CN214339449U

CN214339449U - Crayfish remote feeding device

Info

Publication number: CN214339449U
Application number: CN202120356713.7U
Authority: CN
Inventors: 王用黎; 李淑云; 陈效儒; 张璐; 向芳琴; 金雄华; 杨英豪
Original assignee: Tongwei Co Ltd
Current assignee: Tongwei Agricultural Development Co Ltd
Priority date: 2021-02-07
Filing date: 2021-02-07
Publication date: 2021-10-08
Anticipated expiration: 2031-02-07

Abstract

The utility model discloses a crayfish remote feeding device, which comprises a first positioning component, a second positioning component and a feeding device, wherein the first positioning component comprises a first upright post and a first cross beam horizontally arranged on the first upright post; the second positioning assembly comprises a second upright column, and a second cross beam and a third cross beam which are horizontally arranged on the second upright column respectively; the traction rope sequentially penetrates through the first fixed pulley, the third fixed pulley, the fifth fixed pulley, the sixth fixed pulley, the fourth fixed pulley and the second fixed pulley; the traction assembly provides tension and tensioning force for two ends of the traction rope respectively, so that the guide traction part can be always in a horizontal tensioning state while the guide traction part reciprocates between the first positioning assembly and the second positioning assembly; the feeding device is used for throwing materials. The reciprocating motion of the feeding device above the culture area is controlled by controlling the reciprocating motion of the traction rope on the fixed pulley block, so that the remote feeding operation in the culture area is realized.

Description

Crayfish remote feeding device

Technical Field

The utility model relates to an aquaculture equipment technical field, in particular to remote crayfish feeding device.

Background

The mode of throwing materials is usually adopted in traditional aquaculture, but the manual throwing is only suitable for small-size aquaculture, and along with the improvement of the society to the aquatic products demand, the aquaculture area of aquaculture enlarges gradually. For example, the breeding area of a crayfish breeding pond in a rice field is usually 50-100 mu, the time and the labor are consumed by adopting an artificial feeding mode, and the problem of uneven feeding exists, so that the breeding quality of the crayfish is influenced.

SUMMERY OF THE UTILITY MODEL

The utility model discloses to the above-mentioned technical problem that current correlation exists, provide a crayfish remote feeding device, can solve well and throw the material consuming time power consuming, throw the uneven problem of material.

In order to solve the technical problem, the utility model discloses a technical scheme as follows:

a crawfish remote feeding device comprising:

the first positioning assembly comprises a first upright column and a first cross beam horizontally arranged on the first upright column, and a first fixed pulley and a second fixed pulley are respectively arranged at two ends of the first cross beam;

the second positioning assembly comprises a second upright column, and a second cross beam and a third cross beam which are horizontally arranged on the second upright column respectively, wherein a third fixed pulley and a fourth fixed pulley are arranged at two ends of the second cross beam respectively, the third fixed pulley and the fourth fixed pulley are arranged opposite to the first fixed pulley and the second fixed pulley respectively and are positioned in the same horizontal plane, and a fifth fixed pulley and a sixth fixed pulley are arranged at two ends of the third cross beam respectively;

the traction rope sequentially penetrates through the first fixed pulley, the third fixed pulley, the fifth fixed pulley, the sixth fixed pulley, the fourth fixed pulley and the second fixed pulley, and guide traction parts which are arranged in parallel are respectively formed between the first fixed pulley and the third fixed pulley as well as between the second fixed pulley and the fourth fixed pulley;

the traction assembly is arranged on the outer side of the first positioning assembly, two ends of the traction rope are respectively connected to the traction assembly, the traction assembly respectively provides tension and tensioning force for two ends of the traction rope, and the guide traction part can be always in a horizontal tensioning state while reciprocating between the first positioning assembly and the second positioning assembly;

the feeding device is fixedly connected between one side of the feeding device and one of the guide traction parts, the other side of the feeding device is connected with the other guide traction part in a sliding manner, and the feeding device can be driven to reciprocate between the first positioning assembly and the second positioning assembly when the traction rope is pulled.

In the above technical scheme, further, the third beam is arranged below the second beam, and the traction ropes arranged among the third fixed pulley, the fifth fixed pulley, the sixth fixed pulley and the fourth fixed pulley are positioned in the same vertical plane.

In the above technical solution, further, the traction assembly includes a driving mechanism and a roller assembly, the roller assembly includes a roller support and a roller disposed on the roller support, the driving mechanism drives the roller to rotate on the roller support, two ends of the traction rope are respectively fixedly wound on the roller, and two ends of the traction rope are wound on the roller in opposite directions.

In the above technical solution, further, at least two fixing hangers are arranged on one of the guiding and pulling portions, and the fixing hangers are fixedly connected to the guiding and pulling portion;

at least two sliding hangers are arranged on the other guiding traction part, and the sliding hangers are connected with the guiding traction part in a sliding manner;

and two sides of the feeding device are respectively connected to the fixed hanging piece and the sliding hanging piece.

In the above technical scheme, further, the feeding device comprises a housing, a bin arranged in the housing, a feeding assembly and a motor;

the feeding assembly is arranged below the storage bin, the feeding assembly is rotationally connected with the shell through a bearing, and the motor is connected with the feeding assembly and drives the feeding assembly to rotate;

the feeding assembly comprises a hollow feeding shaft with two open ends, one end of the feeding shaft is positioned below the discharge port of the storage bin, the other end of the feeding shaft extends out of the shell, one end of the feeding shaft extending out of the shell is provided with a feeding disc, the feeding disc is of a hollow cavity structure, the feeding shaft is communicated with the inside of the feeding disc, and the outer edge of the feeding disc is provided with a plurality of discharge ports along the circumferential direction of the feeding disc.

Among the above-mentioned technical scheme, furtherly, the guide shaft one end tip that is located feed bin discharge gate below sets up to the infundibulate structure, the feed bin discharge gate stretches into in the infundibulate structure.

In the above technical scheme, further, a plurality of material guide plates are arranged in the hollow cavity of the feeding disc, and the material guide plates are arranged along the radial direction of the feeding disc.

In the above technical scheme, further, a certain distance is provided between one end of the material guide plate close to the material guide shaft and the outer edge of the material guide shaft.

The utility model discloses the beneficial effect who has:

1) the device realizes the control of the reciprocating motion of the feeding device above the culture area by controlling the reciprocating motion of the traction rope on the fixed pulley block, thereby realizing the remote feeding operation in the culture area, and having simple feeding operation and even feeding.

2) The two groups of guide traction parts arranged in parallel are arranged in the device to fixedly hoist the feeding device, so that the feeding device can be stably hoisted on the guide traction parts while reciprocating motion along with the traction ropes is realized, and the stability of operation of the feeding device is ensured.

3) The utility model discloses an improve through the structure to throwing the material subassembly among the feeding device, can effectively improve the stability that the material was shed.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present invention.

Fig. 2 is a top view of the embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a second positioning assembly in an embodiment of the present invention.

Fig. 4 is a schematic structural view of a feeding device in an embodiment of the present invention.

In the figure: 100. the device comprises a first positioning assembly 101, a first upright post 102, a first cross beam 103, a first fixed pulley 104 and a second fixed pulley;

200. a second positioning component 201, a second upright column 202, a second beam 203, a third beam 204, a third fixed pulley 205, a fourth fixed pulley 206, a fifth fixed pulley 207 and a sixth fixed pulley;

300. a traction rope 301, a guide traction part 302, a fixed hanging part 303 and a sliding hanging part;

401. a driving motor 402, a roller bracket 403 and a roller;

500. the feeding device comprises 501, a shell body 502, a storage bin 521, a storage bin discharge port 522, a control valve 503, a motor 504, a guide shaft 505, a feeding disc 506, a discharge port 507 and a guide plate.

Detailed Description

The invention will be further described with reference to the accompanying drawings and specific embodiments.

Example one

As shown in fig. 1, 2 and 3, the crawfish remote feeding device in this embodiment comprises a first positioning assembly 100, a second positioning assembly 200, a pulling rope 300, a pulling assembly and a feeding device 500 for throwing materials.

The first positioning assembly 100 comprises a first upright 101 and a first beam 102 horizontally arranged on the first upright, and a first fixed pulley 103 and a second fixed pulley 104 are respectively arranged at two ends of the first beam 102.

As shown in fig. 3, the second positioning assembly 200 includes a second vertical column 201, and a second cross beam 202 and a third cross beam 203 horizontally disposed on the second vertical column, wherein a third fixed pulley 204 and a fourth fixed pulley 205 are disposed on two ends of the second cross beam 202, the third fixed pulley 204 and the fourth fixed pulley 205 are disposed opposite to the first fixed pulley 103 and the second fixed pulley 104, respectively, and are located in the same horizontal plane, and a fifth fixed pulley 206 and a sixth fixed pulley 207 are disposed on two ends of the third cross beam 203, respectively. In this embodiment, the third beam 203 is disposed below the second beam 202, and the traction ropes 300 sequentially disposed between the third fixed pulley 204, the fifth fixed pulley 206, the sixth fixed pulley 207, and the fourth fixed pulley 205 are located in the same vertical plane.

The traction rope 300 sequentially penetrates through the first fixed pulley 103, the third fixed pulley 204, the fifth fixed pulley 206, the sixth fixed pulley 207, the fourth fixed pulley 205 and the second fixed pulley 104, and guide traction parts 301 which are arranged in parallel are respectively formed between the first fixed pulley 103 and the third fixed pulley 204 and between the second fixed pulley 104 and the fourth fixed pulley 205 by the traction rope 300.

The traction assembly is arranged outside the first positioning assembly, two ends of the traction rope 300 are respectively connected to the traction assembly, the traction assembly respectively provides pulling force and tensioning force for two ends of the traction rope, and the guide traction part can be always in a horizontal tensioning state while reciprocating between the first positioning assembly and the second positioning assembly.

Specifically, the traction assembly in this embodiment includes a driving mechanism and a roller assembly, the roller assembly includes a roller support 402 and a roller 403 disposed on the roller support, the driving mechanism drives the roller to rotate on the roller support, two ends of the traction rope 300 are respectively fixedly wound on the roller 403, and two ends of the traction rope 300 are wound on the roller 403 in opposite directions, i.e., in opposite directions. Here, the driving mechanism may be a driving motor 401 and a speed reducer (not shown), wherein the driving motor 401 is connected to the speed reducer, and the speed reducer is connected to the roller 403 to drive the roller to rotate.

The feeding device 500 is fixedly connected with one of the guiding traction parts 301 at one side, the other side of the feeding device 500 is connected with the other guiding traction part 301 in a sliding manner, and when the traction rope is pulled, the feeding device can be driven to reciprocate between the first positioning assembly and the second positioning assembly. Specifically, in the present embodiment, two fixing hangers 302 are disposed on one of the guiding and pulling portions 301, and the fixing hangers 302 are fixedly connected to the guiding and pulling portions 301; two sliding hangers 303 are arranged on the other guiding traction part 301, and the sliding hangers 303 are connected with the guiding traction part 301 in a sliding manner; two sides of the feeding device 500 are respectively connected to the fixed hanging piece 302 and the sliding hanging piece 303. The fixed hanging piece and the sliding hanging piece can adopt hook structures, and the four corners of the top of the feeding device are respectively provided with the hanging rings, so that the feeding device is convenient to install on the traction rope.

When the driving mechanism drives the roller to rotate, two ends of the traction rope are respectively wound on the roller in a forward direction and a reverse direction, the front side of the feeding device is fixed on the guide traction part at one side, and the rear side of the feeding device and the guide traction part at the other side are connected in a sliding and hoisting manner, for example, as shown in fig. 2, when the roller rotates clockwise, the traction rope moves from the second fixed pulley to the first fixed pulley, and at the moment, the guide traction part at the front side moves towards the second positioning assembly to drive the feeding device to move towards the second positioning assembly; when the cylinder anticlockwise rotates, the haulage rope moves to the second fixed pulley direction from first fixed pulley direction, and at this moment, the direction traction part that is located the front side moves towards first positioning subassembly direction, drives to throw the material device and moves towards first positioning subassembly direction to realize throwing the reciprocating motion of material device in the breed region top.

Of course, the traction assembly may also adopt two sets of driving mechanisms and two sets of roller assemblies, the two sets of driving mechanisms respectively drive the two sets of roller assemblies to rotate, and two ends of the traction rope are respectively connected with one set of roller assemblies. During operation, the two groups of roller assemblies are controlled to rotate, so that one end of the traction rope is wound, the other end of the traction rope is wound and unwound, reciprocating motion of the traction rope on each fixed pulley can be realized, and reciprocating motion control of the feeding device above a culture area is realized.

The feeding device in the embodiment can adopt the existing electric throwing device or electric fertilizer applicator to realize the automatic throwing and throwing of the materials in the culture area.

Example two

The difference between this embodiment and the first embodiment is:

as shown in fig. 1 and 4, the feeding device in this embodiment includes a housing 501, a bin 502 disposed in the housing, a feeding assembly, and a motor 503; the feeding assembly is arranged below the stock bin 502, the feeding assembly is rotatably connected with the shell through a bearing, the motor 503 is connected with the feeding assembly, and the feeding assembly is driven to rotate.

The feeding assembly in this embodiment includes a hollow material guiding shaft 504 with two open ends, one end of the material guiding shaft 504 is located below the discharge port 521 of the storage bin, the other end of the material guiding shaft 504 extends out of the casing 501, a feeding disc 505 is arranged at one end of the material guiding shaft 504 extending out of the casing, the feeding disc 505 is of a hollow cavity structure, the material guiding shaft 504 is communicated with the inside of the feeding disc 505, and a plurality of discharge ports 506 are arranged at the outer edge of the feeding disc 505 along the circumferential direction. The end part of one end of the material guiding shaft 504 positioned below the material bin discharge port is arranged to be a funnel-shaped structure, and the material bin discharge port 521 extends into the funnel-shaped structure. A plurality of material guide plates 507 are arranged in the hollow cavity of the feeding disc 505, and the material guide plates 507 are arranged along the radial direction of the feeding disc; a certain distance is reserved between one end of the material guide plate 507 close to the material guide shaft and the outer edge of the material guide shaft 504, so that a feeding space is formed in a cavity structure in the material guide disc. The material enters into the guide axle through guide axle infundibulate structure one end in, enters into the cavity structures of guide plate through the guide axle inside, and the material in the cavity structures is thrown out at a high speed from each discharge gate of guide plate under the effect of centrifugal force, realizes carrying out throwing on a large scale of material in the breed area.

But set up remote control's control valve 522 on feed bin discharge gate 521, realize the remote control of ejection of compact, can start the feeding device after will throwing the feeding device and convey the assigned position, realize the throwing of material. The control valve and the motor can be controlled by a wired or wireless control mode, and the control mode is realized by adopting the conventional control structure.

The present invention is not limited to the above description and drawings, but should be understood as being illustrative and not restrictive, and the technical features can be replaced and modified without creative efforts by those skilled in the art according to the technical content disclosed, all falling within the scope of the present invention.

Claims

1. A crawfish remote feeding device, comprising:

2. A crawfish remote feeding device according to claim 1, wherein the third beam is arranged below the second beam with the pulling ropes arranged between the third, fifth, sixth and fourth fixed pulleys being in the same vertical plane.

3. A crawfish remote feeding device according to claim 1, wherein the traction assembly comprises a driving mechanism and a roller assembly, the roller assembly comprises a roller support and a roller arranged on the roller support, the driving mechanism drives the roller to rotate on the roller support, two ends of the traction rope are respectively and fixedly wound on the roller, and two ends of the traction rope are wound on the roller in opposite directions.

4. A crawfish remote feeding device as claimed in claim 1, wherein at least two fixing hangers are arranged on one of the guiding and pulling parts, and the fixing hangers are fixedly connected to the guiding and pulling part;

5. A crawfish remote feeding device according to claim 1, wherein the feeding device comprises a housing, a bin disposed inside the housing, a feeding assembly and a motor;

6. The crayfish remote feeding device of claim 5 wherein the end of the one end of the guide shaft below the bin outlet is arranged in a funnel-shaped configuration into which the bin outlet extends.

7. A crawfish remote feeding device as claimed in claim 5, wherein a plurality of material guiding plates are arranged in the hollow cavity of the feeding tray, and the material guiding plates are arranged along the radial direction of the feeding tray.

8. A crawfish remote feeding device as claimed in claim 7, wherein a certain distance is formed between one end of the guiding plate close to the guiding shaft and the outer edge of the guiding shaft.