A granary partitioned storage management and control integrated system

The modularly designed integrated grain silo storage and control system solves the problems of poor gas diffusion and low control precision, achieving precise temperature control and uniform ventilation inside the grain silo, reducing maintenance costs, and improving the safety and environmental friendliness of grain storage.

CN118648449BActive Publication Date: 2026-07-07HENAN AIFUSHENG TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
HENAN AIFUSHENG TECH CO LTD
Filing Date
2024-08-08
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing grain silo structures suffer from poor gas diffusion, inaccurate exhaust control, and high maintenance costs in terms of internal temperature control, internal ventilation, and insecticidal gas injection.

Method used

The modular grain storage and management system includes a support module, a temperature control module, and an air box module. The zoning module is composed of components such as columns, support bases, fixed bases, and pipes, which enables precise airflow control and uniform ventilation. It is combined with a temperature monitoring module and control valves for intelligent management.

Benefits of technology

It enables precise temperature control inside the grain warehouse, reduces the risk of grain mold and pests, reduces losses and pollution, and improves the system's flexibility and scalability, which is in line with the environmental protection concept of green warehousing.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application relates to a granary partition storage, management and control integrated system which comprises a supporting module, a temperature control module and a wind box module, the supporting module, the temperature control module and the wind box module are combined together to form a partition module; the partition module is combined together along a circumference to form a circular granary main body; the supporting module comprises a stand, a supporting seat and a fixing seat; the temperature control module comprises a pipeline, an air inlet module, an air outlet module and a control valve; a plurality of branch pipes which are in communication with the inside of the pipeline are distributed in the pipeline in a vertical direction, the two ends of the pipeline are connected with the air inlet module and the air outlet module through air pipes and the control valve, the wind box module comprises a plurality of wind box units which are adaptively spliced along the pipeline direction, the wind box unit comprises a box body, a butt joint pipe, a connecting rod, a supporting frame and a mesh plate; each module of the application can be independently manufactured, installed and maintained, the construction difficulty and cost are reduced, the modular design improves the flexibility and expandability of the system, uniform ventilation in the granary is realized, and grain mildewing and insect damage are effectively prevented.
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Description

Technical Field

[0001] This invention relates to the field of grain storage technology, specifically to an integrated system for zoned storage and control of grain storage. Background Technology

[0002] Food security is a global concern, and it is particularly crucial for my country, as a populous nation, a stable food supply is the cornerstone of all national development. Food security involves multiple aspects, including the economy, people's livelihoods, development, and security. With the increasing demand for green food and the improvement of people's living standards, my country has made significant progress in green grain storage technology, reflecting a high degree of importance attached to food quality and safety.

[0003] Traditional grain silo ventilation systems are open, lowering the temperature by introducing outside air to exchange matter and energy with the grain pile. However, this method may struggle to precisely control the grain pile temperature when ambient temperature changes, and it also lacks energy efficiency and environmental friendliness. Grain storage technology is shifting from traditional conventional storage to more advanced temperature-controlled storage methods such as low-temperature and near-low-temperature storage to better maintain grain quality. Currently, grain silo temperature control largely relies on manual monitoring and adjustment, which suffers from problems such as slow response, high labor intensity, significant energy waste, and environmental impact.

[0004] Existing technology, such as the invention patent with patent number 201910121710.2, discloses a novel zero-loss ventilation system for grain silos, belonging to the technical field of grain silo constant temperature control systems. This invention aims to solve the problem of existing open ventilation systems significantly reducing grain yield. The invention includes a grain silo installed on the ground plane. The outer wall of the grain silo is equipped with an external cooling pipe and a ground cooling pipe. The upper end of the outer wall of the grain silo has an upper ground cooling outlet and an upper external cooling outlet, and the lower end of the outer wall has a lower external cooling outlet. The upper and lower ends of the external cooling pipe are connected to the upper and lower external cooling outlets, respectively. One end of the ground cooling pipe is connected to the upper ground cooling outlet, and the other end of the ground cooling pipe extends below the ground plane to form a "U-shaped pipe" before exiting the ground plane and connecting to the external cooling pipe. A first fan is installed at the bottom end of the external cooling pipe.

[0005] In summary, existing grain silo structures suffer from poor gas diffusion, inaccurate exhaust and ventilation control, and high maintenance costs in areas such as internal temperature control, ventilation, and insecticidal gas injection. Therefore, it is necessary to research an integrated zoned storage and management system for grain silos. Summary of the Invention

[0006] Therefore, the purpose of this invention is to provide an integrated system for zoned storage and management of grain warehouses, which effectively solves the problems of poor gas diffusion, poor accuracy of exhaust and ventilation control, and high maintenance costs in existing grain warehouses in terms of internal temperature control, internal ventilation, and insecticidal gas injection.

[0007] To achieve the above objectives, the technical solution adopted by the present invention is: an integrated system for zoned storage and control of grain warehouses, comprising a support module, a temperature control module, and a bellows module, wherein the support module, temperature control module, and bellows module are combined together to form a zoned module; the zoned modules are combined together along the circumference to form a circular grain warehouse body;

[0008] The support module includes a column, a support base, and a fixed base; the column is continuous in the vertical direction and its bottom is fixed to the bottom of the grain silo; the support base is fixed to the column at intervals in the vertical direction, and a groove and a side plate are formed in the middle and on both sides of the support base, respectively.

[0009] The temperature control module includes a pipe, an air intake module, an exhaust module, and a control valve. The pipe is fitted into the groove, and the pipe has multiple branch pipes that communicate with the interior at vertical intervals. The fixing seat has through holes to avoid the branch pipes. The fixing seat is fitted onto the outside of the pipe and combined with the support seat to clamp the pipe between the support seat and the fixing seat. The two ends of the pipe are connected to the air intake module and the exhaust module via air pipes and the control valve, respectively.

[0010] The bellows module includes multiple bellows units that are adapted and spliced ​​along the pipeline direction. Each bellows unit includes a box body, a connecting pipe, a connecting rod, a support frame, and a mesh plate. The box body is hollow inside, and a connecting pipe communicating with its interior is fixed in the central area of ​​its back side. The connecting rod is fixed to the back side of the box body and can be fixedly assembled on the side plate. At this time, the connecting pipe is connected to the branch pipe, so that the interior of the box body is connected to the pipeline. The support frame is assembled inside the box body, and the mesh plate is fixedly snapped into the front opening of the box body and supported by the support frame.

[0011] Furthermore, the column has a U-shaped structure, and the support base includes a connecting block and a side plate. The connecting block is adapted to be installed in the U-shaped structure, and an arc-shaped groove is provided on its front side. The side plate is located on both sides of the connecting block and extends to both sides of the column. A connecting hole is provided on the side plate, and the connecting rod is adapted to be installed in the connecting hole and fastened with a nut.

[0012] Furthermore, the shapes of the fixing seat and the support seat are adapted to each other, and after assembly, they form a pipe clamp to attach the pipe to the column.

[0013] Furthermore, the connecting rod is a screw rod with an inner nut and an outer nut. The fixing seat is assembled on the support seat and has a corresponding connecting hole. The connecting rod is fitted into the connecting hole, with the inner nut and the outer nut on both sides of the connecting hole, so as to realize the clamping of the pipe and the fixing of the box.

[0014] Furthermore, the outer end of the connecting rod passes through the housing and a combination sleeve is provided at its end, and the support frame is fixed inside the combination sleeve.

[0015] Furthermore, the mesh plate is snapped into the opening of the box, and a grid-like support is provided on the support frame, which is adapted to the back of the mesh plate.

[0016] Furthermore, the connecting pipe is provided with a mating groove that is adapted to the sealing of the branch pipe, and a sealing gasket is provided in the mating groove.

[0017] Furthermore, the exhaust module includes an exhaust pipe and an exhaust device; the exhaust pipe is distributed in a ring at the upper part of the pipeline and is connected to the pipelines distributed circumferentially on the circumference of the grain silo through an upper distribution pipe and an upper control valve, respectively; the air intake module includes an air intake pipe and an air intake device; the air intake pipe is distributed in a ring at the lower part of the pipeline and is connected to the pipelines distributed circumferentially on the circumference of the grain silo through a lower distribution pipe and a lower control valve, respectively.

[0018] Furthermore, the intake pipe includes multiple slit pipes, each slit pipe having one or more air inlets, and the lower control valve and upper control valve are wireless control valves.

[0019] Furthermore, the edge of the bellows module and the center of the grain silo form a partition, and a temperature monitoring module is vertically arranged in the center of the partition.

[0020] Furthermore, adjacent columns are connected by reinforcing frames to form the main support structure.

[0021] The beneficial effects of the above technical solution are as follows: The present invention optimizes and improves the structure of a cylindrical grain silo. Structurally, it includes a support module, a temperature control module, and a bellows module combined together to form a partitioned module. The partitioned modules are combined along the circumference to form a circular grain silo body. The edge of the bellows module and the center of the grain silo form a partition. A temperature monitoring module is vertically arranged at the center of the partition. In this structure, multiple independently operating temperature control modules are distributed on the circumference of the grain silo body. The temperature of the partition is obtained through temperature sensors, and the partition is adaptively operated, such as by evacuating or inleting air, to adjust the internal temperature of the partition.

[0022] Structurally, this invention uses a column as a fixed foundation and sets a support on the column. The fixed base and the support base are used to reinforce the pipeline, so that a pipeline is arranged vertically on the column. At the same time, the bellows is connected to the support base to realize the internal connection between the bellows and the pipeline. When the air is being introduced, the airflow can be diffused through the bellows structure, which increases the diffusion effect of the airflow. When the air is being exhausted, the exhaust range can be expanded through the bellows, so that the air intake and exhaust can better cover the grain silo.

[0023] The present invention achieves air intake and exhaust through a single pipe. By setting a switching valve at the end of the pipe, one end of the pipe can be selectively closed while the other end is open, or vice versa, allowing for switching of the pipe's operating mode. In other words, during implementation, the present invention can provide exhaust or intake operations within a zone according to actual needs, thus enabling better control of the internal temperature of the grain silo.

[0024] This invention employs a modular design, including a support module, a temperature control module, and a bellows module. Each module can be independently manufactured, installed, and maintained, significantly reducing construction difficulty and costs. Simultaneously, the modular design enhances the system's flexibility and scalability. The temperature control module, through the precise coordination of pipes, an intake module, an exhaust module, and control valves, achieves accurate temperature control within the grain silo. The bellows module, using bellows units spliced ​​along the pipe direction, achieves uniform ventilation within the grain silo, effectively preventing grain mold and pests. Through precise temperature control and ventilation management, the system reduces grain loss and contamination, aligning with the environmental protection concept of green warehousing and providing an efficient, convenient, and environmentally friendly solution for grain storage management. Attached Figure Description

[0025] Figure 1 This is a three-dimensional structural diagram of the present invention;

[0026] Figure 2 for Figure 1 A top-view structural diagram;

[0027] Figure 3 for Figure 2 Cross-sectional view along the AA direction;

[0028] Figure 4 This is a schematic diagram of the main structure of the present invention;

[0029] Figure 5 for Figure 4 Cross-sectional view along the BB direction;

[0030] Figure 6 This is a schematic diagram of the reinforcement structure for the column;

[0031] Figure 7 This is a schematic diagram of the implementation structure of the partition module;

[0032] Figure 8 This is a schematic diagram of the partition module from another perspective.

[0033] Figure 9 This is a schematic diagram of the internal structure of the bellows unit;

[0034] Figure 10 This is a schematic diagram of the partitioning;

[0035] Figure 11 This is a schematic diagram of the implementation structure of the temperature control module.

[0036] Reference numerals: 1-Column, 2-Support base, 21-Connecting block, 22-Side plate, 23-Arc-shaped groove, 24-Fixed column, 3-Pipe, 31-Branch pipe, 4-Fixed base, 5-Box body, 6-Connecting rod, 7-Connecting pipe, 8-Sealing gasket, 9-Support frame, 10-Mesh plate, 11-Reinforcing frame, 12-District, 13-Temperature monitoring module, 14-Control valve, 141-Upper control valve, 142-Lower control valve, 15-Main pipe, 151-Exhaust pipe, 152-Intake pipe, 16-Upper distribution pipe, 17-Lower distribution pipe. Detailed Implementation

[0037] The present invention will be further described in detail below with reference to the accompanying drawings and specific embodiments:

[0038] Example 1: This example aims to provide an integrated system for zoned storage and control of grain silos. It is mainly used for circular grain silo structures. Existing circular grain silo structures only have air pipes on their sides. However, this structure has poor air diffusion and the air pipes have a single function. As a result, there are problems such as poor gas diffusion, poor air extraction and exhaust control accuracy, and high maintenance costs in terms of internal temperature control, internal ventilation, and insecticidal gas injection. Based on this, this example provides an integrated system for zoned storage and control of grain silos.

[0039] like Figure 1-6 As shown, an integrated system for zoned storage and control of grain silos includes a support module, a temperature control module, and a bellows module. In this embodiment, the support module provides a supporting foundation and a positional and fixing foundation for other components. The temperature control module provides airflow and provides airflow-driven temperature control within the grain silo. The bellows module disperses and converges the airflow to ensure effective airflow dispersion. Through the cleverly designed support module, temperature control module, and bellows module, this system achieves precise control of the internal environment of the grain silo and improves storage efficiency.

[0040] Structurally, this embodiment combines the support module, temperature control module, and bellows module into a partitioned module configuration. See the appendix for details of the partitioned module. Figure 7-8As shown, the partition module is an independent structure, arranged vertically with an inner arc-shaped structure. The partition modules are assembled around the circumference to form the main body of the circular grain silo. This embodiment adopts a modular design, including a support module, a temperature control module, and a bellows module. These modules can be independently manufactured, installed, and maintained, greatly reducing construction difficulty and cost. At the same time, the modular design also improves the system's flexibility and scalability.

[0041] In the specific structure, the support module includes a column 1, a support base 2, and a fixing base 4; the column 1 is continuous vertically and its bottom is fixed to the bottom of the grain silo; the support base 2 is fixed vertically at intervals on the column 1, and a groove and a side plate are formed in the middle and on both sides of the support base 2 respectively; structurally, the column 1 is limited from the outside and forms a support foundation, the support base 2 is distributed at intervals, and multiple fixed points are formed at intervals on the column 1. Adjacent columns 1 are connected by a reinforcing frame assembly 11 to form the main support body to ensure the overall structural strength.

[0042] The temperature control module includes pipe 3, air intake module, exhaust module and control valve; in this embodiment, pipe 3 is a circular pipe structure, pipe 3 is fitted into the groove and limited from the inside by the groove, pipe 3 has multiple branch pipes that are connected to its interior at intervals along the vertical direction, the branch pipes can be integrated with pipe 3 and face outwards. In this embodiment, pipe 3 is used as the main airflow channel, and multiple branch pipes are formed by the branch pipes to divert the airflow.

[0043] The fixed seat 4 has a through hole to avoid the branch pipe. The fixed seat 4 is fitted and sleeved on the outside of the pipe 3 and combined with the support seat 2 to clamp the pipe 3 between the support seat 2 and the fixed seat 4. In this embodiment, the pipe 3 is limited on the column 1 by the combination structure of the fixed seat 4 and the support seat 2, and the structure forms an outward branch pipe structure to facilitate docking with the bellows module.

[0044] Pipeline 3 is connected to the air intake module and the air exhaust module at both ends via air pipes and control valve 14, respectively. The temperature control module, through the precise coordination of pipeline 3, the air intake module, the air exhaust module, and the control valve, achieves accurate temperature control inside the grain silo. The bellows module, through bellows units spliced ​​along pipeline 3, achieves uniform ventilation inside the grain silo, effectively preventing grain mold and pests. The application of intelligent devices such as control valves and temperature monitoring modules enables intelligent control of the grain silo's internal environment. This not only saves labor costs but also improves the accuracy and efficiency of control.

[0045] In the specific structure, the bellows module includes multiple bellows units that are adapted and spliced ​​along the direction of the pipe 3. Structurally, the bellows units correspond one-to-one with the branch pipes and are assembled one by one on the column 1 along the vertical direction. The bellows module, the corresponding pipe 3, the support seat 2 of the column 1 and the fixing seat 4 constitute a standard component. The standard component is assembled to form a circular grain silo structure.

[0046] Structurally, the bellows unit includes a box body 5, a connecting pipe 7, a connecting rod 6, a support frame 9, and a mesh plate 10. The box body 5 is hollow inside, and a connecting pipe 7 communicating with its interior is fixed in the middle area of ​​its back side. The connecting pipe 7 is provided with a mating groove that is sealed and adapted to the branch pipe 31. A sealing gasket 8 is provided in the mating groove. The sealing gasket 8 provided in the connecting pipe 7 ensures the sealing and adaptation between the mating groove and the branch pipe, effectively preventing energy loss during transmission and improving the energy efficiency of the system.

[0047] In order to achieve the connection of the housing 5 and provide active driving force for the docking of the connecting pipe 7 and the branch pipe, the connecting rod 6 is fixed on the back side of the housing 5 and can be fixedly assembled on the side plate. At this time, the connecting pipe 7 and the branch pipe are connected together, so that the inside of the housing 5 is connected to the pipe 3. The function of the connecting rod 6 is to fix the housing 5 on the support base 2 and provide sealing force for the docking of the connecting pipe 7 and the branch pipe. In implementation, four connecting rods 6 can be configured to ensure structural strength.

[0048] The support frame 9 is assembled inside the box 5. The mesh plate 10 is fixedly clipped to the front opening of the box 5 and supported by the support frame 9. The mesh plate 10 is clipped to the opening of the box 5. The support frame 9 is provided with a grid-like support body, which is adapted to the back of the mesh plate 10. The mesh plate 10 has an overall arc-shaped structure and mesh holes. Grain cannot pass through, but airflow can pass through freely. In this embodiment, the contact area between the branch pipe and the grain bin can be enlarged through the structure of the box 5. When exhausting gas outward, it has a larger exhaust area, and when gas enters, it also has a larger injection area.

[0049] In this embodiment, during operation, the switching valve at one end of pipe 3 is opened, while the switching valve at the other end is closed, allowing any pipe 3 to have both exhaust and intake modes. This operating mode can be adjusted by rotating the corresponding pipe 3 as needed, such as alternately exhausting and intake, with one side of pipe 3 intake and the opposite side exhausting. Switching between modes is convenient, and the appropriate operating mode can be selected adaptively based on the specific conditions of the grain silo. For example, if mold appears in a portion, the affected area is first ventilated, and then inert gas is injected for protection. The temperature and concentration of the injected gas can be adjusted, such as by adding insect repellent. Alternatively, pipe 3 can be divided into two parts during operation, one for exhaust and the other for intake, achieving overall ventilation of the grain silo and ensuring airflow.

[0050] Therefore, the operating mode of this embodiment is easily adjustable, allowing switching between appropriate modes as needed. This constructs a comprehensive and balanced ventilation system within the grain warehouse, enabling precise control of the grain storage environment. This system not only significantly reduces the risk of grain mold and pests but also greatly minimizes grain loss and potential contamination caused by poor storage conditions. It is easy to operate and has low maintenance costs, providing warehouse management personnel with an unprecedentedly convenient experience. It completely transforms the inefficient traditional warehousing model, which relies on manual experience and frequent inspections, into a data-driven intelligent management system that significantly improves work efficiency and accuracy, making a vital contribution to food security and agricultural modernization.

[0051] Example 2 further illustrates the installation structure of the support module.

[0052] In this embodiment, the column 1 has a U-shaped structure, and the support base 2 includes a connecting block 21 and a side plate 22. The connecting block is adapted to be installed in the U-shaped structure, and an arc-shaped groove 23 is provided on its front side. The side plate 22 is located on both sides of the connecting block 21 and extends to both sides of the column 1. A connecting hole is provided on the side plate, and the connecting rod 6 is adapted to be installed in the connecting hole and fastened by a nut. The fastening of the nut provides a locking force.

[0053] Structurally, a fixing post 24 is provided on the rear side of the connecting block 21. The post 24 is provided with a fixing hole. The fixing post passes through the fixing hole and is fixed by applying a nut from the back side of the post.

[0054] The fixed base 4 and the support base 2 are shaped to fit each other and form a pipe clamp after assembly, which attaches the pipe 3 to the column 1. During implementation, the fixed base 4 can be fixed to the side plate. If bolts are added, it can also be temporarily limited. Secondary fixation is achieved using the connecting rod 6. During implementation, the connecting rod 6 is a screw rod with an inner nut and an outer nut. The fixed base 4 is assembled on the support base 2 and has corresponding connecting holes. The connecting rod 6 is fitted into the connecting holes, with the inner and outer nuts on both sides of the connecting holes, thus achieving the clamping of the pipe 3 and the fixation of the box 5. That is, the fixed base 4 can be limited by the connecting rod 6, and the double nuts are used for locking, thus achieving the fastening of the box 5 and the fixed base 4.

[0055] The outer end of the connecting rod 6 passes through the housing 5 and a combination sleeve is provided at its end. The support frame 9 is fixed inside the combination sleeve. Structurally, the combination sleeve and the connecting rod 6 can be an interference fit structure to realize the snack positioning of the support frame 9, or a rotatable structure with movable limit, which is connected by threads.

[0056] The support module consists of a U-shaped column 1, a matching and snap-fit ​​support base 2, a fixing base 4, and a reinforcing frame, forming a stable support structure that ensures the structural stability and load-bearing capacity of the entire grain storage system.

[0057] Example 3 further illustrates the implementation structure of the temperature control module.

[0058] In this embodiment, as shown Figure 10-11 As shown, the main pipe 15 connects to each pipe 3 via control valve 16 and branch pipes to achieve the function of airflow distribution. The specific exhaust module includes an exhaust pipe 151 and an exhaust device. The exhaust pipe 151 is distributed in a ring at the upper part of the pipe 3 and is connected to the pipes 3 distributed circumferentially on the circumference of the grain silo via the upper distribution pipe 16 and the upper control valve 141, respectively. The air intake module includes an air intake pipe 152 and an air intake device. The air intake pipe 152 is distributed in a ring at the lower part of the pipe 3 and is connected to the pipes 3 distributed circumferentially on the circumference of the grain silo via the lower distribution pipe 17 and the lower control valve 142, respectively.

[0059] like Figure 4 and Figure 10 As shown, the air intake pipe includes multiple sections, each with one or more air inlets. The lower and upper control valves are wireless control valves. In a specific implementation, the air intake pipe is arranged in a ring and positioned on the outer side of pipe 3. The air intake pipe includes two semicircular pipes, the ends of which are closed and each has two air inlets. Of course, in practice, the number of sections of the air intake pipe can be increased according to the radius of the grain silo, and multiple air inlets can be configured on each section to increase the air intake volume and pressure, and to adjust the intensity and amount of gas injection.

[0060] In practice, the control valve is a wireless control valve, and the power required by the equipment is supplied by a solar power generation system configured on the top or side of the grain silo. In addition, the number of pipes 3 in this embodiment can be appropriately increased or decreased according to the actual situation.

[0061] A partition 12 is formed by connecting the edge of the bellows module with the center of the grain silo. A temperature monitoring module 13 is vertically positioned at the center of partition 12 to monitor the temperature of the partition. In this embodiment, the support module, temperature control module, and bellows module are combined to form a partition module. The partition modules are assembled around the circumference to form a circular grain silo body. The edge of the bellows module is connected with the center of the grain silo to form a partition 12. A temperature monitoring module is vertically positioned at the center of partition 12. In this structure, multiple independently operating temperature control modules are distributed around the circumference of the grain silo body. The temperature of the partition is obtained through temperature sensors, and the partition is adjusted accordingly, such as by evacuating or inleting air, to regulate the internal temperature of the partition.

[0062] The edges of the bellows module are connected to the center of the grain silo to form zones 12. Each zone 12 is equipped with a temperature monitoring module 13, enabling zoned management of the grain silo's internal environment. This management method not only improves storage efficiency but also facilitates the classification, storage, and monitoring of grain. The system integrates advanced sensing technology and automated control logic, enabling real-time sensing of temperature and humidity changes in different areas of the grain silo. Since each pipe 3 can be independently controlled, the system automatically adjusts the ventilation intensity and frequency accordingly, ensuring that grain in every corner enjoys a suitable and uniform storage environment. This improves the freshness and long-term storage stability of the grain, effectively promoting the efficient use of resources and sustainable environmental protection, representing a significant advancement in the field of grain storage management.

[0063] The embodiments of the present invention described above do not constitute a limitation on the scope of protection of the present invention. The basic concept of the present invention is that each module can be independently manufactured, installed, and maintained. The modular design also improves the flexibility and scalability of the system, realizes precise control of the internal temperature of the grain warehouse, effectively prevents grain mold and pests, and reduces grain loss and contamination. Any modifications, equivalent substitutions, and improvements made within the spirit and principles of the present invention should be included within the scope of protection of the claims of the present invention.

Claims

1. A grain warehouse zoned storage and control integrated system, characterized in that: It includes a support module, a temperature control module, and a bellows module, which are combined together to form a partitioned module; The partitioned modules are assembled along the circumference to form the main body of the circular grain silo; The support module includes a column, a support base, and a fixed base; the column is continuous in the vertical direction and its bottom is fixed to the bottom of the grain silo; the support base is fixed to the column at intervals in the vertical direction, and a groove and a side plate are formed in the middle and on both sides of the support base, respectively. The temperature control module includes a pipe, an air intake module, an exhaust module, and a control valve. The pipe is fitted into the groove, and the pipe has multiple branch pipes that communicate with the interior at vertical intervals. The fixing seat has through holes to avoid the branch pipes. The fixing seat is fitted onto the outside of the pipe and combined with the support seat to clamp the pipe between the support seat and the fixing seat. The two ends of the pipe are connected to the air intake module and the exhaust module via air pipes and the control valve, respectively. The bellows module includes multiple bellows units that are adapted and spliced ​​along the pipeline direction. Each bellows unit includes a box body, a connecting pipe, a connecting rod, a support frame, and a mesh plate. The box body is hollow inside, and a connecting pipe communicating with its interior is fixed in the central area of ​​its back side. The connecting rod is fixed to the back side of the box body and can be fixedly assembled on the side plate. At this time, the connecting pipe is connected to the branch pipe, so that the interior of the box body is connected to the pipeline. The support frame is assembled inside the box body, and the mesh plate is fixedly snapped into the front opening of the box body and supported by the support frame. The column has a U-shaped structure. The support base includes a connecting block and a side plate. The connecting block is adapted to be installed in the U-shaped structure. An arc-shaped groove is provided on its front side. The side plate is located on both sides of the connecting block and extends to both sides of the column. A connecting hole is provided on the side plate. The connecting rod is adapted to be installed in the connecting hole and fastened with a nut. The fixed base and the support base are adapted to each other in shape and form a pipe clamp after assembly, which assembles the pipe onto the column. The connecting rod is a screw rod with an inner nut and an outer nut. The fixing seat is assembled on the support seat and has a corresponding connecting hole. The connecting rod is fitted into the connecting hole, with the inner nut and the outer nut on both sides of the connecting hole, so as to realize the clamping of the pipe and the fixing of the box. The outer end of the connecting rod passes through the box and a combination sleeve is provided at its end, and the support frame is fixed inside the combination sleeve.

2. The integrated grain storage and management system according to claim 1, characterized in that: The mesh plate is snapped into the opening of the box, and a grid-like support is provided on the support frame, which is adapted to the back of the mesh plate.

3. The integrated grain storage and management system according to claim 1, characterized in that: The connecting pipe is provided with a mating groove that is compatible with the sealing of the branch pipe, and a sealing gasket is provided in the mating groove.

4. The integrated grain storage and management system according to claim 1, characterized in that: The exhaust module includes an exhaust pipe and an exhaust device; the exhaust pipe is distributed in a ring at the upper part of the pipeline and is connected to the pipelines distributed circumferentially around the grain silo through an upper distribution pipe and an upper control valve, respectively. The air intake module includes an air intake pipe and an air intake device; the air intake pipe is distributed in a ring at the lower part of the pipeline and is connected to the pipelines distributed circumferentially around the grain silo through a lower distribution pipe and a lower control valve, respectively.

5. The integrated grain storage and management system according to claim 4, characterized in that: The air intake pipe includes multiple air sections, each with one or more air inlets. The lower control valve and the upper control valve are wireless control valves.

6. The integrated grain storage and management system according to claim 1, characterized in that: The edge of the bellows module and the center of the grain silo form a partition, and a temperature monitoring module is set vertically at the center of the partition.