CN112755880A

CN112755880A - Mixing arrangement for duck feed processing

Info

Publication number: CN112755880A
Application number: CN202110044171.4A
Authority: CN
Inventors: 周生会
Original assignee: Fengxian Xinzhongmu Feed Co ltd
Current assignee: Fengxian Xinzhongmu Feed Co ltd
Priority date: 2021-01-13
Filing date: 2021-01-13
Publication date: 2021-05-07
Anticipated expiration: 2041-01-13
Also published as: CN112755880B

Abstract

The invention discloses a mixing device for duck feed processing, which adopts a mixing box, and also comprises a grinding tank, a grinding block I, a grinding block II, a transmission mechanism, a stirrer I, a stirrer II and a feeding pipe; a grinding box and a stirring box are sequentially arranged in the mixing box from top to bottom; two grinding grooves are formed; the two grinding grooves are arranged on the bottom surface inside the grinding box; the two grinding grooves penetrate through the bottom of the grinding box and the top of the stirring box and are uniformly provided with a plurality of sieve pores; the grinding block I and the grinding block II are horizontally movably arranged in the corresponding grinding grooves through a transmission mechanism; the stirrer I and the stirrer II are symmetrically arranged in the stirring box through a transmission mechanism; the upper end surface of the mixing box is provided with a feed inlet which extends into the grinding box through a feed pipe; the bottom of the mixing box is provided with a discharge hole communicated with the stirring box; the invention can grind in advance and improve the mixing efficiency.

Description

Mixing arrangement for duck feed processing

Technical Field

The invention relates to the technical field of feed processing equipment, in particular to a mixing device for duck feed processing.

Background

Duck fodder need mix the raw materials in process of production, and the tradition mixes the leading-in container of raw materials that the machine will need to mix and stirs the mixture, and wherein the unable flash mixed of raw materials of large granule, big thing piece is even, often appears the caking, and the mixing quality is poor, inefficiency, consequently provides one kind can grind in advance, improves mixing efficiency's mixing arrangement for duck feed processing.

Disclosure of Invention

In view of the technical problems in the background art, the present invention provides a mixing device for duck feed processing, which can grind in advance and improve mixing efficiency. In order to achieve the purpose, the invention provides the following technical scheme:

a mixing device for duck feed processing adopts a mixing box, and further comprises a grinding tank, a grinding block I, a grinding block II, a transmission mechanism, a stirrer I, a stirrer II and a feeding pipe; a grinding box and a stirring box are sequentially arranged in the mixing box from top to bottom; the number of the grinding grooves is two; the two grinding grooves are arranged on the bottom surface inside the grinding box; a plurality of sieve pores which penetrate through the bottom of the grinding box and the top of the stirring box are uniformly distributed on the two grinding grooves; the grinding block I and the grinding block II are horizontally movably arranged in the corresponding grinding grooves through a transmission mechanism; the stirrer I and the stirrer II are rotatably arranged on the inner walls of the two sides of the stirring box through a transmission mechanism; the upper end surface of the mixing box is provided with a feed inlet, and the feed inlet extends into the grinding box through a feed pipe; and a discharge hole communicated with the stirring box is formed in the bottom of the mixing box.

The transmission mechanism comprises a driving wheel, a driven wheel I, a driven wheel II, a driven wheel III, a belt and a connecting assembly; the number of the connecting components is two; the driving wheel, the driven wheel I, the driven wheel II and the driven wheel III are all internally connected with a connecting frame I, and the circumferential outer side wall is provided with a clamping groove capable of containing a belt; the belt is annular and is sequentially connected with the driving wheel, the driven wheel II, the driven wheel I and the driven wheel III in series through clamping grooves of the driving wheel, the driven wheel II, the driven wheel I and the driven wheel III; the driving wheel and the driven wheel I are oppositely arranged in the mixing box and at the positions on two sides of the grinding box; one end of the driving shaft is rotatably arranged on the inner wall of one side of the mixing box through a motor, and the other end of the driving shaft is connected with the center of the driving wheel connecting frame I in a penetrating manner, extends into the grinding box and is connected with the grinding block I in a transmission manner through a connecting assembly; one end of the driven shaft I is rotatably connected with the inner wall of the other side of the mixing box, and the other end of the driven shaft I is connected with the center of the driven wheel I connecting frame I in a penetrating manner and is in transmission connection with the grinding block II through a connecting assembly; the driven wheel II and the driven wheel III are oppositely arranged in the mixing box and at the two ends of the stirring box; driven shaft II, III one end of driven shaft respectively with the mixing box both ends inner wall rotates to be connected, and the other end respectively through connection corresponds from driving wheel II and from the I center of driving wheel III link to stretch into the agitator tank and be connected with agitator I, agitator II that correspond.

The connecting assembly comprises a crank and a connecting rod; one end of the crank is fixedly connected with the corresponding driving shaft or driven shaft I; one end of the connecting rod is hinged with the other end of the corresponding crank, and the other end of the connecting rod is hinged with the corresponding grinding block I or grinding block II.

The stirrer I comprises a stirring shaft and a stirring blade I; the stirring shaft is detachably connected with the driven shaft II, and a plurality of stirring blades I are uniformly distributed on the stirring shaft;

the stirrer II comprises a stirring ring and a stirring blade II; a connecting frame II is connected in the stirring ring; the driven shaft III is connected with the center of the connecting frame II; a plurality of stirring blades II are uniformly distributed on the stirring ring close to the end face of the stirring shaft; and the motion space formed by the rotation of each stirring blade I along with the stirring shaft is positioned in each stirring blade II.

The feed pipe is in an inverted Y shape, two ports at the lower part are respectively arranged above the corresponding grinding grooves, and the upper port extends out of the grinding box and is communicated with the feed port.

And a liquid inlet communicated with the stirring box is formed in the outer wall of the mixing box.

And an observation window is arranged on the outer wall of the mixing box.

The invention has the beneficial effects that:

1. according to the invention, the grinding box and the stirring box are integrally arranged, so that a transmission mechanism can simultaneously control grinding and stirring, and time and labor are saved, and high-efficiency mixing is realized;

2. the driving wheel, the driven wheel II, the driven wheel I and the driven wheel III are sequentially connected in series through the annular belt, and the grinding and stirring mechanisms are simultaneously controlled;

3. the driving wheel and the driven wheel I which are symmetrically arranged on two sides of the grinding box rotate, so that the two cranks drive the two grinding blocks to grind the solid raw materials in a reciprocating manner through the connecting rods, and the grinding efficiency is improved;

4. ground raw materials smaller than the aperture of the sieve plate fall into the stirring box through the sieve plate, liquid raw materials are added into the liquid inlet, and the stirring blades which are uniformly arranged by the two symmetrically-arranged stirrers fully stir the solid-liquid food raw materials, so that the mixing range is enlarged, and the mixing efficiency and the mixing quality are greatly improved.

Drawings

FIG. 1 is a schematic view of the internal structure of the mixing box of the present invention;

FIG. 2 is a cross-sectional view A-A of FIG. 1 (with the feed tube omitted);

FIG. 3 is a sectional view taken along line B-B in FIG. 1 (with the inlet port omitted);

FIG. 4 is a schematic view of the structure of the transmission mechanism of the present invention;

FIG. 5 is a schematic view of the location structure of the stirring ring in FIG. 4;

in the figure, 1-mixing box, 2-belt, 3-driven wheel II, 301-clamping groove, 4-transmission mechanism, 5-stirring box, 6-driving wheel, 7-driving shaft, 8-motor, 9-crank, 10-connecting rod, 11-feeding pipe, 12-feeding hole, 13-grinding box, 14-grinding block II, 15-driven wheel I, 16-driven shaft I, 17-grinding groove, 1701-sieve hole, 18-liquid inlet, 19-connecting frame I, 20-driven shaft II, 21-discharging hole, 22-driven wheel III, 23-stirring ring, 24-connecting frame II, 25-driven shaft III, 26-stirring blade II, 27-stirring blade I, 28-stirring shaft, 29-stirring device I, 30-stirrer II, 31-connecting component, 32-grinding block I.

Detailed Description

Referring to fig. 1 to 5, a mixing device for duck feed processing, which adopts a mixing box 1, and further comprises a grinding tank 17, a grinding block i 32, a grinding block ii 14, a transmission mechanism 4, a stirrer i 29, a stirrer ii 30 and a feeding pipe 11; a grinding box 13 and a stirring box 5 are sequentially arranged in the mixing box 1 from top to bottom; two grinding grooves 17 are provided; the two grinding grooves 17 are arranged on the bottom surface inside the grinding box 13; two grinding grooves 17 penetrate through the bottom of the grinding box 13 and the top of the stirring box 5 and are uniformly distributed with a plurality of sieve holes 1701; the grinding block I32 and the grinding block II 14 are horizontally movably arranged in the corresponding grinding grooves 17 through the transmission mechanism 4; the stirrer I29 and the stirrer II 30 are rotatably and symmetrically arranged on the inner walls of the two sides of the stirring box 5 through the transmission mechanism 4; the upper end surface of the mixing box 1 is provided with a feed inlet 12, and the feed inlet 12 extends into a grinding box 13 through a feed pipe 11; the bottom of the mixing box 1 is provided with a discharge port 21 communicated with the stirring box 5.

As shown in fig. 4-5, the transmission mechanism 4 includes a driving wheel 6, a driven wheel i 15, a driven wheel ii 3, a driven wheel iii 22, a belt 2, and a connecting assembly 31; the number of the connecting components 31 is two; the driving wheel 6, the driven wheel I15, the driven wheel II 3 and the driven wheel III 22 are all internally connected with a connecting frame I19, and the circumferential outer side wall is provided with a clamping groove (taking the driven wheel II 3 as an example) 301 capable of accommodating a belt; the belt 2 is annular and is sequentially connected with the driving wheel 6, the driven wheel II 3, the driven wheel I15 and the driven wheel III 22 in series through clamping grooves 301 of the driving wheel 6, the driven wheel II 3, the driven wheel I15 and the driven wheel III 22; the driving wheel 6 and the driven wheel I15 are oppositely arranged in the mixing box 1 and at the positions on two sides of the grinding box 13; one end of a driving shaft 7 is rotatably arranged on the inner wall of one side of the mixing box 1 through a motor 8, and the other end of the driving shaft penetrates through the center of a connecting frame I19 of a driving wheel 6 and extends into the grinding box 13 to be in transmission connection with a grinding block I32 through a connecting component 31; one end of a driven shaft I16 is rotatably connected with the inner wall of the other side of the mixing box 1, and the other end of the driven shaft I16 is connected with the center of a driven wheel I15 connecting frame I19 in a penetrating way and is in transmission connection with a grinding block II 14 through a connecting component 31; the driven wheel II 3 and the driven wheel III 22 are oppositely arranged in the mixing box 1 and at the two ends of the stirring box 5; one end of each of the driven shafts II 20 and III 25 is rotatably connected with the inner walls of the two ends of the mixing box 1, and the other end of each of the driven shafts II 3 and III 22 is connected with the center of the corresponding driven wheel II 3 or driven wheel III 19 connecting frame I19 in a penetrating mode and extends into the stirring box 5 to be connected with the corresponding stirrer I29 and the corresponding stirrer II 30.

The connecting assembly 31 comprises a crank 9 and a connecting rod 10; one ends of the two cranks 9 are respectively and fixedly connected with the corresponding driving shaft 7 and the driven shaft I16; one end of each of the two connecting rods 10 is hinged to the other end of the corresponding crank 9, the other end of each of the two connecting rods is hinged to the corresponding grinding block I32 or the corresponding grinding block II 14, the two connecting rods 9 are similar to a crank rocker mechanism, the two cranks 7 are driven by the corresponding driving shafts 7 and the corresponding driven shafts I16 to do circular reciprocating motion, the corresponding grinding blocks I32 or the corresponding grinding blocks II 14 are driven by the connecting rods 10 to horizontally move along the length direction of the corresponding grinding grooves 17, and solid raw materials are ground.

The stirrer I29 comprises a stirring shaft 28 and a stirring blade I27; the stirring shaft 28 is detachably connected with the driven shaft II 20, and a plurality of stirring blades I27 are uniformly distributed on the stirring shaft 28; the stirrer II 30 comprises a stirring ring 23 and a stirring blade II 26; a connecting frame II 24 is connected in the stirring ring 23; the driven shaft III 25 is connected with the center of the connecting frame II 24; a plurality of stirring blades II 26 are uniformly distributed on the end face of the stirring ring 23 close to the stirring shaft 28; the motion space that each stirring vane I27 formed along with the rotation of (mixing) shaft 28 is located each stirring vane II 26, and driven shaft II 20 and driven shaft III 25 direction of rotation are opposite for stirring vane I27 on two agitators, II 26 directions of rotation of stirring vane are opposite, and mixing efficiency accelerates, and stirring vane II 26 is located I27 periphery side of stirring vane all the time, enlarges the mixing range.

The feeding pipe 11 is inverted Y-shaped, the two ports at the lower part are respectively arranged above the corresponding grinding grooves 17, the upper port extends out of the grinding box 13 and is communicated with the feeding port 12, and the solid raw materials respectively fall into the two grinding grooves 17 from the two ports at the lower part through the upper port of the feeding pipe.

The outer wall of the mixing box 1 is communicated with the stirring box 5, and a liquid inlet 18 is obliquely and inwards arranged for pouring liquid raw materials.

The outer wall of the mixing box 1 is provided with an observation window.

As shown in fig. 1-5, the working principle and flow of the present invention are as follows:

solid raw materials to be ground enter two grinding grooves 17 through a feed pipe 11 through a feed inlet 12, a motor 8 is started, a driving wheel 6 is driven by a driving shaft 7 to start rotating, the driving wheel 2 is driven by a belt 2 to enable a driven wheel II 3, a driven wheel I15 and a driven wheel III 22 to rotate together, the driving shaft 7 and the driven shaft I16 respectively drive a crank 9 to rotate, a corresponding grinding block I32 and a corresponding grinding block II 14 are driven by a connecting rod 10 to horizontally reciprocate along the corresponding grinding grooves 17, the solid raw materials are ground, and the ground raw materials smaller than the mesh aperture of a sieve plate 1701 fall into a stirring box 5 through sieve holes 1701; liquid raw materials are added into the liquid inlet 18, the driven shafts II 20 and III 25 respectively drive the stirring shaft 28 and the stirring ring 23 to rotate, and the solid-liquid raw materials are stirred and mixed in a reciprocating mode through the stirring blades I27 and the stirring blades II 26.

Claims

1. The utility model provides a mixing arrangement for duck feed processing, this mixing arrangement adopts mixing box, its characterized in that: the mixing device also comprises a grinding groove, a grinding block I, a grinding block II, a transmission mechanism, a stirrer I, a stirrer II and a feeding pipe; a grinding box and a stirring box are sequentially arranged in the mixing box from top to bottom; the number of the grinding grooves is two; the two grinding grooves are arranged on the bottom surface inside the grinding box; a plurality of sieve pores which penetrate through the bottom of the grinding box and the top of the stirring box are uniformly distributed on the two grinding grooves; the grinding block I and the grinding block II are horizontally movably arranged in the corresponding grinding grooves through a transmission mechanism; the stirrer I and the stirrer II are rotatably arranged on the inner walls of the two sides of the stirring box through a transmission mechanism; the upper end surface of the mixing box is provided with a feed inlet, and the feed inlet extends into the grinding box through a feed pipe; and a discharge hole communicated with the stirring box is formed in the bottom of the mixing box.

2. The mixing device for duck feed processing according to claim 1, wherein: the transmission mechanism comprises a driving wheel, a driven wheel I, a driven wheel II, a driven wheel III, a belt and a connecting assembly; the number of the connecting components is two; the driving wheel, the driven wheel I, the driven wheel II and the driven wheel III are all internally connected with a connecting frame I, and the circumferential outer side wall is provided with a clamping groove capable of containing a belt; the belt is annular and is sequentially connected with the driving wheel, the driven wheel II, the driven wheel I and the driven wheel III in series through clamping grooves of the driving wheel, the driven wheel II, the driven wheel I and the driven wheel III; the driving wheel and the driven wheel I are oppositely arranged in the mixing box and at the positions on two sides of the grinding box; one end of the driving shaft is rotatably arranged on the inner wall of one side of the mixing box through a motor, and the other end of the driving shaft is connected with the center of the driving wheel connecting frame I in a penetrating manner, extends into the grinding box and is connected with the grinding block I in a transmission manner through a connecting assembly; one end of the driven shaft I is rotatably connected with the inner wall of the other side of the mixing box, and the other end of the driven shaft I is connected with the center of the driven wheel I connecting frame I in a penetrating manner and is in transmission connection with the grinding block II through a connecting assembly; the driven wheel II and the driven wheel III are oppositely arranged in the mixing box and at the two ends of the stirring box; driven shaft II, III one end of driven shaft respectively with the mixing box both ends inner wall rotates to be connected, and the other end respectively through connection corresponds from driving wheel II and from the I center of driving wheel III link to stretch into the agitator tank and be connected with agitator I, agitator II that correspond.

3. The mixing device for duck feed processing according to claim 2, wherein: the connecting assembly comprises a crank and a connecting rod; one end of the crank is fixedly connected with the corresponding driving shaft or driven shaft I; one end of the connecting rod is hinged with the other end of the corresponding crank, and the other end of the connecting rod is hinged with the corresponding grinding block I or grinding block II.

4. The mixing device for duck feed processing according to claim 2, wherein: the stirrer I comprises a stirring shaft and a stirring blade I; the stirring shaft with driven shaft II can dismantle the connection, a plurality of stirring vane I of equipartition on this stirring shaft.

5. The mixing device for duck feed processing according to claim 4, wherein: the stirrer II comprises a stirring ring and a stirring blade II; a connecting frame II is connected in the stirring ring; the driven shaft III is connected with the center of the connecting frame II; a plurality of stirring blades II are uniformly distributed on the stirring ring close to the end face of the stirring shaft; and the motion space formed by the rotation of each stirring blade I along with the stirring shaft is positioned in each stirring blade II.

6. The mixing device for duck feed processing according to claim 1, wherein: the feed pipe is in an inverted Y shape, two ports at the lower part are respectively arranged above the corresponding grinding grooves, and the upper port extends out of the grinding box and is communicated with the feed port.

7. The mixing device for duck feed processing according to claim 1, wherein: and a liquid inlet communicated with the stirring box is formed in the outer wall of the mixing box.

8. The mixing device for duck feed processing according to claim 1, wherein: and an observation window is arranged on the outer wall of the mixing box.