NMN enzyme catalytic surfactant high-efficiency dispersing device

By designing an efficient dispersion device for NMN enzyme-catalyzed surfactants, the release of surfactants is controlled by limiting wedges and limiting grooves. Combined with a stirring paddle and a rotating motor, the problem of uneven dispersion of surfactants in solution is solved, and a uniform dispersion effect is achieved.

CN224485595UActive Publication Date: 2026-07-14BICELLS SCI LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
BICELLS SCI LTD
Filing Date
2025-05-19
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

In existing technologies, surfactants tend to crystallize into clumps in solution, leading to uneven dispersion.

Method used

A highly efficient dispersion device for NMN enzyme-catalyzed surfactants was designed, comprising a tank, a stirring unit, and a limiting wedge structure. The release and dispersion of surfactants are controlled by the cooperation of the limiting wedge and the limiting groove, and uniform dispersion is achieved by using a stirring paddle and a rotating motor.

Benefits of technology

This method achieves uniform dispersion of surfactants in solution, avoids crystallization and improves dispersion effect.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses a NMN enzyme catalytic surfactant high-efficiency dispersing device, and belongs to the field of surfactant dispersion. The device comprises a tank body, a cavity in the tank body, a support structure fixedly connected to the bottom of the tank body, a tank body cover fixedly installed on the top of the tank body, a stirring unit installed in the tank body, and the stirring unit is used for uniformly and slowly releasing and dispersing the surfactant. The inner hole and the outer hole are coincided when the outer cylinder and the stirring paddle are rotated by the rotating motor shaft, so that the surfactant in the solution is dispersed.
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Description

Technical Field

[0001] This invention relates to a high-efficiency dispersion device for surfactants, and more particularly to a high-efficiency dispersion device for NMN enzyme-catalyzed surfactants. Background Technology

[0002] High-efficiency dispersion devices for NMN enzyme-catalyzed surfactants typically utilize principles such as mechanical stirring, ultrasound, and jetting to uniformly disperse the surfactant in the reaction system. For example, the high-speed rotation of a stirring device generates strong shear forces and convection, breaking down surfactant aggregates and distributing them uniformly in the solution as individual molecules or small micelles. Alternatively, the cavitation effect of ultrasound can be used to generate microbubbles in the liquid; the impact force and microfluidic field generated when these bubbles burst contribute to surfactant dispersion. Jetting technology uses high-speed jetting fluid to impact and mix the surfactant, achieving efficient dispersion.

[0003] For example, Chinese patent CN212040024U discloses a high-efficiency surfactant dispersion device. By setting a dispersion mechanism, it can drive the rotating shaft to rotate, thereby causing the dispersion disc to rotate and displace. The dispersion disc can mix and disperse the liquid inside the dispersion tank, thereby achieving the purpose of surfactant dispersion. The rotating shaft can drive the scraper to rotate and displace, which can separate the surfactant deposited at the bottom of the dispersion tank, thereby effectively moving the attached surfactant and improving the surfactant dispersion and mixing effect. Although this patent sets a dispersion structure to disperse the surfactant at the bottom, the surfactant is often added to the dispersion tank at once, which often crystallizes into lumps, resulting in uneven distribution in the dispersion tank and inefficient dispersion of surfactant. Utility Model Content

[0004] The purpose of this invention is to provide a highly efficient dispersion device for NMN enzyme-catalyzed surfactants, thereby solving the problems mentioned in the background art. The highly efficient dispersion device for NMN enzyme-catalyzed surfactants includes:

[0005] The container has a chamber for dispersing reagents;

[0006] A support structure is fixedly connected to the bottom of the tank body, and the support structure is used to fix the tank body;

[0007] A tank cover, which is fixedly installed on the top of the tank and is used to seal the tank;

[0008] A stirring unit is installed in the chamber of the tank, which is capable of uniformly and slowly releasing and dispersing the surfactant.

[0009] Preferably, the tank body includes a container and a discharge pipe. The container is a hollow cylinder with an opening at the top, and the discharge pipe is located at the bottom of the tank body.

[0010] Preferably, the support structure includes a support ring and support legs. The support ring is parallel to the bottom of the tank and is fixedly connected to the tank. The plurality of support legs are fixedly connected to the bottom of the support ring.

[0011] Preferably, the tank cover includes a cover body and a feed pipe, the cover body is fixed to the tank body, and the feed pipe is opened on the upper surface of the cover body.

[0012] Preferably, the feed pipe is used to add the solution.

[0013] Preferably, the stirring unit includes an inner cylinder, an outer cylinder, a stirring paddle, a rotating motor, a bearing, and a limiting wedge. The inner cylinder is nested inside the outer cylinder, the stirring paddle is fixed to the outer wall of the outer cylinder, the rotating motor drives the outer cylinder to rotate through the bearing, and the limiting wedge is fixedly connected to the top of the inner cylinder.

[0014] Preferably, the inner cylinder has a plurality of inner holes, and the outer cylinder has a plurality of outer holes.

[0015] Preferably, a limiting groove is formed at the upper end of the outer cylinder near the top. When the limiting wedge and the limiting groove work together to limit the movement, the outer cylinder drives the inner cylinder to rotate. When the limiting wedge is on the right side of the limiting groove, the inner hole and the outer hole coincide, and the surfactant can flow out from the inner hole and the outer hole. When the limiting wedge is on the left side of the limiting groove, the inner hole and the outer hole are misaligned, preventing the surfactant in the inner cylinder from flowing into the tank chamber. When the bearing of the rotating motor drives the outer cylinder to rotate, the inner cylinder and the stirring paddle rotate simultaneously with the outer cylinder. When the limiting wedge is on the right side of the limiting groove, the surfactant flows out from the inner cylinder and enters the tank, thereby making the surfactant uniformly distributed throughout the tank and slowly entering the solution and being dispersed. Attached Figure Description

[0016] Figure 1 This is an overall view of the tank body of this utility model;

[0017] Figure 2 This is a cross-sectional view of the tank body of this utility model;

[0018] Figure 3 This is a three-dimensional sectional view of the tank body of this utility model;

[0019] Figure 4 This is a partial enlarged view of the stirring device of this utility model;

[0020] Figure 5 This is a front view of the stirring device of this utility model.

[0021] The markings in the diagram are as follows:

[0022] 100-Stirring unit; 101-Inner cylinder; 1011-Inner hole; 102-Outer cylinder; 1021-Outer hole; 1022-Limiting groove; 103-Stirring paddle; 104-Rotating motor; 105-Bearing; 106-Limiting wedge; 107-Active agent inlet; 200-Tank body; 201-Containment tank; 202-Discharge pipe; 300-Supporting structure; 301-Supporting ring; 302-Supporting leg; 400-Tank cover; 401-Cover body; 402-Infeed pipe. Detailed Implementation

[0023] The technical solutions of the embodiments of this application will be clearly described below with reference to the accompanying drawings. Obviously, the described embodiments are only some, not all, of the embodiments of this application. All other embodiments obtained by those skilled in the art based on the embodiments of this application are within the scope of protection of this application.

[0024] To address the problem that surfactants tend to crystallize into lumps when added to a solution all at once, resulting in uneven dispersion of the surfactant in the solution, this embodiment provides an NMN enzyme-catalyzed surfactant high-efficiency dispersion device.

[0025] like Figure 1 As shown, it includes: a tank 200 that contains a solution and provides a mixing area, a support structure 300 that supports the tank, and a tank cover 400 that seals the tank. Figure 2 As shown, the NMN enzyme-catalyzed surfactant high-efficiency dispersion device includes a stirring unit 100, which is used to stir and disperse the surfactant and solution. The stirring unit 100 contains the surfactant, and the stirring unit 100 can release the surfactant into the chamber of the tank 200 when stirring.

[0026] like Figure 3 The image shown is a three-dimensional view with a portion of the tank body 200, inner cylinder 101, and outer cylinder 102 removed. The tank body 200 is a cylindrical container with an open top. The main body of the tank body 200 is a container 201, and inside the container 201 is a container cavity 203, which is where surfactants and solutions are provided for stirring. A discharge pipe 202 is opened at the bottom of the container, and a cover is installed on the discharge pipe. The cover can be used for sealing. The surfactant can be collected through the discharge pipe 202 after undergoing the dispersion step.

[0027] Continue as Figure 3As shown, the support structure 300 is fixedly connected to the bottom of the tank 200. The support structure 300 includes a support ring 301 and a support leg 302. The support ring 301 is annular, and the support leg 302 is cylindrical. The support structure 300 is fixedly connected to the tank 200 through the support ring 301, and the support leg 302 is fixedly connected below the support ring 301. The tank 200 can be stably placed on the ground under the support of the support structure 300.

[0028] Continue as Figure 3 As shown, the tank cover 400 is fixedly connected to the tank 200. The tank cover 400 includes a cover body 401 and a feed pipe 402. The feed pipe 402 is located on the upper surface of the cover body 401. There is a cover inside the feed pipe 402. The cover serves to seal the tank. The solution can enter the tank 200 through the feed pipe 402. After that, the cover can be closed, making the tank 200 a closed space.

[0029] 2. For example Figure 3 Figure 4 Figure 5 As shown, the stirring unit includes an inner cylinder 101, an outer cylinder 102, a stirring paddle 103, a rotating motor 104, and a bearing 105. The top of the inner cylinder 101 is connected to the bearing 105, allowing the inner cylinder 101 to rotate within the bearing 105. Both the inner cylinder 101 and the outer cylinder 102 are hollow cylinders, each containing a chamber. The inner cylinder 101 is embedded within the chamber of the outer cylinder 102. The chamber of the inner cylinder 101 can hold a surfactant. The entire surface of the inner cylinder 101 has an inner hole 1011, and the entire surface of the outer cylinder 102 has an outer hole 1021. The inner hole 1011 and the outer hole 1021 have two states. In the first state, the inner hole 1011 and the outer hole 1021 coincide, and the two holes are connected, allowing the surfactant to flow out. In the second state, the inner hole 1011 and the outer hole 1021 are misaligned, preventing the surfactant from flowing out.

[0030] A limiting wedge 106 is fixed near the top of the inner cylinder 101, and a limiting groove 1022 is formed near the top of the outer cylinder 102. When the limiting wedge 106 and the limiting groove 1022 work together to limit the movement, the outer cylinder 102 drives the inner cylinder 101 to rotate. The limiting wedge 106 and the limiting groove 1022 have two positional states. When the limiting wedge 106 and the limiting groove 1022 are in the first state, the inner hole 1011 and the outer hole 1021 coincide, and the surfactant can flow out from the inner hole and the outer hole. When the limiting wedge 106 and the limiting groove 1022 are in the second state, the inner hole 1011 and the outer hole 1021 are misaligned, preventing the surfactant in the inner cylinder from flowing into the tank chamber. When the bearing of the rotating motor 104 drives the outer cylinder 102 to rotate, the inner cylinder 101 and the stirring paddle 103 rotate simultaneously with the outer cylinder 102. When the limiting wedge 106 and the limiting groove 1022 are in the first state, the surfactant flows out from the inner cylinder 101 and enters the tank 200, thereby allowing the surfactant to enter the solution and be dispersed.

[0031] The inner cylinder 101 is connected to the outer cylinder 102 via a limiting wedge 106 and a limiting groove 1022. When the limiting wedge 106 is on the right side of the limiting groove 1022, the inner hole 1011 and the outer hole 1021 are aligned, and the surfactant can flow out from the inner hole 1011 and the outer hole 1022. When the limiting wedge 106 is on the left side of the limiting groove 1022, the inner hole 1011 and the outer hole 1021 are misaligned, and the surfactant cannot flow out. The inner cylinder 101 is connected to the tank cover 400 via a bearing 106. Twelve stirring paddles 103 are fixedly connected to the entire surface of the outer cylinder 102. A rotating motor 104 is connected to the bottom of the outer cylinder 102, and the rotating motor 104 can drive... When the outer cylinder 102 rotates, and the limiting wedge 106 is on the left side of the limiting groove 1022, a surfactant is added and a solution is added through the feed pipe 402. Then, the inner cylinder 101 is moved upward and rotated to the right side of the limiting groove 1022. The rotating motor 104 is started, which drives the outer cylinder 102 and the inner cylinder 101 to rotate. Due to centrifugal force, the surfactant is slowly released from the inner hole 1011 and the outer hole 1021. Due to the stirring of 103, the surfactant in the inner cylinder is evenly released in the upper and lower positions of the outer cylinder 102, and the surfactant is released and dispersed at the same time. When it is no longer necessary to add surfactant, the limiting wedge 106 can be adjusted to the left side of 1022.

[0032] The embodiments of this application have been described above with reference to the accompanying drawings. Unless otherwise specified, the embodiments and features in the embodiments of this application can be combined with each other. This application is not limited to the specific embodiments described above. The specific embodiments described above are merely illustrative and not restrictive. Those skilled in the art can make many other forms under the guidance of this application without departing from the spirit and scope of the claims, and all of these forms are within the protection scope of this application.

Claims

1. A highly efficient dispersion device for NMN enzyme-catalyzed surfactants, characterized in that, include: The container (200) has a chamber therein for dispersing reagents; A support structure (300) is fixedly connected to the bottom of the tank (200) and is used to fix the tank. A can lid (400) is fixedly installed on the top of the can (200) and is used to seal the can (200). A stirring unit (100) is installed in the chamber of the tank (200). The stirring unit (100) is capable of stirring the surfactant and the solution. The stirring unit (100) contains the surfactant and is capable of releasing the surfactant into the chamber of the tank (200) when the stirring unit (100) is stirring.

2. The high-efficiency dispersion device for NMN enzyme-catalyzed surfactants according to claim 1, characterized in that, The tank (200) includes a container (201) and a discharge pipe (202). The container (201) is a hollow cylinder with an opening at the top, and the discharge pipe (202) is located at the bottom of the tank (200).

3. The high-efficiency dispersion device for NMN enzyme-catalyzed surfactants according to claim 1, characterized in that, The support structure (300) includes a support ring (301) and support legs (302). The support ring (301) is parallel to the bottom of the tank (200) and is fixedly connected to the tank (200). The plurality of support legs (302) are fixedly connected to the bottom of the support ring (301).

4. The high-efficiency dispersion device for NMN enzyme-catalyzed surfactants according to claim 1, characterized in that, The tank cover (400) includes a cover body (401) and a feed pipe (402). The cover body (401) is fixed on the tank body (200), and the feed pipe (402) is opened on the upper surface of the cover body.

5. The high-efficiency dispersion device for NMN enzyme-catalyzed surfactants according to claim 4, characterized in that, The feed pipe (402) is used to add the solution.

6. The high-efficiency dispersion device for NMN enzyme-catalyzed surfactants according to claim 1, characterized in that, The stirring unit includes an inner cylinder (101), an outer cylinder (102), a stirring paddle (103), a rotating motor (104), a bearing (105), and a limiting wedge (106). The inner cylinder (101) is nested inside the outer cylinder (102). The stirring paddle (103) is fixed to the outer wall of the outer cylinder (102). The rotating motor (104) drives the outer cylinder (102) to rotate through the bearing (105). The limiting wedge (106) is fixedly connected to the top of the inner cylinder (101).

7. The high-efficiency dispersion device for NMN enzyme-catalyzed surfactants according to claim 6, characterized in that, The inner cylinder (101) has several inner holes (1011), and the outer cylinder (102) has several outer holes (1021). The inner holes (1011) and outer holes (1021) have two states. In the first state, the inner holes (1011) and outer holes (1021) coincide and are connected, allowing the surfactant to flow out from the holes. In the second state, the inner holes (1011) and outer holes (1021) are offset, and the surfactant cannot flow out from the holes.

8. The high-efficiency dispersion device for NMN enzyme-catalyzed surfactants according to claim 7, characterized in that, A limiting groove (1022) is provided near the top of the upper end of the outer cylinder (102). When the limiting wedge (106) and the limiting groove (1022) are used together for limiting, the outer cylinder (102) drives the inner cylinder (101) to rotate. The limiting wedge (106) and the limiting groove (1022) have two position states. When the limiting wedge (106) and the limiting groove (1022) are in the first state, the inner hole (1011) and the outer hole (1021) coincide, and the surfactant can flow out from the inner hole and the outer hole. When the limiting wedge (106) and the limiting groove (1022) are in the first state, the inner hole (1011) and the outer hole (1021) coincide, and the surfactant can flow out from the inner hole and the outer hole. (1022) In the second state, the inner hole (1011) and the outer hole (1021) are misaligned, preventing the surfactant in the inner cylinder from flowing into the tank chamber. When the bearing of the rotating motor (104) drives the outer cylinder (102) to rotate, the inner cylinder (101) and the stirring paddle (103) rotate simultaneously with the outer cylinder (102). When the limiting wedge (106) and the limiting groove (1022) are in the first state, the surfactant flows out from the inner cylinder (101) and enters the tank (200), thereby allowing the surfactant to enter the solution and be dispersed.