CN214759000U

CN214759000U - Probiotics sustained-release devices

Info

Publication number: CN214759000U
Application number: CN202121189814.6U
Authority: CN
Inventors: 郑燕萍
Original assignee: Guangzhou Kangbeile Biotechnology Co ltd
Current assignee: Guangzhou Kangbeile Biotechnology Co ltd
Priority date: 2021-05-28
Filing date: 2021-05-28
Publication date: 2021-11-19
Anticipated expiration: 2031-05-28

Abstract

The utility model discloses a probiotic slow release device, which comprises a shell, a slow release cylinder, a probiotic particle supply device, a first liquid containing box, a second liquid containing box and a rotating device; the probiotic particle supply device, the first liquid containing tank and the second liquid containing tank are all positioned in the shell; the lower end of the slow release cylinder is provided with a rotating shaft, the rotating shaft is rotatably arranged in the shell, and the rotating device is used for driving the rotating shaft to rotate; the interior of the slow release cylinder is divided into a first slow release cavity and a second slow release cavity by the partition plate; the guiding blanking hopper of the probiotic particle feeding device, the guiding blanking hopper of the second liquid containing box and the guiding blanking hopper of the first liquid containing box are sequentially arranged along the rotating track of the slow release cylinder. The utility model discloses can carry out the slowly-releasing of benefit fungus simultaneously to two kinds of different liquid for use comparatively in a flexible way, and can raise the efficiency.

Description

Probiotics sustained-release devices

Technical Field

The utility model relates to a benefit fungus sustained-release devices that benefit.

Background

The existing probiotic slow-release device comprises a slow-release barrel, wherein a liquid inlet and a feed inlet are formed in the upper end of the slow-release barrel, and when the probiotic slow-release device is used, probiotic particles can enter the slow-release barrel through the feed inlet, liquid is introduced into the liquid inlet through the feed inlet, and the liquid is enabled to have probiotics after being subjected to slow release of the probiotics. But because the existing probiotic slow-release device can only carry out probiotic slow release on a single liquid at each time, the use is limited, the efficiency is low, and the industrial requirements can not be met.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to provide a probiotic slow release device, which can simultaneously carry out probiotic slow release for two different liquids, so that the use is more flexible and the efficiency can be improved.

The purpose of the utility model is realized by adopting the following technical scheme:

a probiotic slow-release device comprises a shell, a slow-release cylinder, a probiotic particle supply device, a first liquid containing box, a second liquid containing box and a rotating device; the probiotic particle supply device, the first liquid containing tank and the second liquid containing tank are all positioned in the shell; the lower end of the slow release cylinder is provided with a rotating shaft, the rotating shaft is rotatably arranged in the shell, and the rotating device is used for driving the rotating shaft to rotate; the interior of the slow release cylinder is divided into a first slow release cavity and a second slow release cavity by the partition plate; the upper end of the slow release cylinder is provided with a first feed inlet communicated with the first slow release cavity and a second feed inlet communicated with the second slow release cavity; the lower ends of the probiotic particle supply device, the first liquid containing tank and the second liquid containing tank are respectively provided with a guide blanking hopper, and the guide blanking hopper of the probiotic particle supply device, the guide blanking hopper of the second liquid containing tank and the guide blanking hopper of the first liquid containing tank are sequentially arranged along the rotating track of the slow release cylinder; the guide of first appearance liquid case is hopper down be used for leading the liquid of first appearance liquid case into first feed inlet, the guide of second appearance liquid case is hopper down be used for leading the liquid of second appearance liquid case into the second feed inlet.

And a first electromagnetic valve is arranged at each guide discharging hopper.

The probiotic particle feeding device comprises a feeding box, a spiral propelling shaft and a driving assembly, wherein the spiral propelling shaft is rotatably arranged in the feeding box; the guiding blanking hopper of the probiotic particle feeding device is arranged at the bottom of the feeding box and is communicated with the interior of the feeding box.

The feeding hopper is arranged at the bottom of the front end of the feeding box, the feeding hopper communicated with the inside of the feeding box is arranged at the top of the rear end of the feeding box, and a through hole opposite to the feeding hopper is arranged at the top of the shell.

The driving assembly comprises a first driving belt wheel, a second driving belt wheel, a first power part and a conveying belt, wherein the first driving belt wheel and the second driving belt wheel are connected to the spiral propelling shaft; the central axis of the second driving belt wheel is parallel to the central axis of the first driving belt wheel; the conveying belt is wound on the first conveying belt wheel and the second conveying belt wheel.

The first power part is a first driving motor, a machine body of the first driving motor is fixed on the feeding box, and the second driving belt wheel is fixed on an output shaft of the first driving motor.

One end of the spiral propelling shaft is formed into a first mounting end, the other end of the spiral propelling shaft is formed into a second mounting end, a first bearing is mounted at the front end of the feeding box, a second bearing is mounted at the rear end of the feeding box, the first mounting end is fixedly inserted into an inner ring of the first bearing, the second mounting end is fixedly inserted into an inner ring of the second bearing, the first mounting end further penetrates out of the feeding box, and the first driving belt wheel is fixed at a position, extending out of the feeding box, of the first mounting end.

The rotating device comprises a first bevel gear fixed on the rotating shaft, a second bevel gear meshed with the first bevel gear and a second power component used for driving the second bevel gear to rotate; the central axis of the first bevel gear is perpendicular to the central axis of the second bevel gear.

The second power part is a second motor, and the second bevel gear is fixed on an output shaft of the second motor.

A first liquid outlet connecting pipe communicated with the first slow release cavity and a second liquid outlet connecting pipe communicated with the second slow release cavity are arranged at the lower end of the slow release cylinder; the casing is also provided with a window which is used for facing the lower end of the slow release cylinder.

Compared with the prior art, the beneficial effects of the utility model reside in that:

the utility model provides a pair of benefit fungus sustained-release devices, it is through adopting the casing, a slowly-releasing section of thick bamboo, benefit fungus granule feeding device, first appearance liquid case, the second holds the liquid case, and rotary device's combination design, it rotates together with a slowly-releasing section of thick bamboo to drive the axis of rotation through utilizing rotary device, thereby benefit fungus granule is sent into respectively to usable benefit fungus granule feeding device toward the first slowly-releasing chamber and the second slowly-releasing chamber of a slowly-releasing section of thick bamboo, and let in liquid toward first slowly-releasing intracavity through first appearance liquid case, the second holds the liquid case and lets in other liquid toward second slowly-releasing intracavity, thereby can carry out benefit fungus slowly-releasing simultaneously to two kinds of different liquid, make to use comparatively nimble, and can raise the efficiency.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the present invention in a state where the housing is separated;

fig. 3 is another schematic view of the present invention in the separated state of the housing;

fig. 4 is an exploded view of the present invention;

FIG. 5 is a schematic structural view of a sustained release cartridge;

10. a housing; 11. a window; 20. a slow release cartridge; 21. a rotating shaft; 22. a first sustained release chamber; 23. a second sustained release chamber; 24. a first feed port; 25. a second feed port; 26. a feed hopper; 27. a first liquid outlet connecting pipe; 28. a second liquid outlet connecting pipe; 30. a probiotic particle supply; 31. guiding the blanking hopper; 32. a feeding box; 33. a screw propulsion shaft; 41. a first liquid tank; 42. a second liquid containing tank; 50. a rotating device; 51. a first bevel gear; 52. a second bevel gear; 53. a second power component; 60. a drive assembly; 61. a first drive pulley; 62. a second drive pulley; 63. a first power component; 64. a conveyor belt; 71. an upper bearing; 72. a lower bearing; 73. and (7) sealing the cover.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and the detailed description, and it should be noted that the embodiments or technical features described below can be arbitrarily combined to form a new embodiment without conflict.

As shown in fig. 1 to 5, a probiotic slow-release device comprises a housing 10, a slow-release cartridge 20, a probiotic granule supply device 30, a first liquid containing tank 41, a second liquid containing tank 42, and a rotating device 50; the probiotic particle supply device 30, the first liquid containing tank 41 and the second liquid containing tank 42 are all positioned in the machine shell 10; the lower end of the slow release cylinder 20 is provided with a rotating shaft 21, the rotating shaft 21 is rotatably installed in the casing 10, and the rotating device 50 is used for driving the rotating shaft 21 to rotate; a partition board is arranged in the slow release cylinder 20, and the interior of the slow release cylinder 20 is divided into a first slow release cavity 22 and a second slow release cavity 23 through the partition board; the upper end of the slow release barrel 20 is provided with a first feed port 24 communicated with the first slow release cavity 22 and a second feed port 25 communicated with the second slow release cavity 23; the lower ends of the probiotic particle supply device 30, the first liquid containing tank 41 and the second liquid containing tank 42 are all provided with a guiding discharge hopper 31, and the guiding discharge hopper 31 of the probiotic particle supply device 30, the guiding discharge hopper 31 of the second liquid containing tank 42 and the guiding discharge hopper 31 of the first liquid containing tank 41 are sequentially arranged along the rotation track of the slow release cylinder 20; the guiding blanking hopper 31 of the first liquid containing box 41 is used for guiding the liquid of the first liquid containing box 41 into the first feed opening 24, and the guiding blanking hopper 31 of the second liquid containing box 42 is used for guiding the liquid of the second liquid containing box 42 into the second feed opening 25. Specifically, the guiding discharge hopper 31 of the probiotic particle supply device 30 is spaced 90 ° from the guiding discharge hopper 31 of the second liquid containing tank 42, the guiding discharge hopper 31 of the second liquid containing tank 42 is spaced 90 ° from the guiding discharge hopper 31 of the first liquid containing tank 41, and the first feed opening 24 is spaced 90 ° from the second feed opening 25.

When in use, different liquids (such as purified water and milk) are respectively contained in the first liquid containing tank 41 and the second liquid containing tank 42, then the rotating device 50 drives the rotating shaft 21 and the slow release cylinder 20 to rotate forward, when the first feeding port 24 rotates to the guiding blanking hopper 31 right opposite to the probiotic particle supply device 30, the probiotic particle supply device 30 works, and the probiotic particles are fed into the first slow release cavity 22 through the first feeding port 24, then the rotating device 50 drives the rotating shaft 21 to rotate forward continuously, when the second feeding port 25 rotates to the guiding blanking hopper 31 right opposite to the probiotic particle supply device 30, the probiotic particle supply device 30 works, and the probiotic particles are fed into the second slow release cavity 23 through the second feeding port 25, then the rotating shaft 21 is driven to rotate forward continuously through the rotating device 50, so that the first feeding port 24 is right opposite to the guiding blanking hopper 31 of the first liquid containing tank 41, the second feed inlet 25 is just being hopper 31 under the guide of second appearance liquid case 42, at this moment, lets in liquid through first appearance liquid case 41 toward first slowly-releasing chamber 22 in, and the second appearance liquid case 42 lets in other liquid toward second slowly-releasing chamber 23 to can carry out the probiotic slowly-releasing simultaneously in two kinds of different liquid, make to use comparatively nimble, and need not to wait that one of them liquid carries out again after the probiotic slowly-releasing to another liquid and carry out the probiotic slowly-releasing, can raise the efficiency.

Each guide discharging hopper 31 is provided with a first electromagnetic valve, so that the opening and closing of the guide discharging hopper 31 can be conveniently controlled through the first electromagnetic valve.

The probiotic particle feeding device 30 comprises a feeding box 32, a spiral propelling shaft 33 which is rotatably arranged in the feeding box 32, and a driving component 60 for driving the spiral propelling shaft 33 to rotate; the guiding discharge hopper 31 of the probiotic particle supply device 30 is arranged on the bottom of the feeding box 32 and is communicated with the interior of the feeding box 32. In use, the driving assembly 60 drives the screw propulsion shaft 33 to rotate, so that the probiotic particles can be propelled forward by the screw propulsion shaft 33.

The guiding blanking hopper 31 of the probiotic particle supply device 30 is arranged at the bottom of the front end of the feeding box 32, the feeding hopper 26 communicated with the interior of the feeding box 32 is arranged at the top of the rear end of the feeding box 32, and the top of the casing 10 is provided with a through hole opposite to the feeding hopper 26, so that probiotic particles can be supplied into the feeding hopper 26 through the through hole and enter the feeding box 32 through the feeding hopper 26. Specifically, a cover 73 for closing the through hole is hinged on the top of the housing 10, so that when probiotic particles are not needed to be supplied, the through hole can be closed by the cover 73, and dust and the like can be prevented from entering the feeding box 32.

The driving assembly 60 comprises a first driving pulley 61, a second driving pulley 62, a first power part 63 for driving the second driving pulley 62 to rotate, and a transmission belt 64, which are connected to the auger shaft 33; the central axis of the second driving pulley 62 is parallel to the central axis of the first driving pulley 61; the belt 64 is wound around the first pulley 61 and the second pulley 62. In use, the second driving pulley 62 is driven by the first power member 63 to rotate the first driving pulley 61 via the transmission belt 64 to rotate the auger shaft 33. By adopting the structure, the positions of the parts can be conveniently and reasonably arranged, so that the structure is more compact, the space can be saved, and the volume of the casing 10 is reduced.

The first power part 63 is a first driving motor, the body of the first driving motor is fixed on the feeding box 32, and the second driving belt wheel 62 is fixed on the output shaft of the first driving motor, so as to facilitate installation. Specifically, the body of the first drive motor is fixed to the top of the feed box 32.

One end of the spiral propelling shaft 33 is a first mounting end, the other end of the spiral propelling shaft is a second mounting end, a first bearing is mounted at the front end of the feeding box 32, a second bearing is mounted at the rear end of the feeding box, the first mounting end is fixedly inserted into an inner ring of the first bearing, the second mounting end is fixedly inserted into an inner ring of the second bearing, the first mounting end further penetrates out of the feeding box 32, and the first driving belt wheel 61 is fixed on a position of the first mounting end extending out of the feeding box 32, so that the spiral propelling shaft 33 can rotate more smoothly.

The rotating device 50 comprises a first bevel gear 51 fixed on the rotating shaft 21, a second bevel gear 52 meshed with the first bevel gear 51, and a second power part 53 for driving the second bevel gear 52 to rotate; the central axis of the first bevel gear 51 is perpendicular to the central axis of the second bevel gear 52. In use, the second power member 53 operates to rotate the second bevel gear 52, so as to rotate the first bevel gear 51 together with the rotating shaft 21.

The second power component 53 is a second motor, and the second bevel gear 52 is fixed on an output shaft of the second motor to facilitate installation.

Specifically, a transverse plate is arranged in the casing 10, an upper accommodating cavity is formed in an interval above the transverse plate of the casing 10, an upper accommodating cavity is formed in an interval below the transverse plate of the casing 10, the slow release cylinder 20, the probiotic particle supply device 30, the first liquid containing tank 41 and the second liquid containing tank 42 are all located in the upper accommodating cavity, the rotating device 50 is located in the upper accommodating cavity, an upper bearing 71 is further installed on the transverse plate, a lower bearing 72 is installed in the upper accommodating cavity, and the rotating shaft 21 is fixedly inserted in an inner ring of the upper bearing 71 and an inner ring of the lower bearing 72, so that the rotating shaft 21 can rotate more smoothly.

Specifically, rotating paddles may be further disposed in the first sustained release chamber 22 and the second sustained release chamber 23.

A first liquid outlet connecting pipe 27 communicated with the first slow release cavity 22 and a second liquid outlet connecting pipe 28 communicated with the second slow release cavity 23 are arranged at the lower end of the slow release cylinder 20; the casing 10 is further provided with a window 11 for facing the lower end of the slow release cylinder 20. Specifically, the first liquid outlet connecting pipe 27 and the second liquid outlet connecting pipe 28 are both provided with a second electromagnetic valve, and after the slow release of the probiotics is completed, the rotating shaft 21 is driven to rotate by the rotating device 50, so that the first liquid outlet connecting pipe 27 and the second liquid outlet connecting pipe 28 are close to the window 11, a first liquid through pipe can be connected to the first liquid outlet connecting pipe 27 through the window 11, a second liquid through pipe is connected to the second liquid outlet connecting pipe 28, and by opening the second electromagnetic valves of the first liquid outlet connecting pipe 27 and the second liquid outlet connecting pipe 28, the liquid in the first slow release cavity 22 can flow out through the first liquid through pipe, and the liquid in the second slow release cavity 23 can flow out through the second liquid through pipe. And third electromagnetic valves are arranged at the first feeding hole 24 and the second feeding hole 25.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention cannot be limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are all within the protection scope of the present invention.

Claims

1. A probiotic slow-release device, which is characterized in that: comprises a shell, a slow release cylinder, a probiotic particle supply device, a first liquid containing box, a second liquid containing box and a rotating device; the probiotic particle supply device, the first liquid containing tank and the second liquid containing tank are all positioned in the shell; the lower end of the slow release cylinder is provided with a rotating shaft, the rotating shaft is rotatably arranged in the shell, and the rotating device is used for driving the rotating shaft to rotate; the interior of the slow release cylinder is divided into a first slow release cavity and a second slow release cavity by the partition plate; the upper end of the slow release cylinder is provided with a first feed inlet communicated with the first slow release cavity and a second feed inlet communicated with the second slow release cavity; the lower ends of the probiotic particle supply device, the first liquid containing tank and the second liquid containing tank are respectively provided with a guide blanking hopper, and the guide blanking hopper of the probiotic particle supply device, the guide blanking hopper of the second liquid containing tank and the guide blanking hopper of the first liquid containing tank are sequentially arranged along the rotating track of the slow release cylinder; the guide of first appearance liquid case is hopper down be used for leading the liquid of first appearance liquid case into first feed inlet, the guide of second appearance liquid case is hopper down be used for leading the liquid of second appearance liquid case into the second feed inlet.

2. The probiotic slow release device of claim 1, characterized in that: and a first electromagnetic valve is arranged at each guide discharging hopper.

3. The probiotic slow release device of claim 1, characterized in that: the probiotic particle feeding device comprises a feeding box, a spiral propelling shaft and a driving assembly, wherein the spiral propelling shaft is rotatably arranged in the feeding box; the guiding blanking hopper of the probiotic particle feeding device is arranged at the bottom of the feeding box and is communicated with the interior of the feeding box.

4. The probiotic slow release device of claim 3, characterized in that: the feeding hopper is arranged at the bottom of the front end of the feeding box, the feeding hopper communicated with the inside of the feeding box is arranged at the top of the rear end of the feeding box, and a through hole opposite to the feeding hopper is arranged at the top of the shell.

5. The probiotic slow release device of claim 3, characterized in that: the driving assembly comprises a first driving belt wheel, a second driving belt wheel, a first power part and a conveying belt, wherein the first driving belt wheel and the second driving belt wheel are connected to the spiral propelling shaft; the central axis of the second driving belt wheel is parallel to the central axis of the first driving belt wheel; the conveying belt is wound on the first conveying belt wheel and the second conveying belt wheel.

6. The probiotic slow release device of claim 5, characterized in that: the first power part is a first driving motor, a machine body of the first driving motor is fixed on the feeding box, and the second driving belt wheel is fixed on an output shaft of the first driving motor.

7. The probiotic slow release device of claim 5, characterized in that: one end of the spiral propelling shaft is formed into a first mounting end, the other end of the spiral propelling shaft is formed into a second mounting end, a first bearing is mounted at the front end of the feeding box, a second bearing is mounted at the rear end of the feeding box, the first mounting end is fixedly inserted into an inner ring of the first bearing, the second mounting end is fixedly inserted into an inner ring of the second bearing, the first mounting end further penetrates out of the feeding box, and the first driving belt wheel is fixed at a position, extending out of the feeding box, of the first mounting end.

8. The probiotic slow release device of claim 1, characterized in that: the rotating device comprises a first bevel gear fixed on the rotating shaft, a second bevel gear meshed with the first bevel gear and a second power component used for driving the second bevel gear to rotate; the central axis of the first bevel gear is perpendicular to the central axis of the second bevel gear.

9. The probiotic slow release device of claim 8, characterized in that: the second power part is a second motor, and the second bevel gear is fixed on an output shaft of the second motor.

10. The probiotic slow release device of claim 1, characterized in that: a first liquid outlet connecting pipe communicated with the first slow release cavity and a second liquid outlet connecting pipe communicated with the second slow release cavity are arranged at the lower end of the slow release cylinder; the casing is also provided with a window which is used for facing the lower end of the slow release cylinder.