KR102607203B1 - Water molecule fission heat generator - Google Patents

Abstract

The present invention relates to a water molecule splitting heat generating device, the water molecule splitting heat generating device comprising: a housing provided with an accommodation space; an internal electrode installed in the receiving space of the housing; and an external electrode surrounding the outside of the internal electrode while maintaining a constant distance from the internal electrode, wherein the internal electrode and the external electrode are made of a non-magnetic material that eliminates the influence of magnetism between the internal electrode and the external electrode. It comes true.

Description

Water molecule fission heat generator {Water molecule fission heat generator}

The present invention relates to a water molecule splitting heat generating device.

Methods of heating room temperature water so that it has thermal energy are divided into gas boilers using gas as a heat source, electric boilers using electricity as a heat source, and electrode boilers using oscillating current generated from electrodes by electricity supply as a heat source.

Among the water heating methods, an electric boiler, which heats water by supplying electricity, is a heater type consisting of a structure equipped with a heating element that generates heat by the resistance of electricity supplied to a tank that stores a certain amount of water, and a power line to which a power line is connected. When installing electrodes and -electrodes in the tank, each electrode is fixed at a predetermined gap, and when current is supplied to the +electrode and -electrode, the water inside the tank is heated by the current caused by ion movement.

The prior art of this electrode method includes Republic of Korea Patent No. 10-1668985.

However, in the case of the prior art, when a current is applied to the internal and external electrodes, magnetism is generated between the internal and external electrodes, and various components in the water stick to the outer surface and inner surface of the external electrode, causing scaling and the internal electrode. There is a problem that corrosion occurs on the external electrode and the efficiency decreases over time.

In addition, as scaling and corrosion occur, when current is applied to the internal and external electrodes, the rust falls off due to collisions between water molecules, generating electrical resistance, which generates heat and increases the temperature of the internal and external electrodes. There is a problem with the external electrode melting.

In addition, there is a problem in that scaling occurring on the outer surface of the internal electrode and the inner surface of the external electrode accumulates over time, causing the outer surface of the internal electrode and the inner surface of the external electrode to come into contact with each other due to the accumulated scaling, thereby generating an electric spark.

The problem to be solved by the present invention is to provide a water molecule splitting heat generating device that does not cause scaling and corrosion on the internal and external electrodes.

In order to solve the above technical problem, according to a preferred aspect of the present invention, a water molecule splitting heat generating device includes: a housing provided with an accommodation space; an internal electrode installed in the receiving space of the housing; and an external electrode surrounding the outside of the internal electrode while maintaining a constant distance from the internal electrode, wherein the internal electrode and the external electrode are made of a non-magnetic material that eliminates the influence of magnetism between the internal electrode and the external electrode. A water molecule splitting heat generating device can be provided.

Here, the non-magnetic material may be any one of 300-series stainless steel, tungsten, and coated metal, and the coated metal may be a metal coated with at least one of titanium and nickel.

In addition, it further includes a power supply unit that supplies alternating current power to enable the water molecule splitting heat generating device to generate heat, and supplies direct current power to remove scaling generated on the outer surface of the internal electrode and the inner surface of the external electrode. can do.

According to another preferred aspect of the present invention, a water molecule splitting heat generating device includes: a housing provided with an accommodation space; an internal electrode installed in the receiving space of the housing; an external electrode surrounding the outside of the internal electrode while maintaining a constant distance from the internal electrode; an alternating current supply unit that supplies alternating current power to cause the water molecule splitting heat generating device to generate heat; and a direct current supply unit that supplies direct current power to remove scaling formed on the outer surface of the internal electrode and the inner surface of the external electrode.

Here, the power supply unit may supply alternating current power when generating heat with the water molecule splitting heat generating device.

Here, the direct current supply unit may supply direct current power when the efficiency of the water molecule splitting heat generating device decreases above a certain level.

The present invention maintains efficiency and prevents electrical sparks from occurring because scaling does not occur on the internal and external electrodes.

In addition, the present invention has the effect of achieving a high temperature because the internal and external electrodes are not corroded.

Figure 1 is a block diagram of a water molecule splitting heat generating device according to an embodiment of the present invention.
Figure 2 is a block diagram of a water molecule splitting heat generating device according to another embodiment of the present invention.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

Terms including ordinal numbers, such as first, second, etc., may be used to describe various components, but the components are not limited by these terms. These terms are used only to distinguish one component from another.

When a component is said to be 'connected' or 'connected' to another component, it may be directly connected or connected to the other component, but other components may exist in between. It must be understood that there is. On the other hand, when it is mentioned that a component is 'directly connected' or 'directly connected' to another component, it should be understood that there are no other components in between.

The terms used in this application are only used to describe specific embodiments and are not intended to limit the invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as 'comprise' or 'have' are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Figure 1 is a block diagram of a water molecule splitting heat generating device according to an embodiment of the present invention.

Referring to FIG. 1, the water molecule splitting heat generating device 100 includes a housing 110, an internal electrode 120, an external electrode 130, a power supply unit 140, a water supply pipe 150, and a heat discharge pipe 160. Includes.

The housing 110 has the shape of a container with an internal space, and water supplied through the water supply pipe 150 is accommodated therein.

The internal electrode 120 is installed in the internal space of the housing 110. Here, the internal electrode 120 may be circular, oval, egg-shaped, or rod-shaped.

The external electrode 130 is combined with the internal electrode 120 in a structure that surrounds the outside of the internal electrode 120 while maintaining a certain gap, and a plurality of grooves 131 are formed on the surface of the external electrode 130. . Here, when the internal electrode 120 and the external electrode 130 have an oval or rod shape, the vortex phenomenon due to bubble generation increases and heat generation efficiency can be higher than other shapes.

When the water contained in the housing 110 is filled with the groove 131 formed in the lower part of the external electrode 130, the space between the internal electrode 120 and the external electrode 130 is filled, and the internal electrode 120 and the external electrode ( Power is applied to 130) through the power supply unit 140.

At this time, electrolysis of water occurs in the space between the outer surface of the internal electrode 120 and the inner surface of the external electrode 130 by the power applied through the power supply unit 140, producing H ₂ , O ₂ , H ⁺ , O ^2- Alternatively, due to the ionization of water such as OH ^- , friction occurs when water molecules push and pull and collide with each other, the sonominesens phenomenon in which heat is generated in the process of creating and bursting fine bubbles, and the splitting of water molecules due to collisions between water molecules, resulting in heat. Gas and water accompanied by heat are generated, and the gas and water accompanied by heat thus generated are transmitted to the heat discharge pipe 160 through the groove 131 formed in the upper part of the external electrode 130, and the external electrode ( New water flows into the space between the internal electrode 120 and the external electrode 130 through the groove 131 formed at the bottom of 130, and the process of splitting water molecules and generating heat is repeated. Here, the gas and water with heat discharged through the heat discharge pipe 160 may be provided as water vapor or water with heat, that is, hot water, to a heat exchanger (not shown).

The internal electrode 120 and the external electrode 130 are made of a non-magnetic material that eliminates the magnetic influence between the internal electrode 120 and the external electrode 130. The non-magnetic material is 300 series stainless steel, and the non-magnetic material is a non-magnetic material that eliminates the magnetic influence. A magnetic material is a material that is non-magnetic or has little magnetism.

When power is applied to the internal electrode 120 and the external electrode 130 through the power supply unit 140 and the water molecule splitting and heat generation process is repeated, magnetism is generated in the internal electrode 120 and the external electrode 130. As time passes, scaling occurs in the internal electrode 120 and external electrode 130, and the internal electrode 120 and external electrode 130 corrode. The internal electrode 120 of 300 series stainless steel This can be prevented because the external electrode 130 is non-magnetic and resistant to corrosion. This can be confirmed through [Table 1] below.

200 series stainless steel ferritic stainless steel 300 series stainless steel Scaling attachment point 3 hours have passed 4.5 hours passed No occurrence Degree of scaling compared to surface area
(After operating the water molecule splitting heat generator for 24 hours) Approximately 3.2% adhered Approximately 2.6% adhesion No attachment Lifespan of water molecule splitting heat generating device (based on 12 hours of operation per day) About 9 months About 12 months semi-permanent significant Not only does scaling occur, but rust occurs due to corrosion. Not only does scaling occur, but rust occurs due to corrosion. No corrosion phenomenon

Referring to [Table 1], in the case of 200-series stainless steel, the nickel and chromium content is significantly lower than that of 300-series stainless steel and thus is magnetic, so scaling occurs after 3 hours of operating the water molecule splitting heat generator (100). Not only is it generated and attached to the outer surface of the internal electrode 120 and the inner surface of the external electrode 130, but also the internal electrode 120 and the external electrode 130 over time when the water molecule splitting heat generating device 100 is continuously operated and used. This corrosion phenomenon causes rust.

In addition, in the case of 400-series stainless steel, since it has less nickel content than 300-series stainless steel and is magnetic, scaling occurs after 4.5 hours after operating the water molecule splitting heat generator 100, causing damage to the outer surface of the internal electrode 120. Not only is it attached to the inner surface of the external electrode 130, but if the water molecule splitting heat generating device 100 continues to operate and is used, the internal electrode 120 and the external electrode 130 will rust due to corrosion over time.

However, in the case of 300 series stainless steel, since there is no magnetism, scaling does not occur and corrosion does not occur even if the water molecule splitting heat generating device 100 continues to operate.

In addition, the internal electrode 120 and the external electrode 130 may be any one of tungsten and a coated metal with a non-magnetic material that eliminates the magnetic influence between the internal electrode 120 and the external electrode 130. The metal may be a metal coated with at least one of titanium and nickel. This is because the inner electrode 120 and the outer electrode 130 made of tungsten and coated metal have a longer lifespan of the water molecule splitting heat generating device 100 than the inner electrode 120 and the outer electrode 130 made of other materials. This can be confirmed through [Table 2] below.

division Lifespan of water molecule splitting heat generating device (based on 12 hours of operation per day) tungsten semi-permanent Nickel (coating) About 36 months titanium
(coating) Approximately 24 to 36 months Dong, Hsinju Approximately 13 to 16 months copper About 6 to 7 months annotation About 1 month

Referring to [Table 2], the inner electrode 120 and the outer electrode 130 of tungsten are non-magnetic, so scaling and corrosion do not occur, so the lifespan of the water molecule splitting heat generator (based on 12 hours of operation per day) is semi-permanent. am.

In addition, the internal electrode 120 and external electrode 130 of metal coated with nickel last about 36 months, and the internal electrode 120 and external electrode 130 of metal coated with titanium last about 24 to 36 months. You can see that it has a longer lifespan.

The power supply unit 140 is installed outside the housing 110 and applies power to the internal electrodes 120 and external electrodes 130. Here, when the internal electrode 120 and the external electrode 130 are made of 300 series stainless steel or tungsten, the power supply unit 140 applies AC power, and the internal electrode 120 and the external electrode 130 are made of nickel or titanium. In the case of a coated metal, if the coating is peeled off, magnetism may occur and scaling may occur. Therefore, the power supply unit 140 supplies alternating current power to allow the water molecule fission heat generating device 100 to generate heat, and the water molecule fission heat If the efficiency of the generator 100 decreases, direct current power may be supplied to remove scaling formed on the outer surface of the internal electrode 120 and the inner surface of the external electrode 130.

The water supply pipe 150 is connected to the lower part of the housing and supplies water from the outside to the inside of the housing 110.

The heat discharge pipe 160 is connected to the upper part of the housing and discharges heat discharged from the groove 131 at the top of the external electrode 130 to the outside.

Figure 2 is a block diagram of a water molecule splitting heat generating device according to another embodiment of the present invention.

Referring to FIG. 2, the water molecule splitting heat generating device 200 includes a housing 210, an internal electrode 220, an external electrode 230, a power supply unit 240, a water supply pipe 250, and a heat discharge pipe 260. Includes.

Since the housing 210, water supply pipe 250, and heat discharge pipe 260 are the same as the water molecule splitting heat generating device 100 of FIG. 1, detailed description will be omitted.

The internal electrode 220 and external electrode 230 are the same as the internal electrode 120 and external electrode 130 of FIG. 1, but are made of general metals that are magnetic but are magnetic, such as 200 series and 400 series stainless steel, excluding 300 series stainless steel. It may be a material that is more resistant to corrosion.

The power supply unit 240 is installed outside the housing 210 and applies power to the internal electrode 220 and the external electrode 230, and the power supply unit 240 provides the direct current supply unit 241 and the alternating current supply unit 242. Includes.

The direct current supply unit 241 supplies direct current power to remove scaling formed on the outer surface of the internal electrode 220 and the inner surface of the external electrode 230.

,

The AC supply unit 242 supplies AC power to the internal electrode 220 and the external electrode 230 when generating heat with the water molecule splitting heat generating device 200.

The power supply unit 240 periodically supplies direct current power with a high instantaneous output force and a pushing force to the internal electrode 220 and the external electrode 230 through the direct current supply unit 241 for a short period of time to generate the internal electrode 220. ) and the inner surface of the external electrode 230 are removed. Here, the cycle in which the power supply unit 240 supplies DC power through the DC supply unit 241 is stored according to user settings. When the time comes, DC power is supplied through the DC supply unit 241 or a sensor (not shown) is used. When the efficiency of the water molecule splitting heat generating device 200 measured through the device decreases beyond a certain level, direct current power can be supplied. Additionally, the user can manually supply direct current power through the direct current supply unit 241 while using the device.

In addition, the direct current supply unit 241 is not included in the power supply unit 240, and can be operated in a portable form by connecting to an external power terminal (not shown) of the water molecule splitting heat generating device 200.

The output, operating time, etc. according to the type of the direct current supply unit 241 can be confirmed through [Table 3] below.

12V DC applied 54V DC applied form When the direct current supply unit 241 is included in the power supply unit 240 When the direct current supply unit 241 is not included in the power supply unit 240 and is in a portable form operating time 12 to 24 hours after water molecule splitting heat generation device operation After about 3 to 6 months of operation of the water molecule splitting heat generating device direct current supply
operating time 10 minutes 1 hours effect Remove scaling Remove scaling

Referring to [Table 3], when the direct current supply unit 241 is included in the power supply unit 240, the direct current supply unit 241 supplies a 12V direct current power internally after 12 to 24 hours of operation of the water molecule splitting heat generating device 200. By applying it to the electrode 220 and the external electrode 230 for 10 minutes, scaling generated on the outer surface of the internal electrode 220 and the inner surface of the external electrode 230 can be removed.

If the direct current supply unit 241 is not included in the power supply unit 240 and is in a portable form, the direct current supply unit 241 supplies 54V direct current power to the internal electrodes (220) after about 3 to 6 months of operation of the water molecule splitting heat generating device 200. ) and applied to the external electrode 230 for 1 hour, scaling generated on the outer surface of the internal electrode 220 and the inner surface of the external electrode 230 can be removed.

At this time, if the operating time of the direct current supply unit 241 is exceeded, the surfaces of the internal electrode 220 and external electrode 230 may be damaged, so care must be taken not to exceed the operating time of the direct current supply unit 241.

Although embodiments according to the present invention have been described above, they are merely illustrative, and those skilled in the art will understand that various modifications and equivalent scope of embodiments are possible therefrom. . Therefore, the true technical protection scope of the present invention should be determined by the following claims.

110: Housing 120: Internal electrode
130: external electrode 140: power supply unit
150: water supply pipe 160: heat discharge pipe

Claims (5)

In the water molecule splitting heat generating device,
A housing with accommodation space;
an internal electrode installed in the receiving space of the housing;
While maintaining a constant distance from the internal electrode,
Surrounding external electrode;
an alternating current supply unit that supplies alternating current power to cause the water molecule splitting heat generating device to generate heat; and
It includes a direct current supply unit that supplies direct current power to remove scaling formed on the outer surface of the internal electrode and the inner surface of the external electrode,
The direct current supply unit supplies direct current power while the alternating current supply unit supplies alternating current power when the efficiency of the water molecule splitting heat generating device measured through the sensor decreases.
A water molecule splitting heat generating device characterized by a.
In the water molecule splitting heat generating device,
A housing with accommodation space;
an internal electrode installed in the receiving space of the housing;
an external electrode surrounding the outside of the internal electrode while maintaining a constant distance from the internal electrode;
an alternating current supply unit that supplies alternating current power to cause the water molecule splitting heat generating device to generate heat; and
It includes a direct current supply unit that supplies direct current power to remove scaling formed on the outer surface of the internal electrode and the inner surface of the external electrode,
The DC supply unit supplies DC power while supplying AC power through the AC supply unit according to a cycle set by the user.
A water molecule splitting heat generating device characterized by a.
According to claim 1 or 2,
The internal electrode and the external electrode are made of a non-magnetic material that eliminates the influence of magnetism between the internal electrode and the external electrode.
A water molecule splitting heat generating device characterized by a.
According to claim 1 or 2,
The AC supply unit and the DC supply unit are included in the power supply unit.
A water molecule splitting heat generating device characterized by a.
According to claim 1 or 2,
The direct current supply unit is portable.
A water molecule splitting heat generating device characterized by a.

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