Edible mushroom glass material box

By using a glass enclosure, combined with multi-section sliding glass doors and adjustable cabinets, the problem of uneven temperature, humidity, and light in edible mushroom cultivation is solved, achieving efficient control of the growth environment and convenient harvesting operations.

CN224386366UActive Publication Date: 2026-06-23DINGXIN SUNSHINE ENVIRONMENTAL TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
DINGXIN SUNSHINE ENVIRONMENTAL TECH CO LTD
Filing Date
2025-06-23
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Traditional edible mushroom cultivation sites suffer from inaccurate temperature and humidity control, uneven light distribution, and inconvenient harvesting, making it difficult to meet the demands of high-quality, large-scale production.

Method used

The enclosure is made of glass and features a multi-section sliding glass door and an adjustable cabinet, enabling precise control of temperature, humidity, carbon dioxide concentration, and light. The sliding design of the planting tray facilitates harvesting.

Benefits of technology

It enables precise control of the edible fungi growth environment, improves harvesting efficiency, adapts to the growth needs of different types of edible fungi, and enhances space utilization.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224386366U_ABST
    Figure CN224386366U_ABST
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Abstract

The utility model relates to an edible mushroom glass material box belongs to edible mushroom planting equipment technical field, including frame, install wall surface on the frame, form the box between frame and wall surface, and the front side and rear side of box all slide installation have multiple push -and -pull glass door, the inside fixed mounting of box has the planting frame, and the planting tray for the edible mushroom planting is slidingly connected in array on the planting frame, the outside one side fixed mounting of frame has the adjusting cabinet, the outlet end fixed mounting of adjusting cabinet has the communicating pipe, the other end of communicating pipe and the upper end one side of box are linked together, through adopting frame and multiple push -and -pull glass door, the growth condition of edible mushroom inside the box is observed directly, and the light intensity is adjusted, the temperature and humidity and carbon dioxide content in the box are adjusted, the planting demand of different edible mushrooms is adapted, and through the planting tray of push -and -pull type, the edible mushroom of planting is picked, convenient operation, convenient to edible mushroom planting use.
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Description

Technical Field

[0001] This utility model relates to the technical field of edible fungus cultivation equipment, and in particular to a glass box for edible fungus cultivation. Background Technology

[0002] Edible fungi refer to large, edible mushrooms (macrofungi), commonly known as mushrooms. With the continuous development of the edible fungi industry, the demand for precise control of its cultivation environment is becoming increasingly prominent. Traditional edible fungi cultivation sites, such as simple greenhouses and mushroom houses, suffer from problems such as inaccurate temperature and humidity control, uneven light distribution, and susceptibility to external contamination. These issues make it difficult to meet the requirements of high-quality, large-scale edible fungi production. Furthermore, during cultivation, edible fungi are mostly placed on planting racks, which are often arranged in vertical arrays, making harvesting inconvenient and difficult to operate. Utility Model Content

[0003] To overcome the technical defects of the existing technology, this utility model provides a glass box for edible fungi, which improves the lighting requirements for the growth of edible fungi and facilitates the harvesting of edible fungi, making the operation convenient.

[0004] The technical solution adopted by this utility model is: a glass box for edible fungi cultivation, including a frame, a wall installed on the frame, forming a box between the frame and the wall, and multiple sliding glass doors slidably installed on the front and rear sides of the box. A planting rack is fixedly installed inside the box, and planting trays for edible fungi cultivation are arrayed and slidably engaged on the planting rack. The number of sliding glass doors is the same as the number of horizontally distributed planting trays. An adjustment cabinet is fixedly installed on one side of the frame, and a connecting pipe is fixedly installed at the air outlet of the adjustment cabinet. The other end of the connecting pipe is connected to the upper side of the box. In use, by placing the edible fungi bags on the planting trays and pushing the planting trays, the planting trays move on the planting rack, thus allowing the edible fungi to grow. The planting tray is fixed on the planting rack and located inside the box. Closing the multi-panel sliding glass door creates a sealed space inside the box. The box is constructed with a frame and glass walls, allowing for easy observation of the edible fungi's growth on the planting tray. During fungi growth, the temperature, humidity, and carbon dioxide concentration inside the box are regulated via the control cabinet. During regulation, regulating gas enters the box through the connecting pipe to exchange the air inside, adapting to the growth of different types of edible fungi and facilitating cultivation. For harvesting, pushing the multi-panel sliding glass door opens both sides of the box, allowing the planting tray to be pulled out from the planting rack for easy harvesting.

[0005] Preferably, the frame is made of aluminum alloy, and the wall is made of double-layer hollow glass, with the outer layer being tempered glass and the inner layer being dimming glass. Inert gas is filled between the two layers of glass. By introducing inert gas, it is easy to provide heat insulation protection for the inside of the box. The dimming glass of the inner layer makes it easy to adjust the light intensity entering the inside of the box to suit the growth needs of different types of edible fungi.

[0006] Preferably, the regulating cabinet is used to regulate the temperature, humidity, and carbon dioxide concentration inside the enclosure, and the regulating cabinet electrically controls the dimming glass in the wall to control the light intensity entering the enclosure and to control the temperature, humidity, and carbon dioxide concentration inside the enclosure.

[0007] Preferably, the planting racks are arranged in an array with support plates, and the planting trays are slidably engaged with the support plates, which facilitates the placement of the planting trays and increases space utilization.

[0008] Preferably, the two sides of the support plate are rotatably mounted with ball bearings in an array, and the two sides of the planting tray are engaged with the ball bearings. When the planting tray is pulled, the planting tray moves on the support plate through the ball bearings.

[0009] Preferably, pin holes are provided at the middle positions of both sides of the support plate, and an electromagnet is fixedly installed at the lower end of the pin holes. Pin plates are slidably inserted at the middle positions of both ends of the planting tray. The pin plates are inserted into the pin holes. When the planting tray moves into place, the electromagnet is activated through the pin holes and the pin plates. The electromagnet attracts the pin plates, so that the pin plates are inserted into the pin holes, thereby restricting the movement of the planting tray.

[0010] Preferably, the planting tray has through holes on both sides, and the pin plate is inserted into the through holes. The pin plate is made of magnetic metal, which facilitates the electromagnet to attract the pin plate. When the electromagnet is closed, the pin plate moves upward along the through hole, releasing the fixation of the planting tray.

[0011] Preferably, handles are fixedly installed at both ends of the planting tray. A guide post is fixedly installed on the inner side of the handle, and the lower end of the guide post is inserted into the pin plate. A spring is fixedly installed on the lower inner end of the handle outside the guide post. The lower end of the spring is fixedly connected to the upper end of the pin plate. The handle facilitates pulling the planting tray. When the electromagnet is closed, the spring pulls the pin plate to the upper position, releasing the restriction on the planting tray. When the electromagnet is opened, the spring is in the extended state, and the pin plate is magnetically attracted by the electromagnet. The pin plate is inserted into the pin hole, achieving the effect of limiting the planting tray.

[0012] The beneficial effects of this utility model are: by adopting a frame and multi-section sliding glass door, it is convenient to observe the growth of edible fungi inside the box intuitively, and to adjust the light intensity, temperature, humidity and carbon dioxide content inside the box to adapt to the planting needs of different edible fungi. The sliding planting tray makes it easy to harvest the planted edible fungi, which is convenient to operate and easy to use for edible fungi cultivation. Attached Figure Description

[0013] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0014] Figure 2 This is a schematic diagram of the structure of this utility model after removing the multi-section sliding glass door;

[0015] Figure 3 This is a structural diagram showing the position of the box in this utility model;

[0016] Figure 4 This is a structural diagram showing the location of the planting rack in this utility model;

[0017] Figure 5 This utility model Figure 4 A magnified structural diagram of point A in the middle;

[0018] Figure 6 This is a schematic diagram of the structure of the planting tray after an explosion in this utility model.

[0019] Explanation of reference numerals in the attached diagram: 1. Frame; 2. Wall; 3. Multi-section sliding glass door; 4. Planting rack; 5. Planting tray; 6. Adjustment cabinet; 7. Connecting pipe; 8. Support plate; 9. Ball bearing; 10. Pin hole; 11. Electromagnet; 12. Pin plate; 13. Through hole; 14. Handle; 15. Guide post; 16. Spring. Detailed Implementation

[0020] The present invention will be further described below with reference to the accompanying drawings:

[0021] like Figures 1-6 As shown, this embodiment provides a glass box for edible fungi cultivation, including a frame 1, a wall 2 mounted on the frame 1, forming a box between the frame 1 and the wall 2, and multiple sliding glass doors 3 slidably mounted on the front and rear sides of the box. A planting rack 4 is fixedly mounted inside the box, and planting trays 5 for edible fungi cultivation are arrayed and slidably engaged on the planting rack 4. The number of sliding glass doors 3 is the same as the number of horizontally distributed planting trays 5. An adjustment cabinet 6 is fixedly mounted on one side of the frame 1, and a connecting pipe 7 is fixedly mounted at the air outlet of the adjustment cabinet 6. The other end of the connecting pipe 7 is connected to the upper side of the box. In use, by placing the edible fungi bag on the planting tray 5 and pushing the planting tray 5, the planting tray 5 moves on the planting rack 4, thus moving the planting tray 5... Fixed to the planting rack 4 and located inside the box, the multi-section sliding glass door 3 is closed, creating a sealed space inside the box. The box is composed of a frame 1 and glass walls 2, allowing for easy and direct observation of the growth status of the edible fungi on the planting tray 5. During the growth of the edible fungi, the temperature, humidity, and carbon dioxide concentration inside the box are regulated by adjusting the cabinet 6. During regulation, the regulating gas enters the box through the connecting pipe 7 to ventilate the air inside the box, adapting to the growth of different types of edible fungi and facilitating the cultivation of edible fungi. When harvesting, the multi-section sliding glass door 3 is pushed to open both sides of the box, and the planting tray 5 is pulled out from the planting rack 4, making it easy to harvest the edible fungi on the planting tray 5. This makes the operation convenient and easy to use.

[0022] As a technical optimization solution of this utility model, specifically as follows: Figures 1 to 3 As shown, frame 1 is made of aluminum alloy, and wall 2 is made of double-layer hollow glass, with the outer layer being tempered glass and the inner layer being dimming glass. Inert gas is filled between the two layers of glass. The introduction of inert gas facilitates heat insulation protection of the interior of the chamber. The dimming glass allows for adjustment of the light intensity entering the chamber to suit the growth needs of different types of edible fungi, such as the low light requirement for enoki mushrooms in their early growth stages and the appropriate high light requirement for shiitake mushrooms during their fruiting period. The regulating cabinet 6 is used to regulate the temperature, humidity, and carbon dioxide concentration inside the chamber. The cabinet 6 electrically controls the dimming glass in the wall 2 to control the light intensity entering the chamber, as well as the temperature, humidity, and carbon dioxide concentration inside the chamber. The temperature and humidity control is achieved by installing temperature and humidity sensors inside the chamber to collect real-time data on the internal environment. This data is then combined with temperature and humidity control devices (such as air conditioners, humidifiers, and dehumidifiers) on the cabinet 6 to exchange air inside the chamber, thus regulating the temperature and humidity. Furthermore, the carbon dioxide concentration entering the chamber is adjusted to maintain it within a suitable range, which is beneficial for mycelial growth and fruiting body formation.

[0023] As a technical optimization solution of this utility model, specifically as follows: Figure 4 and Figure 5 As shown, support plates 8 are arranged in an array between planting racks 4. Planting trays 5 are slidably engaged on the support plates 8, facilitating the placement of planting trays 5 and increasing space utilization, thus increasing the amount of edible fungi that can be grown. Ball bearings 9 are rotatably mounted in an array on both sides of the support plates 8, and the sides of the planting trays 5 are engaged with the ball bearings 9. When the planting trays 5 are pulled, they move along the support plates 8 via the ball bearings 9, improving the flexibility of movement during pulling. Pin holes 10 are provided in the middle of both sides of the support plates 8. An electromagnet 11 is fixedly installed at the lower end of the pin hole 10, and pin plates 12 are slidably inserted into the middle positions of both ends of the planting tray 5. The pin plates 12 are inserted into the inside of the pin hole 10. Through the pin hole 10 and the pin plates 12, when the planting tray 5 moves into place, the electromagnet 11 is activated, and the electromagnet 11 attracts the pin plates 12, so that the pin plates 12 are inserted into the inside of the pin hole 10, thereby restricting the movement of the planting tray 5 and improving the stability of the planting tray 5 during growth. Through holes 13 are opened on both sides of the planting tray 5, through which the pin plates 12 are inserted. On the through hole 13, the pin plate 12 is made of magnetic metal, which facilitates the electromagnet 11 to attract the pin plate 12. When the electromagnet 11 is closed, the pin plate 12 moves upward along the through hole 13, releasing the planting tray 5. Handles 14 are fixedly installed above both ends of the planting tray 5. Guide posts 15 are fixedly installed on the inner side of the handles 14, and the lower end of the guide posts 15 is inserted into the pin plate 12. A spring 16 is fixedly installed on the lower inner end of the handles 14, located outside the guide posts 15. The upper end of the pin plate 12 is fixedly connected to the handle 14, which facilitates the pulling of the planting tray 5. When the electromagnet 11 is closed, the tension of the spring 16 causes the pin plate 12 to be in the upper position, releasing the restriction on the planting tray 5. When the electromagnet 11 is turned on, the spring 16 is in the extended state, and the pin plate 12 is attracted by the magnetic force of the electromagnet 11. The pin plate 12 is inserted into the pin hole 10, achieving the effect of limiting the planting tray 5 and improving the stability of the planting tray 5 when planting edible fungi.

[0024] The foregoing has shown and described the basic principles, main features, and advantages of this invention. Those skilled in the art should understand that this invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of this invention. Various changes and modifications may be made to this invention without departing from its spirit and scope. All such changes and modifications fall within the scope of this invention as defined by the appended claims and their equivalents.

Claims

1. A glass container for edible fungi, characterized in that: The system includes a frame (1), on which a wall (2) is installed. A box is formed between the frame (1) and the wall (2). Multiple sliding glass doors (3) are slidably installed on the front and rear sides of the box. A planting rack (4) is fixedly installed inside the box. Planting trays (5) for edible fungi cultivation are arrayed and slidably attached to the planting rack (4). The number of the multiple sliding glass doors (3) is the same as the number of the horizontally distributed planting trays (5). An adjustment cabinet (6) is fixedly installed on one side of the frame (1). A connecting pipe (7) is fixedly installed at the air outlet of the adjustment cabinet (6). The other end of the connecting pipe (7) is connected to the upper side of the box.

2. The mushroom glass material box according to claim 1, characterized in that: The frame (1) is made of aluminum alloy, and the wall (2) is made of double-layer hollow glass, with the outer layer being tempered glass and the inner layer being dimming glass, and inert gas filling the space between the two layers of glass.

3. The mushroom glass material box according to claim 2, characterized in that: The regulating cabinet (6) is used to regulate the temperature, humidity and carbon dioxide concentration inside the box, and the regulating cabinet (6) electrically controls the dimming glass in the wall (2).

4. The mushroom glass material box according to claim 1, characterized in that: The planting racks (4) are arranged in an array with support plates (8), and the planting trays (5) are slidably attached to the support plates (8).

5. The mushroom glass material box according to claim 4, characterized in that: The bearing plate (8) has ball bearings (9) mounted in an array on both sides, and the planting tray (5) is engaged with the ball bearings (9) on both sides.

6. The mushroom glass material box according to claim 4, characterized in that: The support plate (8) has pin holes (10) at the middle of both sides. An electromagnet (11) is fixedly installed at the lower end of the pin hole (10). Pin plates (12) are slidably inserted into the middle of both ends of the planting tray (5). The pin plates (12) are inserted into the inside of the pin holes (10).

7. The glass container for edible fungi according to claim 6, characterized in that: The planting tray (5) has through holes (13) on both sides, and the pin plate (12) is inserted into the through holes (13). The pin plate (12) is made of magnetic metal.

8. The glass container for edible fungi according to claim 7, characterized in that: Handles (14) are fixedly installed on both ends of the planting tray (5). Guide posts (15) are fixedly installed on the inner side of the handles (14), and the lower end of the guide posts (15) is inserted into the pin plate (12). A spring (16) is fixedly installed on the lower inner end of the handles (14) outside the guide posts (15). The lower end of the spring (16) is fixedly connected to the upper end of the pin plate (12).