An easy-to-maintain aeration pipe structure for organic fertilizer workshops
The modular design of the aeration pipe structure solves the problem of blockage in the aeration pipes of the organic fertilizer workshop, enabling quick disassembly and installation and improving the ease of equipment maintenance.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HUNAN MINGSHENG ENVIRONMENTAL PROTECTION TECHNOLOGY CO LTD
- Filing Date
- 2025-09-08
- Publication Date
- 2026-06-30
AI Technical Summary
The existing aeration pipes in organic fertilizer workshops are easily clogged by moisture and fine fibers during use, making maintenance difficult.
An easy-to-maintain aeration pipe structure for an organic fertilizer workshop was designed, including an aeration pipe body, a connecting mechanism, a conveying mechanism, and a seepage prevention mechanism. The modular installation and quick disassembly are achieved through the combination of barbed joints, conveying hoses, bending pipes, and inserts, preventing moisture and fibers from entering the pipe.
It effectively prevents moisture and fine fibers from entering the pipes, avoids blockages, simplifies the maintenance process, and improves the maintainability of the equipment.
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Figure CN224433855U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to organic fertilizer fermentation equipment technology, specifically to an easy-to-maintain aeration pipe structure for an organic fertilizer workshop. Background Technology
[0002] In the aerobic fermentation process of organic fertilizer, the aeration system is the core equipment for maintaining microbial activity, controlling fermentation temperature, and ensuring efficient decomposition of organic matter. The aeration pipes deliver air through blowers, so that oxygen is evenly distributed inside the organic fertilizer fermentation pile. Aerobic microorganisms decompose organic matter in an aerobic environment, releasing energy and synthesizing humus. This is the core process of organic fertilizer fermentation. The airflow generated by aeration can drive the heat transfer inside the pile, avoiding local high temperature accumulation. Reasonable aeration can prevent the excessive reproduction of thermophilic bacteria from causing the pile to overheat, while promoting the decomposition of refractory substances such as cellulose. The microporous bubbles formed by aeration can break the compacted layer of the pile and enhance the permeability of the material.
[0003] However, existing aeration pipes in organic fertilizer workshops typically require trenches to be dug in the workshop floor for use. The aeration pipes are then buried in the trenches using filler material. Air is allowed to flow out through the openings in the pipes to aerate the organic fertilizer raw materials piled on top. However, after prolonged use, the organic fertilizer raw materials produce a large amount of moisture during fermentation, which can easily flow into the trenches. This moisture contains fine fibers that can seep into the aeration pipes and clog the air outlets, making cleaning difficult and causing considerable trouble for maintenance. Utility Model Content
[0004] The purpose of this utility model is to provide an easy-to-maintain aeration pipe structure for organic fertilizer workshops, in order to solve the problem that in the existing technology, organic fertilizer raw materials will produce a large amount of water during the fermentation process, which can easily flow into the channel. The water contains some fine fibers, which will flow with the water flow and block the air outlet on the aeration pipe, making it difficult to clean and causing a lot of trouble for maintenance.
[0005] To achieve the above objectives, this utility model provides the following technical solution: an easy-to-maintain aeration pipe structure for an organic fertilizer workshop, comprising an aeration pipe body and a transfer mechanism assembled on the top of the aeration pipe body, a conveying mechanism assembled on the top of the transfer mechanism and a water-proof mechanism assembled on one end of the conveying mechanism, wherein an air outlet is provided on the top of the aeration pipe body.
[0006] The adapter includes a barbed connector inserted into the vent, and a connecting pipe is threaded onto the top of the barbed connector.
[0007] The conveying mechanism includes a conveying hose threaded to the top of the connecting pipe, and locking sleeves are fitted at both ends of the conveying hose;
[0008] The water-proof mechanism includes a bent pipe threaded onto one end of the delivery hose. The bottom of the bent pipe and the top of the connecting pipe are both equipped with connecting mechanisms that connect with the delivery hose. An air outlet is threaded onto one side of the bent pipe, and a filter screen is fixedly installed on one side of the air outlet. A plug rod is inserted into the other side of the bent pipe.
[0009] Furthermore, a threaded opening is fixedly installed on the top of the barbed connector, and a threaded cap that is threadedly connected to the threaded opening is rotatably installed on the periphery of the connecting tube.
[0010] Furthermore, the threaded cap is evenly distributed with anti-slip blocks on its periphery, and the locking sleeve is evenly distributed with anti-slip strips on its periphery.
[0011] Furthermore, the connecting mechanism includes a mating interface respectively installed on the top of the mating tube and the bottom of the bent tube, and a threaded sleeve for threaded connection of the locking sleeve is installed on the periphery of the mating interface, and locking flaps are distributed on the top of the threaded sleeve.
[0012] Furthermore, the bent tube and the air outlet are connected by a threaded seat, and the inner wall of one end of the bent tube is provided with a threaded groove for the threaded seat to engage.
[0013] Furthermore, a sleeve is fixedly installed on one side of the bent tube, and the top of the insertion rod is inserted into the sleeve.
[0014] Furthermore, the bottom of the insertion rod is conical, and a support plate is fixedly installed on the periphery of the insertion rod.
[0015] Compared with existing technologies, this utility model provides an easy-to-maintain aeration pipe structure for organic fertilizer workshops. Through the cooperation of a connecting mechanism and a seepage-proof mechanism, the connecting mechanism can be installed on the aeration pipe body, providing an installation position. A delivery hose allows for quick connection between the bent pipe and the connecting mechanism. The bent pipe can be inserted into the packing material in the groove next to the aeration pipe body, allowing air inside the aeration pipe body to be discharged through the bent pipe to aerate the organic fertilizer raw materials piled on top. A filter screen is installed at the air outlet of the bent pipe to intercept fine fibers in the seepage water, preventing them from entering the pipe. The bend in the bent pipe effectively prevents water from flowing into the pipe, facilitating anti-clogging.
[0016] By setting up a mutual cooperation between the insert rod and the sleeve, the top of the insert rod can be inserted into the sleeve, and the insert rod can be inserted into the packing next to the aeration pipe body. This facilitates the support of the bent pipe, making it less likely to tip over. The entire structure can be buried in the trench along with the aeration pipe body. The overall structure adopts modular assembly, which can be disassembled and installed according to the maintenance location for quick maintenance. Attached Figure Description
[0017] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments recorded in this utility model. For those skilled in the art, other drawings can be obtained based on these drawings.
[0018] Figure 1 This is a schematic diagram of the overall structure from the front view of an embodiment of the present utility model;
[0019] Figure 2 This is a schematic diagram of the rear view structure provided for an embodiment of the present utility model;
[0020] Figure 3 This is a schematic diagram of the adapter mechanism provided in an embodiment of the present utility model;
[0021] Figure 4 A schematic diagram of the conveying mechanism and connecting mechanism provided in the embodiments of this utility model;
[0022] Figure 5 A schematic diagram of the waterproofing mechanism provided in this embodiment of the utility model.
[0023] Explanation of reference numerals in the attached figures:
[0024] 1. Aeration pipe body; 11. Air outlet; 2. Adapter mechanism; 21. Barbed connector; 22. Threaded port; 23. Connecting pipe; 24. Threaded cap; 25. Anti-slip block; 3. Conveying mechanism; 31. Conveying hose; 32. Locking sleeve; 33. Anti-slip strip; 4. Waterproofing mechanism; 41. Bending pipe; 42. Threaded groove; 43. Air outlet; 44. Filter screen; 45. Threaded seat; 46. Sleeve; 47. Insert rod; 48. Support plate; 5. Connecting mechanism; 51. Threaded sleeve; 52. Locking blade; 53. Connecting port. Detailed Implementation
[0025] To enable those skilled in the art to better understand the technical solution of this utility model, the present utility model will be further described in detail below with reference to the accompanying drawings.
[0026] As attached Figure 1 To be continued Figure 5 As shown:
[0027] Example 1:
[0028] This utility model provides an easy-to-maintain aeration pipe structure for an organic fertilizer workshop, including an aeration pipe body 1 and a transfer mechanism 2 assembled on the top of the aeration pipe body 1, as well as a conveying mechanism 3 assembled on the top of the transfer mechanism 2 and a seepage prevention mechanism 4 assembled on one end of the conveying mechanism 3. An air outlet 11 is provided on the top of the aeration pipe body 1.
[0029] The adapter 2 includes a barbed connector 21 that is inserted into the vent 11, and a connecting tube 23 is threaded onto the top of the barbed connector 21.
[0030] The conveying mechanism 3 includes a conveying hose 31 threaded to the top of the connecting pipe 23, and locking sleeves 32 are fitted at both ends of the conveying hose 31;
[0031] The waterproof mechanism 4 includes a bent pipe 41 threaded onto one end of the delivery hose 31. The bottom of the bent pipe 41 and the top of the connecting pipe 23 are both equipped with a connecting mechanism 5 that connects to the delivery hose 31. An air outlet 43 is threaded onto one side of the bent pipe 41. A filter screen 44 is fixedly installed on one side of the air outlet 43. An insert rod 47 is inserted onto the other side of the bent pipe 41.
[0032] As can be seen from the above, during use, a trench is dug in the workshop floor, the aeration pipe body 1 is placed in the trench, and filler is filled in the trench to fix the aeration pipe body 1. An air outlet 11 is drilled at the top of the aeration pipe body 1 using a hole saw, and the barbed connector 21 is inserted into the air outlet 11. The conical barbed structure at the bottom of the barbed connector 21 can engage inside the air outlet 11, allowing the top of the barbed connector 21 to be exposed. The connecting pipe 23 is then inserted into the barbed connector 21 for mating installation, allowing the connecting pipe 23 to engage with the barbed connector 21. The connection is achieved by inserting the conveying hose 31 into the connecting mechanism 5. The connecting mechanism 5 can be easily locked using the locking sleeve 32, allowing the conveying hose 31 to be connected to the connecting pipe 23 and the bent pipe 41. Due to the flexibility of the conveying hose 31, the bent pipe 41 can be easily arranged in a suitable position next to the aeration pipe body 1. The insert rod 47 can be inserted into the packing next to the aeration pipe body 1 to easily support the bent pipe 41. The overall structure can be buried in the trench on the workshop floor along with the aeration pipe body 1 through the packing.
[0033] By delivering air into the aeration pipe body 1, the airflow can be guided along the delivery hose 31 into the bent pipe 41. The air outlet 43 allows for easy air discharge, facilitating the aeration of the organic fertilizer material piled on top. The filter screen 44 on the air outlet 43 can intercept fine fibers in the seepage water, preventing them from entering the pipe. The bend in the bent pipe 41 effectively prevents water from flowing into the pipe, facilitating anti-clogging. The overall structure adopts modular assembly, allowing for quick maintenance by disassembling and installing according to the maintenance location.
[0034] From the appendix Figure 3 It can be seen that the top of the barbed connector 21 is fixedly installed with a threaded port 22, and the periphery of the connecting pipe 23 is rotatably installed with a threaded cap 24 that is threadedly connected to the threaded port 22.
[0035] As can be seen from the above, when the connecting tube 23 is inserted into the barbed connector 21, the threaded cap 24 can be rotated to engage with the threaded opening 22, which can easily fix the connecting tube 23 and the barbed connector 21. At the same time, the threaded cap 24 can be used to seal the connection point and prevent leakage.
[0036] For details, please refer to the appendix. Figure 3 and attached Figure 4 As shown, anti-slip blocks 25 are evenly distributed around the outer periphery of the threaded cap 24, and anti-slip strips 33 are evenly distributed around the outer periphery of the locking sleeve 32.
[0037] As can be seen from the above, the anti-slip block 25 can increase the friction between the threaded cover 24 and the hand, making it easier to operate the threaded cover 24 and prevent slippage when rotating it, and making it easier to lock the threaded cover 24. The anti-slip strip 33 can increase the friction between the locking sleeve 32 and the hand, making it easier to operate the locking sleeve 32 and prevent slippage when rotating it.
[0038] For details, please refer to the appendix. Figure 3 Appendix Figure 4 As shown and attached Figure 5 The connecting mechanism 5 includes a coupling interface 53 installed on the top of the coupling tube 23 and the bottom of the bent tube 41 respectively. A threaded sleeve 51 for threaded connection of the locking sleeve 32 is installed on the periphery of the coupling interface 53. Locking flaps 52 are distributed on the top of the threaded sleeve 51.
[0039] As can be seen from the above, by inserting the delivery hose 31 between the interface 53 and the threaded sleeve 51, and by rotating the locking sleeve 32, the locking sleeve 32 and the threaded sleeve 51 are engaged by thread. The locking sleeve 32 can move downward along the thread of the threaded sleeve 51, which allows the locking sleeve 32 to squeeze the locking leaf 52, so that the locking leaf 52 can close inward. This facilitates the compression and fixation of the delivery hose 31, enabling quick connection and quick disassembly, thus providing greater convenience for maintenance.
[0040] Working principle: The aeration pipe body 1 is placed in a trench on the workshop floor. The barbed connector 21 is inserted into the air outlet 11 at the top of the aeration pipe body 1. The connecting pipe 23 is inserted into the barbed connector 21 to connect them. The connecting pipe 23 and the barbed connector 21 are locked by rotating the threaded cap 24. The connecting mechanism 5 connects the conveying hose 31, the bent pipe 41, and the connecting pipe 23. The insert rod 47 is inserted into the packing next to the aeration pipe body 1 to support the bent pipe 41. Air is injected into the aeration pipe body 1 and guided into the bent pipe 41 through the conveying hose 31. The air outlet 43 can easily vent the air to aerate the organic fertilizer raw materials piled on top. The filter screen 44 intercepts fine fibers in the water to prevent them from entering the pipe. The bend of the bent pipe 41 prevents water from flowing into the pipe, effectively preventing blockage. The overall structure adopts modular assembly, which facilitates disassembly and maintenance.
[0041] Example 2:
[0042] Reference Appendix Figure 5 As shown, the bent pipe 41 and the air outlet 43 are connected by a threaded seat 45. The inner wall of one end of the bent pipe 41 is provided with a threaded groove 42 for the threaded seat 45 to engage.
[0043] As can be seen from the above, by rotating the air outlet 43, the threaded seat 45 and the threaded groove 42 can be engaged, which makes it easy to screw the threaded seat 45 into the bent pipe 41, and makes it easy to install and remove the air outlet 43.
[0044] Reference Appendix Figure 5 As shown, a sleeve 46 is fixedly installed on one side of the bent tube 41, and the top of the insertion rod 47 is inserted into the sleeve 46.
[0045] As can be seen from the above, by inserting the top of the insertion rod 47 into the sleeve 46, the sleeve 46 can be used to limit the insertion rod 47, which can facilitate the insertion rod 47 to support the bent tube 41.
[0046] Reference Appendix Figure 5As shown, the bottom of the insertion rod 47 is conical, and a support plate 48 is fixedly installed on the periphery of the insertion rod 47.
[0047] As can be seen from the above, by inserting the rod 47 into the packing next to the aeration pipe body 1, the support plate 48 can provide lateral support, which can prevent the rod 47 from tipping over.
[0048] The foregoing description only illustrates certain exemplary embodiments of the present invention. Undoubtedly, those skilled in the art can modify the described embodiments in various ways without departing from the spirit and scope of the present invention. Therefore, the above drawings and descriptions are illustrative in nature and should not be construed as limiting the scope of protection of the claims of the present invention.
Claims
1. A maintenance-friendly organic fertilizer plant aeration pipeline structure, comprising an aeration pipe body (1) and an adapter mechanism (2) assembled on the top of the aeration pipe body (1), and a conveying mechanism (3) assembled on the top of the adapter mechanism (2) and a water seepage prevention mechanism (4) assembled on one end of the conveying mechanism (3), characterized in that, An air outlet (11) is provided at the top of the aeration pipe body (1); The adapter (2) includes a barbed connector (21) inserted into the vent (11), and a connecting pipe (23) is threaded onto the top of the barbed connector (21); The conveying mechanism (3) includes a conveying hose (31) threaded to the top of the connecting pipe (23), and locking sleeves (32) are fitted at both ends of the conveying hose (31); The waterproofing mechanism (4) includes a bent pipe (41) threaded onto one end of the delivery hose (31). The bottom of the bent pipe (41) and the top of the connecting pipe (23) are both equipped with a connecting mechanism (5) that connects to the delivery hose (31). An air outlet (43) is threaded onto one side of the bent pipe (41). A filter screen (44) is fixedly installed on one side of the air outlet (43). A plug rod (47) is inserted into the other side of the bent pipe (41).
2. A maintenance-friendly organic fertilizer plant aeration pipeline structure according to claim 1, characterized in that, The top of the barbed connector (21) is fixedly installed with a threaded opening (22), and the periphery of the connecting pipe (23) is rotatably installed with a threaded cap (24) that is threadedly connected to the threaded opening (22).
3. A maintenance-friendly aeration conduit structure for an organic fertilizer plant according to claim 2, characterized in that, The threaded cap (24) has anti-slip blocks (25) evenly distributed around its periphery, and the locking sleeve (32) has anti-slip strips (33) evenly distributed around its periphery.
4. The easily-maintained organic fertilizer plant aeration pipeline structure according to claim 1, characterized in that, The connecting mechanism (5) includes a coupling interface (53) respectively installed on the top of the coupling tube (23) and the bottom of the bent tube (41). A threaded sleeve (51) for threaded connection of the locking sleeve (32) is installed on the periphery of the coupling interface (53). Locking flaps (52) are distributed on the top of the threaded sleeve (51).
5. The easily-maintained organic fertilizer plant aeration pipeline structure according to claim 1, characterized in that, The bent tube (41) and the air outlet (43) are connected by a threaded seat (45). The inner wall of one end of the bent tube (41) is provided with a threaded groove (42) for the threaded seat (45) to engage.
6. A maintenance-friendly organic fertilizer plant aeration conduit structure according to claim 1, characterized in that, A sleeve (46) is fixedly installed on one side of the bent tube (41), and the top of the insertion rod (47) is inserted into the sleeve (46).
7. The easily-maintained organic fertilizer plant aeration pipeline structure according to claim 1, characterized in that, The bottom of the insertion rod (47) is conical, and a support plate (48) is fixedly installed on the periphery of the insertion rod (47).