CN219741584U - Aquaculture feeding device - Google Patents

Abstract

The utility model belongs to the technical field of aquaculture equipment, and particularly relates to an aquaculture feeding device, which comprises a device shell and a control mechanism, wherein an inner space I and an inner space II are arranged in the device shell, the control mechanism, a storage box, a transparent measuring cylinder, a motor and a grating sensor are arranged in the inner space I, the transparent measuring cylinder is connected with the storage box through an electric baffle I, the grating sensor is arranged in parallel with the transparent measuring cylinder, a vibration mechanism is arranged in the inner space II, the electric baffle II is arranged at the bottom of the inner space II and communicated with a discharge hole at the outer side of the inner space, so that the timing and quantitative automatic feeding of feed is realized, the feeding amount of the feed is automatically adjusted according to different conditions, meanwhile, the feeding range of the feed is enlarged by utilizing the structure of a discharge groove, and the problems of large manual feeding workload, small feeding range and the like are solved.

Description

Aquaculture feeding device

Technical Field

The utility model belongs to the technical field of aquaculture equipment, and particularly relates to an aquaculture feeding device.

Background

The fish farming, also called aquaculture, refers to the cultivation of fish or various seafood in fish farms opened up by manpower on the shore for eating. For inland freshwater aquaculture, the feeding operation is required to be carried out on the water body regularly, nutrient substances are timely provided for guaranteeing the growth of fishes, and the feed amount required by different times is different for guaranteeing the benefit.

However, for a large-scale cultivation industry, one or more people are required to perform feeding operation regularly, the feeding operation is finished by manually sowing the feed, the sowing range is limited, the feeding operation is time-consuming and labor-consuming, and the amount of the feed at different time periods is difficult to grasp by manual feeding.

Disclosure of Invention

The utility model provides an aquaculture feeding device which aims to solve the problems in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an aquaculture feeding device, includes device shell, control mechanism, there is first, the inner space second in the device shell, install in the inner space first control mechanism, storage case, transparent measuring cylinder, motor, grating sensor, the storage case link up the device shell top surface, the inside movable box board that is equipped with of storage case, electric baffle first, movable box board moves through the spout, transparent measuring cylinder passes through electric baffle first with the storage case links to each other, grating sensor with parallel arrangement between the transparent measuring cylinder, install vibration mechanism in the inner space second, vibration mechanism comprises vibration case, vibration motor, electric baffle second, vibration case with be separated by rack baffle between the transparent measuring cylinder, inner space second bottom be equipped with electric baffle second with inner space outside discharge gate is linked together, rack baffle install in between inner space first with the inner space second.

Preferably, the device shell is provided with a fixing mechanism, the fixing plate and the fixing nails are arranged at the bottom of the bracket of the device shell, and each surface around the device shell is provided with a fixing ring.

Preferably, the device shell and the storage box are internally provided with a sealing and moistureproof mechanism, a chute sealing strip is arranged at the chute at the inlet of the storage box, a sealing layer is arranged on the top surface of the storage box, a sealing layer is arranged in the first inner space of the device shell, and a drying box is arranged in the first inner space.

Preferably, an independent energy supply mechanism is arranged, a storage battery is arranged in the first internal space, and a solar panel is arranged on the top surface of the device shell.

Preferably, the whole bottom surface of the discharge hole is inclined, and the inclination direction is downward inclination by taking the second position of the electric baffle plate as the top end.

Compared with the prior art, the utility model has the beneficial effects that:

the utility model realizes the timing and quantitative automatic feeding of the feed, realizes the automatic adjustment of the feed feeding amount according to different conditions, enlarges the feeding range of the feed by utilizing the structure of the discharge chute, solves the problems of large manual feeding workload, small feeding range and the like,

drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a side cross-sectional view of the present utility model;

FIG. 3 is a front cross-sectional view of the present utility model;

FIG. 4 is a schematic view of a rack bottom plate installation in accordance with the present utility model;

FIG. 5 is a schematic view of a storage bin gate according to the present utility model.

FIG. 6 is a schematic view of the bottom of the spout according to the present utility model

In the figure: 1. device housing 11, first inner space 12, second inner space 2, control mechanism 3, storage and discharge mechanism 31, storage tank 311, moving tank plate 312, chute 313, first electric baffle 32, transparent measuring cylinder 33, vibration mechanism 331, vibration tank 332, vibration motor 333, second electric baffle 34, discharge chute 35, grating sensor 36, rack baffle 37, motor 4, independent energy supply mechanism 41, battery 42, solar panel 5, fixing mechanism 51, fixing plate 52, fixing nail 53, fixing ring 6, sealing and moisture-proof mechanism 61, chute sealing strip 62, sealing layer 63, and drying oven.

Detailed Description

Referring to fig. 2-3, the present utility model provides the following technical solutions: the utility model provides an aquaculture feeding device, includes device shell 1, control mechanism 2, its characterized in that: the device is characterized in that an inner space I11 and an inner space II 12 are arranged in the device shell 1, a control mechanism 2, a storage box 31, a transparent measuring cylinder 32, a motor 37 and a grating sensor 35 are arranged in the inner space I11, the storage box 31 penetrates through the top surface of the device shell 1, a movable box plate 311 and an electric baffle I313 are arranged in the storage box 31, the movable box plate 311 moves through a chute 312, the transparent measuring cylinder 32 is connected with the storage box 31 through the electric baffle I313, the grating sensor 35 and the transparent measuring cylinder 32 are arranged in parallel, a vibration mechanism 33 is arranged in the inner space II 12, the vibration mechanism 33 consists of a vibration box 331, a vibration motor 332 and an electric baffle II 333, the vibration box 331 is separated from the transparent measuring cylinder 32 by a rack baffle 36, the bottom of the inner space II 12 is provided with the electric baffle II 333 which is communicated with a discharging groove 34 outside the inner space II 12, and the rack baffle 36 is arranged between the inner space I11 and the inner space II 12.

There are first inner space 11, second inner space 12 in the device shell 1, install rack baffle 36 between first inner space 11, second inner space 12, rack baffle 36 is equipped with the hole the same as transparent measuring cylinder 32 size, mutually support between motor 37 and the rack baffle 36, whether communicate between control motor 37 and the transparent measuring cylinder 32, parallel arrangement between grating sensor 35 and the transparent measuring cylinder 32, grating sensor 35 can confirm the volume of fodder in the transparent measuring cylinder 32, thereby realize the ration and take fodder, electric baffle 313 links to each other with transparent measuring cylinder 32, realize the timing of fodder and take, vibration mechanism 33 installs in inside second inner space 12, vibration motor 332 is installed to vibration box 331 both sides, vibration motor 332 can make the inside fodder of vibration box 331 evenly tile inside, prevent that the fodder from piling up together after getting into vibration box 331 from transparent measuring cylinder 32, avoid leading to extravagant fodder because of the fodder is unrestrained inhomogeneous and the emergence of the phenomenon such as being injured because of the aquatic products disputed fodder.

Specifically, referring to fig. 1, a fixing mechanism 5 is installed on a device housing 1, a fixing plate 51 and fixing nails 52 are installed at the bottom of a bracket of the device housing 1, and fixing rings 53 are installed on each surface of the periphery of the device housing 1.

During installation, the fixing plate 51 is buried by sludge at the bottom of the culture pond, the fixing nails 52 are inserted into the bottom of the culture pond, and the device is prevented from toppling due to water flow, because the gravity center of the device is positioned at the upper half part, in order to increase the overall stability of the device, the fixing rings 53 are respectively arranged on the peripheral surfaces of the device shell 1, ropes with one ends connected with the fixing nails 52 in series and the other ends connected with hooks are used during installation, the fixing nails 52 are fixed at the bottom of the culture pond, and the hooks are connected with the fixing rings 53.

Specifically, the device shell 1 and the storage box 31 are internally provided with a sealing and moistureproof mechanism 6, a chute sealing strip 61 is arranged at the chute 312 at the inlet of the storage box 31, the top surface of the storage box 31 is internally provided with a sealing layer 62, the first inner space 11 of the device shell 1 is internally provided with the sealing layer 62, and the first inner space 11 is internally provided with a drying box 63.

In order to prevent the water vapor from affecting the operation of the device, the first inner space 11 and the second inner space 12 are arranged in the device shell 1 to isolate the water vapor, and the discharge hole in the discharge chute 34 is in a slender square shape, so that the water vapor entering during discharging is reduced.

Referring to fig. 4-5, the first interior space 11 and the storage tank 31 are sealed by the chute sealing strip 61 and the sealing layer 62 to prevent water vapor from entering the device when the device is placed on the water surface, and meanwhile, the drying box 63 is installed in the first interior space 11 to ensure that the influence of the moist use environment on the device is reduced to the minimum.

Specifically, an independent energy supply mechanism 4 is set up, a storage battery 41 is arranged in the first internal space 11, and a solar panel 42 is arranged on the top surface of the device shell 1.

In order to increase the cruising ability of the device, the device is prevented from being unusable due to unexpected factors such as power failure, damage to power supply lines and the like, a storage battery 41 is arranged in the first inner space 11, a solar panel 42 is arranged on the upper surface of the device shell 1, and the device can still operate for a period of time after power failure.

Specifically, the discharge slot in the discharge chute 34 is inclined, and the inclination direction is downward inclination by taking the position of the second electric baffle 333 as the top end.

Referring to fig. 2 and 6, the whole bottom surface of the discharge chute 34 is inclined, and the protruding portion is designed at the bottom to ensure that the feed falling from the vibration mechanism 33 can uniformly fall into the water from left and right, and the inclined plane extending outwards can expand the falling range of the feed, so as to avoid adverse effects caused by too dense feed.

The working principle and the using flow of the utility model are as follows: after the set time is reached, the control mechanism 2 opens the first electric baffle 313, the feed falls into the transparent measuring cylinder 32 from the storage box 31, the grating sensor 35 scans the transparent measuring cylinder 32, the first electric baffle 313 is closed after the feed reaches the preset height, the starting motor 37 drives the rack baffle 36, the feed falls into the vibration box 331 from the hole, then the rack baffle 36 is restored to the original position, the vibration motor 332 is started, the second electric baffle 333 is opened after the feed is uniformly shaken, and the feed falls into the water from the discharge slot after the feed falls into the discharge slot 34.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present utility model has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (5)

1. The utility model provides an aquaculture feeding device, includes device shell (1), control mechanism (2), its characterized in that: the device comprises a device shell (1), wherein an inner space I (11) and an inner space II (12) are arranged in the device shell (1), a control mechanism (2), a storage box (31), a transparent measuring cylinder (32), a motor (37) and a grating sensor (35) are arranged in the inner space I (11), the storage box (31) penetrates through the top surface of the device shell (1), a movable box plate (311) and an electric baffle I (313) are arranged in the storage box (31), the movable box plate (311) moves through a sliding groove (312), the transparent measuring cylinder (32) is connected with the storage box (31) through the electric baffle I (313), a vibration mechanism (33) is arranged in the inner space II (12) in parallel, the vibration mechanism (33) consists of a vibration box (331), a vibration motor (332) and an electric baffle II (333), a rack (36) is arranged between the vibration box (331) and the transparent measuring cylinder (32), the inner space II (12) is separated by the rack II, the inner space II (12) is provided with a discharge groove (34) and is communicated with the outer side of the discharge groove (34), the rack baffle (36) is installed between the first internal space (11) and the second internal space (12).

2. An aquaculture feeding apparatus according to claim 1 wherein: the device is characterized in that the device housing (1) is provided with a fixing mechanism (5), a fixing plate (51) and fixing nails (52) are arranged at the bottom of a bracket of the device housing (1), and each surface around the device housing (1) is provided with a fixing ring (53).

3. An aquaculture feeding apparatus according to claim 1 wherein: the device comprises a device shell (1) and a storage box (31), wherein a sealing and moistureproof mechanism (6) is arranged inside the storage box (31), a chute sealing strip (61) is arranged at an inlet chute (312) of the storage box (31), a sealing layer (62) is arranged on the inner top surface of the storage box (31), the sealing layer (62) is arranged inside an inner space I (11), and a drying box (63) is arranged inside the inner space I (11).

4. An aquaculture feeding apparatus according to claim 1 wherein: an independent energy supply mechanism (4) is arranged, a storage battery (41) is arranged in the first internal space (11), and a solar panel (42) is arranged on the top surface of the device shell (1).

5. An aquaculture feeding apparatus according to claim 1 wherein: the discharge slot in the discharge chute (34) is of an inclined design, and the inclined direction is that the second electric baffle (333) is taken as the top end to incline downwards.