Multi-directional rotating locking building model display platform
By working together with the rotation locking component and the lifting adjustment component, the building model can be rotated in multiple directions, locked at any angle, and adjusted in height. This solves the problem that existing technologies cannot display the model from all angles, and improves the stability and effect of the display.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- NANJING JINLI CULTURE CO LTD
- Filing Date
- 2025-05-13
- Publication Date
- 2026-06-26
AI Technical Summary
Existing architectural model display platforms cannot achieve multi-directional rotation, arbitrary angle locking, and height adjustment, which prevents viewers from viewing the architectural model from all angles, affecting the display effect and stability.
It adopts a rotary locking component and a lifting adjustment component. The drive motor drives the rotating shaft to rotate, the locking block is embedded in the ratchet groove to achieve mechanical locking, and the hydraulic push rod drives the support plate to rise and fall, realizing multi-directional rotation, arbitrary angle locking and height adjustment.
It enables multi-directional rotation, arbitrary angle locking, and height adjustment of the architectural model, ensuring the stability and accuracy of the display and meeting all-round display needs.
Smart Images

Figure CN224417418U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of display platform technology, and in particular to a multi-directional rotating and locking architectural model display platform. Background Technology
[0002] The multi-directional rotating and locking architectural model display platform is an innovative device that combines mechanical structure with architectural display needs. The platform adopts multi-directional rotation and locking functions, which can flexibly adjust the angle of the model during the display process, ensuring that the audience can appreciate the architectural design from all directions, improving the display effect, and effectively preventing the model from moving accidentally during the display process.
[0003] However, in actual use, the following shortcomings still exist. For example, existing architectural model display platforms cannot realize multi-directional rotation, arbitrary angle locking, and height adjustment functions for the displayed models. The inability to rotate in multiple directions means that the audience can only observe the architectural model from a fixed perspective and cannot view the various facades, details, and internal structure of the building from all angles. For some architectural models with unique shapes or complex spatial layouts, the audience may not be able to fully understand their design concepts and spatial relationships, affecting the display effect and the integrity of information transmission. The lack of arbitrary angle locking function makes it difficult to accurately position and fix the model at a specific angle during the display process, which may cause the model to shake or deviate from the expected display posture, affecting the stability and professionalism of the display.
[0004] Therefore, this utility model proposes a multi-directional rotation locking architectural model display platform to solve the above problems. Utility Model Content
[0005] The purpose of this invention is to address the shortcomings of existing technologies by proposing a multi-directional rotating and locking architectural model display platform.
[0006] To achieve the above objectives, this utility model adopts the following technical solution: a multi-directional rotational locking architectural model display platform, comprising:
[0007] Base plate;
[0008] A rotary locking assembly includes a support frame mounted on a base plate, a drive motor mounted on the support frame, a rotating shaft fixed to the output end of the drive motor, a first support plate fixed to the rotating shaft, the first support plate being rotatably connected to the support frame, a connecting block being rotatably connected to the support frame near the first support plate, a ratchet groove fixed inside the connecting block, a locking block being slidably connected to the first support plate, a telescopic spring being fixed to the locking block, the other end of the telescopic spring being fixed to the rotating shaft, a fixing block being fixed to the first support plate near the locking block, the locking block being slidably connected inside the fixing block, the locking block being disposed on the ratchet groove, and a support seat being fixed to the top of the connecting block.
[0009] A lifting and adjusting assembly includes a hydraulic push rod rotatably connected to a base plate, the output end of the hydraulic push rod being provided with a third support plate, and the support frame being fixed on the third support plate.
[0010] Furthermore, a limiting rod is slidably connected inside the rotating shaft, and the other end of the limiting rod is fixed to the locking block.
[0011] The beneficial effects of adopting the above-mentioned further solution are: the limit rod slides along the inside of the rotating shaft and is rigidly connected to the locking block, ensuring the stability of the movement trajectory of the locking block. When the rotating shaft rotates, the limit rod moves synchronously, pushing the locking block to slide along the fixed block. This structure prevents the locking block from deviating, improves locking accuracy, and enhances mechanical strength, avoiding wear or loosening due to frequent operation, and ensuring the reliability of the rotation and locking process.
[0012] Furthermore, a limiting block is fixed on the card block, and a limiting groove is formed on the side of the fixed block near the limiting block, and the limiting block is slidably connected in the limiting groove.
[0013] The beneficial effects of adopting the above-mentioned further solution are: the limiting block is embedded in the limiting groove, which restricts the movement range of the locking block, so that it can only slide along the preset path. When the locking block moves towards the ratchet groove under the action of the telescopic spring, the limiting block slides smoothly in the limiting groove, avoiding jamming or misalignment, ensuring that the locking block and the ratchet groove are precisely engaged, and improving locking stability.
[0014] Furthermore, a protective cover is fixed to the top of the support base.
[0015] The beneficial effect of adopting the above-mentioned further solution is that the protective cover covers the support base, preventing dust and foreign objects from entering the interior of the building model.
[0016] Furthermore, a second support plate is fixed to the top of the base plate, a connector is fixed to the output end of the hydraulic push rod, a rotating block is rotatably connected to the connector, and the third support plate is rotatably connected to the rotating block.
[0017] The beneficial effects of adopting the above-mentioned further solution are: the hydraulic push rod pushes the connector to rise and fall, which drives the rotating block to move, so that the height of the third support plate is adjusted accordingly. The rotating block, connector, and third support plate are all rotatably connected, realizing independent control of height and rotation, and improving display flexibility.
[0018] Furthermore, a roller is rotatably connected to the rotating block, a limit ring is fixed on the second support plate, the roller is disposed inside the limit ring, and a protective plate is fixed on the second support plate.
[0019] The beneficial effects of adopting the above-mentioned further solution are: the roller rolls along the limiting ring, guiding the movement trajectory of the rotating block, reducing friction, making the lifting and lowering more stable, the limiting ring prevents the roller from derailing, ensuring structural stability, and the protective plate can play a protective role after the building model is lowered and retracted.
[0020] Compared with the prior art, the advantages and positive effects of this utility model are as follows:
[0021] In this invention, the display platform achieves multi-angle display through the coordinated operation of a rotation locking component and a lifting adjustment component. During operation, the drive motor drives the rotating shaft to rotate the first support plate. The locking block, under the action of the telescopic spring, engages with the ratchet groove to achieve mechanical locking, ensuring that the display angle is precisely fixed. The hydraulic push rod of the lifting adjustment component pushes the third support plate to move up and down, driving the entire support frame to rise and fall, changing the display height of the model. The rotation and lifting actions can be performed independently or synchronously. The fixed block guides the linear movement of the locking block to ensure precise engagement with the ratchet groove, realizing the functions of multi-directional rotation, arbitrary angle locking, and height adjustment of the display model, meeting all-round display needs. Attached Figure Description
[0022] Figure 1 This is a structural schematic diagram of a multi-directional rotating locking architectural model display platform according to the present invention;
[0023] Figure 2 This is a schematic diagram of the rotating locking component structure of a multi-directional rotating locking architectural model display platform according to this utility model;
[0024] Figure 3 This is a structural breakdown diagram of the rotating locking component of a multi-directional rotating locking architectural model display platform according to this utility model.
[0025] Figure 4 This is a schematic diagram of the lifting and adjusting component structure of a multi-directional rotating locking architectural model display platform according to this utility model.
[0026] Figure 5 This is a structural breakdown diagram of the lifting and adjusting component of a multi-directional rotating locking architectural model display platform according to this utility model.
[0027] Figure label:
[0028] 1. Base plate;
[0029] 2. Rotary locking assembly; 21. Support frame; 22. Drive motor; 23. Rotating shaft; 24. First support plate; 25. Connecting block; 26. Racket groove; 27. Limiting rod; 28. Locking block; 29. Telescopic spring; 210. Fixing block; 211. Limiting block; 212. Limiting groove; 213. Support base; 214. Protective cover;
[0030] 3. Lifting and adjusting assembly; 31. Second support plate; 32. Hydraulic push rod; 33. Connector; 34. Rotating block; 35. Roller; 36. Limit ring; 37. Third support plate; 38. Protective plate. Detailed Implementation
[0031] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0032] like Figures 1-5 As shown, this embodiment provides a technical solution: a multi-directional rotation-locking architectural model display platform, comprising:
[0033] Base plate 1;
[0034] Rotary locking assembly 2 includes a support frame 21 mounted on a base plate 1, a drive motor 22 mounted on the support frame 21, a rotating shaft 23 fixed to the output end of the drive motor 22, a first support plate 24 fixed to the rotating shaft 23, the first support plate 24 being rotatably connected to the support frame 21, a connecting block 25 being rotatably connected to the support frame 21 near the first support plate 24, a ratchet groove 26 being fixed inside the connecting block 25, a locking block 28 being slidably connected to the first support plate 24, a telescopic spring 29 being fixed to the locking block 28, the other end of the telescopic spring 29 being fixed to the rotating shaft 23, a fixing block 210 being fixed to the first support plate 24 near the locking block 28, the locking block 28 being slidably connected inside the fixing block 210, the locking block 28 being disposed on the ratchet groove 26, and a support seat 213 being fixed to the top of the connecting block 25.
[0035] The lifting and adjusting assembly 3 includes a hydraulic push rod 32 rotatably connected to the base plate 1. A third support plate 37 is provided at the output end of the hydraulic push rod 32. A support frame 21 is fixed to the third support plate 37. During the rotation of the architectural model, the drive motor 22 is turned on, and its output end drives the rotating shaft 23 to rotate. The first support plate 24, fixedly connected to the rotating shaft 23, also performs a circular motion, thereby driving the upper support base 213 and the architectural model to rotate synchronously, displaying the model's appearance from different angles. During this process, the locking block 28 fixed to the first support plate 24 maintains a tendency to move towards the rotating shaft 23 under the action of the telescopic spring 29. When the model rotates to the desired display angle, the drive motor 22 stops operating, and the locking block 28 is embedded into the connecting block 25 under the action of the telescopic spring 29. The ratchet groove 26 completes the mechanical locking, ensuring the precise fixation of the display angle. In terms of height adjustment, the hydraulic push rod 32 in the lifting adjustment component 3 plays a key role. After the hydraulic push rod 32 is activated, its output end extends or shortens, pushing the third support plate 37 to move up and down in a straight line. Since the support frame 21 is fixed on the third support plate 37, it can drive the upper structure of the entire display platform to lift and lower, thereby changing the display height of the model. The rotation and lifting actions can be executed independently to meet the display needs of a single dimension, or they can be performed simultaneously. Furthermore, the fixing block 210 provides a track for the linear movement of the locking block 28, guiding the locking block 28 to accurately embed into the ratchet groove 26, ensuring that the display platform can stably and accurately achieve multi-directional rotation, arbitrary angle locking, and height adjustment functions, fully meeting the display needs.
[0036] The above solutions also have the problem that, when the building model is lowered and retracted, it cannot ensure structural stability and provide protection after the building model is lowered and retracted. Figures 1-3As shown: A limit rod 27 is slidably connected inside the rotating shaft 23. The other end of the limit rod 27 is fixed to the locking block 28. The limit rod 27 slides inside the rotating shaft 23 and is rigidly connected to the locking block 28 to ensure the stability of the movement trajectory of the locking block 28. When the rotating shaft 23 rotates, the limit rod 27 moves synchronously, pushing the locking block 28 to slide along the fixed block 210. This structure prevents the locking block 28 from shifting, improves locking accuracy, and enhances mechanical strength, avoiding wear or loosening due to frequent operation, and ensuring the reliability of the rotation and locking process. A limit block 211 is fixed on the locking block 28, and a limit block 211 is fixed on the fixed block 210 near the limit block 211. A limiting groove 212 is provided on one side, and a limiting block 211 is slidably connected in the limiting groove 212. The limiting block 211 is embedded in the limiting groove 212, which restricts the movement range of the locking block 28, so that it can only slide along the preset path. When the locking block 28 moves towards the ratchet groove 26 under the action of the telescopic spring 29, the limiting block 211 slides smoothly in the limiting groove 212 to avoid jamming or misalignment, ensuring that the locking block 28 and the ratchet groove 26 are precisely engaged, improving locking stability. A protective cover 214 is fixed on the top of the support base 213. The protective cover 214 covers the support base 213 to prevent dust and foreign objects from entering the interior of the building model.
[0037] like Figure 1 as well as Figures 4-5 As shown, a second support plate 31 is fixed to the top of the base plate 1. A connector 33 is fixed to the output end of the hydraulic push rod 32. A rotating block 34 is rotatably connected to the connector 33. A third support plate 37 is rotatably connected to the rotating block 34. The hydraulic push rod 32 pushes the connector 33 to rise and fall, causing the rotating block 34 to move, thus adjusting the height of the third support plate 37 accordingly. The rotating block 34, connector 33, and third support plate 37 are all rotatably connected, enabling independent control of height and rotation, improving display flexibility. A roller 35 is rotatably connected to the rotating block 34. A limit ring 36 is fixed to the second support plate 31. The roller 35 is set inside the limit ring 36. A protective plate 38 is fixed to the second support plate 31. The roller 35 rolls along the limit ring 36, guiding the movement trajectory of the rotating block 34, reducing friction, and making the lifting and lowering more stable. The limit ring 36 prevents the roller 35 from derailing, ensuring structural stability. The protective plate 38 can provide protection after the building model is lowered and retracted.
[0038] Working principle:
[0039] like Figures 1-5As shown, when the model is rotated, the drive motor 22 starts, and its output drives the rotating shaft 23 to rotate. The first support plate 24, which is fixedly connected to the rotating shaft 23, moves in a circular motion, thereby driving the upper support base 213 and the building model to rotate synchronously, achieving a full-range display. The rotating shaft 23 has a slidingly connected limit rod 27, which is rigidly connected to the locking block 28 to ensure the accuracy of the movement trajectory of the locking block 28. When the model rotates to a predetermined angle, the drive motor 22 stops, and the locking block 28 automatically engages with the ratchet groove 26 in the connecting block 25 under the elastic force of the telescopic spring 29, completing the mechanical locking. The sliding of the limit block 211 in the limit groove 212 further ensures the movement accuracy of the locking block 28, preventing offset or jamming. The height adjustment component uses a hydraulic push rod 32 as a power source. After the hydraulic push rod 32 is started, its output end pushes the rotating block 34 through the connector 33, which drives the third support plate 37 to move vertically. Since the support frame 21 is fixed on the third support plate 37, the upper structure of the entire display platform rises and falls accordingly. The rollers 35 installed on the rotating block 34 roll within the limit ring 36, which not only ensures the stability of the lifting process, but also prevents the mechanism from derailing. The protective plate 38 effectively protects the internal mechanism and extends the service life of the equipment. The protective cover 214 on the top of the support base 213 effectively prevents dust from entering, keeps the display environment clean, and ensures that the display platform can stably and accurately achieve multi-directional rotation, arbitrary angle locking, and height adjustment functions, fully meeting the display needs.
[0040] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any other way. Any person skilled in the art may make changes or modifications to the above-disclosed technical content to create equivalent embodiments for application in other fields. However, any simple modifications, equivalent changes, and modifications made to the above embodiments based on the technical essence of the present utility model without departing from the technical solution of the present utility model shall still fall within the protection scope of the technical solution of the present utility model.
Claims
1. A multi-rotational locking architectural model display platform, characterized by, include: Base plate (1); A rotary locking assembly (2) includes a support frame (21) mounted on a base plate (1), a drive motor (22) mounted on the support frame (21), a rotating shaft (23) fixed to the output end of the drive motor (22), a first support plate (24) fixed to the rotating shaft (23), the first support plate (24) being rotatably connected to the support frame (21), and a connecting block (25) rotatably connected to one side of the support frame (21) near the first support plate (24), the connecting block (25) being internally fixed. The first support plate (24) has a ratchet groove (26), a locking block (28) is slidably connected to the first support plate (24), a telescopic spring (29) is fixed on the locking block (28), the other end of the telescopic spring (29) is fixed on the rotating shaft (23), a fixing block (210) is fixed on the side of the first support plate (24) near the locking block (28), the locking block (28) is slidably connected in the fixing block (210), the locking block (28) is set on the ratchet groove (26), and a support seat (213) is fixed on the top of the connecting block (25). The lifting adjustment assembly (3) includes a hydraulic push rod (32) rotatably connected to the base plate (1), and the output end of the hydraulic push rod (32) is provided with a third support plate (37), and the support frame (21) is fixed on the third support plate (37).
2. A multi-rotational locking building model display platform as claimed in claim 1, wherein: A limiting rod (27) is slidably connected inside the rotating shaft (23), and the other end of the limiting rod (27) is fixed on the locking block (28).
3. The multi-directional rotational locking architectural model display platform according to claim 1, characterized in that: A limiting block (211) is fixed on the card block (28), and a limiting groove (212) is provided on the side of the fixed block (210) near the limiting block (211). The limiting block (211) is slidably connected in the limiting groove (212).
4. The multi-directional rotational locking architectural model display platform according to claim 1, characterized in that: A protective cover (214) is fixed to the top of the support base (213).
5. A multi-directional rotational locking architectural model display platform according to claim 1, characterized in that: The top of the base plate (1) is fixed with a second support plate (31), the output end of the hydraulic push rod (32) is fixed with a connector (33), a rotating block (34) is rotatably connected to the connector (33), and the third support plate (37) is rotatably connected to the rotating block (34).
6. The multi-directional rotational locking architectural model display platform according to claim 5, characterized in that: A roller (35) is rotatably connected to the rotating block (34), a limit ring (36) is fixed on the second support plate (31), the roller (35) is set inside the limit ring (36), and a protective plate (38) is fixed on the second support plate (31).