Zero magnetic device for plant cultivation

By designing intervention channels and demagnetizing lines in the plant cultivation box, combined with a temperature and humidity control system, the problem that existing cultivation boxes cannot provide magnetic field-free and temperature and humidity measurement has been solved, realizing a multifunctional plant cultivation device with magnetic shielding and environmental monitoring.

CN224386327UActive Publication Date: 2026-06-23零磁装备(德清)有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
零磁装备(德清)有限公司
Filing Date
2025-06-23
Publication Date
2026-06-23

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  • Figure CN224386327U_ABST
    Figure CN224386327U_ABST
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Abstract

The utility model discloses a zero magnetic device for plant culture relates to plant culture device technical field, including the bucket cover subassembly, the bucket body subassembly is provided with under the bucket cover subassembly, the bucket body subassembly downside is connected with the drainage component. The utility model discloses through the intervention passage of reserving in the upper middle and lower area of bucket body both sides, can make small -size temperature and humidity, gas composition sensor and camera etc. are worn to the device inside, and every hole is through the form of pipe -penetrating and adds two -end plug to close each interlayer space of device, makes interlayer space unable to communicate with the space in the bucket or the space outside the bucket, avoids the material such as water vapor, dust to enter the interlayer intermediate passage and expands temperature and humidity sensor, fills the blank of simply providing zero magnetic culture environment without temperature and humidity measurement function, can be flexible and adapt to various customer demand.
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Description

Technical Field

[0001] This utility model relates to the technical field of plant cultivation devices, specifically a zero-magnetic device for plant cultivation. Background Technology

[0002] The basic structure of other conventional plant cultivation boxes with more comprehensive functions mainly includes the box body, control system, lighting system, temperature control system, humidity control system, gas circulation system, etc., which can realize functions such as simulating the natural environment, promoting plant growth, and extending the plant growth cycle.

[0003] A conventional plant incubator is a device that simulates the conditions required for plants to grow in their natural environment. It typically includes precise control of key parameters such as light, temperature, and humidity. Its disadvantage is that it cannot provide a magnetic field-free environment, making it unsuitable for research that requires special magnetic field conditions. It may also cause interference for some research on plants that are sensitive to magnetic fields.

[0004] With the rapid development of biomedicine and biotechnology in China, the demand for zero-magnetic biological culture experimental environments is increasing. Currently, there are some magnetic shielding devices for biological culture experiments on the domestic market, but most of them focus on providing basic magnetic shielding functions and may lack in terms of environmental monitoring, temperature control and expandability. Utility Model Content

[0005] The technical problem this invention aims to solve is to overcome existing defects and provide a zero-magnetic device for plant cultivation. By pre-reserving access channels in the upper, middle, and lower sections on both sides of the container, small temperature, humidity, and gas composition sensors, as well as cameras, can be inserted into the device. Each hole is sealed off by a tube with end caps, preventing communication between the interlayer spaces and the interior or exterior of the container. This avoids the entry of moisture, dust, and other substances into the interlayers. The extended access channels for temperature and humidity sensors fill the gap of simply providing a zero-magnetic cultivation environment without temperature and humidity measurement functionality. It can flexibly adapt to various customer needs and effectively solves the problems in the prior art.

[0006] To achieve the above objectives, the present invention provides the following technical solution: a zero-magnetic device for plant cultivation, comprising a lid assembly, a body assembly disposed on the lower side of the lid assembly, a drainage assembly connected to the lower side of the body assembly, and a tray assembly disposed inside the body assembly;

[0007] The bucket lid assembly includes an aluminum plate, a sealing ring, an alloy cap, screws, and gaskets. Three layers of the alloy cap are provided on the lower side of the aluminum plate, and gaskets are provided between the aluminum plate and the three alloy caps. A sealing ring is provided on the outer ring side of the aluminum plate. Screws and nuts for locking the aluminum plate and alloy caps are provided on the bucket lid assembly. Three screws and nuts are provided on the bucket lid assembly. The gaskets in the middle of the bucket lid are distributed between every two caps. The installation height is finely adjusted by adding elastic washers of different thicknesses between the layers (to ensure that each cap is in complete contact with the flange edge of the corresponding bucket). The screws are locked to the aluminum cap from bottom to top and fixed with nuts.

[0008] The barrel assembly includes a base plate, shock-absorbing rubber pads, a serpentine cooling pipe, coolant inlet and outlet, intervention channel, an aluminum barrel, a permalloy barrel, a demagnetizing wire, and a fiberglass barrel. The aluminum barrel is located on the innermost side, and three layers of permalloy barrels are arranged on the outer side of the aluminum barrel. The fiberglass barrel is located on the outermost side of the permalloy barrel. The intervention channel runs through the aluminum barrel, the permalloy barrel, and the fiberglass barrel. The base plate is located on the lower side of the barrel assembly, and four shock-absorbing rubber pads are arranged on the lower side of the base plate. The serpentine cooling pipe is arranged between the aluminum barrel and the innermost permalloy barrel. The upper part of the serpentine cooling pipe has a coolant inlet and outlet. A demagnetizing wire is laid between the serpentine cooling pipes. The serpentine cooling pipe is tightly attached to the outer side of the aluminum barrel. The intervention channel consists of a hollow round tube, two through-plate hollow rubber plugs, and two rubber plugs. The demagnetizing wire wraps around the three layers of permalloy through the central hole at the bottom of each barrel.

[0009] Furthermore, a handle is provided on the aluminum plate, and a lifting handle is provided on the upper part of both sides of the base plate.

[0010] Furthermore, the drainage assembly consists of a semi-through-plate connector, a pagoda elbow, a drain valve, and a silicone hose.

[0011] Furthermore, the tray assembly includes a storage tray with three through holes and a moisture-absorbing fiber cloth. The moisture-absorbing fiber cloth is provided on the upper side of the tray assembly and the inner bottom side of the aluminum barrel. The tray assembly consists of three uprights fixed to the bottom of the aluminum barrel and the storage tray. The storage tray has no fasteners, and the three circular through holes in the middle can accommodate the operator's fingers to pass through, making it convenient to hook and lift.

[0012] Furthermore, a trolley is provided on the lower side of the barrel assembly, and a support foot is provided below the shock-absorbing rubber pad of the barrel assembly, with the support foot passing through and installed on the trolley. The trolley consists of a platform, two swivel casters, two fixed casters, four shock-absorbing foot limiting flanges, four limiting flange fixing blocks, and a handle.

[0013] 1. With access channels reserved in the upper, middle and lower sections on both sides of the barrel, small temperature and humidity sensors, gas composition sensors and cameras can be inserted into the device. Each hole is sealed by a tube with plugs at both ends, preventing the interlayer space from connecting with the space inside or outside the barrel. This avoids moisture, dust and other substances from entering the interlayer. The access channels are expanded to include temperature and humidity sensors, filling the gap of simply providing a zero magnetic culture environment without temperature and humidity measurement function. It can flexibly adapt to various customer needs.

[0014] 2. An integrated serpentine heat pipe is wrapped around the outer wall of the aluminum bucket. A metal material with a high thermal conductivity (such as copper) or a flexible and easy-to-lay plastic pipe can be selected. The first and last ends of the structure are located at the bucket opening, which can be connected to an external water supply system to achieve heat dissipation and temperature control functions. The humidity inside the bucket can be adjusted by the moisture-absorbing fiber cloth, so that the temperature and humidity inside the cultivation device can be effectively regulated.

[0015] 3. By using adjustable-spacing bucket lid assemblies and demagnetizing lines, and by adding elastic shims to adjust the spacing, each layer of alloy bucket is connected to the corresponding bucket lid, so that the magnetic lines of force are closed, and the demagnetizing lines ensure the magnetic shielding performance of the device. Attached Figure Description

[0016] Figure 1 This is a three-dimensional structural diagram of the present invention;

[0017] Figure 2 This utility model Figure 1 Front view structural diagram of the middle barrel lid assembly;

[0018] Figure 3 This utility model Figure 1 Schematic diagram of the main sectional structure of the middle barrel lid assembly;

[0019] Figure 4 This utility model Figure 3 Enlarged structural diagram at point A;

[0020] Figure 5 This utility model Figure 1 Front view structural diagram;

[0021] Figure 6 This utility model Figure 5 A schematic diagram of the AA cross-sectional structure in the diagram;

[0022] Figure 7 This utility model Figure 6 Enlarged structural diagram at point B;

[0023] Figure 8 This is a schematic diagram of the serpentine cooling pipe in this utility model.

[0024] In the diagram: 1. Lid assembly; 101. Handle; 102. Aluminum plate; 103. Sealing ring; 104. Alloy lid; 105. Gasket; 106. Screw; 2. Body assembly; 201. Base plate; 202. Handle; 203. Shock-absorbing pad; 204. Serpentine cooling pipe; 205. Coolant inlet / outlet; 206. Intervention channel; 207. Aluminum drum; 208. Permalloy drum; 209. Fiberglass drum; 210. Demagnetizing wire; 3. Trolley; 4. Drainage assembly; 5. Tray assembly. Detailed Implementation

[0025] Please see Figure 1-8 This embodiment provides a technical solution: a zero-magnetic device for plant cultivation, including a bucket lid assembly 1, a bucket body assembly 2 disposed on the lower side of the bucket lid assembly 1, a drainage assembly 4 connected to the lower side of the bucket body assembly 2, and a tray assembly 5 disposed inside the bucket body assembly 2.

[0026] The bucket lid assembly 1 includes an aluminum plate 102, a sealing ring 103, an alloy cover 104, a screw 106, and a gasket 105. The lower side of the aluminum plate 102 is provided with a three-layer alloy cover 104, and a gasket 105 is provided between the aluminum plate 102 and the three-layer alloy cover 104. The sealing ring 103 is provided on the outer ring side of the aluminum plate 102. The bucket lid assembly 1 is provided with a screw 106 and a nut for locking the aluminum plate 102 and the alloy cover 104.

[0027] The tank assembly 2 includes a base plate 201, shock-absorbing rubber pads 203, a serpentine cooling pipe 204, coolant inlet and outlet 205, an intervention channel 206, an aluminum tank 207, a permalloy tank 208, a demagnetizing line 210, and a fiberglass tank 209. The aluminum tank 207 is located on the innermost side, and three layers of permalloy tanks 208 are arranged on the outer side of the aluminum tank 207. The fiberglass tank 209 is arranged on the outermost side of the permalloy tanks 208. The intervention channel 206 runs through the aluminum tank 207, the permalloy tank 208, and the fiberglass tank 209. The base plate 201 is arranged on the lower side of the tank assembly 2, and four shock-absorbing rubber pads 203 are arranged on the lower side of the base plate 201. A serpentine cooling pipe 204 is arranged between the aluminum tank 207 and the innermost permalloy tank 208. The coolant inlet and outlet 205 are arranged on the upper part of the serpentine cooling pipe 204, and the demagnetizing line 210 is laid between the serpentine cooling pipes 204.

[0028] The lid assembly 1 is equipped with three circumferentially distributed screws 106 and nuts. The alloy lid 104 has three layers: upper, middle, and lower. Gaskets are placed between the aluminum plate 102 and the three alloy lids 104. The installation height is finely adjusted by adding elastic washers of different thicknesses between the layers (to ensure that each lid is in complete contact with the flange edge of the corresponding bucket). The lid is locked to the aluminum lid 102 from bottom to top with screws 106 and fixed with nuts. The serpentine cooling pipe 204 is tightly attached to the outside of the aluminum bucket 207. The demagnetizing wire 210 wraps the three layers of permalloy through the central hole at the bottom of each bucket. The intervention channel 206 consists of a hollow round tube, two through-plate hollow rubber plugs, and two rubber plugs. Intervention channels are reserved in the upper, middle, and lower areas on both sides of the bucket body, allowing small temperature and humidity sensors, gas composition sensors, cameras, etc. to penetrate into the device. Each hole is sealed by through-tubes and plugs at both ends to close the space between the layers of the device.

[0029] The aluminum plate 102 is provided with a handle 101, and the upper sides of the base plate 201 are provided with handles 202.

[0030] The drainage component 4 consists of a semi-through plate joint, a pagoda elbow, a drain valve, and a silicone hose.

[0031] The tray assembly 5 includes a storage tray with three through holes and a moisture-absorbing fiber cloth. The upper side of the tray assembly 5 and the inner bottom side of the aluminum bucket 207 are provided with moisture-absorbing fiber cloth.

[0032] The barrel assembly 2 has a trolley 3 located on its lower side. The barrel assembly 2 has a support foot below its shock-absorbing rubber pad 203, which is mounted on the trolley 3. The trolley 3 consists of a platform, two swivel casters, two fixed casters, four shock-absorbing foot limit flanges, four limit flange fixing blocks, and a handle.

[0033] The working principle of this utility model is as follows: Figures 1-8 As shown, during use, the lid assembly 1 is opened via the handle 101, the cultivated plant is placed on the tray of the tray assembly 5, and then the lid assembly 1 is placed on the body assembly 2. The tightly closed lid assembly 1 and the body assembly 2 form a closed magnetic field structure, creating a zero-magnetic space inside the sealed body, thus providing a zero-magnetic environment for the plant to grow and be observed. The drainage assembly 4 can drain the condensate produced by the plant growth inside the body, the serpentine cooling pipe 204 can cool the inside of the body assembly 2, the moisture-absorbing fiber cloth can regulate humidity, ensuring a good plant growth environment, the demagnetizing line 210 can demagnetize the body assembly, ensuring a zero-magnetic environment, and the intervention channel 206 can be fitted with a temperature and humidity sensor and a camera to ensure data monitoring during the plant growth process.

[0034] The above description is merely an embodiment of this utility model and does not limit the patent scope of this utility model. Any equivalent structural or procedural transformations made based on the content of this utility model specification and drawings, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this utility model.

Claims

1. A zero-magnetic device for plant cultivation, comprising a bucket lid assembly (1), characterized in that: A bucket body assembly (2) is provided on the lower side of the bucket lid assembly (1), a drainage assembly (4) is connected to the lower side of the bucket body assembly (2), and a tray assembly (5) is provided inside the bucket body assembly (2); The bucket lid assembly (1) includes an aluminum plate (102), a sealing ring (103), an alloy cover (104), a screw (106), and a gasket (105). Three layers of the alloy cover (104) are provided on the lower side of the aluminum plate (102). A gasket (105) is provided between the aluminum plate (102) and the three layers of alloy cover (104). A sealing ring (103) is provided on the outer ring side of the aluminum plate (102). The bucket lid assembly (1) is provided with screws (106) and nuts for locking the aluminum plate (102) and the alloy cover (104). The barrel assembly (2) includes a base plate (201), shock-absorbing rubber pads (203), a serpentine cooling pipe (204), a coolant inlet / outlet (205), an intervention channel (206), an aluminum barrel (207), a permalloy barrel (208), a demagnetizing wire (210), and a fiberglass barrel (209). The aluminum barrel (207) is located on the innermost side, and three layers of the permalloy barrels (208) are arranged on the outer side of the aluminum barrel (207). The fiberglass barrel (209) is arranged on the outermost side of the permalloy barrels (208). The intervention channel (206) runs through the barrel. The aluminum bucket (207), the permalloy bucket (208), and the fiberglass bucket (209) are arranged. The bottom plate (201) is provided on the lower side of the bucket assembly (2). Four shock-absorbing rubber pads (203) are provided on the lower side of the bottom plate (201). The serpentine cooling pipe (204) is provided between the aluminum bucket (207) and the innermost permalloy bucket (208). The upper part of the serpentine cooling pipe (204) is provided with a coolant inlet and outlet (205). Demagnetizing wires (210) are laid between the serpentine cooling pipes (204).

2. The zero-magnetic device for plant cultivation according to claim 1, characterized in that: A handle (101) is provided on the aluminum plate (102), and a lifting handle (202) is provided on the upper part of both sides of the base plate (201).

3. The zero-magnetic device for plant cultivation according to claim 1, characterized in that: The drainage assembly (4) consists of a half-through plate joint, a pagoda elbow, a drain valve and a silicone hose.

4. The zero-magnetic device for plant cultivation according to claim 1, characterized in that: The tray assembly (5) includes a tray with three through holes and a moisture-absorbing fiber cloth. The moisture-absorbing fiber cloth is provided on the upper side of the tray assembly (5) and the inner bottom side of the aluminum barrel (207).

5. A zero-magnetic device for plant cultivation according to claim 1, characterized in that: A trolley (3) is provided on the lower side of the barrel assembly (2), and a support foot is provided below the shock-absorbing rubber pad (203) of the barrel assembly (2), and the support foot is installed on the trolley (3).