A layered, mesh-type integrated cultivation container
By designing a layered mesh integrated cultivation pot, the problems of root growth obstruction and nutrient loss in traditional cultivation containers are solved. It realizes a gradient environment for the root system and a stable nutrient supply, reduces the manpower and material consumption during the root promotion period, and maintains the beautiful appearance of the plants.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GUANGDONG VOCATIONAL COLLEGE OF SCI & TRADE
- Filing Date
- 2025-06-25
- Publication Date
- 2026-06-30
AI Technical Summary
Traditional single-layer cultivation containers cannot create a gradient environment for root growth, resulting in obstructed taproot development, insufficient space for fibrous root development, poor air permeability, high root rot rate due to oxygen deficiency, and high nutrient loss rate due to top fertilization, making it impossible to form a stable nutrient supply system.
Design a layered mesh integrated cultivation container, including a substrate pot and a lower trapezoidal sand storage pot. Through the combined use of mesh, bottom plate, material outlet, rectangular stacking board, cultivation frame and density board, the upper and lower layers are reasonably separated. The substrate pot has ideal bulk density and physicochemical properties, while the lower trapezoidal sand storage pot is made of loose and breathable sand and is equipped with organic fertilizer, so as to achieve the simultaneous implementation of root strengthening, root promotion and root nourishment.
Ensure the main root grows normally, promote the rapid propagation of fibrous roots, reduce the investment of manpower, material resources and financial resources, and provide a reasonably structured cultivation pot that not only meets the plant's root promotion needs, but also maintains an beautiful appearance without any ornamental obstacles.
Smart Images

Figure CN224419480U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of cultivation pot technology, and in particular to a layered mesh integrated cultivation pot. Background Technology
[0002] Traditional single-layer cultivation containers cannot create a gradient environment for root growth, which hinders the downward growth of the taproot and reduces the space for the development of fibrous roots. This severely affects root aeration and increases the rate of root rot due to oxygen deficiency. Most existing cultivation containers use top fertilization, requiring multiple artificial fertilizations during the root promotion period. Direct mixing of sandy substrate with fertilizer can lead to a nutrient loss rate of over 50%, making it impossible to form a continuous and stable nutrient supply system.
[0003] In summary, this application proposes a layered mesh integrated cultivation pot to solve the aforementioned problems. Utility Model Content
[0004] The purpose of this invention is to provide a layered mesh integrated cultivation container that can solve the problem that traditional single-layer cultivation containers cannot achieve a gradient environment for root growth, resulting in obstructed taproot growth, insufficient space for fibrous root development, serious impact on root aeration, and increased root hypoxia and rot rate. Existing cultivation containers mostly use top fertilization, requiring multiple artificial fertilizations during the root promotion period. Direct mixing of sandy substrate and fertilizer can lead to nutrient loss exceeding 50%, making it impossible to form a continuous and stable nutrient supply system.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a layered mesh integrated cultivation pot, comprising a substrate pot, a lower trapezoidal sand storage pot, and an integrated structure. The bottom of the substrate pot is fixedly connected to the lower trapezoidal sand storage pot, wherein the ratio of the substrate pot to the lower trapezoidal sand storage pot is 1:2. The lower trapezoidal sand storage pot is used to store sandy soil. Because sandy soil lacks nutrients, plants need fertilizer to promote root growth. The integrated structure is located on the substrate pot and the lower trapezoidal sand storage pot. The integrated structure includes a mesh, a bottom plate, a feeding port, a rectangular support plate, a cultivation frame, and a density plate. A cultivation frame is provided on the substrate pot, and a density plate is integrally formed at the bottom of the cultivation frame. The density plate has multiple sets of horizontal holes to facilitate the growth of seedling roots. The density plate separates the substrate pot and the lower trapezoidal sand storage pot. The sand storage basin, through the combined use of mesh, bottom plate, material outlet, rectangular stacking board, cultivation frame, and density board, compared with traditional root-promoting cultivation, rationally separates the upper and lower layers. The substrate basin has ideal bulk density and good physical and chemical properties, which is conducive to fixing seedlings or miniature potted plants to maintain upright growth and ensure that the taproot grows normally. The lower trapezoidal sand storage basin is filled with loose and breathable sand with good total porosity, which facilitates the rapid propagation of fibrous roots by the taproot. Organic fertilizer is placed on both sides of the sand to help plants obtain the nutrients needed during the root promotion period. It realizes the three steps of root fixation, root promotion, and root nourishment at the same time, reducing the manpower, material resources, and financial resources during the root promotion period. It strives to provide a reasonable structure that can not only meet the needs of plant root promotion, but also keep the plant with an beautiful appearance without any ornamental obstacles.
[0006] Preferably, the lower trapezoidal sand storage basin has a rectangular groove inside, and several mesh openings are evenly distributed on both sides of the rectangular groove, with a mesh opening diameter of 3mm.
[0007] Preferably, the bottom of the lower trapezoidal sand storage basin is fixedly connected to a base plate, and the two sides of the lower trapezoidal sand storage basin are provided with discharge ports with a diameter of 8mm. The discharge ports are designed to facilitate the placement of organic fertilizer to meet the nutritional needs of plants during the root promotion period.
[0008] Preferably, a rectangular support plate is fixedly connected to the inner side of the substrate pot. The rectangular support plate facilitates the placement of the cultivation frame and further increases the stability of the cultivation frame placement.
[0009] Preferably, the front and rear sides of the cultivation frame are designed with hanging ears, the height of which is 5mm. This design facilitates the cultivation frame to be hung on the top of the substrate pot via the hanging ears.
[0010] Preferably, the horizontal holes on the sparse-dense plate are arranged in a matrix with a hole spacing of 2cm.
[0011] Compared with existing technologies, the beneficial effects of this utility model are as follows: This layered mesh integrated cultivation pot, through the combined use of mesh, bottom plate, material outlet, rectangular stacking board, cultivation frame and density board, rationally separates the upper and lower layers compared with traditional root-promoting cultivation methods. The substrate pot has ideal bulk density and good physical and chemical properties, which is conducive to fixing seedlings or miniature potted plants to maintain upright growth and ensure that the taproot grows normally. The lower trapezoidal sand storage pot is made of loose and breathable sand with good total porosity, which facilitates the rapid propagation of fibrous roots by the taproot. Organic fertilizer is provided on both sides of the sand to help the plant obtain the nutrients needed during the root-promoting period. It realizes the three steps of root fixation, root promotion and root nourishment at the same time, reducing the manpower, material resources and financial resources during the root promotion period. It strives to provide a reasonable structure that can not only meet the needs of plant root promotion, but also keep the plant with a beautiful appearance without ornamental obstacles. Attached Figure Description
[0012] The present invention will be further described below with reference to the accompanying drawings and embodiments:
[0013] Figure 1 This is a perspective view of the present utility model;
[0014] Figure 2 This utility model Figure 1 An exploded view of the cultivation frame;
[0015] Figure 3 This utility model Figure 2 A bottom view.
[0016] Attached diagram labels: 1. Substrate basin; 2. Lower trapezoidal sand storage basin; 3. Mesh; 4. Bottom plate; 5. Feed outlet; 6. Rectangular stacking board; 7. Cultivation frame; 8. Density board. Detailed Implementation
[0017] In the description of this utility model, it should be understood that the directional descriptions, such as up, down, front, back, left, right, etc., indicate the directional or positional relationship based on the directional or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.
[0018] Please see Figure 1-3This utility model provides a technical solution: a layered mesh integrated cultivation pot, including a substrate pot 1, a lower trapezoidal sand storage pot 2, and an integrated structure. The bottom of the substrate pot 1 is fixedly connected to the lower trapezoidal sand storage pot 2, wherein the ratio of the substrate pot 1 to the lower trapezoidal sand storage pot 2 is 1:2. The lower trapezoidal sand storage pot 2 is used to store sandy soil. Because sandy soil lacks nutrients, plants need fertilizer to promote root growth. The integrated structure is located on the substrate pot 1 and the lower trapezoidal sand storage pot 2. The integrated structure includes a mesh 3, a bottom plate 4, a material outlet 5, a rectangular support plate 6, a cultivation frame 7, and a spacing plate 8. The cultivation frame 7 is provided on the substrate pot 1, and the bottom of the cultivation frame 7 is integrally formed with a spacing plate. The plate 8 has multiple sets of horizontal holes to facilitate the growth of seedling roots. The plate 8 separates the substrate pot 1 and the lower trapezoidal sand storage pot 2. The lower trapezoidal sand storage pot 2 has a rectangular groove inside, with several mesh openings 3 evenly distributed on both sides of the groove. The mesh openings 3 have a diameter of 3mm. A base plate 4 is fixedly connected to the bottom of the lower trapezoidal sand storage pot 2. Discharge ports 5, with a diameter of 8mm, are located on both sides of the lower trapezoidal sand storage pot 2 to facilitate the placement of organic fertilizer to meet the nutritional needs of the plants during the root promotion period. A rectangular support plate 6 is fixedly connected to the inner side of the substrate pot 1. The rectangular support plate 6 facilitates the placement of the cultivation frame 7. The placement of the cultivation frame 7 further increases its stability. The front and back sides of the cultivation frame 7 feature hanging ears, each 5mm high. This design allows the cultivation frame 7 to be easily hung on top of the substrate pot 1. During use, seedlings are placed inside the cultivation frame 7 for planting. Simultaneously, the cultivation frame 7 is manually placed into the substrate pot 1. Sand is then piled between the two sets of mesh 3. Fertilizer is added to the trapezoidal sand storage basin 2 through the feeding port 5. The fertilizer flows through the mesh 3 into the sand to compensate for the poor quality of the sandy soil. The system utilizes the mesh 3, bottom plate 4, feeding port 5, rectangular support plate 6, cultivation frame 7, and density plate 8. When used together, compared with traditional root-promoting cultivation, this product features a rationally separated upper and lower layer. The substrate pot 1 has ideal bulk density and good physical and chemical properties, which is conducive to fixing seedlings or miniature potted plants to maintain upright growth and ensure that the main root grows normally. The lower trapezoidal sand storage pot 2 is made of loose and breathable sand with good total porosity, which facilitates the rapid propagation of fibrous roots by the main root. Organic fertilizer is provided on both sides of the sand to help the plant obtain the nutrients needed during the root-promoting period. This allows the three steps of root fixation, root promotion, and root nourishment to be carried out simultaneously, reducing the manpower, material resources, and financial resources required during the root-promoting period. It strives to provide a product with a reasonable structure that can meet the needs of plant root promotion while keeping the plant with a beautiful appearance and no ornamental obstacles.
[0019] Working principle: When using, place the seedlings in the cultivation frame 7 for planting. At the same time, manually place the cultivation frame 7 in the substrate pot 1. Then, pile sand between the two sets of mesh 3. At the same time, through the feeding port 5, the user puts fertilizer into the trapezoidal sand storage pot 2. The fertilizer flows into the sand through the mesh 3 to compensate for the barrenness of the sandy soil.
[0020] The embodiments of the present utility model have been described in detail above with reference to the accompanying drawings. However, the present utility model is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present utility model.
Claims
1. A layered mesh integrated cultivation container, characterized in that, include: The substrate basin (1) and the lower trapezoidal sand storage basin (2) are fixedly connected to the bottom of the substrate basin (1); An integrated structure is located on the substrate pot (1) and the lower trapezoidal sand storage pot (2), including a mesh (3), a bottom plate (4), a material outlet (5), a rectangular stacking plate (6), a cultivation frame (7) and a density plate (8). The cultivation frame (7) is provided on the substrate pot (1), and the bottom of the cultivation frame (7) is integrally formed with a density plate (8). The density plate (8) has multiple sets of horizontal holes to facilitate the growth of seedling roots.
2. The layered mesh integrated cultivation container according to claim 1, characterized in that: The lower trapezoidal sand storage basin (2) has a rectangular groove inside, and several meshes (3) are evenly distributed on both sides of the rectangular groove. The mesh (3) has a diameter of 2 mm.
3. The layered mesh integrated cultivation container according to claim 2, characterized in that: The bottom of the lower trapezoidal sand storage basin (2) is fixedly connected to a base plate (4), and discharge ports (5) are opened on both sides of the lower trapezoidal sand storage basin (2), with a diameter of 15mm.
4. The layered mesh integrated cultivation container according to claim 3, characterized in that: A rectangular stacking plate (6) is fixedly connected to the inner side of the substrate basin (1).
5. The layered mesh integrated cultivation container according to claim 4, characterized in that: The cultivation frame (7) has a hanging ear design on the front and back sides, and the height of the hanging ear is 5mm.
6. The layered mesh integrated cultivation container according to claim 5, characterized in that: The horizontal holes on the sparse plate (8) are arranged in a matrix with a hole spacing of 2cm.