CN116492889A - A ration compounding device for feed processing - Google Patents

Abstract

The invention belongs to the technical field of feed processing, and particularly relates to a quantitative mixing device for feed processing. The device mainly comprises a feed box, a solid material input mechanism, a material pressing mechanism, a stirring mechanism and a granulating mechanism, wherein when quantitative material mixing is needed, all solid materials and liquid materials are added into the feed box according to the proportion, a feed inlet on a pressing plate in the material pressing mechanism is opened before the solid materials are added, the feed inlet is closed by a sliding plate after the solid materials are added, and meanwhile, a second material extruding hole of a driven plate in the granulating mechanism is staggered with a first material extruding hole of the bottom plate, and the stirring mechanism is started to perform stirring and mixing operation; after mixing, the rotary column in the stirring mechanism is moved out of the mixing box, the stirring blade plate is stored in a storage groove of the rotary column in the moving-out process, then a hydraulic push rod of the material pressing mechanism works to drive the pressing plate to move downwards, and then a second material extruding hole of the driven plate in the granulating mechanism is communicated with a first material extruding hole gap of the bottom plate, so that the mixture can be extruded and granulated.

Description

A ration compounding device for feed processing

Technical Field

The invention belongs to the technical field of feed processing, and particularly relates to a quantitative mixing device for feed processing.

Background

The mixer consists of a container, a rotating vertical stirring spiral blade and the like, when the molding materials are stirred, the spiral She Xiangyou rotates, each particle of the molding materials close to the spiral blade moves upwards, outwards after reaching the top, downwards moves along the inner wall of the container, upwards moves again when reaching the bottom of the container and contacts the spiral blade, the opportunity of mutual contact of various raw materials is increased, the stirring efficiency is high, the mixing is relatively uniform, and the mixer is essential production equipment in the feed production and processing process. In the feed production and processing process, different raw materials are required to be manually quantified and then put into a mixer for stirring. The labor consumption is large, and misoperation is easy to occur in the throwing process, so that the problem of inaccurate feed ingredient proportion is caused.

For this reason, disclose a fodder processing ration blendor in the patent specification of publication number CN218358785U, which comprises an outer shell, the inside top both sides of shell all are provided with the storage case, the below of storage case corresponds to be provided with and deposits the case, the bottom both sides of depositing the case all are provided with pressure sensor, pressure sensor's bottom and the inner wall boss fixed connection of shell, the equal fixedly connected with slide rail of outer wall below both sides of depositing the case, the outer wall slip joint of slide rail has the slider, slider fixed connection is in the inner wall of shell, the equal fixedly connected with first servo motor of side below of storage case and storage case, first servo motor is connected with the gear through first belt transmission. Through automatic ration, the controllable input of raw materials, closed stirring, it is big to have solved the manpower that consumes, the inaccurate problem of fodder composition ratio.

However, the quantitative mixing device for feed processing still has the defects that the quantitative mixing device cannot realize quantitative input of each solid raw material; secondly, the solid raw materials and the liquid raw materials which are put into the mixer cannot be fully mixed, and the mixture cannot be extruded and granulated. Therefore, there is a need for an optimization improvement.

Disclosure of Invention

The invention aims to overcome the problems in the prior art and provide a quantitative mixing device for feed processing.

In order to achieve the technical purpose and the technical effect, the invention is realized by the following technical scheme:

a quantitative mixing device for feed processing comprises a mixing box, a solid material input mechanism, a material pressing mechanism, a stirring mechanism and a granulating mechanism; the solid material input mechanisms are arranged in a plurality of ways and are arranged on the box cover of the mixing box; the material pressing mechanism is arranged at the upper part of the mixing box and is used for pressing the mixture; the stirring mechanism is arranged at the side part of the mixing box and is used for stirring the mixture; the granulating mechanism is arranged at the bottom of the mixing box and is used for granulating the mixture by matching with the pressing mechanism.

Further, in the quantitative mixing device for feed processing, the top side of the mixing box is connected with the liquid feed inlet pipe.

Further, in the quantitative mixing device for feed processing, the solid material input mechanism comprises a feed bin, a feed pipe, a cylindrical shell, a discharge pipe, a material taking roller, a rotating shaft and a first servo motor, wherein the feed bin and the first servo motor are directly or indirectly fixed on a box cover of the mixing box, the bottom end of the feed bin is connected with the upper end of the cylindrical shell through the feed pipe, the lower end of the cylindrical shell is connected with the discharge pipe penetrating through the box cover of the mixing box, the material taking roller is arranged in the cylindrical shell, the side end of the material taking roller is fixed with the rotating shaft penetrating out of the cylindrical shell, and the rotating shaft is driven to rotate by the first servo motor.

Further, in the quantitative mixing device for feed processing, the surface of the material taking roller is provided with a plurality of quantitative material taking grooves along the circumferential direction, and the openings of the quantitative material taking grooves are matched with the cross section shapes of the inner cavities of the feeding pipe and the discharging pipe.

Further, in the quantitative mixing device for feed processing, the pressing mechanism comprises a hydraulic push rod, a pressing plate, a second servo motor, a screw rod and a sliding plate, the hydraulic push rod is fixed on a box cover of the mixing box, the pressing plate is fixedly arranged at the movable end of the hydraulic push rod, a plurality of groups of feeding holes are symmetrically formed in the pressing plate, a transverse sliding groove is formed in the position of the feeding hole of the pressing plate, the second servo motor is fixed on the pressing plate, the output end of the second servo motor is connected with the screw rod, the sliding plate is an L-shaped plate, the sliding of the transverse plate part of the sliding plate is limited in the transverse sliding groove, and a screw rod groove matched with the screw rod is formed in the vertical plate part of the sliding plate.

Further, in the quantitative mixing device for feed processing, the cross section of the transverse chute is of an inverted T-shaped structure with a narrow upper part and a wide lower part.

Further, in the quantitative mixing device for feed processing, the stirring mechanism comprises a slide rail bracket, a horizontal slide rail, a slide block, a third servo motor, a rotating column, a storage sleeve, a spring and a stirring blade plate, wherein the horizontal slide rail is fixed on the outer wall of a middle side plate of the mixing box through the slide rail bracket, the slide block forming a linear slide rail pair with the horizontal slide rail is arranged on the horizontal slide rail, the third servo motor is arranged at the upper end of the slide block, the output end of the third servo motor is connected with the rotating column through a coupling, and the storage sleeve sleeved on the outer wall of the middle side plate of the mixing box is fixed; the outer side of the rotary column is provided with a plurality of groups of storage grooves which are symmetrically distributed, the rotary column is positioned at the storage groove and is rotationally connected with stirring blades, a compression spring is connected between two opposite stirring blades, and a through hole which is convenient for installing the compression spring is formed between the two storage grooves in the same group.

Further, in the quantitative mixing device for feed processing, the granulating mechanism comprises a fourth servo motor, a driving gear and a driven disc, a plurality of first extrusion holes are formed in the bottom plate of the mixing box, the driven disc is propped against the bottom plate downside of the mixing box, a convex pipe is formed in the side plate of the mixing box in a downward extending mode relative to the bottom plate, an annular positioning groove matched with the driven disc is formed in the inner wall of the convex pipe, a plurality of second extrusion holes are formed in the driven disc, the positions of the second extrusion holes and the positions of the first extrusion holes are in one-to-one correspondence, the fourth servo motor is fixed on the outer wall of the mixing box, the driving gear is mounted at the movable end of the fourth servo motor, a tooth groove matched with the driving gear is formed in the outer side of the driven disc in a circumferential mode, and a through hole for avoiding the driving gear is formed in the convex pipe.

The beneficial effects of the invention are as follows:

the invention has reasonable structural design, is mainly formed by a feed box, a solid material input mechanism, a material pressing mechanism, a stirring mechanism and a granulating mechanism, when quantitative material mixing is needed, each solid material and each liquid material are added into the mixing box according to the proportion, a feed inlet on a pressing plate in the material pressing mechanism is opened before the solid material is added, the feed inlet is closed by a sliding plate after the solid material is added, and meanwhile, a second material extruding hole of a driven plate in the granulating mechanism is staggered with a first material extruding hole of a bottom plate, and the stirring mechanism is started to perform stirring and mixing operation; after mixing, the rotary column in the stirring mechanism is moved out of the mixing box, the stirring blade plate is stored in a storage groove of the rotary column in the moving-out process, then a hydraulic push rod of the material pressing mechanism works to drive the pressing plate to move downwards, and then a second material extruding hole of the driven plate in the granulating mechanism is communicated with a first material extruding hole gap of the bottom plate, so that the mixture can be extruded and granulated.

Of course, it is not necessary for any one product to practice the invention to achieve all of the advantages set forth above at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic structural view of a solid material feeding mechanism in the present invention;

FIG. 3 is a schematic view of the structure of the take-out roll according to the present invention;

FIG. 4 is a schematic structural view of a pressing mechanism in the present invention;

FIG. 5 is a schematic view of the stirring mechanism according to the present invention;

FIG. 6 is a schematic view of the granulation mechanism of the present invention;

in the drawings, the reference numerals of the components are as follows:

1-mixing box, 101-bottom plate, 102-first extrusion hole, 2-solid material input mechanism, 201-bin, 202-feeding pipe, 203-cylindrical shell, 204-discharging pipe, 205-material taking roller, 206-rotating shaft, 207-first servo motor, 3-material pressing mechanism, 301-hydraulic push rod, 302-pressing plate, 303-feeding hole, 304-transverse sliding chute, 305-second servo motor, 306-screw rod, 307-sliding plate, 308-sealing ring, 4-stirring mechanism, 401-sliding rail bracket, 402-horizontal sliding rail, 403-sliding block, 404-third servo motor, 405-rotating column, 406-containing sleeve, 407-containing groove, 408-spring, 409-stirring blade plate, 5-granulating mechanism, 501-fourth servo motor, 502-driving gear, 503-driven disc, 504-second extrusion hole.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-6, the present embodiment is a quantitative mixing device for feed processing, which includes a mixing box 1, a solid material input mechanism 2, a pressing mechanism 3, a stirring mechanism 4 and a granulating mechanism 5. The solid material input mechanism 2 is provided with a plurality of solid material input mechanisms and is arranged on the box cover of the mixing box 1. The pressing mechanism 3 is arranged at the upper part of the mixing box 1 and is used for extruding the mixture. The stirring mechanism 4 is installed at the side of the mixing box 1 and is used for stirring the mixture. The granulating mechanism 5 is arranged at the bottom of the mixing box 1 and is used for granulating the mixture by matching with the pressing mechanism 3.

In this embodiment, the top side of the mixing tank 1 is terminated with a liquid material inlet pipe.

In this embodiment, the solid material feeding mechanism 2 includes a bin 201, a feeding pipe 202, a cylindrical shell 203, a discharge pipe 204, a material taking roller 205, a rotating shaft 206 and a first servo motor 207, where the bin 201 and the first servo motor 207 are directly or indirectly fixed on a box cover of the mixing box 1, a bottom end of the bin 201 is connected with an upper end of the cylindrical shell 203 through the feeding pipe 202, and a lower end of the cylindrical shell 203 is connected with the discharge pipe 204 penetrating through the box cover of the mixing box 1. A material taking roller 205 is arranged in the cylindrical shell 203, a rotating shaft 206 penetrating out of the cylindrical shell 203 is fixed at the side end of the material taking roller 205, and the rotating shaft 206 is driven to rotate by a first servo motor 207.

In this embodiment, a plurality of quantitative material taking grooves are formed in the surface of the material taking roller 205 along the circumferential direction, and the openings of the quantitative material taking grooves are matched with the cross-sectional shapes of the inner cavities of the material feeding pipe 202 and the material discharging pipe 204.

In this embodiment, the pressing mechanism 3 includes a hydraulic push rod 301, a pressing plate 302, a second servo motor 305, a screw 306, and a slide plate 307. The hydraulic push rod 301 is fixed on the box cover of the mixing box 1, the movable end of the hydraulic push rod 301 is fixedly provided with the pressing plate 302, a plurality of groups of feeding holes 303 are symmetrically formed in the pressing plate 302, the pressing plate 302 is provided with a transverse sliding groove 304 at the position of the feeding hole 303, and the cross section of the transverse sliding groove 304 is of an inverted T-shaped structure with a narrow upper part and a wide lower part. The second servo motor 305 is fixed on the pressing plate 302, and a lead screw 306 is connected to the output end of the second servo motor 305. The slide plate 307 is an L-shaped plate, the cross plate portion of the slide plate 307 is slidingly restricted in the transverse chute 304, and the vertical plate portion of the slide plate 307 is provided with a screw rod groove matched with the screw rod 306. A seal ring 308 is mounted to the outer periphery of the platen 302.

In this embodiment, the stirring mechanism 4 includes a slide rail bracket 401, a horizontal slide rail 402, a slide block 403, a third servo motor 404, a rotating column 405, a storage sleeve 406, a spring 408 and a stirring blade 409, the horizontal slide rail 402 is fixed on the outer wall of the middle side plate of the mixing box 1 through the slide rail bracket 401, and the slide block 403 forming a linear slide rail pair with the horizontal slide rail 402 is mounted on the horizontal slide rail 402. A third servo motor 404 is installed at the upper end of the sliding block 403, and a rotating column 405 is connected to the output end of the third servo motor 404 through a coupling. The outer wall of the middle side plate of the mixing box 1 is fixedly provided with a storage sleeve 406 sleeved outside the rotating column 405. The outer side of the rotating post 405 is provided with a plurality of groups of storage slots 407 which are symmetrically distributed, the rotating post 405 is positioned at the storage slots 407 and is rotationally connected with stirring blades 409, compression springs 408 are connected between two opposite stirring blades 409, and through holes which are convenient for installing the compression springs 408 are formed between the two storage slots 407 in the same group.

In this embodiment, the granulation mechanism 5 includes a fourth servomotor 501, a drive gear 502, and a driven disk 503. A plurality of first extrusion holes 102 are formed in the bottom plate 101 of the mixing box 1, the driven plate 503 is propped against the lower side of the bottom plate 101 of the mixing box 1, a convex pipe is formed by extending the side plate of the mixing box 1 downwards relative to the bottom plate 101, and an annular positioning groove matched with the driven plate 503 is formed in the inner wall of the convex pipe. The driven plate 503 is provided with a plurality of second extrusion holes 504, and the positions of the second extrusion holes 504 and the first extrusion holes 102 are in one-to-one correspondence. The fourth servo motor 501 is fixed on the outer wall of the mixing box 1, the driving gear 502 is installed at the movable end of the fourth servo motor 501, tooth grooves matched with the driving gear 502 are formed in the outer side of the driven plate 503 along the circumferential direction, and the convex tube is provided with an avoidance through hole for avoiding the driving gear 502.

One specific application of this embodiment is: the device mainly comprises a feed box 1, a solid material input mechanism 2, a material pressing mechanism 3, a stirring mechanism 4 and a granulating mechanism 5, when quantitative material mixing is needed, all solid materials and liquid materials are added into the feed box 1 according to the proportion, a feed inlet 303 on a pressing plate 302 in the material pressing mechanism 2 is opened before the solid materials are added, the feed inlet 303 is closed by a sliding plate after the solid materials are added, a second material extruding hole 504 of a driven plate 503 in the granulating mechanism 5 is staggered with a first material extruding hole 102 of a bottom plate 101, and the stirring mechanism 4 is started for stirring and mixing operation; after the mixing is finished, the rotating column 405 in the stirring mechanism 4 is moved out of the mixing box 1, the stirring blade 409 is stored in the storage slot 407 of the rotating column 405 in the moving-out process, then the hydraulic push rod 301 of the pressing mechanism 3 works to drive the pressing plate 302 to move downwards, and then the second extruding hole 504 of the driven plate 503 in the granulating mechanism 5 is communicated with the first extruding hole 102 of the bottom plate 101 in a clearance manner, so that the mixture can be extruded and granulated.

The preferred embodiments of the invention disclosed above are intended only to assist in the explanation of the invention. The preferred embodiments are not exhaustive or to limit the invention to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best understand and utilize the invention. The invention is limited only by the claims and the full scope and equivalents thereof.

Claims (8)

1. The quantitative mixing device for feed processing is characterized by comprising a mixing box, a solid material input mechanism, a material pressing mechanism, a stirring mechanism and a granulating mechanism; the solid material input mechanisms are arranged in a plurality of ways and are arranged on the box cover of the mixing box; the material pressing mechanism is arranged at the upper part of the mixing box and is used for pressing the mixture; the stirring mechanism is arranged at the side part of the mixing box and is used for stirring the mixture; the granulating mechanism is arranged at the bottom of the mixing box and is used for granulating the mixture by matching with the pressing mechanism.

2. A quantitative mixing device for feed processing according to claim 1, characterized in that: the top side end of the mixing box is connected with a liquid material inlet pipe.

3. A quantitative mixing device for feed processing according to claim 2, characterized in that: the solid material input mechanism comprises a feed bin, a feed pipe, a cylindrical shell, a discharge pipe, a material taking roller, a rotating shaft and a first servo motor, wherein the feed bin and the first servo motor are directly or indirectly fixed on a box cover of a mixing box, the bottom end of the feed bin is connected with the upper end of the cylindrical shell through the feed pipe, the lower end of the cylindrical shell is connected with the discharge pipe penetrating through the box cover of the mixing box, the material taking roller is arranged in the cylindrical shell, the side end of the material taking roller is fixed with the rotating shaft penetrating out of the cylindrical shell, and the rotating shaft is driven to rotate by the first servo motor.

4. A quantitative mixing device for feed processing according to claim 3, wherein: the surface of the material taking roller is provided with a plurality of quantitative material taking grooves along the circumferential direction, and the openings of the quantitative material taking grooves are matched with the cross section shapes of the inner cavities of the feeding pipe and the discharging pipe.

5. A quantitative mixing device for feed processing according to claim 4, wherein: the material pressing mechanism comprises a hydraulic push rod, a pressing plate, a second servo motor, a screw rod and a sliding plate, wherein the hydraulic push rod is fixed on a box cover of the mixing box, the pressing plate is fixedly arranged at the movable end of the hydraulic push rod, a plurality of groups of feeding holes are symmetrically formed in the pressing plate, a transverse sliding groove is formed in the position of the feeding hole of the pressing plate, the second servo motor is fixed on the pressing plate, the output end of the second servo motor is connected with the screw rod, the sliding plate is an L-shaped plate, the transverse plate part of the sliding plate is limited in the transverse sliding groove in a sliding mode, and a screw rod groove matched with the screw rod is formed in the vertical plate part of the sliding plate.

6. A quantitative mixing device for feed processing according to claim 5, wherein: the cross section of the transverse chute is of an inverted T-shaped structure with a narrow upper part and a wide lower part.

7. A quantitative mixing device for feed processing according to claim 6, wherein: the stirring mechanism comprises a slide rail bracket, a horizontal slide rail, a slide block, a third servo motor, a rotating column, a storage sleeve, a spring and a stirring blade plate, wherein the horizontal slide rail is fixed on the outer wall of a middle side plate of the mixing box through the slide rail bracket; the outer side of the rotary column is provided with a plurality of groups of storage grooves which are symmetrically distributed, the rotary column is positioned at the storage groove and is rotationally connected with stirring blades, a compression spring is connected between two opposite stirring blades, and a through hole which is convenient for installing the compression spring is formed between the two storage grooves in the same group.

8. A quantitative mixing device for feed processing according to claim 7, wherein: the granulating mechanism comprises a fourth servo motor, a driving gear and a driven disc, wherein a plurality of first extruding holes are formed in a bottom plate of the mixing box, the driven disc is propped against the lower side of the bottom plate of the mixing box, a convex pipe is formed by extending downwards relative to the bottom plate of the mixing box, an annular positioning groove matched with the driven disc is formed in the inner wall of the convex pipe, a plurality of second extruding holes are formed in the driven disc, the positions of the second extruding holes and the positions of the first extruding holes are in one-to-one correspondence, the fourth servo motor is fixed on the outer wall of the mixing box, the driving gear is mounted at the movable end of the fourth servo motor, tooth grooves matched with the driving gear are formed in the outer side of the driven disc along the circumferential direction, and an avoidance through hole for avoiding the driving gear is formed in the convex pipe.