WO2016134612A1

WO2016134612A1 - Water storage type electric water heater capable of outputting electrolyzed water

Info

Publication number: WO2016134612A1
Application number: PCT/CN2016/000090
Authority: WO
Inventors: 罗民雄; 黎明
Original assignee: 罗民雄; 黎明
Priority date: 2015-02-26
Filing date: 2016-02-24
Publication date: 2016-09-01
Also published as: CN104633912A

Abstract

A water storage type electric water heater capable of outputting electrolyzed water comprises a water storage container (14), an electric water heater electronic control system (5), a controllable electrolytic power supply (9) and a membraneless electrolytic electrode assembly (10). The water storage type electric water heater is characterized in that: the water storage container (14) has a water inlet (18) and a water outlet (13); raw water enters the water storage container (14) from the water inlet (18) of the water storage container (14); the electric water heater electronic control system (5) controls heating of the water in the water storage container (14); the controllable electrolytic power supply (9) provides a current to the membraneless electrolytic electrode assembly (10); the membraneless electrolytic electrode assembly (10) electrolyzes the water in the water storage container (14); and electrolyzed water is output from the water outlet (13) of the water storage container (14). A membraneless electrolytic electrode assembly effectively electrolyzes, by using a membraneless water electrolysis technology, water that is stored in the water storage container and that falls within a required temperature range, and the water electrolysis efficiency is improved.

Description

Storage water electric water heater capable of outputting electrolyzed water

Technical field

The invention relates to a water storage type electric water heater capable of outputting electrolyzed water, belonging to the technical field of membrane-free electrolyzed water.

Background technique

The storage type electric water heater is widely used in bathing and using hot water, and the electrolyzed water with negative potential rich in hydrogen has the functions of anti-oxidation, sterilization and decontamination, and beauty cleansing, and is used as a bathing and washing water application. There are at least six major benefits: First, it can be used less or even without shower gels, so as to reduce adverse reactions such as skin allergies, itching and hair loss; second, there are some pruritus skin diseases such as athlete's foot (Hong Kong feet). Efficacy; Third, it has the health effects of anti-oxidation and anti-aging; beauty is the strong decontamination ability of washing equipment; fifth, washing fruits and vegetables have the function of removing pollution from pesticides and fertilizers; sixth is beneficial to environmental protection and reducing chemical pollution. It can be seen that the combination of electrolyzed water technology and water heaters to create a storage-type electric water heater that can output electrolyzed water is of great practical value and multi-faceted significance. So why haven't electric water heaters that can output electrolyzed water come out so far? The reason is: First, because the popular electrolysis machine uses low-efficiency membrane electrolyzed water technology, it can only electrolyze normal temperature water, and when the water temperature exceeds 50-60 degrees Celsius, the electrolyzed water index will disappear, and it is necessary to simultaneously output acid-alkaline Two kinds of water, small amount of water, large power consumption and other serious defects, obviously do not meet the needs of electrolyzed water heaters; second, the membrane-free electrolyzed water technology shows the advantages of membrane electrolysis water technology, for example: The unique advantage of electrolyzing any temperature raw water and outputting only one type of electrolyzed water, but the defect is that the electrolysis efficiency is still low. In the past, it was limited to the application of drinking pots and other electrolyzed natural static water devices to provide drinking water. Applicants found that the production of water storage type electric water heaters with practical value, due to the large water storage capacity, requires the use of membrane-free electrolyzed water technology with high electrolysis efficiency. The innovative development of membrane-free electrolyzed water technology has provided such inventions. With the feasibility, the present invention has come into being.

Summary of the invention

The invention provides a water storage type electric water heater capable of outputting electrolyzed water, which is created and designed for people to conveniently use electrolyzed water to bathe. Since the water storage capacity of the electric water heater is large, for the convenience and practical use, the membrane-free electrolyzed water technology with higher electrolysis efficiency should be adopted to meet certain electrolysis water index requirements. If the new principle and new method of electrolyzed water discovered and invented by the applicant are adopted, high electrolysis water efficiency and electrolyzed water index can be obtained, which is of great significance for improving the practicability of the electrolyzed water bath device. The water electrolysis efficiency or electrolysis water efficiency can be generally defined as: a representative index of electrolyzed water produced by electrolysis of a certain amount of water and electrolysis for a certain period of time (for example, ORP negative value or hydrogen content of electrolytically reduced water). The ratio of the quantity) to the amount of electricity consumed. In other words, in an electrolysis method or an electrolysis device, the smaller the electric energy consumed by the same amount of electrolysis to reach the same electrolyzed water index, the higher the electrolysis water efficiency of the device.

The new principle of electrolyzed water discovered by the applicant and the method for significantly improving the efficiency of electrolyzed water are rooted in the deep research on the main defects of the electrolysis water principle of the traditional electrolysis machine. The traditional electrolysis water principle is limited to the so-called ion chemical reaction equilibrium equation generated by water molecule electrolysis, completely ignoring the electrons and impurity particles generated by electrolysis of water impurities during electrolysis, and its importance for improving electrolysis water index and electrolysis efficiency. Significance, therefore, it is impossible to explain that the alkaline water in the cathode region has a higher index of higher reducing water, ie, a higher redox potential (ORP) negative value and a higher hydrogen content (H, H ₂ , H ⁻ ), completely ignoring the cathode. The formation of higher ORP negative and negative hydrogen (H ^- ) content in the zone water requires a significant amount of active electrons, so it cannot solve the problem that the existing electrolysis technology is too low, even if the electrolysis current is increased, it does not reach the expected higher electrolyzed water. The problem of indicators. The applicant's long-term research has won six new discoveries:

One of the new discoveries: in the process of electrolyzing water, in order to improve the efficiency of electrolyzed water, the first thing is to electrolyze impurities in water. Impurities are electrolyzed to produce free electrons and impurity particles which are beneficial to improve the index of electrolyzed water. This article is referred to as “impurity electrolysis effect”. The impurity electrolysis effect forms a certain electrolysis current, which causes the water molecules to disintegrate into hydrogen, oxygen ions or hydroxide ions. For "water molecule electrolysis effect." The efficiency and index of electrolyzed water are the result of the interaction between “impurity electrolysis effect” and “water molecule electrolysis effect”; the second discovery: reveals the dual meaning of active electrons generated by “impurity electrolysis effect” to improve electrolysis efficiency. It can increase the electrolysis current, and it has another important significance for electrolytically producing reduced water, which is to satisfy the negative value of ORP (negative redox potential) and its corresponding hydrogen content (negative hydrogen content) of certain electrolyzed water indexes such as electrolytically reduced water. The need for electronics. Therefore, in order to improve the electrolysis efficiency, the electrolysis process should strengthen the "impurity electrolysis effect" as much as possible to produce more active electrons; the newly discovered three: small gaps of different polarity electrodes (especially small gaps less than 1 mm) for strengthening "impurity electrolysis" "effect" has a significant effect, although the previous non-isolated membrane electrolyzed water technology also mentioned the design considerations of different polarity electrode spacing less than 3mm, but did not understand the practical significance of small spacing, and the matching process measures are even more difficult to talk about. The effect of significantly improving the efficiency of electrolyzed water cannot be achieved; the fourth finding: another important significance of the design of the small spacing of the electrolysis electrode gap is that it can create more opportunities and better conditions for the combination of active electrons and active hydrogen H into negative hydrogen. Thereby significantly improving the efficiency of electrolytic production of reduced water; the new discovery of five: the small gap of different polarity electrodes is small to a certain value, the electrolysis efficiency does not rise and fall, what is the reason? Studies have confirmed that to strengthen the "impurity effect of impurities", it is also necessary to ensure that the water has a certain flow in the gap between different polar electrodes during the electrolysis process, which can promote more water molecules and impurities to be electrolyzed repeatedly, thereby strengthening the "impurities". Electrolytic effect", improve water electrolysis efficiency and electrolyzed water reduction index; in-depth study of the flowability in the electrolysis water process, explains why the electrolysis water efficiency does not rise and fall after the electrolysis current increases to a certain value. The important reason is that if the flow of water in the electrode gap is not good, the ion concentration in the electrode gap will be too high, which will affect the electrolysis efficiency. The newly discovered six: for the electrolysis externally driven flowing water such as tap water, in the electrode assembly Within a certain space, adopting a design scheme that reasonably increases the area of the electrolytic gap is beneficial to the repeated electrolysis of more impurities and water molecules in the water, which can improve the water electrolysis efficiency and the electrolysis index. In addition, in the case of flowing water with too fast electrolysis flow rate, the channel for installing the electrolysis electrode assembly adopts a design in which the outlet passage (outlet) is appropriately narrower than the inlet passage (inlet), and the flow rate of water passing through the electrolysis electrode assembly can be reduced. Thereby increasing the time and opportunity for impurities and water molecules to be electrolyzed, and increasing the index of electrolyzed water.

Through comprehensive analysis of the above six new findings, the applicant proposed the following new principle of electrolyzed water: electrolyzed water process, firstly, the process of generating active electrons by electrolysis of impurities in water, forming electric current, and converting electric energy into decomposition energy of water molecules. Therefore, more water molecules are decomposed by obtaining larger electric energy, which is the basis for obtaining higher electrolysis efficiency, but obtaining higher electrolysis efficiency requires additional important conditions. This is because the electrolysis process is also: the various ions (especially active electrons) released by the electrolysis of the impurities and the various hydroxide ions and ion roots generated by the decomposition of water molecules. In the process of chemical action, there are two important conditions for improving the electrolysis efficiency of water. First, if more impurities are electrolyzed, more electrons and ions are released, and the probability of combining with hydroxide ions is Higher, the electrolyzed water index may be higher, and the electrolysis efficiency is higher. Second, if conditions can be created, the probability of combining the electron ions released by the electrolysis with the hydroxide ions is higher, and the electrolyzed water index may be higher. The electrolysis efficiency is also higher. For example, the higher ORP negative value and the hydrogen content of electrolytically reduced water (the applicant briefly refers to the two indicators as the "negative hydrogen" index), which requires more active electrons to participate. Therefore, impurities in the water are electrolyzed to release more electrons. And the combination of electrons and hydrogen ions with a higher probability of negative hydrogen can increase the negative hydrogen index and the electrolysis efficiency.

Applicant's new principle of electrolyzed water reveals that it is necessary to adopt a three-pronged process to improve the efficiency of electrolytic reduction water. It is necessary to strengthen the electrolysis of impurities in water, increase the electrons released by the electrolysis of impurities, and increase the electrons released by electrolysis. The probability of combining hydrogen with negative hydrogen. Applicant's research found a specific electrolysis process to achieve this three-pronged process: one is to appropriately reduce the distance between the electrolysis gaps of electrodes of different polarities, and the other is to appropriately enlarge the area of the electrolysis gap of electrodes of different polarities, and the third is to properly maintain The fluidity of water in and out of the gap between different polar electrodes in the electrolysis water process, the coordinated realization of these three technological conditions can better balance the effect of strengthening the impurity electrolysis and improving the reduction index, thereby significantly improving the efficiency of electrolysis water. The invention relates to a water storage type electric water heater capable of outputting electrolyzed water. Because of the certain requirements of water storage capacity and electrolysis water time, the use of a higher efficiency membrane-free electrolyzed water technology has higher practicability. The new method of electrolyzed water invented by the applicant is a better choice for improving the efficiency and performance of the device and the cost performance.

The invention relates to a water storage type electric water heater capable of outputting electrolyzed water, comprising a water storage container, an electric hot water electric control system, a controllable electrolysis power source and a membraneless electrolysis electrode assembly, wherein the water storage container has a water inlet and a water outlet. The raw water enters the water storage container from the water inlet of the water storage container; the electric water electric control system controls the heating of the water in the water storage container; the controllable electrolysis power supply supplies current to the membraneless electrolysis electrode assembly; the membraneless electrolysis electrode assembly is in the water storage container The water is electrolyzed; the electrolyzed water is discharged from the water outlet of the water storage container; the membrane-free electrolysis electrode assembly adopts a high-efficiency membrane-free electrolyzed water technology, and can effectively electrolyze the water stored in the required temperature range in the water storage container.

According to the second aspect of the present invention, the gap between the electrodes of different polarity electrodes is designed according to the principle of reasonable miniaturization, and the gap distance is less than 5 mm and greater than 0 mm, so as to enhance the impurities in the water. Electrolysis with water molecules; in a certain space occupied by the electrode assembly, the area of the gap between the electrodes of different polarities is designed according to the principle of reasonable enlargement, so that more impurities and water molecules in the water can be repeated many times in the electrode gap. Electrolytic electrode assembly and its installation process conditions are characterized in that water can flow smoothly in the gap of different polarity electrodes during electrolysis of water, so that the electrolyzed water in the gap of different polarity electrodes can be replaced and More impurities and water molecules are repeatedly electrolyzed by different polarity electrodes, increasing the probability and quantity of impurities and water molecules being electrolyzed by different polarity electrodes, thereby improving the electrolysis efficiency of water.

The third aspect of the present invention: the membraneless electrolytic electrode assembly, if necessary, the spacing between the electrodes of different polarity of the electrolytic electrode assembly can be as small as 1 mm or less, which is advantageous for a certain electrolysis power and a certain electrolysis electrode assembly structure. Strengthen the electrolysis of impurities and water molecules in water to improve the efficiency of water electrolysis.

According to the fourth aspect of the present invention, the membrane-free electrolytic electrode assembly can make daily drinking water and water into electrolytic reduction water having a negative oxidation-reduction potential and a hydrogen content greater than zero.

The fifth aspect of the invention: the membraneless electrolytic electrode assembly, the electrode structure of different polarities is designed to be: when the electrodes are When the water in the gap is electrolyzed to generate fluidity, the water and ions in the electrode gap can flow along the potential, so that more water flows through the gaps of the electrodes of different polarities, and the water that is electrolyzed in the gap is replaced, so that more impurities and water molecules in the water can be The current between the electrodes of different polarities is repeatedly electrolyzed several times, increasing the probability and quantity of impurities and water molecules being electrolyzed by different polarity electrodes, and improving the efficiency of water electrolysis.

According to the sixth aspect of the present invention, the membrane-free electrolytic electrode assembly has a certain space outside the two-port position of the electrode gap, so that water can flow smoothly in the gap of different polarity electrodes when the water flows during the electrolysis process. Improve the efficiency of water electrolysis.

According to the seventh aspect of the present invention, the membrane-free electrolytic electrode assembly can prolong the time during which the flowing water is electrolyzed in the electrode gap by making a reasonable increase in the area of the electrode gap in a certain space occupied by the electrolytic electrode assembly, so that more impurities and water are present. The molecules are repeatedly electrolyzed by different polarity electrodes to increase the probability and quantity of impurities and water molecules being electrolyzed by different polarity electrodes, thereby improving the efficiency of water electrolysis.

According to the eighth aspect of the present invention, in the case of the membrane-free electrolytic electrode assembly, when the material and shape of the electrolytic cell wall of the electrolytic electrode assembly are suitable as electrodes, the electrode can be appropriately connected as an electrolytic electrode to increase the gap area of the electrolytic electrode and increase the water. Electrolysis efficiency.

The nineth aspect of the present invention: the membraneless electrolytic electrode assembly is composed of two electrodes of different polarities, one of the electrodes is in the shape of a cylindrical hole, the number of cylindrical electrodes is N, N is equal to or greater than 1, and the wall of the tube is absent. Notched or notched, the positions of the electrodes of the respective barrel holes are mechanically fixed and electrically connected to each other; the second electrode is columnar, and the positions of the respective columns are mechanically fixed and electrically connected to each other, and the number of columns of the columnar electrodes is M, M is equal to or greater than 1 The column is hollow or solid, and may be unnotched or notched; the height of the cylindrical electrode and the columnar electrode is not limited, and is selected according to the requirement; the cylindrical electrode is inserted correspondingly to the columnar electrode, that is, the columnar electrode is inserted into each corresponding cylindrical hole In the middle, the gap between the surface of the inserted column electrode and the opposite surface of the barrel electrode is left to electrolyze the water; during the electrolysis work, the water in the electrode gap can flow; the outside of the two port positions of the electrode gap is fixed Space so that water can flow in the electrode gap during the process of being electrolyzed.

Basic technical solution: The invention relates to a water storage type electric water heater capable of outputting electrolyzed water, comprising a water storage container, an electric hot water electric control system, a controllable electrolysis power source, and a membraneless electrolysis electrode assembly, wherein the water storage container has a feed. The water inlet and the water outlet; the raw water enters the water storage container from the water inlet of the water storage container; the electric water electric control system controls the heating of the water in the water storage container; the controllable electrolytic power source supplies the current to the membraneless electrolytic electrode assembly; the membraneless electrolytic electrode assembly The water in the water storage container is electrolyzed; the electrolyzed water is output from the water outlet of the water storage container; the membrane-free electrolysis electrode assembly adopts a high-efficiency membrane-free electrolyzed water technology, and can effectively electrolyze the water stored in the required temperature range in the water storage container.

One of the specific technical solutions: the membrane-free electrolytic electrode assembly, the spacing of the gaps between the electrodes of different polarities is designed according to the principle of reasonable miniaturization, and the gap distance is less than 5 mm and greater than 0 mm, so as to enhance the impurities in the water. Electrolysis with water molecules; in a certain space occupied by the electrode assembly, the area of the gap between the electrodes of different polarities is designed according to the principle of reasonable enlargement, so that more impurities and water molecules in the water can be repeated many times in the electrode gap. Electrolytic electrode assembly and its installation process conditions are characterized in that water can flow smoothly in the gap of different polarity electrodes during electrolysis of water, so that the electrolyzed water in the gap of different polarity electrodes can be replaced and More impurities and water molecules are repeatedly electrolyzed by different polarity electrodes, increasing the probability and quantity of impurities and water molecules being electrolyzed by different polarity electrodes, thereby improving the electrolysis efficiency of water.

The second specific technical solution: the membrane-free electrolytic electrode assembly, if necessary, the spacing between the electrodes of different polarity of the electro-electrode assembly can be as small as 1 mm or less, which is advantageous for a certain electrolysis power and a certain electro-electrode assembly structure. Strengthen the electrolysis of impurities and water molecules in water to improve the efficiency of water electrolysis.

The third technical solution: the membrane-free electrolytic electrode assembly can make daily drinking water and water into electrolytic reduction water with a negative oxidation-reduction potential and a hydrogen content greater than zero.

The fourth technical solution: the membrane-free electrolytic electrode assembly, the electrode structure of different polarities is designed such that when water in the electrode gap is electrolyzed to generate fluidity, water and ions in the electrode gap can flow with each other so that more water flows. The electrode gaps of different polarities replace the electrolyzed water in the gap, so that more impurities and water molecules in the water can be repeatedly electrolyzed by the currents of different polarity electrodes, increasing the probability of impurities and water molecules being electrolyzed by different polarity electrodes. The quantity increases the efficiency of water electrolysis.

According to the fifth aspect of the invention, the membrane-free electrolytic electrode assembly has a certain space outside the two-port position of the electrode gap, so that when the water flows during the electrolysis, the water can flow smoothly in the gap of the different polarity electrodes. Improve the efficiency of water electrolysis.

The sixth technical solution: the membrane-free electrolytic electrode assembly can prolong the time of electrolysis of the flowing water in the electrode gap by increasing the area of the electrode gap within a certain space occupied by the electrolysis electrode assembly, so that more impurities and water are provided. The molecules are repeatedly electrolyzed by different polarity electrodes to increase the probability and quantity of impurities and water molecules being electrolyzed by different polarity electrodes, thereby improving the efficiency of water electrolysis.

According to a seventh aspect of the present invention, in the case of the membrane-free electrolytic electrode assembly, when the material and shape of the electrolytic cell wall of the electrolytic electrode assembly are suitable as an electrode, the electrode can be appropriately connected as an electrolytic electrode to increase the gap area of the electrolytic electrode and increase the water. Electrolysis efficiency.

A specific technical solution eight: the membrane-free electrolytic electrode assembly is composed of two electrodes of different polarities, one of the electrodes is a cylindrical hole shape, the number of cylindrical electrodes is N, N is equal to or greater than 1, and the wall of the tube can be Notched or notched, the positions of the electrodes of the respective barrel holes are mechanically fixed and electrically connected to each other; the second electrode is columnar, and the positions of the respective columns are mechanically fixed and electrically connected to each other, and the number of columns of the columnar electrodes is M, M is equal to or greater than 1 The column is hollow or solid, and may be unnotched or notched; the height of the cylindrical electrode and the columnar electrode is not limited, and is selected according to the requirement; the cylindrical electrode is inserted correspondingly to the columnar electrode, that is, the columnar electrode is inserted into each corresponding cylindrical hole In the middle, the gap between the surface of the inserted column electrode and the opposite surface of the barrel electrode is left to electrolyze the water; during the electrolysis work, the water in the electrode gap can flow; the outside of the two port positions of the electrode gap is fixed Space so that water can flow in the electrode gap during the process of being electrolyzed.

DRAWINGS

The invention is further illustrated by the following figures.

1 is a storage type electric water heater capable of outputting electrolyzed water according to Embodiment 1 of the present invention

detailed description

The basic structure and basic working principle of the embodiment will be described below with reference to FIG. 1 of Embodiment 1.

Example 1

As shown in FIG. 1 , a water storage type electric water heater capable of outputting electrolyzed water comprises a water storage container 14 , an electric hot water electric control system 5 , a controllable electrolysis power source 9 , and a membrane-free electrolysis electrode assembly 10 immersed in water. The working process is: the water storage container 14 has a water inlet 18 and a water outlet 13; Water enters the water storage container 14 from the water inlet 18 of the water storage container 14; the dotted line 15 in the figure is the water level line of the water in the water storage container 14; the electric hot water electronic control system 5 controls the heating of the water in the water storage container 14; the controllable electrolysis power supply 9 supplying current to the membraneless electrolysis electrode assembly 10; the electrolysis electrode assembly 10 electrolyzing the water in the water storage container; the electrolyzed water is output from the water outlet of the water storage container; the electrolysis electrode assembly adopts a higher efficiency membraneless electrolysis water technology for storage The water storage in the desired temperature range of the water container can be effectively electrolyzed; the electrolysis electrode assembly 8 is characterized in that two electrodes of different polarities are respectively a cylindrical electrode 1 (hereinafter referred to as a hole electrode) and can be correspondingly inserted. The toothed electrode 2, the tooth of the toothed electrode 2 is inserted into the corresponding hole of the hole electrode, and an electrolytic gap 3 is left between the tooth surface and the surface of the hole, and three gaps 3 are schematically illustrated in FIG. If necessary, it is selected in the range of more than 0 to 5 mm: in the case of satisfying the certain flowability of water in the gap 3 during the electrolysis work, the spacing of the gap 3 may take a small value (for example, equal to or even less than 2 mm) to strengthen the water and therein. Electrolytic effect of impurities, this It is especially advantageous to dilute water with low conductivity such as distilled water of purified water; in the case of a certain gap distance, it is obvious that the probability and quantity of impurities and water molecules being electrolyzed are proportional to the gap area, so the area of the gap 3 is larger (ie, pores). The diameter and height take a larger value) to improve the electrolysis efficiency; 11 and 12 are respectively the bottom and upper space of the electrolysis electrode assembly 8, which are designed to make the water flow smoothly in the electrode gap, and in the process of electrolyzing water, the gap After the water molecules are electrolytically decomposed, hydrogen and oxygen bubbles will flow upward along the gap, thereby causing the water in the gap 3 to flow upward and out of the upper port of the gap 3, causing water to continuously flow from the opening of the gap 3, that is, the space 11 In the electrode gap, during the flow of water in the gap, water impurities and water molecules are repeatedly electrolyzed by the electrolysis current in the gap; obviously, the gap 3 is reasonably selected for a small spacing and a large area and satisfies the gap 3 with good circulation of water. Sex, these three aspects of the coordination of the technical solutions are conducive to strengthen the electrolysis effect, improve the efficiency of the storage of water in the container 4 and the reference of electrolyzed water (E.g., the ORP of the electrolytic reduced water and negative hydrogen content). If the space of the gap 3 does not leave the

space

11 or 11 too narrow, the water in the gap 3 cannot flow smoothly, and the electrolysis efficiency will be significantly reduced. Similarly, the space of the gap 3 does not leave the

space

12 or 12 too narrow, and the electrolysis efficiency is also significantly reduced. However, there is another possibility that the flow velocity of the water in the electrode gap is too fast, and the treatment method is that the circulation space 12 of the water at the outlet outlet port can be appropriately narrower than the circulation space 11 of the inlet port water to appropriately slow the passage of water. The flow rate of the gap, thereby increasing the time during which the water in the gap is electrolyzed, and enhancing the electrolysis effect. Table 1 test data helps to understand the above description.

Table 1: The measured data of the first embodiment of the water storage type electric water heater capable of outputting electrolyzed water of the present invention

Note: Electrolytic voltage 12V, raw water: ORP=+365-402mv, hydrogen content=0, normal temperature

From the A, B column or A, C column detection data can be seen: the electrode gap 3 area difference is half, or the electrode The water flow difference in the gap and the electrolyzed water index are significantly different, which confirms the new principle and new method of electrolyzed water proposed by the applicant. The relevant test data proves that the storage type electric water heater capable of outputting electrolyzed water is feasible and innovative. Sexuality, practicality.

The invention relates to a water storage type electric water heater capable of outputting electrolyzed water, wherein the electrolysis electrode assembly is not limited to the specific structure adopted in the first embodiment, and in the selection of the actual product technical scheme, the storage of the electrolyzed water which can reach the present invention is used. Any type of membraneless electrolytic electrode structure required for the (electrical, low, high) electrolyzed water index of the water-type electric water heater product belongs to the protection scope of the present invention.

Claims

The utility model relates to a water storage type electric water heater capable of outputting electrolyzed water, comprising a water storage container, an electric hot water electric control system, a controllable electrolysis power source and a membraneless electrolysis electrode assembly, wherein the water storage container has a water inlet and a water outlet; the raw water Entering the water storage container from the water inlet of the water storage container; the electric water electric control system controls the heating of the water in the water storage container; the controllable electrolysis power supply supplies the current to the membraneless electrolysis electrode assembly; the membraneless electrolysis electrode assembly supplies the water in the water storage container Electrolysis is carried out; electrolyzed water is output from the water outlet of the water storage container; the membrane-free electrolysis electrode assembly adopts a high-efficiency membrane-free electrolyzed water technology, and can effectively electrolyze the water stored in the required temperature range in the water storage container.
The water storage type electric water heater capable of outputting electrolyzed water according to claim 1, wherein the gap of the gap between the electrodes of different polarity is substantially reduced according to the principle of the membraneless electrolytic electrode assembly Design, the gap distance is less than 5mm, greater than 0mm, in order to strengthen the electrolysis of impurities and water molecules in the water; in the space occupied by the electrolytic electrode assembly, the area of the gap between the electrodes of different polarities is designed according to the principle of reasonable enlargement Therefore, more impurities and water molecules in the water can be electrolyzed repeatedly in the electrode gap; the characteristics of the electrolysis electrode assembly and its installation process conditions are: water can be smoothly in the gap of different polarity electrodes during the electrolysis of water Flow, so that the electrolyzed water in the gap of different polarity electrodes can be replaced, and more impurities and water molecules are repeatedly electrolyzed by different polarity electrodes, increasing the probability and quantity of impurities and water molecules being electrolyzed by different polarity electrodes. , thereby increasing the electrolysis efficiency of water.
A water storage type electric water heater capable of outputting electrolyzed water according to claim 1, wherein: said membraneless electrolysis electrode assembly, if necessary, the spacing between electrodes of different polarity of the electrolysis electrode assembly can be as small as 1 mm Or smaller, in order to strengthen the electrolysis of impurities and water molecules in water under a certain electrolysis power and certain electrolysis electrode assembly structure, and improve the efficiency of water electrolysis.
The water storage type electric water heater capable of outputting electrolyzed water according to claim 1, wherein the membrane-free electrolytic electrode assembly can make daily drinking water and water into a redox potential and a hydrogen content. Electrolytic reduced water greater than zero.
A water storage type electric water heater capable of outputting electrolyzed water according to claim 1, wherein said membraneless electrolytic electrode assembly has different polarity electrode structure design: when water is electrolyzed in the electrode gap to generate flow When it is sexual, the water and ions in the electrode gap can flow with each other, so that more water flows through the gaps of different polarity electrodes, and the water that is electrolyzed in the gap is replaced, so that more impurities and water molecules in the water can be more current between the electrodes of different polarities. Repeated electrolysis repeatedly increases the probability and quantity of impurities and water molecules being electrolyzed by different polarity electrodes, improving the efficiency of water electrolysis.
A water storage type electric water heater capable of outputting electrolyzed water according to claim 1, wherein said membrane-free electrolytic electrode assembly has a space outside the two-port position of the electrode gap, so that water is electrolyzed. When the flow occurs, the water can flow smoothly in the gaps of different polarity electrodes, improving the efficiency of water electrolysis.
A water storage type electric water heater capable of outputting electrolyzed water according to claim 1, wherein said membrane-free electrolytic electrode assembly has a reasonable increase in the area of the electrode gap within a certain space occupied by the electrolytic electrode assembly. The time during which the flowing water is electrolyzed in the electrode gap can be prolonged, so that more impurities and water molecules are repeatedly electrolyzed by different polarity electrodes, increasing the probability and quantity of impurities and water molecules being electrolyzed by different polarity electrodes, and improving water electrolysis. effectiveness.
A water storage type electric water heater capable of outputting electrolyzed water according to claim 1, wherein said membraneless electrolytic electrode assembly is in the case where the material and shape of the electrolytic cell wall of the electrolytic electrode assembly are suitable as electrodes It can be appropriately connected as an electrolysis electrode to increase the gap area of the electrolysis electrode and improve the electrolysis efficiency of water.
The water storage type electric water heater capable of outputting electrolyzed water according to claim 1, wherein the membraneless electrolysis electrode assembly is composed of two electrodes of different polarities, and one of the electrodes is in the shape of a cylinder hole. The number of cylindrical electrodes is N, N is equal to or greater than 1, the wall of the tube can be free of gaps or gaps, and the positions of the electrodes of the respective barrel holes are mechanically fixed and electrically connected to each other; the second electrode is columnar, and the positions of the respective columns are mechanically fixed and Electrically connected to each other, the number of columns of the columnar electrode is M, M is equal to or greater than 1; the column is hollow or solid, and may be unnotched or notched; the height of the cylindrical electrode and the columnar electrode is not limited, as needed; The electrode is inserted into the column electrode, that is, each column of the column electrode is inserted into each corresponding tube hole, and a gap for electrolysis of water is left between the surface of the inserted column electrode and the opposite surface of the barrel electrode; during the electrolysis work, the electrode The water in the gap can flow; there is a space outside the two port positions of the electrode gap so that water can flow in the electrode gap during the electrolysis process.