Compound bio-enzyme production device

By setting up multiple feeding pipes and nozzles in the compound bio-enzyme production device, combined with the design of electric push rods and geared motors, the problems of material residue and low stirring efficiency are solved, achieving efficient bio-enzyme mixing and cleaning, and ensuring production quality.

CN224450708UActive Publication Date: 2026-07-03XIASHENG (SHANGHAI) BIOTECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
XIASHENG (SHANGHAI) BIOTECHNOLOGY CO LTD
Filing Date
2025-08-06
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

When using traditional compound bio-enzyme production equipment, the ingredients tend to form localized high-concentration areas inside the tank, affecting the stirring efficiency. Furthermore, the ingredients are prone to remain on the inner wall of the feeding pipe, affecting the mixing quality.

Method used

Multiple feeding pipes are installed on the top of the sealing cap, along with a cover plate and nozzles. Gas sprayed from the nozzles blows away residual ingredients from the inner wall. At the same time, an electric push rod drives the sealing cap to move upward to facilitate cleaning of the stirring paddle and the inner wall of the tank. Combined with a geared motor driving the stirring paddle, the mixing efficiency is improved.

Benefits of technology

It effectively avoids the impact of ingredient residue on mixing quality, improves mixing efficiency, facilitates cleaning, and ensures the continuity and quality of subsequent production.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224450708U_ABST
    Figure CN224450708U_ABST
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Abstract

This utility model discloses a compound bio-enzyme production device, specifically relating to the field of bio-enzyme production technology. It includes a reaction vessel with a detachably connected sealing cap at its top. Multiple feeding pipes arranged in a circular array pass through the top of the sealing cap, each communicating with the interior of the reaction vessel. A cover plate is hinged to the top of each feeding pipe, and a circular hole is formed at the center of the top of the cover plate. A rubber sleeve is fixed inside the circular hole, and a nozzle passes through the rubber sleeve. A support frame is fixed to the outer wall of the reaction vessel, and electric push rods are fixed to both sides of the support frame. This utility model, by setting multiple feeding pipes at the top of the sealing cap for inputting different bio-enzyme ingredients and sealing the feeding pipes with cover plates, allows the operator to hold the nozzle and adjust its opening direction. The gas emitted from the nozzle blows off the ingredients adhering to the inner wall of the feeding pipes, preventing ingredient residue from affecting the mixing quality.
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Description

Technical Field

[0001] This utility model relates to the field of bioenzyme production technology, and more specifically to a compound bioenzyme production device. Background Technology

[0002] Biological enzymes are organic compounds produced by living cells that possess catalytic properties; most are proteins, with a very small portion being RNA. The study of their fundamental properties is called "enzymology." The applied research of enzymes is called "enzyme engineering," and its industrialization has led to the development of the enzyme preparation industry and its penetration into various industrial sectors. Due to their unique biological functions and highly efficient catalysis, biological enzymes have gained widespread applications. Currently, they are increasingly being used in industries such as medicine, textiles, petroleum, food, and papermaking.

[0003] In the preparation of compound bioenzymes, raw materials are added to a preparation device, and the internal stirring mechanism mixes and reacts the raw materials. For example, a compound bioenzyme preparation device with prior art publication number CN218290887U includes an input motor fixedly connected to the top of a reaction vessel, and a main shaft fixedly connected to the output end of the stirring assembly. The main shaft passes through the reaction vessel and extends into its interior. After materials are added, the input motor is started, and through the engagement of a first gear, a second gear, and an internal gear, the main shaft rotates, causing the rotating shaft to rotate around the first gear. This, along with the stirring rod, stirs the raw materials, improving stirring efficiency and ensuring more thorough mixing.

[0004] However, the existing technology described above still has the following problems in use: When using traditional compound bio-enzyme production devices, operators typically pour large amounts of ingredients into the reaction tank at once, which easily creates localized high-concentration areas inside the tank, affecting stirring efficiency. Furthermore, the ingredients are prone to remain on the inner wall of the feeding pipe, affecting the quality of subsequent production. Based on this, this utility model provides a compound bio-enzyme production device that facilitates ingredient feeding. Utility Model Content

[0005] To overcome the aforementioned deficiencies of the prior art, this utility model provides a compound bio-enzyme production device. By setting multiple feeding pipes on the top of the sealing cover for inputting different bio-enzyme ingredients, and sealing the feeding pipes with cover plates, the operator can hold the nozzle and adjust its opening direction. The gas sprayed from the nozzle blows off the ingredients adhering to the inner wall of the feeding pipe, avoiding ingredient residue from affecting the mixing quality, thus solving the problems mentioned in the background art.

[0006] To achieve the above objectives, this utility model provides the following technical solution: a compound bio-enzyme production device, including a reaction vessel, a sealing cover detachably connected to the top of the reaction vessel, a plurality of feeding pipes arranged in a ring array passing through the top of the sealing cover, each feeding pipe communicating with the interior of the reaction vessel, a cover plate hinged to the top of each feeding pipe, a circular hole being opened at the center of the top of the cover plate, a rubber sleeve being fixedly installed inside the circular hole, a nozzle passing through the rubber sleeve, a support frame being fixedly installed on the outer wall of the reaction vessel, electric push rods being fixedly installed on both sides of the support frame, a connecting plate being fixedly installed at the top of the piston rod of each electric push rod, and the connecting plate being detachably fixed together with the sealing cover.

[0007] In a preferred embodiment, rubber sealing rings are provided between the bottom of the sealing cap and the top of the reaction vessel, and between the bottom of the cover plate and the top of the feeding pipe. The rubber sealing rings can fill the gaps between the sealing cap and the reaction vessel, and between the cover plate and the feeding pipe, thereby preventing leakage.

[0008] In a preferred embodiment, each cover plate is threaded with a fastening bolt at its top, and the cover plate is detachably connected to the feeding pipe by the fastening bolt. The connection between the cover plate and the feeding pipe by the fastening bolt can improve the firmness between the cover plate and the feeding pipe.

[0009] In a preferred embodiment, a geared motor is fixedly installed at the center of the top of the sealing cover. The bottom end of the output shaft of the geared motor passes through the sealing cover and extends into the interior of the reaction vessel. A stirring paddle is fixedly installed at the bottom end of the output shaft of the geared motor. The geared motor drives the stirring paddle to stir various ingredients, thereby improving the production efficiency of biological enzymes.

[0010] In a preferred embodiment, a bracket is fixedly provided on the top of the sealing cover, and an air supply pipe is fixedly provided on the top of the bracket. The air supply pipe is connected to multiple nozzles via flexible hoses.

[0011] In a preferred embodiment, an air pump is fixedly installed at the rear end of the support frame. The air outlet of the air pump is connected to the air supply pipe through an exhaust pipe. A filter screen is fixedly installed inside the air inlet of the air pump. The filter screen can filter out dust and impurities in the external environment and prevent dust and impurities from contaminating the inside of the reaction vessel.

[0012] In a preferred embodiment, a discharge pipe is provided through the center of the bottom of the reaction vessel, the discharge pipe is connected to the inside of the reaction vessel, and an electromagnetic valve is fixedly provided on the discharge pipe. The electromagnetic valve is used to control the opening and closing of the discharge pipe, thereby facilitating the control of the discharge volume.

[0013] The technical effects and advantages of this utility model are as follows:

[0014] 1. This utility model provides multiple feeding tubes on the top of the sealing cap for inputting different biological enzyme ingredients. The feeding tubes are sealed with a cover plate. Meanwhile, the operator can hold the nozzle and adjust its opening direction. The gas sprayed from the nozzle blows off the ingredients adhering to the inner wall of the feeding tube, thus avoiding ingredient residue that affects the mixing quality.

[0015] 2. The sealing cover and its components are moved upwards by the electric push rod on the support frame, automatically removing the agitator from the inside of the reaction tank. This makes it easier for staff to clean the agitator and the inner wall of the reaction tank, preventing residual biological enzymes from affecting subsequent production. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0017] Figure 2 This is a front view of the overall structure of this utility model;

[0018] Figure 3 This is a top view of the overall structure of this utility model;

[0019] Figure 4 This is a bottom view of the sealing cap of this utility model;

[0020] Figure 5 This is a schematic diagram of the cover plate of this utility model being opened.

[0021] The attached diagram is labeled as follows: 1. Reaction vessel; 2. Sealing cap; 3. Feed pipe; 4. Cover plate; 5. Round hole; 6. Rubber sleeve; 7. Nozzle; 8. Support frame; 9. Electric push rod; 10. Connecting plate; 11. Rubber sealing ring; 12. Fastening bolt; 13. Gear motor; 14. Stirring paddle; 15. Bracket; 16. Gas supply pipe; 17. Hose; 18. Air pump; 19. Filter screen; 20. Discharge pipe; 21. Solenoid valve. Detailed Implementation

[0022] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0023] Refer to the instruction manual appendix Figures 1-5This utility model provides a compound bio-enzyme production device, including a reaction tank 1. A sealing cover 2 is detachably connected to the top of the reaction tank 1. Multiple feeding pipes 3 arranged in a ring array pass through the top of the sealing cover 2. Each feeding pipe 3 communicates with the interior of the reaction tank 1. A cover plate 4 is hinged to the top of each feeding pipe 3. A circular hole 5 is opened at the center of the top of the cover plate 4. A rubber sleeve 6 is fixedly installed inside the circular hole 5. A nozzle 7 passes through the rubber sleeve 6. A support frame 8 is fixedly installed on the outer wall of the reaction tank 1. Electric push rods 9 are fixedly installed on both sides of the support frame 8. A connecting plate 10 is fixedly installed at the top of the piston rod of each electric push rod 9. The connecting plate 10 is detachably fixed to the sealing cover 2.

[0024] A geared motor 13 is fixedly installed at the top center of the sealing cover 2. The bottom end of the output shaft of the geared motor 13 passes through the sealing cover 2 and extends into the interior of the reaction vessel 1. A stirring paddle 14 is fixedly installed at the bottom end of the output shaft of the geared motor 13. The geared motor 13 drives the stirring paddle 14 to stir various ingredients, thereby improving the production efficiency of biological enzymes.

[0025] The top of the sealing cover 2 is fixedly provided with a bracket 15, and the top of the bracket 15 is fixedly provided with an air supply pipe 16. The air supply pipe 16 is connected to multiple nozzles 7 through a hose 17. The rear end of the support frame 8 is fixedly provided with an air pump 18. The air outlet of the air pump 18 is connected to the air supply pipe 16 through an exhaust pipe. The air inlet of the air pump 18 is fixedly provided with a filter screen 19.

[0026] In actual use, the staff pours various bio-enzyme ingredients into the reaction tank 1 through multiple feeding pipes 3. After closing the cover plate 4 on the top of the feeding pipe 3, the staff uses the air pump 18 to deliver gas into the nozzle 7 through the exhaust pipe, gas supply pipe 16 and hose 17. The staff then holds the nozzle 7 and rotates it to blow off the ingredients adhering to the inner wall of the feeding pipe 3 with the gas sprayed from the nozzle 7, thus preventing the ingredients from remaining and affecting the mixing quality. After the various ingredients are mixed, the staff uses two electric push rods 9 to drive the sealing cover 2 and the parts on the sealing cover 2 to move upward together, so that the stirring paddle 14 can be removed from the inside of the reaction tank 1. This makes it easier for the staff to clean the stirring paddle 14 and the inner wall of the reaction tank 1, thus preventing the bio-enzyme residue from affecting subsequent production work.

[0027] In this embodiment, a discharge pipe 20 is inserted through the center of the bottom of the reaction vessel 1. The discharge pipe 20 is connected to the inside of the reaction vessel 1. A solenoid valve 21 is fixedly installed on the discharge pipe 20. The solenoid valve 21 is used to control the opening and closing of the discharge pipe 20, so as to facilitate the control of the discharge amount.

[0028] Refer to the instruction manual appendix Figure 4 and Figure 5A rubber sealing ring 11 is provided between the bottom of the sealing cover 2 and the top of the reaction vessel 1, and between the bottom of the cover plate 4 and the top of the feeding pipe 3. The rubber sealing ring 11 can fill the gap between the sealing cover 2 and the reaction vessel 1, and between the cover plate 4 and the feeding pipe 3, thereby preventing leakage.

[0029] like Figure 5 As shown, each cover plate 4 is threaded with a fastening bolt 12 at its top. The cover plate 4 is detachably connected to the feeding pipe 3 by the fastening bolt 12. The connection between the cover plate 4 and the feeding pipe 3 by the fastening bolt 12 can improve the firmness between the cover plate 4 and the feeding pipe 3.

[0030] Finally: The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A compound bioenzyme production device, comprising a reaction vessel (1), characterized in that: The top of the reaction vessel (1) is detachably connected to a sealing cover (2), and the top of the sealing cover (2) is permeated with multiple feeding pipes (3) arranged in a ring array, each feeding pipe (3) being connected to the inside of the reaction vessel (1); Each feeding tube (3) is hinged to a cover plate (4) at the top. A round hole (5) is opened at the center of the top of the cover plate (4). A rubber sleeve (6) is fixed inside the round hole (5). A nozzle (7) passes through the rubber sleeve (6). The outer wall of the reaction vessel (1) is fixedly provided with a support frame (8), and electric push rods (9) are fixedly provided on both sides of the support frame (8). The piston rod top of the electric push rod (9) is fixedly provided with a connecting plate (10), and the connecting plate (10) and the sealing cover (2) are detachably fixed together.

2. The compound bio-enzyme production device according to claim 1, characterized in that: Rubber sealing rings (11) are provided between the bottom of the sealing cover (2) and the top of the reaction vessel (1), and between the bottom of the cover plate (4) and the top of the feeding pipe (3).

3. The compound bioenzyme production device according to claim 1, characterized in that: Each cover plate (4) has a threaded fastening bolt (12) at its top, and the cover plate (4) is detachably connected to the feeding pipe (3) by the fastening bolt (12).

4. The compound bio-enzyme production device according to claim 1, characterized in that: A geared motor (13) is fixedly installed at the top center of the sealing cover (2). The bottom end of the output shaft of the geared motor (13) passes through the sealing cover (2) and extends into the interior of the reaction vessel (1). A stirring paddle (14) is fixedly installed at the bottom end of the output shaft of the geared motor (13).

5. The compound bio-enzyme production device according to claim 1, characterized in that: The top of the sealing cover (2) is fixedly provided with a bracket (15), and the top of the bracket (15) is fixedly provided with an air supply pipe (16). The air supply pipe (16) is connected to multiple nozzles (7) through a hose (17).

6. The compound bio-enzyme production device according to claim 5, characterized in that: The support frame (8) is fixedly equipped with an air pump (18) at its rear end. The air outlet of the air pump (18) is connected to the air supply pipe (16) through the exhaust pipe. The air inlet of the air pump (18) is fixedly equipped with a filter screen (19).

7. The compound bio-enzyme production device according to claim 1, characterized in that: A discharge pipe (20) runs through the center of the bottom of the reaction vessel (1). The discharge pipe (20) is connected to the inside of the reaction vessel (1). A solenoid valve (21) is fixedly installed on the discharge pipe (20).