CN219279841U - Autolysis mechanism for producing single cell protein - Google Patents

Abstract

The utility model discloses an autolysis mechanism for producing single-cell protein, which comprises a fixed bracket, wherein the top of the fixed bracket is fixedly connected with a main box body, two sides of the outer wall of the main box body are fixedly connected with a plurality of groups of air inlet structures, and two sides of the inner wall of the main box body are provided with a plurality of groups of autolysis heating structures corresponding to the air inlet structures; the tops of the multiple groups of autolysis heating structures are fixedly connected with multiple guide plates. According to the utility model, the multiple groups of cross-distributed autolysis heating structures are arranged on both sides of the inner wall of the main box body, so that the mixed solution can slowly flow downwards through the multiple groups of autolysis heating structures from top to bottom, the multiple cross-distributed guide plates arranged at the top of the multiple groups of autolysis heating structures can further have the guide and blocking effects on the flowing mixed solution, the mixed solution is further fully mixed in the flowing process, meanwhile, the time of the mixed solution in the main box body can be further prolonged, the heating time is further prolonged, and autolysis of strains in the mixed solution is accelerated.

Description

Autolysis mechanism for producing single cell protein

Technical Field

The utility model relates to the technical field of single-cell protein processing equipment, in particular to an autolysis mechanism for producing single-cell protein.

Background

The single cell protein is also called microbial protein, which is a microbial thallus artificially cultured by a plurality of industrial and agricultural wastes and petroleum wastes, is not a pure protein, but is a cytoplasmic group composed of protein, fat, carbohydrate, nucleic acid, nitrogen-containing compound which is not protein, vitamin, inorganic compound and the like; important among single cell proteins are yeast proteins, bacterial proteins and algal proteins, which are generally based on proteins and fats in their chemical composition.

The utility model of China with the patent number ZL201520232554.4 discloses autolysis equipment for producing single-cell protein, which comprises a belt wheel, a speed reducer, a transmission gear, a cover plate, a feed inlet, a heating hollow blade, a heat-insulating hollow blade, an overflow plate, a discharge outlet, a steam inlet and outlet, a motor, a main machine shell and a transmission main shaft, wherein the autolysis equipment can preheat materials before drying, improve the temperature before drying and reduce the production cost; the equipment has the advantages of quick temperature rise and easy control of temperature, but the structural design of the equipment is relatively complex, and the rotary stirring structure is driven by a motor and a transmission mechanism, so that a large amount of energy is wasted, the production and processing cost is not reduced, and meanwhile, the daily maintenance is not convenient.

It is therefore desirable to provide an autolysis mechanism for producing single cell proteins that addresses the above-described problems.

Disclosure of Invention

The technical problem to be solved by the utility model is that the structural design of the existing equipment is relatively complex, and the rotary stirring structure is required to be driven by a motor and a transmission mechanism, so that a large amount of energy is wasted, the production and processing cost is not reduced, and meanwhile, the daily maintenance is not convenient.

In order to solve the technical problems, the utility model adopts a technical scheme that: the utility model provides an autolysis mechanism for producing single-cell protein, which comprises a fixed bracket, wherein the top of the fixed bracket is fixedly connected with a main box body, the front end of the main box body is fixedly connected with a front heat-preserving cover plate, the rear end of the main box body is fixedly connected with a rear heat-preserving cover plate, and one side of the top of the main box body is provided with a feeding port;

multiple groups of air inlet structures are fixedly connected to two sides of the outer wall of the main box body, and multiple groups of autolysis heating structures corresponding to the air inlet structures are arranged on two sides of the inner wall of the main box body;

the top of multiunit autolyze heating structure all fixedly connected with a plurality of guide plates, multiunit autolyze heating structure all is provided with the water conservancy diversion mouth between one side of main tank body inner wall, the bottom fixedly connected with unloading return bend of main tank body outer wall one side.

The utility model is further provided with: the front heat-insulating cover plate and the rear heat-insulating cover plate are respectively fixed at the front end and the rear end of the main box body through a plurality of fixing screws.

Through above-mentioned technical scheme for preceding heat preservation apron and back heat preservation apron can realize stable sealed and fixed, also convenient to install simultaneously and dismantle.

The utility model is further provided with: and a feeding hole corresponding to the feeding hole is formed in one side of the top of the main box body.

Through above-mentioned technical scheme, the material can get into the loading hole through the feed inlet, then gets into in the main tank body.

The utility model is further provided with: the air inlet structure comprises a mounting seat, and an air inlet nozzle and an air outlet nozzle are respectively arranged on the outer side of the mounting seat.

Through the technical scheme, the air inlet nozzle is used for being connected with an external high-temperature steam pipe, the connected high-temperature steam is led into the corresponding autolyzed heating structure, and the steam subjected to heat exchange is discharged through the air outlet nozzle.

The utility model is further provided with: the multiple groups of autolysis heating structures are distributed on two sides of the inner wall of the main box body in a crossed manner.

Through the technical scheme, the multiple groups of autolysis heating structures which are distributed at two sides of the inner wall of the main box body in a crossing manner can play a role in heating autolysis and mixing of the introduced mixed culture solution and strains, the mixed solution slowly flows downwards from top to bottom through the multiple groups of autolysis heating structures after being introduced into the main box body through the feeding port, the top parts of the multiple groups of autolysis heating structures are also provided with the multiple cross-distributed guide plates, the multiple cross-distributed guide plates can further play a role in guiding and blocking the flowing mixed solution, the mixed solution can be further fully mixed in the flowing process, meanwhile, the time of the mixed solution in the main box body can be further prolonged, the heating time is further prolonged, and autolysis of the strains in the mixed solution is accelerated.

The utility model is further provided with: the autolyzing heating structure comprises a steam heating plate, wherein an air inlet pipeline and an air outlet pipeline are respectively arranged in the center of the steam heating plate, and an air inlet and an air outlet corresponding to the air inlet pipeline and the air outlet pipeline are respectively arranged on one side of the steam heating plate.

Through above-mentioned technical scheme, high temperature steam can get into the admission line through the air inlet, is the admission line that snakelike structure distributes and can evenly heat the steam heating board, and then evenly heats the mixed solution that flows its top through the steam heating board, and steam after the heat transfer can flow out the gas outlet through the gas outlet pipeline.

The utility model is further provided with: the air inlet pipeline is communicated with the air outlet pipeline.

Through the technical scheme, a complete heat exchange pipeline can be formed between the air inlet pipeline and the air outlet pipeline.

The utility model is further provided with: the air inlet and the air outlet are respectively communicated with the air inlet nozzle and the air outlet nozzle.

Through above-mentioned technical scheme for high temperature steam can get into the air inlet through the air inlet nozzle, and the cooled steam also can flow out the air outlet nozzle through the gas outlet after the pipe is hot.

The beneficial effects of the utility model are as follows:

1. according to the utility model, the multiple groups of cross-distributed autolysis heating structures are arranged on both sides of the inner wall of the main box body, so that the mixed solution can slowly flow downwards through the multiple groups of autolysis heating structures from top to bottom, the multiple cross-distributed guide plates arranged at the top of the multiple groups of autolysis heating structures can further have the guide and blocking effects on the flowing mixed solution, the mixed solution is further fully mixed in the flowing process, meanwhile, the time of the mixed solution in the main box body can be further prolonged, the heating time is further prolonged, and autolysis of strains in the mixed solution is accelerated;

2. according to the self-drainage structure, the whole mechanism does not need any driving structure, so that a large amount of energy sources can be saved, the production and processing cost is further reduced, meanwhile, the self-drainage structure is convenient for daily maintenance, and the working efficiency is greatly improved.

Drawings

FIG. 1 is a first view angle block diagram of the present utility model;

FIG. 2 is a second view angle block diagram of the present utility model;

FIG. 3 is an internal block diagram of the present utility model;

FIG. 4 is a front view of the present utility model;

fig. 5 is a cross-sectional view of an autolytic heating configuration of the utility model.

In the figure: 1. a fixed bracket; 2. a main case; 3. a front thermal insulation cover plate; 4. a rear heat-preserving cover plate; 5. a feeding port; 6. an air intake structure; 601. a mounting base; 602. an air inlet nozzle; 603. an air outlet nozzle; 7. an autolytic heating structure; 701. a steam heating plate; 702. an air intake duct; 703. an air outlet pipe; 704. an air inlet; 705. an air outlet; 8. a deflector; 9. a diversion port; 10. and (5) blanking the bent pipe.

Detailed Description

The preferred embodiments of the present utility model will be described in detail below with reference to the accompanying drawings so that the advantages and features of the present utility model can be more easily understood by those skilled in the art, thereby making clear and defining the scope of the present utility model.

Referring to fig. 1-5, an autolysis mechanism for producing single-cell protein comprises a fixing bracket 1, wherein the top of the fixing bracket 1 is fixedly connected with a main box body 2, the front end of the main box body 2 is fixedly connected with a front heat-insulation cover plate 3, the rear end of the main box body 2 is fixedly connected with a rear heat-insulation cover plate 4, and the front heat-insulation cover plate 3 and the rear heat-insulation cover plate 4 are respectively fixed at the front end and the rear end of the main box body 2 through a plurality of fixing screws, so that the front heat-insulation cover plate 3 and the rear heat-insulation cover plate 4 can realize stable sealing and fixing, and are convenient to install and detach;

a feeding hole 5 is formed in one side of the top of the main box body 2, a feeding hole corresponding to the feeding hole 5 is formed in one side of the top of the main box body 2, and materials can enter the feeding hole through the feeding hole 5 and then enter the main box body 2;

as shown in fig. 1, two sides of the outer wall of the main box body 2 are fixedly connected with a plurality of groups of air inlet structures 6, each air inlet structure 6 comprises a mounting seat 601, an air inlet nozzle 602 and an air outlet nozzle 603 are respectively arranged on the outer side of each mounting seat 601, each air inlet nozzle 602 is used for being connected with an external high-temperature steam pipe, the connected high-temperature steam is led into a corresponding autolyzed heating structure 7, and the steam subjected to heat exchange is discharged through the corresponding air outlet nozzle 603;

a plurality of groups of autolysis heating structures 7 corresponding to the air inlet structures 6 are arranged on two sides of the inner wall of the main box body 2; the multiple groups of autolysis heating structures 7 are distributed on two sides of the inner wall of the main box body 2 in a crossing manner, the multiple groups of autolysis heating structures 7 distributed on two sides of the inner wall of the main box body 2 can perform heating autolysis and mixing effects on the introduced mixed culture solution and strains, the mixed solution slowly flows downwards from top to bottom through the multiple groups of autolysis heating structures 7 after being introduced into the main box body 2 through the feeding opening 5, the top of the multiple groups of autolysis heating structures 7 is also provided with multiple cross-distributed guide plates 8, the multiple cross-distributed guide plates 8 can further perform the guide and blocking effects on the flowing mixed solution, so that the mixed solution can be fully mixed in the flowing process, the time of the mixed solution in the main box body 2 can be further prolonged, the heating time is further prolonged, and the autolysis of the strains in the mixed solution is accelerated;

as shown in fig. 5, the autolyzed heating structure 7 comprises a steam heating plate 701, wherein an air inlet pipeline 702 and an air outlet pipeline 703 are respectively arranged in the center of the steam heating plate 701, an air inlet 704 and an air outlet 705 corresponding to the air inlet pipeline 702 and the air outlet pipeline 703 are respectively arranged at one side of the steam heating plate 701, high-temperature steam can enter the air inlet pipeline 702 through the air inlet 704, the air inlet pipeline 702 distributed in a serpentine structure can uniformly heat the steam heating plate 701, and then the mixed liquid flowing at the top of the steam heating plate 701 is uniformly heated through the steam heating plate 701, and the steam subjected to heat exchange can flow out of the air outlet 705 through the air outlet pipeline 703; the air inlet pipeline 702 is communicated with the air outlet pipeline 703, so that a complete heat exchange pipeline can be formed between the air inlet pipeline 702 and the air outlet pipeline 703; the air inlet 704 and the air outlet 705 are respectively communicated with the air inlet nozzle 602 and the air outlet nozzle 603, so that high-temperature steam can enter the air inlet 704 through the air inlet nozzle 602, and the steam cooled after tube heating can also flow out of the air outlet nozzle 603 through the air outlet 705;

as shown in fig. 3-4, the top parts of the multiple groups of self-dissolving heating structures 7 are fixedly connected with multiple guide plates 8, guide ports 9 are arranged between the multiple groups of self-dissolving heating structures 7 and one side of the inner wall of the main box body 2, the bottom part of one side of the outer wall of the main box body 2 is fixedly connected with a blanking elbow 10, and a discharging hole communicated with the blanking elbow 10 is formed in the bottom part of one side of the outer wall of the main box body 2.

When the utility model is used, the two sides of the outer wall of the main box body 2 are fixedly connected with a plurality of groups of air inlet structures 6, the air inlet nozzles 602 are used for being connected with external high-temperature steam pipes, the connected high-temperature steam is led into the corresponding autolyzed heating structures 7, the steam subjected to heat exchange is discharged through the air outlet nozzles 603, the mixed liquor is led into the main box body 2 through the feeding ports 5 and slowly flows downwards from top to bottom through the plurality of groups of autolyzed heating structures 7, the plurality of cross-distributed guide plates 8 arranged at the tops of the plurality of groups of autolyzed heating structures 7 can further have the flow guiding and blocking effects on the flowing mixed liquor, so that the mixed liquor is fully mixed in the flowing process, the time of the mixed liquor in the main box body 2 can be further prolonged, the heating time is further prolonged, the autolyzed of strains in the mixed liquor is accelerated, and finally the heated mixed liquor is discharged out of the main box body 2 through the blanking bent pipe 10.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present utility model.

Claims (8)

1. An autolysis mechanism for producing single cell proteins, comprising a fixed support (1), characterized in that: the top of the fixed support (1) is fixedly connected with a main box body (2), the front end of the main box body (2) is fixedly connected with a front heat-insulation cover plate (3), the rear end of the main box body (2) is fixedly connected with a rear heat-insulation cover plate (4), and one side of the top of the main box body (2) is provided with a feeding port (5);

a plurality of groups of air inlet structures (6) are fixedly connected to two sides of the outer wall of the main box body (2), and a plurality of groups of autolysis heating structures (7) corresponding to the air inlet structures (6) are arranged on two sides of the inner wall of the main box body (2);

the top of multiunit autolyzing heating structure (7) all fixedly connected with a plurality of guide plates (8), multiunit autolyzing heating structure (7) all are provided with water conservancy diversion mouth (9) between main tank body (2) inner wall one side, the bottom fixedly connected with unloading return bend (10) of main tank body (2) outer wall one side.

2. An autolysis mechanism for producing a single cell protein according to claim 1 wherein: the front heat-preservation cover plate (3) and the rear heat-preservation cover plate (4) are respectively fixed at the front end and the rear end of the main box body (2) through a plurality of fixing screws.

3. An autolysis mechanism for producing a single cell protein according to claim 1 wherein: and a feeding hole corresponding to the feeding hole (5) is formed in one side of the top of the main box body (2).

4. An autolysis mechanism for producing a single cell protein according to claim 1 wherein: the air inlet structure (6) comprises a mounting seat (601), and an air inlet nozzle (602) and an air outlet nozzle (603) are respectively arranged on the outer side of the mounting seat (601).

5. An autolysis mechanism for producing a single cell protein according to claim 1 wherein: the multiple groups of autolysis heating structures (7) are distributed on two sides of the inner wall of the main box body (2) in a crossing way.

6. An autolysis mechanism for producing a single cell protein according to claim 4 wherein: the autolyzing heating structure (7) comprises a steam heating plate (701), wherein an air inlet pipeline (702) and an air outlet pipeline (703) are respectively arranged in the center of the steam heating plate (701), and an air inlet (704) and an air outlet (705) which correspond to the air inlet pipeline (702) and the air outlet pipeline (703) are respectively arranged on one side of the steam heating plate (701).

7. An autolysis mechanism for producing a single cell protein according to claim 6 wherein: the air inlet pipeline (702) is communicated with the air outlet pipeline (703).

8. An autolysis mechanism for producing a single cell protein according to claim 6 wherein: the air inlet (704) and the air outlet (705) are respectively communicated with the air inlet nozzle (602) and the air outlet nozzle (603).

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