CN220386311U - Novel microorganism mixes device - Google Patents

Abstract

The utility model discloses a novel microorganism mixing device which comprises a tank body, wherein a discharging pipe is communicated with the left side of the tank body and near the bottom end of the tank body, a support is erected at the top end of the tank body, a positioning plate is fixed at the middle position of the support, a feeding pipe vertically penetrates through the positioning plate, a scattering frame is integrally communicated with the bottom end of the feeding pipe, a servo motor is arranged at the bottom end of the tank body, a rotating shaft is arranged in the tank body, the bottom end of the rotating shaft is fixedly connected with an output shaft of the servo motor, and stirring blades are fixed on the outer wall of the rotating shaft in the tank body at equal intervals. This novel microorganism mixing arrangement is through being provided with inlet pipe, pivot and scattering the frame when using, and when servo motor's output shaft rotated, it rotates to drive the frame that falls by the pivot, falls down with rotatory mode to the material of throwing into the frame that falls through scattering the frame rotation, realizes throwing in the material and stirs the processing, has improved material mixing uniformity.

Description

Novel microorganism mixes device

Technical Field

The utility model relates to the technical field of mixing, in particular to a novel microorganism mixing device.

Background

It is difficult for the naked eye to see, and all micro-organisms which can be observed by means of an optical microscope or an electron microscope are known. Microorganisms include bacteria, viruses, fungi, few algae, etc., but also some microorganisms are visible to the naked eye, such as ganoderma lucidum, lentinus edodes, etc., and when culturing or otherwise treating the microorganisms, a microorganism mixing device is used, through which the microorganisms are mixed.

When the microbial mixing device is used, microorganisms are put into the tank body on the microbial mixing device, the servo motor below the tank body is started, the output shaft of the servo motor drives the rotating shaft to rotate when rotating, and meanwhile the stirring blades rotate, so that the microorganisms put into the tank body can be stirred and mixed through the rotation of the stirring blades.

But before stirring and mixing the microorganism, the required materials are poured into the tank body, the servo motor is started again, the output shaft of the servo motor drives the rotating shaft to rotate, and the materials are stirred and mixed through the stirring blades, but as the materials are poured into the tank body in sequence, the same microorganism is piled up to occupy a large area, so that the microorganism is difficult to quickly perform the mixing treatment, and the mixing time is prolonged.

Disclosure of Invention

The utility model aims to provide a novel microorganism mixing device, which aims to solve the problems that in the prior art, the microorganism is difficult to quickly mix due to the fact that the materials are stacked and occupied by the same microorganism in a large area, and the mixing duration is prolonged because the materials are sequentially poured into the device, the novel microorganism mixing device is used, when the device is used, but before the microorganism is stirred and mixed, required materials are poured into a tank body, a servo motor is started, an output shaft of the servo motor drives a rotating shaft to rotate, and the materials are stirred and mixed through stirring blades.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a novel microorganism mixes device, includes the jar body, jar body left side and the position department intercommunication that is close to the bottom have the discharging pipe, the support has been erect on the top of jar body, and the intermediate position department of support is fixed with the locating plate, vertical the running through has the inlet pipe in the locating plate, and the inlet pipe bottom extends to jar internally to the bottom integration intercommunication of inlet pipe has the frame that spills, servo motor is installed to the bottom of jar body, the inside of jar body is provided with the pivot, and the output shaft fixed connection of pivot bottom and servo motor to pivot top and the fixed connection of frame bottom intermediate position department are located the equidistance of jar internal pivot and are fixed with the stirring leaf. When the output shaft of the servo motor rotates positively and negatively, the servo motor is arranged on the rotating shaft, meanwhile, the feeding pipe rotates, microorganisms are thrown into the feeding pipe, and then are scattered in a large-area scattering mode through the scattering frame, when the microorganisms are thrown into the tank body, scattering and mixing are carried out, so that the mixing uniformity is improved, and the mixing speed is improved.

Preferably, a top end fixing frame positioned on the feeding pipe upper support is provided with a feeding box, the bottom end of the feeding box is close to the top end of the feeding pipe, strip-shaped through holes are formed in two sides of the feeding box, and a screening net is transversely arranged in the feeding box in a penetrating mode through the strip-shaped through holes. Before the microorganisms are put into the tank body, the microorganisms with different thicknesses are subjected to screening treatment through a screening net.

Preferably, a rotating rod vertically rotates at a position close to the right side on the tank body, a first driving wheel is fixed at a position close to the bottom end of the rotating rod, a second driving wheel is fixed on the outer wall of the feeding pipe on the tank body, and a belt is sleeved outside the second driving wheel and the first driving wheel. The feeding pipe and the rotating rod form force transmission through the transmission wheel II, the transmission wheel I and the belt.

Preferably, the position that the bull stick just is close to the top is fixed with the gear, screening net right side integration is fixed with the pinion rack, and intermesh between pinion rack and the gear. The output shaft of the servo motor drives the gear to rotate when rotating in the forward and reverse directions, so that the toothed plate is driven to move left and right.

Preferably, the screening net forms a left-right reciprocating movement structure through the first driving wheel, the toothed plate, the second driving wheel, the gears, the rotating rods and the belt. The screening treatment of microorganisms is improved.

Preferably, the upper surface and the lower surface of the screening net are tightly attached to the strip-shaped through holes formed in the two sides of the material box. The microorganisms are prevented from accidentally flowing out of the strip-shaped through holes on the two sides of the feed box.

Preferably, the bottom end of the scattering frame is provided with discharge holes in an annular equidistant manner. So that the microorganisms are scattered in a large area.

Compared with the prior art, the utility model has the beneficial effects that:

(1) When the output shaft of the servo motor rotates, the rotating shaft drives the falling frame to rotate, and the falling frame rotates to drop materials put into the falling frame in a rotating mode, so that stirring treatment while putting the materials is realized, and the mixing uniformity of the materials is improved;

(2) When the microorganisms are put into the feed box, the filtering treatment is carried out through the screening net, the screening treatment is carried out on the microorganisms with larger particles and the fine microorganisms in the microorganisms through the filtering treatment, and the later-stage better mixing treatment is carried out on the microorganisms through the screening treatment;

(3) The first driving wheel, the second driving wheel, the gear and the toothed plate are arranged, when the feeding pipe rotates, the second driving wheel, the first driving wheel and the belt drive the rotating rod to rotate, and when the rotating rod reciprocally rotates, the screening net is driven to reciprocally move through the cooperation of the gear and the toothed plate, so that the microorganism filtering speed is improved.

Drawings

FIG. 1 is a left-hand structural schematic diagram of the present utility model;

FIG. 2 is a right side view of the present utility model;

FIG. 3 is a schematic view of a front partial cross-sectional structure of the present utility model;

FIG. 4 is an enlarged schematic view of the structure of FIG. 3A according to the present utility model;

fig. 5 is a schematic view of a partial perspective structure of the present utility model.

In the figure: 1. a tank body; 2. a positioning plate; 3. a feed pipe; 4. a feed box; 5. a bracket; 6. a discharge pipe; 7. a servo motor; 8. screening net; 9. a first driving wheel; 10. a toothed plate; 11. a second driving wheel; 12. a gear; 13. a rotating rod; 14. a belt; 15. stirring the leaves; 16. a rotating shaft; 17. and (5) scattering a falling frame.

Detailed Description

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

Referring to fig. 1-5, the present utility model provides a technical solution: the utility model provides a novel microorganism mixes device, includes a jar body 1, and jar body 1 left side just is close to the position department intercommunication of bottom and has discharging pipe 6, and the bottom is the slope setting to discharging pipe 6 direction in the jar body 1. The discharge pipe 6 is arranged obliquely, so that mixed microorganisms can be discharged from the tank 1. The top of the tank body 1 is erected with a support 5, a locating plate 2 is fixed at the middle position of the support 5, a preformed hole for the feeding pipe 3 to penetrate is vertically formed in the locating plate 2, the locating plate 2 plays a bearing role on the feeding pipe 3, and the height of the feeding pipe 3 is kept. The locating plate 2 is vertically penetrated with a feeding pipe 3, and the tank body 1 is provided with a hole for the feeding pipe 3 to penetrate. And the bottom end of the feeding pipe 3 extends into the tank body 1, and the bottom end of the feeding pipe 3 is integrally communicated with a scattering frame 17, and the front upper part of the feeding pipe 3 is arranged in a T shape. The servo motor 7 is installed to the bottom of jar body 1, and the inside of jar body 1 is provided with pivot 16, and the output shaft fixed connection of pivot 16 bottom and servo motor 7 to pivot 16 top and the intermediate position department fixed connection of falling frame 17 bottom, pivot 16 and falling frame 17 are welded connection, so that when servo motor 7 output shaft just reverses, drive falling frame 17 rotation, realize that the material evenly spills and falls the processing. Stirring blades 15 are fixed on the outer wall of a rotating shaft 16 in the tank body 1 at equal distance, and when the rotating shaft 16 rotates, the stirring blades 15 perform mixing treatment on microorganisms in the tank body 1 in a stirring mode. Wherein, the bottom of the scattering frame 17 is annular equidistant to leave and is provided with a discharge hole, so as to realize even scattering effect. Referring to fig. 1 and 3, when the servo motor 7 is started, the output shaft of the servo motor 7 drives the rotating shaft 16 to rotate when the output shaft of the servo motor 7 reciprocally rotates, and meanwhile, the dropping frame 17 rotates, and when the dropping frame 17 rotates, the feeding pipe 3 rotates. Referring to fig. 2-5, a feed box 4 is arranged on a top end fixing frame of a support 5 on a feed pipe 3, four groups of the support 5 are distributed on a tank body 1 at equal intervals along a vertical central line of the feed pipe 3, and the support 5 is symmetrically distributed on the vertical central lines of the feed pipe 3, the tank body 1 and the feed box 4 to bear the positioning plate 2 and the feed box 4. And the bottom end of the feed box 4 is close to the top end of the feed pipe 3, and strip-shaped through holes are formed in two sides of the feed box 4 and used for the penetration of the screening net 8. And the inside of the feed box 4 is transversely provided with a screening net 8 in a penetrating way through the strip-shaped through holes, and the transverse length of the screening net 8 is greater than that of the feed box 4. The tank body 1 is vertically rotated with a rotating rod 13 at a position close to the right side, a driving wheel I9 is fixed at a position close to the bottom end of the rotating rod 13, a driving wheel II 11 is fixed on the outer wall of the feeding pipe 3 on the tank body 1, a belt 14 is sleeved outside the driving wheel II 11 and the driving wheel I9, and the feeding pipe 3 and the rotating rod 13 form force transmission through the driving wheel II 11, the driving wheel I9 and the belt 14. Therefore, the driving source is reduced, and the energy-saving effect is achieved. The position department that bull stick 13 and are close to the top is fixed with gear 12, and screening net 8 right side integration is fixed with pinion rack 10, and intermeshes between pinion rack 10 and the gear 12, and pinion rack 10 reciprocating motion when reciprocating rotation is geared 12, and screening net 8 reciprocating motion realizes screening the processing to microorganism with the mode of rocking. Wherein, screening net 8 forms the left and right reciprocating motion structure through drive wheel 9, pinion rack 10, drive wheel two 11, gear 12, bull stick 13 and belt 14. In addition, the upper surface and the lower surface of the screening net 8 are tightly attached to the strip-shaped through holes formed in the two sides of the material box 4, so that microorganisms are prevented from accidentally flowing out of gaps between the screening net 8 and the material box 4. Referring to fig. 5, the feeding pipe 3 rotates, the driving wheel two 11, the belt 14 and the driving wheel one 9 drive the rotating rod 13, the gear 12 starts to rotate, the toothed plate 10 is triggered to rotate by the gear 12, and the screening net 8 moves reciprocally.

Working principle: when the screening device is used, the device is placed in a working area and is connected with an external power supply, then the servo motor 7 is started, when the output shaft of the servo motor 7 rotates in a reciprocating manner, the output shaft of the servo motor 7 drives the rotating shaft 16 to rotate, meanwhile, the scattering frame 17 rotates, when the scattering frame 17 rotates, the feeding pipe 3 rotates, the driving wheel II 11, the belt 14 and the driving wheel I9 drive the rotating rod 13, the gear 12 starts to rotate, the toothed plate 10 is triggered to rotate through the gear 12, and the screening net 8 moves in a reciprocating manner; the microorganisms to be mixed are then put into the feed box 4, are subjected to screening treatment by reciprocating movement of the screening net 8, fall into the feed pipe 3, enter the scattering frame 17, are scattered by the scattering frame 17, are subjected to mixing treatment by the stirring blades 15 while being scattered, and flow out of the tank 1 through the discharge pipe 6 after the mixing treatment.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a novel microorganism mixes device, includes jar body (1), its characterized in that: the utility model discloses a jar of jar body (1), including jar body (1), jar body (1) and jar body (1) are equipped with the support (5) in the top, and the intermediate position department of support (5) is fixed with locating plate (2), it has inlet pipe (3) to vertically run through in locating plate (2), and in inlet pipe (3) bottom extends to jar body (1) to the bottom integration intercommunication of inlet pipe (3) has spills frame (17), servo motor (7) are installed to the bottom of jar body (1), the inside of jar body (1) is provided with pivot (16), and the output shaft fixed connection of pivot (16) bottom and servo motor (7) to pivot (16) top and the intermediate position department fixed connection of the bottom of scattering frame (17) are located equidistance and are fixed with stirring leaf (15) on the outer wall of jar body (1) inner rotating shaft (16).

2. The novel microbiological mixing device of claim 1, wherein: the top mount that is located feed pipe (3) upper bracket (5) is equipped with workbin (4), and the top that is close to feed pipe (3) is located to workbin (4) bottom, bar through-hole has been opened to workbin (4) both sides, and the inside of workbin (4) transversely runs through bar through-hole and installs screening net (8).

3. A novel microbiological mixing device according to claim 2, wherein: the rotary rod (13) vertically rotates at the position close to the right side on the tank body (1), the first driving wheel (9) is fixed at the position close to the bottom end of the rotary rod (13), the second driving wheel (11) is fixed on the outer wall of the feeding pipe (3) on the tank body (1), and a belt (14) is sleeved outside the second driving wheel (11) and the first driving wheel (9).

4. A novel microbiological mixing device according to claim 3, wherein: the rotary rod (13) is fixed with a gear (12) at a position close to the top end, the right side of the screening net (8) is integrally fixed with a toothed plate (10), and the toothed plate (10) and the gear (12) are meshed with each other.

5. The novel microbial mixing device according to claim 4, wherein: the screening net (8) forms a left-right reciprocating movement structure through a first driving wheel (9), a toothed plate (10), a second driving wheel (11), a gear (12), a rotating rod (13) and a belt (14).

6. A novel microbiological mixing device according to claim 2, wherein: the upper surface and the lower surface of the screening net (8) are tightly attached to the strip-shaped through holes arranged on the two sides of the material box (4).

7. The novel microbiological mixing device of claim 1, wherein: the bottom of the scattering frame (17) is provided with discharge holes in an annular equidistant way.