CN214628954U - Feeding device and feeding system - Google Patents

Abstract

The application discloses feeding equipment and a feeding system, wherein the feeding equipment comprises a shell and a material storage assembly, and the shell is provided with a first blanking port and a first blanking channel connected with the blanking port; storage component sets up in the shell, storage component is used for storing the fodder, storage component includes second feed opening and the second unloading passageway of being connected with the second feed opening, the second feed opening is located first feed opening in the projection of horizontal plane at the projection of horizontal plane, the equal perpendicular horizontal plane of inner wall of the inner wall of first unloading passageway and second unloading passageway, first unloading passageway and second unloading passageway cooperation are so that the fodder gets into first unloading passageway from second unloading passageway. The utility model provides a first unloading passageway and second unloading passageway do not have turning and gap, and the fodder is difficult for accumulation in second unloading passageway and first unloading passageway to prevent the fodder pollution and the passageway jam problem that the fodder accumulation leads to.

Description

Feeding device and feeding system

Technical Field

The application relates to the technical field of animal feeding, more specifically relates to a feeding equipment and feeding system.

Background

At present, the scale of breeding industries such as pig breeding is continuously enlarged, for example, a farm may breed ten thousand pigs at the same time, and therefore, a large amount of manual management is needed. In order to improve the culture efficiency and reduce the labor cost, feeding equipment and other equipment are adopted in a large-scale culture farm to improve the culture efficiency. However, due to the complex structure of the automatic feeding equipment, the feed is easily accumulated at the corners and gaps of the channel, and due to the fact that the feed cannot be cleaned in time, the feed may be mildewed and polluted, and even the channel for feeding is blocked, so that the feeding efficiency is reduced.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides a feeding equipment and feeding system.

The feeding device of this application embodiment includes shell and storage component. The shell is provided with a first blanking port and a first blanking channel connected with the blanking port; storage component sets up in the shell, storage component is used for storing the fodder, storage component include the second feed opening and with the second unloading passageway that the second feed opening is connected, the second feed opening is located in the projection of horizontal plane first feed opening is in the projection of horizontal plane, the equal perpendicular horizontal plane of inner wall of the inner wall of first unloading passageway and second unloading passageway, first unloading passageway and second unloading passageway cooperation are so that the fodder is followed second unloading passageway gets into first unloading passageway.

In certain embodiments, the second blanking channel is located within and joined to the first blanking channel, and an outer wall of the second blanking channel is in contact with an inner wall of the first blanking channel.

In certain embodiments, the feeding apparatus further comprises a seal assembly comprising a first seal connected to the housing, the first seal comprising a third feed channel, the second feed channel at least partially positioned within the third feed channel, the third feed channel positioned within the first feed channel, an outer wall of the third feed channel bonded to an inner wall of the first feed channel.

In certain embodiments, the seal assembly further comprises a second seal surrounding the second feed channel and sealing a gap between an outer wall of the second feed channel and an inner wall of the third feed channel.

In some embodiments, the equipment of feeding has still included the unloading subassembly, the unloading subassembly include the axis of rotation, encircle the axis of rotation and with axis of rotation fixed connection's rotating blade and with axis of rotation connection's driving piece, the axis of rotation is worn to establish storage component's diapire, rotating blade is located the diapire, the driving piece is located storage component's outside the driving piece drive the axis of rotation rotates in order to drive when rotating blade rotates, rotating blade will be located the fodder of diapire pushes away the second feed opening.

In certain embodiments, the driver is disposed between the first seal and the magazine assembly, the driver being secured to the first seal.

In certain embodiments, the feeding device further comprises an industrial control assembly, the first seal and the bottom of the housing enclose an installation space, and the industrial control assembly is disposed within the installation space.

In some embodiments, the feeding device further comprises a feeding assembly and a weighing assembly, wherein the feeding assembly is used for conveying feed into a storage space of the storage assembly, the weighing assembly is used for weighing the feed in the storage space, the industrial control assembly is electrically connected with the feeding assembly, the weighing assembly and the discharging assembly, and the industrial control assembly is used for controlling the feeding assembly, the weighing assembly and the discharging assembly to work in a matched mode so as to output the feed with preset mass into the first discharging channel.

In some embodiments, the feeding device further comprises a feed delivery pipe and a feed pipe, the feed delivery pipe is connected with the first feeding channel and the feed pipe, and feed output by the first feeding channel enters the trough after passing through the feed delivery pipe and the feed pipe.

A feeding system of an embodiment of the application includes a stockline and a feeding apparatus of any of the embodiments described above. The feeding equipment is arranged on the material line. The stockline is used for conveying feed to the feeding equipment.

In the equipment of feeding and the feeding system of this application embodiment, the equal perpendicular horizontal plane of inner wall of the first unloading passageway of shell and the inner wall of the second unloading passageway of storage component for there are not turning and gap in the inner wall of first unloading passageway and the inner wall of second unloading passageway, when making the fodder in the storage component carry out the ejection of compact through second unloading passageway and first unloading passageway, the fodder is difficult to accumulate in second unloading passageway and first unloading passageway, thereby prevent fodder pollution and the passageway jam problem that the fodder accumulation leads to.

Additional aspects and advantages of embodiments of the present application will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of embodiments of the present application.

Drawings

The above and/or additional aspects and advantages of the present application will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a schematic plan view of a feeding apparatus and trough of certain embodiments of the present application;

FIG. 2 is a schematic plan view of another perspective of a feeding apparatus of certain embodiments of the present application;

FIG. 3 is a schematic cross-sectional view of the feeding device shown in FIG. 1 along line III-III; and

fig. 4 is a schematic diagram of the feeding system of certain embodiments of the present application.

Detailed Description

Embodiments of the present application will be further described below with reference to the accompanying drawings. The same or similar reference numbers in the drawings identify the same or similar elements or elements having the same or similar functionality throughout.

In addition, the embodiments of the present application described below in conjunction with the accompanying drawings are exemplary and are only for the purpose of explaining the embodiments of the present application, and are not to be construed as limiting the present application.

In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through intervening media. Also, a first feature "on," "above," and "over" a second feature may mean that the first feature is directly above or obliquely above the second feature, or that only the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

Referring to fig. 1 to 3, a feeding apparatus 100 according to an embodiment of the present application includes a housing 10 and a magazine assembly 20. The shell 10 is provided with a first feed opening 11 and a first feed channel 12, and the first feed channel 12 is connected with the first feed opening 11; storage component 20 sets up in shell 10, storage component 20 forms storage space 21, storage space 21 is used for storing the fodder, storage component 20 includes second feed opening 22 and second unloading passageway 23, second unloading passageway 23 and second feed opening 22 are connected, second unloading passageway 23 and storage space 21 intercommunication, second feed opening 22 is located first feed opening 11 in the projection of horizontal plane, second unloading passageway 23 corresponds the setting with first unloading passageway 12, the equal perpendicular horizontal plane of inner wall of first unloading passageway 12 and second unloading passageway 23, first unloading passageway 12 and the cooperation of second unloading passageway 23 are so that the fodder gets into first unloading passageway 12 from second unloading passageway 23.

In the feeding equipment 100 of this application embodiment, the equal vertical horizontal plane of inner wall of the first unloading passageway 12 of shell 10 and the inner wall of the second unloading passageway 23 of storage component 20 for there is not turning and gap in the inner wall of first unloading passageway 12 and the inner wall of second unloading passageway 23, when fodder in storage component 20 carries out the ejection of compact through second unloading passageway 23 and first unloading passageway 12, the fodder is difficult for accumulating in second unloading passageway 23 and first unloading passageway 12, thereby prevent fodder pollution and the passageway jam problem that the fodder accumulation leads to.

Referring to fig. 1 and 4, a feeding system 1000 according to an embodiment of the present application includes a feeding device 400, a material line 300, a feeding device 100, and a trough 200. The head and the tail of the stockline 300 are both connected with the feeding device 400, the feeding device 400 is used for inputting the feed from the head of the stockline 300, and the unused feed is recovered by the feeding device 400 from the tail after the feed is transported through the stockline 300, so that the feed is prevented from being wasted.

The feeding device 100 is arranged on the material line 300, the material line 300 is arranged along the culture space 500 where the cultured objects are located, the position where the feeding device 100 is arranged corresponds to the culture space 500, and the feeding device 100 is used for conveying the feed transported on the material line 300 to the trough 200 in the culture space 500.

The cultivated objects can be animals or plants, such as pigs, cattle, sheep, rice, etc., which are not listed here, and the cultivation space 500 is the space where the cultivated objects are located.

Referring to fig. 1 to 3, the feeding apparatus 100 includes a housing 10, a feeding assembly 30, a weighing assembly 40, a storing assembly 20, a blanking assembly 50, a sealing assembly 60, a feeding assembly 70 and an industrial control assembly 80.

The shell 10, the feeding subassembly 30, the weighing subassembly 40, the storage subassembly 20, the unloading subassembly 50, the seal assembly 60, feed subassembly 70 and industrial control subassembly 80 are all detachably connected together, when at least one of the shell 10, the feeding subassembly 30, the weighing subassembly 40, the storage subassembly 20, the unloading subassembly 50, the seal assembly 60, the feed subassembly 70 and the industrial control subassembly 80 needs to be replaced or maintained, the dismouting is very convenient, and the use cost of the feeding device 100 is reduced.

The feeding assembly 30, the weighing assembly 40, the storage assembly 20, the blanking assembly 50, the sealing assembly 60, the feeding assembly 70 and the industrial control assembly 80 are all arranged in the shell 10, and the shell 10 plays a role in protecting the feeding assembly 30, the weighing assembly 40, the storage assembly 20, the blanking assembly 50, the sealing assembly 60, the feeding assembly 70 and the industrial control assembly 80.

The stockline 300 penetrates through the shell 10, the feeding assembly 30 is connected with the stockline 300, the feeding assembly 30 can selectively convey feed in the stockline 300 to the storage space 21 of the storage assembly 20, the feeding assembly 30 is connected with the industrial control assembly 80, and the industrial control assembly 80 can control the feeding speed of the feeding assembly 30.

After the fodder got into storage space 21, weighing component 40 can weigh the fodder in storage space 21 in real time, and industry control assembly 80 is connected with weighing component 40 in order to obtain weighing data, and after the weight of the fodder in storage space 21 reached and predetermines the quality, industry control assembly 80 controlled feeding component 30 promptly and stopped the feeding, and the quality of predetermineeing is confirmed according to the required food intake of the breed quantity of current breed space 500 (shown in figure 4) breed and every breed.

The storage assembly 20 comprises a first end 24 and a second end 25 which are opposite to each other, the first end 24 is connected with the weighing assembly 40, and the second end 25 is connected with the blanking assembly 50.

The first end 24 defines a feed opening 241, an annular sidewall 242 surrounding the feed opening 241, and a projection 243 extending from the annular sidewall 242 in a direction perpendicular to the annular sidewall 242. The bosses 243 may be one and may be disposed annularly around the annular sidewall 242; the bosses 243 may also be multiple, evenly distributed about the center of the annular sidewall 243. The load cell 40 includes a load ring 41 and a load cell 42 fixed between the load ring 41 and the housing 10, the load ring 41 having a ring shape, the bosses 243 being carried on the load ring 41, the load cell 42 being adapted to detect the weight of the magazine 20 carried on the load ring 41 by the bosses 243. The number of the weighing sensors 42 can be one, the weighing sensors 42 are annular and are arranged corresponding to the bearing ring 41, the weighing sensors 42 can be multiple, the weighing sensors 42 are uniformly arranged around the center of the bearing ring 41, whether different weighing sensors 42 are stressed uniformly can be judged according to data detected by the weighing sensors 42, and the obtained weighing data are determined to be effective weighing data when the stress is uniform (if the difference value of the weights detected by any two weighing sensors 42 is smaller than a preset value). In this way, since the weighing assembly 40 carries the annular boss 243 or the plurality of bosses 243 uniformly distributed around the center of the annular side wall 243 through the carrying ring 41, different areas of the load cell 42 or different load cells 42 are uniformly stressed, and thus the detection accuracy of the weighing assembly 40 is improved.

Storage component 20 forms storage space 21, and storage space 21 can be used for storing the fodder for the fodder is difficult by external steam, bacterium etc. and pollutes, makes the fodder can preserve the longer time. The feed may be fluid feed, granular feed, powdered feed, block feed, etc., and the specific form of the feed is not limited herein. The magazine assembly 20 may be made of iron, plastic, silicone, alloy, stainless steel, etc.

The first feed opening 11 and the first feed passage 12 connected to the first feed opening 11 are disposed in the housing 10, and the first feed opening 11 and the first feed passage 12 are both located at the second end 25 of the storage component 20.

The second end 25 of the storing component 20 is provided with a second feed opening 22 matched with the feed opening 241 and a second feed channel 23 matched with the first feed channel 12. The matching relationship between the second feed opening 22 and the first feed opening 11 is as follows: after the feeding device 100 is vertically (i.e., vertical to the horizontal plane) disposed on the material line 3009 (shown in fig. 4), the projection of the second feed opening 22 on the horizontal plane is located within the projection of the first feed opening 11 on the horizontal plane; the matching relationship between the first blanking channel 12 and the second blanking channel 23 may be: the second blanking channel 23 is at least partially located within the first blanking channel 12 and is combined with the first blanking channel 12, and the outer wall of the second blanking channel 23 is in contact with the inner wall of the first blanking channel 12.

The first blanking channel 12 and the second blanking channel 23 are both cylindrical structures, the outer wall of the second blanking channel 23 is in contact with the inner wall of the first blanking channel 12, that is, the inner diameter of the first blanking channel 12 is equal to the outer diameter of the second blanking channel 23, so that the first blanking channel 12 and the second blanking channel 23 are just sleeved together, and after being combined, the first blanking channel 12 and the second blanking channel 23 basically have no gap, and the sealing performance is good. Of course, the matching relationship between the first blanking channel 12 and the second blanking channel 23 may also be: the second discharging channel 23 is at least partially located in the first discharging channel 12, the outer wall of the second discharging channel 23 is not in contact with the inner wall of the first discharging channel 12, although there is a certain sealing system between the outer wall of the second discharging channel 23 and the inner wall of the first discharging channel 12, the feed can directly enter the first discharging channel 12 due to the gravity after coming out from the second discharging channel 23, and basically cannot enter the gap between the outer wall of the second discharging channel 23 and the inner wall of the first discharging channel 12. Therefore, the first blanking channel 12 and the second blanking channel 23 are both cylindrical, corners and gaps are not formed inside the first blanking channel 12 and the second blanking channel 23, and feed is not easy to accumulate in the first blanking channel 12 and the second blanking channel 23, so that the problems of feed pollution and channel blockage are solved.

In one embodiment, the inner wall of the first discharging channel 12 and the inner wall of the second discharging channel 23 are both vertical to the horizontal plane, and compared with the inner wall of the first discharging channel 12 and the inner wall of the second discharging channel 23 which are not vertical to the horizontal plane, the feed will generate an interaction force with the channels under the action of gravity and thus attach to the channels, so that the feed will not substantially generate an interaction force with the inner walls of the first discharging channel 12 and the second discharging channel 23, thereby reducing the probability that the feed will attach to the inner walls of the first discharging channel 12 and the second discharging channel 23, and further preventing the feed from accumulating in the channels.

Further, the light transmittance of the housing 10 and the magazine assembly 20 may be greater than 65% so that the condition of the feed in the magazine assembly 20 can be observed. In one embodiment, the housing 10 and the storage component 20 may be made of plastic with high light transmittance, such as polymethyl Methacrylate (PMMA), Polystyrene (Polystyrene, PS), Polycarbonate (PC), etc., so as to make it possible to more visually observe whether the feed in the storage component 20 has mildew, caking, moisture, and pests; in addition, plastics have better corrosion resistance for storage component 20 is also difficult to be corroded for long-term use, the security of fodder has been guaranteed to a higher degree.

Further, the magazine 20 may be a single-layer structure, which may make the thickness of the magazine 20 smaller, and thus make the magazine 20 more transparent, so that the condition of the feed in the magazine 20 can be observed more clearly and intuitively. Meanwhile, the storage assembly 20 is of a single-layer structure, and the manufacturing cost of the storage assembly 20 can be reduced.

In one embodiment, the scale values are arranged on the outer surface or the inner surface of the storage assembly 20, so that the volume of the feed in the storage assembly 20 can be visually known according to the scale values, and the feed can be timely supplemented when the feed is insufficient.

The seal assembly 60 includes a first seal 61 and a second seal 62.

The first seal 61 is connected to the housing 10. The first sealing member 61 is formed with a third blanking channel 611, the third blanking channel 611 is at least partially located in the first blanking channel 12, and the outer wall of the portion of the third blanking channel 611 located in the first blanking channel 12 is combined with the inner wall of the first blanking channel 12, that is, the outer diameter of the portion of the third blanking channel 611 located in the first blanking channel 12 is the same as the inner diameter of the first blanking channel 12, so that no gap exists between the third blanking channel 611 and the first blanking channel 12.

A second seal 62 is arranged between the second feed channel 23 and the third feed channel 611 and is connected to the first seal 61, the second feed channel 23 being at least partially located in the third feed channel 611, the second seal 62 sealing the gap between the second feed channel 23 and the third feed channel 611.

The first sealing element 61 and the housing 10 form an installation space 91 (hereinafter referred to as a first installation space 91), after the fodder comes out from the second discharging channel 23, the fodder cannot enter the first installation space 91 from a gap between the first discharging channel 12 and the third discharging channel 611, the first sealing element 61, the second sealing element 62 and the storage component 20 form a second installation space 92, the discharging component 50 is arranged in the second installation space 92, after the fodder comes out from the second discharging channel 23, the fodder cannot enter the second installation space 92 from a gap between the second discharging channel 23 and the third discharging channel 611, and therefore the fodder can only pass through the second discharging channel 23, the third discharging channel 611 and the first discharging channel 12 in sequence and then is output from the first discharging channel 12. In this embodiment, the first sealing member 61 and the second sealing member 62 may be made of silicone material, which has better sealing performance.

In one embodiment, the third blanking passage 611 is also cylindrical, and the outer diameter of the second blanking passage 23 is the same as the inner diameter of the third blanking passage 611, so that there is no gap between the third blanking passage 611 and the second blanking passage 23 without providing the second seal 62.

In another embodiment, the third blanking passage 611 is not cylindrical, the third blanking passage 611 includes a first sealing portion 612 having a truncated cone shape and a second sealing portion 613 having a cylindrical shape, and the first sealing portion 612 and the second sealing portion 613 are connected. The second blanking passage 23 is at least partially located within the first seal 612, a gap exists between the inner wall of the first seal 612 and the outer wall of the second blanking passage 23, and a second seal 62 is disposed between the inner wall of the first seal 612 and the outer wall of the second blanking passage 23 to seal the gap. The minimum inner diameter of the first sealing portion 612 is equal to the inner diameter of the second sealing portion 613, and the second feeding channel 23 can be disposed in the first sealing portion 612 with a larger outer diameter (e.g. larger than the inner diameter of the second sealing portion 613), so as to increase the amount of the feed output per unit time and increase the feeding speed.

The blanking assembly 50 comprises a rotating shaft 51, a rotating blade 52 and a driving piece 53, the rotating shaft 51 penetrates through the bottom wall 26 of the magazine assembly 20, the rotating blade 52 surrounds the rotating shaft 51 and is fixedly connected with the rotating shaft 51, the rotating blade 52 is located on the bottom wall 26, and the driving piece 53 is connected with the rotating shaft 51. The driving member 53 is located in the magazine assembly 20 at a position corresponding to the bottom wall 26 and in the second mounting space 92, and the driving member 53 is fixedly disposed on the first seal member 61.

When the driving member 53 drives the rotating shaft 51 to rotate, the rotating shaft 51 drives the rotating blade 52 to rotate, and the rotating blade 52 can push the fodder located on the bottom wall 26 to the second feed opening 22, so that the fodder is output from the second feed opening 22.

The industrial control assembly 80 includes a first industrial control 81 connected to the weighing assembly 40 and the feeding assembly 30, and a second industrial control 82 connected to the blanking assembly 50. The first tool control 81 is disposed in the third installation space 93 defined by the feeding assembly 30 and the housing 10, and the second tool control 82 is disposed in the first installation space 91. The first and second industrial controls 81 and 82 may also be connected by internal routing within the enclosure 10.

The industrial control assembly 80 further includes a connector 83 and a display 84, the connector 83 is disposed on the housing 10, and the connector 83 includes at least two connecting ends 831. It is understood that the number of attachment ends 831 can be any greater number, such as two, three, four, five, six, etc. In the example shown in fig. 3, the two connecting ends 831 are respectively connected to the first work control 81 and the display 84 to realize the communication between the first work control 81 and the display 84, the first work control 81 can acquire the weight of the feed measured by the weighing assembly 40 and control the display 84 to display the weight of the feed, so that the user can see the feed amount in the storage space 21 in real time, the display 84 can display the actual mass when displaying the feed amount, and the percentage of the remaining feed amount in the storage space 21 to the maximum feed amount can also be displayed.

The feeding assembly 70 comprises a feeding pipe 71 and a feeding pipe 72. The feeding assembly 70 is connected to the first baiting path 12 of the housing 10.

The feeding pipe 71 is hermetically connected with the first feeding channel 12 and the feeding pipe 72, so that the opening of the first feeding channel 12 is prevented from being directly exposed to the outside, and various insects in the culture space 500 enter the storage assembly 20 from the opening of the first feeding channel 12 to pollute the feed. The feed delivery pipe 71 can be a plastic hose, which has low cost and is convenient for connecting the feed delivery pipe 71 and the feed pipe 72. The feeding pipe 72 is provided on the trough 200 of the culture space 500.

In operation, the first tool control 81 controls the feeding assembly 30 to feed, then the amount of the feed in the storage space 21 is obtained from the weighing assembly 40 in real time and displayed on the display 84, and when the amount of the feed in the storage space 21 reaches the preset mass, the first tool control 81 controls the feeding assembly 30 to stop feeding. When the feeding assembly 30 feeds, the first worker control 81 sends a feeding signal to the second worker control 82, and the second worker control 82 controls the feeding assembly 50 to feed at the same time, that is, the feeding assembly 50 can feed at the same time, so that the feeding efficiency is improved; the feeding component 50 can also feed when the feeding component 30 stops feeding, that is, the amount of feed in the storage space 21 reaches the preset quality, and at this time, the amount of feed pushed to the second feeding hole 22 when the rotating blade 52 of the feeding component 50 rotates is more, and the feeding amount per unit time is increased, so that the working time of the feeding component 50 is shortened, and the power consumption is reduced. The following description will take the feeding of the feeding assembly 50 when the amount of the feed in the storage space 21 reaches a predetermined amount.

During feeding, the weighing component 40 detects the amount of the remaining feed in real time, and after the feed output from the first feeding channel 12 passes through the feed delivery pipe 71 and the feed pipe 72, the feed can enter the trough 200 corresponding to the feed pipe 72, so as to feed the cultured objects. When the residual feed amount is 0, the feed with the preset mass is discharged, and the discharging is considered to be finished at the moment.

In summary, in the feeding device 100 and the feeding system 1000 according to the embodiments of the present application, the inner wall of the first discharging channel 12 of the housing 10 and the inner wall of the second discharging channel 23 are both vertical to the horizontal plane and are cylindrical, so that there are no corners and gaps on the inner wall of the first discharging channel 12 and the inner wall of the second discharging channel 23, and when the feed in the storage assembly 20 is discharged through the second discharging channel 23 and the first discharging channel 12, the feed is not easily accumulated in the second discharging channel 23 and the first discharging channel 12, thereby preventing the feed pollution and channel blockage caused by the feed accumulation.

In the description herein, reference to the description of the terms "certain embodiments," "one embodiment," "some embodiments," "illustrative embodiments," "examples," "specific examples," or "some examples" means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the application. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one of the feature. In the description of the present application, "a plurality" means at least two, e.g., two, three, unless specifically limited otherwise.

Although embodiments of the present application have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present application, and that variations, modifications, substitutions and alterations of the above embodiments may be made by those of ordinary skill in the art within the scope of the present application, which is defined by the claims and their equivalents.

Claims (10)

1. A feeding apparatus, comprising:

the shell is provided with a first feed opening and a first feed channel connected with the first feed opening; and

the setting is in storage component in the shell, storage component is used for storing the fodder, storage component include the second feed opening and with the second unloading passageway that the second feed opening is connected, the second feed opening is located in the projection of horizontal plane first feed opening is in the projection of horizontal plane, the equal perpendicular horizontal plane of inner wall of the inner wall of first unloading passageway and second unloading passageway, first unloading passageway and second unloading passageway cooperate so that the fodder is followed second unloading passageway gets into first unloading passageway.

2. The feeding apparatus of claim 1, wherein the second feed channel is at least partially located within and integrated with the first feed channel, and an outer wall of the second feed channel is in contact with an inner wall of the first feed channel.

3. The feeding apparatus of claim 2, further comprising a seal assembly, the seal assembly comprising a first seal, the first seal being connected to the housing, the first seal comprising a third feed channel, the second feed channel being at least partially positioned within the third feed channel, the third feed channel being positioned within the first feed channel, an outer wall of the third feed channel being bonded to an inner wall of the first feed channel.

4. The feeding apparatus of claim 3, wherein the seal assembly further comprises a second seal that surrounds the second feed channel and seals a gap between an outer wall of the second feed channel and an inner wall of the third feed channel.

5. The feeding equipment of claim 3, further comprising a blanking assembly, wherein the blanking assembly comprises a rotating shaft, a rotating blade and a driving piece, the rotating shaft is surrounded by the rotating shaft, the rotating blade is fixedly connected with the rotating shaft, the driving piece is connected with the rotating shaft, the bottom wall of the storage assembly is penetrated by the rotating shaft, the rotating blade is located at the bottom wall, the driving piece is located outside the storage assembly, and when the driving piece drives the rotating shaft to rotate so as to drive the rotating blade to rotate, the rotating blade pushes feed located at the bottom wall to the second blanking opening.

6. The feeding apparatus of claim 5, wherein the drive is disposed between the first seal and the magazine assembly, the drive being secured to the first seal.

7. The feeding apparatus of claim 5, further comprising an industrial control assembly, the first seal and the bottom of the housing enclosing an installation space, the industrial control assembly being disposed within the installation space.

8. The feeding device of claim 7, further comprising a feeding assembly and a weighing assembly, wherein the feeding assembly is used for conveying feed into a storage space of the storage assembly, the weighing assembly is used for weighing the feed in the storage space, the industrial control assembly is electrically connected with the feeding assembly, the weighing assembly and the blanking assembly, and the industrial control assembly is used for controlling the feeding assembly, the weighing assembly and the blanking assembly to work cooperatively so as to output feed with preset mass into the first blanking channel.

9. The feeding device of claim 1, further comprising a feeding assembly, wherein the feeding assembly comprises a feed delivery pipe and a feed pipe, the feed delivery pipe is connected with the first feeding channel and the feed pipe, and feed output from the first feeding channel passes through the feed delivery pipe and the feed pipe and then enters the trough.

10. A feeding system, comprising:

a stockline for conveying feed to the feeding apparatus; and

the feeding device of any one of claims 1-9, which is disposed on the feed line.

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