CN215426695U - Rich hydrogen ion functional assembly that atomizes - Google Patents
Rich hydrogen ion functional assembly that atomizes Download PDFInfo
- Publication number
- CN215426695U CN215426695U CN202121021482.0U CN202121021482U CN215426695U CN 215426695 U CN215426695 U CN 215426695U CN 202121021482 U CN202121021482 U CN 202121021482U CN 215426695 U CN215426695 U CN 215426695U
- Authority
- CN
- China
- Prior art keywords
- shell
- sheet
- negative electrode
- positive electrode
- hydrogen
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
Images
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B05—SPRAYING OR ATOMISING IN GENERAL; APPLYING FLUENT MATERIALS TO SURFACES, IN GENERAL
- B05B—SPRAYING APPARATUS; ATOMISING APPARATUS; NOZZLES
- B05B17/00—Apparatus for spraying or atomising liquids or other fluent materials, not covered by the preceding groups
- B05B17/04—Apparatus for spraying or atomising liquids or other fluent materials, not covered by the preceding groups operating with special methods
- B05B17/06—Apparatus for spraying or atomising liquids or other fluent materials, not covered by the preceding groups operating with special methods using ultrasonic or other kinds of vibrations
- B05B17/0607—Apparatus for spraying or atomising liquids or other fluent materials, not covered by the preceding groups operating with special methods using ultrasonic or other kinds of vibrations generated by electrical means, e.g. piezoelectric transducers
- B05B17/0638—Apparatus for spraying or atomising liquids or other fluent materials, not covered by the preceding groups operating with special methods using ultrasonic or other kinds of vibrations generated by electrical means, e.g. piezoelectric transducers spray being produced by discharging the liquid or other fluent material through a plate comprising a plurality of orifices
- B05B17/0646—Vibrating plates, i.e. plates being directly subjected to the vibrations, e.g. having a piezoelectric transducer attached thereto
Landscapes
- Electrolytic Production Of Non-Metals, Compounds, Apparatuses Therefor (AREA)
Abstract
The utility model discloses a hydrogen-rich ion atomization functional component. Wherein, this subassembly includes the shell, the stock solution storehouse that is equipped with in the shell, be equipped with on one side of the shell with the communicating external switching mouth of stock solution storehouse, the electrolysis module that is equipped with in the stock solution storehouse, the atomizing module structure that is equipped with between shell and external switching mouth, and the back lid that is equipped with on the shell of electrolysis module one side. The utility model integrates the vertical electrolytic module or the horizontal electrolytic module and the atomization module into a whole, not only can realize the single water solution/liquid medicine atomization function, but also can produce and generate the hydrogen-rich ion/hydrogen element water solution for atomization, and has the function of separating/isolating the accompanying electrolytic impurities.
Description
Technical Field
The utility model belongs to the field of atomizer application, and particularly relates to a hydrogen-rich ion atomization functional component.
Background
At present, most of atomizers on the market adopt self-contained liquid medicine or solution for atomization, and in practical application, the conventional aqueous solution cannot achieve the specific gain effect of the hydrogen-rich ion/hydrogen element aqueous solution. If the user desires to use the hydrogen-rich element/hydrogen element aqueous solution for atomization, either a pre-filled hydrogen-rich element/hydrogen element aqueous solution is purchased at high cost through a special route, or an additional apparatus for producing the hydrogen ion/hydrogen element-rich aqueous solution is purchased. In such a way, the former can not ensure that the effective hydrogen ion concentration of the pre-filled hydrogen-rich element/hydrogen element water reaches the standard when the pre-filled hydrogen-rich element/hydrogen element water is used, and the latter specially purchases equipment for producing the hydrogen-rich ion/hydrogen element water solution, so that the use cost is increased, a series of complicated operations are generated, and the use cost is also increased. At present, similar atomizing equipment with an electrolytic water module for producing hydrogen ion/hydrogen element-rich aqueous solution appears in the market, and conventional positive and negative electrodes (cathode and anode) are simultaneously soaked/arranged in a liquid storage bin, so that when hydrogen ions are produced by electrolysis of a negative electrode (cathode), accompanying impurities such as oxygen ions, ozone, hypochlorous acid and the like produced by the positive electrode (anode) are mixed in the aqueous solution required to be used, wherein particularly, the accompanying ozone can cause the aqueous solution required by a user to contain peculiar smell, the accompanying hypochlorous acid can generate negative effects on the user, the negative effects of the accompanying impurities need to be eliminated, but the functional atomizer can not effectively prevent or separate the accompanying impurities and can not achieve the expected purpose.
SUMMERY OF THE UTILITY MODEL
In view of the above problems, an object of the present invention is to provide a hydrogen-rich ion atomization module that integrates the vertical electrolysis module or the horizontal electrolysis module with the atomization module, and that can not only achieve a single function of atomizing an aqueous solution/chemical solution, but also produce and atomize an aqueous solution rich in hydrogen ions/hydrogen elements, and has a function of separating/isolating accompanying electrolytic impurities.
In order to achieve the purpose, the utility model provides a hydrogen-rich ion atomization functional component, which comprises a shell, a liquid storage bin arranged in the shell, an external adapter port arranged on one side of the shell and communicated with the liquid storage bin, a vertical type electrolysis module or a horizontal type electrolysis module arranged in the liquid storage bin, and an atomization module structure arranged between the shell and the external adapter port; a back cover is arranged on the shell at one side of the vertical electrolysis module or the horizontal electrolysis module. The vertical type electrolysis module comprises a first support arranged in a liquid storage bin, a first negative electrode electrolytic sheet and a first positive electrode electrolytic sheet which are arranged on the first support, a first ion exchange medium arranged between the first negative electrode electrolytic sheet and the first positive electrode electrolytic sheet, a first silica gel sealing sleeve sleeved on the first negative electrode electrolytic sheet and the first positive electrode electrolytic sheet, a first positive electrode contact and a first negative electrode contact which are respectively connected with the first negative electrode electrolytic sheet and the first positive electrode electrolytic sheet, a containing bin formed by the inner wall of the shell and arranged on one side of the first support, and a first air outlet which extends through the shell and the rear cover and is arranged on the containing bin. The atomization module structure comprises an inner shell, a second silica gel sealing sleeve, an atomization module and an end cover, wherein the inner shell is arranged between the outer shell and the external adapter, the second silica gel sealing sleeve is arranged on the inner shell, the atomization module is arranged on the second silica gel sealing sleeve, and the end cover is arranged on one side of the second silica gel sealing sleeve.
In some embodiments, a first dry-fire prevention probe is disposed within the reservoir. And a first end face contact connected with the first anti-dry heating probe is arranged on the bottom of the shell.
In some embodiments, a first atomizing electrode contact connected with the atomizing module is arranged on the outer part of the external adapter.
In some embodiments, a gasket and a first seal ring are disposed between the rear cover and the housing.
In some embodiments, the horizontal electrolysis module comprises a second support arranged in the liquid storage bin, a third support arranged on the second support, a second negative electrode electrolyte sheet and a second positive electrode electrolyte sheet arranged between the third support and the bottom of the liquid storage bin, a second ion exchange medium arranged between the second positive electrode electrolyte sheet and the second negative electrode electrolyte sheet, a third silica gel sealing sleeve sleeved on the second negative electrode electrolyte sheet and the second positive electrode electrolyte sheet, a negative conductive screw arranged on the second negative electrode electrolyte sheet on one side of the liquid storage bin and extending downwards through the second negative electrode electrolyte sheet and the second positive electrode electrolyte sheet, a negative conductive nut arranged on the end of the negative conductive screw, an electrical isolation pad arranged between the second positive electrode electrolyte sheet and the negative conductive nut, a positive conductive elastic sheet arranged between the electrical isolation pad and the second positive electrode electrolyte sheet, a negative conductive elastic sheet arranged between the electrical isolation pad and the negative conductive nut, A negative conductive gasket is arranged between the negative conductive elastic sheet and the electric isolation pad, the bottom of the second bracket is provided with a positive electrode guide post and a negative electrode guide post which are respectively contacted with the positive conductive elastic sheet and the negative conductive gasket, the bottom cover is arranged at the bottom of the shell, and the bottom cover is provided with a second air outlet hole communicated with the inside of the shell; a second sealing ring is arranged between the bottom cover and the shell.
In some embodiments, a second anti-dry heating probe is disposed within the reservoir; and a second end surface contact connected with the second anti-dry heating probe is arranged on the bottom of the shell.
In some embodiments, a second positive electrode contact and a second negative electrode contact connected to the second negative electrode electrolyte sheet and the second positive electrode electrolyte sheet, respectively, are disposed on the bottom of the housing.
In some embodiments, a second atomization electrode contact connected with the atomization module is arranged on the outer portion of the external adapter.
Another purpose is to provide an application method of the hydrogen-rich ion atomization functional component, wherein the application method specifically comprises the following steps:
(1) after the alternating voltage is converted into the direct voltage by the switching power supply, the direct voltage is applied to a first positive electrode contact and a first negative electrode contact of the vertical electrolysis module or the horizontal electrolysis module. (2) The solution (aqueous solution or liquid medicine) in the liquid storage bin generates an electric field under the action of direct current voltage to generate an electrolysis effect, and H and O molecules are generated. The chemical formula of the step (2) is 2H2O=2H2↑+O2× (energization).
In some embodiments, under the action of a specific electric field in the vertical electrolysis module or the horizontal electrolysis module, hydrogen bonds between water molecules are partially opened, and water reacts on the anode and the cathode of the vertical electrolysis module or the horizontal electrolysis module as follows:
at the cathode 4H++4e-=2H2;
At the anode 4OH-–4e-=2H2O+O2;
The water exists in a liquid state as water molecule groups, and the solution is usually a water molecule cluster composed of water molecule groups.
The beneficial effects of the utility model are as follows: (1) the vertical type electrolytic module or the horizontal type electrolytic module and the atomization module are structurally integrated, the working mode is controlled by software and hardware of a host machine matched with the vertical type electrolytic module or the horizontal type electrolytic module, a single water solution/liquid medicine atomization function can be realized, hydrogen-rich ion/hydrogen element water solution can be produced and atomized, and a user does not need to purchase a pre-filled hydrogen-rich element/hydrogen element water solution additionally, and does not need to purchase a device for producing the hydrogen-rich ion/hydrogen element water solution additionally when using an atomizer. (2) By adopting the latest hydrogen-oxygen separation electrolysis technology, the used hydrogen-oxygen separation electrolysis module can only contact the negative electrode (cathode) electrolysis sheet generating hydrogen ions with the aqueous solution, and the aqueous solution is intercepted and blocked by the ion exchange membrane/interlayer between the positive first negative electrode electrolysis sheet and cannot be directly contacted with the positive electrode (anode). Therefore, the anode and the cathode indirectly generate electrolytic reaction through the ion exchange membrane/interlayer, hydrogen ions (with positive charges) generated at the periphery of the surface layer of the cathode are removed, a part of the hydrogen ions are combined into molecules to form hydrogen gas to be diffused outside the top of the liquid storage bin, and the rest of the hydrogen ions are mixed in an aqueous solution in an ion form. Oxygen ions/chlorine ions and the like generated around the surface layer of the positive electrode are combined and molecule-formed into accompanying impurities such as oxygen, ozone, hypochlorous acid and the like, and the impurities are blocked by the ion exchange membrane/interlayer, cannot permeate and mix into the hydrogen-rich ion aqueous solution prepared by a user, and are finally discharged out of the atomizer through the vent hole. So realized that atomization effect is good and the function is various, and saved use cost's effect.
Drawings
FIG. 1 is a schematic diagram of the vertical configuration of the present invention;
FIG. 2 is a schematic top view of the vertical configuration of the present invention;
FIG. 3 is a schematic view of another vertical configuration of the present invention;
FIG. 4 is a schematic side view of the vertical configuration of the present invention;
FIG. 5 is a schematic cross-sectional view of A-A in FIG. 4;
FIG. 6 is a schematic diagram of the horizontal configuration of the present invention;
FIG. 7 is a schematic top view of the horizontal configuration of the present invention;
FIG. 8 is a schematic view of another embodiment of the present invention;
FIG. 9 is a schematic view of the horizontal configuration of the present invention;
FIG. 10 is a schematic view of the internal structure of the horizontal electrolytic module according to the present invention.
Detailed Description
The following describes the present invention in further detail with reference to the accompanying drawings.
As shown in fig. 1-5, a hydrogen-rich ion atomization functional component includes a housing 01, a liquid storage chamber 02 disposed in the housing 01, an external connection port 03 disposed on one side of the housing 01 and communicated with the liquid storage chamber 02, a vertical electrolysis module 04 or a horizontal electrolysis module 11 disposed in the liquid storage chamber 02, and an atomization module structure 05 disposed between the housing 01 and the external connection port 03. A rear cover 06 is provided on the housing 01 on one side of the vertical electrolytic module 04. The vertical electrolytic module 04 comprises a first support 41 arranged in the liquid storage bin 02, a first negative electrode electrolytic sheet 43 and a first positive electrode electrolytic sheet 42 arranged on the first support 41, a first ion exchange medium 44 arranged between the first negative electrode electrolytic sheet 42 and the first positive electrode electrolytic sheet 43, a first silica gel sealing sleeve 45 sleeved on the first negative electrode electrolytic sheet 43 and the first positive electrode electrolytic sheet 42, a first positive electrode contact 46 and a first negative electrode contact 47 respectively connected with the first negative electrode electrolytic sheet 42 and the first negative electrode electrolytic sheet 43 and arranged on the bottom of the shell 01, a containing bin 48 formed with the inner wall of the shell 01 and arranged on one side of the first support 41, and a first air outlet 49 arranged on the containing bin 48 and extending through the shell 01 and the rear cover 06. The containing chamber 48 is not communicated with the interior of the liquid storage chamber 02, and the isolation is beneficial to atomization, so that the non-beneficial substances are isolated from entering the liquid storage chamber and discharged through the first air outlet. The atomization module structure 05 comprises an inner shell 51 arranged inside between an outer shell 01 and an external adapter 03, a second silica gel sealing sleeve 52 arranged on the inner shell 51, an atomization module 53 arranged on the second silica gel sealing sleeve 52, and an end cover 54 arranged on one side of the second silica gel sealing sleeve 52. A first dry burning prevention probe 110 is arranged in the liquid storage bin 02. A first end contact 07 connected to the first dry-burning prevention probe 110 is provided on the bottom of the case 01. And a first atomizing electrode contact 08 connected with the atomizing module 53 is arranged on the outer part of the external adapter 03. A seal 09 and a first seal ring 10 are provided between the rear cover 06 and the housing 01.
As shown in fig. 6-10, a hydrogen-rich ion atomization functional component comprises a housing 01, a liquid storage bin 02 arranged in the housing 01, an external adapter 03 arranged on one side of the housing 01 and communicated with the liquid storage bin 02, and a horizontal electrolysis module 11 arranged in the liquid storage bin 02. The horizontal electrolytic module 11 comprises a second bracket 111 arranged in the liquid storage bin 02, a third bracket 112 arranged on the second bracket 111, a second negative electrode electrolytic sheet 113 and a second positive electrode electrolytic sheet 114 arranged between the third bracket 112 and the bottom of the liquid storage bin, a second ion exchange medium 115 arranged between the second positive electrode electrolytic sheet 114 and the second negative electrode electrolytic sheet 113, a third silica gel sealing sleeve 116 sleeved on the second negative electrode electrolytic sheet 113 and the second positive electrode electrolytic sheet 114, a negative conductive screw 117 extending downwards through the second negative electrode electrolytic sheet 113 and the second positive electrode electrolytic sheet 114 on the second negative electrode electrolytic sheet 113 at one side of the liquid storage bin, a negative conductive nut 118 arranged on the end of the negative conductive screw 117, an electrical isolation pad 119 arranged between the second positive electrode electrolytic sheet 114 and the negative conductive nut 118, a positive conductive elastic sheet 120 arranged between the electrical isolation pad 119 and the second positive electrode electrolytic sheet 114, and a negative conductive elastic sheet 120, A negative conductive elastic sheet 121 arranged between the electrical isolation pad 119 and the negative conductive nut 118, a negative conductive gasket 122 arranged between the negative conductive elastic sheet 121 and the electrical isolation pad 119, a positive electrode guide post 123 and a negative electrode guide post 124 arranged at the bottom of the second bracket 111 and respectively contacted with the positive conductive elastic sheet 120 and the negative conductive gasket 122, a bottom cover 125 arranged at the bottom of the shell 01, and a second air outlet 126 arranged on the bottom cover 125 and communicated with the inside of the shell 01. A second sealing ring 127 is arranged between the bottom cover 125 and the housing 01. A second dry burning prevention probe 128 is arranged in the liquid storage bin. A second end contact 129 connected to the second dry-burning prevention probe 128 is provided on the bottom of the housing 01. A second positive electrode contact 130 and a second negative electrode contact 131 connected to the second negative electrode tab 113 and the second positive electrode tab 114, respectively, are provided on the bottom of the case 01. And a second atomizing electrode contact 132 connected with the atomizing module is arranged on the outer part of the external adapter. The horizontal electrolytic module 11 is placed at the bottom of the liquid storage bin, the negative conductive screw 117 at the middle position is connected with the negative electrode of the horizontal electrolytic module, atomized solution can be poured in to cover the horizontal electrolytic module, the surface of the horizontal electrolytic module contacted with the solution is a second negative electrode electrolytic sheet 113, a layer of second ion exchange medium 115 (which is a sheet-shaped or block-shaped or mixed/composite-shaped electrolytic ion exchange medium consisting of single layer/two layers or more than two layers of same or different non-metal materials) in the horizontal electrolytic module is a second positive electrode electrolytic sheet 114 (the principle of the electrolytic solution of the horizontally placed electrolytic module is consistent with that of the vertically or obliquely placed electrolytic module and is not described), the second positive electrode electrolytic sheet 114 is electrically connected with the positive conductive elastic sheet 120, and the positive conductive elastic sheet 120 is electrically connected with the positive electrode guide post 123 at the lower part, the positive electrode guide post 123 is electrically connected with the matched positive electrode of the host; the negative conductive screw 117 at the middle position of the other side of the positive electrode guide post 123 is connected with the negative conductive nut 118, the conductive nut is connected with the conductive gasket, the conductive gasket is connected with the negative conductive elastic sheet, the conductive gasket can also play a role in buffering the installation torsional impact force of the nut and the negative conductive elastic sheet in the installation process and simultaneously can increase the conductive contact surface to be more conductive and smooth, the negative conductive elastic sheet is connected with the negative electrode guide post 124, the electrode is electrically connected with a host in matched connection with the electrode, in addition, a non-conductive isolation pad is arranged between the two conductive elastic sheets, and the isolation pad can effectively isolate the positive conductive elastic sheet from the negative conductive elastic sheet and effectively relieve the torsional impact force in the installation process.
The academia has recognized that hydrogen has the only selective antioxidant material that selectively neutralizes hydroxyl radicals and nitrite anions. The hydrogen molecule has small volume, can quickly permeate and diffuse to the whole body, can penetrate various physiological barriers and cell membranes, enters cell nucleus and is taken awayMalignant active oxygen which cannot be eliminated by general means. The hydrogen can be changed into water to be utilized by human body after active oxygen is removed, the normal functions of other benign active oxygen and biomolecules are not influenced, and important biomolecules and cells which are easy to be damaged by oxidation damage are perfectly protected. An application method of a hydrogen-rich ion atomization functional component comprises the following specific steps: (1) after the alternating voltage is converted into the direct voltage by the switching power supply, the direct voltage is applied to the first positive electrode contact 46 and the first negative electrode contact 47 of the vertical electrolysis module 04 or the horizontal electrolysis module 11. (2) The solution in the liquid storage bin 02 generates an electric field under the action of direct current voltage to generate an electrolysis effect, and H and O molecules are generated. The chemical formula of the step (2) is 2H2O=2H2↑+O2× (energization). Under the action of a specific electric field in the vertical electrolysis module 04 or the horizontal electrolysis module 11, hydrogen bonds between water molecules are partially opened, and water reacts on the anode and the cathode of the vertical electrolysis module 04 or the horizontal electrolysis module 11 as follows:
at the cathode 4H++4e-=2H2;
At the anode 4OH-–4e-=2H2O+O2;
The water exists in a liquid state as water molecule groups, and the solution is usually a water molecule cluster composed of water molecule groups. In the vertical electrolysis module 04 or the horizontal electrolysis module 11, water is ionized into hydrogen ions and hydroxyl ions in a liquid state, and the hydrogen ions are positively charged to move to the cathode after being electrified; the hydrogen ions get an electron and then become active hydrogen with strong reducibility, and the oxidation-reduction potential of water is changed from positive to negative. The active hydrogen is unstable and the two hydrogen atoms acquire two electrons and become hydrogen to escape. The reversible equilibrium of water ionization is destroyed, and in order to reach equilibrium again, water is ionized continuously, and then hydrogen ions are accumulated on the cathode continuously; in contrast, the hydroxide ions move negatively toward the anode, losing electrons and becoming oxygen. So that hydrogen and oxygen can continuously escape. The oxyhydrogen atomizer provides oxyhydrogen gas mixture, enters a human body through a respiratory system for disease treatment, and can be mixed with atomized liquid medicine particles for medical institutions and families to carry out atomization inhalation and humidification treatment on the human body. It is used for adjuvant treatment of asthma and chronic obstructive pulmonary disease. The oxyhydrogen water and the atomized medicine can strengthen the medicine property and treat respiratory diseases such as asthma, chronic obstructive pulmonary disease and the like, and meanwhile, the single atomization of the oxyhydrogen water can remove certain deteriorated oxygen molecules in our bodies.
Case 1 version of horizontally disposed Electrolysis Module
Case 2 version of electrolytic Module set placed longitudinally or obliquely
1. Common principle of two structural forms
The bottom of the hydrogen-rich ion atomizer functional component is provided with a plurality of electrode contacts which can be butted/connected with a matched atomizer main machine.
The system comprises an atomization module structure anode and cathode electrode contact, a first dry-burning prevention probe 110/a second dry-burning prevention probe 128 dry-burning prevention module electrode contact, an electrolysis module anode and cathode electrode contact and the like.
A certain amount of aqueous solution or liquid medicine is injected into the liquid storage bin 02, after a matched host machine can be started, the prefabricated software and hardware can realize the electrification work of the electrolysis module, the anode and the cathode indirectly generate the electrolysis reaction through the ion exchange membrane/interlayer, hydrogen ions (with positive charges) generated on the periphery of the surface layer of the cathode are removed and combined into molecules to form hydrogen gas to be diffused outside the top of the liquid storage bin 02, and the rest parts can be mixed in the aqueous solution in an ion form. Oxygen ions/chlorine ions and the like generated around the surface layer of the positive electrode are combined and molecule-formed into accompanying impurities such as oxygen, ozone, hypochlorous acid and the like, and the impurities are blocked by the ion exchange membrane/interlayer, cannot permeate and mix into the hydrogen-rich ion aqueous solution prepared by a user, and are finally discharged out of the atomizer through the vent hole. After the positive electrode and the negative electrode work for a certain time (a period of time preset by a control program), the hydrogen ion content in the aqueous solution/liquid medicine can reach a certain PPB content standard, and at the moment, the atomization module structure starts to work in an electrified mode. The aqueous solution/drug solution containing hydrogen ions is formed into fine mist particles desired by the user by the high frequency vibration of the atomizing module 53 in the atomizing module structure.
2. Differentiation of the two structural morphologies (different application ranges):
case 1 version of horizontally disposed Electrolysis Module
As shown in the figure: the electrolysis module is horizontally arranged at the bottom of the liquid storage bin 02 and is positioned at the lowest position of the whole liquid storage bin 02 together with the electrolysis module, and the electrolysis module does not need to stop working in advance before the aqueous solution/liquid medicine is atomized and consumed in the electrolysis and atomization processes from beginning to end.
After the power-on and startup, the program prefabricated by the matched host computer firstly powers on the electrolysis module, and the electrolysis hydrogen production starts to work. When the work reaches the preset appointed time (namely the hydrogen ion content concentration in the water solution/liquid medicine which is measured in a preset mode can reach the appointed PPB content standard), the preset program can electrify the atomization module structure, the atomization function is started, and meanwhile, the preset flashing light/vibration/sound prompting signals are accompanied.
When the water solution/liquid medicine in the reservoir 02 is atomized and consumed to the final limit, there is not enough water solution/liquid medicine between the second dry-burning prevention probe 128 and the high-frequency vibration atomization module structure to transmit a vibration signal of a certain frequency. At the moment, under the detection, judgment and control of a prefabricated program of a matched host, the electrolysis module and the atomization module are powered off, and specific light flicker/vibration/sound prompt and the like are further sent out through host hardware to serve as prompt signals of water solution/liquid medicine exhaustion and the like until the final shutdown is finished.
In this embodiment, there is no fear that the electrolytic module will be separated from the aqueous solution/chemical solution and exposed to the air for dry burning, but due to the wall thickness of the structural member, the top of the electrolytic module is isolated by the wall thickness of the silica gel/plastic portion to form an unavoidable low-lying space, and some aqueous solution/chemical solution will be remained in this space. Therefore, the configuration example of this embodiment is only applicable to an aqueous solution/chemical solution that is not highly required for quantitative determination or is relatively inexpensive, and is not applicable to an aqueous solution/chemical solution that is required to have no significant residue.
Case 2 version of electrolytic Module set placed longitudinally or obliquely
As shown in the figure: the electrolytic module is disposed or vertically arranged on the side wall of the liquid storage bin 02 with a certain inclination angle, and the atomizing module structure is positioned at the lowest position of the whole liquid storage bin 02.
After the power-on and startup, the program prefabricated by the matched host computer firstly powers on the electrolysis module, and the electrolysis hydrogen production starts to work. When the work reaches the preset appointed time (namely the hydrogen ion content concentration in the water solution/liquid medicine which is measured in a preset mode can reach the appointed PPB content standard), the preset program can electrify the atomization module structure, the atomization function is started, and meanwhile, the preset flashing light/vibration/sound prompting signals are accompanied.
In the process of electrolysis/atomization, when the liquid level of the aqueous solution/liquid medicine is above the electrolytic hydrogen production window, the electrolysis module is in a normal working state. When the electrolysis work reaches the preset duration of the matched host, or the liquid level detection functional component detects that the liquid level of the aqueous solution/liquid medicine is reduced to the upper edge of the electrolysis hydrogen production window, the matched host can cut off the power of the electrolysis module through a preset program to stop the electrolysis module, and only the working state of the atomization module structure and the detection work of the first anti-dry heating probe 110 are kept at the moment.
When the water solution/liquid medicine in the liquid storage bin 02 is atomized and consumed to the final limit, no sufficient water solution/liquid medicine is available between the first dry burning prevention probe 110 and the high-frequency vibration atomization module structure to transmit a vibration signal with a certain frequency. At the moment, under the detection, judgment and control of a prefabricated program of a matched host, the power-off of the atomization module structure is realized, and specific light flicker/vibration/sound prompt and the like are further sent out through host hardware to serve as prompt signals of water solution/liquid medicine exhaustion and the like until the final shutdown is finished.
The structure of the vertical electrolysis module needs to be stopped in advance. Otherwise, when the liquid level of the aqueous solution/liquid medicine is below the electrolytic hydrogen production window, part of the electrolytic module starts to be exposed in the air for dry burning, so that the service life of the ion exchange membrane/interlayer is influenced.
The structural form of the vertical electrolysis module can control the residual quantity of the aqueous solution/liquid medicine to be the lowest like a common atomizer, and is suitable for the aqueous solution/liquid medicine which is expensive or has higher requirement on the residual quantity control.
What has been described above are merely some embodiments of the present invention. It will be apparent to those skilled in the art that various changes and modifications can be made without departing from the inventive concept herein, and it is intended to cover all such modifications and variations as fall within the scope of the utility model.
Claims (8)
1. A hydrogen-rich ion atomization functional component is characterized by comprising a shell, a liquid storage bin arranged in the shell, an external connection port arranged on one side of the shell and communicated with the liquid storage bin, a vertical electrolysis module or a horizontal electrolysis module arranged in the liquid storage bin, and an atomization module structure arranged between the shell and the external connection port;
a rear cover is arranged on the shell at one side of the vertical electrolysis module;
the vertical electrolytic module comprises a first support arranged in a liquid storage bin, a first negative electrode electrolytic sheet and a first positive electrode electrolytic sheet which are arranged on the first support, a first ion exchange medium arranged between the first negative electrode electrolytic sheet and the first positive electrode electrolytic sheet, a first silica gel sealing sleeve sleeved on the first negative electrode electrolytic sheet and the first positive electrode electrolytic sheet, a first positive electrode contact and a first negative electrode contact which are respectively connected with the first negative electrode electrolytic sheet and the first positive electrode electrolytic sheet, a containing bin formed by the inner wall of the shell and arranged on one side of the first support, and a first air outlet hole which extends through the shell and the rear cover and arranged on the containing bin;
atomizing module structure include the inner shell that is equipped with inside between shell and external switching mouth, the second silica gel seal cover that is equipped with at the inner shell, the atomizing module that is equipped with on second silica gel seal cover, and the end cover that is equipped with on second silica gel seal cover one side.
2. The hydrogen-rich ion atomizing functional assembly according to claim 1, wherein a first dry-heating prevention probe is disposed in the reservoir; and a first end face contact connected with the first anti-dry heating probe is arranged on the bottom of the shell.
3. The hydrogen-rich ion atomizing functional component according to claim 2, wherein a first atomizing electrode contact connected with the atomizing module is arranged on the outer portion of the external adapter.
4. The hydrogen-rich ion atomizing functional component according to claim 1, wherein a seal gasket and a first seal ring are disposed between the rear cover and the housing.
5. The hydrogen-rich ion atomization functional assembly according to claim 1, wherein the horizontal electrolysis module comprises a second support arranged in the liquid storage bin, a third support arranged on the second support, a second negative electrode electrolyte sheet and a second positive electrode electrolyte sheet arranged between the third support and the bottom of the liquid storage bin, a second ion exchange medium arranged between the second positive electrode electrolyte sheet and the second negative electrode electrolyte sheet, a third silica gel sheathed on the second negative electrode electrolyte sheet and the second positive electrode electrolyte sheet, a negative electrode conductive screw arranged on the second negative electrode electrolyte sheet on one side of the liquid storage bin and extending downwards through the second negative electrode electrolyte sheet and the second positive electrode electrolyte sheet, a negative electrode conductive nut arranged on an end of the negative electrode conductive screw, an electrical isolation pad arranged between the second positive electrode electrolyte sheet and the negative electrode conductive nut, a positive electrode conductive elastic sheet arranged between the electrical isolation pad and the second positive electrode electrolyte sheet, and a negative electrode conductive elastic sheet arranged between the second positive electrode electrolyte sheet, A negative conductive elastic sheet is arranged between the electrical isolation pad and the negative conductive nut, a negative conductive gasket is arranged between the negative conductive elastic sheet and the electrical isolation pad, the bottom of the second bracket is provided with a positive electrode guide post and a negative electrode guide post which are respectively contacted with the positive conductive elastic sheet and the negative conductive gasket, the bottom of the shell is provided with a bottom cover, and the bottom cover is provided with a second air outlet hole communicated with the inside of the shell;
and a second sealing ring is arranged between the bottom cover and the shell.
6. The hydrogen-rich ion atomizing functional assembly according to claim 5, wherein a second dry-heating prevention probe is disposed in the reservoir; and a second end surface contact connected with the second anti-dry heating probe is arranged on the bottom of the shell.
7. The hydrogen-rich ion atomizing functional component according to claim 5, wherein a second positive electrode contact and a second negative electrode contact connected to a second negative electrode electrolytic sheet and a second positive electrode electrolytic sheet, respectively, are provided on the bottom of the housing.
8. The hydrogen-rich ion atomizing functional component according to claim 5, wherein a second atomizing electrode contact connected with the atomizing module is arranged on the outer portion of the external adapter.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202121021482.0U CN215426695U (en) | 2021-05-13 | 2021-05-13 | Rich hydrogen ion functional assembly that atomizes |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202121021482.0U CN215426695U (en) | 2021-05-13 | 2021-05-13 | Rich hydrogen ion functional assembly that atomizes |
Publications (1)
Publication Number | Publication Date |
---|---|
CN215426695U true CN215426695U (en) | 2022-01-07 |
Family
ID=79707115
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN202121021482.0U Active CN215426695U (en) | 2021-05-13 | 2021-05-13 | Rich hydrogen ion functional assembly that atomizes |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN215426695U (en) |
-
2021
- 2021-05-13 CN CN202121021482.0U patent/CN215426695U/en active Active
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN107773829B (en) | Gas generator | |
JP5788247B2 (en) | Mist generator and mist generator | |
CN106430453B (en) | Electrolysis water cup | |
KR101020982B1 (en) | Water ionizer | |
KR101728010B1 (en) | Ultrasonic generating apparatus for hydrogen water mist | |
CN205472822U (en) | Hydrogen water manufacturing installation | |
JP2005087257A (en) | Method of inhalation of hydrogen gas into body and its device | |
CN105879098A (en) | Hydrogen-rich hydrogen water atomization device | |
WO2021189614A1 (en) | Ozone water ultrasonic atomization structure and ozone water spray bottle having same | |
KR20160133621A (en) | Spray for hydrogen water | |
TWM536542U (en) | Healthy gas generating system | |
KR20140107774A (en) | Sterilizing humidifier | |
CN111001525A (en) | Multifunctional portable electrolytic spraying device and working method thereof | |
JP2009208021A (en) | Water absorption device and atomizer | |
WO2012043230A1 (en) | Functional mist generating device | |
CN215426695U (en) | Rich hydrogen ion functional assembly that atomizes | |
CN113144352A (en) | Hydrogen-rich ion atomization functional assembly and application method thereof | |
KR20170136121A (en) | Generating apparatus for mist having a water tank | |
JP6373213B2 (en) | Mist generator | |
KR101036381B1 (en) | Alkali ion water generator | |
JP5213793B2 (en) | Active oxygen generator, humidifier, air purifier | |
KR101919571B1 (en) | Electrode structure and hydrogen enriched water producing apparatus for enriching hydrogen concentration in freshwater or tap water, and wireless hydrogen enriched water producing apparatus for the same | |
CN212596708U (en) | Atomizing assembly and portable sterilizer | |
CN211937593U (en) | Multifunctional portable electrolytic spraying device | |
CN217817287U (en) | Atomizing disinfection device |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
GR01 | Patent grant | ||
GR01 | Patent grant |