Water treatment device and cleaning machine
By integrating a magnetization module and an ozone generator into the water treatment device, the problems of cleaning agent residue and bulky equipment have been solved. This enables cleaning without cleaning agents and is suitable for small-scale equipment, improving cleaning effect and drying efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- WUHAN POPULARIZATION TECH CO LTD
- Filing Date
- 2025-08-06
- Publication Date
- 2026-07-10
AI Technical Summary
Existing cleaning equipment suffers from health hazards and environmental pollution due to cleaning agent residue, and its bulky structure makes it unsuitable for small household appliances.
The water treatment device adopts a left-right layout, integrating a magnetization module and an ozone generating component to reduce pipeline distribution. It includes a magnetization module, an ozone generating module, a gas-liquid mixer, and an overflow component, which are connected by a U-shaped pipe. A water flow sensor is set to control the ozone output, realizing the mixing of small molecule clusters of water and ozone.
It enables cleaning without detergent, reduces the space required for the housing, is suitable for small household appliances, improves cleaning effect and drying efficiency, and reduces the risk of environmental pollution.
Smart Images

Figure CN224477985U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of water treatment technology, and more specifically, to a water treatment device cleaning machine. Background Technology
[0002] In various industries, including industrial production, daily life, and healthcare, there are scenarios where cleaning is necessary. Ordinary tap water lacks sterilization capabilities and has low water activity. To address these issues, cleaning methods are used in applications such as cleaning tobacco tar, household or commercial tableware, medical supplies, oil tanks, and toilets. Current cleaning techniques typically involve adding cleaning agents to remove stubborn stains such as grease, blood, and urine scale.
[0003] The cleaning method of adding cleaning agents has the following problems:
[0004] 1. No matter how you rinse after using a cleaning agent, there will always be cleaning agent residue. As long as there is residue, it can cause some kind of harm. For example, in the case of dishwashing, using tableware with chemical residue can harm the human body; in the case of laundry, clothing with chemical residue may cause skin allergies or skin diseases.
[0005] 2. After cleaning with cleaning agents, the discharged agents can cause soil compaction, and the seepage of the cleaning agents can also lead to groundwater pollution, severely damaging the living environment. Treating the cleaning agents at the discharge point would require specialized environmental protection equipment, inevitably resulting in additional expenses and increasing the cost of cleaning.
[0006] To address the aforementioned issues, existing cleaning equipment can improve the cleaning effect by adding an ozone generating module and a magnetization device to alter the physicochemical properties of tap water. However, existing cleaning equipment has numerous internal pipes and a bulky structure, resulting in a large overall external size for this invention, making it unsuitable for some small household appliances (such as dishwashers). Utility Model Content
[0007] The purpose of this utility model is to overcome the shortcomings of the prior art. This utility model proposes a water treatment device and a cleaning machine, which greatly reduces the distribution of pipelines inside the shell, thereby reducing the space required for the shell and making it effective for use in small household appliances such as dishwashers.
[0008] To achieve the above objectives, a water treatment device is proposed, comprising a housing and a magnetization module and an ozone generating assembly encapsulated within the housing cavity. The housing is further provided with an inlet pipe and an outlet pipe. The magnetization module is disposed on one side of the housing cavity, and the ozone generating assembly is disposed on the other side of the housing cavity. The ozone generating assembly includes an encapsulation box and an ozone generating module, a gas-liquid mixer, an overflow component, and a one-way valve disposed within the encapsulation box. The inlet pipe, magnetization module, gas-liquid mixer, and outlet pipe are connected sequentially. The ozone generating module is connected to the gas-liquid mixer via a pipe. The overflow component is disposed on the pipe between the ozone generating module and the gas-liquid mixer. The one-way valve is disposed at the outlet of the ozone generating module, and the inlet of the ozone generating module is connected to the outside.
[0009] In this technical solution, the water treatment device adopts a left-right layout, with the main components such as the magnetization module and ozone generator arranged on the left and right sides of the inner cavity of the housing. The ozone generator integrates the ozone generator module, gas-liquid mixer, overflow component and one-way valve together and is packaged in a box. The internal structure of the housing is modular. When assembled, the liquid inlet pipe, magnetization module and ozone generator outlet pipe are connected together in sequence, which greatly reduces the pipeline distribution inside the housing and reduces the space required for the housing. It can be effectively applied to small household appliances such as dishwashers.
[0010] When the water treatment device is working: tap water enters the water treatment device through the inlet pipe, first passes through the magnetization module to form small molecule clusters of water, and then enters the gas-liquid mixer. At the same time, the ozone generation module enters through its connected one-way valve and processes the ozone to form ozone, which is then introduced into the gas-liquid mixer. After being processed by the gas-liquid mixer, the ozone is fully dissolved in the water, and finally discharged through the outlet pipe. When the pressure inside the gas-liquid mixer exceeds the preset value of the overflow component, the medium inside the gas-liquid mixer can overflow to the outside of the shell through the overflow component to prevent pressure buildup. The water treatment device of this solution has complete functions, which can magnetize tap water to form small molecule clusters of water to improve water permeability. After ozone is introduced, it can work better with the small molecule clusters of water to improve the decontamination ability.
[0011] As a preferred embodiment, the gas-liquid mixer has a first inlet, a second inlet, and an outlet. The magnetization module is connected to the first inlet of the gas-liquid mixer, the second inlet of the gas-liquid mixer is connected to one port of the overflow component, and the outlet of the gas-liquid mixer is connected to the liquid outlet pipe. The gas-liquid mixer is a prior art technology that adopts two main methods: static mixing (fixed element diversion and convergence) and dynamic mixing (mechanical stirring or jetting). It improves the mixing efficiency of ozone and water through structural designs such as corrugated flow channels, microporous filter elements, and baffles.
[0012] As a preferred embodiment, the magnetization module is connected to the first inlet of the gas-liquid mixer via a U-shaped tube. The use of a U-shaped tube can change the linear distribution of components, making the overall structure more compact.
[0013] As a preferred embodiment, the inner cavity of the housing is also provided with an electrical control box, which is located on the side of the ozone generating component away from the liquid outlet pipe, and is arranged adjacent to the U-shaped tube. The electrical control box is electrically connected to the magnetization module and the ozone generating module.
[0014] As a preferred embodiment, the overflow component is an overflow valve.
[0015] As a preferred embodiment, the outlet pipe is equipped with a water flow sensor, which is used to display the water flow rate and velocity, thereby controlling the ozone output and output rate of the ozone generating module as needed.
[0016] As a preferred embodiment, the water flow sensor is a flow meter.
[0017] As a preferred embodiment, the oxygen-17 NMR half-width of the water flowing out of the outlet pipe is 60-70Hz. Water treated by this invention's water treatment device exhibits enhanced permeability during the cleaning process, allowing it to better encapsulate and clean contaminants. Furthermore, the treatment weakens the intermolecular forces, reduces surface tension, and lowers the contact angle, making it easier for water to form flowing droplets. This reduces water film residue and improves drying efficiency, achieving natural drying without the need for drying agents or other catalytic drying methods. The dipole moments of the two H1O bonds in water molecules cannot cancel each other out, and the centers of positive and negative charges do not coincide, resulting in high polarity for the entire molecule. Utilizing the attraction between the polarity of water molecules and the positive and negative charges of oil, water molecules easily trap and carry away oil (due to the absence of emulsification), thus partially replacing petrochemical detergents.
[0018] As a preferred embodiment, in order to magnetize tap water and form small molecule clusters of water, the magnetic field force parameter of the magnetization module is 5000-6000 Gs.
[0019] To achieve the above objectives, a cleaning machine is proposed, comprising the aforementioned water treatment device, and further comprising:
[0020] A washing device suitable for rinsing dirt;
[0021] A drainage device connected to the washing device;
[0022] The washing device has a water inlet, and the liquid outlet pipe of the water treatment device is connected to the water inlet of the washing device.
[0023] Compared with the prior art, the beneficial effects of this utility model are:
[0024] 1. The water treatment device of this utility model integrates the ozone generating module, gas-liquid mixer, overflow component and one-way valve into a package, so that the internal structure of the shell is modular. When connecting, only the liquid inlet pipe, magnetization module, ozone generating component and liquid outlet pipe need to be connected together in sequence, which greatly reduces the pipeline distribution inside the shell, reduces the space required for the shell, and can be effectively applied to small household appliances such as dishwashers.
[0025] 2. The magnetization module is connected to the first inlet of the gas-liquid mixer through a U-shaped tube. The use of a U-shaped tube can change the linear distribution of components, making the overall structure more compact.
[0026] 3. By installing an overflow component between the ozone generating module and the gas-liquid mixer, when the pressure inside the gas-liquid mixer exceeds the preset value of the overflow component, the medium inside the gas-liquid mixer can overflow to the outside of the housing through the overflow component, preventing pressure buildup.
[0027] 4. By installing a water flow sensor in the outlet pipe to display the water flow rate and velocity, the ozone output and output rate of the ozone generator module can be controlled as needed. Attached Figure Description
[0028] Figure 1 This is a schematic diagram of the structure of the water treatment device of this utility model;
[0029] Figure 2 This is a structural diagram of the water treatment device with one side of the casing hidden.
[0030] Figure 3 yes Figure 2 A schematic diagram of the encapsulation box for the hidden ozone generator component.
[0031] In the diagram: 1. Housing; 11. Inlet pipe; 12. Outlet pipe; 13. Indicator light; 2. Magnetization module; 3. U-tube; 4. Ozone generator assembly; 41. Ozone generator module; 42. Overflow component; 43. Gas-liquid mixer; 44. Check valve; 5. Water flow sensor; 6. Electrical control box. Detailed Implementation
[0032] The accompanying drawings are for illustrative purposes only and should not be construed as limiting this patent. To better illustrate this embodiment, some components in the drawings may be omitted, enlarged, or reduced, and do not represent the actual dimensions of the product. It is understandable to those skilled in the art that some well-known structures and their descriptions may be omitted in the drawings. The positional relationships described in the drawings are for illustrative purposes only and should not be construed as limiting this patent.
[0033] In the accompanying drawings of this utility model, the same or similar reference numerals correspond to the same or similar components. In the description of this utility model, it should be understood that if terms such as "upper," "lower," "left," "right," "long," and "short" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, they are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or component referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, the terms used to describe positional relationships in the drawings are only for illustrative purposes and should not be construed as limiting this patent. For those skilled in the art, the specific meaning of the above terms can be understood according to the specific circumstances.
[0034] The technical solution of this utility model will be further described in detail below through specific embodiments and with reference to the accompanying drawings:
[0035] Example 1:
[0036] like Figure 1-3 As shown, this embodiment provides a water treatment device, including a housing 1 and a magnetization module 2 and an ozone generating assembly 4 encapsulated in the inner cavity of the housing 1. The housing 1 is also provided with an inlet pipe 11 and an outlet pipe 12. The magnetization module 2 is disposed on one side of the inner cavity of the housing 1, and the ozone generating assembly 4 is disposed on the other side of the inner cavity of the housing 1. The ozone generating assembly 4 includes an ozone generating module 41, a gas-liquid mixer 43, an overflow component 42, and a one-way valve 44. The inlet pipe 11, the magnetization module 2, the gas-liquid mixer 43, and the outlet pipe 12 are connected in sequence. The ozone generating module 41 is connected to the gas-liquid mixer 43 through a pipe. The overflow component 42 is disposed on the pipe between the ozone generating module 41 and the gas-liquid mixer 43. The one-way valve 44 is disposed at the outlet of the ozone generating module 41, and the inlet of the ozone generating module 41 is connected to the outside.
[0037] In this embodiment, the magnetization module 2 is a prior art technology. The magnetization module 2 has a metal shell on the outside and mainly consists of a magnetic conductive layer and magnet blocks inside. The magnetic conductive layer is designed by computer simulation calculation and is symmetrical and can be connected and combined. The magnet blocks are installed inside. These magnet blocks and the magnetic conductive layer are covered by soft plastic to form an integrated state. Gaps are formed between the magnet blocks, and these gaps serve as water flow channels. When water flows through these gaps, it is affected by the magnetic field generated by the magnet, forming small water molecule clusters. Under the influence of the magnetic field, the positive and negative ions in the water molecules are rearranged. The dipole moments of the two H1O bonds of the water molecules cannot cancel each other out, and the centers of positive and negative charges do not coincide, resulting in a high polarity of the entire molecule. Utilizing the attraction between the polarity of the water molecules and the positive and negative charges of the oil stains, the water molecules easily trap and carry away the oil stains (because there is no emulsification reaction). This achieves the purpose of cleaning stains without detergent. After tap water forms small water molecule clusters, on the one hand, the water's penetrating ability is stronger during the cleaning process, which can better encapsulate the dirt and clean it thoroughly; on the other hand, the smaller the water molecule clusters, the easier they evaporate, and the less water droplets remain on the rinsed items, making them drier. This achieves the purpose of natural drying without the need for drying agents or other drying methods.
[0038] In this embodiment, by setting a one-way valve 44 at the outlet of the ozone generating module 41, water can be prevented from flowing out of the inlet. The overflow component 42 is a prior art technology and can be an overflow valve. Pressure control is achieved through pressure difference and flow rate regulation. When the pressure in the gas-liquid mixer 43 exceeds the preset value, the valve core overcomes the spring force under hydraulic force to open the valve port, so that the medium in the gas-liquid mixer 43 can overflow to the outside of the housing 1 through the overflow component 42, preventing pressure buildup. The outlet of the overflow component 42 is connected to the drainage pipe.
[0039] Specifically, the gas-liquid mixer 43 has a first inlet, a second inlet, and an outlet. The magnetization module 2 is connected to the first inlet of the gas-liquid mixer 43, the second inlet of the gas-liquid mixer 43 is connected to one port of the overflow component 42, and the outlet of the gas-liquid mixer 43 is connected to the liquid outlet pipe 12.
[0040] In this embodiment, the gas-liquid mixer 43 is a static mixer, which is a prior art technology. It adopts static mixing (fixed element diversion and convergence) and improves mixing efficiency through structural design such as waveform flow channel, microporous filter element, and baffle plate.
[0041] Specifically, the magnetization module 2 is connected to the first inlet of the gas-liquid mixer 43 through the U-shaped tube 3.
[0042] In this embodiment, the ozone generating assembly 4 is provided with an encapsulation box, in which the ozone generating module 41, gas-liquid mixer 43, overflow component 42 and one-way valve 44 are encapsulated. The encapsulation box is provided with mounting holes corresponding to the first inlet and outlet of the gas-liquid mixer 43 and the pipe of the overflow component 42 for pipeline connection. The encapsulation box is provided with heat dissipation guide holes corresponding to the position of the ozone generating module 41. During installation, the entire ozone generating assembly 4 is installed in the inner cavity of the housing 1, and one end of the U-shaped tube 3 is connected to the magnetization module 2. The other end of the U-shaped tube 3 passes through the mounting hole of the encapsulation box and is connected to the first inlet of the gas-liquid mixer 43. The liquid outlet pipe 12 passes through the other mounting hole of the encapsulation box and is connected to the outlet of the gas-liquid mixer 43. The installation is convenient and quick.
[0043] Specifically, the inner cavity of the housing 1 is also provided with an electrical control box 6. The electrical control box 6 is located on the side of the ozone generating component 4 away from the liquid outlet pipe 12, and the electrical control box 6 is arranged adjacent to the U-shaped pipe 3. The electrical control box 6 is electrically connected to the magnetization module 2 and the ozone generating module 41.
[0044] Specifically, an indicator light 13 is provided on the housing 1, and the indicator light 13 is electrically connected to the electrical control box 6.
[0045] Specifically, the oxygen-17 nuclear magnetic resonance half-width in the water flowing out of the outlet pipe 12 is 60-70Hz.
[0046] In this embodiment, the half-width of the oxygen-17 nuclear magnetic resonance (NMR) signal can be used to assess the size of water molecule clusters. The smaller the water molecule clusters, the smaller the half-width of the oxygen-17 NMR signal. The half-width of the oxygen-17 NMR signal in tap water is usually between 94-127 Hz, while the half-width of the oxygen-17 NMR signal in the water flowing out of the outlet pipe 12 is lower than this value, indicating that the water molecule clusters become smaller under the effect of magnetization.
[0047] Specifically, the magnetic field force parameter of the magnetization module 2 is 5000-6000 Gs.
[0048] Example 2:
[0049] This embodiment is similar to Embodiment 1, except that, as Figure 2 , 3 As shown in this embodiment, the liquid outlet pipe 12 is equipped with a water flow sensor 5, which is electrically connected to the electrical control box 6.
[0050] Specifically, the water flow sensor 5 is a flow meter, which is existing technology, used to display the size and velocity of the water flow, thereby controlling the ozone output and output rate of the ozone generating module 41 as needed.
[0051] Example 3:
[0052] This embodiment provides a cleaning machine, including the water treatment device described above, and further including:
[0053] A washing device suitable for rinsing dirt;
[0054] Drainage device, connected to the washing device;
[0055] The washing device has a water inlet, and the liquid outlet pipe 12 of the water treatment device is connected to the water inlet of the washing device.
[0056] Although embodiments of the present invention have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention. Those skilled in the art can make changes, modifications, substitutions and variations to the above embodiments within the scope of the present invention.
[0057] Obviously, the above embodiments of this utility model are merely examples for clearly illustrating this utility model, and are not intended to limit the implementation of this utility model. Those skilled in the art can make other variations or modifications based on the above description. It is neither necessary nor possible to exhaustively describe all embodiments here. Any modifications, equivalent substitutions, and improvements made within the spirit and principles of this utility model should be included within the protection scope of the claims of this utility model.
Claims
1. A water treatment device, characterized in that, The device includes a housing (1) and a magnetization module (2) and an ozone generating assembly (4) encapsulated within the housing (1). The housing (1) is also provided with an inlet pipe (11) and an outlet pipe (12). The magnetization module (2) is located on one side of the inner cavity of the housing (1), and the ozone generating assembly (4) is located on the other side of the inner cavity of the housing (1). The ozone generating assembly (4) includes an encapsulation box and an ozone generating module (41), a gas-liquid mixer (43), and an overflow component (44) disposed within the encapsulation box. 2) One-way valve (44), the inlet pipe (11), magnetization module (2), gas-liquid mixer (43) and outlet pipe (12) are connected in sequence, the ozone generating module (41) is connected to the gas-liquid mixer (43) through a pipe, the overflow component (42) is provided on the pipe between the ozone generating module (41) and the gas-liquid mixer (43), the one-way valve (44) is provided at the outlet of the ozone generating module (41), and the inlet of the ozone generating module (41) is connected to the outside.
2. The water treatment device according to claim 1, characterized in that, The gas-liquid mixer (43) has a first inlet, a second inlet, and an outlet. The magnetization module (2) is connected to the first inlet of the gas-liquid mixer (43). The second inlet of the gas-liquid mixer (43) is connected to one port of the overflow component (42). The outlet of the gas-liquid mixer (43) is connected to the liquid outlet pipe (12).
3. The water treatment device according to claim 2, characterized in that, The magnetization module (2) is connected to the first inlet of the gas-liquid mixer (43) through the provided U-shaped tube (3).
4. A water treatment device according to claim 3, characterized in that, The inner cavity of the housing (1) is also provided with an electrical control box (6). The electrical control box (6) is located on the side of the ozone generating component (4) away from the liquid outlet pipe (12). The electrical control box (6) is arranged adjacent to the U-shaped pipe (3). The electrical control box (6) is electrically connected to the magnetization module (2) and the ozone generating module (41).
5. A water treatment device according to claim 1, characterized in that, The overflow component (42) is an overflow valve.
6. A water treatment device according to claim 1, characterized in that, A water flow sensor (5) is provided on the liquid outlet pipe (12).
7. A water treatment device according to claim 6, characterized in that, The water flow sensor (5) is a flow meter.
8. A water treatment device according to claim 1, characterized in that, The oxygen-17 nuclear magnetic resonance half-width in the water flowing out of the outlet pipe (12) is 60-70 Hz.
9. A water treatment device according to claim 1, characterized in that, The magnetic field parameters of the magnetization module (2) are 5000-6000 Gs.
10. A cleaning machine, characterized in that, The water treatment apparatus comprising any one of claims 1 to 9 further comprises: A washing device suitable for rinsing dirt; A drainage device connected to the washing device; The washing device has a water inlet, and the liquid outlet pipe (12) of the water treatment device is connected to the water inlet of the washing device.