CN112791652A - Vacuum stirring equipment capable of cooling - Google Patents

Abstract

The invention discloses a coolable vacuum stirring device, which comprises an outer coating, an inner cylinder, an upper sealing cover, pot lugs, a grinding homogenizer, an outer stirring frame, an inner stirring frame, a first driving mechanism and a second driving mechanism, wherein the outer coating is fixedly arranged on the pot lugs, the inner cylinder is arranged in the outer coating, the upper sealing cover is hermetically arranged on the inner cylinder, so that the inner cylinder forms a closed cavity, a feeding cover is arranged on the upper sealing cover, the outer stirring frame and the inner stirring frame are arranged in the inner cylinder and are driven to concentrically rotate by the first driving mechanism and the second driving mechanism respectively, the grinding homogenizer is arranged at the bottom of the inner cylinder and is connected with other devices and the upper sealing cover by pipelines respectively. The invention has the advantages of simple structure, convenient operation, less personnel demand and good stirring effect. The reverse motion of the inner stirring frame and the outer stirring frame is realized through the first driving mechanism and the second driving mechanism, so that the crushing and stirring of various mixtures are promoted, the crushing efficiency is high, and the quality is good; the vacuum operation does not change the chemical property of the product.

Description

Vacuum stirring equipment capable of cooling

Technical Field

The invention relates to the field of chemical material production, in particular to a vacuum stirring device capable of cooling.

Background

With the development of pharmaceutical, cosmetic and food industries, the technical requirements for emulsion production are continuously improved, and not only precise emulsification and grinding equipment but also matched stirring equipment are required, so that the quality requirements of product production can be met. The usual processes for liquids are of great importance. But explosion, fire, etc. are easily generated in these processes. And has toxic and corrosive media, which threatens the health of human body. And the field working environment is severe, which also influences the application range of the stirring equipment. Meanwhile, the requirements of the industries on production are accurate and reliable. Therefore, the design of the liquid stirring device is necessary!

Disclosure of Invention

Aiming at overcoming the defects in the prior art, the invention mainly aims to overcome the defects in the prior art and discloses a coolable vacuum stirring device which comprises an outer cladding layer, an inner cylinder body, an upper sealing cover, pot ears, a grinding homogenizer, an outer stirring frame, an inner stirring frame, a first driving mechanism and a second driving mechanism, the outer coating is fixedly arranged on the pot ears, the inner cylinder body is arranged in the outer coating, the upper sealing cover is arranged on the inner cylinder body in a sealing way, so that the inner cylinder body forms a closed cavity, the upper sealing cover is provided with a feeding cover, the outer stirring frame and the inner stirring frame are arranged in the inner cylinder body and are driven to concentrically rotate by the first driving mechanism and the second driving mechanism respectively, the grinding homogenizer is arranged at the bottom of the inner cylinder body and is respectively connected with other equipment and the upper sealing cover by pipelines.

Further, interior agitator frame sets up in the outer agitator frame, set up the first stirring vane of a plurality of from top to bottom in the outer agitator frame inboard, the interior agitator frame outside sets up a plurality of first stirring vane, and outer agitator frame with interior agitator frame first stirring vane is cross arrangement.

Furthermore, a plurality of liquid through holes are formed in the first stirring blade.

Furthermore, a plurality of auxiliary stirring blades are arranged on the outer side of the outer stirring frame along the edge of the outer stirring frame.

Further, the included angle alpha between the first stirring blade and the outer stirring frame or the inner stirring frame is 30-60 degrees.

Further, the first driving mechanism comprises a first motor and a first speed reducer; the second driving mechanism comprises a second motor and a second speed reducer, an output shaft of the second speed reducer is sleeved outside an output shaft of the first speed reducer, the output shaft of the first speed reducer is connected with the inner stirring frame through a coupler, the first motor drives the first speed reducer to drive the inner stirring frame to rotate, the output shaft of the second speed reducer is connected with the outer stirring frame through a coupler, the second motor drives the second speed reducer to drive the outer stirring frame to rotate, and the rotation direction of the inner stirring frame is opposite to that of the outer stirring frame.

Further, the inner wall and the outer wall of the outer cladding are provided with cooling pipes in a surrounding mode, and the pipe openings are respectively formed above and below the outer cladding.

Furthermore, a plurality of functional holes are arranged on the upper sealing cover.

Furthermore, the two sides below the rotating shaft of the outer stirring frame are respectively provided with a lifting blade which is inclined up and down.

The invention has the following beneficial effects:

the invention has the advantages of simple structure, convenient operation, less personnel demand and good stirring effect. The reverse motion of the inner stirring frame and the outer stirring frame is realized through the first driving mechanism and the second driving mechanism, so that the crushing and stirring of various mixtures are promoted, the crushing efficiency is high, and the quality is good; the vacuum operation is carried out, so that the product is not contacted by external substances, and the chemical property of the product is not changed; design the multiple entry structure, get and put convenient and fast, save time raises the efficiency.

Drawings

FIG. 1 is a schematic perspective view of a coolable vacuum stirring apparatus of the present invention;

FIG. 2 is a top view of FIG. 1;

FIG. 3 is a cross-sectional view A-A of FIG. 2;

FIG. 4 is a front view of FIG. 1;

FIG. 5 is a cross-sectional view B-B of FIG. 4;

FIG. 6 is a schematic view of the functional hole distribution of the upper cover;

the reference numbers are as follows:

21. outer cladding, 22, inner cylinder, 23, upper cover, 24, pot handle, 25, grinding homogenizer, 26, outer stirring frame, 27, inner stirring frame, 28, first driving mechanism, 29, second driving mechanism, 31, first stirring vane, 32, liquid through hole, 33, auxiliary stirring vane, 34, lifting vane, 281, first motor, 282, first speed reducer, 291, second motor, 292, second speed reducer.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be further described in detail with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

A coolable vacuum stirring device is shown in figures 1-5 and comprises an outer cladding layer 21, an inner cylinder 22, an upper sealing cover 23, pot lugs 24, a grinding homogenizer 25, an outer stirring frame 26, an inner stirring frame 27, a first driving mechanism 28 and a second driving mechanism 29, wherein the outer cladding layer 21 is fixedly arranged on the pot lugs 24, the inner cylinder 22 is arranged in the outer cladding layer 21, the upper sealing cover 23 is hermetically arranged on the inner cylinder 22, so that the inner cylinder 22 forms a closed cavity, and a feeding cover is arranged on the upper sealing cover 23, so that a worker can rapidly feed semi-finished materials (powder and/or liquid) into the inner cylinder 22. The outer stirring frame 26 and the inner stirring frame 27 are arranged in the inner cylinder 22, the outer stirring frame 26 and the inner stirring frame 27 are driven to concentrically rotate by a first driving mechanism 28 and a second driving mechanism 29 respectively, and the grinding homogenizer 25 is arranged at the bottom of the inner cylinder 22 and is respectively connected with other equipment and the upper sealing cover 25 by pipelines. The grinding homogenizer 25 may be one described in CN105214807B, a grinding disperser. In use, the first driving mechanism 28 drives the inner stirring frame 27 to rotate, and at the same time, the first driving mechanism 29 drives the outer stirring frame 26 to rotate, so that the outer stirring frame 26 and the inner stirring frame 27 can rotate in the same direction, or in opposite directions, so that the materials in the inner cylinder 22 collide with each other.

In one embodiment, as shown in fig. 1 to 5, the inner stirring frame 27 is disposed inside the outer stirring frame 26, the plurality of first stirring blades 31 are disposed on the inner side of the outer stirring frame 27, the plurality of first stirring blades 31 are disposed on the outer side of the inner stirring frame 27, and the outer stirring frame 26 and the first stirring blades 31 of the inner stirring frame 27 are disposed in a crossing manner. By the arrangement of the first stirring blade 31, the contact area with the material is increased to promote the dispersive mixing of the material. In addition, if the mixer is used in a forward and reverse rotation mode, namely the rotation directions of the outer stirring frame 26 and the inner stirring frame 27 are opposite, the working chamber and the two stirring blades 31 collide with each other to shear, so that the materials are smashed under the mixing condition. Specifically, the first stirring blade 31 is provided with a plurality of liquid through holes 32, and in this embodiment, the first stirring blade 31 is uniformly provided with 8 liquid through holes 32. When the outer stirring frame 26 and the inner stirring frame 27 rotate, part of materials reversely rotate at the same speed through the 8 liquid through holes 32 of the first stirring blades 31 of the inner stirring frame and the outer stirring frame, and the liquids in the two directions collide with each other after encountering each other, so that the stirring and mixing effects are achieved. In addition, when the rotation directions of the outer and inner racks 26 and 27 are opposite to each other, the mutual collision and shearing of the materials are further promoted to promote the mixing of the materials.

In the above embodiment, as shown in fig. 1 to 5, the angle α between the first agitating blade 31 and the outer agitating frame 26 or the inner agitating frame 27 is 30 ° to 60 °. The first stirring blades 31 are horizontally and obliquely arranged, so that the first stirring blades rotate to stir the materials to one side, and the first stirring blades 31 of the outer stirring frame 26 and the inner stirring frame 27 are alternately arranged to further promote the materials to be fully mixed.

In one embodiment, as shown in FIGS. 1-5, the outer side of the outer agitator frame 26 is provided with a plurality of auxiliary agitating blades 33 along the edge thereof. The outer stirring frame 26 is in a rotary type, and the auxiliary stirring blades 33 drive the materials to collide and shear with the inner wall of the inner cylinder 22, so that the materials are fully mixed and smashed.

In one embodiment, as shown in fig. 1-5, lifting blades 34 are provided on both sides of the lower portion of the rotating shaft of the outer mixing frame 26, and are inclined upward and downward to promote mixing of the bottom material.

In one embodiment, as shown in fig. 1-5, the first drive mechanism 28 includes a first motor 281, a first speed reducer 282; the second driving mechanism 29 includes a second motor 291 and a second speed reducer 292, an output shaft of the second speed reducer 292 is sleeved outside an output shaft of the first speed reducer 282, the output shaft of the first speed reducer 282 is connected with the inner stirring frame 27 through a coupler, the first motor 281 is driven to drive the first speed reducer so as to drive the inner stirring frame 27 to rotate, the output shaft of the second speed reducer 292 is connected with the outer stirring frame 26 through a coupler, the second motor 291 is used to drive the second speed reducer 292 to drive the outer stirring frame 26 to rotate, and the rotation directions of the inner stirring frame 27 and the outer stirring frame 26 are opposite. Among them, the coupling preferably uses a spline type coupling. To increase its transmission torque.

In one embodiment, as shown in FIGS. 1-5, cooling tubes are circumferentially disposed on the inner and outer walls of the overwrap 21, and nozzles are disposed above and below the overwrap, respectively. Because some materials have high temperature requirements, the temperature of the inner cylinder 22 needs to be controlled, temperature data is acquired by a temperature sensor, and the cooling pipe is controlled to work. When the working environment is too low, water vapor is introduced through the upper pipe orifice and can heat the materials in the inner cylinder 22, so that the activity of emulsion is increased, the stirring resistance is reduced, and the water vapor is cooled and becomes liquid to flow out from the lower pipe orifice; when the working environment is overheated, the liquid in the container is added to be stirred at a high speed to generate heat, the emulsion needs to be cooled, cooling water is injected through the pipe orifice at the lower part, and the cooling water flows out from the pipe orifice at the upper part to form a circulating system.

In one embodiment, the upper cover 23 is provided with a plurality of functional holes. As shown in fig. 6, 8 functional holes are disposed on the upper sealing cover 23, wherein, hole a is a fixing device, hole b can be externally connected with a fast-assembly perfume hole, hole c is a hole-in sight glass, hole d is a feed hole, hole e is a pressure gauge hole, hole f is a sight glass lamp socket, hole g is a vacuum hole, and hole j is a spare hole.

When the grinding and stirring device 2 is used, as shown in figures 1-6, powder spice is added through the hole b, emulsion is added through the hole d, air in the container is vacuumized through a vacuum machine connected through the hole g through the hole c, the inner pot is vacuumized to 0.08MPa, the oxidation of the emulsion is prevented, the pressure in the container is observed through a pressure gauge connected through the hole e, and an automatic pressure relief device is arranged to prevent the safety accident caused by overhigh pressure in the container; the liquid of the inner cylinder 22 enters the grinding homogenizer 25 under the action of the vacuum suction force and gravity of the grinding homogenizer 25, the emulsion is further ground, the ground emulsion flows into the inner cylinder 22 again through a pipeline to be mixed, stirred and smashed until the grinding effect is achieved, and then the materials are conveyed into the downward moving equipment through the grinding homogenizer 25 through a switching pipeline.

The above are merely preferred embodiments of the present invention, and are not intended to limit the scope of the invention; it is intended that the following claims be interpreted as including all such alterations, modifications, and equivalents as fall within the true spirit and scope of the invention.

Claims (9)

1. The utility model provides a can refrigerated vacuum stirring equipment which characterized in that, includes surrounding layer, interior barrel, upper cover, pot ear, grinds isotropic symmetry, outer stirring frame, interior stirring frame, first actuating mechanism and second actuating mechanism, the surrounding layer is fixed to be set up on the pot ear, interior barrel sets up in the surrounding layer, the upper cover is sealed to be set up on the interior barrel for interior barrel forms airtight cavity, set up on the upper cover and throw the material lid, outer stirring frame with interior stirring frame sets up in the inner tube, utilize respectively first actuating mechanism with its concentric rotation of second actuating mechanism drive, it sets up in the bottom of interior barrel to grind isotropic symmetry, utilize the pipeline respectively with other equipment with upper cover is connected.

2. The coolable vacuum mixer according to claim 1, wherein the inner mixer is disposed inside the outer mixer, a plurality of first mixing blades are disposed on the inner side of the outer mixer, a plurality of first mixing blades are disposed on the outer side of the inner mixer, and the first mixing blades of the outer mixer and the first mixing blades of the inner mixer are disposed in a crossing manner.

3. A coolable vacuum mixer apparatus as claimed in claim 2, wherein said first mixing blade is provided with a plurality of through holes.

4. A coolable vacuum mixer apparatus as claimed in claim 1, wherein the outer side of said outer agitator frame is provided with a plurality of auxiliary agitating blades along the edge thereof.

5. A coolable vacuum mixer according to claim 2, wherein the angle α between the first mixing blade and the outer or inner mixing frame is between 30 ° and 60 °.

6. A coolable vacuum stirring apparatus as claimed in claim 3, wherein said first driving mechanism comprises a first motor, a first reducer; the second driving mechanism comprises a second motor and a second speed reducer, an output shaft of the second speed reducer is sleeved outside an output shaft of the first speed reducer, the output shaft of the first speed reducer is connected with the inner stirring frame through a coupler, the first motor drives the first speed reducer to drive the inner stirring frame to rotate, the output shaft of the second speed reducer is connected with the outer stirring frame through a coupler, the second motor drives the second speed reducer to drive the outer stirring frame to rotate, and the rotation direction of the inner stirring frame is opposite to that of the outer stirring frame.

7. The coolable vacuum mixer of claim 1 wherein cooling tubes are circumferentially disposed on the inner and outer walls of the envelope and nozzles are disposed above and below the envelope.

8. A coolable vacuum mixer apparatus as claimed in claim 1, wherein said upper cover is provided with a plurality of functional holes.

9. The coolable vacuum mixer according to claim 1, wherein the outer agitator has elevating blades inclined upward and downward at both sides below the rotation axis.

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