CN213549610U - Feed additive processingequipment - Google Patents

Abstract

The utility model relates to the technical field of batching, in particular to a feed additive processing device, a first feeder is communicated with a first conveying pipeline, and a first high-pressure fan conveys materials fed by the first feeder into a material bin through the first conveying pipeline; the second feeding bin can be lifted above the carrier bin by the lifting machine, and carriers in the second feeding bin are conveyed into the carrier bin through the second conveying pipeline; the materials in the material bin and the carriers in the carrier bin are conveyed into the high-efficiency mixer through a third conveying pipeline to be uniformly mixed; a first pulse dust collector is arranged above the first feeder, and a second pulse dust collector is arranged above the material bin. The device adopts a positive pressure pneumatic conveying pipeline when the materials enter the stock bin, the pipeline is sealed without leakage, and the tail end of the pipeline is provided with a bag-type dust collector to separate dust from air, so that the discharged outdoor air reaches the air discharge standard and does not pollute the environment.

Description

Feed additive processingequipment

Technical Field

The utility model relates to a batching technical field, concretely relates to feed additive processingequipment.

Background

The feed additive is a small amount or trace substance added in the production, processing and using processes of feed, and the feed additive is small in dosage but remarkable in effect. The feed additive is a raw material inevitably used in modern feed industry, and has obvious effects on strengthening the nutritive value of basic feed, improving the production performance of animals, ensuring the health of the animals, saving the feed cost, improving the quality of animal products and the like.

The existing solid feed additive processing technology generally adopts a production technology similar to that of complete feed, the feed is directly fed into a bin manually or is conveyed to the top of the bin through a lifter and then enters the bin, the additive and a carrier are mixed according to a certain proportion, and the mixture is diluted and packaged to obtain a finished product. Therefore, the labor intensity of workers is high, and due to the non-tightness of conveying equipment, material residues and additive leakage are caused, raw materials are wasted, the production environment is polluted, and the health of the workers is damaged.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem in this application, the utility model provides a feed additive processingequipment.

The utility model provides a following technical scheme: a feed additive processing device comprises a material batching component, a carrier batching component and a high-efficiency mixer; the material batching component comprises a first high-pressure fan, a first conveying pipeline, a first feeder and a material bin; the first feeder is communicated with the first conveying pipeline, and the first high-pressure fan conveys the materials fed by the first feeder into the material bin through the first conveying pipeline; the carrier batching component comprises a second feeding bin, a second conveying pipeline, a lifting machine and a carrier bin; the second feeding bin can be lifted above the carrier bin by the lifting machine, and carriers in the second feeding bin are conveyed into the carrier bin through the second conveying pipeline; the materials in the material bin and the carriers in the carrier bin are conveyed into the high-efficiency mixer through a third conveying pipeline to be uniformly mixed; a first pulse dust collector is arranged above the first feeder, and a second pulse dust collector is arranged above the material bin.

Preferably, the first conveying pipeline is communicated with at least one material bin, and a valve is arranged between each material bin and the first conveying pipeline.

Preferably, one second pulse dust collector is arranged above each material bin, and each second pulse dust collector is connected to a second high-pressure fan.

Preferably, a first air-tight spiral conveyor is arranged at the lower end of each material bin, a first single-leaf butterfly valve is arranged below the first air-tight spiral conveyor, and at least one first single-leaf butterfly valve is connected to a first batching scale.

Preferably, a second air-tight spiral conveyor is arranged at the lower end of each carrier bin, a second single-page butterfly valve is arranged below the second air-tight spiral conveyor, and at least one second single-page butterfly valve is connected to a second batching scale.

Preferably, first batching scale with first batching scale connects in the storehouse of keeping in jointly, the storehouse of keeping in passes through the third pipeline connect in the high-efficient machine that mixes, the high-efficient machine that mixes pass through the second feeder connect in the inspection sieve.

Preferably, a third pulse dust collector is arranged on the third conveying pipeline and connected to a third high-pressure fan.

The utility model relates to a feed additive processingequipment, its beneficial effect lies in: feeding the materials into a conveying pipeline by using an air-closed feeding valve after feeding, then blowing the materials into each bin by using a high-pressure fan, wherein each bin is independently provided with an efficient pulse bag dust collector, gas accompanied by the materials passes through a bag of the dust collector, the materials are adsorbed on the surface of the bag, and clean gas passes through the bag and is discharged to the outside; the conveying pipeline adopts a national standard seamless pipe, the connecting part of the storage bin adopts a thickened sealing layer, the whole conveying process is carried out in a sealed environment, no material is leaked, and the manpower is reduced (workers are needed only when feeding is carried out); after various materials enter the storage bin, an automatic weighing and batching process is adopted and is controlled by a computer, so that batching is accurate, the automation degree is high, and the manual consumption is reduced; materials which are matched are sent into a pipeline through an air-closed feeding valve, negative pressure is pumped by a high-pressure fan, the materials are sent to a specified position, and a high-efficiency pulse bag dust collector is also arranged at the top of the storage bin to separate the materials from air, so that clean air is discharged out of the room; then the materials enter a mixer to be mixed, and screening and packaging are carried out after the mixing is finished; the valve port scale is used for metering and packaging, the valve port scale is provided with an automatic bag unloading mechanism, and when automatic packaging is finished at every time, the bag unloading mechanism automatically unloads the packaged packaging bag onto the belt conveyor, so that the labor intensity of workers is effectively reduced, and meanwhile, the valve port scale is also provided with a gas ring bag expanding device with a discharge port capable of being selected and installed, so that dust is obviously reduced, and the working environment is improved.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention. In the drawings:

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

labeled as: 1. a material dosing assembly; 11. a first high pressure fan; 12. a first delivery conduit; 13. a first feeder; 14. a material bin; 2. a carrier dosing assembly; 21. a second charging bin; 22. A second delivery conduit; 23. a hoist; 24. a carrier bin; 3. a high-efficiency mixer; 4. a first pulse dust collector; 5. a second pulse dust collector; 6. a valve; 7. a second high pressure fan; 8. a first closed-air screw conveyor; 9. a first single-leaf butterfly valve; 10. a first batching scale; 301. a second airlock screw conveyor; 302. a second single-leaf butterfly valve; 303. a second batching scale; 304. a temporary storage bin; 306. a second feeder; 307. inspecting and screening; 308. a third pulse dust collector; 309. a third high pressure fan; 410. A third delivery conduit; 411. a water inlet device.

Detailed Description

The conception, the specific structure and the technical effects of the present invention will be clearly and completely described below in conjunction with the embodiments and the accompanying drawings to fully understand the objects, the schemes and the effects of the present invention. It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. It should be noted that, unless otherwise specified, when a feature is referred to as being "fixed" or "connected" to another feature, it may be directly fixed or connected to the other feature or indirectly fixed or connected to the other feature. Further, the description of the upper, lower, left, right, etc. used in the present invention is only with respect to the positional relationship of the respective components of the present invention with respect to each other in the drawings.

The following describes preferred embodiments of the present invention in detail with reference to the accompanying drawings.

As shown in fig. 1, a feed additive processing device comprises a material batching component 1, a carrier batching component 2 and a high-efficiency mixer 3; the material batching assembly 1 comprises a first high-pressure fan 11, a first conveying pipeline 12, a first feeder 13 and a material bin 14; the first feeder 13 is communicated with the first conveying pipeline 13, and the first high-pressure fan 11 conveys the materials fed by the first feeder 13 into the material bin 14 through the first conveying pipeline 13; the carrier batching assembly 2 comprises a second batch bin 21, a second conveying pipeline 22, a lifter 23 and a carrier bin 24; the elevator 23 can lift the second batch bin 21 above the carrier bin 24, and the carriers in the second batch bin 21 are conveyed into the carrier bin 24 through the second conveying pipeline 22; the materials in the material bin 14 and the carriers in the carrier bin 24 are conveyed into the high-efficiency mixer 3 through a third conveying pipeline 410 to be uniformly mixed; a first pulse dust collector 4 is arranged above the first feeder 13, and a second pulse dust collector 5 is arranged above the material bin 14. The first pulse dust collector 4 can prevent the dust of the materials from flying when the materials are poured into the first feeder 13 from the feeding port and the first high-pressure fan 11 is started to convey the materials into the material bin 14. When the carrier is manually poured into the second feeding bin 21, the second feeding bin 21 is lifted above the carrier bin 24 by the lifter 23, and the carrier is conveyed into the carrier bin 24 by the second conveying pipeline 22.

The first conveying pipeline 12 is communicated with at least one material bin 14, and a valve 6 is arranged between each material bin 14 and the first conveying pipeline 12. And one second pulse dust collector 5 is arranged above each material bin 14, and each second pulse dust collector 5 is connected to a second high-pressure fan 7. The utility model discloses be provided with 6 material feed bins 14 among the device, through closing the valve 6 of material feed bin 14 top to can carry into different material feed bins 14 with the material of difference, second high pressure positive blower 7 starts, can make and produce the negative pressure in the material feed bin 14, make the gas in the material feed bin 14 filter out from second pulse dust collector 5, and the material stays in material feed bin 14 through the effect of second pulse dust collector 5.

Each 14 lower extremes of material feed bin are equipped with first airlock screw conveyer 8, first airlock screw conveyer 8 below is equipped with first single page butterfly valve 9, at least one first single page butterfly valve 9 connects in first batching balance 10. A second airtight spiral conveyor 301 is arranged at the lower end of each carrier bin 24, a second single-page butterfly valve 302 is arranged below the second airtight spiral conveyor 201, and at least one second single-page butterfly valve 302 is connected to a second batching scale 303. And opening the corresponding first single-page butterfly valve 9, and conveying the materials in the corresponding material bin 14 to a first ingredient scale 10 through a first air-tight spiral conveyor 8 for weighing. The second batching scale 303 can also perform weighing and proportioning of the carrier.

First batching scale 10 with second batching scale 303 connects in temporary storage bin 304 jointly, temporary storage bin 304 passes through third pipeline 410 connect in the high-efficient machine of mixing 3, the high-efficient machine of mixing 3 below is equipped with rather than the water installations 411 of connecting, the high-efficient machine of mixing 3 pass through second feeder 306 connect in inspection sieve 307. The materials in the first ingredient scale 10 and the carriers in the second ingredient scale 303 enter the high-efficiency mixer 3 through a third conveying pipeline 410, the solvent can be conveyed into the high-efficiency mixer 3 through the water inlet device for mixing, and after the mixing is completed, the mixed materials enter the inspection sieve 307 through the second feeder 306, so that the agglomerated mixture can be screened out.

A third pulse dust collector 308 is arranged on the third conveying pipeline 410, and the third pulse dust collector 308 is connected to a third high-pressure fan 309. The third high pressure fan 309 generates negative pressure to make the materials in the temporary storage bin 304 enter the high efficiency mixer 3, and the third pulse dust collector 308 can prevent the mixed materials from being ejected out of the fan under the action of the negative pressure.

The material passing through the inspection screen 307 is packed in two ways, one is manually packed and the other is weighed and automatically packed.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. A feed additive processing device is characterized by comprising a material batching component, a carrier batching component and a high-efficiency mixer; the material batching component comprises a first high-pressure fan, a first conveying pipeline, a first feeder and a material bin; the first feeder is communicated with the first conveying pipeline, and the first high-pressure fan conveys the materials fed by the first feeder into the material bin through the first conveying pipeline; the carrier batching component comprises a second feeding bin, a second conveying pipeline, a lifting machine and a carrier bin; the second feeding bin can be lifted above the carrier bin by the lifting machine, and carriers in the second feeding bin are conveyed into the carrier bin through the second conveying pipeline; the materials in the material bin and the carriers in the carrier bin are conveyed into the high-efficiency mixer through a third conveying pipeline to be uniformly mixed; a first pulse dust collector is arranged above the first feeder, and a second pulse dust collector is arranged above the material bin.

2. The feed additive processing device as recited in claim 1, wherein the first conveying pipe is connected to at least one of the material bins, and a valve is disposed between each of the material bins and the first conveying pipe.

3. The feed additive processing device as recited in claim 2, wherein one of said second pulse dust collectors is disposed above each of said material bins, and each of said second pulse dust collectors is connected to a second high pressure fan.

4. The feed additive processing device as recited in claim 3, wherein a first air-tight screw conveyor is disposed at a lower end of each of the material bins, a first single-leaf butterfly valve is disposed below the first air-tight screw conveyor, and at least one of the first single-leaf butterfly valves is connected to a first ingredient scale.

5. The feed additive processing device of claim 4 wherein a second airlock screw conveyor is provided at a lower end of each of the carrier silos, a second single-leaf butterfly valve is provided below the second airlock screw conveyor, and at least one of the second single-leaf butterfly valves is connected to a second ingredient scale.

6. The feed additive processing device of claim 5 wherein the first ingredient scale and the first ingredient scale are commonly connected to a temporary storage bin, the temporary storage bin being connected to the high efficiency mixer through the third delivery conduit, the high efficiency mixer being connected to a test screen through a second feeder.

7. The feed additive processing device as claimed in claim 6, wherein a third pulse dust collector is provided on the third conveying pipeline, and the third pulse dust collector is connected to a third high-pressure fan.

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