CN214629100U

CN214629100U - Cutter suction type timing and quantitative goose liver breeding and feeding device

Info

Publication number: CN214629100U
Application number: CN202120198907.9U
Authority: CN
Inventors: 江玉才; 黄志友
Original assignee: Luan Vocational and Technical College
Current assignee: Luan Vocational and Technical College
Priority date: 2021-01-25
Filing date: 2021-01-25
Publication date: 2021-11-09
Anticipated expiration: 2031-01-25

Abstract

The utility model relates to a aquaculture technical field discloses cutter-suction type regularly quantitative formula goose liver is supported into and is fed and eat device, including hopper one, set up the material pipe of a discharge gate department of hopper and set up the auger in hopper one, the feed inlet has on the hopper one. One end of the packing auger extends into the material pipe. The material pipe is internally provided with a material baffle plate for plugging the pipeline of the material pipe, and the material baffle plate is provided with a material passing hole. And a driving mechanism which is used for driving the packing auger to rotate and synchronously driving the striker plate to horizontally reciprocate is arranged on the hopper I. Through the auger that sets up in the hopper, can stir and transmit the fodder, avoid fluid feed to deposit in the hopper bottom, make fluid feed's consistency the same, improved the yield of fostering into the goose liver, simultaneously through the striker plate that sets up and be used for ordering about striker plate horizontal reciprocating motion's drive, can realize the quantitative feed of every turn of higher accuracy, many gooses feed the fluid feed of the output of overall process in succession, the fodder that wherein contains is stable with the proportion of water.

Description

Cutter suction type timing and quantitative goose liver breeding and feeding device

Technical Field

The utility model relates to a aquaculture technical field especially relates to cutter-suction type regular and quantitative formula goose liver is supported and is fed and eat device.

Background

The liver is an important organ for storing nourishment and detoxifying in animals, contains rich nutrient substances and is a good blood-enriching product. Goose liver is sought by many eaters because of its tender meat quality and unique flavor. Most of the goose livers existing in the market are artificially fed.

The breed of goose liver needs the manual work to eat the device through feeding and send the food for the goose regularly and quantitatively in the plant, and the device of feeding of goose adopts the suction type structure in the plant at present, thereby goes up and down through the cylinder and promotes fluid feed to pour into in the esophagus of goose into.

Because the fluid feed is sucked from the storage barrel in a quantitative mode in a pneumatic mode and the fluid feed is precipitated at the bottom, the consistency of the fluid feed sucked and output finally is different, the fed goose livers are inconsistent in specification, and the finished product qualification rate is low. Meanwhile, the output fluid feed is directly and pneumatically injected into the mouth of the goose, so that the esophagus of the goose is easily damaged. In addition, the original feeding device adopts a pneumatic mode, the pipeline is long, the feeding process is complex in operation, and potential safety hazards exist.

SUMMERY OF THE UTILITY MODEL

The utility model provides a formula goose liver is supported into to feed and eats device at regular time and quantity is inhaled to the cutter, and it is inhomogeneous to have overcome the fodder ejection of compact, the inhomogeneous technical problem of goose liver quality that leads to.

The utility model discloses a following technical scheme realizes: the cutter suction type timed and quantitative goose liver breeding and feeding device comprises a first hopper, a material pipe arranged at a discharge port of the first hopper and a packing auger arranged in the first hopper, wherein the first hopper is provided with a feed port; one end of the packing auger extends into the material pipe; a material baffle plate for plugging a pipeline of the material pipe is arranged in the material pipe, and a material passing hole is formed in the material baffle plate;

and a driving mechanism which is used for driving the packing auger to rotate and synchronously driving the striker plate to horizontally reciprocate is arranged on the hopper I.

As a further improvement of the above scheme, the driving mechanism comprises a housing which is attached to the first hopper and the material pipe, a double-shaft motor is installed in the housing, one output shaft of the double-shaft motor is connected with a first rotating shaft parallel to the auger, and a belt wheel is fixed at the other end of the first rotating shaft; a partition plate is arranged in the first hopper; the other end of the packing auger rotatably penetrates through the partition plate and is fixed with a belt wheel; the two belt wheels are connected through a belt in a transmission way.

As a further improvement of the scheme, a second rotating shaft parallel to the packing auger is connected to the other output shaft of the double-shaft motor, a first bevel gear is fixed to the other end of the second rotating shaft, a limiting plate parallel to the packing auger is fixed to the bottom in the housing, and a transmission shaft is inserted into the limiting plate in a rotating mode; one end of the transmission shaft is fixedly provided with a second bevel gear meshed with the first bevel gear, the other end of the transmission shaft is fixedly provided with a turntable, and one side of the turntable, far away from the transmission shaft, is provided with a slope;

the material pipe comprises a pipe body and is characterized in that a first sliding groove and a second sliding groove which are vertically communicated with the inside of the pipe body are oppositely arranged on two sides of the pipe body, a sliding block is elastically connected in the first sliding groove, one side, close to the material pipe, of the sliding block is fixedly connected with one end of a material baffle plate, and the other end of the material baffle plate slidably penetrates through the second sliding groove and is fixedly provided with a sliding ball which is in extrusion fit with the slope surface.

As a further improvement of the above scheme, the sliding block is connected with the first sliding groove through a spring; when the spring is not deformed, the material passing hole of the material baffle plate is positioned in the second sliding groove.

As a further improvement of the above scheme, a handle is mounted on the hopper I, a switch button is mounted on the handle, a storage battery is mounted on the housing, and the double-shaft motor is electrically connected with the storage battery through the switch button.

As a further improvement of the scheme, a second hopper covering the feeding hole is arranged on the first hopper.

As a further improvement of the scheme, the bottom of the first hopper is funnel-shaped.

The utility model has the advantages that:

the utility model discloses a formula goose liver is supported to feed and eats device regularly and quantitatively by cutter suction, auger through setting up in the hopper, can stir and transmit the fodder, avoid fluid feed to deposit in the hopper bottom, make fluid feed's consistency the same, the yield of having improved and having supported the goose liver, simultaneously through the striker plate that sets up and be used for ordering about striker plate horizontal reciprocating motion's drive, can realize the quantitative feed of every turn of higher precision, many gooses feed the fluid feed of the output in the overall process in succession, the fodder that wherein contains is stable with the proportion of water, avoid damaging the goose esophagus and adopt battery powered, high convenience and high speed, the potential safety hazard is reduced.

Drawings

Fig. 1 is a schematic cross-sectional structure view of a cutter-suction type regular and quantitative goose liver feeding device provided in an embodiment of the present invention;

fig. 2 is an enlarged schematic view of a portion a in fig. 1.

Description of the main symbols:

1. a first hopper; 2. a material pipe; 3. a packing auger; 4. a partition plate; 5. a housing; 6. a pulley; 7. a double-shaft motor; 8. a first rotating shaft; 9. a second rotating shaft; 10. a first bevel gear; 11. a limiting plate; 12. a drive shaft; 13. a second bevel gear; 14. a turntable; 15. a first sliding chute; 16. a second chute; 17. a slider; 18. a spring; 19. a striker plate; 20. a material passing hole; 21. a sliding bead; 22. a handle; 23. a switch button; 24. a second hopper; 25. and (4) a storage battery.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

Referring to fig. 1 to 2, the cutter suction type feeding device for goose liver breeding with timing and quantitative method comprises a hopper 1, a material pipe 2 disposed at the discharge port of the hopper 1, and an auger 3 disposed in the hopper 1, wherein the hopper 1 has a feed port (not labeled). One end of the packing auger 3 extends into the material pipe 2. A material baffle plate 19 for plugging the pipeline of the material pipe 2 is arranged in the material pipe 2, and a material passing hole 20 is formed in the material baffle plate 19.

And a driving mechanism for driving the packing auger 3 to rotate and synchronously driving the material baffle plate 19 to horizontally reciprocate is arranged on the hopper I1. The auger 3 can synchronously stir the feed while conveying the feed in the hopper I1 so as to prevent the feed from being deposited at the bottom of the hopper I1. The screw thread on auger 3 in this embodiment is the wave form screw thread, has promoted fodder feeding in-process precision and smoothness.

The driving mechanism comprises a housing 5 which is attached to the hopper I1 and the material pipe 2, a double-shaft motor 7 is installed in the housing 5, and the double-shaft motor 7 can be a common direct-current double-shaft motor. One output shaft of the double-shaft motor 7 is connected with a first rotating shaft 8 parallel to the packing auger 3, and the other end of the first rotating shaft 8 is fixed with a belt wheel 6. A partition plate 4 is arranged in the hopper I1. In this embodiment, the partition plate 4 is an L-shaped structure, a shaft hole (not shown) for the hinge shaft of the packing auger 3 to pass through is formed in the plate body of the partition plate 4, and the hinge shaft of the packing auger 3 can rotate relatively in the shaft hole. The other end of the packing auger 3 is rotatably penetrated through the clapboard 4 and is fixed with a belt wheel 6. The two belt wheels 6 are connected through a belt in a transmission way.

The other output shaft of the double-shaft motor 7 is connected with a second rotating shaft 9 parallel to the packing auger 3, the other end of the second rotating shaft 9 is fixedly provided with a first bevel gear 10, the bottom in the housing 5 is fixedly provided with a limiting plate 11 parallel to the packing auger 3, and a transmission shaft 12 is rotatably inserted in the limiting plate 11. One end of the transmission shaft 12 is fixed with a second bevel gear 13 engaged with the first bevel gear 10, and the other end is fixed with a rotary disc 14, and one side of the rotary disc 14 far away from the transmission shaft 12 is provided with a slope surface (not shown). The slope surface is subjected to smoothing treatment.

The two sides of the material pipe 2 are oppositely provided with a first sliding chute 15 and a second sliding chute 16 which are vertically communicated with the inside of the pipe body, and the first sliding chute 15 and the second sliding chute 16 are vertical to the axial direction of the material pipe 2 in the embodiment.

And a sliding block 17 is elastically connected in the first sliding groove 15, one side of the sliding block 17, which is close to the material pipe 2, is fixedly connected with one end of a material baffle plate 19, and the other end of the material baffle plate 19 slidably penetrates through the second sliding groove 16 and is fixed with a sliding ball 21 which is in extrusion fit with the slope surface.

The sliding block 17 is connected with the first sliding groove 15 through a spring 18, and two ends of the spring 18 are respectively fixed on the block body of the sliding block 17 and the inner wall of the first sliding groove 15. When the spring 18 is not deformed, the material passing hole 20 of the striker plate 19 is located in the second sliding groove 16. Through driving the striker plate 19 horizontal reciprocating motion, make the punishment in advance hole 20 of striker plate 19 align with the pipeline of material pipe 2, make the fodder in the material pipe 2 flow out smoothly.

The hopper I1 is provided with the handle 22, the handle 22 is provided with the switch button 23, the housing 5 is provided with the storage battery 25, and the double-shaft motor 7 is electrically connected with the storage battery 25 through the switch button 23 so that a user can control the double-shaft motor 7 to be turned on or turned off through the switch button 23.

The first hopper 1 is provided with a second hopper 24 covering the feed inlet, and feed is conveniently input into the first hopper 1 through the second hopper 24.

The hopper 1 is integrally funnel-shaped, so that the feed accumulated at the bottom in the hopper 1 can move to the feed outlet of the hopper 1 under the action of gravity.

The utility model discloses an operating principle specifically does, during the use, will add hopper 1 through hopper two 24 with the fodder earlier, and the punishment in advance hole 20 of striker plate 19 is located spout two 16 this moment, and then striker plate 19 is in the separation state to the fodder of expecting in the pipe 2. When the goose needs to be fed, the handle 22 is held by a hand to insert the feed pipe 2 into the goose esophagus, the switch button 23 is pressed to start the double-shaft motor 7, one output shaft of the double-shaft motor 7 drives the first rotating shaft 8 to rotate, the first rotating shaft 8 and the auger 3 keep synchronous motion through the belt wheel 6 and the belt, so that the auger 3 stirs the feed in the hopper 1 and transmits the feed to the feed pipe 2. Meanwhile, the other output shaft of the double-shaft motor 7 drives the second rotating shaft 9 and the first bevel gear 10 to rotate, the first bevel gear 10 drives the transmission shaft 12 to rotate through the meshing action of the first bevel gear 10 and the second bevel gear 13, and the transmission shaft 12 drives the rotating disc 14 to rotate, so that the slope surface of the rotating disc 14 continuously extrudes the striker plate 19 through the sliding balls 21. In the process, when the slope surface of the rotary disc 14 gradually rotates from the lowest position to the highest position, the slope surface of the rotary disc 14 continuously increases, the extrusion force on the sliding ball 21 gradually increases, the sliding ball 21 drives the striker plate 19 to move towards the first sliding groove 15 and drives the slide block 17 to compress the spring 18, so that the material passing hole 20 enters the flow channel of the material pipe 2 to enable the material pipe 2 to be communicated, when the slope surface of the rotary disc 14 gradually rotates from the highest position to the lowest position, the slope surface of the rotary disc 14 continuously decreases, the extrusion force on the sliding ball 21 gradually decreases, the elastic force of the spring 18 is released to push the slide block 17 and the striker plate 19 to gradually move reversely to the initial position, so that the material passing hole 20 of the striker plate 19 returns to the second sliding groove 16 to enable the material pipe 2 to be sealed, the process continuously reciprocates along with the continuous driving of the double-shaft motor 7, the reciprocating movement of the striker plate 19 in the horizontal direction is realized, and the feed is quantitatively output at intervals in the material pipe 2, is convenient and quick. The feed flowing out from the feed pipe 2 can smoothly flow into the goose esophagus so as to complete the feeding of the goose.

The above description is only exemplary of the present invention and should not be construed as limiting the present invention, and any modifications, equivalents and improvements made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims

1. The cutter suction type regular and quantitative goose liver breeding and feeding device is characterized by comprising a first hopper, a material pipe arranged at a discharge port of the first hopper and a packing auger arranged in the first hopper, wherein the first hopper is provided with a feed port; one end of the packing auger extends into the material pipe; a material baffle plate for plugging a pipeline of the material pipe is arranged in the material pipe, and a material passing hole is formed in the material baffle plate;

2. The cutter-suction type timed and quantitative French goose liver feeding device as claimed in claim 1, wherein the driving mechanism comprises a housing attached to the hopper I and the material pipe, a double-shaft motor is installed in the housing, one output shaft of the double-shaft motor is connected with a first rotating shaft parallel to the auger, and the other end of the first rotating shaft is fixed with a belt wheel; a partition plate is arranged in the first hopper; the other end of the packing auger rotatably penetrates through the partition plate and is fixed with a belt wheel; the two belt wheels are connected through a belt in a transmission way.

3. The cutter-suction type timed and quantitative French goose liver feeding device according to claim 2, wherein a second rotating shaft parallel to the packing auger is connected to the other output shaft of the double-shaft motor, a first bevel gear is fixed to the other end of the second rotating shaft, a limiting plate parallel to the packing auger is fixed to the bottom in the housing, and a transmission shaft is inserted in the limiting plate in a rotating manner; one end of the transmission shaft is fixedly provided with a second bevel gear meshed with the first bevel gear, the other end of the transmission shaft is fixedly provided with a turntable, and one side of the turntable, far away from the transmission shaft, is provided with a slope;

4. The cutter-suction type timed and quantitative goose liver feeding device as claimed in claim 3, wherein the sliding block is connected with the first sliding groove through a spring; when the spring is not deformed, the material passing hole of the material baffle plate is positioned in the second sliding groove.

5. The cutter-suction type timed and quantitative goose liver feeding device as claimed in claim 2, wherein a handle is mounted on the hopper, a switch button is mounted on the handle, a storage battery is mounted on the housing, and the double-shaft motor is electrically connected with the storage battery through the switch button.

6. The cutter-suction type timed and quantitative goose liver feeding device as claimed in claim 1, wherein a second hopper is installed on said first hopper to cover said feeding hole.

7. The cutter-suction type timed and quantitative goose liver feeding device as claimed in claim 1, wherein the bottom of hopper I is funnel-shaped.