Assembled landscape simulation tree
By designing a foldable or detachable landscape simulation tree skeleton structure and using fasteners, hinges, and other connectors, quick folding and assembly can be achieved, solving the problems of large land area, high cost, and inconvenient storage for transporting landscape simulation trees, and improving the convenience and flexibility of use.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GUANGDONG SONGTAO LANDSCAPE GARDENING CO LTD
- Filing Date
- 2025-07-25
- Publication Date
- 2026-06-12
AI Technical Summary
The existing metal frames of artificial landscape trees are fixed structures, which result in large land occupation, high cost and inconvenient storage during transportation.
Designed as a foldable or detachable structure, it utilizes fasteners, hinges, and other connectors to achieve quick folding and assembly. The fast folding and assembly are achieved through the cooperation of components such as lead screws, knobs, lifting plates, rotating plates, and mounting plates.
It significantly reduces the space occupied during transportation and storage, lowers costs, improves ease of use and flexibility, and facilitates placement and storage.
Smart Images

Figure CN224344362U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of artificial tree technology, and in particular to assembled landscape artificial trees. Background Technology
[0002] Artificial trees are landscape decoration products designed to mimic the form of natural trees. They are typically made of polymer materials (such as PVC, PE, and resin), fiberglass, and metal frames. Through simulation techniques, they recreate the details of tree trunk texture, branch and leaf shape, and color, achieving a high degree of resemblance to real trees. They can even simulate the unique characteristics of different tree species (such as pine, banyan, and cherry trees).
[0003] The existing metal frames of artificial landscape trees are mostly fixed structures, which are inconvenient to fold up, resulting in large space occupation and high cost during transportation, and inconvenient storage when not in use. The improved design makes the frame a foldable or detachable structure, which can be quickly folded and assembled through fasteners, hinges and other connectors. This not only greatly reduces the transportation and storage volume and lowers costs, but also improves the flexibility of use, making it easy to adjust the placement and storage according to the needs of the scene.
[0004] Therefore, given that the existing metal frames of landscape artificial trees are fixed structures, which occupy a large area during transportation, are costly, and are inconvenient to store, there is an urgent need to design a new type of modular landscape artificial tree that can be folded or detached, and can be quickly assembled and folded using buckles, hinges, etc. This would reduce the transportation and storage volume, lower costs, and improve the flexibility of use, making it easier to adjust the placement and storage. Utility Model Content
[0005] To overcome the limitations of existing landscape artificial tree metal frames, which are fixed structures, require large transport space, are costly, and are inconvenient to store, an improved foldable or detachable design was developed. Utilizing snap-fit mechanisms and hinges, the frames can be quickly assembled and folded, reducing transport and storage volume, lowering costs, and enhancing flexibility in use, making it easier to adjust placement and storage.
[0006] The technical solution of this utility model is as follows: an assembled landscape simulation tree, including a support cylinder and a storage groove opened at the outer end of the support cylinder. Several storage grooves are provided. A lead screw is rotatably connected inside the support cylinder, and a knob is connected to the bottom of the lead screw. The knob is connected to the lead screw and rotatably connected to the support cylinder. A fixing ring is connected to the upper outer end of the support cylinder, and multiple mounting plates are rotatably connected to the upper outer end of the fixing ring. A lifting groove is opened inside the support cylinder, and a lifting plate is slidably connected to the lower outer end of the support cylinder. The lifting plate is threadedly connected to the lead screw and slidably connected to the lifting groove. Multiple rotating grooves are opened at the outer end of the lifting plate, and rotating plates are rotatably connected inside the rotating grooves. The rotating plates are rotatably connected to the mounting plates. A threaded wire is connected to the lower outer end of the support cylinder, and a threaded sleeve is connected to the top of the support cylinder. Rotating the knob drives the lead screw to drive the lifting plate to slide on the lifting groove. The movement of the lifting plate drives the rotating plate to push the mounting plate to rotate on the fixing ring, so that the mounting plate passes through the storage groove and unfolds.
[0007] Preferably, quick folding and assembly are achieved by setting components such as a lead screw, knob, lifting plate, rotating plate, mounting plate, and storage slot, reducing the space occupied. Turning the knob drives the lead screw to rotate, causing the lifting plate to slide in the lifting slot. The movement of the lifting plate causes the rotating plate to push the mounting plate to rotate on the fixed ring, allowing the mounting plate to unfold through the storage slot. When folding up, turning the knob in the opposite direction allows the mounting plate to be stored in the storage slot. Folding and assembly can be completed without complicated operations, greatly reducing the space occupied during transportation and storage and improving the convenience of use.
[0008] Preferably, a support plate is movably connected to the bottom of the support cylinder. The support plate is conical in shape, and multiple mounting holes are provided on the top of the mounting plate.
[0009] Preferably, the mounting plate has a movable groove inside, and a threaded rod is rotatably connected inside the movable groove.
[0010] Preferably, the threaded rod has an internal threaded connection with a clamping plate, which is threadedly connected to the threaded rod and slidably connected to the movable groove.
[0011] Preferably, a knob is connected to the end of the threaded rod away from the retaining ring, and the knob is rotatably connected to the mounting plate.
[0012] Preferably, the mounting hole is inserted into the external simulated leaf, and the threaded rod is rotated by turning the knob.
[0013] Preferably, the rotation of the threaded rod drives the clamping plate to slide within the movable groove, and the clamping plate slides within the movable groove and approaches the mounting hole.
[0014] The beneficial effects of this utility model are:
[0015] 1. Components such as lead screws, knobs, lifting plates, rotating plates, mounting plates, and storage slots allow for quick folding and assembly, significantly reducing space occupation. Turning the knob rotates the lead screw, causing the lifting plate to slide, which in turn causes the rotating plate to push the mounting plate open. Reverse rotation allows the mounting plate to be stored in the storage slot. The operation is simple, greatly shortening the folding and assembly time and improving convenience. The reduced volume after folding lowers transportation and storage costs. It has obvious advantages in bulk transportation and idle storage, and can also flexibly adapt to different scenarios, enhancing practicality. Attached Figure Description
[0016] Figure 1 The diagram shown is a schematic representation of the assembled landscape simulation tree structure of this utility model.
[0017] Figure 2 The diagram shown is a bottom view of the assembled landscape simulation tree structure of this utility model.
[0018] Figure 3 The diagram shown is a three-dimensional cross-sectional view of the assembled landscape simulation tree mounting plate of this utility model.
[0019] Figure 4 The diagram shown is a cross-sectional view of the assembled landscape simulation tree structure of this utility model.
[0020] Figure 5 This invention showcases an assembled landscape simulation tree. Figure 3 Enlarged structural diagram of point A in the middle.
[0021] Explanation of reference numerals in the attached drawings: 1. Support cylinder; 21. Storage groove; 22. Lead screw; 23. Knob; 24. Fixing ring; 25. Mounting plate; 26. Lifting groove; 27. Lifting plate; 28. Rotating groove; 29. Rotating plate; 210. Threaded wire; 211. Threaded sleeve; 31. Support plate; 32. Mounting hole; 33. Movable groove; 34. Threaded rod; 35. Clamping plate; 36. Knob. Detailed Implementation
[0022] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0023] Please see Figures 1-5This utility model provides an embodiment of an assembled landscape simulation tree, including a support cylinder 1 and a storage groove 21 formed at the outer end of the support cylinder 1. The storage groove 21 has several openings. A lead screw 22 is rotatably connected inside the support cylinder 1. A knob 23 is connected to the bottom of the lead screw 22 and is connected to the lead screw 22. The knob 23 is rotatably connected to the support cylinder 1. A fixing ring 24 is connected to the upper outer end of the support cylinder 1. Multiple mounting plates 25 are rotatably connected to the upper outer end of the fixing ring 24. A lifting groove 26 is formed inside the support cylinder 1. A lifting plate 27 is slidably connected to the lower outer end of the support cylinder 1. The lifting plate 27 is threadedly connected to the lead screw 22 and slidably connected to the lifting groove 26. Multiple rotating grooves 28 are formed at the outer end of the lifting plate 27. A rotating plate 29 is rotatably connected inside the rotating groove 28 and is rotatably connected to the mounting plate 25. A threaded wire 210 is connected to the lower outer end of the support cylinder 1. The top of the support cylinder 1 is connected to a threaded sleeve 211. Rotating the knob 23 drives the lead screw 22 to slide the lifting plate 27 on the lifting groove 26. The movement of the lifting plate 27 drives the rotating plate 29 to push the mounting plate 25 to rotate on the fixing ring 24, so that the mounting plate 25 passes through the storage groove 21 and unfolds. By setting up components such as the lead screw 22, knob 23, lifting plate 27, rotating plate 29, mounting plate 25 and storage groove 21, quick folding and assembly can be achieved, reducing the space occupied. Rotating the knob 23 drives the lead screw 22 to rotate, which drives the lifting plate 27 to slide in the lifting groove 26. The movement of the lifting plate 27 causes the rotating plate 29 to push the mounting plate 25 to rotate on the fixing ring 24, so that the mounting plate 25 passes through the storage groove 21 and unfolds. When folding up, rotating the knob 23 in the opposite direction allows the mounting plate 25 to be stored in the storage groove 21. Folding and assembly can be completed without complicated operations, which greatly reduces the space occupied during transportation and storage and improves the convenience of use.
[0024] Please see Figures 1-5 In this embodiment, a support plate 31 is movably connected to the bottom of the support cylinder 1. The support plate 31 is conical. Multiple mounting holes 32 are provided on the top of the mounting plate 25. A movable groove 33 is provided inside the mounting plate 25. A threaded rod 34 is rotatably connected inside the movable groove 33. A clamping plate 35 is threadedly connected inside the threaded rod 34. The clamping plate 35 is threadedly connected to the threaded rod 34 and slidably connected to the movable groove 33. The conical shape of the support plate 31 can increase the contact area with the ground, improve the stability of the overall device, and prevent the artificial tree from tipping over. The mounting holes 32 provide convenient insertion positions for external artificial leaves, making it easy to quickly install leaves. The movable groove 33 provides movement space for the threaded rod 34 and the clamping plate 35. The threaded engagement between the threaded rod 34 and the clamping plate 35 allows for precise control of the movement of the clamping plate 35 through the rotation of the threaded rod 34, ensuring that the clamping plate 35 can stably fix the leaves inserted into the mounting holes 32.
[0025] Please see Figures 2-5In this embodiment, a knob 36 is connected to the end of the threaded rod 34 away from the fixing ring 24. The knob 36 is rotatably connected to the mounting plate 25. The mounting hole 32 is inserted into the external simulated leaf. Rotating the knob 36 causes the threaded rod 34 to rotate. The rotation of the threaded rod 34 drives the clamping plate 35 to slide in the movable groove 33. The clamping plate 35 slides in the movable groove 33 and approaches the mounting hole 32. By rotating the knob 36 to drive the threaded rod 34 to rotate, the clamping plate 35 slides in the movable groove 33 and approaches the mounting hole 32. This can quickly clamp and fix the simulated leaf inserted in the mounting hole 32, preventing the leaf from loosening and falling off, ensuring the overall shape of the simulated tree is beautiful and stable. It also facilitates the subsequent disassembly and replacement of the leaf, improving the flexibility of use.
[0026] During operation, firstly, the support plate 31 is installed at the bottom of the support cylinder 1. Its conical structure increases the contact area with the ground, providing stable support for the whole structure. Next, the main body unfolds by rotating the knob 23 at the bottom of the support cylinder 1. The knob 23 drives the internal screw 22 to rotate, causing the lifting plate 27 to slide in the lifting groove 26. When the lifting plate 27 moves, the rotating plate 29 in the rotating groove 28 at its outer end pushes the mounting plate 25. The mounting plate 25 rotates on the fixing ring 24 and unfolds through the storage groove 21 at the outer end of the support cylinder 1, completing the unfolding of the main structure. Then, the artificial leaves are installed by inserting the external artificial leaves into the mounting holes 32 at the top of the mounting plate 25. The knob 36 on the mounting plate 25 is rotated, and the knob 36 drives the threaded rod 3 4. Rotate within the movable groove 33 to allow the clamping plate 35, which is threadedly connected to the threaded rod 34, to slide within the movable groove 33 and approach the mounting hole 32, thereby clamping and fixing the leaves to prevent them from loosening and falling off. The threaded connection between the threaded wire 210 and the threaded sleeve 211 allows for the assembly of multiple devices, increasing the height of the simulated tree and improving flexibility. When it is necessary to retract, turn the knob 36 in the opposite direction to loosen the clamping plate 35, remove the leaves, and then turn the knob 23 in the opposite direction. The lead screw 22 drives the lifting plate 27 to slide in the opposite direction, and the rotating plate 29 pulls the mounting plate 25 back and stores it in the storage groove 21, reducing the overall volume and facilitating transportation and storage. The threaded wire 210 at the outer end of the support cylinder 1 and the threaded sleeve 211 at the top can be additionally connected or extended as needed to improve the flexibility of use.
[0027] Through the above steps, by setting up components such as lead screw 22, knob 23, lifting plate 27, rotating plate 29, mounting plate 25, and storage slot 21 to work together, rapid folding and assembly can be achieved, significantly reducing the space occupied. When the knob 23 is turned, the lead screw 22 rotates accordingly, causing the lifting plate 27 to slide, which in turn causes the rotating plate 29 to push the mounting plate 25 to unfold. When the knob 23 is turned in the opposite direction, the mounting plate 25 can be stored in the storage slot 21. The whole operation is simple and convenient, greatly shortening the folding and assembly time. The overall volume is significantly reduced after folding, effectively reducing transportation and storage costs. It has outstanding advantages in batch transportation and idle storage. At the same time, it can flexibly adapt to different scenarios, enhancing the practicality of use. It solves the problem that the existing landscape simulation tree metal frame is a fixed structure, which has a large transportation footprint, high cost, and inconvenient storage. It is improved to be foldable or detachable, and quick folding and assembly can be achieved with buckles, hinges, etc., which can reduce the transportation and storage volume, reduce costs, and improve the flexibility of use, making it convenient to adjust the placement and storage.
Claims
1. An assembled landscape simulation tree, comprising a support tube (1); characterized in that: It also includes a storage slot (21) at the outer end of the support cylinder (1), with several storage slots (21). A lead screw (22) is rotatably connected inside the support cylinder (1). A knob (23) is connected to the bottom of the lead screw (22), and the knob (23) is connected to the lead screw (22) and rotatably connected to the support cylinder (1). A fixing ring (24) is connected to the upper outer end of the support cylinder (1), and multiple mounting plates (25) are rotatably connected to the upper outer end of the fixing ring (24). A lifting groove (26) is provided inside the support cylinder (1), and a lifting plate (27) is slidably connected to the lower outer end of the support cylinder (1). The lifting plate (27) is threadedly connected to the lead screw (22). The lowering plate (27) is slidably connected to the lifting groove (26). Multiple rotating grooves (28) are opened at the outer end of the lifting plate (27). A rotating plate (29) is rotatably connected inside the rotating groove (28). The rotating plate (29) is rotatably connected to the mounting plate (25). A threaded wire (210) is connected to the lower side of the outer end of the support cylinder (1). A threaded sleeve (211) is connected to the top of the support cylinder (1). The knob (23) rotates and drives the screw (22) to drive the lifting plate (27) to slide on the lifting groove (26). The movement of the lifting plate (27) drives the rotating plate (29) to push the mounting plate (25) to rotate on the fixing ring (24), so that the mounting plate (25) passes through the storage groove (21) and unfolds.
2. The assembled landscape simulation tree according to claim 1, characterized in that: The bottom of the support cylinder (1) is movably connected to a support plate (31), which is conical in shape, and the top of the mounting plate (25) is provided with multiple mounting holes (32).
3. The assembled landscape simulation tree according to claim 2, characterized in that: The mounting plate (25) has a movable groove (33) inside, and a threaded rod (34) is rotatably connected inside the movable groove (33).
4. The assembled landscape simulation tree according to claim 3, characterized in that: The threaded rod (34) has an internal threaded connection with a clamping plate (35), which is threaded to the threaded rod (34) and slidably connected to the movable groove (33).
5. The assembled landscape simulation tree according to claim 4, characterized in that: A knob (36) is connected to the end of the threaded rod (34) away from the fixed ring (24), and the knob (36) is rotatably connected to the mounting plate (25).
6. The assembled landscape simulation tree according to claim 5, characterized in that: The mounting hole (32) is inserted into the external simulated leaf, and the knob (36) is turned to rotate the threaded rod (34).
7. The assembled landscape simulation tree according to claim 6, characterized in that: The rotation of the threaded rod (34) drives the clamp (35) to slide in the movable groove (33), and the clamp (35) slides in the movable groove (33) and approaches the mounting hole (32).