Grain storage tank
By combining the dispensing and control sections of the grain storage bin, the problem of cumbersome and laborious steps in retrieving rice from existing rice bins is solved, achieving convenience and flexibility in retrieving rice from the cabinet with one hand.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- YIWU ZHAISHANG HOUSEHOLD PROD CO LTD
- Filing Date
- 2025-08-12
- Publication Date
- 2026-07-14
AI Technical Summary
Existing rice buckets are cumbersome in design, making it difficult to take out rice. They are especially inconvenient to use in kitchen cabinets as they are laborious and prone to tipping over.
Design a grain storage bin that adopts a combined structure of a discharge section and a control section. By operating the discharge section with one hand and coordinating with the control section, the discharge port and the inlet can be connected or disconnected, simplifying the material handling process.
It enables one-handed material retrieval within the cabinet, simplifying steps, saving time and effort, improving operational convenience, and supporting flexible retrieval requirements to adapt to different containers.
Smart Images

Figure CN224492210U_ABST
Abstract
Description
Technical Field
[0001] This application belongs to the field of storage container technology, and specifically relates to a grain storage bin. Background Technology
[0002] Most existing rice containers have a top-opening lid design, requiring users to open the lid to take out the rice and then close it again, a cumbersome process. Furthermore, rice containers are often placed inside cabinets, but due to space limitations, removing the container from the cabinet before opening the lid and taking out the rice further complicates the process. In addition, when the rice container is full or heavy, pulling it out is very strenuous and difficult to control, easily leading to the container tipping over and spilling, causing considerable inconvenience to users. Utility Model Content
[0003] The purpose of this application is to address the aforementioned problems in the prior art by providing a grain storage bin with simple operation steps and convenient material discharge.
[0004] This application provides a grain storage bin, including a bin body and a discharge structure. The bin body includes a bottom wall and a peripheral wall. The peripheral wall is arranged around the outer periphery of the bottom wall to form a receiving space together with the bottom wall. The bottom wall has a first outlet communicating with the receiving space. The discharge structure is located outside the receiving space and includes a discharge section and a control section. The discharge section has an inlet and an outlet. The discharge section is rotatably connected to the side of the bottom wall opposite to the peripheral wall, and the inlet communicates with the first outlet. As the discharge section rotates, the outlet can selectively rotate out of or back into the orthogonal projection range of the bottom wall. The control section is movably connected to the discharge section to control the connection or disconnection of the inlet and the outlet.
[0005] In some embodiments, the discharge section includes a bottom plate, a side plate, a top plate, and a first baffle. The side plate is connected between the bottom plate and the top plate to form a storage space together with the bottom plate and the top plate. The first baffle is connected to the side plate and located between the top plate and the bottom plate to divide the storage space into a first storage space and a second storage space. The top plate has an inlet communicating with the first storage space, and the bottom plate has an outlet communicating with the second storage space. A gap is formed between the first baffle and the bottom plate, and the first storage space communicates with the second storage space through the gap. The control unit is movably connected to the discharge section to seal or unseal the gap.
[0006] In some embodiments, the control unit includes a button and a second baffle connected to the button. The horizontal projection of the second baffle is located within the range of the horizontal projection of the discharge port. The top plate also has an opening communicating with the second storage space. The button is movably disposed in the second storage space through the opening, and the side of the button away from the second baffle is exposed to the opening. The second baffle is movably disposed in the second storage space along with the button to selectively block or unblock the gap.
[0007] In some embodiments, the button portion includes a button, a connecting portion, and an elastic portion. The button is exposed in the opening. The connecting portion includes a connecting plate and a sliding portion disposed on the connecting plate. The connecting plate is connected between the button and the second baffle. The second storage space is provided with a mating portion that cooperates with the sliding portion and a mating plate that cooperates with the elastic portion. The sliding portion is slidably connected to the mating portion, and the elastic portion abuts against the button and the mating plate.
[0008] In some embodiments, the discharge section further includes a limiting plate located in the second storage space. The limiting plate is connected to at least one of the top plate, the side plate, and the bottom plate. The limiting plate is disposed opposite to the first baffle and together with the first baffle forms a channel communicating with the opening and the discharge port. The mating part is disposed between the limiting plate and the first baffle or at least one of the limiting plate, the first baffle, and the side plate. The mating plate is disposed at least one of the limiting plate, the first baffle, and the side plate.
[0009] In some embodiments, the discharge structure further includes a pulley disposed on the side of the bottom plate opposite to the top plate.
[0010] In some embodiments, the base plate is an inclined surface that slopes from the feed inlet toward the gap direction.
[0011] In some embodiments, the grain storage hopper further includes a support structure, the support structure including a top support surface and a first side support surface, the first side support surface being arranged around the outer periphery of the top support surface, a groove being formed on one side of the first side support surface, the top support surface having a second outlet communicating with the groove, the bottom wall being connected to the top support surface on the side away from the peripheral wall, and the first outlet communicating with the second outlet, the second outlet also communicating with the feed inlet, the discharge part being rotatably connected to the top surface of the groove, so that the discharge structure can be movably accommodated in the groove.
[0012] In some embodiments, the support structure further includes a second support side surface, which is arranged around the outer periphery of the top support surface, and the second support side surface and the second support side are respectively located on both sides of the top support surface, and the second support side surface is connected to the peripheral wall.
[0013] In some embodiments, the support structure further includes a support bottom surface connected to the first support side surface and disposed opposite to the support top surface, wherein the groove is located between the support top surface and the support bottom surface.
[0014] In some embodiments, the bottom wall includes a plurality of inclined plates connected to each other, each of the inclined plates being inclined from the end away from the first outlet toward the end of the first outlet.
[0015] In some embodiments, the grain storage bin further includes a lid that is movably positioned over the side of the peripheral wall away from the bottom wall.
[0016] In summary, in some embodiments of this application, the grain storage bin utilizes a rotatable discharge section. Users only need to rotate the discharge section with one hand to extend the discharge port beyond the projected area of the bottom wall, and then continue operating the control unit with one hand to connect the inlet and outlet. The material stored in the receiving space will then be sequentially retrieved through the first outlet, inlet, and outlet. After retrieval, the user simply needs to rotate the discharge section to reset it. Therefore, even when the grain storage bin is placed in a cabinet, the user only needs to rotate the discharge section with one hand to extend the discharge port outside the cabinet, completing retrieval in place without dragging the grain storage bin. This significantly simplifies the process, saves time and effort, and the entire retrieval and reset process is done with one hand, completely freeing up the other hand and significantly improving operational convenience. Furthermore, the method of discharging using the discharge section and control unit is more compatible, no longer limited to the fixed container provided with the product. Users can choose any container at home to collect the material, flexibly meeting personalized retrieval needs, achieving a triple breakthrough in space adaptability, operational convenience, and retrieval flexibility. Attached Figure Description
[0017] Figure 1 This is a schematic diagram of the structure of a grain storage bin in one state according to some embodiments of this application.
[0018] Figure 2 For along Figure 1 A schematic cross-sectional view of line II is shown.
[0019] Figure 3 This is a structural schematic diagram of another state of the grain storage tank according to some embodiments of this application.
[0020] Figure 4 For along Figure 1 A schematic cross-sectional view of line II-II shown.
[0021] Figure 5 For along Figure 1 A schematic cross-sectional view of line III-III shown.
[0022] Figure 6 This is a structural schematic diagram of another state of the grain storage tank according to some embodiments of this application.
[0023] Figure 7 This is a cross-sectional schematic diagram of the discharge structure of some embodiments of this application.
[0024] Figure 8 This is a schematic diagram of the structure of the barrel according to some embodiments of this application.
[0025] Figure 9 This is an exploded view of the discharge structure of some embodiments of this application.
[0026] Figure 10 for Figure 9 The diagram shows an exploded view of the discharge structure.
[0027] Figure 11 This is a structural schematic diagram of a grain storage bin according to some other embodiments of this application.
[0028] Figure 12 This is another structural schematic diagram of a grain storage bin according to some embodiments of this application.
[0029] In the diagram, 1. Grain storage bin; 10. Bin body; 11. Bottom wall; 111. First outlet; 112. Inclined plate; 12. Peripheral wall; 13. Receiving space; 14. Lid; 141. Receiving groove; 142. Through opening; 15. Groove cover; 20. Discharge structure; 21. Discharge section; 211. Bottom plate; 212. Side plate; 213. Top plate; 2131. Opening; 214. First baffle; 215. Limiting plate; 216. Channel; 217. Handle; 22. Control section; 221. Button section; 2211. Button; 22 12. Connecting part; 2213. Elastic part; 2214. Connecting plate; 2215. Sliding part; 2216. Mounting part; 222. Second baffle; 23. Feed inlet; 24. Discharge outlet; 25. Storage space; 251. First storage space; 252. Second storage space; 26. Gap; 27. Fitting part; 28. Fitting plate; 29. Pulley; 30. Support structure; 31. Support top surface; 311. Second outlet; 32. First support side surface; 33. Groove; 34. Support bottom surface; 35. Second support side surface. Detailed Implementation
[0030] The following are specific embodiments of this application, which are described in conjunction with the accompanying drawings to further illustrate the technical solutions of this application. However, this application is not limited to these embodiments.
[0031] Reference Figures 1 to 7 , some embodiments of the present application provide a grain storage barrel 1, which includes a barrel body 10 and a discharging structure 20. The barrel body 10 includes a bottom wall 11 and a peripheral wall 12. The peripheral wall 12 is disposed around the outer periphery of the bottom wall 11 to form a receiving space 13 together with the bottom wall 11. The bottom wall 11 is provided with a first outlet 111 communicating with the receiving space 13. The discharging structure 20 is located outside the receiving space 13. The discharging structure 20 includes a discharging part 21 and a control part 22. The discharging part 21 is provided with a feeding port 23 and a discharging port 24. The discharging part 21 is rotatably connected to one side of the bottom wall 11 facing away from the peripheral wall 12, and the feeding port 23 communicates with the first outlet 111. As the discharging part 21 rotates, the discharging port 24 can be selectively rotated out of the range of the orthographic projection of the bottom wall 11 or rotated back into the range of the orthographic projection of the bottom wall 11. The control part 22 is movably connected to the discharging part 21 to control the connection or disconnection of the feeding port 23 and the discharging port 24.
[0032] It can be understood that, by means of the rotatable connection of the discharging part 21 in some embodiments of the present application, the user only needs to rotate the discharging part 21 with one hand to make the discharging port 24 rotate out of the range of the orthographic projection of the bottom wall 11, and then continue to operate the control part 22 with one hand to connect the feeding port 23 and the discharging port 24. Then, the materials stored in the receiving space 13 will sequentially pass through the first outlet 111, the feeding port 23 and the discharging port 24 to complete the material taking; and when the material taking is completed, the user only needs to rotate the discharging part 21 back to its original position with one hand. It can be seen that even if the grain storage barrel 1 is placed in a cabinet, the user only needs to rotate the discharging part 21 with one hand to make the discharging port 24 extend out of the cabinet, and the material can be taken in place without dragging the grain storage barrel 1, greatly simplifying the steps, saving time and effort, and the whole process of material taking and resetting is a single-handed operation, completely liberating the other hand, and significantly improving the operation convenience. In addition, the way of the discharging part 21 and the control part 22 cooperating for discharging has stronger compatibility and is no longer limited to the fixed containers supporting the product. The user can select any container in the home as needed to receive the materials, flexibly meeting the personalized material taking quantity requirements, and achieving triple breakthroughs in space adaptability, operation convenience and material taking flexibility.
[0033] Further, in some embodiments, reference Figure 5 , the barrel body 10 further includes a lid 14. The lid 14 is movably covered on one side of the peripheral wall 12 away from the bottom wall 11 to prevent dust and other impurities from falling into the receiving space 13 and affecting the quality of the materials stored therein. Of course, in some other embodiments, the lid 14 can be omitted.
[0034] Furthermore, a receiving slot 141 is provided on the side of the lid 14 facing away from the bottom wall 11. The receiving slot 141 has several through openings 142. The receiving slot 141 can be used to store desiccants, moisture-proof bags, etc., to ensure the quality of the stored items. It is understood that the barrel body 10 also includes a cover 15. The cover 15 is used to cover the receiving slot 141 to ensure the overall appearance of the product.
[0035] Of course, in some other embodiments, the receiving slot 141 and the slot cover 15 may be omitted.
[0036] In some implementations, the reference Figure 5 and Figure 8 The bottom wall 11 includes a plurality of interconnected inclined plates 112. Each inclined plate 112 is inclined from the end away from the first outlet 111 toward the end of the first outlet 111, so that the material contained in the receiving space 13 can automatically slide down under its own weight by means of the inclined plates 112, which facilitates material retrieval and avoids accumulation. It can be understood that the number of inclined plates 112 can be as follows: Figure 8 The quantity shown can also be three, four, five, etc., as long as the material can easily slide out of the first outlet 111. There is no limitation here.
[0037] In some implementations, please refer to Figures 3 to 10 The discharge section 21 includes a bottom plate 211, a side plate 212, a top plate 213, and a first baffle 214. The side plate 212 is connected between the bottom plate 211 and the top plate 213 to form a storage space 25 together with the bottom plate 211 and the top plate 213. The first baffle 214 is connected to the side plate 212 and is located between the top plate 213 and the bottom plate 211 to divide the storage space 25 into a first storage space 251 and a second storage space 252. The top plate 213 has an inlet 23 that communicates with the first storage space 251. The bottom plate 211 has an outlet 24 that communicates with the second storage space. A gap 26 is formed between the first baffle 214 and the bottom plate 211. The first storage space 251 communicates with the second storage space 252 through the gap 26. The control unit 22 is movably connected to the discharge section 21 to seal or unseal the gap 26. It is understandable that when materials are stored in the receiving space 13, the materials can slide out through the first outlet 111 connected to the receiving space 13 and fall into the first storage space 251 through the inlet 23. At this time, the control unit 22 is in the state of blocking the gap 26 (e.g., Figure 4 As shown), the material cannot continue to pass through the gap 26; and when the operation control unit 22 releases the gap 26 (as shown), the material cannot pass through the gap 26. Figure 7As shown), the material can continue to pass through the gap 26 into the second storage space 252 and then be discharged through the discharge port 24. Therefore, in some embodiments of this application, the grain storage hopper 1 controls material dispensing through the cooperation of the gap 26 and the control unit 22. This not only makes operation convenient but also avoids the limitation of the dispensing capacity of the fixed container provided with the product, thus meeting personalized dispensing needs.
[0038] Specifically, in some embodiments, the control unit 22 includes a button unit 221 and a second baffle 222 connected to the button unit 221. The horizontal projection of the second baffle 222 is located within the horizontal projection range of the discharge port 24. The top plate 213 also has an opening 2131 communicating with the second storage space 252. The button unit 221 is movably disposed in the second storage space 252 through the opening 2131, and the side of the button unit 221 away from the second baffle 222 is exposed to the opening 2131. The second baffle 222 is movably disposed in the second storage space 252 along with the button unit 221, so as to selectively block or unblock the gap 26. It can be seen that the grain storage tank 1 of some embodiments of this application, by controlling the pressure of the button unit 221 to control the size of the gap 26 blocked by the second baffle 222, can effectively control the discharge speed while ensuring the accuracy of material handling.
[0039] In some embodiments, the button portion 221 includes a button 2211, a connecting portion 2212, and an elastic portion 2213. The button 2211 is exposed in the opening 2131 for easy pressing. The connecting portion 2212 includes a connecting plate 2214 and a sliding portion 2215 disposed on the connecting plate 2214. The connecting plate 2214 is connected between the button 2211 and the second baffle 222. The second storage space 252 is provided with a mating portion 27 that mates with the sliding portion 2215 and a mating plate 28 that mates with the elastic portion 2213. The sliding portion 2215 is slidably connected to the mating portion 27. The elastic portion 2213 abuts against the button 2211 and the mating plate 28. It is understandable that when there is a need to retrieve material, after the user rotates the discharge section 21 so that the discharge port 24 is outside the projected range of the bottom wall 11, the user presses the button 2211 exposed at the opening 2131. The second baffle 222 connected to it is driven by the pressing of the button 2211 to open the gap 26 to realize the retrieval of material. At the same time, the elastic part 2213 gains elastic potential energy due to the pressure of the button 2211. After the retrieval is completed, after the pressing of the button 2211 is released, the elastic part 2213 releases elastic potential energy due to the loss of the pressure of the button 2211, pushing the button 2211 to reset, so as to ensure that the grain storage tank 1 can repeatedly retrieve material.
[0040] Furthermore, in some embodiments, the button 2211 has a mounting portion 2216 protruding from the side facing the mating plate 28. The mounting portion 2216 is used for mounting the elastic portion 2213 to prevent it from slipping off during use. Specifically, one end of the elastic portion 2213 is disposed on the mounting portion 2216, and the other end abuts against the mating plate 28.
[0041] In some embodiments, the discharge section 21 further includes a limiting plate 215 located in the second storage space 252, the limiting plate 215 being connected to the side plate 212. The limiting plate 215 is disposed opposite to the first baffle 214, and together with the first baffle 214 forms a channel 216 connecting the opening 2131 and the discharge port 24. A mating part 27 is disposed between the limiting plate 215 and the first baffle 214. A mating plate 28 is connected to the side plate 212 and is connected between the limiting plate 215 and the first baffle 214. It can be understood that the mating design of the limiting plate 215 and the first baffle 214 provides installation and movement space for the control section 22 while also playing a certain limiting role to ensure the use of the control section 22.
[0042] In some other embodiments, the limiting plate 215 is not limited to the position described above, and may also be provided in at least two of the top plate 213, the bottom plate 211, the top plate 213, the side plate 212, and the bottom plate 211; this is not limited here. Similarly, the mating part 27 is not limited to the position described above, and may also be provided in at least one of the limiting plate 215, the first baffle 214, and the side plate 212; this is not limited here. The mating plate 28 is also not limited to the position described above, and may also be provided in at least two of the limiting plate 215, the first baffle 214, the side plate 212, or the limiting plate 215, the first baffle 214, and the side plate 212; this is not limited here.
[0043] In some implementations, the reference Figure 4 The discharge structure 20 also includes a pulley 29. The pulley 29 is located on the side of the bottom plate 211 opposite to the top plate to reduce movement resistance during the rotation of the discharge section 21 and improve the ease of operation of the grain storage tank 1. Of course, in some other embodiments, the pulley 29 may be omitted.
[0044] In some implementations, the reference Figure 4 and Figure 7 The bottom plate 211 is an inclined surface that slopes from the feed inlet 23 toward the gap 26. In this way, after the material enters the first storage space 251 through the feed inlet 23, the material will automatically slide down to the gap 26 under its own gravity due to the inclined surface design of the bottom plate 211 and then enter the second storage space 252, and then exit from the discharge outlet 24 to complete the material retrieval. At the same time, it also effectively avoids problems such as material accumulation.
[0045] In some embodiments, the side plate 212 is also provided with a handle 217. The handle 217 is located outside the storage space 25 and is used to assist the rotation of the discharge section 21. Of course, in other embodiments, the handle 217 may be omitted.
[0046] In some implementations, the reference Figure 2 , Figure 3 , Figure 4 , Figure 5 , Figure 11 and Figure 12 The grain storage bin 1 also includes a support structure 30. The support structure 30 includes a top support surface 31 and a first side support surface 32. The first side support surface 32 is arranged around the outer periphery of the top support surface 31. A groove 33 is formed on one side of the first side support surface 32. The top support surface 31 has a second outlet 311 communicating with the groove 33. The side of the bottom wall 11 away from the peripheral wall 12 is connected to the top support surface 31, and the first outlet 311 communicates with the second outlet 311. The second outlet 311 is also connected to the feed inlet 23. The discharge part 21 is rotatably connected to the top surface of the groove 33 so that the discharge structure 20 can be movably accommodated in the groove 33. It can be understood that the support structure 30 is provided to support the bin body 10 on the one hand, and to provide storage space for the discharge structure 20 on the other hand, ensuring the overall aesthetics of the product when not in use.
[0047] Furthermore, in some embodiments, the support structure 30 further includes a second support side 35. The second support side 35 is arranged around the outer periphery of the support top surface 31, and the first support side 32 and the second support side 35 are respectively located on both sides of the support top surface 31. The second support side 35 is also connected to the peripheral wall 12 to cover the bottom wall 11, ensuring the overall aesthetics of the product. The side of the second support side 35 can be as follows: Figure 1 The rectangle shown can also Figure 12 The trapezoid shown can serve any purpose of support or shielding; there are no restrictions here.
[0048] Furthermore, in some embodiments, the support structure 30 also includes a support bottom surface 34, which serves a supporting function. The support bottom surface 34 is connected to the support side surface 32 and is disposed opposite to the support top surface 31. A groove 33 is located between the support top surface 31 and the support bottom surface 34.
[0049] The specific embodiments described herein are merely illustrative examples of the spirit of this application. Those skilled in the art to which this application pertains may make various modifications or additions to the described specific embodiments or use similar methods to substitute them, without departing from the spirit of this application or exceeding the scope defined by the appended claims.
[0050] Although this document uses a large number of technical terms, the possibility of using other terms is not excluded. These terms are used merely to facilitate the description and explanation of the nature of this application; interpreting them as any additional limitation would be contrary to the spirit of this application.
Claims
1. A grain storage silo comprising a silo body, characterised in that, The barrel body comprises a bottom wall and a peripheral wall, the peripheral wall is annularly arranged at the outer periphery of the bottom wall to form a receiving space together with the bottom wall, the bottom wall is provided with a first outlet communicating with the receiving space, the grain storage barrel further comprises a discharging structure located outside the receiving space, the discharging structure comprises a discharging part and a control part, the discharging part is provided with a feeding port and a discharging port, the discharging part is rotatably connected to the side of the bottom wall opposite to the peripheral wall, and the feeding port communicates with the first outlet, the discharging port can be selectively turned out of the range of the orthographic projection of the bottom wall or turned back into the range of the orthographic projection of the bottom wall with the rotation of the discharging part, and the control part is movably connected to the discharging part to control the communication or disconnection of the feeding port and the discharging port.
2. The grain storage silo of claim 1, wherein The discharging part comprises a bottom plate, a side plate, a top plate and a first baffle, the side plate is connected between the bottom plate and the top plate to form a storage space together with the bottom plate and the top plate, the first baffle is connected to the side plate and located between the top plate and the bottom plate to separate the storage space into a first storage space and a second storage space, the top plate is provided with the feeding port communicating with the first storage space, the bottom plate is provided with the discharging port communicating with the second storage space, a gap is formed between the first baffle and the bottom plate, and the first storage space communicates with the second storage space through the gap, and the control part is movably connected to the discharging part to block or unblock the gap.
3. The grain storage silo of claim 2, wherein, The control part comprises a key part and a second baffle connected to the key part, the horizontal projection of the second baffle is located in the range of the horizontal projection of the discharging port, the top plate is further provided with an opening communicating with the second storage space, the key part is movably arranged in the second storage space through the opening, and the side of the key part away from the second baffle is exposed to the opening, and the second baffle is movably arranged in the second storage space with the key part to selectively block or unblock the gap.
4. The grain storage silo of claim 3, wherein, The key part comprises a key, a connecting part and an elastic part, the key is exposed to the opening, the connecting part comprises a connecting plate and a sliding part arranged on the connecting plate, the connecting plate is connected between the key and the second baffle, the second storage space is provided with a matching part matched with the sliding part and a matching plate matched with the elastic part, the sliding part is slidably connected to the matching part, and the elastic part abuts between the key and the matching plate.
5. The grain storage silo of claim 4, wherein, The discharging part further comprises a limiting plate located in the second storage space, the limiting plate is connected to at least one of the top plate, the side plate and the bottom plate, the limiting plate is arranged opposite to the first baffle and forms a channel communicating with the opening and the discharging port together with the first baffle, the matching part is arranged between the limiting plate and the first baffle or at least one of the limiting plate, the first baffle and the side plate, and the matching plate is arranged at least one of the limiting plate, the first baffle and the side plate.
6. A grain storage silo as claimed in any one of claims 2 to 5 wherein, The discharging structure further comprises a pulley arranged on the side of the bottom plate opposite to the top plate.
7. A grain storage silo as claimed in any one of claims 2 to 5 wherein, The bottom plate is a slope inclined from the feeding port to the gap.
8. The grain storage silo of any one of claims 1-5, wherein, The grain storage barrel further comprises a support structure, the support structure comprises a support top surface and a first support side surface, the first support side surface is annularly arranged on the outer periphery of the support top surface, one side of the first support side surface is provided with a groove, the support top surface is provided with a second outlet communicated with the groove, one side of the bottom wall away from the peripheral wall is connected with the support top surface, the first outlet is communicated with the second outlet, the second outlet is further communicated with the feeding port, and the discharging part is rotatably connected with the top surface of the groove, so that the discharging structure is movably accommodated in the groove.
9. The grain storage silo of claim 8, wherein, The support structure further comprises a second support side surface, the second support side surface is annularly arranged on the outer periphery of the support top surface, and the second support side surface and the second support side surface are respectively arranged on two sides of the support top surface, and the second support side surface is connected with the peripheral wall.
10. The grain storage silo of claim 9, wherein, The support structure further comprises a support bottom surface, the support bottom surface is connected with the first support side surface and arranged opposite to the support top surface, and the groove is located between the support top surface and the support bottom surface.
11. The grain storage silo according to any one of claims 1-5, 9 and 10, wherein, The bottom wall comprises a plurality of inclined plates connected with each other, and each inclined plate is inclined from one end away from the first outlet to one end toward the first outlet.
12. The grain storage silo according to any one of claims 1-5, 9 and 10, wherein, The grain storage barrel further comprises a cover, the cover is movably arranged on the side of the peripheral wall away from the bottom wall.