CN110215987B

CN110215987B - Utilize rice bran dregs of rice preparation fodder equipment

Info

Publication number: CN110215987B
Application number: CN201910490768.4A
Authority: CN
Inventors: 高峰
Original assignee: Yantai Hairunjia Biotechnology Co Ltd
Current assignee: Yantai hairunjia Biotechnology Co., Ltd
Priority date: 2019-06-06
Filing date: 2019-06-06
Publication date: 2020-12-04
Anticipated expiration: 2039-06-06
Also published as: CN110215987A

Abstract

The invention relates to feed equipment, in particular to equipment for preparing feed by utilizing rice bran meal, which comprises a device bracket, a feeding bracket, a power mechanism, a transmission mechanism I, a feeding mechanism, a feeding barrel, a transmission mechanism II, a transmission mechanism III, a magnetic sieve bracket, a magnetic sieve wheel I, a containing box and a magnetic sieve wheel II, wherein the feeding mechanism and the feeding barrel can be driven to rotate by the power mechanism; the power mechanism realizes the mutual intermittent motion between the transmission mechanism I and the transmission mechanism II, and the transmission mechanism II drives the magnetic sieve wheel I and the magnetic sieve wheel II to rotate for a circle together, so that the magnetic screening of the rice bran meal in the discharging groove is completed.

Description

Utilize rice bran dregs of rice preparation fodder equipment

Technical Field

The invention relates to feed equipment, in particular to equipment for preparing feed by utilizing rice bran meal.

Background

For example, publication No. CN208542077U discloses a mixing device for preparing a feed additive, which includes a tank, a stirring device, and a moving device, wherein the moving device is connected to the stirring device through a connecting plate, a moving track is provided on a cover of the tank, and the stirring device is located in the moving track; the stirring device comprises a power part, a rotating shaft and a plurality of stirring rods positioned on the rotating shaft, wherein the lower end of the rotating shaft is provided with a rotating wheel, and the power part is provided with a shell; the moving device comprises an eccentric part, a lifting rod and a reset part sleeved with the lifting rod, wherein one end of the lifting rod is provided with a fixed plate, the other end of the lifting rod penetrates through the fixed seat to be connected with a connecting plate, a pulley is arranged on the fixed plate, and the pulley is abutted to the eccentric part; the utility model has the defects that the rice bran meal can not be dried efficiently and the iron impurities can not be removed by magnetic screening.

Disclosure of Invention

The invention aims to provide equipment for preparing feed by using rice bran meal, which can efficiently dry the rice bran meal and remove iron impurities by magnetic screening.

The purpose of the invention is realized by the following technical scheme:

a device for preparing feed by utilizing rice bran meal comprises a device support, a feeding support, a power mechanism, a transmission mechanism I, a feeding mechanism, a feeding barrel, a transmission mechanism II, a transmission mechanism III, a magnetic sieve support, a magnetic sieve wheel I, a storage box and a magnetic sieve wheel II, wherein the feeding support is fixedly connected to the device support, the power mechanism is fixedly connected to the device support, the transmission mechanism I is rotatably connected to the device support, the transmission mechanism I and the feeding mechanism are in gear engagement transmission, the feeding mechanism is rotatably connected to the feeding support, the feeding mechanism is connected with the transmission mechanism I through belt transmission, the feeding barrel is rotatably connected to the feeding support, the feeding barrel is connected with the transmission mechanism I through belt transmission, the transmission mechanism II is rotatably connected to the device support, the transmission mechanism II and the feeding mechanism are in gear engagement transmission, and the transmission mechanism III and the transmission mechanism II are in gear engagement transmission, magnetism sieve support fixed connection is on the device support, magnetism sieve wheel I rotates to be connected in the magnetism sieve support, magnetism sieve wheel I and drive mechanism III are connected through the belt drive, containing box fixed connection is on the magnetism sieve support, magnetism sieve wheel II rotates to be connected in the containing box, magnetism sieve wheel II and drive mechanism III are connected through the belt drive, drive ratio between drive mechanism II and the magnetism sieve wheel I is one, drive ratio between drive mechanism II and the magnetism sieve wheel II is one, be provided with heating device in the feed cylinder.

As a further optimization of the technical scheme, the device bracket comprises a supporting plate and supporting frames, the supporting frames are fixedly connected to two sides of the rear end of the supporting plate, a feeding port is formed in the feeding bracket, and the feeding bracket is fixedly connected to the supporting plate. As a further optimization of the technical scheme, the invention relates to equipment for preparing the feed by utilizing the rice bran meal, which comprises the following steps of

As a further optimization of the technical scheme, the device for preparing the feed by using the rice bran meal comprises a power mechanism and a power mechanism, wherein the power mechanism comprises a motor and a tooth-lacking gear, the tooth-lacking gear is fixedly connected to an output shaft of the motor, a half-circle of teeth are arranged on the tooth-lacking gear, and the motor is fixedly connected to a supporting plate.

As the technical scheme is further optimized, the device for preparing the feed by using the rice bran meal comprises a transmission mechanism I, a transmission gear I, a transmission belt wheel I and a transmission belt wheel II, wherein the transmission gear I is fixedly connected to the middle of the transmission shaft I, the transmission gear I and the transmission belt wheel II are respectively and fixedly connected to two ends of the transmission shaft I, the transmission gear I and a tooth-missing gear are in meshing transmission, and the transmission shaft I is rotatably connected to a supporting plate.

As a further optimization of the technical scheme, the feed device utilizing the rice bran meal comprises a feed screw shaft and a feed belt wheel I, wherein the feed screw shaft is rotationally connected to a feeding support, the feed belt wheel I is fixedly connected to the feed screw shaft, the feed belt wheel I is in belt transmission connection with a transmission belt wheel II, the feed cylinder comprises a feed cylinder body, a feed belt wheel II and a feed screw body, the outer side of the feed cylinder body is fixedly connected with the feed belt wheel II, the feed belt wheel II is in belt transmission connection with the transmission belt wheel I, the inner side of the feed cylinder body is provided with the feed screw body, the spiral directions of the feed screw body and the feed screw shaft are the same, and the transmission ratio between the feed belt wheel II and the transmission belt wheel I is larger than the transmission ratio between the feed belt wheel I and the.

As a further optimization of the technical scheme, the device for preparing the feed by using the rice bran meal comprises a transmission mechanism II, a transmission gear II and a transmission bevel gear I, wherein the transmission shaft II is rotatably connected to a support plate, the two ends of the transmission shaft II are respectively and fixedly connected with the transmission gear II and the transmission bevel gear I, the transmission gear II is in meshing transmission with a tooth-lacking gear, the reference circle diameter of the transmission gear II is half of the reference circle diameter of the tooth-lacking gear, the transmission mechanism III comprises a transmission shaft III, a transmission bevel gear II, a transmission belt wheel III and a transmission belt wheel IV, the transmission shaft III is rotatably connected to the support plate, the middle part of the transmission shaft III is fixedly connected with the transmission bevel gear II, and the two ends of the transmission shaft III are respectively and fixedly connected with.

According to the technical scheme, the feed preparation equipment utilizing the rice bran meal comprises two magnetic sieve side plates, two magnetic sieve cylinders, two magnetic sieve holes I, two magnetic sieve holes II, two magnetic sieve holes III and two magnetic sieve holes IV, wherein the two magnetic sieve side plates are fixedly connected to two support frames respectively, the magnetic sieve cylinders are fixedly connected between the two magnetic sieve side plates, the magnetic sieve holes I, the magnetic sieve holes II, the magnetic sieve holes III and the magnetic sieve holes IV are circumferentially and sequentially arranged on the magnetic sieve cylinders, and the magnetic sieve holes I are located below the outlet end of the feeding cylinder.

As a further optimization of the technical scheme, the device for preparing the feed by using the rice bran meal comprises a magnetic sieve wheel body I, a discharging groove, a discharging hole, a magnetic sieve shaft I and a magnetic sieve belt wheel I, wherein the discharging groove and the discharging hole are formed in the magnetic sieve wheel body I, the magnetic sieve shaft I is fixedly connected to two sides of the magnetic sieve wheel body I, the two magnetic sieve shafts I are respectively and rotatably connected to two support frames, the magnetic sieve belt wheel I is fixedly connected to one magnetic sieve shaft I, the magnetic sieve belt wheel I is in belt transmission connection with a transmission belt wheel III, the transmission ratio between the magnetic sieve belt wheel I and the transmission belt wheel III is one, and the transmission ratio between the transmission bevel gear II and the transmission bevel gear I is one.

According to the technical scheme, the storage box is fixedly connected to the magnetic sieve hole II, the magnetic sieve wheel II comprises a magnetic sieve shaft II, a magnetic sieve belt wheel II, a magnetic sieve wheel body II and a magnet, the magnetic sieve shaft II is rotatably connected to the storage box, the magnetic sieve shaft II is fixedly connected with the magnetic sieve belt wheel II, the magnetic sieve wheel body II and the magnet, the magnetic sieve belt wheel II is connected with the transmission belt wheel IV through belt transmission, the transmission ratio between the magnetic sieve belt wheel II and the transmission belt wheel IV is one, the magnetic sieve wheel body II and the magnet are both located in the storage box, and when the discharging groove is communicated with the magnetic sieve hole I, the magnet is located between 90 degrees and 180 degrees.

The equipment for preparing the feed by utilizing the rice bran meal has the beneficial effects that:

according to the device for preparing the feed by using the rice bran meal, the feeding mechanism and the feeding barrel can be driven to rotate by the power mechanism, the transmission ratio between the feeding belt wheel II and the transmission belt wheel I is larger than that between the feeding belt wheel I and the transmission belt wheel II, and the rice bran meal is crushed, polished and fed into the discharging groove by differential motion between the feeding mechanism and the feeding barrel; the power mechanism realizes the mutual intermittent motion between the transmission mechanism I and the transmission mechanism II, and the transmission mechanism II drives the magnetic sieve wheel I and the magnetic sieve wheel II to rotate for a circle together, so that the magnetic screening of the rice bran meal in the discharging groove is completed.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated 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, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

FIG. 1 is a schematic view of the overall structure of the apparatus for preparing feed from rice bran meal according to the present invention;

FIG. 2 is a schematic structural view of a sectional view of the apparatus for preparing fodder using rice bran meal according to the present invention;

FIG. 3 is a schematic view of the device support structure of the present invention;

FIG. 4 is a schematic view of the pan feeding stand configuration of the present invention;

FIG. 5 is a schematic diagram of a power mechanism according to the present invention;

FIG. 6 is a schematic structural diagram of a transmission mechanism I of the invention;

FIG. 7 is a schematic view of the feed mechanism of the present invention;

FIG. 8 is a schematic view of the feed cartridge of the present invention;

FIG. 9 is a schematic cross-sectional view of the feed cartridge of the present invention;

FIG. 10 is a schematic structural diagram of a transmission mechanism II of the present invention;

FIG. 11 is a schematic view of the structure of a transmission mechanism III of the present invention;

FIG. 12 is a schematic view of the magnetic screen support structure of the present invention;

FIG. 13 is a schematic cross-sectional view of a magnetic screen support of the present invention;

FIG. 14 is a schematic structural view of a magnetic sieve wheel I of the present invention;

FIG. 15 is a schematic cross-sectional view of a magnetic screen wheel I of the present invention;

FIG. 16 is a schematic view of the storage case of the present invention;

FIG. 17 is a schematic cross-sectional view of the storage case of the present invention;

FIG. 18 is a schematic structural view of a magnetic sieve wheel II of the present invention;

fig. 19 is a schematic structural view of a cross section of a magnetic sieve wheel II of the invention.

In the figure: a device holder 1; a support plate 1-1; 1-2 of a support frame; feeding a bracket 2; a feeding port 2-1; a power mechanism 3; a motor 3-1; 3-2 parts of a gear with missing teeth; a transmission mechanism I4; a transmission shaft I4-1; a transmission gear I4-2; a transmission belt wheel I4-3; a transmission belt wheel II 4-4; a feeding mechanism 5; 5-1 parts of a feeding screw shaft; a feeding belt wheel I5-2; a feeding cylinder 6; 6-1 of a feeding cylinder body; a feeding belt wheel II 6-2; 6-3 parts of feeding spiral body; a transmission mechanism II 7; a transmission shaft II 7-1; a transmission gear II 7-2; transmission bevel gears I7-3; a transmission mechanism III 8; a transmission shaft III 8-1; the transmission bevel gear II 8-2; 8-3 of a driving belt wheel; a transmission belt wheel IV 8-4; a magnetic screen support 9; a magnetic screen side plate 9-1; a magnetic screen cylinder 9-2; magnetic sieve pores I9-3; magnetic sieve pores II 9-4; 9-5 of magnetic sieve pores III; IV 9-6 of magnetic sieve pores; a magnetic sieve wheel I10; a magnetic sieve wheel body I10-1; a discharge chute 10-2; 10-3 of a discharge hole; 10-4 parts of a magnetic sieve shaft; 10-5 parts of a magnetic screen belt wheel; a storage box 11; a magnetic sieve wheel II 12; a magnetic sieve shaft II 12-1; a magnetic screen belt wheel II 12-2; a magnetic screen wheel body II 12-3; and a magnet 12-4.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1-19, and an apparatus for preparing feed from rice bran meal comprises a device support 1, a feeding support 2, a power mechanism 3, a transmission mechanism i 4, a feeding mechanism 5, a feeding barrel 6, a transmission mechanism ii 7, a transmission mechanism iii 8, a magnetic sieve support 9, a magnetic sieve wheel i 10, a storage box 11 and a magnetic sieve wheel ii 12, wherein the feeding support 2 is fixedly connected to the device support 1, the power mechanism 3 is fixedly connected to the device support 1, the transmission mechanism i 4 is rotatably connected to the device support 1, the transmission mechanism i 4 and the feeding mechanism 5 are in gear engagement transmission, the feeding mechanism 5 is rotatably connected to the feeding support 2, the feeding mechanism 5 and the transmission mechanism i 4 are connected by belt transmission, the feeding barrel 6 is rotatably connected to the feeding support 2, the feeding barrel 6 is connected to the transmission mechanism i 4 by belt transmission, the transmission mechanism ii 7 is rotatably connected to the device support 1, the transmission mechanism II 7 and the feeding mechanism 5 are in meshing transmission through gears, the transmission mechanism III 8 and the transmission mechanism II 7 are in meshing transmission through gears, the magnetic sieve support 9 is fixedly connected to the device support 1, the magnetic sieve wheel I10 is rotatably connected into the magnetic sieve support 9, the magnetic sieve wheel I10 and the transmission mechanism III 8 are in belt transmission connection, the containing box 11 is fixedly connected onto the magnetic sieve support 9, the magnetic sieve wheel II 12 is rotatably connected into the containing box 11, the magnetic sieve wheel II 12 and the transmission mechanism III 8 are in belt transmission connection, the transmission ratio between the transmission mechanism II 7 and the magnetic sieve wheel I10 is one, the transmission ratio between the transmission mechanism II 7 and the magnetic sieve wheel II 12 is one, and the feeding barrel 6 is internally provided with a heating device; the feeding mechanism 5 and the feeding barrel 6 can be driven to rotate by the power mechanism 3, the transmission ratio between the feeding belt wheel II 6-2 and the transmission belt wheel I4-3 is larger than the transmission ratio between the feeding belt wheel I5-2 and the transmission belt wheel II 4-4, differential motion between the feeding mechanism 5 and the feeding barrel 6 is realized, and the rice bran meal is crushed, polished and fed into the discharging groove 10-2; power unit 3 realizes the mutual intermittent type motion between drive mechanism I4 and drive mechanism II 7, and drive mechanism II 7 drives magnetism sieve wheel I10 and magnetism sieve wheel II 12 and rotates a week jointly, accomplishes the magnetic force screening of rice bran dregs in the blowing groove.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 19, and the embodiment further describes the first embodiment, where the apparatus bracket 1 includes a supporting plate 1-1 and a supporting frame 1-2, both sides of the rear end of the supporting plate 1-1 are fixedly connected with the supporting frame 1-2, the feeding bracket 2 is provided with a feeding port 2-1, and the feeding bracket 2 is fixedly connected to the supporting plate 1-1.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 19, and the second embodiment is further described in the embodiment, where the power mechanism 3 includes a motor 3-1 and a tooth-missing gear 3-2, the tooth-missing gear 3-2 is fixedly connected to an output shaft of the motor 3-1, the tooth-missing gear 3-2 is provided with a half-circle of teeth, and the motor 3-1 is fixedly connected to the support plate 1-1; when the rice bran cake processing machine is used, rice bran cakes to be processed are placed in the feeding support 2 through the feeding opening 2-1, the motor 3-1 is started, the output shaft of the motor 3-1 starts to rotate, and the output shaft of the motor 3-1 drives the tooth-missing gear 3-2 to rotate by taking the axis of the output shaft of the motor 3-1 as the center.

The fourth concrete implementation mode:

the third embodiment is further described with reference to fig. 1-19, in which the transmission mechanism i 4 includes a transmission shaft i 4-1, a transmission gear i 4-2, a transmission pulley i 4-3 and a transmission pulley ii 4-4, the middle of the transmission shaft i 4-1 is fixedly connected with the transmission pulley i 4-3, two ends of the transmission shaft i 4-1 are respectively fixedly connected with the transmission gear i 4-2 and the transmission pulley ii 4-4, the transmission gear i 4-2 is in meshing transmission with the gear with teeth 3-2, and the transmission shaft i 4-1 is rotatably connected to the support plate 1-1; the gear-missing gear 3-2 is in meshed transmission with the transmission gear I4-2, a half-circle of teeth are arranged on the gear-missing gear 3-2, when the gear-missing gear 3-2 is in meshed transmission with the transmission gear I4-2, the gear-missing gear 3-2 and the transmission gear II 7-2 are out of meshed transmission, the gear-missing gear 3-2 drives the transmission gear I4-2 to rotate, the transmission gear I4-2 drives the transmission shaft I4-1 to rotate by taking the axis of the transmission shaft I4-1 as the center, and the transmission shaft I4-1 drives the transmission belt wheel I4-3 and the transmission belt wheel II 4-4 to rotate by taking the axis of the transmission shaft I4-1 as.

The fifth concrete implementation mode:

the fourth embodiment is further described with reference to fig. 1-19, wherein the feeding mechanism 5 includes a feeding screw shaft 5-1 and a feeding belt wheel i 5-2, the feeding screw shaft 5-1 is rotatably connected to the feeding support 2, the feeding belt wheel i 5-2 is fixedly connected to the feeding screw shaft 5-1, the feeding belt wheel i 5-2 is connected to the driving belt wheel ii 4-4 through belt transmission, the feeding barrel 6 includes a feeding barrel 6-1, a feeding belt wheel ii 6-2 and a feeding spiral body 6-3, the feeding barrel 6-1 is fixedly connected to the feeding belt wheel ii 6-2 at the outer side, the feeding belt wheel ii 6-2 is connected to the driving belt wheel i 4-3 through belt transmission, the feeding spiral body 6-3 is arranged at the inner side of the feeding barrel 6-1, the spiral directions of the feeding spiral body 6-3 and the feeding spiral shaft 5-1 are the same, and the transmission ratio between the feeding belt wheel II 6-2 and the transmission belt wheel I4-3 is larger than the transmission ratio between the feeding belt wheel I5-2 and the transmission belt wheel II 4-4; the transmission belt wheel II 4-4 drives the feeding belt wheel I5-2 to rotate by taking the self axis as the center, the feeding belt wheel I5-2 drives the feeding screw shaft 5-1 to rotate by taking the self axis as the center, the transmission belt wheel I4-3 drives the feeding belt wheel II 6-2 to rotate by taking the self axis as the center, the feeding belt wheel II 6-2 drives the feeding cylinder body 6-1 to rotate by taking the self axis as the center, the rotating directions of the feeding screw body 6-3 and the feeding screw shaft 5-1 are the same, the transmission ratio between the feeding belt wheel II 6-2 and the transmission belt wheel I4-3 is larger than that between the feeding belt wheel I5-2 and the transmission belt wheel II 4-4, the rotating directions of the feeding screw shaft 5-1 and the feeding screw body 6-3 are the same, and the differential speed is formed between the feeding screw shaft 5-1 and the, the rice bran meal in the feeding screw shaft 5-1 and the feeding screw 6-3 is crushed and ground, and the rice bran meal can be pushed into the discharging groove 10-2 by paying attention to the rotation direction of the feeding screw shaft 5-1 and the feeding screw 6-3 and the rotation direction of the feeding screw shaft 5-1 and the feeding screw 6-3 to be matched with each other.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1-19, and the fifth embodiment is further described, wherein the transmission mechanism ii 7 comprises a transmission shaft ii 7-1, a transmission gear ii 7-2 and a transmission bevel gear i 7-3, the transmission shaft ii 7-1 is rotatably connected to the support plate 1-1, two ends of the transmission shaft ii 7-1 are respectively and fixedly connected with a transmission gear ii 7-2 and a transmission bevel gear i 7-3, the transmission gear ii 7-2 is in mesh transmission with the gear with teeth missing 3-2, the reference circle diameter of the transmission gear ii 7-2 is half of the reference circle diameter of the gear with teeth missing 3-2, the transmission mechanism iii 8 comprises a transmission shaft iii 8-1, a transmission bevel gear ii 8-2, a transmission belt pulley iii 8-3 and a transmission belt pulley iv 8-4, the transmission shaft iii 8-1 is rotatably connected to the support plate 1-1, the middle part of the transmission shaft III 8-1 is fixedly connected with a transmission bevel gear II 8-2, and two ends of the transmission shaft III 8-1 are respectively and fixedly connected with a transmission belt wheel III 8-3 and a transmission belt wheel IV 8-4; when the transmission gear II 7-2 and the gear with missing teeth 3-2 are in meshing transmission, the gear with missing teeth 3-2 and the transmission gear I4-2 are out of meshing transmission, the feeding mechanism 5 does not push rice bran meal into the discharging groove 10-2, the reference circle diameter of the transmission gear II 7-2 is half of the reference circle diameter of the gear with missing teeth 3-2, the gear with missing teeth 3-2 rotates for one circle, the transmission gear II 7-2 drives the transmission shaft II 7-1 to rotate for one circle by taking the axis of the transmission gear II 7-2 as the center, the transmission shaft II 7-1 drives the transmission conical tooth I7-3 to rotate for one circle by taking the axis of the transmission conical tooth I7-3 as the center, the transmission conical tooth I7-3 drives the transmission conical tooth II 8-2 to rotate for one circle by taking the axis of the transmission conical tooth II 8-2 as the center, the transmission conical tooth II 8-2 drives the transmission, the transmission shaft III 8-1 drives the transmission belt wheel III 8-3 and the transmission belt wheel IV 8-4 to rotate for one circle by taking the self axis as the center, and the transmission belt wheel III 8-3 and the transmission belt wheel IV 8-4 respectively drive the corresponding magnetic sieve wheel I10 and the corresponding magnetic sieve wheel II 12 to rotate for one circle by taking the self axis as the center.

The seventh embodiment:

this embodiment will be described below with reference to fig. 1 to 19, and this embodiment will further describe embodiment six, the magnetic screen support 9 comprises two magnetic screen side plates 9-1, two magnetic screen cylinders 9-2, two magnetic screen holes I9-3, two magnetic screen holes II 9-4, two magnetic screen holes III 9-5 and two magnetic screen holes IV 9-6, the two magnetic screen side plates 9-1 are respectively and fixedly connected to the two support frames 1-2, the magnetic screen cylinder 9-2 is fixedly connected between the two magnetic screen side plates 9-1, the magnetic screen cylinder 9-2 is circumferentially and sequentially provided with the magnetic screen holes I9-3, the magnetic screen holes II 9-4, the magnetic screen holes III 9-5 and the magnetic screen holes IV 9-6, and the magnetic screen holes I9-3 are positioned below the outlet end of the feeding cylinder 6-1; as shown in fig. 13, the magnetic sieve holes I9-3, the magnetic sieve holes II 9-4, the magnetic sieve holes III 9-5 and the magnetic sieve holes IV 9-6 are sequentially and circumferentially and uniformly arranged on the magnetic sieve cylinder 9-2, and the magnetic sieve holes I9-3, the magnetic sieve holes II 9-4, the magnetic sieve holes III 9-5 and the magnetic sieve holes IV 9-6 are separated by 90 degrees.

The specific implementation mode is eight:

the embodiment is described below with reference to fig. 1 to 19, and the seventh embodiment is further described in the present embodiment, where the magnetic sieve wheel i 10 includes a magnetic sieve wheel body i 10-1, a discharging slot 10-2, a discharging hole 10-3, a magnetic sieve shaft i 10-4 and a magnetic sieve pulley i 10-5, the discharging slot 10-2 and the discharging hole 10-3 are provided on the magnetic sieve wheel body i 10-1, the magnetic sieve shaft i 10-4 is fixedly connected to both sides of the magnetic sieve wheel body i 10-1, the two magnetic sieve shafts i 10-4 are respectively and rotatably connected to the two support frames 1-2, the magnetic sieve pulley i 10-4 is fixedly connected to the magnetic sieve pulley i 10-5, the magnetic sieve pulley i 10-5 and the driving pulley iii 8-3 are connected by belt transmission, a transmission ratio between the magnetic sieve pulley i 10-5 and the driving pulley iii 8-3 is one, the transmission ratio between the transmission bevel gear II 8-2 and the transmission bevel gear I7-3 is one; as shown in fig. 15, during installation of the device, the discharging groove 10-2 is communicated with the magnetic sieve pore I9-3, rice bran can fall into the discharging groove 10-2 through the magnetic sieve pore I9-3, the difference between the discharging groove 10-2 and one end of the discharging pore 10-3 is 90 degrees, when the magnetic sieve wheel body I10-1 rotates for a circle, the magnetic sieve wheel body I10-1 drives the discharging groove 10-2 and the discharging pore 10-3 to rotate for a circle, when the magnetic sieve wheel body I10-1 rotates clockwise for 90 degrees, the discharging groove 10-2 is superposed with the magnetic sieve pore II 9-4, as shown in fig. 19, during installation, the magnet 12-4 is positioned between 90 degrees and 180 degrees, when the magnet 12-4 rotates clockwise for 90 degrees, the discharging groove 10-2 is superposed with the magnetic sieve pore II 9-4, the magnet 12-4 sucks the iron product in the discharging groove 10-2 into the storage box 11, when the magnetic sieve wheel body I10-1 rotates clockwise for 180 degrees, the magnetic sieve holes I9-3 and the magnetic sieve holes II 9-4 coincide, when the magnet 12-4 rotates clockwise for 180 degrees, the magnet 12-4 cannot continuously generate suction to iron products in the storage box 11, the iron products fall through the discharge holes 10-3 under the action of gravity and fall off from the magnetic sieve holes IV 9-6, rice bran meal in the magnetic separation finished discharging groove 10-2 is communicated with the magnetic sieve holes III 9-5 when the magnetic sieve wheel body I10-1 rotates clockwise for 180 degrees, and falls off from the magnetic sieve holes III 9-5.

The specific implementation method nine:

the embodiment is described below with reference to fig. 1-19, and the embodiment further describes an eighth embodiment, where the storage box 11 is fixedly connected to a magnetic sieve pore ii 9-4, the magnetic sieve wheel ii 12 includes a magnetic sieve shaft ii 12-1, a magnetic sieve pulley ii 12-2, a magnetic sieve wheel body ii 12-3 and a magnet 12-4, the magnetic sieve shaft ii 12-1 is rotatably connected to the storage box 11, the magnetic sieve shaft ii 12-1 is fixedly connected to a magnetic sieve pulley ii 12-2, a magnetic sieve wheel body ii 12-3 and a magnet 12-4, the magnetic sieve pulley ii 12-2 and a driving pulley iv 8-4 are connected by belt transmission, a transmission ratio between the magnetic sieve pulley ii 12-2 and the driving pulley iv 8-4 is one, the magnetic sieve wheel body ii 12-3 and the magnet 12-4 are both located in the storage box 11, and the discharge chute 10-2 is communicated with the magnetic sieve pore i 9-3, the magnet 12-4 is located between 90 ° and 180 °.

The invention relates to a device for preparing feed by rice bran meal, which has the working principle that:

when in use, rice bran meal to be processed is placed in the feeding support 2 through the feeding port 2-1, the motor 3-1 is started, the output shaft of the motor 3-1 starts to rotate, and the output shaft of the motor 3-1 drives the tooth-missing gear 3-2 to rotate by taking the axis of the output shaft of the motor 3-1 as the center; the gear-missing gear 3-2 is in meshed transmission with the transmission gear I4-2, a half-circle of teeth are arranged on the gear-missing gear 3-2, when the gear-missing gear 3-2 is in meshed transmission with the transmission gear I4-2, the gear-missing gear 3-2 and the transmission gear II 7-2 are out of meshed transmission, the gear-missing gear 3-2 drives the transmission gear I4-2 to rotate, the transmission gear I4-2 drives the transmission shaft I4-1 to rotate by taking the axis of the transmission shaft I4-1 as the center, and the transmission shaft I4-1 drives the transmission belt pulley I4-3 and the transmission belt pulley II 4-4 to rotate by taking the axis of the transmission shaft I4-1 as; the transmission belt wheel II 4-4 drives the feeding belt wheel I5-2 to rotate by taking the self axis as the center, the feeding belt wheel I5-2 drives the feeding screw shaft 5-1 to rotate by taking the self axis as the center, the transmission belt wheel I4-3 drives the feeding belt wheel II 6-2 to rotate by taking the self axis as the center, the feeding belt wheel II 6-2 drives the feeding cylinder body 6-1 to rotate by taking the self axis as the center, the rotating directions of the feeding screw body 6-3 and the feeding screw shaft 5-1 are the same, the transmission ratio between the feeding belt wheel II 6-2 and the transmission belt wheel I4-3 is larger than that between the feeding belt wheel I5-2 and the transmission belt wheel II 4-4, the rotating directions of the feeding screw shaft 5-1 and the feeding screw body 6-3 are the same, and the differential speed is formed between the feeding screw shaft 5-1 and the, the rice bran meal in the feeding screw shaft 5-1 and the feeding screw 6-3 is crushed and ground, and the rice bran meal can be pushed into the discharging groove 10-2 by paying attention to the mutual matching of the rotation direction of the feeding screw shaft 5-1 and the feeding screw 6-3 and the rotation direction of the feeding screw shaft 5-1 and the feeding screw 6-3; when the transmission gear II 7-2 and the gear with missing teeth 3-2 are in meshing transmission, the gear with missing teeth 3-2 and the transmission gear I4-2 are out of meshing transmission, the feeding mechanism 5 does not push rice bran meal into the discharging groove 10-2, the reference circle diameter of the transmission gear II 7-2 is half of the reference circle diameter of the gear with missing teeth 3-2, the gear with missing teeth 3-2 rotates for one circle, the transmission gear II 7-2 drives the transmission shaft II 7-1 to rotate for one circle by taking the axis of the transmission gear II 7-2 as the center, the transmission shaft II 7-1 drives the transmission conical tooth I7-3 to rotate for one circle by taking the axis of the transmission conical tooth I7-3 as the center, the transmission conical tooth I7-3 drives the transmission conical tooth II 8-2 to rotate for one circle by taking the axis of the transmission conical tooth II 8-2 as the center, the transmission conical tooth II 8-2 drives the transmission, the transmission shaft III 8-1 drives the transmission belt wheel III 8-3 and the transmission belt wheel IV 8-4 to rotate for one circle by taking the self axis as the center, and the transmission belt wheel III 8-3 and the transmission belt wheel IV 8-4 respectively drive the corresponding magnetic sieve wheel I10 and the corresponding magnetic sieve wheel II 12 to rotate for one circle by taking the self axis as the center; as shown in fig. 13, the magnetic sieve holes i 9-3, the magnetic sieve holes ii 9-4, the magnetic sieve holes iii 9-5 and the magnetic sieve holes iv 9-6 are sequentially and circumferentially and uniformly arranged on the magnetic sieve cylinder 9-2, and the magnetic sieve holes i 9-3, the magnetic sieve holes ii 9-4, the magnetic sieve holes iii 9-5 and the magnetic sieve holes iv 9-6 are separated by 90 degrees; as shown in fig. 15, during installation of the device, the discharging groove 10-2 is communicated with the magnetic sieve pore I9-3, rice bran can fall into the discharging groove 10-2 through the magnetic sieve pore I9-3, the difference between the discharging groove 10-2 and one end of the discharging pore 10-3 is 90 degrees, when the magnetic sieve wheel body I10-1 rotates for a circle, the magnetic sieve wheel body I10-1 drives the discharging groove 10-2 and the discharging pore 10-3 to rotate for a circle, when the magnetic sieve wheel body I10-1 rotates clockwise for 90 degrees, the discharging groove 10-2 is superposed with the magnetic sieve pore II 9-4, as shown in fig. 19, during installation, the magnet 12-4 is positioned between 90 degrees and 180 degrees, when the magnet 12-4 rotates clockwise for 90 degrees, the discharging groove 10-2 is superposed with the magnetic sieve pore II 9-4, the magnet 12-4 sucks the iron product in the discharging groove 10-2 into the storage box 11, when the magnetic sieve wheel body I10-1 rotates clockwise for 180 degrees, the magnetic sieve holes I9-3 and the magnetic sieve holes II 9-4 coincide, when the magnet 12-4 rotates clockwise for 180 degrees, the magnet 12-4 cannot continuously generate suction to iron products in the storage box 11, the iron products fall through the discharge holes 10-3 under the action of gravity and fall off from the magnetic sieve holes IV 9-6, rice bran meal in the magnetic separation finished discharging groove 10-2 is communicated with the magnetic sieve holes III 9-5 when the magnetic sieve wheel body I10-1 rotates clockwise for 180 degrees, and falls off from the magnetic sieve holes III 9-5.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides an utilize rice bran dregs preparation fodder equipment, includes device support (1), pan feeding support (2), power unit (3), drive mechanism I (4), feeding mechanism (5), a pay-off section of thick bamboo (6), drive mechanism II (7), drive mechanism III (8), magnetism sieve support (9), magnetism reel I (10), containing box (11) and magnetism reel II (12), its characterized in that: the feeding support (2) is fixedly connected to the device support (1), the power mechanism (3) is fixedly connected to the device support (1), the transmission mechanism I (4) is rotatably connected to the device support (1), the transmission mechanism I (4) and the feeding mechanism (5) are in gear meshing transmission, the feeding mechanism (5) is rotatably connected to the feeding support (2), the feeding mechanism (5) and the transmission mechanism I (4) are in belt transmission connection, the feeding barrel (6) is rotatably connected to the feeding support (2), the feeding barrel (6) and the transmission mechanism I (4) are in belt transmission connection, the transmission mechanism II (7) is rotatably connected to the device support (1), the transmission mechanism II (7) and the feeding mechanism (5) are in gear meshing transmission, the transmission mechanism III (8) and the transmission mechanism II (7) are in gear meshing transmission, the magnetic sieve support (9) is fixedly connected to the device support (1), the magnetic sieve wheel I (10) is rotatably connected in the magnetic sieve support (9), the magnetic sieve wheel I (10) is connected with the transmission mechanism III (8) through belt transmission, the containing box (11) is fixedly connected on the magnetic sieve support (9), the magnetic sieve wheel II (12) is rotatably connected in the containing box (11), the magnetic sieve wheel II (12) is connected with the transmission mechanism III (8) through belt transmission, the transmission ratio between the transmission mechanism II (7) and the magnetic sieve wheel I (10) is one, the transmission ratio between the transmission mechanism II (7) and the magnetic sieve wheel II (12) is one, and the heating device is arranged in the feeding barrel (6);

the device support (1) comprises a support plate (1-1) and support frames (1-2), the support frames (1-2) are fixedly connected to two sides of the rear end of the support plate (1-1), a feeding port (2-1) is formed in the feeding support (2), and the feeding support (2) is fixedly connected to the support plate (1-1);

the power mechanism (3) comprises a motor (3-1) and a tooth-missing gear (3-2), the tooth-missing gear (3-2) is fixedly connected to an output shaft of the motor (3-1), a half-circle of teeth are arranged on the tooth-missing gear (3-2), and the motor (3-1) is fixedly connected to the supporting plate (1-1);

the transmission mechanism I (4) comprises a transmission shaft I (4-1), a transmission gear I (4-2), a transmission belt wheel I (4-3) and a transmission belt wheel II (4-4), the middle part of the transmission shaft I (4-1) is fixedly connected with the transmission belt wheel I (4-3), two ends of the transmission shaft I (4-1) are respectively and fixedly connected with the transmission gear I (4-2) and the transmission belt wheel II (4-4), the transmission gear I (4-2) and the tooth-missing gear (3-2) are in meshing transmission, and the transmission shaft I (4-1) is rotatably connected to the support plate (1-1);

the feeding mechanism (5) comprises a feeding screw shaft (5-1) and a feeding belt wheel I (5-2), the feeding screw shaft (5-1) is rotatably connected to the feeding support (2), the feeding belt wheel I (5-2) is fixedly connected to the feeding screw shaft (5-1), the feeding belt wheel I (5-2) is in belt transmission connection with a transmission belt wheel II (4-4), the feeding barrel (6) comprises a feeding barrel body (6-1), a feeding belt wheel II (6-2) and a feeding spiral body (6-3), the feeding belt wheel II (6-2) is fixedly connected to the outer side of the feeding barrel body (6-1), the feeding belt wheel II (6-2) is in belt transmission connection with the transmission belt wheel I (4-3), the feeding spiral body (6-3) is arranged on the inner side of the feeding barrel body (6-1), the spiral directions of the feeding spiral body (6-3) and the feeding spiral shaft (5-1) are the same, and the transmission ratio between the feeding belt wheel II (6-2) and the transmission belt wheel I (4-3) is larger than the transmission ratio between the feeding belt wheel I (5-2) and the transmission belt wheel II (4-4);

the transmission mechanism II (7) comprises a transmission shaft II (7-1), a transmission gear II (7-2) and a transmission bevel gear I (7-3), the transmission shaft II (7-1) is rotatably connected to the support plate (1-1), two ends of the transmission shaft II (7-1) are respectively and fixedly connected with the transmission gear II (7-2) and the transmission bevel gear I (7-3), the transmission gear II (7-2) and the tooth-lacking gear (3-2) are in meshing transmission, the reference circle diameter of the transmission gear II (7-2) is half of that of the tooth-lacking gear (3-2), the transmission mechanism III (8) comprises a transmission shaft III (8-1), a transmission bevel gear II (8-2), a transmission belt wheel III (8-3) and a transmission belt wheel IV (8-4), the transmission shaft III (8-1) is rotatably connected to the support plate (1-1), the middle part of the transmission shaft III (8-1) is fixedly connected with a transmission bevel gear II (8-2), and two ends of the transmission shaft III (8-1) are respectively and fixedly connected with a transmission belt wheel III (8-3) and a transmission belt wheel IV (8-4);

the magnetic sieve support (9) comprises a magnetic sieve side plate (9-1), a magnetic sieve cylinder (9-2), a magnetic sieve pore I (9-3), a magnetic sieve pore II (9-4), a magnetic sieve pore III (9-5) and a magnetic sieve pore IV (9-6), the two magnetic sieve side plates (9-1) are respectively fixedly connected to the two support frames (1-2), a magnetic sieve cylinder (9-2) is fixedly connected between the two magnetic sieve side plates (9-1), a magnetic sieve pore I (9-3), a magnetic sieve pore II (9-4), a magnetic sieve pore III (9-5) and a magnetic sieve pore IV (9-6) are sequentially arranged on the magnetic sieve cylinder (9-2) in the circumferential direction, and the magnetic sieve pore I (9-3) is positioned below the outlet end of the feeding cylinder body (6-1);

the magnetic sieve wheel I (10) comprises a magnetic sieve wheel body I (10-1), a discharge groove (10-2), a discharge hole (10-3), a magnetic sieve shaft I (10-4) and a magnetic sieve belt wheel I (10-5), the discharge groove (10-2) and the discharge hole (10-3) are arranged on the magnetic sieve wheel body I (10-1), the two sides of the magnetic sieve wheel body I (10-1) are fixedly connected with the magnetic sieve shaft I (10-4), the two magnetic sieve shafts I (10-4) are respectively and rotatably connected onto the two support frames (1-2), one magnetic sieve shaft I (10-4) is fixedly connected with the magnetic sieve belt wheel I (10-5), the magnetic sieve belt wheel I (10-5) and the transmission belt wheel III (8-3) are connected through belt transmission, the transmission ratio between the magnetic sieve belt wheel I (10-5) and the transmission belt wheel (8-3) is one, the transmission ratio between the transmission bevel gear II (8-2) and the transmission bevel gear I (7-3) is one;

the storage box (11) is fixedly connected to a magnetic sieve pore II (9-4), the magnetic sieve wheel II (12) comprises a magnetic sieve shaft II (12-1), a magnetic sieve belt wheel II (12-2), a magnetic sieve wheel body II (12-3) and a magnet (12-4), the magnetic sieve shaft II (12-1) is rotatably connected to the storage box (11), the magnetic sieve shaft II (12-1) is fixedly connected with the magnetic sieve belt wheel II (12-2), the magnetic sieve wheel body II (12-3) and the magnet (12-4), the magnetic sieve belt wheel II (12-2) and the transmission belt wheel IV (8-4) are connected through belt transmission, the transmission ratio between the magnetic sieve belt wheel II (12-2) and the transmission belt wheel IV (8-4) is one, and the magnetic sieve wheel body II (12-3) and the magnet (12-4) are both located in the storage box (11), when the feeding groove (10-2) is communicated with the magnetic sieve pore I (9-3), the magnet (12-4) is positioned between 90 degrees and 180 degrees.