A microscale multiple bubble generating device
The intelligently controlled micron-level multi-foam generation device solves the problem of existing foam generation devices being unable to be customized, enabling the generation of efficient and stable foam according to user needs, and improving the applicability and flexibility of the device.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHENZHEN ZHONGXIN TRUST DIGITAL TECHNOLOGY CO LTD
- Filing Date
- 2025-07-02
- Publication Date
- 2026-06-19
AI Technical Summary
Existing foam generation devices lack intelligent control functions, cannot be customized according to diverse user needs, and cannot flexibly adjust foam generation parameters, thus limiting their applicability and flexibility in different application scenarios.
A micron-level multi-foam generation device was designed, which uses a touch screen and a main control device for intelligent control. Combined with components such as a concealed pump, water pump, air pump, flow control module and foaming effect sensor, the foam generation parameters can be dynamically adjusted to ensure stable foam quality.
It enables users to personalize their experience, allowing them to set foaming parameters according to different scenarios and preferences, generating efficient and stable high-quality foam to meet various cleaning needs.
Smart Images

Figure CN224371132U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to a foam generating device, and more particularly to a micron-level multi-foam generating device. Background Technology
[0002] Foam plays an indispensable role in numerous industries, such as cleaning and personal care, chemical production, and firefighting. Taking cleaning and personal care as an example, foam increases the contact area with stains, effectively encapsulating and removing them, thus improving cleaning efficiency and effectiveness. Therefore, the performance and quality of foam generation devices are crucial to the success of related applications.
[0003] Currently, existing foam generation devices mainly rely on simple mechanical stirring or gas-liquid mixing methods to generate foam. Mechanical stirring typically uses a stirrer to vigorously agitate the liquid, causing air to mix into the liquid and form foam; gas-liquid mixing involves mixing gas and liquid within a specific device to promote foam generation. However, both methods have significant limitations.
[0004] Existing foam generation devices lack intelligent control functions and cannot be customized to meet diverse user needs. Different users have different requirements for foam quality in different scenarios. For example, cleaning items made of different materials may require foams of different densities and types. However, existing devices cannot flexibly adjust the foam generation parameters to meet users' personalized needs for foam density, type, etc., thus limiting the applicability and flexibility of foam generation devices in different application scenarios.
[0005] Therefore, there is a need to provide a micron-scale multi-foam generation device. Utility Model Content
[0006] To overcome the shortcomings of poor foam generation effect and lack of intelligent control function, this utility model provides a micron-level multi-foam generation device.
[0007] A micron-scale multifoam generation device includes a housing and a cover, with the cover installed on the top of the housing, and also includes a generation component, which is located on the top of the cover.
[0008] Optionally, the generating components include a touch screen, a main control device, a concealed pump, an infusion tube, a water pump, a gas infusion tube, an air pump, a delivery pipeline, a flow control module, and a foam generating pipe. The touch screen is installed on the top of the housing cover, the main control device is installed on the upper right side of the bottom inside the housing, the concealed pump is installed on the lower left side of the bottom inside the housing, the infusion tube is connected to the upper part of the concealed pump, the water pump is installed in the middle of the infusion tube, the gas infusion tube is connected to the upper part of the concealed pump, the air pump is installed on the left side of the gas infusion tube, the delivery pipeline is connected to the right side of the concealed pump, the flow control module is installed at the lower end of the delivery pipeline, the flow control module is connected to the bottom inside the housing, and the foam generating pipe is installed below the flow control module.
[0009] Optionally, it also includes a foaming effect sensor and a foam outlet. The foaming effect sensor is installed at the lower end of the foam generating tube. The foaming effect sensor is electrically connected to the main control device. The bottom end of the foaming effect sensor is provided with a foam outlet.
[0010] Optionally, it also includes a water supply pipe, with the water supply pipe connected to the left side of the foam generating pipe, and a notch adapted to the water supply pipe is provided on the left side of the shell.
[0011] Optionally, a foaming net is provided inside the foam generating tube.
[0012] Optionally, mounting holes are pre-installed at the four internal corners of the housing.
[0013] The beneficial effects and significant advancements of this utility model are as follows:
[0014] This invention, through the design of a touch screen and a main control device, allows users to easily set various foaming parameters to meet different scenarios and preferences, achieving a personalized experience; the main control device intelligently regulates and dynamically adjusts parameters to ensure stable foam quality; all components work together to efficiently and stably generate high-quality foam, and can quickly produce a large amount of foam to meet various cleaning and other usage needs. Attached Figure Description
[0015] Figure 1 This is a three-dimensional structural diagram of the present invention.
[0016] Figure 2 This is a three-dimensional structural diagram of the internal structure of the housing of this utility model.
[0017] Figure 3 This is a three-dimensional structural diagram of the main control device, concealed pump, and infusion pipe of this utility model.
[0018] Explanation of reference numerals in the attached drawings: 1_House, 2_House cover, 3_Touch screen, 4_Main control device, 5_Concealed pump, 6_Infusion tube, 7_Water pump, 8_Gas tube, 9_Air pump, 10_Delivery pipeline, 11_Flow control module, 12_Foam generation tube, 13_Foaming effect sensor, 14_Foam outlet, 15_Water tube. Detailed Implementation
[0019] The following description is only a preferred embodiment of the present invention and does not limit the scope of protection of the present invention.
[0020] Example: A micron-scale multi-foam generation device, please see [link / reference]. Figures 1 to 3As shown, the device includes a housing 1, a cover 2, a touchscreen 3, a main control unit 4, a concealed pump 5, an infusion pipe 6, a water pump 7, a gas infusion pipe 8, an air pump 9, a delivery pipeline 10, a flow control module 11, a foam generation pipe 12, a foaming effect sensor 13, a foam outlet 14, and a water infusion pipe 15. The housing 1 serves as the outer shell structure of the entire device, providing installation space and physical protection for the internal components, playing a supporting, fixing, and protective role. A cover 2 is installed on the top of the housing 1 to seal it and prevent dust, debris, etc., from entering the device. Installation openings are pre-set at the four corners inside the housing 1 to facilitate installation between the housing 1 and the cover 2. A touchscreen 3 is installed on the top of the cover 2; the touchscreen 3 is the interface for user interaction with the device. Users can interact with the device by touching the screen. The touchscreen 3 sets the foaming parameters. A main control device 4 is installed on the upper right side of the bottom inside the housing 1. The main control device 4 integrates a central processing unit, memory, communication module, and multiple foaming drive circuits to achieve intelligent control of the foaming process. The central processing unit dynamically adjusts the foaming parameters based on user settings and real-time feedback to ensure foam quality. A concealed pump 5 is installed on the lower left side of the housing 1. The concealed pump 5 serves as the power source for mixing the liquid. Through a precise mechanical structure and electronic control, the concealed pump 5 ensures that the bath liquid and air are mixed in a predetermined ratio to form a stable foam material. An infusion pipe 6 is connected to the upper part of the concealed pump 5, passing through the upper side of the housing 1. A water pump 7 is installed in the middle of the infusion pipe 6 to increase the pressure and flow rate of the liquid delivery. The concealed pump 5 is connected to an air supply pipe 8 at its upper part. An air pump 9 is installed on the left side of the air supply pipe 8. The air pump 9 provides power for air delivery, ensuring that the air can be mixed with the bath liquid in a predetermined ratio to form foam raw material. The concealed pump 5 is connected to a delivery pipe 10 on its right side. The delivery pipe 10 is used to transport the mixed liquid and serves as a connection and transmission pipe. A flow control module 11 is installed at the lower end of the delivery pipe 10. The flow control module 11 can monitor and adjust the output flow of the concealed pump 5 in real time to ensure the stability and consistency of the mixed liquid, which is key to the accuracy of foaming. The flow control module 11 is connected to the bottom of the housing 1. A foam generating pipe 12 is installed below the flow control module 11. The foam generating pipe 12 is the main site for foam generation. Therefore, the mixed liquid and air undergo a foaming reaction inside the foam generating tube 12. A foaming mesh is evenly spaced inside the foam generating tube 12. When the mixed liquid and air pass through the foaming mesh, the mesh structure causes a change in the surface tension of the liquid, generating a large number of tiny bubbles, thereby achieving foam generation and refinement, and improving foam quality. A foaming effect sensor 13 is installed at the lower end of the foam generating tube 12. The foaming effect sensor 13 is used to monitor the foaming effect in real time, including parameters such as foam density, size, and stability. The foaming effect sensor 13 is electrically connected to the main control device 4. A foam outlet 14 is provided at the bottom of the foaming effect sensor 13, penetrating the lower side of the housing 1, and is used to discharge the generated foam.For user use, a water supply pipe 15 is connected to the left side of the foam generating pipe 12. A notch adapted to the water supply pipe 15 is provided on the left side of the casing 1. The water supply pipe 15 is used to supply clean water into the foam generating pipe 12. During the foaming process, the clean water can dilute and adjust the foam concentration.
[0021] When using the micron-level multiple foam generator, first place it stably on a level, dry, and well-ventilated surface, ensuring sufficient space around the device for easy operation and maintenance, while preventing it from shaking or tipping over due to instability. Prepare a suitable water pipe, connecting one end to a tap or other clean water source, and the other end to the water supply pipe 15 inside the device through a notch on the left side of the housing 1 that matches the water supply pipe 15. The air pump 9 of this device can draw in air. If there are special requirements for air quality, appropriate air purification equipment or air source can be prepared and connected to the air inlet of the air supply pipe 8 through a suitable pipe.
[0022] Then connect the infusion tube 6 to the shower gel delivery tube 10, and turn on the device. The device will then enter standby mode, at which point the touchscreen 3 will light up. Depending on the actual usage needs, select the appropriate foam density by operating the touchscreen 3. A higher foam density will result in thicker, finer foam, suitable for scenarios requiring stronger cleaning power or a richer foam experience; a lower foam density will result in sparser foam, suitable for situations where the amount of foam required is not high or where quick rinsing is needed.
[0023] Some devices may offer multiple foam types to choose from, such as dense or fluffy. Users can select according to personal preference or usage scenario. Different types of foam will differ in texture, durability, and user experience. Depending on the device's function, other parameters such as foaming time and flow rate may also be set, which users can adjust according to specific needs. After setting the parameters, save them to the device. Then, start the device by operating the touchscreen 3. At this point, the main control device 4 begins to work, controlling the various components to operate collaboratively according to the set parameters.
[0024] The concealed pump 5, acting as the power source for the mixed liquid, begins to work. Through a precise mechanical structure and electronic control, it draws bath liquid and air in a predetermined ratio to mix them and form a stable foam material.
[0025] The water pump 7 can increase the pressure and flow rate of liquid delivery, ensuring that the mixed liquid can be smoothly delivered through the infusion pipe 6 and the delivery pipeline 10; the air pump 9 provides power for air delivery, ensuring that air continuously and stably enters the mixing process.
[0026] The flow control module 11 monitors and adjusts the output flow of the concealed pump 5 in real time to ensure the stability and consistency of the mixed liquid, making the foaming process more precise. After the mixed liquid and air enter the foam generating pipe 12, the surface tension of the liquid changes under the action of the evenly spaced foaming net inside the foam generating pipe 12, generating a large number of tiny bubbles, thus realizing the generation and refinement of foam.
[0027] The foaming effect sensor 13 monitors the foaming effect in real time, including parameters such as foam density, size, and stability, and feeds the monitoring information back to the main control device 4. The main control device 4 compares and analyzes the feedback information with the parameters set by the user, and dynamically adjusts the foaming parameters if necessary to ensure that the quality of the generated foam meets the requirements.
[0028] The foam generated during foaming is discharged through the foam outlet 14. Users can place a suitable container below the foam outlet 14 to collect the foam. The foaming time can be controlled according to actual needs to obtain a sufficient amount of foam.
[0029] The collected foam can be applied to appropriate scenarios, such as cleaning the body or cleaning object surfaces. During use, the foaming parameters can be adjusted as needed, or the device can be restarted to replenish the foam.
[0030] After use, stop foaming by operating the touchscreen 3 to shut down the device. When the micron-level multi-foam generator is no longer needed, turn off the power switch, disconnect the power supply, and finally place the device in a dry, well-ventilated place, avoiding direct sunlight and humid environments to extend its service life.
[0031] The above description is merely an embodiment of this utility model and is not intended to limit the scope of this utility model. All equivalent substitutions made within the principles of this utility model should be included within the protection scope of this utility model. Contents not described in detail in this utility model are existing technologies known to those skilled in the art.
Claims
1. A micron-scale multifoam generation device, comprising a housing (1) and a cover (2), wherein the cover (2) is mounted on the top of the housing (1), characterized in that, It also includes a generation component, which is provided on the top of the shell cover (2); The generating components include a touch screen (3), a main control device (4), a concealed pump (5), an infusion tube (6), a water pump (7), an air infusion tube (8), an air pump (9), a delivery pipe (10), a flow control module (11), and a foam generating pipe (12). The touch screen (3) is installed on the top of the cover (2). The main control device (4) is installed on the upper right side of the bottom inside the housing (1). The concealed pump (5) is installed on the lower left side of the bottom inside the housing (1). The infusion tube (6) is connected to the upper part of the concealed pump (5). The water pump (7) is installed in the middle of the infusion tube (6). The air infusion tube (8) is connected to the upper part of the concealed pump (5). The air pump (9) is installed on the left side of the air infusion tube (8). The delivery pipe (10) is connected to the right side of the concealed pump (5). The flow control module (11) is installed at the lower end of the delivery pipe (10). The flow control module (11) is connected to the bottom inside the housing (1). The foam generating pipe (12) is installed at the lower part of the flow control module (11).
2. The micron-level multi-foam generation device according to claim 1, characterized in that, It also includes a foaming effect sensor (13) and a foam outlet (14). The foaming effect sensor (13) is installed at the lower end of the foam generating tube (12). The foaming effect sensor (13) is electrically connected to the main control device (4). The bottom end of the foaming effect sensor (13) is provided with a foam outlet (14).
3. The micron-level multi-foam generation device according to claim 2, characterized in that, It also includes a water supply pipe (15), and the foam generating pipe (12) is connected to the water supply pipe (15) on the left side. The shell (1) has a notch on the left side that is compatible with the water supply pipe (15).
4. The micron-level multiple foam generation device according to claim 1, characterized in that, A foaming net is provided inside the foam generating tube (12).
5. The micron-level multiple foam generation device according to claim 1, characterized in that, The housing (1) has mounting holes at the four corners inside.