CN209898253U - Pipeline closed type large-stroke feed transportation premixing comprehensive management system - Google Patents

Abstract

The utility model discloses a pipeline closed large-stroke fodder transportation mixes integrated management system in advance, including setting up the first storage silo that a plurality of in the feedlot is used for storing different feedstuff, set up the second storage silo that a plurality of in the feedlot is used for providing finished feed to the breed animal, with the discharge gate intercommunication of each first storage silo and with the feed inlet intercommunication of each second storage silo and be used for mixing and transporting the feedstuff of various differences to the first transport mechanism of the second storage silo department that corresponds, and with the discharge gate valve of each first storage silo and the feed inlet valve signal connection of each second storage silo, a controller for controlling opening and close state between them. The utility model discloses a controller can conveniently, realize fodder transportation and raw materials mixture between feedlot to the plant high-efficiently to the mixed transportation of the open-close control of each discharge gate and feed inlet valve and first transport mechanism, eliminates external factor and to the disease propagation risk of breed animal, reduces the cost of raising.

Description

Pipeline closed type large-stroke feed transportation premixing comprehensive management system

Technical Field

The utility model relates to a material transport technical field, in particular to pipeline closed large stroke fodder transportation mixes integrated management system in advance.

Background

With the development of livestock husbandry in China, the scale and the integration level of livestock breeding centers are larger and larger.

In order to meet the requirement of large-scale livestock breeding, a feed field is generally arranged outside the farm and is specially used for providing feed for breeding animals (such as pigs, cattle, sheep and the like) in the farm. Because different farmed animals have different requirements and preferences for feeds, and a feedlot generally can only provide a plurality of different types of feed raw materials, the feeds are often required to be mixed in the feedlot to form a mixed feed with a certain raw material ratio, i.e. a finished feed. Meanwhile, in order to ensure continuity and stability of feed supply in the farm, a feed transport line needs to be provided between the farm and the farm.

At present, a relatively mature feed conveying mode is pneumatic transmission, namely a conveying line is formed by components such as an air pump, an air compressor and an airtight pipeline, the feed raw materials in the pipeline are pushed by the power of compressed air to be conveyed, but the pneumatic transmission is high in cost, short in conveying distance, large in power consumption and relatively low in conveying efficiency (generally less than 5t/h), and the feed supply requirement of a farm cannot be met. More importantly, the traditional finished feed supply almost completely depends on the bulk feed car to feed the unit charging bucket, so still need to get into the plant through the feed car, mix the stirring evenly by artifical or professional mixer in the plant again, this just brings very big disease propagation risk for the breed animal in the plant, and the artifical low efficiency of mixing the stirring fodder, intensity of labour is big, and professional mixer is high in cost, still occupies the plant space, and the raising cost of plant is higher.

Therefore, how to conveniently and efficiently realize the feed transportation and the raw material mixing between the feeding farms and the cultivation farms, and simultaneously eliminate the risk of disease transmission of the external factors to the cultivated animals and reduce the feeding cost is a technical problem faced by the technical personnel in the field.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a pipeline closed large stroke fodder transportation mixes integrated management system in advance can realize fodder transportation and raw materials mixture between fodder field to the plant conveniently, high-efficiently, eliminates external factor and to breeding animal's disease propagation risk, reduces the cost of raising.

In order to solve the technical problem, the utility model provides a pipeline closed large stroke fodder transportation mixes integrated management system in advance, including set up a plurality of in the feedlot be used for storing different feedstuff's first storage silo, set up a plurality of in the feedlot be used for providing the second storage silo of finished product fodder to the breed animal, with each the discharge gate intercommunication of first storage silo and with each the feed inlet intercommunication of second storage silo and be used for mixing and transporting various different feedstuff to corresponding the first transport mechanism of second storage silo department to and with each the discharge gate valve of first storage silo and each the feed inlet valve signal connection of second storage silo, be used for controlling the controller of the state of opening and close between them.

Preferably, the feed storage device further comprises a first material monitor which is arranged in each first storage bin and used for monitoring the current feed raw material storage amount of the first storage bin, and the first material monitor is in signal connection with the controller so as to judge the discharge amount of each first storage bin according to the change of the detection value of the first material monitor and control the opening and closing state of the corresponding discharge port valve.

Preferably, the feed storage device further comprises a second material monitor which is arranged in each second storage bin and used for monitoring the current finished feed storage amount of the second storage bin, and the second material monitor is in signal connection with the controller so as to judge the feeding amount of each second storage bin according to the change of the detection value of the second material monitor and control the opening and closing state of the corresponding feed inlet valve according to the feeding amount.

Preferably, the feed storage device further comprises a formula management module which is in signal connection with each second material monitor and is used for storing the feed ingredient formula of the finished feed in each second storage bin, and the formula management module is in signal connection with the controller, so that the controller controls the discharge amount of each first storage bin according to the feed ingredient formula of the finished feed with insufficient current storage amount.

Preferably, the feed ingredient management module further comprises a formula modifier in signal connection with the formula management module and used for modifying the stored data of each feed ingredient component formula stored in the storage unit of the formula modifier according to input parameters.

Preferably, the first transportation mechanism includes each of intercommunication discharge gate valve reaches the first transportation pipeline of feed inlet valve, follows the extending direction of first transportation pipeline distributes in its inner chamber the plug dish chain, and set up in on the first transportation pipeline, with controller signal connection, be used for controlling the plug dish chain carries out axial motion and circumference rotation's first transportation motor.

Preferably, the feed storage device further comprises a second transportation mechanism which is communicated between each discharge port valve and the first transportation pipeline and is used for uniformly transporting the feed raw materials in each first storage bin to the transportation pipeline according to a preset discharge amount.

Preferably, the second transportation mechanism includes a second transportation pipeline communicated between each discharge port valve and the first transportation pipeline, propeller columns axially distributed in the second transportation pipeline, and a second transportation motor arranged on the second transportation pipeline and used for controlling the motion state of the propeller columns; the second transportation motor is in signal connection with the controller.

Preferably, two groups of the first transportation mechanisms are simultaneously distributed on two sides of each first storage bin and respectively correspond to the two groups of the second storage bins; two ends of the second conveying pipeline are respectively communicated with the first conveying pipelines in the two adjacent groups of the first conveying mechanisms, and the second conveying motor drives the propeller columns to rotate forward and backward under the control of the controller.

Preferably, the first transportation pipeline is communicated with the second transportation pipeline through an electric control three-way valve, and a control end of the electric control three-way valve is in signal connection with the controller.

The utility model provides a pipeline closed large-stroke fodder transportation mixes integrated management system in advance mainly includes the first storage silo of a plurality of, a plurality of second storage silo, first transport mechanism and controller. Wherein, each first storage silo is used for storing different kinds of feed ingredient respectively, and each second storage silo is used for providing the finished feed of different grade type respectively to breeding the animal, and this finished feed is formed by feed ingredient mixes, and different feed ingredient mix proportion just can obtain the finished feed of different grade type. Be provided with discharge gate and discharge gate valve on each first storage silo, simultaneously, be provided with feed inlet and feed inlet valve on each second storage silo, and first transport mechanism communicates with the discharge gate of each first storage silo and the feed inlet of each second storage silo simultaneously, and mainly used acquires the back from each discharge gate with various feed ingredient and mixes in the pipeline, and transport to the feed inlet of the second storage silo that corresponds, transport promptly at every turn and can both transport the same or different grade type's finished feed. The controller is in signal connection with the discharge port valve of each first storage bin and the feed inlet valve of each second storage bin, and can control the opening and closing states of each discharge port valve and each feed inlet valve according to received control instructions. The controller can control the valves of the discharge ports to be opened at the moment, and various feed raw materials are conveyed into the first conveying mechanism to be mixed and then conveyed into the corresponding second storage bin. Therefore, the utility model provides a pipeline closed large stroke fodder transportation mixes integrated management system in advance, through the on-off control of controller to each discharge gate valve and feed inlet valve, the mixing and the transportation effect of the first transport mechanism of rethread, can be convenient, realize fodder transportation and raw materials mixture between feedlot to the plant high-efficiently, compare in prior art, need not to get into the plant through the feed carriage and transport, also need not to carry out the feed ingredient through artifical or professional mixer and mix, can effectively eliminate external factor and propagate the risk to the disease of breed animal, reduce the cost of raising.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a main top-down comparison view of an overall structure of an embodiment of the present invention.

Fig. 2 is a schematic structural diagram of the first storage bin and the second transportation mechanism shown in fig. 1.

Fig. 3 is a schematic diagram of the control logic of the controller.

Wherein, in fig. 1-3:

the system comprises a first storage bin-1, a discharge port valve-101, a second storage bin-2, a feed port valve-201, a first transportation mechanism-3, a first transportation pipeline-301, a controller-4, a first material monitor-5, a second material monitor-6, a formula management module-7, a formula modifier-701, a second transportation mechanism-8, a second transportation pipeline-801, a second transportation motor-802 and an electric control three-way valve-9.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1, fig. 1 is a front view of an overall structure of an embodiment of the present invention.

The utility model provides an among the concrete implementation mode, pipeline closed large-stroke fodder transportation mixes integrated management system in advance mainly includes the first storage silo 1 of a plurality of, a plurality of second storage silo 2, first transport mechanism 3 and controller 4.

Wherein, each first storage silo 1 is used for storing different kinds of feed ingredient respectively, and each second storage silo 2 is used for providing the finished feed of different grade type respectively to breeding the animal, and this finished feed is formed by feed ingredient mixes, and different feed ingredient mix proportion just can obtain the finished feed of different grade type.

Be provided with discharge gate and discharge gate valve 101 on each first storage silo 1, simultaneously, be provided with feed inlet and feed inlet valve 201 on each second storage silo 2, and first transport mechanism 3 communicates with the discharge gate of each first storage silo 1 and the feed inlet of each second storage silo 2 simultaneously, mainly used obtains the back from each discharge gate with various feed ingredient and mixes in the pipeline, and transport to the feed inlet of the second storage silo 2 that corresponds, transport promptly at every turn and can both transport the finished feed of the same or different grade type.

The controller 4 is in signal connection with the discharge port valve 101 of each first storage bin 1 and the feed port valve 201 of each second storage bin 2, and can control the opening and closing states of each discharge port valve 101 and each feed port valve 201 according to a received control instruction. The control instruction can be sent manually or automatically by other components, when a certain feed inlet valve 201 is opened, that is, it indicates that the second storage bin 2 corresponding to the feed inlet valve 201 needs to be fed, at this time, the controller 4 can control each discharge outlet valve 101 to be opened, and send various feed raw materials into the first transport mechanism 3 to be mixed and then transported into the corresponding second storage bin 2. Of course, the controller 4 also has a monitoring feedback function, and can judge whether the operation conditions of each component are normal.

Consequently, the pipeline closed large stroke fodder transportation that this embodiment provided mixes integrated management system in advance, through controller 4 to the on-off control of each discharge gate valve 101 and feed inlet valve 201, the mixing and the transportation effect of the first transport mechanism 3 of rethread, can be convenient, realize fodder transportation and raw materials mixture between fodder field to the plant high-efficiently, compare in prior art, need not to get into the plant through the fodder car and transport, also need not to carry out the feed ingredient through artifical or professional mixer and mix, can effectively eliminate external factor and propagate the risk to the disease of breed animal, reduce the cost of raising

In order to accurately control the discharge amount and the feed amount of the feed, the present embodiment provides a first material monitor 5 in each first storage silo 1, and a second material monitor 6 in each second storage silo 2. Preferably, the first material monitor 5 and the second material monitor 6 may both be capacitive level sensors.

The first material monitor 5 is mainly used for monitoring the storage amount of the current feed raw materials in the corresponding first storage bin 1, and the first material monitor 5 adopts a real-time monitoring means, so that the change of the material amount in the first storage bin 1 can be clearly and accurately known. Simultaneously, this first material monitor 5 and 4 signal connection of controller, send its real-time detection value for controller 4 to make controller 4 control the material volume in the first material monitor 5, thereby carry out ejection of compact in-process at each first storage silo 1, judge the load of each first storage silo 1, and then conveniently according to the on-off state of this data control discharge gate valve 101. For example, if the discharge amount of the first storage silo 1 is insufficient, the controller 4 keeps the corresponding discharge port valve 101 in an open state, and conversely, when the discharge amount of the first storage silo 1 reaches the target value, the controller 4 closes the corresponding discharge port valve 101. And when the first material monitor 5 detects that the current amount of material in the first storage silo 1 is insufficient, a signal is simultaneously sent to the feedlot to replenish the corresponding feed material.

Similarly, the second material monitoring side device is mainly used for monitoring the current storage amount of finished feed in the corresponding second storage bin 2, and the second material monitor 6 adopts a real-time monitoring means, so that the change of the material amount in the second storage bin 2 can be clearly and accurately obtained. Simultaneously, this second material monitor 6 and controller 4 signal connection send its real-time detection value for controller 4 to make controller 4 control the material volume in the second material monitor 6, thereby carry out the feeding in-process at each second storage silo 2, judge the feed volume of each second storage silo 2, and then conveniently according to the on-off state of this data control feed inlet valve 201. For example, if the feeding amount of the second storage bin 2 is insufficient, the controller 4 keeps the corresponding feeding port valve 201 in an open state, and conversely, when the feeding amount of the second storage bin 2 reaches the target value, the controller 4 closes the corresponding feeding port valve 201.

In addition, considering that the requirements and preferences of different types of animals or animals in different states among the same species for finished feed are different, in order to realize the fine feeding of the cultured animals, the formula management module 7 and the formula modifier 701 are additionally arranged in the embodiment.

Specifically, the types of the finished feed in each second storage bin 2 are generally different, so that the finished feed in each second storage bin 2 can be used for supplying different types of animals or animals with the same type but different states, for example, breeding pigs, the age and weight ranges of different unit pig groups correspond to different types of finished feed, and the nutritional formulas of the different types of finished feed are different, that is, the components of the basic feed raw materials for forming the finished feed are different. In order to accurately configure the finished feed in each second storage bin 2, the formula management module 7 is in signal connection with each second material monitor 6 and also in signal connection with the controller 4. When the second material monitor 6 monitors that the amount of finished feed in a certain second storage bin 2 is insufficient, the trigger signal is sent to the control module through the formula management module 7, then the control module calls a finished feed formula corresponding to the second storage bin 2 which needs to be fed currently and is stored in the formula management module 7, and the proportion of various feed raw materials corresponding to the finished feed can be obtained according to the formula. Afterwards, the control module can control the discharge gate valves 101 on each first storage silo 1 to open according to the ratio, so that the feed raw materials therein flow out of the first transportation mechanism 3. In the meantime, the first material monitor 5 constantly monitors the amount change of the feedstuff in each first storage bin 1, so that the controller 4 accurately controls the amount of the feedstuff discharged according to the detected value, thereby achieving the effect of accurate proportioning.

It should be noted here that, due to the different feeding rates of different types of animals or animals of the same type but in different states, the consumption rates of different types of finished feed in the respective second storage bins 2 are different, that is, the respective second storage bins 2 are normally insufficient in the sequential order, and the situation that the storage amounts of a plurality of second storage bins 2 are insufficient at the same time does not generally occur.

Further, considering that the farm animals corresponding to each second storage bin 2 may be replaced or changed along with the change of the breeding period, the finished feed stored in each second storage bin 2 also needs to be changed along with the change of the farm animals. In this regard, the recipe modifier 701 is added in this embodiment. Specifically, the formula modifier 701 is in signal connection with the formula management module 7, and can be regarded as a subordinate unit of the formula management module 7, and is mainly used for modifying the feed ingredient formula data stored in the storage unit of the formula management module 7 according to the input parameters. Generally, the formula modifier 701 can be configured with a touch screen and other human-computer interaction interfaces, so that the quick modification by farm managers is facilitated. With this arrangement, after the formula modifier 701 modifies the stored data of the formula management module 7, the type and ratio of the finished feed corresponding to each second storage bin 2 are updated.

Furthermore, in order to improve the mixing accuracy and uniformity of the various feed materials in the first transporting mechanism 3, the present embodiment improves the first transporting mechanism 3. Specifically, the first transportation mechanism 3 includes a first transportation pipe 301, a pallet chain (not shown in the figure), and a first transportation motor (not shown in the figure). Wherein, first transportation pipeline 301 simultaneously with the discharge gate valve 101 of each first storage silo 1 and the feed inlet valve 201 intercommunication of each second storage silo 2, can realize fodder raw materials's ejection of compact, mix, transportation and feeding respectively along with the transportation process. The plug disc chains are distributed in the inner cavity of the first conveying pipeline 301 along the extending direction of the first conveying pipeline 301, and the first conveying motor is arranged on the first conveying pipeline 301 and is mainly used for controlling the axial movement and the circumferential rotation movement of the plug disc chains in the first conveying pipeline 301 according to the control instruction of the controller 4.

So set up, when the chock plug chain moves in first transport pipe way 301, can drive and get into various feed ingredient wherein and carry out along the pipe transportation, the vibration that produces when utilizing the circumferential direction rotation and the motion of chock plug chain simultaneously still lasts the stirring to it when transporting feed ingredient to various feed ingredient's mixing uniformity has been improved. Of course, in the transportation, for guaranteeing whole mixing uniformity, each first storage silo 1 can open discharge gate valve 101 in proper order according to the transportation order and carry out the ejection of compact, thereby guarantee that the raw feed in next storage silo can fall into in the preceding partial raw feed smoothly when the ejection of compact, because first transport pipe 301 has enough big radial space or memory space, consequently the raw feed that falls into first transport pipe 301 earlier is spread at the bottom, the raw feed that falls into first transport pipe 301 later is spread on the top layer, so carry out the unloading back according to the formulation of formulation management module 7, can utilize the circumferential direction and the motion stirring of chock plug dish chain in the transportation.

Here, preferably, in order to ensure the transportation tightness of the feedstuff, the first transportation pipeline 301 may be designed as a circulation pipeline which is communicated end to end, and a sealing component such as a sealing ring is added at the opening of the pipe wall.

Further, consider that in the transportation, the load of each first storage silo 1 is general different, consequently it is very likely to form the condition that some fodder raw materials just fall into first transportation pipeline 301 completely soon and another part fodder raw materials can't completely ejection of compact again for a long time, the density of fodder raw materials distributes unevenly in the pipeline, is difficult to the problem of misce bene to appear easily this moment, for example when the load of first two sections fodder raw materials of tail differed too greatly, may not come to misce bene before transporting to corresponding second storage silo 2. To this, the second transport mechanism 8 has been add between the discharge gate valve 101 of each first storage silo 1 and first transport pipe 301 to this embodiment to carry out corresponding adjustment to the discharge rate of various feed ingredient according to the ratio through second transport mechanism 8, carry out accurate control to the load simultaneously, thereby guarantee various feed ingredient misce bene.

As shown in fig. 2, fig. 2 is a schematic structural diagram of the first storage bin and the second transportation mechanism shown in fig. 1.

Specifically, the second transportation mechanism 8 mainly includes a second transportation pipe 801, a propeller column (not shown in the figure), and a second transportation motor 802. The second transport pipeline 801 is connected between each discharge port valve 101 and the first transport pipeline 301, and serves as an intermediate transport mechanism for the first storage bin 1 and the first transport mechanism 3, and the second transport pipeline 801 is generally a straight circular pipe due to the short distance between the two. The propeller columns are arranged in the second transport pipe 801, distributed along the axial direction of the second transport pipe 801, and a plurality of fan blades extending in a continuous curve are arranged in the circumferential direction of the propeller columns, like a worm structure. The second transportation motor 802 is disposed on the second transportation pipeline 801 and is mainly used for driving the propeller column to rotate, so that when the propeller column rotates, the feed raw materials in the propeller column are driven to be transported along the axial direction through the rotation of fan blades on the propeller column. Of course, the control end of the second transportation motor 802 is in signal connection with the controller 4, so that the formula data of the formula management module 7 and the corresponding feeding amount of the second storage bin 2 can be obtained by the controller 4, the rotation speed of the propeller column can be accurately controlled according to the data, the movement speed of the feed raw materials in the second transportation pipeline 801 and the amount of the feed raw materials falling into the first transportation pipeline 301 can be accurately adjusted, and finally, various feed raw materials can fall into the first transportation pipeline 301 timely and uniformly,

in addition, controller 4 still can be connected with the control center in the field, and this control center in the field is connected and adopts wireless connection with total monitoring platform, generally is provided with a plurality of fields in large-scale aquaculture factory, and every field is provided with the fence of a plurality of units, and a set of first transport mechanism 3 can give the fence of a plurality of units simultaneously and carry the fodder. So, through setting up a field control center in a field, the centralized management is realized to a plurality of controllers 4 of this field control center control of rethread, at last through total monitoring platform management control field control center, for example all unloading records are automatic to be preserved at field control center, and the whole online maintenance data of unit fence information realize the information management of whole breeding process, and all valves and motor trouble all have the warning suggestion, and the personnel of being convenient for inspect and maintain. As shown in fig. 3, fig. 3 is a schematic diagram of the control logic of the controller.

Taking two fields in a farm as an example, in this embodiment, two groups of the first transportation mechanisms 3 may be distributed on two sides of each first storage bin 1, corresponding to two groups of the second storage bins 2, respectively, and the plurality of second storage bins 2 is a group. At this time, the two ends of the second transporting pipeline 801 in the second transporting mechanism 8 can extend to be respectively communicated with the first transporting pipelines 301 in the two adjacent groups of first transporting mechanisms 3, so that various feed raw materials can be simultaneously conveyed to the two groups of first transporting mechanisms 3 through the rotating motion of the propeller columns, namely, two transporting lines are simultaneously carried out. Of course, in order to realize the bidirectional transportation function of the propeller column, the second transportation motor 802 needs to drive the propeller column to rotate forward and backward under the control of the controller 4.

In addition, in order to facilitate the connection between the pipelines, in this embodiment, the electrically controlled three-way valves 9 are disposed at the respective connecting positions of the first transportation pipeline 301 and the second transportation pipeline 801, and the control ends of the electrically controlled three-way valves 9 are in signal connection with the controller 4. In this way, the controller 4 controls the opening and closing of the valves of the electrically controlled three-way valves 9, so that the first transportation pipeline 301 and the second transportation pipeline 801 can be communicated and cut off. Similarly, the feed inlet valve 201 of each second storage bin 2 can be designed as an electrically controlled three-way valve 9. Specifically, the electrically controlled three-way valve 9 can adopt the design principle of a gate valve, namely, the purpose of opening and closing the valve is realized by using an electric push rod gate, and meanwhile, the mechanical travel switch is used for realizing the in-place detection of the valve switch, or an air cylinder is used for replacing the electric push rod, so that the opening and closing speed is higher, the operation is more stable and reliable, and meanwhile, whether the valve is opened or closed in place is detected by using a magnetic switch.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. The pipeline closed type large-stroke feed transportation premixing comprehensive management system is characterized by comprising a plurality of first storage bins (1) arranged in a feed yard and used for storing different feed raw materials, a plurality of second storage bins (2) arranged in the feed yard and used for providing finished feed for cultured animals, first transportation mechanisms (3) communicated with discharge ports of the first storage bins (1), communicated with feed ports of the second storage bins (2) and used for mixing and transporting the different feed raw materials to the corresponding second storage bins (2), and controllers (4) connected with the discharge port valves (101) of the first storage bins (1) and the feed port valves (201) of the second storage bins (2) in a signal mode and used for controlling the opening and closing states of the first storage bins and the second storage bins.

2. The pipeline closed type large-stroke feed transportation and premixing comprehensive management system as claimed in claim 1, further comprising a first material monitor (5) disposed in each first storage bin (1) and used for monitoring the current feed raw material storage amount, wherein the first material monitor (5) is in signal connection with the controller (4) so as to judge the discharge amount of each first storage bin (1) according to the change of the detection value, and accordingly control the opening and closing state of the corresponding discharge port valve (101).

3. The pipe-sealed type large-stroke feed transportation and premixing comprehensive management system as claimed in claim 2, further comprising a second material monitor (6) disposed in each second storage bin (2) and used for monitoring the current finished feed storage amount, wherein the second material monitor (6) is in signal connection with the controller (4) so as to judge the feeding amount of each second storage bin (2) according to the change of the detection value, and accordingly control the opening and closing state of the corresponding feed inlet valve (201).

4. The pipe-closed type large-stroke feed transportation and premixing comprehensive management system as claimed in claim 3, further comprising a formula management module (7) in signal connection with each second material monitor (6) for storing feed ingredient formula of finished feed in each second storage bin (2), and the formula management module (7) is in signal connection with the controller (4) so that the controller (4) controls the discharge amount of each first storage bin (1) according to the feed ingredient formula of finished feed with insufficient current storage amount.

5. The pipe-sealed type long-stroke feed transportation and premixing comprehensive management system as claimed in claim 4, further comprising a formula modifier (701) in signal connection with the formula management module (7) for modifying the stored data of each feed ingredient formula stored in the storage unit thereof according to input parameters.

6. The closed pipeline type large-stroke feed transportation and premixing comprehensive management system as claimed in claim 5, wherein the first transportation mechanism (3) comprises a first transportation pipeline (301) communicating with each of the discharge port valve (101) and the feed port valve (201), a plug disc chain distributed in an inner cavity of the first transportation pipeline (301) along an extending direction of the first transportation pipeline, and a first transportation motor arranged on the first transportation pipeline (301), in signal connection with the controller (4), and used for controlling the plug disc chain to perform axial movement and circumferential rotation.

7. The closed pipeline type large-stroke feed transportation and premixing comprehensive management system as claimed in claim 6, further comprising a second transportation mechanism (8) communicated between each discharge port valve (101) and the first transportation pipeline (301) and used for uniformly transporting the feed raw materials in each first storage bin (1) to the first transportation pipeline (301) according to a preset discharge amount.

8. The pipe closed type large-stroke feed transportation and premixing comprehensive management system as claimed in claim 7, wherein the second transportation mechanism (8) comprises a second transportation pipe (801) communicated between each discharge port valve (101) and the first transportation pipe (301), propeller columns axially distributed in the second transportation pipe (801), and a second transportation motor (802) arranged on the second transportation pipe (801) and used for controlling the motion state of the propeller columns; the second transport motor (802) is in signal connection with the controller (4).

9. The pipeline closed type large-stroke feed transportation and premixing comprehensive management system as claimed in claim 8, wherein two groups of the first transportation mechanisms (3) are simultaneously distributed on two sides of each first storage bin (1) and respectively correspond to two groups of the second storage bins (2); two ends of the second conveying pipeline (801) are respectively communicated with the first conveying pipelines (301) in the two adjacent groups of the first conveying mechanisms (3), and the second conveying motor (802) drives the propeller columns to rotate forward and backward under the control of the controller (4).

10. The closed pipeline type large-stroke feed transportation and premixing comprehensive management system as claimed in claim 9, wherein the first transportation pipeline (301) and the second transportation pipeline (801) are communicated through an electrically controlled three-way valve (9), and a control end of the electrically controlled three-way valve (9) is in signal connection with the controller (4).

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