CN220712543U - Distributed feeding device for aquaculture - Google Patents

Abstract

The utility model relates to and proposes a distributed feeding device for aquaculture, which comprises a feeding box provided with a feeding layer; a driving box is arranged on one side of the feeding layer, and a support column is arranged between the feeding layer and the driving box; the bottom of the feeding box is provided with a discharge hole, the top of the feeding box is provided with a feeding pipe, and the feeding box is communicated with the feeding pipe; the feeding layer comprises a shell and a rotating device; the rotating device comprises a rotating rod and a feeding plate; the feeding plate is positioned at one side of the rotating rod, and a connecting piece is arranged at one side of the rotating rod, which is close to the feeding plate; the shell is provided with a through hole, the connecting piece is positioned in the through hole and is abutted against the through hole, the rotating rod is positioned in the through hole, and the feeding plate is positioned outside the through hole; a linkage structure is arranged in the shell, and the rotating rod is linked with the linkage structure; the driving box drives the linkage structure to rotate; through the technical scheme, the problem of uneven feeding and deviation of the cultured aquatic product feeding amount in the prior art is solved.

Description

Distributed feeding device for aquaculture

Technical Field

The utility model relates to the technical field of aquaculture decentralized feeding devices, in particular to an aquaculture decentralized feeding device.

Background

The aquaculture industry is an industry in which humans use water areas available for aquaculture and aquaculture techniques and facilities to perform aquaculture of aquatic animals and plants. However, in the actual cultivation process, the cultivation objects need to be fed manually frequently, so that an automatic feeding device is provided, and the problem that manpower is wasted due to manual feeding is solved.

At present, automatic feeding device among the prior art mainly includes rotation type dispenser, through rotation type dispenser, though solved the problem of manual feed, rotation type dispenser rotation method is too regular, leads to throwing the material scope relatively fixed, and the fodder coverage area of throwing is limited, causes the inhomogeneous, the problem that produces the deviation to the aquatic products each region of breeding of throwing easily.

Disclosure of Invention

The utility model provides a distributed feeding device for aquaculture, which mainly solves the problems of uneven feeding and deviation of feeding amount of cultured aquaculture in the related technology.

The technical scheme of the utility model is as follows:

the utility model provides an aquaculture dispersed type feeding device, includes the feeding case, is equipped with the material layer of throwing; a driving box is arranged on one side of the feeding layer, a support column is arranged between the feeding layer and the driving box, and two ends of the support column are fixedly connected with the driving box and the feeding box respectively; the bottom of the feeding box is provided with a discharge hole, the top of the feeding box is provided with a feeding pipe, and the feeding box is communicated with the feeding pipe; the feeding layer comprises a shell and a rotating device; the rotating device comprises a rotating rod and a feeding plate; the feeding plate is positioned at one side of the rotating rod, a connecting piece is arranged at one side of the rotating rod, which is close to the feeding plate, the rotating rod is fixedly connected with the connecting piece, and the connecting piece is fixedly connected with the feeding plate; the shell is provided with a through hole, the connecting piece is positioned in the through hole and is abutted against the through hole, the rotating rod is positioned in the through hole, and the feeding plate is positioned outside the through hole; a linkage structure is arranged in the shell, and the rotating rod is linked with the linkage structure; the driving box drives the linkage structure to rotate.

Further, the driving box comprises a first motor, a driving wheel, a driven wheel, a belt and a supporting plate; the first motor is positioned below the supporting plate and fixedly connected with the bottom of the driving box, and is linked with the driving wheel; the driving wheel, the driven wheel and the belt are all positioned above the supporting plate, the belt is sleeved on the driving wheel and the driven wheel and mutually linked, and the driven wheel is linked with the main gear.

Further, a second motor is arranged on one side of the feeding pipe, a stirring paddle is arranged above the discharging hole, the stirring paddle is linked with the second motor, and the second motor is fixedly connected with the feeding box.

Further, the top of the shell is of a conical structure.

Further, the support columns are distributed around the shell, and the cross sections of the support columns in the horizontal direction are triangular structures.

Further, the linkage structure comprises a main gear and a bevel gear, wherein the bevel gear is positioned on the upper portion of the main gear and meshed with the main gear, the bevel gear is linked with the rotating rod, and the driving box drives the main gear to rotate.

Further, the feeding box is located above the feeding layer.

Further, the section of the feeding plate is of a rectangular structure.

Further, the section of the feeding pipe is of an L-shaped structure and is fixedly connected with the feeding box.

Further, a blanking plate is arranged in the feeding box and fixedly connected with the feeding box.

The beneficial effects of the utility model are as follows:

according to the utility model, the rotating rod and the feeding plate are additionally arranged, under the cooperation of the linkage structure, the rotating rod and the feeding plate can rotate and turn around the center of the shell, and the rotation enables the feeding plate to change the angle, so that the force applied to the feed is different, the feeding range is different, and the practicability is high.

Drawings

The utility model will be described in further detail with reference to the drawings and the detailed description.

FIG. 1 is a front view showing a specific structure of an embodiment of the present utility model;

FIG. 2 is a top view of an embodiment of the present utility model;

FIG. 3 is a side view of a specific construction of an embodiment of the present utility model;

FIG. 4 is a schematic diagram of a partial linkage structure between the interior of the housing and the drive case in an embodiment of the utility model;

fig. 5 is a cross-sectional view showing a specific structure of an embodiment of the present utility model.

In the figure: 1. a feed box; 2. feeding a material layer; 3. a drive box; 4. a discharge port; 5. a feed pipe; 6. a support column; 7. a housing; 8. a rotating device; 9. a rotating rod; 10. a feeding plate; 11. a connecting piece; 12. a main gear; 13. bevel gears; 14. a through hole; 15. a first motor; 16. a driving wheel; 17. driven wheel; 18. a belt; 19. a support plate; 20. a second motor; 21. stirring paddles; 22. a blanking plate; 23. and a linkage structure.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below in conjunction with the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1 to 5, an embodiment of the present utility model provides a distributed feeding device for aquaculture, which includes a feeding box 1 for temporarily placing feed, and a feeding layer 2 for feeding the feed. One side of the feeding layer 2 is provided with a driving box 3 for driving, a supporting column 6 for supporting is arranged between the feeding layer 2 and the driving box 3, and two ends of the supporting column 6 are welded with the driving box 3 and the feeding box 1 in a strong stability mode. The bottom of the feeding box 1 is provided with a discharge hole 4, the top of the feeding box 1 is provided with a feeding pipe 5, and the feeding box 1 is communicated with the feeding pipe 5, so that feeding is facilitated; the feeding layer 2 comprises a shell 7 and a rotating device 8.

The rotating device 8 in this embodiment comprises a rotating rod 9, a feeding plate 10. The flitch 10 is located one side of rotary rod 9, and one side that rotary rod 9 is close to flitch 10 is equipped with connecting piece 11, and rotary rod 9 adopts high the cup joint of stability with connecting piece 11, and connecting piece 11 adopts the welding of intensity height with flitch 10. The shell 7 is provided with the through hole 14, and the connecting piece 11 is located in the through hole 14 and is in conflict with the through hole 14, and the rotary rod 9 is located in the through hole 14, and the flitch 10 is located outside the through hole 14, conveniently exerts force to the fodder to conveniently throw the material. Be equipped with linkage structure 23 in the casing 7, rotary rod 9 and linkage structure 23 linkage, drive case 3 drive linkage structure 23 rotate, can make rotary rod 9 and throw flitch 10 through linkage structure 23 can the autorotation with around casing 7 center turnover, the autorotation makes throw flitch 10 can change the angle, therefore also the power of applying to the fodder is different to make throw the material scope different, the practicality is high.

The feeding case 1 in this embodiment is inside to be equipped with flitch 22, avoids causing fodder putty, makes things convenient for the ejection of compact, and flitch 22 adopts the welding that intensity is high with feeding case 1, avoids flitch 22 to damage because of fodder impact, in addition, still can set up electronic closing cap (or gate valve or the like structure) in the bottom of feeding case 1 for store the fodder, prevent that the fodder from dropping by oneself, can open voluntarily when throwing the material, drop the fodder and throw in. The top of the feeding box 1 can be communicated with external batching and feeding equipment, and feeding can be performed through the external equipment when feeding is needed.

The inlet pipe 5 cross-section in this embodiment is L shape structure, avoids the fodder to block up, makes things convenient for the feeding, and inlet pipe 5 and feeding case 1 welding for stability is strong, thereby makes the feeding process stable.

The section of the feeding plate 10 in the embodiment is of a rectangular structure, so that stress points are dispersed, the bearing capacity is enhanced, and stable feeding is facilitated.

In the embodiment, the feeding box 1 is arranged above the feeding layer 2, so that the feed entering the feeding box 1 can fall only by gravity without other external force, and the feeding is convenient.

The linkage structure 23 in this embodiment includes the master gear 12, the bevel gear 13, and the bevel gear 13 is located master gear 12 upper portion, and with master gear 12 meshing, bevel gear 13 and rotary rod 9 linkage, and drive case 3 drive master gear 12 rotates, can make rotary rod 9 and throwing flitch 10 rotation and around casing 7 center turnover through linkage structure 23, and the rotation makes throwing flitch 10 can change the angle, therefore also the power of exerting to the fodder is different to make throwing material scope different, the practicality is high.

Support column 6 in this embodiment distributes around casing 7, has dispersed external force, has reduced the risk of deformation, support feeding case 1 that can be better, and the transversal triangle-shaped structure of personally submitting of support column 6 horizontal direction and triangle-shaped's one of them angle orientation casing 7 center not only are little to the fodder resistance, save space moreover for throw material efficiency higher.

The top of the shell 7 in the embodiment is of a conical structure, so that the size is small, the inclined plane of the shell is convenient for dispersing feed, the feeding plate 10 is convenient for feeding, and the feeding efficiency is improved.

In addition, inlet pipe 5 one side is equipped with second motor 20, and discharge gate 4 top is equipped with stirring rake 21, and stirring rake 21 and second motor 20 linkage, second motor 20 are fixed in on the feeding case 1, and stirring rake 21 and second motor 20 linkage make when the fodder enters into feeding case 1, can stir earlier then reentrant discharge gate 4, then reentrant batch layer 2 of throwing, and the stirring has avoided the fodder to wet and has glued together to jam discharge gate 4, influence the going on of throwing.

The driving box 3 in the embodiment comprises a first motor 15, a driving wheel 16, a driven wheel 17, a belt 18 and a supporting plate 19; the design of the whole driving box 3 makes the whole structure compact; the first motor 15 is located below the supporting plate 19 and is fixed at the bottom of the driving box 3, so that the first motor 15 can conveniently drive the driving wheel 16 to rotate, the driving wheel 16, the driven wheel 17 and the belt 18 are located above the supporting plate 19, the driving wheel 16 and the driven wheel 17 can stably rotate, the belt 18 is sleeved on the driving wheel 16 and the driven wheel 17, the driven wheel 17 is driven to rotate through the belt 18 under the rotation of the driving wheel 16, the driven wheel 17 is linked with the main gear 12, the main gear 12 can be driven to rotate when the driven wheel 17 rotates, the bevel gear 13 is driven to rotate, and then feeding is started.

The feed is put into the feed pipe 5, then enters the feed box 1, and under the stirring of the stirring paddle, the feed is prevented from being wetted and stuck together, so that the discharge hole 4 is blocked, and then enters the feed layer 2 through the blanking plate 22 and the discharge hole 4; under the drive of the first motor 15, the driving wheel 16 rotates, the driven wheel 17 starts to rotate through the belt 18, the driven wheel 17 rotates to drive the main gear 12 to rotate, then the main gear 12 rotates to drive the bevel gear 13 to rotate, the rotating rod 9 and the feeding plate 10 are driven to rotate and turn around the center of the shell 7 along with the rotation of the bevel gear 13, and the turn-around of the rotating rod 9 drives the shell 7 to turn around; when the fodder gets into and throws material layer 2, because rotary rod 9 drives and throws flitch 10 rotation for throw flitch 10 can constantly rotate, change self position, thereby change throw material angle and direction, therefore also different to the effort that the fodder was applyed, the cooperation turnover simultaneously, constantly beats out the fodder that falls, makes throw material scope and angle constantly improve, covers more throw material scope.

The rotation mode in this embodiment is that the feeding plate 10 rotates around the axis of the rotating rod 9, and the turnover is that the feeding plate 10 rotates around the central axis of the shell 7.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (10)

1. The aquaculture decentralized feeding device comprises a feeding box (1) and is characterized by being provided with a feeding layer (2); a driving box (3) is arranged on one side of the feeding layer (2), a supporting column (6) is arranged between the feeding layer (2) and the driving box (3), and two ends of the supporting column (6) are fixedly connected with the driving box (3) and the feeding box (1) respectively;

a discharge hole (4) is formed in the bottom of the feeding box (1), a feeding pipe (5) is arranged at the top of the feeding box (1), and the feeding box (1) is communicated with the feeding pipe (5); the feeding layer (2) comprises a shell (7) and a rotating device (8);

the rotating device (8) comprises a rotating rod (9) and a feeding plate (10); the feeding plate (10) is positioned at one side of the rotating rod (9), a connecting piece (11) is arranged at one side of the rotating rod (9) close to the feeding plate (10), the rotating rod (9) is fixedly connected with the connecting piece (11), and the connecting piece (11) is fixedly connected with the feeding plate (10);

the shell (7) is provided with a through hole (14), the connecting piece (11) is positioned in the through hole (14) and is in conflict with the through hole (14), the rotating rod (9) is positioned in the through hole (14), and the feeding plate (10) is positioned outside the through hole (14);

a linkage structure (23) is arranged in the shell (7), and the rotating rod (9) is linked with the linkage structure (23); the driving box (3) drives the linkage structure (23) to rotate.

2. An aquaculture decentralized feeding device according to claim 1, characterized in that the driving box (3) comprises a first motor (15), a driving wheel (16), a driven wheel (17), a belt (18) and a supporting plate (19); the first motor (15) is positioned below the supporting plate (19) and fixedly connected with the bottom of the driving box (3), and the first motor (15) is linked with the driving wheel (16); the driving wheel (16), the driven wheel (17) and the belt (18) are all positioned above the supporting plate (19), the belt (18) is sleeved on the driving wheel (16) and the driven wheel (17) and are mutually linked, and the driven wheel (17) is linked with the main gear (12).

3. The aquaculture decentralized feeding device according to claim 1, characterized in that a second motor (20) is arranged on one side of the feeding pipe (5), a stirring paddle (21) is arranged above the discharging hole (4), the stirring paddle (21) is linked with the second motor (20), and the second motor (20) is fixedly connected with the feeding box (1).

4. An aquaculture decentralized feeding device according to claim 1, characterized in that the top of the housing (7) is of conical construction.

5. The aquaculture decentralized feeding device according to claim 1, wherein the support columns (6) are distributed around the housing (7), and the cross section of the support columns (6) in the horizontal direction is triangular.

6. An aquaculture decentralized feeding device according to claim 1, characterized in that the linkage structure (23) comprises a main gear (12) and a bevel gear (13), wherein the bevel gear (13) is arranged on the upper part of the main gear (12) and meshed with the main gear (12), the bevel gear (13) is linked with the rotary rod (9), and the driving box (3) drives the main gear (12) to rotate.

7. An aquaculture decentralized feeder according to claim 1, characterized in that the feed box (1) is located above the feed layer (2).

8. An aquaculture decentralized feeder according to claim 1, characterized in that the feeder plate (10) has a rectangular cross-section.

9. An aquaculture decentralized feeding device according to claim 1, characterized in that the feeding pipe (5) has an L-shaped cross section and is fixedly connected with the feeding box (1).

10. The aquaculture decentralized feeding device according to claim 1, characterized in that a blanking plate (22) is arranged inside the feeding box (1), and the blanking plate (22) is fixedly connected with the feeding box (1).