A type of slope tower-style farming structure

The design of the ring-shaped double-layer insulated roof and the supporting drive structure solves the problem of debris accumulation on the roof affecting sunlight, enabling convenient cleaning and healthy plant growth, and improving the efficiency and resource utilization efficiency of the sloping tower planting and breeding structure.

CN224439830UActive Publication Date: 2026-07-03高松 +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
高松
Filing Date
2025-08-07
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

In existing sloping tower-style planting and breeding structures, the accumulation of debris on the top of the insulated shed affects sunlight exposure, leading to poor plant growth. Furthermore, cleaning is inconvenient and makes it impossible to achieve automated irrigation and resource recycling.

Method used

Design a ring-shaped double-layer insulated roof, equipped with a support drive structure and isolation rods. The roof is driven by a motor to rotate in a circular manner, which is convenient for cleaning. The support drive structure includes a rotating roller and a limiting roller, and the isolation rods are used to separate the upper and lower layers to avoid friction.

Benefits of technology

It enables convenient cleaning of the insulated greenhouse roof, ensures effective sunlight exposure, extends service life, promotes healthy plant growth, and simplifies the cleaning process.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224439830U_ABST
    Figure CN224439830U_ABST
Patent Text Reader

Abstract

This utility model discloses a sloping tower-type planting and breeding structure, relating to the field of planting and breeding technology. It includes a breeding house, a planting shed fixed to the top of the breeding house, a planting trough fixed to the top of the breeding house and located inside the planting shed, and an insulated roof covering the top of the planting shed. The insulated roof has a ring-shaped double-layer structure, with its top and bottom located at the upper and lower ends of the planting shed, respectively. A support and drive structure is installed inside the planting shed. This structure supports the insulated roof to conform to the curvature of the planting shed's top and also drives the insulated roof to rotate cyclically. This utility model, through the double-layered insulated roof and the support and drive structure, facilitates cleaning of the upper layer of the insulated roof, ensures effective sunlight penetration, and eliminates the need for disassembly and reassembly of the entire insulated roof, making cleaning convenient and quick, thus promoting the healthy growth of the plants inside.
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Description

Technical Field

[0001] This utility model relates to the field of planting and breeding technology, and in particular to a slope tower-type planting and breeding structure. Background Technology

[0002] Currently, the costs of planting and raising livestock in rural areas are increasing, with single-source production, low efficiency, and non-recyclable resources, leading to environmental pollution and high costs of labor and materials. This results in extremely low returns, significantly reducing farmers' enthusiasm for farming and leading to widespread land abandonment. While existing technologies have incorporated facilities such as greenhouses for improvement, the greenhouse ecosystem is too independent, unable to effectively utilize other systems, increasing costs with minimal benefits. Furthermore, it cannot be integrated with other equipment or structures, nor can it achieve automated irrigation.

[0003] To address the aforementioned issues, patent document CN221128110U discloses a circulating ladder / slope tower-type aquaculture structure, comprising a planting trough tower assembly, a circulating pipeline, an internal aquaculture space, and an underground aquaculture pond, forming a circulating system. The inlet end of the water supply pipe is located inside the aquaculture pond, and the outlet end is located at the top of the planting trough on the tower. Water filtered and overflowing from the planting trough flows through a permeable pipe inside the planting trough into the aquaculture pond for repeated recycling. This aquaculture structure technology requires minimal investment, has a short construction period, can be used long-term, and can be applied in wastelands, mountains, and deserts. It can also be utilized in the renovation of farmhouses.

[0004] Based on the above research and combined with existing technologies, it was found that existing sloping tower-type planting and breeding structures have heat-insulating sheds installed on the top of the planting area to improve planting productivity. The heat-insulating sheds mainly rely on sunlight to form a temperature accumulation inside, which achieves the heat-insulating effect. However, the top of the heat-insulating shed is not easy to clean. If a lot of debris or dust accumulates on the top of the heat-insulating shed during long-term use, it will affect the sunlight exposure. In severe cases, it will lead to insufficient sunlight for the plants inside, resulting in reduced yield and hindering the smooth growth of the plants. Therefore, a sloping tower-type planting and breeding structure is needed. Utility Model Content

[0005] The purpose of this application is to provide a slope-tower type farming structure to solve the problems mentioned in the background art.

[0006] To achieve the above objectives, this application provides the following technical solution: a slope tower-type breeding and farming structure, including a breeding house, a planting shed fixed to the top of the breeding house, a planting trough fixed to the top of the breeding house and located inside the planting shed, and an insulated roof covering the top of the planting shed;

[0007] The roof of the insulated shed has a ring-shaped double-layer structure, with the top and bottom of the roof located at the top of the upper end and the bottom end of the planting shed, respectively.

[0008] The planting shed is equipped with a support and drive structure, which is used to support the roof of the insulated shed so that it fits the curvature of the top of the planting shed. The support and drive structure is also used to drive the roof of the insulated shed to rotate in a cycle.

[0009] Preferably, the support drive structure includes a rotating roller and a limiting roller. Two rotating rollers are provided and are rotatably connected to the top of the upper end and the top of the lower end of the planting shed, respectively. The heat-insulating shed roof is fitted between the two rotating rollers.

[0010] Multiple limiting rollers are provided and rotatably connected inside the planting shed, and all the limiting rollers are in rolling contact with the inner surface of the heat-insulating shed roof.

[0011] Preferably, the support drive structure also includes a drive motor, which is fixed on the planting shed, and the output shaft of the drive motor is connected to the rotating roller at the lower end of the planting shed.

[0012] Preferably, the support drive structure also includes isolation rods, which are fixed inside the planting shed and are arranged parallel to the limiting rollers. Multiple isolation rods are also provided and located inside the roof of the insulation shed. The surfaces of the multiple isolation rods are all smooth surfaces and slide in contact with the inner surface of the roof of the insulation shed.

[0013] Preferably, a drainage ditch is fixed at the bottom of the planting shed, the outlet of the drainage ditch is connected to a sewage pipe, and a grating cover is provided on the top of the drainage ditch.

[0014] Preferably, the lower end of the planting shed has an entrance / exit on one side, with an openable door at the entrance / exit, and ventilation windows are installed on both sides of the planting shed.

[0015] In summary, the technical effects and advantages of this utility model are as follows:

[0016] 1. In this utility model, by setting up a double-layer insulated roof and a support drive structure, when it is necessary to clean the insulated roof, the support drive structure is used to drive the insulated roof to rotate in a cycle, so that the upper layer of the insulated roof rotates towards the lower end of the planting shed. During this process, the staff only needs to stand at the lower end of the planting shed and continuously clean the surface of the insulated roof that they pass over to complete the cleaning work of the upper layer of the insulated roof, ensuring the sunlight exposure effect, and there is no need to disassemble or install the entire insulated roof. The cleaning is convenient and quick, which is more conducive to the healthy growth of the plants inside.

[0017] 2. In this utility model, by setting up the isolation rod, an isolation can be formed between the upper and lower layers of the insulated roof, thereby separating the upper and lower layers of the insulated roof and avoiding large friction generated inside the insulated roof during the cyclic rotation process, thus extending the service life of the insulated roof. Attached Figure Description

[0018] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0019] Figure 1 This is a schematic diagram of the three-dimensional structure in this embodiment;

[0020] Figure 2 This is a schematic cross-sectional view of the structure in this embodiment;

[0021] Figure 3 for Figure 2 Enlarged view of the structure at point A in the middle;

[0022] Figure 4 for Figure 2 Enlarged view of the structure at point B in the middle.

[0023] In the picture: 1. Breeding house; 2. Planting shed; 21. Entrance and exit; 22. Ventilation window; 3. Insulated shed roof; 4. Planting trough; 5. Rotating roller; 6. Limiting roller; 7. Drive motor; 8. Isolation bar; 9. Drainage ditch; 91. Fence cover. Detailed Implementation

[0024] 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.

[0025] Example: Reference Figures 1-4 The above-described slope tower-type farming structure includes a farming house 1, a planting shed 2 fixed to the top of the farming house 1, a planting trough 4 fixed to the top of the farming house 1 and located inside the planting shed 2, and an insulated roof 3 covering the top of the planting shed 2. The insulated roof 3 is made of an insulated film commonly used in the prior art and applicable to this embodiment.

[0026] The insulated roof 3 has a ring-shaped double-layer structure, with the top and bottom of the insulated roof 3 located at the top of the upper end and the top of the lower end of the planting shed 2, respectively.

[0027] The planting shed 2 is equipped with a support and drive structure, which is used to support the insulated shed roof 3 so that it fits the top curvature of the planting shed 2. The support and drive structure is also used to drive the insulated shed roof 3 to rotate cyclically.

[0028] Based on the above structure, when it is necessary to clean the roof of the insulated greenhouse 3, the roof of the insulated greenhouse 3 can be rotated in a cycle by using the support drive structure, so that the upper layer of the roof of the insulated greenhouse 3 rotates towards the lower end of the planting shed 2 (the lower layer rotates upward). During this process, the staff only needs to stand at the lower end of the planting shed 2 and continuously clean the surface of the roof of the insulated greenhouse 3 that they pass over, so as to complete the cleaning of the upper layer of the roof of the insulated greenhouse 3 (which becomes the new lower layer after rotation), ensuring the sunlight exposure effect. Moreover, there is no need to disassemble or install the entire roof of the insulated greenhouse 3, making the cleaning convenient and quick, which is more conducive to the healthy growth of the plants inside.

[0029] Furthermore, the support drive structure includes a rotating roller 5, a limiting roller 6, and a drive motor 7. Two rotating rollers 5 are provided and are respectively rotatably connected to the top of the upper end and the top of the lower end of the planting shed 2. The heat preservation shed roof 3 is fitted between the two rotating rollers 5.

[0030] Multiple limiting rollers 6 are provided and rotatably connected inside the planting shed 2, and all the multiple limiting rollers 6 are in rolling contact with the inner heat-insulating shed roof 3 surface;

[0031] The drive motor 7 is fixed on the planting shed 2, and the output shaft of the drive motor 7 is connected to the rotating roller 5 at the lower end of the planting shed 2.

[0032] With the setting of rotating roller 5, limiting roller 6 and drive motor 7, rotating roller 5 and limiting roller 6 support the roof of the insulation shed 3 under normal conditions (when the roof of the insulation shed 3 does not need to be cleaned), so that it fits the top shape of the planting shed 2 and forms a sealed insulation shed structure.

[0033] When it is necessary to clean the roof of the insulated shed 3, simply start the drive motor 7, which will drive the lower rotating roller 5 to rotate, thereby causing the roof of the insulated shed 3 to rotate in a cycle (during the rotation of the roof of the insulated shed 3 driven by the lower rotating roller 5, the upper rotating roller 5 and multiple limiting rollers 6 will rotate accordingly), thus achieving the purpose of facilitating the cleaning of the roof of the insulated shed 3.

[0034] Furthermore, the support and drive structure also includes isolation rods 8, which are fixed inside the planting shed 2 and are arranged parallel to the limiting rollers 6. Multiple isolation rods 8 are also provided and located inside the insulation shed roof 3. The surfaces of the multiple isolation rods 8 are all smooth surfaces and slide in contact with the inner surface of the insulation shed roof 3.

[0035] By setting the isolation rod 8, an isolation can be formed between the upper and lower layers of the insulated roof 3, thereby separating the upper and lower layers of the insulated roof 3 and avoiding large friction inside the insulated roof 3 during the cyclic rotation process, thus extending the service life of the insulated roof 3.

[0036] Furthermore, a drainage ditch 9 is fixed at the bottom of the planting shed 2. The output end of the drainage ditch 9 is connected to the drainage pipe. The top of the drainage ditch 9 is covered with a grate 91, so that the sewage after cleaning can be collected in the drainage ditch 9 and discharged smoothly. At the same time, it is convenient for staff to stand up and clean the roof of the heat preservation shed 3. It also allows the water generated by irrigation in the planting shed 2 to be collected and discharged together.

[0037] The planting shed 2 has an entrance and exit on one side of the lower end, and an opening and closing door 21 is installed at the entrance and exit. Ventilation windows 22 are installed on both sides of the planting shed 2.

[0038] The working principle of this utility model is as follows: In daily use, when it is necessary to clean the upper layer of the insulated roof 3 exposed to the outside of the planting shed 2, simply start the drive motor 7, which will drive the rotating roller 5 at the lower end to rotate, thereby causing the insulated roof 3 to rotate in a cycle. This will cause the upper layer of the insulated roof 3 to rotate towards the lower end of the planting shed 2. During this process, the staff only needs to stand at the lower end of the planting shed 2 and continuously clean the surface of the insulated roof 3 that has passed by, thus completing the cleaning work on the upper layer of the insulated roof 3. This ensures the effect of sunlight exposure, and there is no need to disassemble or install the entire insulated roof 3. The cleaning is convenient and quick, which is more conducive to the healthy growth of the plants inside.

[0039] It should be further noted that the technical features of the breeding house, planting trough, drive motor, grid cover, etc. involved in this utility model patent application should be regarded as prior art. The specific structure, working principle, and possible control methods and spatial arrangement methods of these technical features can be adopted by conventional choices in the field and should not be regarded as the inventive point of this utility model patent. This utility model patent will not be further elaborated in detail.

[0040] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A sloping tower-type aquaculture structure, comprising a breeding house (1), a planting shed (2) fixed to the top of the breeding house (1), a planting trough (4) fixed to the top of the breeding house (1) and located inside the planting shed (2), and an insulated roof (3) covering the top of the planting shed (2), characterized in that: The insulated roof (3) is a ring-shaped double-layer structure, with the top and bottom of the insulated roof (3) located at the top of the upper end and the top of the lower end of the planting shed (2), respectively. The planting shed (2) is equipped with a support and drive structure, which is used to support the heat-insulating shed roof (3) so that it fits the top curvature of the planting shed (2). The support and drive structure is also used to drive the heat-insulating shed roof (3) to rotate cyclically.

2. A slope tower type seed breeding structure according to claim 1, characterized in that: The support drive structure includes a rotating roller (5) and a limiting roller (6). There are two rotating rollers (5) and they are rotatably connected to the top of the upper end and the top of the lower end of the planting shed (2). The heat-insulating shed roof (3) is fitted between the two rotating rollers (5). Multiple limiting rollers (6) are provided and rotatably connected inside the planting shed (2), and multiple limiting rollers (6) are in rolling contact with the surface of the inner heat-insulating shed roof (3).

3. The structure according to claim 1, wherein: The support drive structure also includes a drive motor (7), which is fixed on the planting shed (2). The output shaft of the drive motor (7) is connected to the rotating roller (5) at the lower end of the planting shed (2).

4. The structure according to claim 1, wherein: The support drive structure also includes an isolation rod (8), which is fixed inside the planting shed (2) and is arranged parallel to the limiting roller (6). Multiple isolation rods (8) are also provided and located inside the heat preservation shed roof (3). The surfaces of the multiple isolation rods (8) are all smooth surfaces and slide in contact with the inner surface of the heat preservation shed roof (3).

5. The structure of claim 1, wherein: The bottom of the planting shed (2) is fixed with a sewage ditch (9), the output end of the sewage ditch (9) is connected to the sewage pipe, and the top of the sewage ditch (9) is covered with a grate (91).

6. A slope tower type seed breeding structure according to any one of claims 1 to 5, characterized in that: The planting shed (2) has an entrance and exit on one side of its lower end. The entrance and exit are equipped with an openable door (21). The planting shed (2) has ventilation windows (22) installed on both sides.