually connected to the cabinet 20 in the Z direction. However, this method is inconvenient when splicing products with narrow seams.
[0136] To address this issue, embodiments of this disclosure provide a splicing display device, which includes multiple splicing units 1 that are spliced together, such as... Figure 2 and Figure 3 As shown, the splicing unit 1 includes a display component 10 and a housing 20 disposed on the non-display side of the display component 10. The structure of the display component 10 can be found in the description of the above embodiments, and will not be repeated here.
[0137] In addition, such as Figure 12A As shown, the splicing unit 1 may further include: a first magnetic component 50, which includes a first component 51 and a second component 52 capable of magnetic attraction. The first component 51 is disposed on the display component 10, and the second component 52 is disposed on the housing 20. Figure 24 As shown, the housing 20 has a hollow portion 20v extending through the housing 20 along the Z direction. The arrangement of the second component 52 on the housing 20 can be referred to in the above embodiment. Figure 12A , Figure 13 The description will not be repeated here. Additionally, combining... Figures 21 to 24 As shown, the splicing unit 1 may further include a magnetic adsorption sheet 61, wherein the magnetic adsorption sheet 61 is configured to be rotatably connected to the display component 10, so that the magnetic adsorption sheet 61 is in a first state (e.g., Figure 22 (as shown) and the second state (as shown) Figure 23 (as shown) one of the states; in the first state, the magnetic adsorption sheet 61 is positioned opposite the surface of the display component 10 facing the housing 20.
[0138] In one example, an auxiliary member 62 is provided on the side of the cutout portion 20v. In the second state, the magnetic adsorption piece 61 extends into the cutout portion 20v and magnetically attracts it to the auxiliary member 62. Either the magnetic adsorption piece 61 or the auxiliary member 62 can be made of a ferromagnetic material, such as iron; the other can be a magnet.
[0139] Alternatively, in another example, in the second state, the magnetic adsorption sheet 61 is magnetically attracted to the magnetic adsorption sheet 61 in the adjacent splicing unit 1. In this case, one of the two magnetic adsorption sheets 61 in adjacent splicing units 1 that are close to each other can be made of a ferromagnetic material, such as iron; the other can be made of a magnet.
[0140] In this embodiment of the disclosure, "mutual magnetic attraction" refers to the magnetic force that attracts two components to each other. The two components can be in contact or there can be a certain gap between them.
[0141] In this embodiment, a magnetic adsorption sheet 61 is provided on the side of the display component 10 facing the housing 20, and the magnetic adsorption sheet 61 can be in a first state or a second state. Therefore, during the assembly process of the splicing display device, after multiple housings 20 are assembled, each display component 10 can be sequentially placed on the corresponding housing 20. By controlling the state of different magnetic adsorption sheets 61, the direction of force on the display component 10 can be controlled, thereby achieving a sufficiently small gap between adjacent display components 10. Specifically, taking the magnetic adsorption sheet 61 in the second state and its magnetic attraction to the auxiliary component 62 as an example, ... Figure 25As shown, assuming the splicing display device includes two splicing units 1, after splicing the housings 20 of the two splicing units 1, the display component 10 of the left splicing unit is fixed to the housing 20. Then, the magnetic adsorption sheet on the left edge of the display component 10 in the right splicing unit is in the second state, and the magnetic adsorption sheets in other positions are in the first state. This causes the magnetic adsorption sheet 61 on the left edge of the right display component 10 to generate a magnetic attraction force with the auxiliary component 62 on the housing 20 at the opposite position (e.g., ...). Figure 25 As shown in F1), it also shows that component 10 is subjected to longitudinal gravity (as shown in F1). Figure 25 As shown in F2), the resultant force on the right display component 10 is as shown in F3, causing it to move and squeeze together with the left display component 10.
[0142] Similarly, when the auxiliary component 62 is not provided on the cabinet 20, the display component 10 can be moved relative to each other by relying on the magnetic attraction between the magnetic adsorption pieces 61 in the adjacent splicing unit 1.
[0143] For example, such as Figure 22 and Figure 23 As shown, the splicing unit 1 also includes a mounting component 63, which includes a movable part 632, a fixed part 631, and a rotating shaft 633. The movable part 632 is fixedly connected to the display component 10, and the movable part 632 is rotatably connected to the fixed part 631 through the rotating shaft 633. The rotating shaft 633 extends along the surface of the display component 10 toward the cabinet 20. The magnetic adsorption sheet 61 is fixed on the movable part 632, thereby achieving an indirect rotatable connection between the magnetic adsorption sheet 61 and the display component 10 by means of the mounting component 63.
[0144] For example, both the movable part 632 and the fixed part 631 can be plate-shaped structures. The fixed part 631 can be connected to the carrier plate 12 of the display assembly 10. For example, the fixed part 631 can be fixed to the carrier plate 12 by welding, bonding, or by screws or other connectors. The magnetic adsorption piece 61 can be fixed to the movable part 632 by bonding, welding, or other methods, or by screws or other connectors. Alternatively, a mounting groove can be provided on the movable part 632, and the magnetic adsorption piece 61 can engage in the mounting groove. This disclosure does not limit the shape of the magnetic adsorption piece 61; it can be circular, elliptical, rectangular, or other irregular shapes.
[0145] For example, multiple splicing units 1 are arranged sequentially in a first direction (hereinafter referred to as the X direction). Specifically, the multiple splicing units 1 can be arranged in an array, with the X direction being the row direction, and the X direction can be perpendicular to the height direction of the splicing display device. The splicing display device can be installed on a wall or other mounting base, and the height direction of the splicing display device is the height direction when the splicing display device is in use. The multiple splicing units 1 can be arranged in one row and multiple columns, or in multiple rows and multiple columns.
[0146] The display component 10 includes a first edge and a second edge disposed opposite to each other in the X direction. Mounting members 63 and magnetic adsorption pieces 61 are disposed near both the first and second edges. The pivot 633 of the mounting member 63 near the first edge extends in the same direction as the first edge, and the pivot 633 of the mounting member 63 near the second edge extends in the same direction as the second edge. Multiple mounting members 63 and multiple magnetic adsorption pieces 61 can be disposed near both the first and second edges.
[0147] Figure 26 The diagram shows the force directions of the display components of splicing unit 1 during the assembly process. The force directions of each display component are as follows: Figure 26 As indicated by the arrows in the diagram. Taking a splicing display device comprising two rows and four columns of splicing units 1 as an example, as shown... Figure 26 As shown, during the splicing process, the magnetic adsorption pieces 61 on the left side of each splicing unit 1 in the first and second columns, and the magnetic adsorption pieces 61 on the right side of each splicing unit 1 in the third and fourth columns, are in a first state. The magnetic adsorption pieces 61 on the right side of each splicing unit 1 in the first and second columns, and the magnetic adsorption pieces 61 on the left side of each splicing unit 1 in the third and fourth columns, are in a second state. In this state, after each display component 10 is placed on its corresponding housing 20, the magnetic adsorption between the magnetic adsorption pieces 61 and the corresponding auxiliary parts 62, along with the gravity of the display components 10 themselves, causes the display components 10 in each splicing unit 1 in the first and second columns to be subjected to a force in the lower right direction, and the display components 10 in each splicing unit 1 in the third and fourth columns to be subjected to a force in the lower left direction. This causes the splicing units 1 on both sides of the splicing display device to automatically tighten. This method improves the installation efficiency of the splicing display device and reduces installation difficulty.
[0148] In this disclosure, Figures 21 to 26 The illustrated embodiments can be used with Figures 4 to 20The embodiments are combined. Specifically, when the display component 10 is provided with a magnetic adsorption sheet 61, the display component 10 can be supported on the housing 20, or a support area 30a can be provided on the housing 20, and the display component 10 is supported on the support surface 30 of the support area 30a. The specific overlapping method of the display component 10 on the support area 30a, the connection method between adjacent housings 20, and the connection method between the display component 10 and the housing 20 can all be referred to the above description. Figures 4 to 20 The description will not be repeated here.
[0149] Figure 27 This is a schematic diagram of the housing 20 and adjustment components provided in some embodiments of this disclosure. Figure 28 for Figure 27 A magnified view of region M, such as Figures 27 to 28 As shown, in some embodiments, the housings 20 of multiple splicing units 1 form a supporting structure 2. The supporting structure 2 is provided with an adjustment component, which is configured to connect the supporting structure 2 to the mounting base and adjust the installation position of the supporting structure 2 on the mounting base.
[0150] The installation base can be a wall or other structures.
[0151] For example, such as Figure 27 and Figure 28 As shown, the adjustment assembly includes multiple connectors 80 and multiple sliders 83. Each connector 80 includes a first connecting portion 81 and a second connecting portion 82. The second connecting portion 82 is configured to connect to the mounting base. The first connecting portion 81 has a first guide groove 81v. A portion of the first guide groove 81v on the connectors 80 extends along the X direction, while the other portion extends along a second direction (hereinafter referred to as the Y direction). The X and Y directions intersect and are both perpendicular to the Z direction; for example, the X direction is perpendicular to the Y direction. Each slider 83 corresponds to a first guide groove 81v. The slider 83 is slidably disposed within the corresponding first guide groove 81v (i.e., the slider 83 can undergo relative displacement with the connector 80 along the extension direction of the first guide groove 81v) and is fixedly connected to the bearing structure 2.
[0152] For example, the first guide groove 81v can be a through groove that passes through the second connecting part 82 along the Z direction, and the slider 83 can be a screw that passes through the first guide groove 81v.
[0153] For example, the first connecting part 81 and the second connecting part 82 can be plate-like structures, and the two can be connected as a single structure. Of course, the first connecting part 81 and the second connecting part 82 can also be connected by other connectors.
[0154] In this embodiment, by controlling the sliding member 83 to move along the first guide groove 81v, the bearing structure 2 is displaced relative to the connecting member 80, thereby adjusting the installation position of the bearing structure 2 on the mounting base; compared with the bracket behind the traditional housing 20, the connecting member 80 and the sliding member 83 have simple structures and are easy to install and implement.
[0155] For example, the support structure 2 includes two third edges disposed opposite to each other in the X direction and two fourth edges disposed opposite to each other in the Y direction. Each third edge and each fourth edge is provided with a connector 80. A first guide groove 81v on the connector 80 of the third edge extends in the X direction, and a first guide groove 81v on the connector 80 of the fourth edge extends in the Y direction.
[0156] In this embodiment, the number of connectors 80 provided at each third edge and each fourth edge is not limited. In one example, to improve the installation stability of the load-bearing structure 2, multiple connectors 80 may be provided at each third edge and each fourth edge.
[0157] For example, such as Figure 28 As shown, a second guide groove 82v is provided on the second connecting part 82, and the second guide groove 82v extends along the Z direction. The second guide groove 82v can penetrate along the thickness direction of the second connecting part 82. In practical applications, screws can be inserted into the second guide groove 82v and connected to the mounting base, thereby mounting the second connecting part 82 onto the mounting base. Since the second guide groove 82v extends along the Z direction, the second connecting part 82 can move relative to the mounting base along the Z direction, thereby adjusting the position of the splicing display device in the Z direction.
[0158] In this disclosure, Figures 27 to 28 The illustrated embodiments can be used with Figures 4 to 26 The embodiments are combined. Specifically, when the adjustment component is provided on the supporting structure 2, the display component 10 can be supported on the housing 20, or a support area 30a can be provided on the housing 20, and the display component 10 can be supported on the support area 30a. The specific implementation method of the display component 10 overlapping the support area 30a can be found in the above description. Figures 4 to 20 The box 20 can be equipped with a first eaves structure 22, or both a first eaves structure 22 and a second eaves structure 23 can be installed simultaneously. For details, please refer to the above description. Figures 4 to 20 The description is as follows. Additionally, when an adjustment component is installed on the support structure 2, a magnetic adsorption sheet can also be installed on the display component 10, as described above.
[0159] It is understood that the above embodiments are merely exemplary embodiments used to illustrate the principles of this disclosure, and this disclosure is not limited thereto. For those skilled in the art, various modifications and improvements can be made without departing from the spirit and substance of this disclosure, and these modifications and improvements are also considered to be within the scope of protection of this disclosure.
Claims
1. A splicing display device, comprising multiple splicing units spliced together, characterized in that, The splicing unit includes: Display components; The housing is located on the non-display side of the display component; A support area is provided at the edge of the housing, and the support area has a support surface facing the display component. The support surface is configured to support at least the display component in the splicing unit. In this configuration, the support areas in different splicing units are spaced apart, and the support surface of the support area in at least one splicing unit is also configured to support the display components in adjacent splicing units.
2. The splicing display device according to claim 1, characterized in that, In each pair of adjacent splicing units, the support surface of at least one support area of one of the splicing units is configured to support the display components in the two adjacent splicing units.
3. The splicing display device according to claim 1, characterized in that, The outline of the housing projected onto the reference plane is a polygon, and the reference plane is a plane perpendicular to the thickness direction of the display component; the support area is located in the interior corner region of the polygon.
4. The splicing display device according to claim 1, characterized in that, The distance between the support areas in any two adjacent splicing units is greater than or equal to 60mm.
5. The splicing display device according to claim 1, characterized in that, The display components of two adjacent splicing units are spaced apart; at least one support area has a groove, the orthographic projection of the groove on the reference surface overlaps with the orthographic projection of the space on the reference surface, and a light-absorbing material is disposed in the groove; the reference surface is a plane perpendicular to the thickness direction of the display component.
6. The splicing display device according to claim 1, characterized in that, Each pair of adjacent enclosures is designated as a first enclosure and a second enclosure. Both the first enclosure and the second enclosure include a main structure. The first enclosure also includes a first eaves structure disposed on the main structure. The first eaves structure is configured to cover part of the edge area of the main structure of the second enclosure. The supporting surface is located on the surface of the first eaves structure facing the display component.
7. The splicing display device according to claim 6, characterized in that, The first housing also includes a second eaves structure disposed on the main structure. Along the thickness direction of the display component, the main structure is located between the first eaves structure and the second eaves structure, and the second eaves structure, the first eaves structure, and the main structure of the first housing define a limiting groove, with a portion of the main structure of the second housing located in the limiting groove.
8. The splicing display device according to claim 6, characterized in that, The second housing also includes a limiting post disposed on the main structure, and the first eaves structure has an avoidance gap, with a portion of the limiting post located in the avoidance gap.
9. The splicing display device according to claim 1, characterized in that, Any two adjacent enclosures can be detachably connected by fasteners.
10. The splicing display device according to any one of claims 1 to 9, characterized in that, The housing includes a cutout portion that extends through the housing along the thickness direction of the display component. The splicing unit further includes: A first magnetic component, comprising a first part and a second part capable of magnetic attraction, wherein the first part is disposed on the display component and the second part is disposed on the housing; A magnetic adsorption sheet is configured to be rotatably connected to the display assembly so that the magnetic adsorption sheet is in one of a first state and a second state. In the first state, the magnetic adsorption sheet is positioned opposite the surface of the display component facing the housing; In the second state, the magnetic adsorption sheet is magnetically attracted to the auxiliary component located on the side of the hollowed-out portion, or the magnetic adsorption sheet is magnetically attracted to the magnetic adsorption sheet in the adjacent splicing unit.
11. The splicing display device according to claim 10, characterized in that, The splicing unit also includes: The mounting component includes a movable part, a fixed part, and a rotating shaft. The movable part is fixedly connected to the display component, and the movable part is rotatably connected to the fixed part via the rotating shaft. The rotating shaft extends along the surface of the display component toward the housing. The magnetic adsorption sheet is fixed to the movable part.
12. The splicing display device according to claim 11, characterized in that, The plurality of splicing units are arranged sequentially in a first direction. The display component includes a first edge and a second edge disposed opposite to each other in the first direction. The mounting members are disposed at positions near the first edge and near the second edge. The rotation axis of the mounting member near the first edge is in the same direction as the extension of the first edge, and the rotation axis of the mounting member near the second edge is in the same direction as the extension of the second edge.
13. The splicing display device according to any one of claims 1 to 9, characterized in that, The splicing unit also includes: A first magnetic component, comprising a first part and a second part capable of magnetic attraction, wherein the first part is disposed on the display component; Mounting base, the mounting base being disposed on the housing and configured to move relative to the housing along the thickness direction of the display component; The second component is fixed to the mounting base.
14. The splicing display device according to claim 13, characterized in that, The housing has a threaded hole, and the mounting base includes a mounting part and a screw part. At least a portion of the screw part is located in the threaded hole, and the mounting part is fixedly connected to one end of the screw part; the second component is fixed on the mounting part.
15. The splicing display device according to any one of claims 1 to 9, characterized in that, The housings of the multiple splicing units form a load-bearing structure. An adjustment component is provided on the load-bearing structure. The adjustment component is configured to connect the load-bearing structure to the mounting base and adjust the installation position of the load-bearing structure on the mounting base.
16. The splicing display device according to claim 15, characterized in that, The adjustment component includes: Multiple connectors, each connector including a first connecting portion and a second connecting portion, the second connecting portion being configured to connect to a mounting base, the first connecting portion having a first guide groove; wherein, a portion of the first guide grooves on the connectors extend along a first direction, and another portion of the first guide grooves on the connectors extend along a second direction, the first direction and the second direction intersecting and both being perpendicular to the thickness direction of the display component; A sliding member corresponding to each of the first guide grooves is slidably disposed in the corresponding first guide groove and fixedly connected to the bearing structure.
17. The splicing display device according to claim 16, characterized in that, The load-bearing structure includes two third edges disposed opposite to each other in the first direction and two fourth edges disposed opposite to each other in the second direction. Each of the third edges and each of the fourth edges is provided with the connector. The guide groove on the connector of the third edge extends along the first direction, and the first guide groove on the connector of the fourth edge extends along the second direction.
18. The splicing display device according to claim 16, characterized in that, The second connecting part is provided with a second guide groove, which extends along the thickness direction of the display component.
19. A splicing display device, comprising a plurality of splicing units spliced together, characterized in that, The splicing unit includes: Display components; A cabinet is disposed on the backlight side of the display component, the cabinet including a cutout portion that penetrates the cabinet along the thickness direction of the display component; A first magnetic component, comprising a first part and a second part capable of magnetic attraction, wherein the first part is disposed on the display component and the second part is disposed on the housing; A magnetic adsorption sheet is configured to be rotatably connected to the display assembly so that the magnetic adsorption sheet is in one of a first state and a second state. In the first state, the magnetic adsorption sheet is positioned opposite the surface of the display component facing the housing; In the second state, the magnetic adsorption sheet is magnetically attracted to the auxiliary component located on the side of the hollowed-out portion, or the magnetic adsorption sheet is magnetically attracted to the magnetic adsorption sheet in the adjacent splicing unit.
20. The splicing display device according to claim 19, characterized in that, The splicing unit also includes: The mounting component includes a movable part, a fixed part, and a rotating shaft. The movable part is fixedly connected to the display component, and the movable part is rotatably connected to the fixed part via the rotating shaft. The rotating shaft extends along the surface of the display component toward the housing. The magnetic adsorption sheet is fixed to the movable part.
21. The splicing display device according to claim 20, characterized in that, The plurality of splicing units are arranged sequentially in a first direction. The display component includes a first edge and a second edge disposed opposite to each other in the first direction. The mounting members are disposed at positions near the first edge and near the second edge. The rotation axis of the mounting member near the first edge is in the same direction as the extension of the first edge, and the rotation axis of the mounting member near the second edge is in the same direction as the extension of the second edge.
22. The splicing display device according to any one of claims 19 to 21, characterized in that, The splicing unit also includes: A first magnetic component, comprising a first part and a second part capable of magnetic attraction, wherein the first part is disposed on the display component; Mounting base, the mounting base being disposed on the housing and configured to move relative to the housing along the thickness direction of the display component; The second component is fixed to the mounting base.
23. The splicing display device according to any one of claims 19 to 21, characterized in that, The housings of the multiple splicing units form a load-bearing structure. An adjustment component is provided on the load-bearing structure. The adjustment component is configured to connect the load-bearing structure to the mounting base and adjust the installation position of the load-bearing structure on the mounting base.
24. The splicing display device according to claim 23, characterized in that, The adjustment component includes: Multiple connectors, each connector including a first connecting portion and a second connecting portion, the second connecting portion being configured to connect to a mounting base, the first connecting portion having a first guide groove; wherein, a portion of the first guide grooves on the connectors extend along a first direction, and another portion of the first guide grooves on the connectors extend along a second direction, the first direction and the second direction intersecting and both being perpendicular to the thickness direction of the display component; A sliding member corresponding to each of the first guide grooves is slidably disposed in the corresponding first guide groove and fixedly connected to the bearing structure.
25. The splicing display device according to claim 24, characterized in that, The load-bearing structure includes two third edges disposed opposite to each other in the first direction and two fourth edges disposed opposite to each other in the second direction. Each of the third edges and each of the fourth edges is provided with the connector. The guide groove on the connector of the third edge extends along the first direction, and the first guide groove on the connector of the fourth edge extends along the second direction.
26. The splicing display device according to claim 24, characterized in that, The second connecting part is provided with a second guide groove, which extends along the thickness direction of the display component.