CN210655325U - Plug disc line centralized feeding system - Google Patents

Abstract

The utility model discloses a plug disc line centralized feeding system, which comprises a plug disc line centralized feeding system, and comprises a centralized feeding station, a plurality of pre-house storage towers and an electric control system, wherein the centralized feeding station comprises a plurality of feeding towers, the feeding towers are connected in series by arranging plug disc pipelines, a plurality of plug disc pipelines are connected in parallel at the discharge port of each feeding tower, and each plug disc pipeline is connected in series with the pre-house storage towers respectively; the utility model discloses fodder delivery capacity increase, the pipe arrangement is more simple reasonable.

Description

Plug disc line centralized feeding system

Technical Field

The utility model relates to a stockbreeding industry feeder equipment field, especially a plug disc line centralized feeding system and feeding method.

Background

When the animal husbandry industry faces African plague, great attention is paid to the biological safety of the pig farm. The entry of either personnel or vehicles to the site is subject to rigorous disinfection and quarantine, whereas the feed delivery vehicles have to provide feed to the pig farm on a daily basis. How to meet the safety problem is a demand which needs to be solved urgently, and the applicant confirms a specific solution of the problem through solution discussion and experimental verification and designs and develops a plug disc line centralized feeding system.

The original centralized feeding systems all adopt output auger pipelines which have the main defects of short conveying distance, complex arrangement, disordered arrangement of more complex feeding systems and complicated control systems;

in the prior art, when a feed tower conveys feed to different storage towers before a shed, an output hopper line needs to be added for switching. Other controls are also possible, as the on-site pipeline is numerous and the clutter control is very complex if necessary.

In conclusion, the conveying distance is short, the single-line conveying capacity can only reach 3.2 tons/hour, the concentrated material tower cannot be switched to convey the material tower in the pig farm at will, the pipeline arrangement is messy, and the control is complex.

SUMMERY OF THE UTILITY MODEL

In order to solve the existing problems, the utility model discloses a plug disc line centralized feeding system, which comprises a centralized feeding station, a pre-house unit storage tower and an electric control system, wherein the centralized feeding station comprises a plurality of feeding towers;

the material supply towers are connected in series through plug disc pipelines, the discharge port of each material supply tower is connected with a plurality of plug disc pipelines in parallel, and each plug disc pipeline is connected with the front material storage tower in series respectively.

Preferably, the tower bottoms of the feeding tower and the storage tower before the shed are provided with weighing sensors.

Preferably, the plug disc pipeline comprises a plug disc chain positioned in the pipeline and a stockline power box for driving the plug disc chain transmission.

Preferably, an electric switch is arranged on the top of the storage tower before the shed; and an output hopper is arranged at the bottom of the feeding tower.

Preferably, the electric switch comprises a first box body and a feeding pipe, the feeding pipe penetrates through two ends of the first box body, a blanking pipe is arranged at the lower end of the first box body, a blanking through hole is formed in the lower surface of the feeding pipe located in the first box body, a speed reduction motor is arranged on the outer wall of the first box body, an output shaft of the speed reduction motor penetrates through the wall portion of the first box body and extends to the first box body to be connected with a driving gear, the driving gear is meshed with a driven gear, the driven gear is welded with an opening and closing pipe along the axial direction of the feeding pipe, the opening and closing pipe can cover the blanking through hole, two induction sheets are symmetrically arranged on the side wall of one end, away from the speed reduction motor, of the opening and closing pipe, and an induction sensor is arranged;

the plug disc chain penetrates through the feeding pipe.

Preferably, the output hopper comprises a second box body, a hopper is arranged in the second box body, a discharge port is arranged below the hopper, a feed conveying groove is arranged below the discharge port, a motor is arranged on the outer side wall of the second box body, an output shaft of the motor penetrates through the wall part of the second box body and extends to the feed conveying groove, a spiral conveying rod is connected into the feed conveying groove, and a discharge pipe communicated with the feed conveying groove is further arranged on the second box body; the plug disc chain penetrates through the discharge pipe;

a vibrating plate is arranged on one side wall in the hopper, a vibrating wheel is arranged on the lower surface of the vibrating plate, and the lower surface of the vibrating wheel can be in contact with the helical blade of the helical conveying rod.

Preferably, a corner device is installed at the corner of the plug disc pipeline.

Preferably, a controller is installed in the electric control system, and the controller is in electric signal connection with the stockline power box, the electric switch, the output hopper and the weighing sensor.

Preferably, the motor and the gear motor are covered with a rain cover.

The utility model also discloses a feeding method of any kind of above-mentioned plug disc line centralized feeding system, including following step:

the method comprises the following steps:

s0: presetting a conveying preset value G of a weighing sensor below the feeding tower, wherein the real-time weighing value is G ', the initial weight G1 of the feeding tower is G', and when G1 is more than G, entering the next step;

presetting a material receiving preset value G0 of a weighing sensor of a storage tower before a house, wherein a real-time weighing value is G0 ', and an initial weight value G2 is G0'; when G2+ G0 is less than the capacity of the storage tower before the house, the next step is carried out;

s1: recording the initial weights G1 and G2 of the weighing sensors below each feeding tower, and then opening a stockline power box to drive a plug disc chain to operate; simultaneously starting one of the feed towers or a plurality of output hoppers below the feed towers to convey the feed into the plug disc pipeline;

s2: when the storage tower before the shed needs to supply materials, an electric switch above the storage tower before the shed needing to store the materials is turned on, when the feed flows through the electric switch above the storage tower before the shed, the feed enters the storage tower before the shed, a weighing sensor below the storage tower before the shed records the weight G0' of the feed entering the storage tower in real time, and when the weight of the feed input by the storage tower before the shed reaches a receiving preset value G0, the electric switch on the storage tower before the shed is turned off;

s3: when other pre-shed storage towers need to feed materials, repeating the step S2;

s4: when the feeding tower has no other conveying tasks and the conveying amount reaches a conveying preset value, the output hopper below the feeding tower is closed, and when the weighing sensor below the storage tower before the storage tower displays that the weight G0' is not changed any more, the stockline power box stops working, the plug disc chain stops moving, and the electric switch is closed.

The utility model has the advantages that:

(1) the conveying capacity of the feeding system of the utility model is greatly improved from 3.2 tons/hour to 5.2 tons/hour in the prior proposal;

(2) the utility model adopts the plug disc pipeline to feed materials, the pipeline arrangement is simpler and more reasonable, compared with the cross arrangement of a plurality of pipelines in the prior art, the pipeline arrangement is more disordered, the transmission is fixed, and the pipeline can not be flexibly converted to other material towers, the utility model has simple transmission pipeline and simple and clear control;

(3) the utility model can realize the transportation of mixed feed besides the transportation of single feed, and the feed formula can be matched in real time through the control system;

(4) the utility model discloses the storage tower increases weighing sensor before feed tower and house, can know the fodder condition in the storage tower before the house in real time, can realize through system control that the fodder volume is less than the automatic feed supplement behind the setting value in the storage tower before the house, concentrates the storage tower in the fodder and is less than the automatic switch-over to the storage tower feed before other houses behind the setting value.

(5) The utility model adopts the electric switch, the structure is novel, the driving gear is driven to rotate by the motor, the driving gear drives the driven gear to rotate, thereby driving the switching tube welded on the driven gear to rotate, the switching is realized, the switching scale is positioned by two symmetrical induction sheets welded on the switching tube, when the blanking is needed to the material tower, the opening signal of the speed reducing motor is sent, the controller receives the signal and controls the induction sheets to start to operate, when the induction sheets are driven to the position of the induction sensor by the rotation, the induction sensor senses the induction sheets, the induction sensor sends the instruction to the controller, the controller receives the signal and controls the speed reducing motor to stop, the blanking through hole is communicated with the blanking tube, the blanking action is realized, after the blanking is finished, the speed reducing motor is given a starting state, the speed reducing motor rotates reversely at the moment, the induction sheets are driven to rotate, when the induction, and sending a signal to the controller, controlling the speed reduction motor to stop running by the controller, and covering the blanking through hole by the opening and closing pipe so as to realize automatic opening and closing.

(6) The utility model discloses an output hopper novel structure, the fodder in the feeding tower falls the fodder transmission tank through the vibrations board from the hopper on, owing to rotate at the blade of auger delivery pole, can collide with the vibrations wheel to drive the vibrations board shake, shake remaining fodder and fall to the fodder transmission tank in, then carry the discharging pipe through the auger delivery pole in the fodder, the plug dish chain will drive the fodder transmission in the discharging pipe to the plug dish pipeline in.

Drawings

FIG. 1 is a first schematic structural diagram of the present invention;

FIG. 2 is a second schematic structural view of the present invention;

fig. 3 is a schematic perspective view of the output hopper of the present invention;

fig. 4 is a top view of the output hopper of the present invention;

fig. 5 is a side view of the output hopper of the present invention;

FIG. 6 is a view A-A of FIG. 4;

fig. 7 is a schematic structural diagram of the electric switch of the present invention;

fig. 8 is a partial schematic view one of the electric switch of the present invention;

fig. 9 is a partial schematic view of the electric switch of the present invention;

fig. 10 is a third schematic view of a portion of the electric switch of the present invention;

fig. 11 is a control principle framework diagram of the present invention;

fig. 12 is a detailed block diagram of the control system of the present invention;

FIG. 13 is a logic flow diagram of the feed method control of the present invention;

in the figure, a No. 100-1 feeding tower, a No. 101-2 feeding tower, a No. 102-3 feeding tower, a No. 103-4 feeding tower, a No. 104-5 feeding tower, a No. 200-nursing house, a No. 300-fattening house, a No. 201-A1 front-cut storage tower, a No. 202-A2 front-cut storage tower, a No. 203-A3 front-cut storage tower, a No. 204-A4 front-cut storage tower, a No. 301-B1 front-cut storage tower, a No. 302-B2 front-cut storage tower, a No. 303-B3 front-cut storage tower, a No. 304-B4 front-cut storage tower, a No. 305-C1 front-cut storage tower, a No. 306-C2 front-cut storage tower, a No. 307-C3 front-cut storage tower, a No. 308-C4 front-cut storage tower, a No. 500-plug tray pipeline, a No. 700-output hopper, a 701-hopper, 706-spiral conveying rod, 707-spiral blade, 708-feed conveying trough, 709-box II, 800-electric switch, 801-box I, 802-reducing motor, 8021-driving gear, 8022-driven gear, 803-feeding pipe, 804-opening and closing pipe, 805-induction sheet and 806-induction sensor.

Detailed Description

It should be noted that, in the present invention, the embodiments and features of the embodiments may be combined with each other without conflict.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention. Furthermore, the terms "first", "second", etc. 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," "second," etc. may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art through specific situations.

The following detailed description of the embodiments of the present invention will be made with reference to the accompanying drawings.

Example 1

As shown in fig. 1 to 13, a plug disc line centralized feeding system comprises a centralized feeding station, a plurality of pre-shed storage towers and an electric control system, wherein the centralized feeding station comprises a plurality of feeding towers, and in specific implementation, the pre-shed unit storage towers are used for feeding to a nursing shed 200 or a fattening shed 300; but is not limited thereto.

The feeding towers are connected in series by arranging plug disc pipelines 500, the discharge port of each feeding tower is connected with a plurality of plug disc pipelines 500 in parallel, and each plug disc pipeline 500 is respectively connected with the storage tower before the house in series, as shown in fig. 1 and 2.

And weighing sensors are arranged at the bottoms of the material supply tower and the material storage tower before the house.

The plug disc pipeline 500 comprises a plug disc chain positioned in a pipeline and a stockline power box used for driving the plug disc chain to drive, the utility model discloses a stockline power box, which adopts the patent product applied by the applicant in 2018.07.25, and the application publication number is CN109205234A, and the patent name is 'a stockline power box', which can be used for reference, but is not limited thereto.

An electric switch 800 is arranged on the top of the storage tower before the house, and a fault detection switch is arranged on the electric switch 800;

the bottom of the feeding tower is provided with an output hopper 700.

Example 2

The present embodiment is further optimized based on embodiment 1, and specifically, the electric switch 800 includes a first box 801 and a feeding pipe 803, the feeding pipe 803 penetrates through two ends of the first box 801, a discharging pipe is disposed at a lower end of the first box 801, a discharging through hole 8031 is disposed on a lower surface of the feeding pipe 803 located in the first box 801, a reduction motor 802 is disposed on an outer wall of the first box 801, an output shaft of the reduction motor 802 extends through a wall portion of the first box 801 to be connected to a driving gear 8021 in the first box 801, the driving gear 8021 is engaged with a driven gear 8022, the driven gear 8022 is welded with an opening and closing pipe 807 along an axial direction of the feeding pipe 803, the opening and closing pipe 807 can cover the discharging through hole 8031, two sensing pieces 805 are symmetrically disposed on a side wall of the opening and closing pipe 807 at an end away from the reduction motor 802, an induction sensor 806 is arranged on the inner wall of the first box body 801 and opposite to one induction sheet 805, and in the specific implementation, the induction sensor adopts a fault detection switch with the model number of ND 8-S3-M12/Switzerland;

the plug chain passes through the feed pipe 803, and the feed pipe 803 is connected with the pipe of the plug pipeline.

When the blanking device is used, the driving gear 8021 is driven to rotate by the speed reducing motor 802, the driving gear 8021 drives the driven gear 8022 to rotate, so as to drive the opening and closing pipe 807 welded on the driven gear 8022 to rotate, so as to realize opening and closing, the opening and closing dimension is positioned by two symmetrical sensing sheets 805 welded on the opening and closing pipe 807, when blanking to a material tower is needed, an opening signal of the speed reducing motor 802 is sent, a controller in the electric control system receives the signal and controls the sensing sheets 805 to start running, when the sensing sheets 805 are driven to the position of the sensing sensor 806 by rotation, the sensing sensor 806 senses the sensing sheets 805, specifically, the sensing sheets are metal sheets, the sensing sensor 806 sends an instruction to the controller in the electric control system, the controller in the electric control system receives the signal and controls the speed reducing motor 802 to stop blanking, the blanking through hole 8031 is communicated with the blanking pipe, so as to realize blanking, when the speed reducing motor 802 is in a starting state, the speed reducing motor 802 rotates reversely to drive the induction sheet 805 to rotate, when the induction sensor 806 senses the induction sheet 805, a signal is sent to a controller in the electric control system, the controller in the electric control system controls the speed reducing motor to stop running, and the opening and closing pipe 807 covers the blanking through hole 8031, so that automatic opening and closing are realized.

Example 3

The embodiment is further optimized on the basis of embodiment 2, specifically, the output hopper 700 includes a second box 709, a hopper 701 is arranged in the second box 709, a discharge port is arranged below the hopper 701, a feed conveying groove 708 is arranged below the discharge port, a motor 703 is installed on the outer side wall of the second box 709, an output shaft of the motor 703 penetrates through the wall of the second box 709 and extends into the feed conveying groove 708, a spiral conveying rod 706 is connected, and a discharge pipe 702 communicated with the feed conveying groove 708 is further arranged on the second box 709; the plug chain passes through the discharge pipe 702, and the discharge pipe 702 is connected with the pipe of the plug pipeline;

a vibration plate 704 is arranged on one side wall in the hopper 701, a vibration wheel 705 is arranged on the lower surface of the vibration plate 704, and the lower surface of the vibration wheel 705 can be in contact with a spiral blade 707 of the spiral conveying rod 706.

In specific implementation, a level indicator is further arranged on the second box body 709.

When the feed conveying device is used, feed falls onto the feed conveying groove 708 from the hopper 701 through the vibration plate 704, and can collide with the vibration wheel 705 due to the rotation of the helical blade 707 of the spiral conveying rod 706, so that the vibration plate 704 is driven to vibrate, residual feed is shaken off into the feed conveying groove 708, then the feed is conveyed into the discharge pipe 702 through the spiral conveying rod 706, and the feed is conveyed into a feed storage tower before a house from a plug disc chain of the discharge pipe.

Example 4

The embodiment is further optimized on the basis of embodiment 3, and particularly, a corner device is installed at a corner of the plug disc pipeline 500, so that feed can be conveyed conveniently.

Install the controller among the electrical system in the electrical system, controller among the electrical system with stockline headstock, electric switch, weighing sensor signal of telecommunication connect, controller among the electrical system adopts siemens PLC, the positive tai electrical apparatus original paper during concrete implementation.

Example 5

As shown in fig. 12, a feeding method of a plug disc line centralized feeding system comprises the following steps:

s0: presetting a conveying preset value G of a weighing sensor below the feeding tower, wherein the real-time weighing value is G ', the initial weight G1 of the feeding tower is G', and when G1 is more than G, entering the next step;

presetting a material receiving preset value G0 of a weighing sensor of a storage tower before a house, wherein a real-time weighing value is G0 ', and an initial weight value G2 is G0'; when G2+ G0 is less than the capacity of the storage tower before the house, the next step is carried out;

s1: recording the initial weights G1 and G2 of the weighing sensors below each feeding tower, and then opening a stockline power box to drive a plug disc chain to operate; simultaneously starting one of the feed towers or a plurality of lower output hoppers 700 to deliver feed into the plug pan line 500;

s2: when a pre-shed storage tower in the pre-shed unit storage station needs to supply materials, an electric switch 800 above the pre-shed storage tower needing to store the materials is opened, when the feed flows through the electric switch 800 above the pre-shed storage tower, the feed enters the pre-shed storage tower, a weighing sensor below the pre-shed storage tower records the weight G0' of the feed entering the storage tower in real time, and when the weight of the feed input by the pre-shed storage tower reaches a receiving preset value G0, the electric switch 800 on the pre-shed storage tower is closed;

s3: when other pre-shed storage towers need to feed materials, repeating the step S2;

s4: when the feeding tower has no other conveying tasks and the conveying amount reaches the conveying preset value, the output hopper 700 below the feeding tower is closed, and when the weighing sensor below the storage tower before the storage tower stores the materials shows that the weight G0' is not changed any more, the stockline power box stops working, the plug disc chain stops moving, and the electric switch 800 is closed.

Example 6

This example is a single feed delivery process.

During specific implementation, a No. 1 feeding tower 100, a No. 2 feeding tower 101, a No. 3 feeding tower 102, a No. 4 feeding tower 103 and a No. 5 feeding tower 104 are arranged in the centralized feeding station side by side, piglet feed is filled in the No. 1 feeding tower 100, and the same or different adult pig feed is filled in the No. 2 feeding tower 101, the No. 3 feeding tower 102, the No. 4 feeding tower 103 and the No. 5 feeding tower 104;

a front storage tower 201 of A1 house, a front storage tower 202 of A2 house, a front storage tower 203 of A3 house and a front storage tower 204 of A4 house are arranged in front of the nursing house 200;

a B1 front storage tower 301, a B2 front storage tower 302, a B3 front storage tower 303, a B4 front storage tower 304, a C1 front storage tower 305, a C2 front storage tower 306, a C3 front storage tower 307 and a C4 front storage tower 308 are arranged in front of a fattening house 300. More storage towers before the house can be added if necessary.

(taking 5 tons of feed conveyed by the No. 2 feeding tower 101 to the B1 pre-house storage tower 301 and the C1 pre-house storage tower 305 in the fattening house as an example):

a feeding method of a plug disc line centralized feeding system comprises the following steps:

s0: presetting a conveying preset value G of a weighing sensor below the No. 2 feeding tower 101 to be 10 tons, a real-time weighing value G' and an initial weight G1 of the feeding tower; judging that the condition G1 is more than or equal to 10 tons, and carrying out the next step;

presetting the receiving preset values G0 of the weighing sensors of the storage tower 301 before B1 and the storage tower 305 before C1 are respectively 5 tons; the real-time weighing value is G0', the initial weight value is G2, and the judgment condition is as follows: g2+ G0 is less than the capacity of the storage tower before the house, and the next step is carried out;

s1: starting a stockline power box to drive a plug disc chain to operate, and starting an output hopper below the No. 2 feeding tower 101 to convey feed into a plug disc pipeline 500; recording the initial weight G1 of the load cell below No. 2 feeder tower 101;

s2: the electric switches on the B1 front storage tower 301 and the C1 front storage tower 305 of the fattening house are started, when feed flows through the feeding pipe 803 in the electric switch 800 above the B1 front storage tower 301, the speed reduction motor is started, the driven gear drives the opening and closing pipe to rotate, the feed falls into the B1 front storage tower 301 from the feeding through hole of the feeding pipe, the weighing sensor below the B1 front storage tower 301 records the weight G0' of the feed entering the feed tower in real time, when the weight of the feed input by the B1 front storage tower reaches a preset value and receives the material G0(5 tons), the controller in the electric control system receives signals and controls the electric switch on the B1 front storage tower 301, and the feed is continuously conveyed to the C1 front storage tower 305 through a pipeline;

s3: when feed enters the C4 pre-house storage tower 305 when flowing through an electric switch above the C1 pre-house storage tower 305, when a weighing sensor below the No. 2 feeding tower 101 shows that 10 tons are conveyed, a discharge hopper below the No. 2 feeding tower 101 is closed, the feed conveying into a pipeline is stopped, the residual feed in the pipeline is continuously conveyed to the C4 pre-house storage tower 305, when the weighing sensor below the C4 pre-house storage tower 305 shows that the weight is not changed any more, a stockline power box stops working, and a plug disc chain 500 in the pipeline stops moving.

Example 7

In this embodiment, a mixed feed conveying process is illustrated, in which 5 tons of feed are conveyed from the feeding towers No. 2 and No. 3, respectively, 101, 102 to the storage tower before B1 shed 301 and the storage tower before C1 shed 305.

During specific implementation, a No. 1 feeding tower 100, a No. 2 feeding tower 101, a No. 3 feeding tower 102, a No. 4 feeding tower 103 and a No. 5 feeding tower 104 are arranged in the centralized feeding station side by side, piglet feed is filled in the No. 1 feeding tower 100, and the same or different adult pig feed is filled in the No. 2 feeding tower 101, the No. 3 feeding tower 102, the No. 4 feeding tower 103 and the No. 5 feeding tower 104;

a front storage tower 201 of A1 house, a front storage tower 202 of A2 house, a front storage tower 203 of A3 house and a front storage tower 204 of A4 house are arranged in front of the nursing house 200;

a B1 front storage tower 301, a B2 front storage tower 302, a B3 front storage tower 303, a B4 front storage tower 304, a C1 front storage tower 305, a C2 front storage tower 306, a C3 front storage tower 307 and a C4 front storage tower 308 are arranged in front of a fattening house 300. More storage towers before the house can be added if necessary.

S0: the sum of the preset conveying values T of the weighing sensors below the No. 2 feeding tower 101 and the No. 3 feeding tower 102 is preset to be 10 tons, and the preset conveying values T can be adjusted according to a mixed formula; judging that the condition G1 is more than or equal to 10 tons, and carrying out the next step;

presetting the receiving preset values T0 of the weighing sensors of the storage tower 301 before B1 and the storage tower 305 before C4 are both 5 tons; the real-time weighing value is G0', the initial weight value is G2, and the judgment condition is as follows: g2+ G0 is less than the capacity of the storage tower before the house, and the next step is carried out;

s1: starting a stockline power box to drive a plug disc chain to operate, starting 60% of rotation speed of an output hopper below the No. 2 feeding tower 101 and 40% of rotation speed of an output hopper below the No. 3 feeding tower 102 to start to convey feed into a plug disc pipeline 500; a controller in the electric control system records the weight of the weighing sensors below the No. 2 feeding tower 101 and the No. 3 feeding tower 102;

s2: opening an electric switch 800 above a B1 pre-shed storage tower 301 and a C1 pre-shed storage tower 305, enabling the feed to enter the B1 pre-shed storage tower 301 when the feed flows through the electric switch above the B1 pre-shed storage tower 301, recording the weight of the feed entering the feed tower by a weighing sensor below the B1 pre-shed storage tower 301 in real time, closing the electric switch 800 above the B1 pre-shed storage tower when the weight of the feed input into the B1 pre-shed storage tower 301 reaches 5 tons, and continuously conveying the feed to the C1 pre-shed storage tower through a rear pipeline;

s3: when feed flows through the electric switch 800 above the pre-house C1 storage tower 305, the feed enters the pre-house C1 storage tower 305, when the weighing sensor below the No. 2 feeding tower 101 shows that 5 tons of feed are conveyed, the output hopper below the No. 2 feeding tower is closed, when the weighing sensor below the No. 3 feeding tower 102 shows that 5 tons of feed are conveyed, the output hopper and the output hopper 700 below the No. 3 feeding tower 102 are closed, feed conveying into the plug disc pipeline is stopped, residual feed in the pipeline is continuously conveyed to the pre-house C1 storage tower 305, when the weighing sensor below the pre-house C1 storage tower 305 shows that the weight does not change any more, the line power box stops working, and the plug disc chain 500 in the pipeline stops moving.

The applicant has proved through experiments that the utility model discloses a feeding system delivery capacity has had great promotion, for example, under the condition that the single line was carried (a feeding tower carries out the pay-off toward a storage tower), the delivery capacity of auger pipeline that adopts prior art was 3.2 tons/hour, and adopted the utility model discloses plug dish pipeline single line delivery capacity can promote 5.2 tons/hour.

The above embodiments only describe the best mode of use of the existing equipment, and the similar common means and control methods are used to replace the elements in the embodiments, which fall into the protection scope.

Claims (9)

1. The utility model provides a centralized feeding system of plug disc line, storage tower and electrical system before concentrating feed station, a plurality of house, its characterized in that: the centralized feeding station comprises a plurality of feeding towers, plug disc pipelines (500) are arranged between the feeding towers and connected in series, a plurality of plug disc pipelines (500) are connected in parallel at the discharge port of each feeding tower, and each plug disc pipeline (500) is connected with the storage towers in series before the shed respectively.

2. The plug deck line centralized feeding system of claim 1, wherein: and weighing sensors are arranged at the bottoms of the material supply tower and the material storage tower before the house.

3. The plug deck line centralized feeding system of claim 1, wherein: the plug disc pipeline (500) comprises a plug disc chain positioned in the pipeline and a stockline power box used for driving the plug disc chain to drive.

4. A plug deck line centralized feeding system as set forth in claim 3, wherein: an electric switch (800) is arranged at the top of the storage tower before the shed; the bottom of the feeding tower is provided with an output hopper (700).

5. The plug deck line centralized feeding system of claim 4, wherein: the electric switch (800) comprises a first box body (801) and a feeding pipe (803), the feeding pipe (803) penetrates through two ends of the first box body (801), a blanking pipe is arranged at the lower end of the first box body (801), a blanking through hole (8031) is arranged on the lower surface of the feeding pipe (803) positioned in the first box body (801), a speed reducing motor (802) is arranged on the outer wall of the first box body (801), an output shaft of the speed reducing motor (802) penetrates through the wall of the first box body (801) and extends to a driving gear (8021) connected in the first box body (801), the driving gear (8021) is meshed with a driven gear (8022), an opening and closing pipe (807) is welded along the axial direction of the feeding pipe (803), the opening and closing pipe (807) can cover the blanking through hole (8031), two induction sheets (805) are symmetrically arranged on the side wall of one end, far away from the speed reducing motor (802), of the opening and closing pipe (807), an induction sensor (806) is arranged at the inner wall of the first box body (801) and opposite to one induction sheet (805);

the plug disc chain passes through the feed pipe (803).

6. The plug deck line centralized feeding system of claim 4, wherein: the output hopper (700) comprises a second box body (709), a hopper (701) is arranged in the second box body (709), a discharge hole is formed below the hopper (701), a feed transmission groove (708) is formed below the discharge hole, a motor (703) is installed on the outer side wall of the second box body (709), an output shaft of the motor (703) penetrates through the wall part of the second box body (709) and extends into the feed transmission groove (708), a spiral conveying rod (706) is connected into the feed transmission groove (708), and a discharge pipe (702) communicated with the feed transmission groove (708) is further arranged on the second box body (709); the plug chain passes through the discharge pipe (702);

a vibrating plate (704) is arranged on one side wall in the hopper (701), a vibrating wheel (705) is arranged on the lower surface of the vibrating plate (704), and the lower surface of the vibrating wheel (705) can be in contact with a spiral blade (707) of the spiral conveying rod (706).

7. The plug deck line centralized feeding system of claim 1, wherein: and a corner device is arranged at the corner of the plug disc pipeline.

8. A plug deck line centralized feeding system as set forth in claim 3, wherein: and a controller is installed in the electric control system, and the controller is in electric signal connection with the stockline power box, the electric switch, the output hopper and the weighing sensor.

9. The plug deck line centralized feeding system of claim 5, wherein: the outer cover of the speed reducing motor is provided with a rain cover.

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