CN115885945A - Splicing ampullaria gigas catching device - Google Patents

Abstract

The invention discloses a splicing ampullaria gigas catching device, which relates to the technical field of ampullaria gigas catching and comprises collecting boxes and a fixing mechanism, wherein two adjacent collecting boxes are attached together by opposite side walls, each collecting box is installed on the bank side of a catching water area through the fixing mechanism, the fixing mechanism comprises a cross beam and two L-shaped pressing plates, the two L-shaped pressing plates are fixedly arranged at two ends of one side of the cross beam respectively, a splicing steel chisel is hinged to the middle section of the other side of the cross beam, a cavity for collecting the ampullaria gigas is arranged in each collecting box, a plurality of inlets which are uniformly distributed at intervals from top to bottom and are communicated with the interior of the cavity are formed in the front end face of each collecting box, and a sealing block is rotatably arranged on the side wall of the upper side of an opening at one end, close to the cavity, of each inlet. According to the invention, a plurality of collecting boxes are arranged according to the width of the shore of the capturing water area, each collecting box is arranged on the shore of the capturing water area through a fixing mechanism, and the ampullaria gigas climb up the shore to lay eggs and enter the cavities of the collecting boxes through inlets, so that the ampullaria gigas can be captured in batches.

Description

Splicing ampullaria gigas catching device

Technical Field

The invention relates to the technical field of ampullaria gigas capture, in particular to a splicing ampullaria gigas capture device.

Background

The ampullaria gigas is mollusk of the family Virididae and genus Virididae, the shell appearance is similar to that of the river snail, the ampullaria gigas has a spiral snail shell, the color is different according to the environment and the age of the snail, the ampullaria mollusk has luster and a plurality of fine longitudinal lines, the head and the ventral legs extend out during crawling, the ampullaria gigas has strong survival ability adapting to the environment and can propagate quickly in rivers, lakes and fields, so that the plant ecosystem of crops and rivers is damaged greatly, in addition, the ampullaria gigas can be eaten by mistake after being picked up by people to cause safety problems, so that the ampullaria gigas need to be cleaned in a large range.

Disclosure of Invention

The invention aims to provide a splicing ampullaria gigas capturing device to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a fushou snail trapping apparatus that can splice, including collecting box and fixed establishment, it is equipped with a plurality of to collect the box, adjacent two collect box relative lateral wall laminating together, every is collected the box and all installs the bank in catching the waters through fixed establishment, set up a plurality of collection boxes according to catching waters bank width, a plurality of collection box that will set for is a style of calligraphy structure along the bank and arranges, and install the bank in catching the waters through fixed establishment, ensure simultaneously that adjacent collection box laminating is in the same place, avoid two adjacent collection boxes between to produce the gap, lead to the fushou snail to pass the gap and climb the bank of laying eggs.

The fixing mechanism comprises a cross beam and two L-shaped pressing plates, the two L-shaped pressing plates are respectively fixedly arranged at two ends of one side of the cross beam, a splicing steel chisel is hinged to the middle section of the other side of the cross beam, a torsional spring is arranged at the hinged position, torsional potential energy of the torsional spring is utilized, the cross beam drives the two L-shaped pressing plates to have the trend of pressing down the collecting box in real time, the collecting box can be stably located on the soil on the bank, and the situation that the gap between the bottom end surface of the collecting box and the soil on the bank is caused to lead to the ampullar snails to pass through the gap to climb to the bank is avoided.

In catching waters bank earth with the embedding of grafting drill rod, two L type clamp plates can closely the pressfitting in the upper end both sides of collecting the box, and the tip of L type clamp plate position of bending can the pressfitting in the preceding terminal surface and the up end handing-over position of collecting the box, collect the box bottom end face and the bank earth laminating of catching the waters, avoid collecting the box bottom end face and appear the gap between the offshore side earth and lead to the porthole snail to pass the gap and climb the bank.

Collect the inside cavity that is used for collecting the ampullaria gigas that is equipped with of box, the preceding terminal surface of collecting the box set up a plurality of about even interval distribution and with the import of the inside intercommunication of cavity, a plurality of collection boxes that are in the same place side by side have blockked the passageway on the bank of ampullaria gigas, the ampullaria gigas crawl along the preceding terminal surface of collection box, get into the cavity of collecting the box through the import in, realize catching the batch of ampullaria gigas.

After a certain time, the ampullaria gigas collected in the collecting box are led out to be subjected to centralized killing operation, so that the situation that the ampullaria gigas is propagated carelessly to destroy ecological balance is avoided.

The wantonly of ampullaria gigas breeds and causes very big destruction to crops and the plant ecosystem in river lake, in addition, also can be picked up by people and make the back food and eat by mistake, cause the safety problem, there is the mode that adopts chemical agent to clear up and kill and the artifical mode of catching to clear up ampullaria gigas among the prior art, but the mode that adopts chemical agent easily causes the pollution to the water, the mode efficiency of artifical seizure is too low, can't satisfy the high-efficient clearance demand to ampullaria gigas, catch the oviferous ampullaria gigas of going to the bank through the collection box that sets up on the bank, replace manpower and the mode of chemical killing, the efficiency of catching improves greatly.

The import is close to the rotation of one end opening upside lateral wall of cavity and is equipped with sealed piece, and sealed piece receives self gravity to influence and can seal the import around the automatic lower pendulum of rotational position, avoids climbing the longevity spiral shell in the cavity and climbs out from the import.

The utility model discloses a sealed piece of fortune longevity spiral shell is upwards crawled along collecting the box front end, climb up the sealed piece of jack-up in the import, make sealed piece can upwards overturn around the turned position, can open the import, make the fortune longevity spiral shell can get into in the cavity smoothly, after in the full entering cavity of fortune longevity spiral shell, sealed piece application of force apical force then can seal the import once more around the automatic lower pendulum of turned position after, can enough satisfy the smooth entering cavity of fortune longevity spiral shell, can avoid again that the fortune longevity spiral shell that gets into in the cavity climbs out and flees, ensure that the catching operation of fortune longevity spiral shell is high-efficient to go on.

In further embodiment, the inside upper and lower both sides lateral wall of import is parallel and all distribute to being close to the inside one side top slope of cavity, and when the ampullaria gigas crawled along collecting box front end face and passed through the import, help the ampullaria gigas can continue to crawl along washing the import inner wall that upwards distributes, until the ampullaria gigas crawls in the cavity completely.

In a further embodiment, two adjacent fixing mechanisms are connected through a connecting piece, and the stability of the fixing mechanisms arranged on the shore is further enhanced by using the connecting piece, so that the stability of the collecting box is enhanced.

The connecting piece is door type grafting pole, and the outer wall symmetry of grafting drill rod is fixed to be equipped with two grafting sleeves, and door type grafting pole runs through respectively two adjacent grafting drill rods and imbeds in bank earth behind the two grafting sleeves that are close to each other, avoids fixed establishment's grafting drill rod to insert bank earth after the horizontal hunting.

In further embodiment, door type peg graft pole both ends are rotated through the external screw thread and are cup jointed threaded sleeve, and threaded sleeve's external diameter is the same with the telescopic external diameter of pegging graft, ensures to rotate the threaded sleeve who pushes down and can effectively push down the grafting sleeve, and door type peg graft pole runs through after the grafting sleeve in embedding bank earth, bare-handed screw sleeve rotates, closely presses in the grafting sleeve upper end until threaded sleeve bottom, can strengthen the stability in the grafting drill rod embedding earth.

In further embodiment, the discharge gate has been seted up to the upper end of collecting the box, and the discharge gate is inside to be equipped with to prevent that the longevity spiral shell from climbing at will in collecting the cavity of box from separating stop gear, utilizes stop gear to set up at the discharge gate for prevent that the longevity spiral shell from climbing at will in the discharge gate and separating, simultaneously, stop gear can assist to derive the longevity spiral shell from the discharge gate.

In further embodiment, stop gear includes the cavity carriage, and the cavity carriage is fixed embedded inside the discharge gate, is equipped with a plurality of wire ropes between the inside both sides lateral wall of cavity carriage, is equipped with the clearance between two adjacent wire ropes, and under the state of no external force intervention, the clearance between two adjacent wire ropes is less than the individual width of ampullaria gigas, avoids ampullaria gigas to cross the clearance at will and climbs away from the collection box.

When exporting the ampullaria gigas, take out the back and invert from the bank with collecting the box for the opening of discharge gate is down, struts two adjacent wire rope, makes the clearance enlarge, and shakes the collection box about the quick, can derive the ampullaria gigas from the clearance between the wire rope of being propped up.

In a further embodiment, the front side wall and the rear side wall of the bottom end of the hollow supporting frame are vertically fixedly provided with backup plates, a transmission rod is inserted between the two backup plates in a rotating mode, a plurality of shifting rods which are opposite to the gaps between the two adjacent steel wire ropes are fixedly arranged on the outer wall of the transmission rod, the transmission rod is rapidly rotated between the two backup plates, the shifting rods perform circular motion by taking the transmission rod as a center, the ampullaria gigas located between the two adjacent steel wire ropes can be unfolded and pulled out, and the exporting efficiency of the ampullaria gigas is accelerated.

One end of the transmission rod rotates to penetrate through the backup plate and the side wall of the collection box and then extends to the outer side of the collection box, a crank is fixedly arranged at the end of the transmission rod, the crank is held by bare hands and rotates by taking the transmission rod as a center, the transmission rod can be driven to rotate, and therefore the driving lever can be driven to rotate and is used for driving and guiding the ampullaria gigas.

In a further embodiment, the outer wall of each shifting lever is fixedly sleeved with a spherical jacking block, the spherical jacking blocks on two adjacent shifting levers are distributed in a staggered mode, and when the shifting lever rotates, the spherical jacking blocks can be used for expanding the gap between two adjacent steel wire ropes, so that the ampullaria gigas can rapidly cross the gap and be led out.

In further embodiment, the dashpot has all been seted up to the inside both sides lateral wall of cavity carriage, the fixed oval stainless steel ring that is equipped with of one side lateral wall of notch is kept away from to the inside of dashpot, wire rope's both ends extend to respectively in two dashpots and respectively with two oval stainless steel ring outer wall fixed connection, when two adjacent wire rope are strutted, wire rope's both ends can slide along the dashpot inside that corresponds separately respectively, oval stainless steel ring receives wire rope's traction force can be by tensile deformation simultaneously, length difference when this compensation wire rope is strutted.

After the steel wire ropes lose the external force, the oval stainless steel rings reset to tension the steel wire ropes, and the gap between every two adjacent steel wire ropes is reset to the size of the initial state again.

Compared with the prior art, the invention has the beneficial effects that:

the invention relates to a splicing ampullaria gigas catching device, wherein a plurality of collecting boxes are arranged according to the width of a water catching area bank, opposite side walls of two adjacent collecting boxes are attached together, each collecting box is installed on the bank of the water catching area through a fixing mechanism, namely, an inserted steel chisel is embedded into soil on the bank of the water catching area, two L-shaped pressing plates can be tightly pressed on two sides of the upper end of each collecting box, the end bending parts of the L-shaped pressing plates can be pressed on the intersection positions of the front end surface and the upper end surface of each collecting box, the bottom end surface of each collecting box is attached to the soil on the bank of the water catching area, the ampullaria gigas are prevented from passing through gaps between the bottom end surface of each collecting box and the soil on the bank of the water catching area and climbing to the bank through the gaps, when the ampullaria gigas lay eggs, the ampullaria gigas which lay eggs on the bank are caught through the collecting boxes arranged on the bank, a plurality of collecting boxes which are arranged together block the passages on the ampullaria gigas, and the bank, the ampullaria gigas climb along the front end surfaces of the collecting boxes and enter a cavity of the collecting boxes through inlets, so that the ampullaria gigas can be caught in batches.

Drawings

FIG. 1 is a schematic view of the main structure of the present invention;

FIG. 2 is a schematic view of the fixing mechanism and the connecting member according to the present invention;

FIG. 3 is a schematic view of a connector structure of the present invention;

FIG. 4 is a schematic view of the construction of the collecting box of the present invention;

FIG. 5 is a sectional view showing the structure of the collecting box of the present invention;

FIG. 6 is an enlarged view of the structure of FIG. 5A in accordance with the present invention;

FIG. 7 is a schematic view of the structure of the limiting mechanism of the present invention;

FIG. 8 is a partial cross-sectional view of a hollow support frame of the present invention;

fig. 9 is a schematic view of a partial structure of the limiting mechanism of the present invention.

In the figure: 1. a collection box; 11. an inlet; 12. a sealing block; 21. a cross beam; 22. an L-shaped pressing plate; 23. inserting a steel chisel; 24. inserting a sleeve; 3. a connecting member; 31. a threaded sleeve; 41. a hollow support frame; 42. a wire rope; 43. a transmission rod; 44. a crank; 45. a backup plate; 46. a deflector rod; 47. a buffer tank; 48. an elliptical stainless steel ring; 49. and a spherical jacking block.

Detailed Description

The following will clearly and completely describe the technical solutions in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

Example one

Please refer to fig. 1, fig. 2 and fig. 5, this embodiment provides a splicing ampullaria gigas trapping apparatus, including collecting box 1 and fixed establishment, collect box 1 and be equipped with a plurality of, adjacent two collect box 1 relative lateral wall pastes together, every collects box 1 and all installs the bank in catching the waters through fixed establishment, set up a plurality of collection box 1 according to catching waters bank width, collect box 1 and be a style of calligraphy structure along the bank and arrange along the bank with setting for a plurality of, and install the bank in catching the waters through fixed establishment, ensure simultaneously that adjacent collection box 1 pastes together, avoid producing the gap between two adjacent collection box 1, lead to ampullaria gigas to pass the gap and climb on the bank and lay eggs.

Collect 1 inside cavity that is used for collecting the ampullaria gigas that is equipped with of box, collect the preceding terminal surface of box 1 and offer a plurality of about even interval distribution and with the inside import 11 that communicates of cavity, a plurality of collection box 1 that is in the same place in parallel has blockked the passageway on the bank of ampullaria gigas, the ampullaria gigas is crawled along collecting 1 preceding terminal surface of box, gets into in collecting box 1's cavity through import 11, realizes catching the batch of ampullaria gigas.

After a certain time, the ampullaria gigas collected in the collecting box 1 are led out to be subjected to centralized killing operation, so that the situation that the ampullaria gigas is propagated carelessly to destroy ecological balance is avoided.

The wantonly of ampullaria gigas breeds and causes very big destruction to the plant ecosystem of crops and river lake, in addition, also can be picked up by people and make the back and make food and eat by mistake, cause the safety problem, there is the mode that adopts chemical agent to clear up and kill and the artifical mode of catching to clear up ampullaria gigas among the prior art, but the mode that adopts chemical agent easily causes the pollution to the water, the mode efficiency of artifical seizure is too low, can't satisfy the high-efficient clearance demand to ampullaria gigas, catch the oviferous ampullaria gigas of going to the bank through the collection box 1 that sets up on the bank, replace manpower and the mode of chemical killing, capture efficiency improves greatly.

Fixing mechanism includes crossbeam 21 and two L type clamp plates 22, two L type clamp plates 22 are fixed respectively and are set up the one side both ends position at crossbeam 21, the opposite side middle section position of crossbeam 21 articulates there is grafting drill rod 23, and articulated position is equipped with the torsional spring, utilize the torsional potential energy of torsional spring, make crossbeam 21 drive two L type clamp plates 22 have the trend of pushing down in real time and collecting box 1, ensure to collect box 1 and can stably be located on bank earth, avoid collecting 1 bottom face of box and lead to the lucky spiral shell to pass the gap and climb the bank between the bank earth.

In catching waters bank earth with the embedding of grafting drill rod 23, two L type clamp plates 22 can closely the pressfitting in the upper end both sides of collecting box 1, and the tip of L type clamp plate 22 bend the position can the pressfitting at the preceding terminal surface and the up end handing-over position of collecting box 1, collect 1 bottom end face of box and the bank earth laminating of catching the waters, avoid collecting 1 bottom end face and leading to the fortune longevity snail to pass the gap and climb the bank apart from appearing the gap between the bank earth.

Because the fortune longevity spiral shell wriggling ability is stronger, it can follow in the 11 cavities that climb into and collect box 1 of import, import 11 is located under the condition of no any obstacle, the fortune longevity spiral shell also can climb out along the 11 inner walls of import from the cavity, the fortune longevity spiral shell that leads to catching climbs away from the cavity of collecting box 1, the efficiency of catching that leads to the fortune longevity spiral shell descends, can't satisfy catches the demand to the fortune longevity spiral shell in batches, in order to solve above-mentioned problem, it is equipped with sealed piece 12 to rotate at the one end opening upside lateral wall that is close to the cavity in import 11, sealed piece 12 receives self gravity to influence and can seal import 11 around the automatic lower pendulum in rotational position, the fortune longevity spiral shell of avoiding climbing into in the cavity climbs out from import 11.

The utility model discloses a fortune longevity snail is upwards crawled along collecting 1 front end of box, climb sealed piece 12 of jack-up in the import 11, make sealed piece 12 upwards overturn around the turned position, can open import 11, make the fortune longevity snail can get into in the cavity smoothly, after in the full entering cavity of fortune longevity snail, sealed piece 12 application of force apical force then can seal import 11 once more around the automatic lower pendulum of turned position after, can enough satisfy the smooth entering cavity of fortune longevity snail, can avoid again getting into the fortune longevity snail in the cavity and climb out and escape, ensure that the catching operation of fortune longevity snail is high-efficient to be gone on.

Through with about 11 inside both sides lateral walls parallels of import and all to being close to the inside one side top slope distribution of cavity, when the ampullaria gigas crawled through import 11 along collecting 1 preceding terminal surface of box, help the ampullaria gigas can continue to crawl along the 11 inner walls of import that wash upwards distribute, creep in the cavity completely until the ampullaria gigas.

Example two

Referring to fig. 1-3, a further improvement is made on the basis of embodiment 1:

two adjacent fixed establishment pass through connecting piece 3 and connect, utilize connecting piece 3 further to strengthen fixed establishment and install the stability at the bank to the stability of box 1 is collected in the reinforcing.

Connecting piece 3 is door type grafting pole, and the outer wall symmetry of grafting drill rod 23 is fixed and is equipped with two grafting sleeves 24, and door type grafting pole runs through respectively two adjacent grafting drill rods 23 and imbeds in the bank earth behind the two grafting sleeves 24 that are close to each other, and the left and right sides swing after avoiding fixed establishment's grafting drill rod 23 to insert bank earth.

The threaded sleeve 31 has been cup jointed through the external screw thread rotation at door type inserted bar both ends, and door type inserted bar runs through and imbeds bank earth behind the grafting sleeve 24 in, bare-handed rotation threaded sleeve 31, closely presses in grafting sleeve 24 upper end until threaded sleeve 31 bottom, can strengthen the stability in the grafting drill rod 23 embedding earth.

The outer diameter of the threaded sleeve 31 is the same as the outer diameter of the plug sleeve 24, ensuring that turning the depressed threaded sleeve 31 effectively depresses the plug sleeve 24.

EXAMPLE III

Please refer to fig. 1, fig. 4, fig. 7 and fig. 9, which are further improved based on the embodiment 2:

the discharge gate has been seted up to the upper end of collecting box 1, and the inside stop gear who prevents that the apple snail from climbing from collecting box 1's cavity at will that is equipped with of discharge gate, utilizes stop gear to set up at the discharge gate for prevent that the apple snail from climbing from in the discharge gate at will, simultaneously, stop gear can assist and derive the apple snail from the discharge gate.

Stop gear includes cavity carriage 41, and cavity carriage 41 is fixed embedded inside the discharge gate, is equipped with a plurality of wire rope 42 between the inside both sides lateral wall of cavity carriage 41, is equipped with the clearance between two adjacent wire rope 42, and under the state of no external force intervention, the clearance between two adjacent wire rope 42 is less than the individual width of fortune longevity snail, avoids the fortune longevity snail to cross the clearance at will and climbs away from collection box 1.

When exporting the ampullaria gigas, take out the back and invert with collecting box 1 from the bank for the opening of discharge gate is down, struts two adjacent wire rope 42, makes the clearance enlarge, and shakes collecting box 1 from top to bottom fast, can export the ampullaria gigas from the clearance between the wire rope 42 that is propped open.

The front side wall and the rear side wall of the bottom end of the hollow supporting frame 41 are both vertically fixedly provided with the backup plates 45, the transmission rod 43 is inserted between the two backup plates 45 in a rotating mode, the outer wall of the transmission rod 43 is fixedly provided with a plurality of deflector rods 46 opposite to the gaps between the two adjacent steel wire ropes 42, the transmission rod 43 is rapidly rotated between the two backup plates 45, the plurality of deflector rods 46 use the transmission rod 43 as the center to do circular motion, the ampullaria gigas located between the two adjacent steel wire ropes 42 can be used for spreading the two adjacent steel wire ropes 42 and are pulled out, and the ampullaria gigas leading-out efficiency is improved.

One end of the transmission rod 43 is rotated to penetrate through the backup plate 45 and the side wall of the collection box 1 and then extends to the outer side of the collection box 1, the end part of the transmission rod 43 is fixedly provided with a crank 44, the crank 44 is held by bare hands, the transmission rod 43 is rotated by taking the transmission rod 43 as a center, the transmission rod 43 can be driven to rotate, and therefore the driving lever 46 can be driven to rotate to drive the ampullaria gigas to be led out.

The outer wall of each deflector rod 46 is fixedly sleeved with a spherical jacking block 49, and when the deflector rods 46 rotate, the spherical jacking blocks 49 can be used for expanding and enlarging the gap between two adjacent steel wire ropes 42, so that the ampullaria gigas can be led out through the gap quickly.

The spherical jacking blocks 49 on two adjacent deflector rods 46 are distributed in a staggered manner, so that gaps between two adjacent steel wire ropes 42 at different positions can be propped open in a staggered manner.

Example four

Referring to fig. 1 and fig. 8, a further improvement is made on the basis of embodiment 3:

buffer slot 47 has all been seted up to the inside both sides lateral wall of cavity carriage 41, one side lateral wall that the notch was kept away from to buffer slot 47's inside is fixed and is equipped with oval stainless steel ring 48, wire rope 42's both ends extend to respectively in two buffer slots 47 and respectively with two oval stainless steel ring 48 outer wall fixed connection, when two adjacent wire rope 42 are strutted, wire rope 42's both ends can be respectively along the inside slip of buffer slot 47 that corresponds separately, oval stainless steel ring 48 receives wire rope 42's traction force can be by tensile deformation simultaneously, with this length difference when compensating wire rope 42 and strutted.

After the ampullaria gigas are completely led out, the collecting box 1 is installed on the shore again, the oval stainless steel ring 48 is reset after the steel wire ropes 42 lose external force, the steel wire ropes 42 can be tensioned, and the gap between every two adjacent steel wire ropes 42 is reset to the size of the initial state again, so that the collected ampullaria gigas can be prevented from climbing away from the gap between every two adjacent steel wire ropes 42.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. The utility model provides a fortune that can splice spiral shell trapping apparatus, includes collection box (1) and fixed establishment, its characterized in that: the collecting boxes (1) are provided with a plurality of collecting boxes, opposite side walls of two adjacent collecting boxes (1) are attached together, and each collecting box (1) is installed on the shore of a captured water area through a fixing mechanism;

the fixing mechanism comprises a cross beam (21) and two L-shaped pressing plates (22), the two L-shaped pressing plates (22) are respectively and fixedly arranged at two ends of one side of the cross beam (21), the middle section of the other side of the cross beam (21) is hinged with a splicing steel chisel (23), and a torsional spring is arranged at the hinged position;

inserting an inserting steel chisel (23) into the shore soil of the captured water area, wherein two L-shaped pressing plates (22) can be tightly pressed on two sides of the upper end of the collecting box (1), bent parts of the end parts of the L-shaped pressing plates (22) can be pressed on the intersection positions of the front end face and the upper end face of the collecting box (1), the bottom end face of the collecting box (1) is attached to the shore soil of the captured water area, and the situation that the ampullaria gigas pass through a gap to climb to the shore due to the fact that the gap is formed between the bottom end face of the collecting box (1) and the shore soil is avoided;

a cavity for collecting ampullaria gigas is formed in the collecting box (1), and a plurality of inlets (11) which are uniformly distributed at intervals up and down and communicated with the cavity are formed in the front end face of the collecting box (1);

import (11) are close to one end opening upside lateral wall of cavity and rotate and are equipped with sealed piece (12), and sealed piece (12) receive self gravity to influence and can seal import (11) around the automatic lower hem in rotational position.

2. The splicing ampullaria gigas capturing device as claimed in claim 1, wherein: the upper side wall and the lower side wall of the inlet (11) are parallel and are obliquely distributed above one side close to the cavity.

3. The splicing ampullaria gigas capturing device as claimed in claim 1, wherein: two adjacent fixing mechanisms are connected through a connecting piece (3);

the connecting piece (3) is a door-shaped inserting rod, two inserting sleeves (24) are symmetrically and fixedly arranged on the outer wall of each inserting steel drill (23), and the door-shaped inserting rod penetrates through the two inserting sleeves (24) which are close to each other and adjacent to the two inserting steel drills (23) respectively and then is embedded into shore soil.

4. The splicing ampullaria gigas capturing device as claimed in claim 3, wherein: threaded sleeve (31) have been cup jointed through the external screw thread rotation at door type inserted bar both ends, the external diameter of threaded sleeve (31) is the same with the external diameter of grafting sleeve (24), and door type inserted bar runs through and imbeds bank soil after grafting sleeve (24) in, bare-handed rotation threaded sleeve (31) until threaded sleeve (31) bottom closely press in grafting sleeve (24) upper end.

5. The splicing ampullaria gigas capturing device as claimed in claim 1, wherein: the discharge hole is formed in the upper end of the collecting box (1), and a limiting mechanism for preventing the ampullaria gigas from climbing away from the cavity of the collecting box (1) at will is arranged in the discharge hole.

6. The splicing ampullaria gigas capturing device as claimed in claim 5, wherein: the limiting mechanism comprises a hollow supporting frame (41), the hollow supporting frame (41) is fixedly embedded in the discharging hole, a plurality of steel wire ropes (42) are arranged between the side walls of the two sides in the hollow supporting frame (41), and a gap is formed between every two adjacent steel wire ropes (42).

7. The splicing ampullaria gigas capturing device as claimed in claim 6, wherein: the front side wall and the rear side wall of the bottom end of the hollow supporting frame (41) are respectively and vertically fixedly provided with a backup plate (45), a transmission rod (43) is rotatably inserted between the two backup plates (45), and the outer wall of the transmission rod (43) is fixedly provided with a plurality of shifting rods (46) which are opposite to the gaps between the two adjacent steel wire ropes (42);

one end of the transmission rod (43) rotates to penetrate through the backup plate (45) and the side wall of the collecting box (1) and then extends to the outer side of the collecting box (1), and a crank (44) is fixedly arranged at the end part of the transmission rod (43).

8. The splicing ampullaria gigas capturing device as claimed in claim 7, wherein: the outer wall of each deflector rod (46) is fixedly sleeved with a spherical jacking block (49), and the spherical jacking blocks (49) on two adjacent deflector rods (46) are distributed in a staggered manner.

9. The splicing ampullaria gigas capturing device as claimed in claim 6, wherein: buffer slot (47) have all been seted up to the inside both sides lateral wall of cavity carriage (41), one side lateral wall that the notch was kept away from to the inside of buffer slot (47) is fixed and is equipped with oval stainless steel ring (48), the both ends of wire rope (42) extend to respectively in two buffer slot (47) and respectively with two oval stainless steel ring (48) outer wall fixed connection.

Images