Bevel decorative frame splicing device

The design of the inclined decorative frame splicing device solves the problems of low efficiency, insufficient precision and equipment jamming in the existing technology, realizes efficient and accurate automated splicing of inclined decorative frames, improves production efficiency and precision, and reduces equipment maintenance costs.

CN224335099UActive Publication Date: 2026-06-09HENAN EVERGRANDE SOPHIA HOME FURNISHING CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HENAN EVERGRANDE SOPHIA HOME FURNISHING CO LTD
Filing Date
2025-05-29
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

The existing splicing process for beveled decorative frames is inefficient, lacks precision, is labor-intensive, and the equipment is prone to jamming, making it difficult to achieve efficient, accurate, and stable automated production.

Method used

A sloping decorative frame assembly device was designed, comprising an assembly platform, a hopper assembly, and a feeding mechanism. It adopts a two-way moving track and a pushing module, combined with an adjustment module and a pusher assembly, to achieve automated feeding and precise positioning of the sloping frame, and supports multiple size adaptations.

Benefits of technology

It achieves a reduction of more than 50% in the single splicing cycle, an increase of 3-5 times in daily production capacity, improved precision, reduced equipment maintenance costs, and adaptability to beveled frames of different sizes without modification.

✦ Generated by Eureka AI based on patent content.

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    Figure CN224335099U_ABST
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Abstract

The utility model provides a kind of bevel decoration frame splicing device, including splicing platform, stock bin assembly and feeding mechanism, the edge of splicing platform is equipped with enclosure structure, splicing area is set thereon, and at least two parallel moving tracks are respectively arranged along length direction and width direction, track is embedded in track slot, stock bin assembly is adjacent to splicing area, bottom is equipped with guide exit, for orderly output bevel frame, feeding mechanism is installed in moving track, and bevel frame is pushed to splicing area by the pushing module of synchronous drive, pushing module includes slide base and push plate component, push plate component is connected slide base by torsion spring, can be forwardly inclined after stress and completely immerse in track slot, avoid jamming due to bevel frame block. Adjustment module is set at both ends of stock bin assembly, and the arrangement spacing of the bevel frame of different sizes is adapted. The utility model solves the technical problem that traditional manual splicing efficiency is low, and mechanical device is easy to jam, realizes automatic accurate splicing and efficient production.
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Description

Technical Field

[0001] This utility model relates to the field of decorative frame production technology, and more specifically, to a slanted decorative frame assembly device. Background Technology

[0002] In the field of architectural decoration, beveled decorative frames are widely used in door and window frames, partition walls, and other applications due to their aesthetic appeal and functionality. However, the current splicing process for beveled decorative frames is still mainly manual, which has the following significant drawbacks:

[0003] Inefficient: Workers need to manually align the tilt angles of the four inclined frames and fix them with right-angle plates and screws. Each assembly takes a long time and depends on the operator's experience.

[0004] Insufficient precision: Manual splicing is prone to uneven seams or loose structure due to angular deviations, affecting the overall aesthetics and stability;

[0005] High labor intensity: Long-term repetitive operations can easily cause worker fatigue and reduce production safety;

[0006] Equipment limitations: Existing semi-automatic devices generally suffer from the problem of the pusher mechanism getting stuck during return stroke, especially when the stack height of the inclined frames is high, the pusher assembly cannot reset smoothly, resulting in equipment shutdown or component damage;

[0007] To solve the above problems, there is an urgent need for a sloping decorative frame splicing device that combines high precision, strong stability and wide applicability to achieve automated, precise splicing and efficient production. Utility Model Content

[0008] Based on the above-mentioned technical problems, this utility model proposes a sloping decorative frame assembly device.

[0009] A beveled decorative frame assembly device, comprising:

[0010] The frame assembly platform has a perimeter enclosure structure. The frame assembly platform is provided with a frame assembly area for positioning and splicing. The frame assembly area is provided with at least two parallel moving tracks along the length and width directions, and the moving tracks are set in the track grooves of the frame assembly platform.

[0011] A hopper assembly is arranged adjacent to the frame assembly area and is used to accommodate and orderly output multiple inclined frames. The bottom of the hopper assembly is provided with a guide outlet, the size of which is adapted to the movement of a single inclined frame.

[0012] The feeding mechanism is installed in the moving track and is configured to push the inclined frame output by the hopper component along a preset path to the splicing area. The inclined frames are stacked alternately in opposite positions in the hopper component to achieve misalignment matching during splicing.

[0013] Preferably, the moving track is divided into at least two groups, each group including several parallel track units. The feeding mechanism is provided with a synchronously driven pushing module for each group of track units. The pushing module includes a slide that can move along the track and a push plate assembly disposed on the slide. The push plate assembly is configured to apply a pushing force to the inclined frame during the movement of the slide to achieve precise positioning.

[0014] Preferably, the push plate assembly is a push plate, the lower end of which is connected to the slide block by a torsion spring, and the other end extends outward from the track groove. The push plate assembly is normally vertical and cannot tilt backward. When the push plate assembly is subjected to force on the rear side, it can tilt forward and completely submerge into the track groove to ensure that the push plate assembly can be smoothly reset.

[0015] Preferably, the hopper assembly further includes an adjustment module, which is disposed at both ends of the hopper assembly and is used to adjust the arrangement spacing of the inclined frames in the hopper to adapt to the matching requirements of inclined frames of different sizes and the splicing area.

[0016] Beneficial effects:

[0017] 1. Efficiency Improvement: Through automated material feeding and precise positioning, the single splicing cycle is shortened by more than 50% compared to manual operation, and the daily production capacity can reach 3-5 times that of traditional processes;

[0018] 2. Versatility and Expansion: The adjustment module supports size changes within a range of ±15%, and can be compatible with various specifications of beveled frames without additional modifications, reducing production line maintenance costs;

[0019] 3. Precision assurance: The coordinated control of the bidirectional moving track and the material pushing module ensures small deviations in splicing angles. Attached Figure Description

[0020] Figure 1 A schematic diagram of the structure of this utility model is shown. Figure 1 ;

[0021] Figure 2 A schematic diagram of the structure of this utility model is shown. Figure 2 ;

[0022] Figure 3 A schematic diagram of the hopper assembly is shown;

[0023] Figure 4 A structural schematic diagram of the inclined frame and push plate assembly is shown;

[0024] Figure 5 A schematic diagram of the pusher assembly is shown. Detailed Implementation

[0025] To better understand the above-mentioned objectives, features, and advantages of this utility model, the present utility model will be further described in detail below with reference to the accompanying drawings and specific embodiments. It should be noted that, unless otherwise specified, the embodiments and features described in these embodiments can be combined with each other.

[0026] like Figures 1-5 The sloping decorative frame assembly device shown includes an assembly platform 10, a hopper assembly 20 and a feeding mechanism 40 disposed on the assembly platform 10.

[0027] Frame assembly platform 10: The edge of the frame assembly platform 10 is equipped with a retaining structure to prevent the inclined frame 30 from shifting during the assembly process;

[0028] At least two parallel moving tracks 11 are arranged along the length and width of the frame area to form an "XY" axial positioning network. The tracks are embedded in the track grooves 12 to protect the transmission components and reserve space for the push plate assembly 41b to avoid it.

[0029] The moving track 11 is divided into two groups, each group containing several parallel track units 11a and 11b. The four-quadrant precise positioning of the inclined frame 30 is achieved through the synchronously driven pusher module 41.

[0030] Container Component 20:

[0031] The hopper assembly 20 is set adjacent to the frame assembly area and has a guide outlet 21 at the bottom. Its size is adapted to the movement of a single inclined frame 30, and it is lowered one by one by gravity or pneumatic assistance.

[0032] The inclined frames 30 are stacked alternately in the facing positions to ensure that the tilting directions of adjacent inclined frames 30 are opposite to each other, so as to meet the misalignment matching requirements during splicing.

[0033] The adjustment module 22 is located at both ends of the hopper. The spacing is adjusted by a screw or hydraulic cylinder, supporting size changes within a range of ±15%. It can be compatible with various specifications of inclined frame 30 without replacing the entire device.

[0034] Feeding mechanism 40:

[0035] The pushing module 41 includes a slide 41a and a push plate assembly 41b. The push plate assembly 41b is connected to the slide 41a by a torsion spring and is normally kept in a vertical position, applying a constant pushing force.

[0036] When the push plate assembly 41b is blocked by the inclined frame 30 during the return stroke, the rear end under force tilts forward and is completely submerged in the track groove 12, eliminating physical interference and ensuring that the slide 41a returns to its original position smoothly.

[0037] Example 1

[0038] In this embodiment, the upper end of the slide block 41a is provided with an opening slot that opens to the front. The lower end of the push plate assembly 41b is hinged to the lower rear side of the opening slot by a torsion spring. Under normal conditions, the push plate assembly 41b remains vertical under the action of the torsion spring and the obstruction of the rear wall of the opening slot. When there is an obstruction on the rear side of the push plate assembly 41b, it can tilt to the front.

[0039] The specific workflow is as follows:

[0040] Initialization phase: The inclined frames 30 in the hopper assembly 20 are stacked in a preset order, and the adjustment module 22 adjusts the hopper spacing according to the current workpiece size;

[0041] Material feeding stage: The inclined frame 30 enters the moving track 11 sequentially through the guide outlet 21, and is pushed to the designated position in the frame assembly area by the push plate assembly 41b of the push module 41;

[0042] During the splicing stage: the two sets of pusher modules 41 move alternately to precisely position the opposite inclined frame 30 at the tilt angle, thus completing the splicing of the four frames;

[0043] Reset phase: If the push plate assembly 41b encounters the inclined frame 30 during the return stroke, it will tilt forward to actively avoid it, ensuring seamless connection of subsequent cycles.

[0044] Example 2

[0045] An auxiliary fixing device is added based on Embodiment 1:

[0046] Existing and integrated lifting gripping arms or programmable robotic arms can be used to perform angle calibration and screw tightening after the inclined frame 30 is spliced.

[0047] The above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Various modifications and variations can be made to this utility model by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model.

Claims

1. A bevel decoration frame splicing device, characterized by, The application relates to a frame splicing platform (10) which is provided with a surrounding structure at the edge, a frame splicing area for positioning splicing is arranged on the frame splicing platform (10), at least two parallel moving tracks (11) are arranged on the frame splicing platform (10) along the length direction and the width direction respectively, and the moving tracks (11) are arranged in track grooves (12) of the frame splicing platform (10). A stock bin assembly (20) is arranged adjacent to the frame splicing area and is used for accommodating and orderly outputting a plurality of inclined frames (30), a guide outlet (21) is arranged at the bottom of the stock bin assembly (20), and the size of the guide outlet (21) is matched with the movement of a single inclined frame (30). A feeding mechanism (40) is arranged in the moving track (11) and is configured to push the inclined frame (30) output by the stock bin assembly (20) along a preset path to the frame splicing area, wherein the inclined frames (30) are alternately arranged in the stock bin assembly (20) in a directly opposite position to realize the staggered matching during splicing. The moving track (11) is divided into at least two groups, each group comprises a plurality of parallel track units (11a, 11b), the feeding mechanism (40) is provided with a synchronously driven pushing module (41) corresponding to each group of track units (11a, 11b), the pushing module (41) comprises a slide (41a) which can move along the track and a pushing plate assembly (41b) arranged on the slide (41a), and the pushing plate assembly (41b) is configured to apply a pushing force to the inclined frame (30) during the movement of the slide (41a) to realize accurate positioning.

2. The bevel trim frame splicing apparatus according to claim 1, wherein The pushing plate assembly (41b) is a pushing plate, the lower end of the pushing plate assembly (41b) is connected with the slide (41a) through a torsion spring, the other end of the pushing plate assembly (41b) extends outwards from the track groove (12), the pushing plate assembly (41b) is in a normal vertical state and cannot be inclined backwards, and the pushing plate assembly (41b) can be inclined forwards and completely immersed in the track groove (12) after being subjected to force at the back side, so that the pushing plate assembly (41b) can be smoothly reset.

3. The bevel trim frame splicing apparatus according to claim 2, wherein The stock bin assembly (20) further comprises an adjusting module (22) arranged at both ends of the stock bin assembly (20) and used for adjusting the arrangement spacing of the inclined frames (30) in the stock bin to adapt to the matching requirements of inclined frames (30) of different sizes and the frame splicing area.

4. The bevel trim frame splicing apparatus of claim 1, wherein, ​