CN110354712B

CN110354712B - Vitamin is feed mixing system in advance

Info

Publication number: CN110354712B
Application number: CN201910756261.9A
Authority: CN
Inventors: 吕国晓; 于洋; 杨在宾; 于培礼
Original assignee: Shandong Zhonggu Fodder Co ltd
Current assignee: Shandong Zhonggu Fodder Co ltd
Priority date: 2019-08-15
Filing date: 2019-08-15
Publication date: 2021-08-24
Anticipated expiration: 2039-08-15
Also published as: CN110354712A

Abstract

The invention aims to provide a vitamin premixing feeding and stirring system which is used for solving the technical problems of stirring of a vitamin mixture and convenience in detection and sampling. The device comprises a control system, and a stirring mechanism, an axial pushing mechanism, a sampling mechanism, a positioning acquisition mechanism, a sample plate shifting mechanism and a material plate switching mechanism which are electrically connected with the control system. The stirring mechanism is used for mixing and stirring the materials; the axial pushing mechanism is longitudinally arranged in the stirring mechanism and is used for axially pushing the materials so as to fully fuse the materials in the axial direction; the positioning acquisition mechanism is movably positioned and arranged in the stirring mechanism and is used for driving the sampling mechanism to carry out multi-point sampling at different points; the sampling mechanism is used for respectively placing materials at different point positions on the sample disc displacement mechanism; the sample tray displacement mechanism is used for containing a sample and transferring the sample to the material tray switching mechanism; the charging tray switching mechanism is used for transferring the sample to the outside of the stirring mechanism so as to facilitate sampling of workers.

Description

Vitamin is feed mixing system in advance

Technical Field

The invention relates to the technical field of stirring systems, in particular to a vitamin premixing feeding and stirring system.

Background

In the feed production industry, whether the mixture ratio of various components in the feed is scientific is the key point of the quality of the feed. After the feeds are mixed according to a certain proportion, the feeds are also required to be fully and uniformly stirred; if the stirring is not proper, the high-quality production requirement cannot be met. In the prior art, a stirrer is often adopted for stirring. However, the stirrer has the defect that the sample is not convenient enough to obtain, so that the uniformity of the stirred material cannot be accurately obtained.

Disclosure of Invention

The invention aims to provide a vitamin premixing feeding and stirring system which is used for solving the technical problems of stirring of a vitamin mixture and convenience in detection and sampling.

The technical scheme adopted by the invention for solving the technical problems is as follows:

a vitamin premixing feeding and stirring system comprises a stirring mechanism, a sampling mechanism, a positioning acquisition mechanism, a sample plate shifting mechanism and a material plate switching mechanism;

the stirring mechanism comprises a stirring shaft which is rotatably arranged in the stirring cavity, and a stirring rod is arranged on the stirring shaft;

the positioning acquisition mechanism comprises a positioning driving plate arranged on the inner cavity wall of the stirring cavity;

the sampling mechanism comprises a sampling seat, a lofting motor, a sampling arm and a sampling cavity, the sampling seat is arranged on the positioning drive plate, the lofting motor is transversely arranged on the sampling seat, and the rotary power output end of the lofting motor is connected with the sampling arm; the sampling cavity is arranged at the outer end of the sampling arm;

the sample disc shifting mechanism comprises a sample containing plate, a sample disc moving sliding block and a sample disc moving bottom plate, the sample disc moving bottom plate is axially installed on the inner cavity wall of the stirring cavity, and the sample disc moving sliding block is movably installed on the sample disc moving bottom plate; the upper end of the sample disc moving slide block is transversely provided with a first switching guide rail, the lower end of the sample containing plate is provided with a switching chute, and the sample containing plate is arranged on the first switching guide rail through the switching chute; a plurality of sample trays for containing samples are longitudinally arranged at the upper end of the sample containing plate; the sample disc is arranged corresponding to the sampling cavity;

the material tray switching mechanism comprises a switching driving oil cylinder, a second switching guide rail and a switching box; the cavity wall of the stirring cavity is provided with a switching window, the switching box is arranged at the outer end side of the switching window, and the second switching guide rail is transversely arranged at the bottom end in the switching box and corresponds to the first switching guide rail; the switching driving oil cylinder is arranged on the inner end side of the switching window, and the power output end of the switching driving oil cylinder is arranged corresponding to the sample containing plate.

Furthermore, a plurality of stirring rods are arranged and are respectively arranged on the outer side of the stirring shaft along the axial direction; the lengths of the stirring rods are different.

Furthermore, the stirring shaft adopts a hollow shaft structure, and a pushing chute is longitudinally arranged on the side of the stirring shaft and communicated with the inner cavity of the stirring shaft; the stirring shaft is provided with an axial pushing mechanism;

the axial pushing mechanism comprises a pushing screw rod, a pushing motor, a pushing nut and a pushing plate, the pushing screw rod is rotatably arranged in a cavity of the stirring shaft, and the rotary power output end of the pushing motor is connected with the rotary power input end of the pushing screw rod; the pushing nut is screwed on the pushing screw rod, the pushing plate can be axially movably arranged on the pushing chute, and the inner end of the pushing plate is connected with the pushing nut.

Furthermore, an electromagnetic valve for controlling the opening and closing of the sampling cavity is arranged on the sampling cavity.

Furthermore, a positioning guide groove is longitudinally formed in the positioning driving plate, a positioning seat is slidably mounted in the positioning guide groove, and a positioning second driving oil cylinder is arranged at the power input end of the positioning seat; the positioning seat is provided with a positioning motor, and the vertical rotating power output end of the positioning motor is provided with the sampling seat.

Furthermore, one side of the positioning driving plate is connected with the stirring cavity in a swinging mode through a positioning first driving oil cylinder.

Furthermore, the first positioning driving oil cylinder adopts an oil cylinder with a displacement sensor arranged inside.

Furthermore, a power source of the sample disc moving slide block adopts a stepping motor.

Further, a photoelectric sensor is arranged in the sample disc.

Furthermore, a switching proximity switch is arranged at the switching window.

The effect provided in the summary of the invention is only the effect of the embodiment, not all the effects of the invention, and one of the above technical solutions has the following advantages or beneficial effects:

1. according to the invention, the stirring rods with different lengths are arranged on the stirring shaft, and the material pushing plate capable of moving axially is arranged on the stirring shaft, so that the materials can be separated and mixed in the stirring process.

2. The sampling mechanism is matched with the positioning acquisition mechanism, so that sampling of a plurality of different points in the stirring cavity can be realized, and the sampling scientificity is ensured. The sample plate shifting mechanism is matched with the material plate switching mechanism, so that a sample from the sampling mechanism can be smoothly shifted out of the stirring cavity body, and the sample plate is convenient for detection personnel to take.

Drawings

FIG. 1 is a schematic side view of an embodiment of the present invention;

FIG. 2 is a schematic sectional view taken along line A-A in FIG. 1;

FIG. 3 is an enlarged view of a portion of FIG. 2;

FIG. 4 is an enlarged view of a portion of FIG. 2 at B;

FIG. 5 is a schematic side view of the embodiment of the present invention showing the fitting relationship between the stirring shaft and the stirring rod;

FIG. 6 is a schematic side view of the sampling mechanism and the positioning and acquiring mechanism according to the embodiment of the present invention;

FIG. 7 is a schematic side view of a sample plate displacement mechanism according to an embodiment of the present invention;

in the figure: 1. a stirring motor; 2. a stirring cavity; 3. a stirring shaft; 4. a stirring rod; 5. a pushing chute; 6. a pushing screw; 7. a material pushing motor; 8. a pusher nut; 9. a material pushing plate; 10. positioning the driving plate; 11. positioning a first driving oil cylinder; 12. positioning a second driving oil cylinder; 13. positioning a motor; 14. positioning seats; 15. a positioning guide groove; 16. a sampling seat; 17. a lofting motor; 18. a sampling arm; 19. a sampling cavity; 20. an electromagnetic valve; 21. a sample containing plate; 22. a sample disk moving motor; 23. a sample disc moving screw rod; 24. moving a screw by a sample plate; 25. a sample disk moving slide block; 26. a sample plate moving bottom plate; 27. a first transfer rail; 28. a sample tray; 29. a photosensor; 30. the switching driving oil cylinder; 31. a transfer proximity switch; 32. a second transfer rail; 33. a junction box; 34. a switching window; 35. and a control box.

Detailed Description

In order to clearly explain the technical features of the present invention, the following detailed description of the present invention is provided with reference to the accompanying drawings. It should be noted that the components illustrated in the figures are not necessarily drawn to scale. Descriptions of well-known components and techniques are omitted so as to not unnecessarily limit the invention.

As shown in fig. 1 to 7, a vitamin premixing feeding and stirring system comprises a control system, and a stirring mechanism, an axial pushing mechanism, a sampling mechanism, a positioning and obtaining mechanism, a sample plate shifting mechanism and a material plate switching mechanism which are electrically connected with the control system. The stirring mechanism is used for mixing and stirring the materials; the axial pushing mechanism is longitudinally arranged in the stirring mechanism and is used for axially pushing the materials so as to fully fuse the materials in the axial direction; the positioning acquisition mechanism is movably positioned and arranged in the stirring mechanism and is used for driving the sampling mechanism to carry out multi-point sampling at different points; the sampling mechanism is used for respectively placing materials at different point positions on the sample disc displacement mechanism; the sample tray displacement mechanism is used for containing a sample and transferring the sample to the material tray switching mechanism; the charging tray switching mechanism is used for transferring the sample to the outside of the stirring mechanism so as to facilitate sampling of workers.

The stirring mechanism comprises a stirring motor 1, a stirring cavity 2, a stirring shaft 3 and a stirring rod 4. The upper end and the lower end of the stirring cavity 2 are respectively provided with a feeding pipe and a discharging pipe, and the feeding pipe and the discharging pipe are respectively provided with an electric control valve. The stirring shaft 3 is rotatably arranged in the stirring cavity 2, the stirring shaft 3 adopts a hollow rotating shaft, and pushing sliding grooves 5 are arranged on the two longitudinal sides of the stirring shaft 3 and communicated with the inner cavity of the stirring shaft. Stirring motor 1 installs the one end outside stirring cavity 2, and stirring motor 1's rotatory power output end is connected with the rotatory power input of (mixing) shaft 3. The stirring rods 4 are arranged in a plurality, are respectively arranged on the outer side of the stirring shaft 3 along the axial direction, and are arranged at intervals with the pushing sliding chute 5. The length of stirring rod 4 differs to carry out the diversified stirring in space to the material. The axial pushing mechanism is arranged in the cavity of the stirring shaft 3 and comprises a pushing screw rod 6, a pushing motor 7, a pushing nut 8 and a pushing plate 9. The pushing screw 6 is rotatably arranged in the cavity of the stirring shaft 3, and the rotary power input end of the pushing motor 7 is connected with the rotary power input end of the pushing screw 6; the pushing nut 8 is screwed on the pushing screw rod 6, the pushing plate 9 is mounted on the pushing chute 5 in an axially movable manner, and the inner end of the pushing plate 9 is connected with the pushing nut 8. In the process of stirring the materials along with the stirring mechanism in the circumferential direction, the axial pushing mechanism can move the materials in the axial direction, so that the materials are stirred and mixed uniformly and fully.

The positioning acquisition mechanism is arranged on the inner cavity wall of the stirring cavity 2 in a folding manner and comprises a positioning driving plate 10, a positioning first driving oil cylinder 11 (an oil cylinder with a displacement sensor arranged therein), a positioning second driving oil cylinder 12 (an oil cylinder with a displacement sensor arranged therein), a positioning motor 13 and a positioning seat 14. The rear end of the positioning driving plate 10 is hinged with the stirring cavity 2, and a positioning guide groove 15 is arranged on the positioning driving plate 10 in the longitudinal direction; the rear end of the first positioning driving oil cylinder 11 is hinged with the stirring cavity 2, and the outer end of the first positioning driving oil cylinder 11 is hinged with the positioning driving plate 10. The positioning seat 14 is slidably mounted in the positioning guide groove 15, the positioning second driving oil cylinder 12 is mounted at the rear end of the positioning guide groove 15, and the power end of the positioning second driving oil cylinder 12 is connected with the positioning seat 14; the positioning motor 13 is mounted on the positioning seat 14. The sampling mechanism comprises a sampling seat 16, a lofting motor 17, a sampling arm 18, a sampling cavity 19 and a solenoid valve 20. The sample seat 16 is arranged on the power output end of the upper end of the positioning motor 13, the lofting motor 17 is transversely arranged on the sample seat 16, and the rotary power output end of the lofting motor 17 is connected with the sampling arm 18. The sampling cavity 19 is arranged at the outer end of the sampling arm 18, and the electromagnetic valve 20 is arranged at the upper end of the sampling cavity 19. When sampling, the positioning acquisition mechanism drives the sampling mechanism to sequentially move to different positions in the stirring cavity 2 for sampling for multiple times, and then the acquired samples are sequentially placed on the sample plate shifting mechanism. During sampling, the electromagnetic valve 20 is opened, and after the sample enters the sampling cavity 19, the electromagnetic valve 20 is closed. After the sampling cavity 19 moves to the position of the sample plate shifting mechanism, the lofting motor 17 drives the sampling cavity 19 to overturn through the sampling arm 18, then the electromagnetic valve 19 is opened, and the sample falls onto the sample plate shifting mechanism.

The sample plate shift mechanism includes a sample plate 21, a sample plate moving motor 22 (stepping motor), a sample plate moving screw 23, a sample plate moving screw 24, a sample plate moving slider 25, and a sample plate moving base plate 26. The sample plate moving bottom plate 26 is axially installed on the wall of the inner cavity of the stirring cavity 2, a sample plate moving sliding groove is formed in the longitudinal extending direction of the sample plate moving bottom plate 26, and the sample plate moving sliding block 25 is slidably installed in the sample plate moving sliding groove. The sample plate moving screw rod 23 is rotatably arranged along the longitudinal direction of the sample plate moving bottom plate 26, and the rotary power input end of the sample plate moving screw rod 23 is connected with the rotary power output end of the sample plate moving motor 22; the sample plate moving screw nut 24 is screwed on the sample plate moving screw rod 23 in a matching manner, and the sample plate moving screw nut 24 is connected with the sample plate moving slide block 25. A first transfer guide rail 27 is transversely arranged at the upper end of the sample disc moving slide block 25, a transfer chute is arranged at the lower end of the sample containing plate 21, and the sample containing plate 21 is arranged on the first transfer guide rail 27 through the transfer chute; a plurality of sample trays 28 for holding samples are longitudinally arranged at the upper end of the sample holding plate 21 (photoelectric sensors 29 are arranged in the sample trays 28). In the process of lofting from the sampling mechanism to the sample plate shifting mechanism, the sample plate moving motor 22 drives the sample containing plate 21 to move longitudinally through the sample plate moving screw rod 23, and material samples of different sampling points are placed in different sample plates 28. When the sample plate 28 contains the material sample, the sample plate moving motor 22 drives the sample containing plate 21 to the material plate switching mechanism.

The tray switching mechanism comprises a switching driving oil cylinder 30, a switching proximity switch 31, a second switching guide rail 32 and a switching box 33. The wall of the stirring cavity 2 is provided with a switching window 34, the switching box 33 is arranged at the outer end side of the switching window 34, and the upper end of the switching box 33 is provided with a sampling cover plate; the second switching guide rail 32 is transversely arranged at the bottom end in the switching box 33 and is arranged corresponding to the first switching guide rail 27, and the inner end of the second switching guide rail 32 extends into the switching window 34. The transit proximity switch 31 is installed at one side of the transit window 34 and used for detecting whether the sample plate 21 moves to a designated position at the transit window 34. The switching driving oil cylinder 30 is arranged at the inner end side of the switching window 34 through a bracket, and a push plate is arranged at the power output end of the switching driving oil cylinder 30; when the sample containing plate 21 moves to the switching window 34, the switching driving oil cylinder 30 acts to drive the sample containing plate 21 into the switching box 33.

The control system comprises a control box 35, a control panel and a controller (51 single chip microcomputer or PLC), wherein the control box 35 is installed on the outer side of the stirring cavity 2, and the control panel and the controller are respectively installed on the control box 35 in an integrated mode. The signal input part of controller respectively with the photoelectric sensor 29 electricity in control panel, switching proximity switch 31, the sample dish 28 is connected, the signal output part of controller respectively with agitator motor 1, material pushing motor 7, the first actuating cylinder 11 of location, the second actuating cylinder 12 of location, location motor 13, lofting motor 17, solenoid valve 20, sample dish moving motor 22 and switching actuating cylinder 30 electricity are connected.

In addition to the technical features described in the specification, the technology is known to those skilled in the art.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, it is not intended to limit the scope of the present invention, and various modifications and variations can be made by those skilled in the art without inventive efforts based on the technical solution of the present invention.

Claims

1. A vitamin premixing feeding and stirring system is characterized by comprising a stirring mechanism, a sampling mechanism, a positioning acquisition mechanism, a sample plate shifting mechanism and a material plate switching mechanism;

the sampling mechanism comprises a sampling seat, a lofting motor, a sampling arm and a sampling cavity, the lofting motor is transversely arranged on the sampling seat, and the rotary power output end of the lofting motor is connected with the sampling arm; the sampling cavity is arranged at the outer end of the sampling arm;

the material tray switching mechanism comprises a switching driving oil cylinder, a second switching guide rail and a switching box; the cavity wall of the stirring cavity is provided with a switching window, the switching box is arranged at the outer end side of the switching window, and the second switching guide rail is transversely arranged at the bottom end in the switching box and corresponds to the first switching guide rail; the switching driving oil cylinder is arranged at the inner end side of the switching window, and the power output end of the switching driving oil cylinder is arranged corresponding to the sample containing plate;

a positioning guide groove is longitudinally formed in the positioning driving plate, a positioning seat is slidably mounted in the positioning guide groove, and a positioning second driving oil cylinder is arranged at a power input end of the positioning seat; a positioning motor is arranged on the positioning seat, and the sampling seat is arranged on the vertical rotating power output end of the positioning motor;

one side of the positioning driving plate is connected with the stirring cavity in a swinging mode through a positioning first driving oil cylinder.

2. The vitamin premix feed mixing system as in claim 1, wherein a plurality of said mixing rods are axially disposed outside said mixing shaft; the lengths of the stirring rods are different.

3. The vitamin premix feeding and stirring system as in claim 1, wherein the stirring shaft is of a hollow shaft structure, and a pushing chute is longitudinally arranged on the side of the stirring shaft and communicated with the inner cavity of the stirring shaft; the stirring shaft is provided with an axial pushing mechanism;

4. The vitamin premix feeding and stirring system as in claim 1, wherein the sampling chamber is provided with a solenoid valve for controlling the opening and closing of the sampling chamber.

5. A vitamin premix feed blending system as in claim 1, wherein said positioning first actuating cylinder is a displacement sensor cylinder.

6. The vitamin premix feeding and stirring system as in claim 1, wherein the power source of the sample plate moving slide block is a stepping motor.

7. A vitamin premix feed mixing system as in claim 1 wherein a photosensor is located in said sample pan.

8. The vitamin premix feed blending system of claim 1, wherein the switching window is provided with a switching proximity switch.