CN209983178U - Aerial fog cultivation pipeline - Google Patents

Abstract

The utility model provides an aerial fog cultivation pipeline, this aerial fog cultivation pipeline includes: the cultivation tube body is of an open structure at two end parts and the upper side; the fog inlet end cover is detachably arranged at one end part of the cultivation pipe body, and a fog inlet hole is formed in the fog inlet end cover; the backflow end cover is detachably arranged at the other end of the cultivation pipe body, and the backflow end cover is provided with a mist return hole; cultivation panel, detachably installs the upside at the cultivation body, has seted up a plurality of planting holes that are used for cultivating the plant on the cultivation panel. The aerial fog cultivation pipeline adopts a cultivation pipe body with two end parts and an upper side both of which are open structures, a fog inlet end cover and a backflow end cover are detachably arranged at two ends of the cultivation pipe body, and a cultivation panel is detachably arranged at the upper side of the cultivation pipe body; this aerial fog cultivation pipeline easy dismounting will advance fog end cover, backward flow end cover and cultivation panel and dismantle the back, can expose the inner space of cultivation body well, conveniently clears up in the cultivation body.

Description

Aerial fog cultivation pipeline

Technical Field

The utility model relates to a crops cultivation device technical field particularly, relates to an aerial fog cultivation pipeline.

Background

The aerial fog cultivation technology can well solve the problem of water, gas and fertilizer balance of crop roots, is one of the most environment-friendly and energy-saving green cultivation modes, and the low-consumption and water-saving cultivation device combines the advanced cultivation technology and intelligent control and is the development direction of future intelligent agriculture.

The existing aeroponic culture device has fewer types and single form. The device based on ultrasonic atomization cultivation mainly has a barrel shape and a pipeline shape. The barrel-shaped aeroponic culture device is not suitable for large-area popularization and planting, can not fully utilize the culture space and has low space utilization rate. The existing pipeline-shaped aeroponics device is inconvenient to disassemble and assemble, the pipeline is inconvenient to clean after harvesting, and if the pipeline is not clean, the crops are easy to be diseased; moreover, the existing pipeline-shaped aeroponic culture device is inconvenient for automatic planting and harvesting; in addition, the length of the conventional pipeline-shaped aeroponics device is usually fixed, so that the pipeline is too long and inconvenient to transport, and the pipeline with fixed length has poor use flexibility.

SUMMERY OF THE UTILITY MODEL

A primary object of the present invention is to provide an aeroponic cultivation pipeline to at least solve the inconvenient technical problem of the pipeline form aeroponic cultivation device dismouting and clearance pipeline among the prior art.

In order to achieve the above object, the utility model provides an aerial fog cultivation pipeline, this aerial fog cultivation pipeline includes: the cultivation tube body is of an open structure at two end parts and the upper side; the fog inlet end cover is detachably arranged at one end part of the cultivation pipe body, and a fog inlet hole is formed in the fog inlet end cover; the backflow end cover is detachably arranged at the other end of the cultivation pipe body, and is provided with a mist return hole and a backflow hole; cultivation panel, detachably installs the upside at the cultivation body, offers the planting hole that is used for cultivating the plant on the cultivation panel.

Furthermore, the fog inlet end cover comprises a fog inlet end cover outer frame plate, a fog inlet end cover inner frame is arranged on one side, butted with the end part of the cultivation pipe body, of the fog inlet end cover outer frame plate, and first inserting gaps for inserting the end part of the cultivation pipe body are formed between the side face of the fog inlet end cover inner frame and the side face of the fog inlet end cover outer frame plate at intervals.

Furthermore, the bottom shape of the outer frame plate of the fog inlet end cover is matched with the bottom shape of the cultivation pipe body, a first convex strip is arranged on the inner side of the bottom of the outer frame plate of the fog inlet end cover, two ends of the first convex strip are respectively connected with the bottom of the side face of the inner frame of the fog inlet end cover, and the thickness of the first convex strip is the same as the thickness of the pipe wall of the cultivation pipe body.

Furthermore, the top surface of the inner frame of the fog inlet end cover is slightly lower than the upper edge of the cultivation pipe body, the top surface of the outer frame plate of the fog inlet end cover is higher than the top surface of the inner frame of the fog inlet end cover, and the top surface of the inner frame of the fog inlet end cover is used for placing cultivation panels.

Furthermore, the backflow end cover comprises a backflow end cover outer frame plate, a backflow end cover inner frame is arranged on one side, butted with the end portion of the cultivation pipe body, of the backflow end cover outer frame plate, and second inserting and connecting gaps for inserting the end portion of the cultivation pipe body are formed between the side face of the backflow end cover inner frame and the side face of the backflow end cover outer frame plate at intervals.

Furthermore, the bottom shape of the outer frame plate of the backflow end cover is matched with the bottom shape of the cultivation pipe body, a second convex strip is arranged on the inner side of the bottom of the outer frame plate of the backflow end cover, two ends of the second convex strip are respectively connected with the bottom of the side face of the inner frame of the backflow end cover, and the thickness of the second convex strip is the same as the thickness of the pipe wall of the cultivation pipe body.

Furthermore, the backflow hole is formed in the lower portion of the outer frame plate of the backflow end cover, and the height of the lower edge of the backflow hole is lower than or equal to the height of the upper surface of the second convex strip.

Furthermore, the top surface of the inner frame of the backflow end cover is slightly lower than the upper edge of the cultivation pipe body, the top surface of the outer frame plate of the backflow end cover is higher than the top surface of the inner frame of the backflow end cover, and the top surface of the inner frame of the backflow end cover is used for placing cultivation panels.

Furthermore, the fog inlet hole is arranged at the upper middle position of the fog inlet end cover, the fog return hole is arranged at the upper middle position of the fog return end cover, and the height of the fog inlet hole is slightly higher than that of the fog return hole; after the aerial fog cultivation pipeline is installed, the cultivation pipe body is obliquely arranged, and one end, where the fog inlet end cover is installed, of the cultivation pipe body is higher than one end, where the backflow end cover is installed, of the cultivation pipe body.

Furthermore, the two sides of the cultivation panel are provided with ear parts which are convenient for carrying or hoisting the cultivation panel.

Furthermore, the lower edges of the two sides of the cultivation panel are provided with grooves matched with the upper edges of the pipe walls of the cultivation pipe bodies, and the inner side walls of the grooves are tightly attached to the inner sides of the pipe walls of the cultivation pipe bodies.

Further, the cultivation body includes the multistage cultivation body unit, connects through an intermediate junction spare detachably between the adjacent cultivation body unit.

Furthermore, the middle connecting piece comprises two connecting outer arms, the inner side of each connecting outer arm is provided with a connecting inner arm, the middle part of each connecting inner arm is connected with the corresponding connecting outer arm through a connecting strip, and two sides of each connecting strip are provided with partition plate grooves for inserting and cultivating pipe body units; the bottom of two connection outer arms is connected through a bottom linkage segment, and the shape of bottom linkage segment suits with the bottom shape of cultivation body unit, and the inboard middle part of bottom linkage segment is equipped with a third sand grip, and the both ends of third sand grip are connected with the bottom of two connection inner arms respectively, and the thickness of third sand grip is the same with the wall thickness of cultivation body unit.

By applying the technical scheme of the utility model, the cultivation tube body with both ends and the upper side of the cultivation tube body are of an open structure, the fog inlet end cover is detachably arranged at one end of the cultivation tube body, the return end cover is detachably arranged at the other end of the cultivation tube body, and the cultivation panel is detachably arranged at the upper side of the cultivation tube body; this aerial fog cultivation pipeline easy dismounting will advance fog end cover, backward flow end cover and cultivation panel and dismantle the back, can expose the inner space of cultivation body well, conveniently clears up in the cultivation body.

In addition to the above-described objects, features and advantages, the present invention has other objects, features and advantages. The present invention will be described in further detail below with reference to the accompanying drawings.

Drawings

The accompanying drawings, which form a part of the present application, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 is the overall structure schematic diagram of the aerial fog cultivation pipeline of the embodiment of the utility model.

Fig. 2 is a schematic structural view of the mist inlet end cover in the aerial fog cultivation pipeline of the embodiment of the utility model.

Fig. 3 is a schematic structural view of a backflow end cover in an aerial fog cultivation pipeline of the utility model.

Fig. 4 is a schematic structural view of a cultivation panel in an aerial fog cultivation pipeline according to the present invention.

Fig. 5 is a partially enlarged view of a portion a in fig. 1.

Fig. 6 is a schematic structural view of the intermediate connection member in the aerial fog cultivation pipeline of the embodiment of the present invention.

Wherein the figures include the following reference numerals:

10. cultivating the tube body; 11. a cultivation tube unit; 20. a fog inlet end cover; 21. a mist inlet hole; 22. an outer frame plate of the fog inlet end cover; 23. an inner frame of the fog inlet end cover; 24. a first plugging gap; 25. a first rib; 30. a reflux end cap; 31. a mist return hole; 32. a return end cap outer frame plate; 33. a backflow end cover inner frame; 34. a second plugging gap; 35. a second convex strip; 36. a return orifice; 40. a cultivation panel; 41. planting holes; 42. an ear portion; 43. a groove; 50. an intermediate connecting member; 51. connecting the outer arm; 52. connecting the inner arm; 53. a connecting strip; 54. a partition plate groove; 55. a bottom connecting section; 56. a third convex strip.

Detailed Description

To facilitate understanding of the present invention, the present invention will be described more fully and specifically with reference to the accompanying drawings and preferred embodiments, but the scope of the present invention is not limited to the specific embodiments described below. It should be noted that, in the present invention, the embodiments and features of the embodiments may be combined with each other without conflict.

Unless otherwise defined, all terms of art used hereinafter have the same meaning as commonly understood by one of ordinary skill in the art. The use of "first," "second," and similar terms in the description and in the claims does not indicate any order, quantity, or importance, but rather the intention is merely to facilitate a distinction between corresponding parts. Also, the use of the terms "a" or "an" and the like do not denote a limitation of quantity, but rather denote the presence of at least one. The terms "connected" and "coupled" and the like are not restricted to direct connections, but may be indirectly connected through other intermediate connections. "upper", "lower", "left", "right", and the like are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships are changed accordingly.

Referring to fig. 1 to 6, a the utility model discloses an aerial fog cultivation pipeline, this aerial fog cultivation pipeline mainly includes: cultivation body 10, advance fog end cover 20, backward flow end cover 30 and cultivation panel 40. Wherein, the cultivation tube body 10 is a U-shaped pipeline as a whole, and two end parts and the upper side of the cultivation tube body 10 are both in an open structure; the fog inlet end cover 20 is detachably arranged at one end part of the cultivation pipe body 10, and a fog inlet hole 21 is formed in the fog inlet end cover 20; the backflow end cover 30 is detachably mounted at the other end of the cultivation tube body 10, and the backflow end cover 30 is provided with a mist return hole 31 and a backflow hole 36; the cultivation panel 40 is detachably mounted on the upper side of the cultivation tube 10, and a plurality of planting holes 41 for planting plants are formed in the cultivation panel 40 to match with the cultivation basket. The size of the planting holes 41 is matched with the diameter of the existing planting basket.

The aerial fog cultivation pipeline adopts the cultivation pipe body 10 with two end parts and an upper side of the cultivation pipe body being in an open structure, the fog inlet end cover 20 is detachably arranged at one end of the cultivation pipe body 10, the return end cover 30 is detachably arranged at the other end of the cultivation pipe body 10, and the cultivation panel 40 is detachably arranged at the upper side of the cultivation pipe body 10; this aerial fog cultivation pipeline easy dismounting will advance fog end cover 20, backward flow end cover 30 and cultivation panel 40 and dismantle the back, can expose the inner space of cultivation body 10 well, conveniently clears up in the cultivation body 10.

Specifically, referring to fig. 2, in the present embodiment, the fog inlet end cap 20 includes an outer frame plate 22, and an inner frame 23 is disposed on a side of the outer frame plate 22 abutting against the end of the cultivating pipe 10. The side of the inner frame 23 of the fog inlet end cover and the side of the outer frame plate 22 of the fog inlet end cover are spaced to form a first inserting gap 24 for inserting the end of the cultivating pipe 10. The width of the first inserting gap 24 is adapted to the thickness of the tube wall of the cultivating tube 10. When the cultivation pipe body 10 is installed, one end of the cultivation pipe body 10 is inserted into the first inserting gap 24, the fog inlet end cover 20 can be installed at the end portion of the cultivation pipe body 10, the structure is simple, and the disassembly and the installation are very convenient. The lower end of the inner frame 23 of the fog inlet end cover can be a right angle, so that the effect of better fixing the cultivation pipe body 10 is achieved; the lower end of the inner frame 23 of the mist inlet end cover can also be a round angle, so that the assembly is more convenient.

Further, referring to fig. 2, the bottom shape of the outer frame plate 22 of the fog inlet end cap is adapted to the bottom shape of the cultivation tube 10, and is an arc-shaped structure. A first convex strip 25 is arranged on the inner side of the bottom of the outer frame plate 22 of the fog inlet end cover, two ends of the first convex strip 25 are respectively connected with the bottoms of two side surfaces of the inner frame 23 of the fog inlet end cover, and the thickness of the first convex strip 25 is the same as the thickness of the pipe wall of the cultivation pipe body 10. With the arrangement, after the fog inlet end cover 20 is installed at the end of the cultivation tube 10, the inner side of the bottom of the outer frame plate 22 of the fog inlet end cover is in close contact with the outer surface of the lower side of the cultivation tube 10, the side wall of the first raised line 25 is in close contact with the end face of the cultivation tube 10, and the inner surface of the lower side of the cultivation tube 10 is flush with the upper surface of the first raised line 25; on one hand, the installation fit degree between the fog inlet end cover 20 and the cultivation pipe body 10 can be improved, and the joint is reinforced and supported; on the other hand, the height difference between the cultivating pipe body 10 and the first raised line 25 can be avoided to block the backflow of the condensed nutrient solution in the pipeline.

Further, referring to fig. 2, the top surface of the inner frame 23 of the fog inlet end cover is slightly lower than the upper edge of the cultivation tube 10, the top surface of the outer frame plate 22 of the fog inlet end cover is higher than the top surface of the inner frame 23 of the fog inlet end cover, and the top surface of the inner frame 23 of the fog inlet end cover is used for placing the cultivation panel 40. The inner frame 23 of the mist inlet end cover is in an inverted U-shaped structure. With the arrangement, after the cultivation panel 40 is covered on the cultivation tube body 10, the lower surface of the cultivation panel 40 can be well attached to the top surface of the inner frame 23 of the fog inlet end cover due to the fact that the top surface of the inner frame 23 of the fog inlet end cover is slightly lower than the upper edge of the cultivation tube body 10, and leakage of fog is effectively reduced.

Specifically, referring to fig. 1 and 3, in the present embodiment, the return end cap 30 includes a return end cap outer frame 32, a return end cap inner frame 33 is disposed on a side of the return end cap outer frame 32 abutting against the end of the cultivation pipe 10, and a side surface of the return end cap inner frame 33 is spaced from a side surface of the return end cap outer frame 32 to form a second insertion gap 34 into which the end of the cultivation pipe 10 is inserted. The width of the second insertion gap 34 is adapted to the thickness of the tube wall of the cultivation tube 10. When the cultivation pipe body 10 is installed, one end of the cultivation pipe body 10 far away from the fog inlet end cover 20 is inserted into the second inserting gap 34, and then the backflow end cover 30 can be installed at the end part of the cultivation pipe body 10, so that the cultivation pipe body is very convenient to assemble and disassemble.

Further, referring to fig. 3, the bottom shape of the outer frame plate 32 of the return end cap is adapted to the bottom shape of the cultivation tube 10, and is an arc-shaped structure. A second protruding strip 35 is disposed on the inner side of the bottom of the outer frame plate 32 of the return end cap, two ends of the second protruding strip 35 are respectively connected to the bottoms of two sides of the inner frame 33 of the return end cap, and the thickness of the second protruding strip 35 is the same as the thickness of the tube wall of the cultivation tube 10. With the arrangement, after the return end cap 30 is mounted at the end of the cultivation tube 10, the inner side of the bottom of the outer frame plate 32 of the return end cap is in close contact with the outer surface of the lower side of the cultivation tube 10, the side wall of the second protruding strip 35 is in close contact with the end face of the cultivation tube 10, and the inner surface of the lower side of the cultivation tube 10 is flush with the upper surface of the second protruding strip 35; on one hand, the installation fit degree between the backflow end cover 30 and the cultivation tube body 10 can be improved, and the joint is reinforced and supported; on the other hand, the height difference between the cultivation tube body 10 and the second raised line 35 can be avoided to block the backflow of the condensed nutrient solution in the pipeline.

Further, referring to fig. 1 and 3, the return hole 36 is opened at a lower portion of the return end cap outer frame plate 32, and a height of a lower edge of the return hole 36 is lower than or equal to a height of an upper surface of the second rib 35. With such an arrangement, the condensed nutrient solution in the cultivation tube 10 can be more conveniently returned to the liquid storage tank (not shown) through the return hole 36. The diameter of the mist return hole 31 is larger, and the diameter of the mist return hole 36 is smaller.

Referring to fig. 3, in the present embodiment, the top surface of the inner frame 33 of the return end cap is slightly lower than the upper edge of the cultivation pipe 10, and the top surface of the outer frame plate 32 of the return end cap is higher than the top surface of the inner frame 33 of the return end cap, and the top surface of the inner frame 33 of the return end cap is used for placing the cultivation panels 40. The inner frame 33 of the return end cover is in an inverted U-shaped structure. With the arrangement, after the cultivation panel 40 is covered on the cultivation tube 10, the lower surface of the cultivation panel 40 can be well attached to the top surface of the inner frame 33 of the backflow end cover due to the fact that the top surface of the inner frame 33 of the backflow end cover is slightly lower than the upper edge of the cultivation tube 10, and accordingly fog leakage is effectively reduced.

Specifically, referring to fig. 1 to 3, the mist inlet holes 21 are disposed on the upper middle portion of the mist inlet end cover 20, the mist return holes 31 are disposed on the upper middle portion of the mist return end cover 30, and the height of the mist inlet holes 21 is slightly higher than that of the mist return holes 31. After the aerial fog cultivation pipeline is installed, the cultivation pipe body 10 is obliquely arranged at a certain angle, and one end of the cultivation pipe body 10, which is provided with the fog inlet end cover 20, is slightly higher than one end of the cultivation pipe body 10, which is provided with the backflow end cover 30. Because the atomizing nutrient solution can condense gradually after entering into cultivation body 10 to under the self action of gravity of nutrient solution, the atomizing nutrient solution has the trend of flowing downwards slowly along the length direction of cultivation body 10, adopts foretell structure setting, can make the root system homoenergetic of all plants on the cultivation panel 40 fully contact with the atomizing nutrient solution, is favorable to the balanced growth of plant. A thin rubber ring (not shown in the figure) can be arranged at the fog inlet hole 21 and the fog return hole 31, so that a fog inlet pipeline or a fog return pipeline can be inserted into the fog inlet hole 21 and the fog return hole 31 more conveniently, the glue is not needed to be applied, and the fog leakage can be reduced.

When the aerial fog cultivation pipeline is used for cultivating plants, the cultivation panel 40 is frequently required to be taken down to transplant seedlings or harvest products, and the cultivation panel 40 in the existing aerial fog cultivation pipeline is inconvenient to take. To solve this problem, referring to fig. 1 and 4, in the present embodiment, ear portions 42 are provided on both sides of the cultivation panel 40. The cultivation panels 40 can be conveniently carried manually or lifted mechanically by the ears 42, so that seedlings can be transplanted or products can be harvested conveniently. Specifically, the number of the ear portions 42 may be specifically set according to the length of the cultivation panel 40, and if the length of the cultivation panel 40 is longer, a larger number of the ear portions 42 may be correspondingly provided, preferably, the number of the ear portions 42 is an even number (e.g., 2 or 4), and the plurality of the ear portions 42 are symmetrically provided on both sides of the cultivation panel 40. The ears 42 may be embodied as flanges extending outwardly from the sides of the growth panel 40 and may be perforated to facilitate mechanical lifting.

Referring to fig. 1, 4 and 5, in the present embodiment, grooves 43 matched with the upper edge of the pipe wall of the cultivation pipe body 10 are formed on the lower edges of both sides of the cultivation panel 40. After the cultivation panel 40 is mounted on the cultivation pipe body 10, the inner side wall of the groove 43 is closely attached to the inner side of the pipe wall of the cultivation pipe body 10. By the arrangement, fog cannot leak between the cultivation panel 40 and the cultivation pipe body 10 under the condition of small deformation; and the cultivation panel 40 and the cultivation tube 10 are more conveniently installed and butted.

The existing pipeline-shaped aeroponic culture device usually adopts pipelines with fixed lengths, the pipelines are too long and inconvenient to transport, the pipelines with fixed lengths are poor in use flexibility, and the lengths of the pipelines cannot be conveniently adjusted according to the space conditions in practical use. In order to solve the above-mentioned problems, referring to fig. 1, in the present embodiment, the cultivation tube body 10 includes a plurality of sections of cultivation tube body units 11, and adjacent cultivation tube body units 11 are detachably connected to each other by an intermediate connector 50. With the arrangement, the multi-section cultivation pipe body units 11 are connected through the middle connecting piece 50 to form an integral aerial fog cultivation pipeline, and the multi-section cultivation pipe body units 11 can be disassembled during transportation, so that the transportation is convenient and the deformation is not easy to occur; can select 11 sections of the cultivation body unit number of connecting according to the space condition when in actual use, easy dismounting uses more in a flexible way.

Specifically, referring to fig. 6, in the present embodiment, the intermediate connecting member 50 includes two connecting outer arms 51, each connecting outer arm 51 is provided at an inner side thereof with a connecting inner arm 52, the connecting inner arm 52 is connected at a middle portion thereof to the connecting outer arms 51 by a connecting bar 53, and partition grooves 54 for inserting the cultivation pipe body units 11 are formed at both sides of the connecting bar 53. With the above arrangement, when the two sections of cultivation tube units 11 are connected and assembled, the two sections of cultivation tube units 11 are inserted into the partition grooves 54 on both sides of the connecting strip 53, so that the two sections of cultivation tube units 11 can be assembled and butted. The height of connecting outer arm 51 is slightly higher than the height of connecting inner arm 52 and connecting strip 53, which facilitates installation of cultivation panel 40.

Further, referring to fig. 6, the bottoms of the two connecting outer arms 51 are connected by a bottom connecting section 55, and the bottom connecting section 55 is adapted to the bottom shape of the cultivating pipe body unit 11 and has an arc-shaped structure. A third protruding strip 56 is arranged in the middle of the inner side of the bottom connecting section 55, two ends of the third protruding strip 56 are respectively connected with the bottoms of the two connecting inner arms 52, and the thickness of the third protruding strip 56 is the same as the thickness of the tube wall of the cultivation tube body unit 11. With this arrangement, after the two sections of cultivation pipe body units 11 are butt-jointed and mounted, the end portions of the two sections of cultivation pipe body units 11 are respectively attached to the two side surfaces of the third protruding strip 56, the lower surface of the bottom of the cultivation pipe body unit 11 is attached to the inner surface of the bottom connecting section 55, and the upper surface of the third protruding strip 56 is flush with the inner surface of the bottom of the two sections of cultivation pipe body units 11. Thus, not only can the degree of fitting between the two sections of the cultivation tube units 11 and the intermediate connector 50 be improved, but also a height difference between the third projecting strip 56 and the cultivation tube units 11 can be avoided.

As can be seen from the above description, the utility model discloses an aerial fog cultivation pipeline can realize following beneficial effect at least: after the fog inlet end cover 20, the backflow end cover 30 and the cultivation panel 40 are disassembled, the exposed cultivation tube body 10 can be disassembled, and the interior of the cultivation tube body 10 can be conveniently cleaned; the ear parts 42 are arranged on the cultivation panel 40, so that the cultivation panel 40 is convenient to carry manually or hoist mechanically, seedlings are convenient to transplant, products are convenient to harvest, and automatic management of production is convenient; the length of the cultivation pipe body 10 in the aerial fog cultivation pipeline is adjustable, so that the transportation is convenient, and the cultivation pipe body is not easy to deform; the multi-section cultivation pipe body units 11 are connected through the middle connecting piece 50, and are convenient to disassemble and assemble and flexible to use.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. An aerial fog cultivation pipe, characterized in that the aerial fog cultivation pipe comprises:

the cultivation tube body (10), two end parts and the upper side of the cultivation tube body (10) are both of an open structure;

the fog inlet end cover (20) is detachably mounted at one end of the cultivation pipe body (10), and a fog inlet hole (21) is formed in the fog inlet end cover (20);

the backflow end cover (30) is detachably mounted at the other end of the cultivation tube body (10), and a backflow hole (31) and a backflow hole (36) are formed in the backflow end cover (30);

the cultivation panel (40) is detachably mounted on the upper side of the cultivation tube body (10), and planting holes (41) used for cultivating plants are formed in the cultivation panel (40).

2. The aerial fog cultivation pipeline of claim 1, wherein the fog inlet end cover (20) comprises an outer frame plate (22) of the fog inlet end cover, an inner frame (23) of the fog inlet end cover is arranged on one side of the outer frame plate (22) of the fog inlet end cover, which is abutted against the end of the cultivation pipe body (10), and a first inserting gap (24) for inserting the end of the cultivation pipe body (10) is formed between the side surface of the inner frame (23) of the fog inlet end cover and the side surface of the outer frame plate (22) of the fog inlet end cover at intervals.

3. Aerosol cultivation tube according to claim 2,

the bottom shape of the outer frame plate (22) of the fog inlet end cover is matched with the bottom shape of the cultivation pipe body (10), a first convex strip (25) is arranged on the inner side of the bottom of the outer frame plate (22) of the fog inlet end cover, two ends of the first convex strip (25) are respectively connected with the bottom of the side surface of the inner frame (23) of the fog inlet end cover, and the thickness of the first convex strip (25) is the same as the pipe wall thickness of the cultivation pipe body (10);

the top surface of the inner frame (23) of the fog inlet end cover is slightly lower than the upper edge of the cultivation pipe body (10), the top surface of the outer frame plate (22) of the fog inlet end cover is higher than the top surface of the inner frame (23) of the fog inlet end cover, and the top surface of the inner frame (23) of the fog inlet end cover is used for placing the cultivation panel (40).

4. The aerial fog cultivation pipeline of claim 1, wherein the backflow end cover (30) comprises a backflow end cover outer frame plate (32), a backflow end cover inner frame (33) is arranged on one side, butted with the end of the cultivation pipe body (10), of the backflow end cover outer frame plate (32), and a second insertion gap (34) for inserting the end of the cultivation pipe body (10) is formed between the side face of the backflow end cover inner frame (33) and the side face of the backflow end cover outer frame plate (32) at intervals.

5. Aerosol cultivation tube of claim 4,

the bottom shape of the outer frame plate (32) of the backflow end cover is matched with the bottom shape of the cultivation tube body (10), a second convex strip (35) is arranged on the inner side of the bottom of the outer frame plate (32) of the backflow end cover, two ends of the second convex strip (35) are respectively connected with the bottom of the side face of the inner frame (33) of the backflow end cover, and the thickness of the second convex strip (35) is the same as the tube wall thickness of the cultivation tube body (10);

the backflow hole (36) is formed in the lower portion of the backflow end cover outer frame plate (32), and the height of the lower edge of the backflow hole (36) is lower than or equal to the height of the upper surface of the second protruding strip (35).

6. The aerial fog cultivation pipeline of claim 4, wherein the top surface of the inner return end cap frame (33) is slightly lower than the upper edge of the cultivation pipe body (10), the top surface of the outer return end cap frame plate (32) is higher than the top surface of the inner return end cap frame (33), and the top surface of the inner return end cap frame (33) is used for placing the cultivation panel (40).

7. The aerial fog cultivation pipeline as claimed in claim 1, wherein the fog inlet hole (21) is arranged at a position above the middle part of the fog inlet end cover (20), the fog return hole (31) is arranged at a position above the middle part of the fog return end cover (30), and the height of the fog inlet hole (21) is slightly higher than that of the fog return hole (31); after the aerial fog cultivation pipeline is installed, the cultivation pipe body (10) is obliquely arranged, and one end of the fog inlet end cover (20) installed on the cultivation pipe body (10) is higher than one end of the backflow end cover (30).

8. Aerosol cultivation tube according to claim 1,

ear parts (42) which are convenient for carrying or hoisting the cultivation panel (40) are arranged on two sides of the cultivation panel (40);

the lower edges of the two sides of the cultivation panel (40) are provided with grooves (43) matched with the upper edges of the pipe walls of the cultivation pipe bodies (10), and the inner side walls of the grooves (43) are tightly attached to the inner sides of the pipe walls of the cultivation pipe bodies (10).

9. Aerosol cultivation duct according to claim 1, characterized in that the cultivation tubular body (10) comprises a plurality of lengths of cultivation tubular body units (11), adjacent cultivation tubular body units (11) being detachably connected by an intermediate connection (50).

10. Aerial fog cultivation pipe as claimed in claim 9, characterized in that the intermediate connecting member (50) comprises two connecting outer arms (51), each connecting outer arm (51) is provided with a connecting inner arm (52) at the inner side, the middle part of the connecting inner arm (52) is connected with the connecting outer arm (51) through a connecting strip (53), and partition grooves (54) for inserting the cultivation pipe body units (11) are formed at both sides of the connecting strip (53); two the bottom of connecting outer arm (51) is connected through a bottom linkage segment (55), the shape of bottom linkage segment (55) with the bottom shape of cultivation body unit (11) suits, the inboard middle part of bottom linkage segment (55) is equipped with a third sand grip (56), the both ends of third sand grip (56) are respectively with two the bottom of connecting inner arm (52) is connected, the thickness of third sand grip (56) with the wall thickness of cultivation body unit (11) is the same.

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