Magnetized micromolecular emulsion pump for cosmetics

By incorporating a magnetized component into the emulsion pump and using a permanent magnet to alter the molecular structure of the active ingredients in cosmetics, the problem of existing emulsion pumps being unable to improve the penetration rate of cosmetics is solved. This enables rapid penetration and enhanced activity of the active ingredients in cosmetics, thereby improving product efficacy.

CN224371728UActive Publication Date: 2026-06-19ZHEJIANG KESHENG HYDROGEN MEDICAL TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ZHEJIANG KESHENG HYDROGEN MEDICAL TECHNOLOGY CO LTD
Filing Date
2025-05-29
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Existing lotion pumps cannot pre-treat lotions to enhance their efficacy, resulting in the stabilization of the molecular structure of cosmetic active ingredients, which limits their penetration and activity in the skin, and fails to meet consumers' growing skincare needs.

Method used

A magnetized small molecule emulsion pump for cosmetics was designed. By incorporating a magnetization component inside the pump cover housing, and utilizing the closed-loop arrangement and spiral channel design of the permanent magnet component, the emulsion is subjected to a magnetic field during flow, which changes the molecular structure of the effective ingredients in the cosmetic and enhances their activity. The emulsion is then subjected to a secondary magnetization process by pressing the second permanent magnet component at the pump nozzle.

Benefits of technology

It significantly improves the penetration rate and activity of active ingredients in cosmetics, enhances the skincare efficacy of products, while maintaining the convenience of traditional lotion pumps and reducing product upgrade costs.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model relates to the technical field of cosmetic lotion pumps, and discloses a magnetized small molecule lotion pump for cosmetics. It includes: a lotion pump threadedly connected to the top of a lotion bottle; the lotion pump includes a pump cap housing and a pump nozzle; the pump cap housing contains a pressing component and a magnetizing component, the pressing component and the magnetizing component are internally connected, and the pressing component changes the internal pressure by pressing, forming a negative pressure to generate adsorption force; this utility model utilizes the unique closed-loop arrangement of the first permanent magnet component (four sets of permanent magnets connected in a positive-negative-positive-negative configuration) and a spiral channel design, built into the pump cap housing, to allow the lotion to fully receive the magnetic field during flow, effectively changing the molecular structure of the active ingredients in the cosmetic and enhancing their activity. After magnetization, the lotion molecules can more easily penetrate the stratum corneum of the skin and reach deeper into the skin's basal layer, significantly improving the penetration rate of the active ingredients.
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Description

Technical Field

[0001] This utility model belongs to the technical field of cosmetic emulsion pumps, and more specifically, it relates to a magnetized small molecule emulsion pump for cosmetics. Background Technology

[0002] In the cosmetics packaging industry, lotion pumps are widely used liquid dispensers. However, with the development of the cosmetics industry, higher demands are placed on the functionality of lotion pumps. Ordinary lotion pumps can only perform simple extraction and dispensing of lotion, and cannot perform any pretreatment to enhance its efficacy. The active ingredients in cosmetics have relatively stable molecular structures under normal conditions, which to some extent limits their penetration into the skin and their ability to exert their activity. For example, the active ingredients in many serums and creams, due to their large molecular size or structures that are not conducive to absorption, cannot fully exert their effects of nourishing the skin and repairing damage, resulting in products whose efficacy cannot fully meet consumers' growing skincare needs.

[0003] Therefore, in view of this, we have studied and improved the existing structure and its shortcomings, and provided a magnetized small molecule emulsion pump for cosmetics, in order to achieve a more practical purpose. Utility Model Content

[0004] This invention provides a magnetized small molecule emulsion pump for cosmetics, which overcomes the above-mentioned defects in the prior art.

[0005] The purpose and efficacy of this utility model, a magnetized small molecule emulsion pump for cosmetics, are achieved through the following specific technical means:

[0006] A magnetized small molecule emulsion pump for cosmetics includes: an emulsion bottle, wherein the emulsion pump is threadedly connected to the top of the emulsion bottle, and the emulsion pump includes a pump cap housing and a pump nozzle.

[0007] The pump cover housing is equipped with a pressing component and a magnetizing component. The pressing component and the magnetizing component are internally connected. The pressing component changes the internal pressure of the pressing component by pressing, forming a negative pressure to generate an adsorption force.

[0008] The magnetization component is equipped with a first permanent magnet component, which alters the molecular structure of the active ingredients in the cosmetic, causing their molecular structure to rearrange, enhancing their activity, and enabling them to penetrate the skin and enter the bloodstream more quickly.

[0009] A further technical solution is that the pump cover housing includes a pump body connecting shell and a pump body housing. The pump body housing is fixedly installed on the inner side of the pump body connecting shell. The inner side of the pump body connecting shell is provided with a spiral pattern. A connecting part is provided in the middle of the pump body connecting shell. The connecting part is threadedly connected to the pump body housing. A magnetizing component and a pressing component are installed sequentially from top to bottom inside the pump body housing.

[0010] In a further technical solution, the magnetization component includes a magnetization tube body, with multiple sets of isolation plates arranged in a ring array on the outer side of the magnetization tube body, and multiple sets of first permanent magnet components arranged in a vertical array between the multiple sets of isolation plates. The magnetization tube body has a spiral channel inside, and the first permanent magnet components are disposed on the outer side of the spiral channel.

[0011] In a further technical solution, each group of the first permanent magnet components consists of four groups of permanent magnets, which are connected sequentially in a positive-negative-positive-negative configuration to form a closed loop. The distances between the vertically arranged first permanent magnet components are equal.

[0012] In a further technical solution, a central connection control valve is connected to the bottom of the magnetization component, and oblique valve seats are connected to the upper and lower ends of the central connection control valve. A ball is provided on the oblique valve seat near the magnetization component.

[0013] In a further technical solution, a pressing assembly is fixedly connected to the lower part of the central connecting control valve. The pressing assembly includes a bladder-type housing. The upper end of the bladder-type housing is fixedly connected to the central connecting control valve. A support seat is connected to the lower end of the bladder-type housing. An inner cavity is provided inside the bladder-type housing. A support spring is fixedly installed inside the inner cavity. Multiple sets of side holes are provided on the outer side of the support seat.

[0014] In a further technical solution, a single valve assembly is provided at the lower end of the pump body housing, and the single valve assembly communicates with the interior of the inner cavity.

[0015] In a further technical solution, the press pump nozzle includes a pump head, the extension of the pump head is provided with a drain port, and a second permanent magnet assembly is wrapped around the outside of the drain port. The second permanent magnet assembly is composed of a positive pole and a negative pole continuously connected.

[0016] In a further technical solution, the lower end of the pump nozzle is connected to the magnetization component, the drain port is connected to the spiral channel inside the magnetization component, and the spiral channel is connected to the inner cavity.

[0017] Compared with the prior art, the present invention has the following beneficial effects:

[0018] This invention relates to a magnetized small-molecule emulsion pump for cosmetics. Through a magnetization component built into the pump cap housing, and utilizing the unique closed-loop arrangement of the first permanent magnet component (four sets of permanent magnets connected in a positive-negative-positive-negative configuration) and a spiral channel design, the emulsion is fully subjected to a magnetic field during flow, effectively altering the molecular structure of the active ingredients in the cosmetic and enhancing their activity. The magnetized emulsion molecules more easily penetrate the stratum corneum of the skin, reaching deeper into the skin's basal layer, significantly increasing the penetration rate of the active ingredients and substantially enhancing the product's skincare efficacy. Simultaneously, pressing the second permanent magnet component on the outside of the pump nozzle further magnetizes the emulsion, solidifying the molecular structure restructuring effect and maximizing the cosmetic's effectiveness.

[0019] This invention relates to a magnetized small-molecule emulsion pump for cosmetics. It cleverly integrates the magnetization component with the traditional pump's pressing component within the pump cap housing. Without altering the basic shape of the emulsion bottle, a threaded connection allows for convenient installation and disassembly of the pump and bottle. This compact design retains the operational convenience of traditional emulsion pumps while providing magnetization functionality. It requires no additional equipment or complex operations, facilitating manufacturing and marketing, and effectively reducing product upgrade costs. Attached Figure Description

[0020] Figure 1 This is a schematic diagram of the appearance structure of this utility model.

[0021] Figure 2 This is a schematic diagram of the overall front view of this utility model.

[0022] Figure 3 This is a schematic diagram of the structure of the emulsion pump 12 in this utility model.

[0023] Figure 4 This is a top view of the emulsion pump 12 in this utility model.

[0024] Figure 5 This is a top-section structural diagram of the emulsion pump 12 in this utility model.

[0025] Figure 6 This is a schematic diagram of the pressing component 16 and the magnetizing component 17 in this utility model.

[0026] Figure 7 This is a top-section structural diagram of the pressing component 16 and the magnetizing component 17 in this utility model.

[0027] Figure 8 This is a utility model Figure 5 Enlarged schematic diagram of the structure at point A in the middle.

[0028] Explanation of reference numerals in the attached figures:

[0029] 11. Emulsion bottle, 12. Emulsion pump, 13. Pump cover housing, 14. Pump nozzle, 15. Pump body housing, 16. Pressing assembly, 17. Magnetization assembly, 18. Magnetization tube, 19. Isolation plate, 20. First permanent magnet assembly, 21. Central connecting control valve, 22. Bladder housing, 23. Support spring, 24. Inner cavity, 25. Support seat, 26. Side hole, 27. Spiral channel, 28. Inclined valve seat, 29. Ball, 30. Outer tube connection port, 31. Liquid inlet, 32. Valve ball, 33. Liquid outlet, 34. Second permanent magnet assembly, 35. Pump body connecting shell. Detailed Implementation

[0030] The embodiments of this utility model will be described in further detail below with reference to the accompanying drawings and examples. The following examples are for illustrative purposes only and should not be construed as limiting the scope of this utility model.

[0031] In the description of this utility model, unless otherwise stated, "a plurality of" means two or more; the terms "upper," "lower," "left," "right," "inner," "outer," "front end," "rear end," "head," "tail," etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings, and are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this utility model. In addition, the terms "first," "second," "third," etc., are used for descriptive purposes only and should not be construed as indicating or implying relative importance.

[0032] In the description of this utility model, it should be noted that, unless otherwise explicitly specified and limited, the terms "connected" and "linked" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium. Those skilled in the art can understand the specific meaning of the above terms in this utility model based on the specific circumstances.

[0033] Example:

[0034] As attached Figure 1 To be continued Figure 8 As shown:

[0035] This invention provides a magnetized small molecule emulsion pump for cosmetics.

[0036] See attached document Figure 1 To be continued Figure 8 The system includes: a lotion bottle 11, with a lotion pump 12 threadedly connected to the top of the lotion bottle 11, the lotion pump 12 including a pump cover housing 13 and a pump nozzle 14;

[0037] The pump cover housing 13 is provided with a pressing component 16 and a magnetizing component 17 inside. The pressing component 16 and the magnetizing component 17 are internally connected. The pressing component 16 changes the internal pressure of the pressing component 16 by pressing, forming a negative pressure to generate an adsorption force.

[0038] The magnetization component 17 is equipped with a first permanent magnet component 20, which alters the molecular structure of the active ingredients in the cosmetic, causing their molecular structure to rearrange, enhancing their activity, and enabling them to penetrate the skin and enter the bloodstream more quickly.

[0039] Preferred options are shown in the appendix. Figure 5 The pump cover housing 13 includes a pump body connecting shell 35 and a pump body housing 15. The pump body housing 15 is fixedly installed on the inner side of the pump body connecting shell 35. The inner side of the pump body connecting shell 35 is provided with a spiral pattern. A connecting part is provided in the middle of the pump body connecting shell 35. The connecting part is threadedly connected to the pump body housing 15. The pump body housing 15 is equipped with a magnetization component 17 and a pressing component 16 from top to bottom inside.

[0040] Preferred options are shown in the appendix. Figure 6 and appendix Figure 7 The magnetization component 17 includes a magnetization tube 18. Multiple sets of isolation plates 19 are arranged in a ring array on the outer side of the magnetization tube 18. Multiple sets of first permanent magnet components 20 are arranged in a vertical array between the multiple sets of isolation plates 19. A spiral channel 27 is provided inside the magnetization tube 18. The first permanent magnet components 20 are disposed outside the spiral channel 27.

[0041] Preferred options are shown in the appendix. Figure 6 and appendix Figure 7 Each group of first permanent magnet components 20 has four groups of permanent magnets. The four groups of permanent magnets are connected in sequence with positive pole-negative pole-positive pole-negative pole to form a closed loop. The distance between the vertically arranged first permanent magnet components 20 is equal.

[0042] Preferred options are shown in the appendix. Figure 6 and appendix Figure 7 The magnetization component 17 is connected to a central control valve 21 at its bottom. The upper and lower ends of the central control valve 21 are connected to oblique valve seats 28. A ball 29 is provided on the oblique valve seat 28 near the magnetization component 17.

[0043] Preferred options are shown in the appendix. Figure 6The lower part of the central connecting control valve 21 is fixedly connected to a pressing assembly 16. The pressing assembly 16 includes a bladder-type housing 22. The upper end of the bladder-type housing 22 is fixedly connected to the central connecting control valve 21. The lower end of the bladder-type housing 22 is connected to a support seat 25. The bladder-type housing 22 has an inner cavity 24. A support spring 23 is fixedly installed inside the inner cavity 24. The outer side of the support seat 25 has multiple sets of side holes 26.

[0044] Preferred options are shown in the appendix. Figure 5 and appendix Figure 8 The lower end of the pump housing 15 is provided with a single valve assembly, which is in communication with the interior of the inner cavity 24.

[0045] Preferred options are shown in the appendix. Figure 5 The press pump nozzle 14 includes a pump head, and the extension of the pump head is provided with a drain port 33. A second permanent magnet assembly 34 is wrapped around the outside of the drain port 33. The second permanent magnet assembly 34 is composed of a positive pole and a negative pole continuously connected.

[0046] Preferred options are shown in the appendix. Figure 5 The lower end of the press pump nozzle 14 is connected to the magnetization component 17, the drain port 33 is connected to the spiral channel 27 inside the magnetization component 17, and the spiral channel 27 is connected to the inner cavity 24.

[0047] Specific usage method of this utility model:

[0048] When using this device, first fill the lotion bottle 11 with cosmetic lotion, then tighten the lotion pump 12 to the lotion bottle 11 with a threaded connection. After the connection is complete, the device can be used.

[0049] When using this device, pressing the pump nozzle 14 compresses the pressing assembly 16. Under pressure, the volume of the inner cavity 24 within the bladder-like housing 22 of the pressing assembly 16 decreases. When the pump nozzle 14 is released and the device rebounds, a negative pressure is created inside the inner cavity 24. This negative pressure causes the suction valve ball 32 to move upward, opening the emulsion inlet channel. At this time, suction draws in the liquid inside the emulsion bottle 11, and the liquid enters the inner cavity 24 through the single-valve assembly.

[0050] Pressing the pump nozzle 14 again compresses the inner cavity 24, increasing the liquid pressure and pushing the ball 29 in the central control valve 21 upwards, allowing the emulsion to enter the magnetization assembly 17. The emulsion then enters the spiral channel 27 of the magnetization tube 18 from the inner cavity 24. The first permanent magnet assembly 20, arranged in a ring array on the outer side of the spiral channel 27, magnetizes the emulsion. Each first permanent magnet assembly 20 consists of four sets of permanent magnets connected in a positive-negative-positive-negative sequence to form a closed loop. The vertically arranged first permanent magnet assemblies 20 are equidistant, ensuring that the emulsion receives a uniform and stable magnetic field during its flow through the spiral channel 27.

[0051] The magnetization process can alter the molecular structure of active ingredients in cosmetics, causing them to rearrange and become more active, making it easier for them to penetrate the stratum corneum and reach deeper into the skin. At the same time, magnetization can also activate active ingredients in cosmetics, improve their efficacy, change their microstructure, and improve their texture, making them more delicate, smooth, and easier to apply.

[0052] After the emulsion enters the discharge port 33 of the pump nozzle 14 through the spiral channel 27, the second permanent magnet assembly 34 (composed of a continuous connection of positive and negative poles) wrapped around the outside of the discharge port 33 performs a secondary magnetization treatment on the emulsion, further consolidating the molecular structure reorganization effect. Finally, the emulsion is discharged through the discharge port 33. The embodiments of this utility model are given for illustrative and descriptive purposes only and are not intended to be exhaustive or to limit the utility model to the disclosed forms. Many modifications and variations will be apparent to those skilled in the art. The embodiments were chosen and described to better illustrate the principles and practical applications of this utility model and to enable those skilled in the art to understand this utility model and design various embodiments with various modifications suitable for a particular purpose.

Claims

1. A magnetized micromolecular emulsion pump for cosmetics, comprising: A lotion bottle (11), wherein a lotion pump (12) is threadedly connected to the top of the lotion bottle (11), the lotion pump (12) includes a pump cap housing (13) and a pump nozzle (14), characterized in that: The pump cover housing (13) is provided with a pressing component (16) and a magnetizing component (17). The pressing component (16) and the magnetizing component (17) are internally connected. The pressing component (16) changes the internal pressure of the pressing component (16) by pressing, forming a negative pressure to generate an adsorption force. The magnetization component (17) is provided with a first permanent magnet component (20), which changes the molecular structure of the active ingredients in the cosmetic, rearranges their molecular structure, enhances their activity, and enables them to penetrate the skin and enter the blood circulation more quickly.

2. The magnetized small molecule emulsion pump for cosmetics according to claim 1, characterized in that: The pump cover housing (13) includes a pump body connecting shell (35) and a pump body housing (15). The pump body housing (15) is fixedly provided on the inner side of the pump body connecting shell (35). The inner side of the pump body connecting shell (35) is provided with a spiral pattern. A connecting part is provided in the middle of the pump body connecting shell (35). The connecting part is threadedly connected to the pump body housing (15). A magnetization component (17) and a pressing component (16) are installed in the pump body housing (15) from top to bottom.

3. The magnetized small molecule emulsion pump for cosmetics according to claim 2, characterized in that: The magnetization component (17) includes a magnetization tube (18), with multiple sets of isolation plates (19) arranged in a ring array on the outer side of the magnetization tube (18), and multiple sets of first permanent magnet components (20) arranged in a vertical array between the multiple sets of isolation plates (19). The magnetization tube (18) has a spiral channel (27) inside, and the first permanent magnet components (20) are located outside the spiral channel (27).

4. A magnetized small molecule emulsion pump for cosmetics according to claim 3, characterized in that: Each group of the first permanent magnet assembly (20) has four groups of permanent magnets. The four groups of permanent magnets are connected in sequence with positive pole-negative pole-positive pole-negative pole to form a closed loop. The distance between the vertically arranged first permanent magnet assemblies (20) is equal.

5. A magnetized small molecule emulsion pump for cosmetics according to claim 4, characterized in that: The magnetization component (17) is connected to a central connection control valve (21) at its bottom. The upper and lower ends of the central connection control valve (21) are connected to oblique valve seats (28). A ball (29) is provided on the oblique valve seat (28) near the magnetization component (17).

6. A magnetized small molecule emulsion pump for cosmetics according to claim 5, characterized in that: The lower part of the central connecting control valve (21) is fixedly connected to a pressing assembly (16). The pressing assembly (16) includes a bladder-type housing (22). The upper end of the bladder-type housing (22) is fixedly connected to the central connecting control valve (21). The lower end of the bladder-type housing (22) is connected to a support seat (25). The bladder-type housing (22) has an inner cavity (24). A support spring (23) is fixedly installed inside the inner cavity (24). The outer side of the support seat (25) has multiple sets of side holes (26).

7. A magnetized small molecule emulsion pump for cosmetics according to claim 6, characterized in that: The lower end of the pump housing (15) is provided with a single valve assembly, which is in communication with the interior of the inner cavity (24).

8. A magnetized small molecule emulsion pump for cosmetics according to claim 6, characterized in that: The press pump nozzle (14) includes a pump head, the extension of which is provided with a drain port (33), and a second permanent magnet assembly (34) is wrapped around the outside of the drain port (33). The second permanent magnet assembly (34) is composed of a positive pole and a negative pole connected continuously.

9. A magnetized small molecule emulsion pump for cosmetics according to claim 8, characterized in that: The lower part of the press pump nozzle (14) is connected to the magnetization component (17), the drain port (33) is connected to the spiral channel (27) inside the magnetization component (17), and the spiral channel (27) is connected to the inner cavity (24).