CN113080142A

CN113080142A - Method for feeding organisms in three-dimensional high density

Info

Publication number: CN113080142A
Application number: CN202110342624.1A
Authority: CN
Inventors: 克学义
Original assignee: Individual
Current assignee: Chongqing Chengkou County Zhiyou Agricultural Development Co ltd
Priority date: 2021-03-30
Filing date: 2021-03-30
Publication date: 2021-07-09
Anticipated expiration: 2041-03-30
Also published as: CN113080142B

Abstract

The invention relates to the field of breeding methods, in particular to a method for breeding organisms in a three-dimensional high density mode. The snail breeding area is set into the circular area, and then the circular area is set into the four fan-shaped areas to respectively breed the snails, so that on one hand, the invention fully utilizes the three-dimensional space to provide a ventilating place for the snails through three-dimensional breeding, on the other hand, the invention can provide feed or twigs for the snails in time to feed the snails and meanwhile collect and clean the feces by the gravity of the feces or sundries, thereby improving the yield of the snails.

Description

Method for feeding organisms in three-dimensional high density

Technical Field

The invention relates to the field of breeding methods, in particular to a method for breeding organisms in a three-dimensional high density mode.

Background

Some snails in the prior art adopt a mode of raising in a greenhouse, vegetable and fruit peels are directly thrown in the greenhouse to be supplied to the snails for eating, food residues and excrement generated by the snails during eating can not be discharged in time, and meanwhile, the snails like to crawl around and hide in corners, so that the snails are inconvenient to collect.

Disclosure of Invention

In order to solve the problems of the prior art, the invention provides a method for feeding organisms in a three-dimensional high-density manner.

In order to achieve the purpose, the invention adopts the following technical scheme:

a method for feeding organisms in a three-dimensional high density comprises the following steps:

inserting the sealing sieve plate of the sealing sieve net into the insertion gap to enable the plastic net to be close to one side of the culture area;

unzipping the zipper, inserting the branch B with the tender leaves along the adjacent side bracket grooves, clamping the branch B with the tender leaves into the side bracket grooves without displacement, and simultaneously enabling the branch B to be regularly placed by the side bracket grooves;

the partition plate is made of a stainless steel plate and is inserted into the discharge window in a matching mode;

feeding the seed snails from the opening gaps, and then zipping the zipper;

preparing a trolley in advance, integrally fixing a separation frame on the edge of the upper part of a trolley chassis, wherein the cross section of the separation frame is in a shape of inverted L, the trolley chassis is divided into an upper layer and a lower layer by the separation frame, the upper layer is provided with a culture platform area, the lower layer is provided with a waste collection box, and the waste collection box is positioned on the upper part of the trolley chassis and the lower part of the separation frame;

a material collecting groove is arranged in the breeding platform area, the material collecting groove is of a funnel-shaped structure, a waste material discharge port is arranged at the bottom of the material collecting groove, and the waste material discharge port faces the waste material collecting box;

a support upright post is arranged on the breeding platform area, the support upright post is positioned on one side of the edge of the gathering groove, a slotted hole is formed in one side of the upper portion of the support upright post, a bearing is fixed in the slotted hole, an inner ring of the bearing is fixedly connected with the outer wall of one end of a rotating shaft, the rotating shaft penetrates through an inner sleeve, the center lines of the inner ring and the outer ring are coincident with the center line of the rotating shaft, the inner ring and the outer ring are positioned on the upper portion of the gathering groove, a nut is arranged at one end, close;

feed particles or corn flour are added into the discharging groove,

the inner ring is rotated to enable the inner ring to rotate relative to the bearing, feed particles or corn flour in the rotating discharge groove continuously enter the culture areas on two sides through the discharge hole to feed snails, and meanwhile, the snails can enter the main trunk groove and the side bracket grooves for rest on one hand and can feed tender leaves on the branches B on the other hand;

when the culture area rotates to the upper position, the partition plate is changed into a filter screen-shaped structure from a stainless steel plate, excrement and food residues generated by the snails leak into the central ring through the partition plate, and when the culture area rotates to the bottom, the partition plate is changed into the stainless steel plate from the filter screen-shaped structure, so that waste materials in the central ring are prevented from entering the culture area again;

when the snails need to be separated, the sealing screen can be directly placed on the rubber column in a flat mode, the rubber column is distributed in a circular mode and is made of elastic rubber materials, the outer side of the rubber column is fixedly provided with the stand column, the spring is fixedly arranged on the stand column, the height of the stand column is larger than that of the rubber column, the stand column and the spring are distributed in a circular mode, the upper portion of the spring is in close contact with the bottom of the inner ring, the snails can be separated from the inner ring by shaking the inner ring, and most of the snails fall into the sealing screen from the breeding;

the inner side of the outer ring is provided with an inner ring, the inner side of the inner ring is provided with a central ring, the outer ring, the inner ring and the central ring are coaxial, a cultivation area is arranged between the outer side of the central ring and the inner side of the inner ring, the number of the cultivation areas is four, a discharge chute is arranged between adjacent cultivation areas, a branch cultivation limiting frame is arranged in the cultivation area and used for inserting branches containing tender leaves into the branch cultivation limiting frame so as to limit and fix the branches, and then the snails are fed with the tender leaves on the branches step by step through the branch cultivation limiting frame; the outer ring and the inner ring are fixedly connected, the inner ring and the central ring are fixedly connected through a connecting rod,

the discharge chute is used for dispersing corn flour, bran or feed particles, so that the feed particles can enter the breeding area through the discharge chute and are supplied to the snails for eating;

an insertion gap is formed between the outer ring and the inner ring and used for inserting a sealing screen, and one side of the inner ring is blocked by the sealing screen;

the other side of the inner ring is provided with a gauze, the gauze isolates the other side of the inner ring from the outside, the gauze is provided with an opening gap at the upper part of each breeding area, the opening gap is closed and opened through a zipper, the snail is bred by setting the area for breeding the snail into a circular area and then setting the circular area into four fan-shaped areas, one side of the area for breeding the snail is plugged through a screen mesh to avoid the snail from escaping, the other side of the area for breeding the snail is plugged through the gauze, the gauze prevents the snail from escaping from the other side of the area for breeding the snail, and meanwhile, the snail food can be replaced through the opening and closing of the gauze.

The outer ring is annular and the outer ring width is 300-500mm, the inner ring is annular and the inner ring width is 300-500mm, the outer ring and the inner ring width are consistent, the diameter of the inner ring is smaller than that of the outer ring, the circle centers of the outer ring and the inner ring are overlapped, the outer edges of the outer ring and the inner ring are aligned, and the difference value between the diameter of the outer ring and the diameter of the inner ring is the width of the insertion gap.

The outer ring and the inner ring are fixedly connected through the discharge chute, the upper portion of the discharge chute penetrates through the inner ring, the discharge chute penetrates through the outer ring upwards and protrudes out of the outer surface of the outer ring upwards all the time, and the outer wall of the discharge chute is fixedly connected with the inner ring and the outer ring.

The blown down tank is cavity square tubular structure, blown down tank one end and central circle lateral wall fixed connection, and the blown down tank other end runs through inner circle and upper portion salient in outer lane surface, and the blown down tank both sides wall link up and sets up the discharge opening, and the discharge opening is the round hole form, and discharge opening quantity is a plurality of and is covered over the blown down tank both sides wall, and the blown down tank is four regions with regional division between inner circle and the central circle.

The invention has the beneficial effects that: the invention can fully utilize the three-dimensional space to provide a ventilating place for the snail by three-dimensional feeding, can provide feed or twigs for the snail to eat in time and can collect and clean the excrement by the gravity of the excrement or sundries, thereby improving the output of the snail.

Drawings

Fig. 1 is a schematic front view of the present invention.

Fig. 2 is a rear view structure diagram of the present invention.

FIG. 3 is a schematic view of the inner and outer rings and the center ring of the present invention.

Fig. 4 is a schematic top view of the present invention.

Fig. 5 is a schematic view of the structure of the upper cover of the present invention.

Fig. 6 is a side view of the center ring of the present invention.

FIG. 7 is a schematic side view of the present invention screen.

Fig. 8 is a schematic top view of the screen of the present invention.

Fig. 9 is a schematic view of the front view structure of the branch feeding limiting frame of the invention.

FIG. 10 is a schematic side view of the branch feeding limiting frame of the present invention.

Fig. 11 is a schematic diagram of the structure at a in fig. 3.

Fig. 12 is a schematic structural diagram of the snail breeding time.

Fig. 13 is a schematic structural diagram of the snail collecting device of the present invention.

Fig. 14 is a schematic structural diagram of a top view of the rubber column of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the following examples, which are provided only for illustrating the present invention and are not intended to limit the scope of the present invention.

In a method for feeding living organisms in a high density in a three-dimensional manner as shown in FIGS. 1 to 14, a screen plate 122 of a screen sealing net 12 is inserted into an insertion gap 11 so that a plastic net 121 is adjacent to one side of a culture region 4;

the zipper 212 is unzipped, the branch B with the tender leaves is inserted along the adjacent side bracket groove 52, the branch B with the tender leaves is clamped into the side bracket groove 52 and does not shift, and meanwhile, the branch B can be regularly placed by the side bracket groove 52;

the partition plate 320 is made of stainless steel plate, and the partition plate 320 is inserted into the discharge window 31 in a matching manner

The seed snail is fed in from the opening slit 211, and then the zipper 212 is pulled up;

preparing a trolley 7 in advance, integrally fixing a separation frame 72 on the upper edge of a trolley chassis 71, wherein the cross section of the separation frame 72 is in a shape of inverted L, the trolley chassis 71 is divided into an upper layer and a lower layer by the separation frame 72, the upper layer is provided with a culture platform area 8, the lower layer is provided with a waste collection box 9, and the waste collection box 9 is positioned on the upper part of the trolley chassis 71 and the lower part of the separation frame 72.

A material collecting groove 81 is arranged in the breeding platform area 8, the material collecting groove 81 is of a funnel-shaped structure, a waste material outlet 811 is arranged at the bottom of the material collecting groove 81, and the waste material outlet 811 faces the waste material collecting box 9;

the breeding platform area 8 is provided with a support upright post 82, the support upright post 82 is positioned on one side of the edge of the gathering groove 81, one side of the upper part of the support upright post 82 is provided with a slotted hole 821, a bearing 822 is fixed in the slotted hole 821, the inner ring of the bearing 822 is fixedly connected with the outer wall of one end of a rotating shaft 824, the rotating shaft 824 penetrates through the inner sleeve 32, the center lines of the inner ring 2 and the outer ring 1 are coincident with the center line of the rotating shaft 824, the inner ring 2 and the outer ring 1 are positioned on the upper part of the gathering groove 81, the rotating shaft 824 is provided with a nut 825 at one end close to the;

feed particles or corn flour are added into the discharging groove 6,

rotating the inner ring 2 to enable the inner ring 2 to rotate relative to the bearing 822, enabling feed particles or corn flour in the discharging groove 6 to continuously enter the culture areas 4 on two sides through the discharging holes 61 during rotation to feed the snails, and meanwhile enabling the snails to enter the main groove 51 and the side bracket grooves 52 for rest on one hand and to feed tender leaves on the branches B on the other hand;

when the culture area 4 rotates to the upper position, the partition plate 320 is changed into a filter screen-shaped structure from a stainless steel plate, excrement and food residues generated by the snails leak into the central ring 3 through the partition plate 320, and when the culture area 4 rotates to the bottom, the partition plate 320 is changed into the stainless steel plate from the filter screen-shaped structure, so that waste materials in the central ring 3 are prevented from entering the culture area 4 again;

can directly keep flat the screen cloth 12 of sealing to rubber column 101 when needing the separation snail, rubber column 101 is circular form and distributes, rubber column 101 chooses for use the elastic rubber material to constitute, the fixed stand 102 in rubber column 101 outside, fixed spring 103 on the stand 102, stand 102 height is greater than the height of rubber column 101, stand 102 and spring 103 are circular form and distribute, spring 103 upper portion and inner circle 2 bottom are close to the contact, it can break away from snail and inner circle 2 to rock inner circle 2, most snails drop to the completion from breeding district 4 and collect in sealing screen cloth 12.

The inner side of the outer ring 1 is provided with an inner ring 2, the inner side of the inner ring 2 is provided with a central ring 3, the outer ring 1, the inner ring 2 and the central ring 3 are coaxial, a breeding area 4 is arranged between the outer side of the central ring 3 and the inner side of the inner ring 2, the number of the breeding areas 4 is four, a discharge chute 6 is arranged between the adjacent breeding areas 4, a branch breeding limiting frame 5 is arranged in the breeding area 4, the branch breeding limiting frame 5 is used for inserting branches containing tender leaves into the branch breeding limiting frame to limit and fix the branches, and then the snails are fed with the tender leaves on the branches step by step through the branch breeding limiting frame 5; the outer ring 1 and the inner ring 2 are fixedly connected, the inner ring 2 and the central ring 3 are fixedly connected through a connecting rod 321,

the discharge chute 6 is used for dispersing corn flour, bran or feed particles, so that the feed particles can enter the breeding area 4 through the discharge chute 6 to feed snails;

an insertion gap 11 is arranged between the outer ring 1 and the inner ring 2, the insertion gap 11 is used for inserting a sealing screen 12, and the sealing screen 12 seals one side of the inner ring 2;

the gauze 21 is arranged on the other side of the inner ring 2, the gauze 21 isolates the other side of the inner ring 2 from the outside, so that snails are prevented from escaping, meanwhile, the snails can be fed into or taken out of the food materials through the gauze 21, the gauze 21 is provided with an opening gap 211 on the upper portion of each cultivation area 4, the opening gap 211 is closed and opened through a zipper 212, and the opening gap 211 is used for replacing branches in the cultivation areas 4. The snail breeding area is set to be a circular area, the circular area is set to be four fan-shaped areas, the snails are respectively bred, one side of the snail breeding area is blocked through the sealing screen 12, the snails are prevented from escaping, the other side of the snail breeding area is blocked through the screen 21, the screen 21 prevents the snails from escaping from the other side of the snail breeding area, and meanwhile, the snail food materials can be replaced through opening and closing of the screen 21. The invention has the general conception that snails are housed between an inner ring 2 and a central ring 3, both sides of the inner ring 2 are provided with a structure of a breathable gauze 21 or a sealed screen 12, so that ventilation is facilitated, the air in a snail housing area is prevented from being turbid, meanwhile, the sprinkling operation for the snail housing area through the gauze 21 or the sealed screen 12 is facilitated, the food can be conveniently placed and the food waste residues convenient for snails to eat can be automatically discharged by utilizing gravity through the vertical placement of the inner ring 2 and the central ring 3, on one hand, branches are firmly fixed by a branch feeding limiting frame 5, the branches are prevented from being arranged in disorder, on the other hand, the branch feeding limiting frame 5 can facilitate the snails to crawl and rest, the area of a place where the snails are stored and rest is increased, and simultaneously, the snails can climb into grooves at the bottom of the branch feeding limiting frame 5, on the one hand, the branches can shield the body of the snails so as to be convenient for the snails to store, on the other hand, the snails in the grooves can climb out of the grooves at any time to directly eat young leaves on branches in the grooves, so that the snails are favorable for growth, feed particles can be supplied to the snails through the discharge chute 6 at any time along with the rotation of the inner ring 2 in the process of feeding the snails, the snails can absorb food materials with different nutritional ingredients, the snails can grow favorably, on the other hand, excrement and food residues generated by the rotating snails through the inner ring 2 and the central ring 3 leak into the central ring 3 under the action of self gravity, and the excrement and the food residues generated in the eating process are collected through the central ring 3 in time, so that a clean and sanitary environment is provided for the growth of the snails.

The outer ring 1 is annular and the width of the outer ring 1 is 300-500mm, the inner ring 2 is annular and the width of the inner ring 2 is 300-500mm, the widths of the outer ring 1 and the inner ring 2 are consistent, the diameter of the inner ring 2 is smaller than the diameter of the outer ring 1, the circle centers of the outer ring 1 and the inner ring 2 are overlapped, the outer edges of the outer ring 1 and the inner ring 2 are aligned, and the difference value between the diameter of the outer ring 1 and the diameter of the inner ring 2 is the width of the insertion gap 11.

The outer ring 1 and the inner ring 2 are fixedly connected through the discharge chute 6, the upper part of the discharge chute 6 penetrates through the inner ring 2, the discharge chute 6 upwards penetrates through the outer ring 1 and upwards protrudes out of the outer surface of the outer ring 1, and the outer wall of the discharge chute 6 is fixedly connected with the inner ring 2 and the outer ring 1. On the one hand, the discharge chute 6 plays a role in connecting the inner ring 2 and the outer ring 1, and on the other hand, the inlet end of the discharge chute 6 is positioned outside the outer ring 1, so that the discharge chute 6 is conveniently filled with feed, and meanwhile, the discharge chute 6 can spill the feed in the discharge chute 6 into a breeding area through a discharge hole in the side wall of the discharge chute 6 to feed snails.

Please refer to fig. 3 and 6, the discharging chute 6 is a hollow square tubular structure, one end of the discharging chute 6 is fixedly connected with the outer sidewall of the central ring 3, the other end of the discharging chute 6 penetrates through the inner ring 2, and the upper portion of the discharging chute 6 protrudes out of the outer surface of the outer ring 1, i.e. one end of the discharging chute 6 close to the central ring 3 is sealed, one end of the discharging chute 6 protruding out of the outer ring 1 is open, two side walls of the discharging chute 6 are provided with discharging holes 61 in a penetrating manner, the discharging holes 61 are circular holes, the number of the discharging holes 61 is several, and the discharging chute 6 is fully distributed on two side walls of the discharging chute 6, and the region. Along with the rotation of blown down tank 6, thereby the fodder in the blown down tank 6 can be discharged by discharge opening 61 along with the rotation and be convenient for spill the fodder to breeding in the district 4.

Referring to fig. 1, 4 and 5, an outlet end of the discharging chute 6 is provided with an upper cover 62, the upper cover 62 is a hollow cuboid structure, one end of the upper cover 62 is open, the other end is sealed, an open end of the upper cover 62 is inserted into the outlet end of the discharging chute 6, and the upper cover 62 is matched with an outlet of the discharging chute 6. Thereby can through 62 locks of upper cover when need not toward the interior packing fodder of blown down tank 6 on blown down tank 6 seal the exit end of blown down tank 6 and avoid the fodder to spill over, thereby can avoid the fodder to spill over in the port of blown down tank 6 with 62 locks of upper cover in blown down tank 6 when needing toward adding the fodder in blown down tank 6.

Referring to fig. 7 and 8, a plastic mesh 121 is disposed at the bottom of the screen cloth 12, the plastic mesh 121 is circular, the diameter of the plastic mesh 121 is the same as that of the inner ring 2, a screen sealing plate 122 is fixed at the edge of the plastic mesh 121, the screen sealing plate 122 is circular, the height of the screen sealing plate 122 is the same as that of the inner ring 2, the screen sealing plate 122 is inserted into the insertion gap 11, and the plastic mesh 121 is attached to one side of the inner ring 2. After the sealing screen 12 is attached to the inner ring 2 through the sealing screen plate 122 and the insertion gap 11, on one hand, the snails can be prevented from escaping from one side of the inner ring 2 through the plastic net 121, on the other hand, the ventilation and air permeability of the snail breeding area 4 can be increased, meanwhile, the plastic net 121 is of a net structure with small aperture, the feed is prevented from overflowing and escaping from the snails, meanwhile, the snails can be collected through the sealing screen 12 in a concentrated mode when being collected at the later stage, and then the snails are collected through the separation of the sealing screen 12 and the inner ring 2.

The upper part of the sealing sieve plate 122 is provided with limiting grooves 1221, the cross section of the limiting grooves 1221 is U-shaped, the number of the limiting grooves 1221 is four, the limiting grooves 1221 are evenly distributed on the sealing sieve plate 122, and when the sealing sieve plate 122 is inserted into the insertion gap 11, the limiting grooves 1221 are close to the discharge grooves 6 in the insertion gap 11. The limiting groove 1221 is matched with the discharge chute 6 to avoid the sealing sieve plate 122 to be staggered with the screen cloth 12, and the sealing sieve plate 122 can be firmly embedded into the insertion gap 11 through the contact of the limiting groove 1221 and the discharge chute 6 without displacement.

Form breed district 4 between the discharge chute 6 and between 3 outer walls of center circle in inner circle 2, breed district 4 is the fan-shaped form, and breed 4 quantity in district is four, cuts apart by discharge chute 6 between the adjacent breed district 4, and 4 one side upper surfaces in breed district are sealed by sieve 122 shutoff, and 4 opposite side upper surfaces in breed district are wrapped up by gauze 21, and gauze 21 middle part sets up opening gap 211, and opening gap 211 department sets up zip fastener 211. The breeding area 4 can be used as a main place for the growth and rest of the snails, one side of the breeding area can be used for discharging materials, and the other side of the breeding area can be used for collecting the snails in the later period, so that the breeding efficiency of the snails is improved.

Set up the branch in the breed district 4 and raise spacing 5, the spacing 5 quantity is three for the branch is raised, 5 one end of spacing groove and 3 outer walls of center circle are connected fixedly mutually to the branch, the spacing groove 5 is raised to the branch and is unsettled in the breed district 4, the crossing point that spacing groove 5 one end was raised to the branch was located between the blown down tank 6 with 3 outer walls of center circle simultaneously, spacing 5 equidistant settings are raised to adjacent branch, spacing groove 5 is raised to the branch is used as the place that the snail had rest and eat, it distributes and does benefit to the snail in the breed district 4 and moves about in the breed district 4 in the district 4, lie in the feed that spills in the blown down tank 6 between the blown down tank 6 simultaneously and supply to the snail's in the.

Please refer to fig. 3, 9 and 10, the branch feeding limiting frame 5 comprises a main trunk groove 51 and side support grooves 52, the side support grooves 52 are arranged on both sides of the main trunk groove 51, the height of the upper end surface of the side support grooves 52 is greater than that of the main trunk groove 51, the side support grooves 52 are used as the passage for the snails to enter and exit from the main trunk groove 51, the side support grooves 52 are used as the fixing limiting position of the branches, the branches can be arranged in the culture area 4 in an arc shape to feed the snails, and the snails in the branches in the arc shape rest when passing through the main trunk groove 51 because the snails rest in the main trunk groove 51, so the snails can conveniently climb to the tender buds on the branches.

The main trunk groove 51 body is rectangular, the transverse section of the trunk groove 51 is arc-shaped, one end of the trunk groove 51 is fixedly connected with the outer wall of the central ring 3, the other end of the trunk groove 51 protrudes into the culture area 4, the other end of the trunk groove 51 is located at a position close to the inner ring 2, an inlet end 511 is arranged at one side of one end of the trunk groove 51 close to the inner ring 2, and the inlet end 511 is open and used for enabling a snail to enter the trunk groove 51 from the inlet end 511. The inlet end 511 is used for the snails to climb in and out, is beneficial to the snails to eat branches and rest,

the side wall of the trunk groove 51 is provided with a placing groove 512, the placing groove 512 is arc-shaped, the placing groove 512 penetrates through the side wall of the trunk groove 51, the upper end surface of the placing groove 512 is flush with the upper end surface of the side wall of the trunk groove 51, and the side bracket grooves 52 are inserted into the placing groove 512 in a matching manner. The side bracket slots 52 are fitted with the mating card at one end into the placement slot 512, so that the side bracket slots 52 can be quickly inserted and extracted.

The side bracket slot 52 comprises a first side slot 521, a second side slot 522, a third side slot 523 and a fourth side slot 524, the transverse sections of the first side slot 521, the second side slot 522, the third side slot 523 and the fourth side slot 524 are all arc-shaped, the upper end surfaces and the side end surfaces of the first side slot 521, the second side slot 522, the third side slot 523 and the fourth side slot 524 are all open, the bottoms of the first side slot 521, the second side slot 522, the third side slot 523 and the fourth side slot 524 are fixedly connected with the side wall of the placing slot 512, the upper end surfaces of the first side slot 521, the second side slot 522, the third side slot 523 and the fourth side slot 524 are higher than the upper end surface of the main slot 51, the first side slot 521 is positioned on the side close to the end of the main slot 51, and the second side slot 522 is positioned on the side far away from the end of the,

the side groove three 523 is positioned at the other side close to the end part of the main groove 51, the side groove four 524 is positioned at the other side far from the end part of the main groove 51, and the side groove one 521, the side groove two 522, the side groove three 523 and the side groove four 524 are arranged at intervals. The first side groove 521, the second side groove 522, the third side groove 523 and the fourth side groove 524 are distributed at intervals, so that the space utilization rate is improved, the branches can be regularly limited, and the branches are prevented from being placed and stacked in a disordered manner.

Please refer to fig. 6 and 11, the material discharging window 31 is disposed between the adjacent main grooves 51 on the outer wall of the central ring 3, the material discharging window 31 is rectangular, the material discharging window 31 penetrates the side wall of the central ring 3, the material discharging window 31 is disposed on the side wall of the central ring 3, the material discharging window 31 penetrates the side wall of the upper portion of the central ring 3, the partition 320 is inserted into the material discharging window 31, the upper portion of the partition 320 protrudes from the upper end surface of the central ring 3, the partition 320 is made of stainless steel mesh or stainless steel plate, when the stainless steel mesh is selected, the partition 320 can leak materials due to the mesh structure, so the snail excretions accumulated in the breeding area 4 are discharged into the central ring 3 through the stainless steel mesh when the breeding area 4 rotates along with the inner ring 2 and the outer ring 1 to be located at the upper portion, when the stainless steel plate is selected, when the breeding area 4 rotates along with the inner ring 2 and the outer ring 1 to be located at the lower, the waste material accumulated in the central ring 3 is prevented from entering the culture area 4 again.

The central ring 3 comprises an outer central ring 31 and an inner sleeve 32, the outer central ring 31 is hollow cylinder, the central line of the outer central ring 31 coincides with the central lines of the inner ring 2 and the outer ring 1, the width of the outer central ring 31 is consistent with the width of the inner ring 2 and the outer ring 1, the outer edge of the outer central ring 31 is flush with the outer edges of the inner ring 2 and the outer ring 1, one end of the outer central ring 31 is sealed, the other end of the outer central ring 31 is open, a bottom plate 311 is integrally arranged at one end of the outer central ring 31, an opening 312 is arranged at the other end of the outer central ring 31, the inner sleeve 32 is arranged at the center of the outer central ring 31, the inner sleeve 32 is hollow cylinder, the outer wall of the inner sleeve 32 is fixedly connected with the inner wall of the outer central ring 31 through a connecting rod 321, an opening cover 3121 is embedded in the opening 312, the opening cover 3121 is detachably arranged to facilitate cleaning impurities in, the other end of the inner sleeve 32 passes through the base plate 311.

The structures not indicated by the present invention are common structures that should be known to those skilled in the art, and the connection modes not indicated by the present invention are common connection modes that should be known to those skilled in the art.

The foregoing is directed to preferred embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow. However, any simple modification, equivalent change and modification of the above embodiments according to the technical essence of the present invention are within the protection scope of the technical solution of the present invention.

Claims

1. A method for feeding organisms in a three-dimensional high density manner is characterized by comprising the following steps:

feeding the seed snails from the opening gaps, and then zipping the zipper;

feed particles or corn flour are added into the discharging groove,

2. The method as claimed in claim 1, wherein the outer ring is annular and the outer ring has a width of 300-.

3. The method for feeding the biosolids in the high density according to claim 1, wherein the outer ring and the inner ring are fixedly connected through a discharge chute, the upper part of the discharge chute penetrates through the inner ring and the discharge chute penetrates through the outer ring upwards and protrudes upwards from the outer surface of the outer ring, and the outer wall of the discharge chute is fixedly connected with the inner ring and the outer ring.

4. The method for feeding the biosolids at high density according to claim 1, wherein the discharge chute is of a hollow square tubular structure, one end of the discharge chute is fixedly connected with the outer side wall of the central ring, the other end of the discharge chute penetrates through the inner ring, the upper part of the discharge chute protrudes out of the outer surface of the outer ring, two side walls of the discharge chute are provided with discharge holes in a penetrating manner, the discharge holes are round holes, the number of the discharge holes is several, the discharge holes are fully distributed on two side walls of the discharge chute, and the discharge chute divides the area between the inner ring and the central ring into.