KR102435748B1 - Anion Superheated Steam Chamber for Power Generation - Google Patents

Abstract

The present invention relates to a negative ion superheated steam hydrolysis chamber for power generation. Specifically, the present invention relates to the chamber which maintains an internal temperature at 800 to 1200 ℃ with hydrogen, methane, an aqueous alcohol solution, an oil, LPG, oxygen, hydrogen magnetized water, a negative ion magnetizer, magnetized water, and negative ion magnetized air. According to the present invention, when an internal temperature of the chamber decreases, the LPG and oxygen are further injected to maintain the internal temperature of the chamber. In addition, one side inside the chamber is wrapped and steam is sprayed from a hydraulic pump to generate superheated steam through a superheated steam generator accommodated on one side inside the chamber. In addition, the generated superheated steam is supplied to a steam double tube boiler and delivered to a turbine. The negative ion superheated steam hydrolysis chamber for power generation of the present invention comprises: a nozzle (10); the chamber (20); and the steam double tube boiler (30).

Description

Anion Superheated Steam Chamber for Power Generation

The present invention relates to an anion superheated steam hydrolysis chamber for power generation.

Specifically, hydrogen, methane, aqueous alcohol solution, oil (oil), LPG, oxygen, hydrogen magnetized water, anion magnetizer, magnetized water, and anion magnetized air to maintain the internal temperature at 800 ~ 1200 ℃, When the internal temperature of the chamber decreases, more LPG and oxygen are injected to maintain the internal temperature of the chamber, and steam is sprayed from the hydraulic pump around one side of the chamber to generate superheated steam through the superheated steam generator accommodated on one side of the chamber. , It relates to an anion superheated steam hydrolysis chamber for power generation that supplies the generated superheated steam to a steam double tube boiler and delivers it to a turbine.

In general, to extract hydrogen by reforming fossil fuels, a method of catalytic cracking on a catalyst by adding steam or oxygen is generally used. Representative reforming methods include steam reforming, partial oxidation, and autothermal reforming.

Among the above reforming methods, the steam reforming method extracts hydrogen contained in water by reacting hydrocarbons with steam. During production, the production ratio of CO2 is low and a large amount of hydrogen can be obtained from a certain amount of hydrocarbons, but the process temperature is high. It has the disadvantage of high energy consumption.

As a technique for improving the above problems, the following prior literature is described. Registered Patent No. 10-2018297 (2019.08.29.) describes a combustion burner device using superheated steam.

It relates to a combustion burner device using superheated steam, comprising: an inner tube extending upwardly forming a main combustion space; , a first floor plate coupled horizontally across the lower end of the inner tube and the lower end of the exterior and closing the lower part of the separation space, and an auxiliary space extending below the first floor plate to form an auxiliary space communicating with the main combustion space A forming part, a nozzle body mounted on the first bottom plate and provided with a fuel injection nozzle and a steam injection nozzle, a fuel supply unit supplying fuel for combustion through the fuel injection nozzle, and spirally wound to be heated in the inner tube A heating tube having an extended winding portion and one end extending from the winding portion is connected in communication with the steam jet nozzle of the nozzle body, and a spray treatment unit connected through the other end of the heating tube to supply water into the heating tube in a sprayed state. be prepared

In addition, as another prior document, Patent Publication No. 10-2008-0026693 (2008.03.26.) describes a boiler apparatus using steam.

According to the present invention, the steam obtained from the steam generating tube is supplied to the injection nozzle, and the heat generated by combustion together with the fuel supplied from the fuel tank passes through the through hole in the steam generator tube, and the air sucked from the air intake is heated to the blower. It is discharged to the air heat outlet and supplied to the agricultural product drying device, generates high-temperature steam, and burns the steam while spraying it together with the waste oil to induce complete combustion of the waste oil and reinforce the thermal power to produce hot air from the lower and side surfaces of each drying room of the agricultural product drying device. It uses steam that can supply air heat to an agricultural product drying device that can dry agricultural products including red pepper, green tea leaf, sesame, perilla, rice, barley, wheat, tobacco leaf, ginseng, etc. by supplying a constant intensity.

In the above-described techniques, the configuration in which heat is not transferred to the outer case inside the chamber and the structure of the superheated steam generator generating steam in the chamber are different, and the energy supply for saving energy is also different.

Registered Patent No. 10-2018297 (2019.08.29.) Patent Publication No. 10-2008-0026693 (2008.03.26.)

An object of the present invention relates to an anion superheated steam hydrolysis chamber for power generation.

Specifically, hydrogen, methane, aqueous alcohol solution, oil (oil), LPG, oxygen, hydrogen magnetized water, anion magnetizer, magnetized water, and anion magnetized air to maintain the internal temperature at 800 ~ 1200 ℃, When the internal temperature of the chamber decreases, more LPG and oxygen are injected to maintain the internal temperature of the chamber, and steam is sprayed from the hydraulic pump by wrapping one side of the chamber to generate superheated steam through the superheated steam generator accommodated on one side of the inside of the chamber, , to provide an anion superheated steam hydrolysis chamber for power generation that supplies the generated superheated steam to a steam double tube boiler and delivers it to a turbine.

An anion superheated steam hydrolysis chamber for power generation according to the present invention, which has been devised to achieve the above-described object, includes a nozzle 10 for receiving fuel and igniting to generate a flame;

An inner case 410 that communicates from the inlet 401 to the outlet 402 and forms a superheated steam generator accommodating space 405 therebetween, and encloses the superheated steam generator accommodating space 405;

a chamber 20 comprising an outer case 400 accommodating the outer case 420 spaced apart from the inner case 401; and

The nozzle 10 is coupled to the inlet 401, and the steam double tube boiler 30 is coupled to the outlet 402,

The superheated steam generator 600 is accommodated in the superheated steam generator accommodating space 405 and the steam supplied from the nozzle 10 is used in the double tube boiler.

In addition, the nozzle 10,

A first ignition unit 110 for igniting fuel, a first ignition unit case 110a to which the first ignition unit 110 is inserted and protected, and a second fuel supply unit in which a second fuel supply hole 132 is formed 130, the first fuel supply unit 180 in which the first fuel supply hole 181 is formed, the third fuel supply hole 140 in which the third fuel supply hole 142 is formed, and the fourth fuel supply The fourth fuel supply part 150 in which the hole 152 is formed, the fifth fuel supply part and the sixth fuel supply hole 172 in which the fifth fuel supply hole 162 is formed, the seventh fuel supply hole 173 and the second fuel supply hole 172 are formed. A fuel supply rod 100 for supplying and igniting fuel composed of a sixth fuel supply unit 170 having 8 fuel supply holes 174 formed therein;

Confirm that the fuel supply rod connection hole 211 through which the fuel supply rod 100 passes, and a special glass are combined so that the inside of the chamber 20 can be visually checked on one side spaced apart from the fuel supply connection hole 211 The part 213 and the running water supply part 212 which is spaced apart from the confirmation part 213 and receives water through two or more and four or less through-holes along the circumference of the fuel supply connection hole 211, and the confirmation a flange portion 200 in which a second ignition portion 214 capable of ignition is formed on one side corresponding to the portion 213; and

It is characterized in that heat is discharged by a vortex phenomenon by the cone frame 300 having a cone shape that is widened from a narrow entrance to the outside at the rear surface of the flange part 200 .

In addition, the fuel supply rod 100,

It is characterized in that hydrogen, methane, alcohol aqueous solution, oil (oil), LPG, oxygen, hydrogen magnetization water, anion magnetizer, and magnetization water are supplied.

In addition, the cone frame 300,

An outer vortex wing 313 having a twisted shape and the plate is widened from a narrow entrance to a wide entrance along the longitudinal direction on the outside;

A second inlet hole 312 in which two rows of through holes are formed in the transverse direction between the outer vortex nallga 313, the two rows form a pair, and the two rows are farther away from each other in the direction of the wide entrance from the narrow entrance; and

On the inside of the cone frame 300, between the second inlet holes 312, the inner vortex blade 314 is twisted in the opposite direction from the outer vortex blade 313; characterized in that

In addition, the chamber 20,

Anion magnetizers (j) are coupled to both sides to supply anion magnetization oxygen,

Anion magnetized oxygen is supplied between the inner case 410 and the outer case 420 to perform an air cooling function.

In addition, the negative ion magnetizer j of the chamber 20 is characterized in that the negative ion magnetizing oxygen is supplied in the direction of the inlet 401 to help ignite the fuel.

In addition, the inner case 410,

a second case 412 surrounding the superheated steam generator accommodating space 405 on the inside;

Doedoe composed of a first case 411 spaced apart from the second case 412,

A steam hot water pipe 500 to which steam hot water is supplied is wound around the outer diameter of the second case 412, a hydraulic pump p is coupled to one side of the steam hot water pipe 500, and the hydraulic pump p Steam hot water is supplied via do.

In addition, the superheated steam generator 600,

a superheated steam body 610 supplied with heat;

A supply frame 611 having a plurality of perforations formed at one end and the other end of the superheated steam body 610; is coupled,

A central support portion 613 having a tube shape communicating with the center of the supply frame 611 and having a vortex groove formed on the outer diameter thereof is coupled to facilitate the accumulation and discharge of heat.

In addition, a supply plate 615 having a disk shape and having a plurality of perforations formed in one of the central support parts 613; is coupled and the other central support part 613 has a plurality of smaller perforations than the supply plate 615. The discharge plate 614; is coupled,

An extension rod 616 having a cylindrical shape at the other end to which the central support part 613 is coupled and having a thread formed on the outer diameter; characterized in that it is coupled.

In addition, in the superheated steam body 610,

an inner superheated steam body 621 for accumulating heat;

an inner supply frame 622 in which through holes are formed so that heat passes through both ends of the inner superheated steam body 621; And it is characterized in that the inner superheated steam generator 620 consisting of the inner exhaust frame 623 is coupled.

In the anion superheated steam hydrolysis chamber for power generation according to the present invention, various fuels are supplied through a nozzle and ignited, and there is an effect of increasing the combustion efficiency by supplying anion magnetized oxygen from the anion anion magnetizer.

In addition, the heat generated by igniting the fuel has the effect of maximizing the effect by using the vortex phenomenon of the cone frame.

In addition, the user can visually check the condition inside the chamber, and check the internal temperature from the outside of the chamber.

In addition, the superheated steam generator that receives heat generated by igniting fuel has many perforations and receives a lot of heat transfer, which has the effect of generating superheated steam through water.

In addition, since steam and hot water supplied through the superheated steam generator accommodating pipe are supplied, there is an effect of good energy efficiency.

1 is an overall perspective view of an anion superheated steam hydrolysis chamber for power generation.
2 is a perspective view of a nozzle of an anion superheated steam hydrolysis chamber for power generation.
3 is an exploded perspective view of a fuel supply rod and a flange portion of an anion superheated steam hydrolysis chamber for power generation.
4 is a perspective view of the first ignition unit, the first fuel supply unit, and the second fuel supply unit of the anion superheated steam hydrolysis chamber for power generation.
5 is a perspective view showing a fuel supply unit coupled to the anion superheated steam hydrolysis chamber for power generation.
6 is a cross-sectional view of an anion superheated steam hydrolysis chamber for power generation.
7 is an enlarged view of a nozzle rear portion of an anion superheated steam hydrolysis chamber for power generation.
8 shows a circulation path of anion magnetized oxygen in an anion superheated steam hydrolysis chamber for power generation.
9 is a cross-sectional view of a circulation diagram of anion magnetized oxygen supplied from an anion magnetizer of an anion superheated steam hydrolysis chamber for power generation.
10 is an overall perspective view of a heat storage unit of an anion superheated steam hydrolysis chamber for power generation.
11 shows an embodiment in which the steam hot water pipe of the anion superheated steam hydrolysis chamber for power generation surrounds a part of the inner discharge space and the superheated steam generator accommodating space.
12 shows an embodiment in which a plurality of chambers can be coupled to one steam double tube boiler of an anion superheated steam hydrolysis chamber for power generation.
13 is an embodiment showing a front view of a double tube inserted into a steam double tube boiler of an anion superheated steam hydrolysis chamber for power generation.
14 is an embodiment in which the anion superheated steam hydrolysis chamber for power generation is combined with other auxiliary assemblies to form a whole, and the entirety is shown to be combined inside the container.

The terms or words used in the present specification and claims are not to be construed as being limited to their ordinary or dictionary meanings, and the inventor may appropriately define the concepts of the terms in order to best describe his invention. Based on the principle, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Accordingly, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical spirit of the present invention, so various equivalents that can be substituted for them at the time of the present application It should be understood that there may be variations and examples.

Hereinafter, prior to the description with reference to the drawings, it is not shown or specifically described for the known components that are not necessary to reveal the gist of the present invention, that is, a known configuration that can be obviously added by those skilled in the art with ordinary knowledge. reveal the sound

The present invention relates to an anion superheated steam hydrolysis chamber for power generation.

Specifically, hydrogen, methane, aqueous alcohol solution, oil (oil), LPG, oxygen, hydrogen magnetized water, anion magnetizer, magnetized water, and anion magnetized air to maintain the internal temperature at 800 ~ 1200 ℃, When the internal temperature of the chamber decreases, more LPG and oxygen are injected to maintain the internal temperature of the chamber, and steam is sprayed from the hydraulic pump by wrapping one side of the chamber to generate superheated steam through the superheated steam generator accommodated on one side of the inside of the chamber, , It relates to an anion superheated steam hydrolysis chamber for power generation that supplies the generated superheated steam to a steam double tube boiler and delivers it to a turbine.

1 is an overall perspective view of an anion superheated steam hydrolysis chamber for power generation.

Referring to FIG. 1 , the nozzle 10, the chamber 20, and the steam double-tube boiler 30 communicate with each other while maintaining a horizontal level, and the superheated steam generated inside the chamber 20 is transferred to the steam double-tube boiler 30. connected to be supplied to

In order to keep the nozzle 10, the chamber 20, and the steam double tube boiler 30 horizontal, the nozzle 10 and the chamber 20 are seated on the upper part of the wagon 1 to have a height with the steam double tube boiler 30. It is configured to match the steam double tube boiler 30, the volume is large, and the weight of the nozzle 10 and the chamber 20 is heavy, so that a general adult uses the wagon 1 because it is difficult to move.

The wagon 1 has wheels running on the lower part so that a general object can be seated and moved to a desired position, and a handle is run so that a user can move it.

And it may be configured in a hydraulic type so that the height of the nozzle 10 and the chamber can be adjusted, the wagon plate 2 having a predetermined width is formed on the hydraulic upper part, and the same width is on the top of the wagon plate 2 The support plate 3 having a is configured to be seated.

It is composed of a wide and strong iron plate to support various objects on the upper portion of the support plate 3 , and a support leg having a predetermined length is formed under the support plate 3 , and a predetermined space spaced apart from the cart plate 2 . is formed, and the liquid is discharged in the downward direction without accumulating through the space to prevent corrosion of the nozzle 10 and the chamber 20 .

At this time, the nozzle 10 is a plurality of horizontal support (4) is coupled to hold the position of the nozzle (10) from the support plate (3) so as to form a level with the chamber (20).

The nozzle 10 is configured to be ignited by being supplied with fuel, and may lead to an explosion when the nozzle 10 is defective. To prevent this in advance, the nozzle 10 is covered with a safety cover (c) to minimize accidents.

The safety cover (c) is accommodated up to the flange adjacent to the nozzle 10 to further increase safety, but a handle is formed on one side so that it can be opened and closed by a user or a machine.

The safety cover (c) is hinged to one side of the support plate (3) and configured to be opened and closed through rotation, and an opening is further formed on one side of the safety cover (c) to connect the nozzle (10) to the connection part (y`) or It is configured to supply fuel through the fuel supply unit (y) without opening the safety cover (c).

On the other hand, a fixed leg having a predetermined height is formed on the bottom surface of the safety cover (c) so that water does not accumulate between the space separated from the support plate (3), and corrosion of the nozzle (10), the safety cover (c), and the support plate (3) to prevent

The nozzle 10 is supplied with hydrogen, methane, aqueous alcohol solution, oil (oil), LPG, oxygen, hydrogen magnetized water, anion magnetizer, magnetized science water, anion magnetized air, and anion magnetized air is supplied according to the user. .

2 is a perspective view of a nozzle of an anion superheated steam hydrolysis chamber for power generation, FIG. 3 is an exploded perspective view of a fuel supply rod and a flange part of an anion superheated steam hydrolysis chamber for power generation, and FIG. 4 is an anion superheated steam for power generation A perspective view of the first ignition unit, the first fuel supply unit, and the second fuel supply unit of the hydrolysis chamber is shown. A cross-section of the anion superheated steam hydrolysis chamber for power generation is shown.

2 to 6 , the nozzle 10 is coupled to a fuel supply rod 100 , a flange portion 200 , and a cone frame 300 . Among them, the fuel supply rod 100 receives various fuels and ignites the fuel to generate thermal energy.

The fuel supply rod 100 includes a first ignition unit 110 , a first ignition unit case 110a, a first fuel supply unit 180 , a second fuel supply unit 130 , a third fuel supply unit 140 , and a second fuel supply unit ( 140 ). It is composed of a fourth fuel supply unit 150 , a fifth fuel supply unit 160 , and a sixth fuel supply unit 170 .

of the first ignition unit case 110a, the first fuel supply unit 180, the second fuel supply unit 130, the third fuel supply unit 140, the fourth fuel supply unit 150, and the fifth fuel supply unit 160 The structures have the same structure, but have different shapes only in size and length. This is to sequentially combine to form one rod, supply different fuels to each fuel supply unit, and discharge them through one rod.

The fuel is from the first fuel supply hole 182 to the seventh fuel supply hole 173, hydrogen, methane, an aqueous alcohol solution, oil (oil), LPG, oxygen, hydrogen magnetization science water, anion magnetizer, magnetization science water, The negative ion magnetizing air may be supplied in the order desired by the user, and a plurality of them may be supplied in duplicate, but the present invention is not limited thereto.

In addition, according to the embodiment, a fuel supply hole may be further formed on one side of the first ignition unit case 110a, and fuel may be supplied and discharged in one direction, but is not limited thereto.

The fuel supply hole (182, 132, 142, 152, 162, 172, 173, 174) is coupled to a fuel supply unit (y) composed of a pipe, a pressure gauge, and a fuel control unit to supply fuel.

Among the supplied fuels, hydrogen is abbreviated as green hydrogen (MOH).

When the green hydrogen (MOH) is used as a fuel for co-firing, the presence of nitrogen corresponding to 79% of the air used as an oxidizing agent acts as a factor preventing effective heating.

Since 1 mole of hydrogen molecules exist in 1.5 moles of water WEG (WATER ELECTROLYSIS GAS), it generates about 240,000 J of heat with a low gastric calorific value. rises In other words, 79% of unreacted nitrogen is not present when air is used as the oxidizing agent. Therefore, the heating capacity of water electrolysis gas generated from 1 mole of water is greatly increased by 5.8 times if 100% excess air is compared with gasoline combustion.

Accordingly, when green hydrogen (MOH) is supplied, energy efficiency can be increased.

On the other hand, a connection part y` is coupled between the fuel supply hole 182, 132, 142, 152, 162, 172, 173, 174 and the fuel supply part y, so that the fuel supply hole 182, 132, 142, 152, 162, 172, 173, 174) can be prevented from being worn.

In addition, the connection part (y`) is a bolt-shaped pin through which fuel is injected, and a valve that is screwed to the pin to supply and block fuel is coupled, and the reason why the valve of the connection part (y`) is added is It is configured so that the user can visually check the inside of the chamber 20 through the confirmation unit 213 to be described later and quickly cut off or open the fuel supply.

The fuel supply rod 100 to which the fuel supply part y and the connection part y` are coupled is connected as follows, and the ignition tube 112 of the first ignition part 110 is connected to the first ignition part case 110a. ) inserted inside, the ignition head 111 may come out or may be configured in a form in which the ignition head 111 is inserted or not, and the head portion of the first ignition unit case 110a is absent or protruded to the outside. may have, but are not limited to.

Thereafter, the second connection hole 133 is coupled to the screw on one side adjacent to the head of the first ignition unit case 110a, and the third connection portion 136 is connected to the inner screw thread of the first fuel head 181, and the The third connection hole 143 is coupled to the screw formed on one side adjacent to the first fuel head 181 , the fourth connection hole 153 is coupled to the fourth connection part 146 , and the fifth connection part 156 is coupled to the screw formed on one side adjacent to the first fuel head 181 . The fifth connection hole 165 is coupled, and the seventh connection part 171 is coupled to the sixth connection part 166 .

On the other hand, the other side of the fuel supply rod 100 from which the fuel is discharged is configured such that the fuel supply units 110, 120, 130, 140, 150, 160, 170 and the ends of the first ignition unit 110 are located on the same line so that any one does not protrude further.

Accordingly, the first ignition unit 110 , the first ignition unit case 110a , the second fuel supply unit 130 , the first fuel supply unit 180 , the third fuel supply unit 140 , and the fourth fuel supply unit 150 . ), the fifth fuel supply unit 160 and the sixth fuel supply unit 170 are coupled in this order, are inserted along the inner longitudinal direction, and are configured so that all fuel is discharged in one direction. At this time, one side of the discharged fuel supply rod 100 is configured to have a flat shape.

Meanwhile, the second fuel discharge unit 137, the first fuel discharge unit 183, the second fuel discharge pipe 134, the third fuel discharge pipe 144, the fourth fuel discharge pipe 154, and the fifth fuel discharge pipe 164 ), a vortex groove is formed in the outer diameter, so that fuel can be discharged quickly.

The first ignition unit 110 includes an ignition head 111 having an internal penetration to enable ignition from the outside, an ignition tube 112 communicating with an internal hole of the ignition head 111 and having a predetermined length; It is coupled to the inner hole of the ignition tube 112 and is composed of an ignition core 113 that protrudes a predetermined portion to the other side,

A first connection part 114 having a screw shape is formed on one side where the ignition head 111 and the ignition tube 112 contact each other so that the first fuel supply part 120 and the first ignition part 110 to be described later can be coupled. .

At this time, the ignition tube 112 is easily damaged when a force is applied in the form of an insulator so that the first ignition unit case 110a is coupled to protect the ignition tube 112 .

The first ignition unit case 110a includes a pipe having a predetermined length, a vortex groove formed in the outer diameter of the pipe so that fuel can be discharged, and a fuel supply and an ignition head are coupled to one side of the pipe, and the pipe The other side is configured so that the fuel can be discharged. The first ignition unit case 110a is inserted into the second fuel supply unit 130 .

The second fuel supply unit 130 supplies fuel and includes a second fuel head 131 having a predetermined size to be coupled to the first fuel supply unit 120 , and upper and lower centers of the second fuel head 131 . The second connection hole 133, which is threaded through but screwed with the second connection part 126, is communicated from one side of the outer diameter of the second fuel head 131 to the second connection hole 133. It is composed of a second fuel supply hole 132 for supplying fuel, and communicates with the second connection hole 133 on one side of the second fuel head 131 to receive and discharge fuel, and has a predetermined length. , a second fuel discharge pipe 134 through which the inside is penetrated, and a second fuel discharge part 135 in the form of a thread is formed on the outer diameter of the other side of the second fuel discharge pipe 124,

The second fuel discharging unit 137 is coupled to the second fuel discharging unit 135 to discharge fuel and ignite, so as to generate a flame through the fuel ignition.

The fuel discharging part 137 has a cylindrical shape and is configured to be screwed with the second fuel discharging part 135 by having a screw thread therein, a through hole is formed therein, and a longitudinal direction on the outer diameter circumference. Accordingly, a groove of a predetermined depth is formed in an oblique line.

And one more cylindrical shape having a small diameter is extended on the upper part of the cylinder, and a perforation is formed on the circumference and one side so that fuel and the ignited flame are discharged.

In addition, the cylindrical circumference of the fuel discharge unit 137 is coupled to the inner diameter of the cylinder of the first fuel supply unit 180 , and is configured to form a space through which fuel can be discharged.

In addition, a vortex-type groove is formed in the outer diameter of the second fuel discharging part 135 so that fuel can be discharged quickly.

The first fuel supply unit 180 has a predetermined length, a through hole through which fuel is discharged is formed therein, and a vortex groove is formed in the outer diameter along the longitudinal direction of the pipe to discharge the fuel supplied from the second fuel supply unit 130 . 1 is configured to be discharged in the direction of the fuel discharge unit 183 .

The outer diameter is too wide on one side of the cylindrical pipe of the first fuel supply unit 180, and the inner side communicates with the cylindrical pipe, and a thread is formed on the inner diameter so that it can be screwed with the third connection part 136, and the inner diameter on one side of the outer diameter The first fuel head 181 having a first fuel supply hole 182 penetrating through to supply fuel is formed, and the outer diameter of the cylindrical pipe is wider than that of the cylindrical pipe on the other side, and the outer diameter is penetrated so as to communicate with the cylindrical pipe on the inside, and the outer diameter A vortex groove is formed in the first fuel discharge unit 183 for discharging fuel.

A screw thread is formed on one side of the outer diameter of the cylindrical pipe to which the first fuel head 181 and the cylindrical pipe are coupled, and is configured to be coupled to the third connection hole 143 of the third fuel supply unit 140 .

The third fuel supply unit 140 has a third connection hole 143 that has an inner penetration so as to be screwed with the first fuel supply unit 180 and has a screw thread formed therein, and extends with the third connection hole 143 . A third fuel head 141 comprising a third fuel supply hole 142 for supplying fuel by forming a hole of a predetermined size on one side of the outer side, and coupled to one side of the third fuel head 141 to supply fuel to one side It communicates with the third connection hole 143 so as to discharge in the direction and is composed of a third fuel discharge pipe 144 having a predetermined length,

It is coupled to one side of the third fuel discharge pipe 144 to be coupled to a third fuel discharge unit 145 and a fourth fuel supply unit 150 having an inner side through and an oblique groove formed on the outside to discharge fuel. A thread is formed in the third fuel discharge pipe 144 adjacent to the third fuel head 141 so as to

In addition, a screw thread is formed in the outer diameter of the third fuel discharge pipe 144 so that the fuel supplied from the fourth fuel supply unit 150 can be discharged in the direction of the third fuel discharge unit 145 .

The fourth fuel supply unit 150 has a fourth connection hole 153 having a threaded interior therethrough to be screwed with the third fuel supply unit 140 , and a fourth connection hole 153 having an inner diameter, and extending from the fourth connection hole 153 . A fourth fuel head 151 having a fourth fuel supply hole 152 having a predetermined size hole formed on one side thereof to supply fuel, and a fourth fuel head 151 coupled to one side of the fourth fuel head 151 to supply fuel in one direction It communicates with the fourth connection hole 153 so as to discharge to

It is coupled to one side of the fourth fuel discharge pipe 154 to be coupled to the fourth fuel discharge unit 155 and the fifth fuel supply unit 160 having an inside through which the fuel is discharged and an oblique groove formed at the outside. A screw thread is formed on the outer diameter of the fourth fuel discharge pipe 154 adjacent to the fourth fuel head 151 so as to be screwed together.

The fifth fuel supply unit 160 has a fifth connection hole 163 having an inner penetration to be screwed with the fourth fuel supply unit 150 and having a thread formed on the inner diameter, and the fifth connecting hole 163 and the outside so as to extend with the fifth connection hole 163 . A fifth fuel head 161 comprising a fifth fuel supply hole 162 for supplying fuel with a hole having a predetermined size formed on one side thereof, is coupled to one side of the fifth fuel head 161 to supply fuel in one direction It communicates with the fifth connection hole 163 so as to discharge to the

It is coupled to one side of the fifth fuel discharge pipe 164 to be coupled to a fifth fuel discharge unit 165 and a sixth fuel supply unit 170 having an inside through which the fuel is discharged and an oblique groove formed at the outside. A thread is formed in the outer diameter of the fifth fuel discharge pipe 164 adjacent to the fifth fuel head 161 so as to be screwed together.

The sixth fuel supply unit 170 has a predetermined length, communicates in the longitudinal direction, has a thread formed on an inner diameter of one side adjacent to the outside, and is threadedly coupled to the fifth fuel supply unit 160 , a seventh connection unit 171 , and the second fuel supply unit 170 . It has a predetermined size hole on one side adjacent to the 7 connection part 171 and is composed of a sixth fuel supply hole 172 and a seventh fuel supply hole 173 for supplying fuel, and a seventh connection part 171 on the other side corresponding thereto. ) and an eighth fuel supply hole 174 for supplying fuel is formed.

In addition, the sixth fuel supply hole 172 and the seventh fuel supply hole 173 are configured to be spaced apart from each other by a predetermined distance so that the pipes or valves do not contact each other because the pipes and the valves are coupled.

And the sixth fuel supply unit 170 has a screw thread formed on the outer diameter of the other side in which the fuel supply hole is formed, and the fixing key k is attached to the front part so that it is coupled through the flange part 200 to be described later and is not released from the flange part 200 . And the fuel supply rod 100 by coupling to the rear portion is configured to be fixed to the supply flange portion 210 concisely.

This fixed key (k) has a predetermined thickness as shown in FIG. 3, has a screw thread on the inner diameter, and consists of a pair of two fixed keys having a ring shape, a washer penetrated therebetween and a number of protrusions in the outer diameter direction are stiff. are combined to form one fixed key (k).

On the other hand, the discharge flange portion 220 of the flange portion 200 is coupled to one side of the inlet 401 of the chamber 20, and is bolted to the supply flange portion 210 to be described later.

The supply flange part 210 has a disk shape of a predetermined thickness, the center of which is penetrated, and a fuel supply rod connection hole 211 through which the fuel supply rod 100 passes along the penetrating direction, and the fuel supply rod connection hole. 2 or more and 4 or less of oil water supply part 212 for receiving magnetizing water supply from the pump (p) and discharging it into the chamber 20 along the circumference spaced apart from the 211 by a predetermined distance is formed,

A confirmation part 213 and a fuel supply rod 100 on one side spaced apart from the confirmation part 213 so that the inside of the chamber 20 can be visually confirmed on one side of the upper side spaced apart from the fuel supply rod connection hole 211 A second ignition part 214 that can be ignited is formed by extending to one side adjacent to the outlet of the .

The confirmation unit 213 is configured so that a user can visually check the inside of the chamber 20 by combining a special glass that withstands the high temperature of 800 to 1200° C. inside the chamber 20 .

The discharge flange portion 220 is formed of a disk having the same size as the supply flange portion 210, and discharge flange holes 221 through which a flame discharged through ignition of the fuel supplied to the inside is discharged into the chamber 20. ) is formed, and a plurality of bolt holes are formed so as to be bolted to the supply flange part 210 in a circumferential direction spaced apart from the discharge flange hole 221 .

On the other hand, the discharge flange hole 221 has a circular plate shape and a hole through which the fuel supply rod 100 passes in the center, and a running water supply part 212 , a confirmation part 213 and a second ignition part 214 around the hole. ) and the heat insulating plate 230 in which the through hole located on the same line is formed is combined.

The heat insulating plate 230 has excellent insulation properties, so one or two is installed in the discharge flange hole 221 to prevent electricity of superheated steam generated inside the chamber 20 from being discharged to the outside through the inlet of the chamber 20 . are combined

The cone frame 300 will be described with reference to FIGS. 2 and 6 .

The cone frame 300 makes the heat of the flame stronger through the supply of anion and anion magnetizing oxygen supplied from the anion magnetizer j when a flame is generated from the fuel supply unit 100 to save fuel and quickly increase the internal temperature of the chamber 20 configured to be raised.

The cone frame 300 has a cone shape in which a plate of a predetermined thickness communicates from one side to the other, a narrow bore is coupled to one side of the discharge flange unit 220, and the discharge port 402 of the chamber 20 is directed toward It has an increasingly wider diameter.

That is, the inside is penetrated through the narrow inlet portion of the cone frame 300 , has a predetermined length, the extension portion 310 is coupled to one side of the discharge flange 220 , and has a wide inlet of the cone frame 300 . A bending prevention part 320 having a predetermined thickness is formed on the circumference.

The bending prevention part 320 is formed to be thicker than the plate thickness of the cone frame 300 to prevent the wide inlet end of the cone frame 300 from being bent or damaged at a high temperature.

In addition, a first inlet hole 311 having a predetermined length along the circumferential direction is formed on one side where the cone frame 300 and the extension part 310 are in contact, and a plurality of through holes are formed along the length direction of the cone frame 300 . Doedoe formed in two rows side by side in the transverse direction, the through-holes are spaced apart from each other toward the wide inlet direction of the cone frame 300 , and the second inlet hole 312 is located between the first inlet hole 311 and the first inlet hole 311 . ) is formed.

An outer vortex blade 313 is formed between the second inlet hole 312 and the second inlet hole 312, which protrudes a predetermined portion in the outward direction, widens from the narrow entrance to the wide entrance, and has a shape twisted at a predetermined angle. .

In addition, an inner vortex blade 314 larger than the outer vortex blade 313 is formed in the inner diameter of the cone frame 300 between one line of through-holes of the second inlet hole 312 and one line of the other through-holes.

At this time, the inner vortex blade 314 is configured to have a shape twisted at a predetermined angle and twisted in opposite directions to the outer vortex blade 313 .

That is, anion magnetized oxygen is introduced in the direction of the first inlet hole 311 and the second inlet hole 312 by the vortex wing 313, and the outlet 402 of the chamber 20 by the inner vortex wing 314. It is configured so that the discharge is made effectively in the direction.

On the other hand, the end of the fuel supply rod 100 is inserted up to the vicinity of the wide inlet of the cone frame 300 , and the second ignition part 214 is close to the end of the fuel supply rod 100 , that is, near where the fuel is discharged. ) is extended so that ignition can be performed through the second ignition unit 214 when the operation of the first ignition unit 110 of the fuel supply rod 100 is not smooth or it is difficult to ignite.

At this time, the second ignition part 214 penetrates through the first inlet hole 311 located at the center of the lower end as shown in FIG. 8 due to the difficulty in bending because it is magnetically wrapped on the outside and adjacent to the rear end of the fuel supply part 100 . designed to extend to

This nozzle 10 is coupled to one side of the chamber 20 to ignite the fuel, maintain the internal temperature of the chamber 20 at 800 to 1200° C., and discharge the supplied water from the steam hot water pipe 500 to be described later to overheat the inside. The steam is generated and the superheated steam is configured to raise the temperature of the steam double tube boiler (30).

7 is an enlarged view of the nozzle rear part of the anion superheated steam hydrolysis chamber for power generation, and FIG. 8 shows the circulation path of anion magnetized oxygen in the anion superheated steam hydrolysis chamber for power generation.

The chamber 20 has a hemispherical shape and has a space spaced apart from the ground in the lower part, so that a plurality of legs of a predetermined height are formed so that water (liquid) does not accumulate in the lower part.

This chamber 20 has an outer case 400 that blocks foreign substances, etc., an inlet 401 to which the nozzle 10 is coupled, and a steam double tube boiler 30 at the other end corresponding to the inlet 401 is coupled. It is composed of an outlet 402 that is.

An inner inlet space 403 in which the cone frame 300 is positioned adjacent to the inlet 401 and an inner outlet space 404 in which steam is discharged are formed in an inner side adjacent to the outlet 402 .

In addition, a superheated steam generator accommodating space 405 having a predetermined area is formed between the inner inlet space 403 and the inner outlet space 404 to which a superheated steam generator 600 to be described later is coupled.

Accordingly, the inlet 401 , the outlet 402 , the inner inlet space 403 , the inner outlet space 404 and the superheated steam generator accommodating space 405 communicate with each other.

A first case 411 having a horizontal inclination toward the inner inlet space 403 and the inner outlet space 404 while being horizontal on the inside of the outer case 400 adjacent to the portion of the superheated steam generator accommodating space 405 and, It is composed of an inner case 410 composed of a second case 412 spaced apart from the first case 411 .

An inner space 413 is formed between the first case 411 and the second case 412 , and the first case 411 and the second case 412 are connected to one side adjacent to the inlet 401 . The first vertical wall 416 and a first through hole 415 are formed at one side of the first vertical wall 416 .

A third case 417 is further formed between the first case 411 and the second case 412, and a predetermined steam hot water pipe space is formed between the third case 417 and the second case 412 ( 418 is formed, and a steam hot water pipe 500 to be described later is included in the steam hot water pipe space 418 .

The space of the anion magnetized oxygen supplied from the steam hot water pipe 500 and the anion magnetizer j to be described later may be separated.

A central space 419 is formed between the outer wall 425 spaced apart from the first case 411 and the outer wall 425 spaced apart from the first case 411, and spaced apart from the outer wall 425 An inner wall 426 is formed, and an outer space portion 429 is formed therebetween.

A second vertical wall 421 is formed in which one side of the outer wall 425 adjacent to the inlet 401 and one end of the inner wall 426 contact each other, and a central space portion ( 419) and the inner space portion 413 is configured to communicate.

A third vertical wall 423 having a predetermined length in the direction of the outlet 402 is formed at one end of the inner wall 426 corresponding to the second vertical wall 421, and one side of the third vertical wall 423 is formed. A penetrating third through hole 424 is formed.

On the other hand, a second through hole 422 is formed on one side of the second vertical wall 421 on which the outer space portion 429 is formed, and the second through hole 422 and adjacent to the outer space portion 429 direction are formed. An inclined vortex portion 428 having a predetermined inclination is formed on one side of the lower portion, and the inclined vortex portion 428 is formed.

In addition, a plurality of extended vortex portions 427 are spaced apart from each other by a predetermined interval so as to cause a vortex phenomenon along the longitudinal direction of the outer space portion 429 .

On the other hand, the outer wall 425 and the inner wall 426 is composed of an outer case (420).

And if the space into which anion magnetized oxygen is introduced through the anion magnetizer j is described, a supply part 430 is formed on one side adjacent to the inner inflow space 403 , and a plurality of parts are formed at the lower end of the supply part 430 . A supply plate 431 having four through-holes is formed.

On the other hand, the third case 417 and the second case 412 are configured to further protrude a predetermined portion in the direction of the outlet 402 .

The negative ion magnetizer j is formed on both sides adjacent to the inlet 401 of the chamber 20 and is connected to the supply unit 430 . And if the supply of anion magnetic oxygen is described with reference to FIG. 7 , the anion magnetic oxygen supplied to the supply unit 430 is accommodated in the supply unit 430 to the inner inlet space 403 and the second through hole 422 direction. supplied separately.

When supplied to the inner inlet space 403, it is supplied to the cone frame 300, and oxygen is added to the flame ignited in the fuel to improve thermal power.

And with the vortex phenomenon by the surface supplied through the second through hole 422, the inclined vortex portion 428, and the extended vortex portion 427, it passes through the outer space portion 429 at high speed to the third through hole 424. is supplied

Thereafter, it passes through the central space 419 and passes through the first through hole 415 to move along the longitudinal direction of the inner space 413 , and is discharged to the outlet 402 through the bent discharge unit 440 .

Through this, the heat igniting the fuel supplied from the nozzle 10 is prevented from being transferred to the outer case 400 .

On the other hand, the bent discharge part 440 is formed with a plurality of through-holes, and a predetermined portion protrudes along the longitudinal direction of the discharge port (402).

That is, the inner space 413 , the central space 419 , and the outer space 429 have an air cooling function by the anion magnetized oxygen supplied from the anion magnetizer j.

9 is a cross-sectional view of a circulation diagram of anion magnetized oxygen supplied from an anion magnetizer of an anion superheated steam hydrolysis chamber for power generation, and FIG. 10 is an overall perspective view of a heat storage unit of an anion superheated steam hydrolysis chamber for power generation.

It relates to a superheated steam generator 600 that is coupled to the inside of the chamber 20 to maintain the internal temperature of the chamber 20 at 800 to 1200° C. and generates superheated steam through water supply from the steam hot water pipe 500 .

At this time, the superheated steam generator 600 is heated by the thermal energy that ignites the fuel supplied from the nozzle 10 , and generates negative ion steam by the high temperature water supplied from the steam hot water pipe 500 .

The superheated steam generator 600 has a superheated steam body 610 communicating in the longitudinal direction, and has a predetermined thickness at one end and the other end of the superheated steam body 610, has a curved shape in an arcuate shape, and has a circumference on the front and side surfaces A supply frame 611 and a discharge frame 612 in which a plurality of through-holes are formed along the direction are coupled, respectively, and have a cylindrical shape with a center through the center of the supply frame 611 and the discharge frame 612, and A central support portion 613 in which a vortex-shaped groove is formed is coupled.

A discharge plate 614 having a predetermined thickness and formed with a plurality of perforations is formed at the other end of the central support portion 613 coupled to the supply frame 611, and the central support portion 613 coupled to the discharge frame 612. A supply plate 615 having a predetermined thickness and formed with a plurality of perforations is coupled to the other end, and the perforations of the discharge plate 614 are configured to have a larger diameter than the perforations of the supply plate 615 .

On the other hand, an extension rod 616 having a predetermined length on one side of the center of the supply plate 615 and having a vortex groove formed in the outer diameter is coupled.

And to the outer diameter of the superheated steam body 610 adjacent to the supply frame 611 and the discharge frame 612, a superheated steam support part 617 having the same size as the outer diameters of the discharge plate 614 and the supply plate 615 is coupled. .

An inner superheated steam generator 620 is coupled to the inside of the superheated steam body 610, and is configured to generate more steam by accumulating heat.

The inner superheated steam generator 620 has an inner superheated steam body 621 having a predetermined length and has a cylindrical shape through which the inside is penetrated, four through holes are formed at one end and the other end, respectively, and a through hole in the center, and has an arcuate shape. The inner supply frame 622 and the inner discharge frame 623 protruding into the are coupled to each other.

The inner diameter of the superheated steam body 621 has a cross shape, a through hole of a predetermined size is formed in the center, and is formed to cross the inner supply frame 622 and the inner discharge frame 623 misalignedly.

And the inner superheated steam support part 624 having a size to come into contact with the inner diameter of the superheated steam body 610 on the outer diameter of the inner superheated body 621 adjacent to the inner supply frame 622 and the inner discharge frame 623 and has a predetermined thickness. are joined in pairs.

At this time, a plurality of through-holes are formed in the inner overheating support part 624 along the circumferential direction to facilitate the movement of steam.

Meanwhile, the superheated steam generator 600 may be formed as shown in Tables 1 and 2.

Table 1 shows an example in which the superheated steam generator is not heated, and Table 2 shows an example in which the superheated steam generator is heated.

As shown in Tables 1 and 2, the superheated steam generator 600 is configured to maintain 800 to 1200°C.

11 shows an embodiment in which the steam hot water pipe of the anion superheated steam hydrolysis chamber for power generation surrounds a part of the inner discharge space and the superheated steam generator accommodating space.

One side supplying the water accommodated in the steam hot water pipe 500 is configured to be supplied through the pump (p) from one side of the chamber.

The steam hot water pipe 500 is configured to be wound along the longitudinal direction of the second case 412 closest to the superheated steam generator accommodating hole 405 at the rear end of the chamber 20 .

Accordingly, the water has a certain high temperature, not cold water, due to the internal temperature of the superheated steam generator accommodating hole 405, so that the temperature of the superheated steam generator 600 and the superheated steam generator accommodating hole 405 is not rapidly lowered. can save

And the wound one end passes through the other side of the chamber 20 and is coupled to the oil shoe supply unit 212 by a Y-pipe, respectively, and is configured to be sprayed into the superheated steam generator 600 .

At this time, the sprayed water stream is sprayed in the form of a mist to generate a lot of steam inside.

And a valve may be formed at one end of the Y-shaped pipe to stop the supply of water through the valve.

This may be used when the temperature of the internal superheated steam generator 600 gradually drops, making it difficult to generate steam or to finish work.

On the other hand, a water outlet (not shown) is formed on one side adjacent to each inclined end because water does not evaporate on the bottom surface of the superheated steam generator accommodating hole 405 and can be opened and closed through the valve. is composed

On the other hand, each through-hole is formed on each inclined side of the second case 412 so that the water (liquid) accumulated on the inner bottom surface of the second case 412 can be discharged to the outside by penetrating to the outer case 400, A liquid discharge pipe is coupled to one side of the outer case 400 to prevent water from accumulating therein.

12 shows an embodiment in which a plurality of chambers can be coupled to one steam double-tube boiler of the anion superheated steam hydrolysis chamber for power generation, and FIG. 13 is inserted into the steam double-tube boiler of the anion superheated steam hydrolysis chamber for power generation This is an example showing a front view of a double tube.

The steam heated through the nozzle 10 and the chamber 20 is supplied into the steam double tube boiler 30 , and the supplied steam is used to increase the internal temperature of the steam double tube boiler 30 .

At this time, when the capacity of the steam double tube boiler 30 is large, it is configured to supply steam heat by combining a plurality of chambers 20 as shown in FIG. 12 .

And, the inner double tube of the steam double tube boiler 30 may be formed as shown in FIG. 13, but is not limited thereto.

14 is an embodiment in which the anion superheated steam hydrolysis chamber for power generation is combined with other auxiliary assemblies to form a whole, and the entirety is shown to be combined inside the container.

On the other hand, the anion superheated steam hydrolysis chamber for power generation is coupled as shown in FIG. 14 and is configured to be coupled inside the container.

What has been described above using the drawings is to describe only the main points of the present invention, and it is obvious that the present invention is not limited to the configuration of the drawings as much as various designs are possible within the technical scope.

1 : Wagon 2 : Wagon board
3: support plate 4: fuel supply rod horizontal support
10: nozzle 20: chamber
30: steam double tube boiler
100: fuel supply rod
110: first ignition unit 110a: first ignition unit case
111: ignition head 112: ignition tube
113: ignition core 114: first connection part
130: second fuel supply unit
131: second fuel head 132: second fuel supply hole
133: second connection hole 134: second fuel discharge pipe
135: second fuel discharge part 136: third connection part
137: second fuel discharging part
140: third fuel supply unit
141: third fuel head 142: third fuel supply hole
143: third connection hole 144: third fuel discharge pipe
145: third fuel discharge part 146: fourth connection part
150: fourth fuel supply unit
151: fourth fuel head 152: fourth fuel supply hole
153: fourth connection hole 154: fourth fuel discharge pipe
155: fourth fuel discharge part 156: fifth connection part
160: fifth fuel supply unit
161: fifth fuel head 162: fifth fuel supply hole
163: fifth connection hole 164: fifth fuel discharge pipe
165: fifth fuel discharge part 166: sixth connection part
170: sixth fuel supply unit
171: 7th connection part 172: 6th fuel supply hole
173: 7th fuel supply hole 174: 8th fuel supply hole
180: first fuel supply unit
181: first fuel head 182: first fuel supply hole
183: first fuel discharge unit
200: flange part
210: supply flange part
211: fuel supply rod connection hole 212: oil supply part
213: confirmation unit 214: second ignition unit
220: discharge flange part
221: discharge flange hole
230: insulation plate
300: cone frame
310: extension
311: first inflow hole 312: second inflow hole
313: outer vortex blade 314: inner vortex blade
320: bending prevention part
400: outer case
401: inlet 402: outlet
403: inner inlet space 404: inner discharge space
405: superheated steam generator accommodating space
410: inner case
411: first case 412: second case
413: inner space 415: first through hole
416: first vertical wall 417: third case
418: steam hot water pipe space 419: central space
420: outer case
421: second vertical wall 422: second through hole
423: third vertical wall 424: third through hole
425: outer wall 426: inner wall
427: extended vortex part 428: inclined vortex part
429: outer space part
430: supply part 431: supply discharge part
440: curved discharge part
500: steam hot water pipe
510: first steam hot water pipe fixing ring 520: second steam hot water pipe fixing ring
600: superheated steam generator
610: superheated steam body 611: supply frame
612: exhaust frame 613: central branch
614: discharge plate 615: supply plate
616: extension bar 617: superheated steam support part
620: inner superheated steam generator
621: inner superheated steam body 622: inner supply frame
623: inner exhaust frame 624: inner superheated steam support part
c: cover j: anion magnetizer
k : fixed key s : temperature sensor
p : pump y : fuel supply part
y` : connection

Claims (10)

a nozzle 10 that receives fuel and ignites to generate a flame;
An inner case 410 that communicates from the inlet 401 to the outlet 402 and forms a superheated steam generator accommodating space 405 therebetween, and encloses the superheated steam generator accommodating space 405;
a chamber 20 comprising an outer case 400 accommodating the outer case 420 spaced apart from the inner case 410; and
The nozzle 10 is coupled to the inlet 401, and the steam double tube boiler 30 is coupled to the outlet 402,
In the anion superheated steam hydrolysis chamber for power generation, the superheated steam generator 600 is accommodated in the superheated steam generator accommodating space 405 and the steam supplied from the nozzle 10 is used in a double tube boiler,
The nozzle 10 is
A first ignition unit 110 for igniting fuel, a first ignition unit case 110a to which the first ignition unit 110 is inserted and protected, and a second fuel supply unit in which a second fuel supply hole 132 is formed 130, the first fuel supply unit 180 in which the first fuel supply hole 181 is formed, the third fuel supply hole 140 in which the third fuel supply hole 142 is formed, and the fourth fuel supply The fourth fuel supply part 150 in which the hole 152 is formed, the fifth fuel supply part and the sixth fuel supply hole 172 in which the fifth fuel supply hole 162 is formed, the seventh fuel supply hole 173 and the second fuel supply hole 172 are formed. A fuel supply rod 100 for supplying and igniting fuel composed of a sixth fuel supply unit 170 having 8 fuel supply holes 174 formed therein;
Confirm that the fuel supply rod connection hole 211 through which the fuel supply rod 100 passes, and a special glass are combined so that the inside of the chamber 20 can be visually checked on one side spaced apart from the fuel supply connection hole 211 The part 213 and the running water supply part 212 which is spaced apart from the confirmation part 213 and receives water through two or more and four or less through-holes along the circumference of the fuel supply connection hole 211, and the confirmation a flange portion 200 in which a second ignition portion 214 capable of ignition is formed on one side corresponding to the portion 213; and
Hydrolysis of negative ion superheated steam for power generation, characterized in that heat is discharged by a vortex phenomenon by a cone frame 300 having a cone shape that becomes wider from a narrow entrance to the outside at the rear side of the flange part 200 chamber.
delete The method according to claim 1,
The fuel supply rod 100,
Hydrogen, methane, aqueous alcohol solution, oil (oil), LPG, oxygen, hydrogen magnetized water, anion magnetizer, and magnetic field hydrolysis chamber for power generation, characterized in that it is supplied.
The method according to claim 1,
The cone frame 300,
An outer vortex wing 313 having a twisted shape and the plate is widened from a narrow entrance to a wide entrance along the longitudinal direction on the outside;
A second inlet hole 312 in which two rows of through holes are formed in the transverse direction between the outer vortex nallga 313, the two rows form a pair, and the two rows are farther away from each other in the direction of the wide entrance from the narrow entrance; and
On the inside of the cone frame 300, between the second inlet holes 312, the inner vortex blade 314 is twisted in the opposite direction from the outer vortex blade 313; Anion superheated steam hydrolysis chamber for power generation, characterized in that.
The method according to claim 1,
The chamber 20,
Anion magnetizers (j) are coupled to both sides to supply anion magnetization oxygen,
Anion superheated steam hydrolysis chamber for power generation, characterized in that the anion magnetic oxygen is supplied between the inner case (410) and the outer case (420) to perform an air cooling function.
6. The method of claim 5,
The anion magnetizer (j) of the chamber (20) is an anion superheated steam hydrolysis chamber for power generation, characterized in that the anion magnetized oxygen is supplied in the direction of the inlet (401) to help fuel ignition.
The method according to claim 1,
The inner case 410,
a second case 412 surrounding the superheated steam generator accommodating space 405 on the inside;
Doedoe composed of a first case 411 spaced apart from the second case 412,
A steam hot water pipe to which steam hot water is supplied is wound around the outer diameter of the second case 412,
A hydraulic pump (p) is coupled to one side of the steam hot water pipe (500), steam hot water is supplied through the hydraulic pump (p), and the other side of the steam hot water pipe (500) is coupled to the oil water supply unit (212). Anion superheated steam hydrolysis chamber for power generation, characterized in that the superheated steam is generated by spraying steam hot water through a high-pressure sprayer inside the superheated steam generator (600).
The method according to claim 1,
The superheated steam generator 600,
a superheated steam body 610 supplied with heat;
A supply frame 611 having a plurality of perforations formed at one end and the other end of the superheated steam body 610; is coupled,
Anion overheating for power generation, characterized in that it has a tube form communicating with the center of the supply frame 611 and has a vortex groove formed on the outer diameter thereof; is coupled to configured to facilitate the accumulation and discharge of heat. Steam hydrolysis chamber.
9. The method of claim 8,
A supply plate 615 having a disk shape and having a plurality of perforations formed in any one of the central support parts 613; is coupled and the other central support part 613 has a plurality of smaller perforations than the supply plate 615. publishing (614); combined,
Anion superheated steam hydrolysis chamber for power generation, characterized in that; an extension rod (616) having a cylindrical shape at the other end to which the central support part (613) is coupled and having a thread formed on the outer diameter.
9. The method of claim 8,
Inside the superheated steam body 610,
an inner superheated steam body 621 for accumulating heat;
an inner supply frame 622 in which through holes are formed so that heat passes through both ends of the inner superheated steam body 621; and an inner superheated steam generator (620) composed of an inner discharge frame (623) is coupled, anion superheated steam hydrolysis chamber for power generation.

Images