KR20230057551A - Flowing-water acceleration system generator electricity for ectrolytic green-hydrogen plant - Google Patents

Abstract

Today, only about 100 years have passed since the start of civilization development based on fossil energy which is a finite buried resource, and human beings have arrived at a time to develop a new future energy source due to a severe situation with environmental pollution and climate changes. The present invention relates to technology for accelerating and utilizing kinetic energy of overland and maritime water currents (water flows) among water resources which are the most plentiful energy on the planet, and, more specifically, to technology for converting precious water current kinetic energy, which can be used for 24 hours on the land while being available for 40-70% of 24 hours on the sea depending on sea current and tidal current utilization methods, into permanently usable technical resource energy. Moreover, the present invention relates to a plant capable of producing renewable power by having a generator mounted in the plant, which can be moored on the water of the land or on the sea, to be linked with an acceleration system mechanism accelerating a water current step by step, and, occasionally, having a water current acceleration system mechanism and a renewable power production mechanism for producing green hydrogen by water-electrolyzing the produced renewable power, and a water-electrolysis green hydrogen production mechanism using the renewable power.

Description

Flowing Water Acceleration System Power Generation Power Water Electrolysis Green Hydrogen Plant

The present invention is a system that accelerates and energizes the kinetic energy of water currents such as running water in rivers and sea currents or ocean currents among water resources that are most abundant on earth and can be utilized 24 hours a day. Technology resource energy that generates green hydrogen by electrolyzing power obtained by water. It is about.

In general, methods of generating electricity using running water, tidal currents, and ocean currents are classified into tidal power generation and tidal or ocean current power generation. It is a method of generating electricity by installing a tidal current generator fixed in the water using kinetic energy such as running water, tidal current, and ocean current.

However, this conventional technology is a primitive method that utilizes the natural flow rate of flowing water, ocean currents, and algae, and the generation time is not irregular like wind power generation or solar power generation due to the flow rate deviation and the time difference between tidal tides, especially in the case of tidal power generation at sea. There were problems such as the production volume not being constant and the installation area being used only in a specific area that satisfies the conditions.

In order to solve the above problems, a separate system device with constant power generation time and power generation, expandable area of use, and high cost-effectiveness is required.

To this end, a facility that floats the water generator on the water and the sea is required, and by constructing and systematizing a shape for the safety and stability of the internal accelerator and floating facility, power is produced and the power produced is maximized by the flow of water acceleration kinetic energy. It is an object of the present invention to secure a permanent technical resource energy for green hydrogen production by building a plant that generates green hydrogen using

Currently, the power generation formula for wind, tidal and ocean current generators is P(KW)=0.5ρAV³, where ρ is the unit weight of gas or fluid, A is the area of the blade, and V is the wind speed or flow speed, which is the key to determining the power output. can know that

In order to solve the above-mentioned technical problems, the water electrolysis green hydrogen plant using the flow-accelerated power generation of the flow-through acceleration system power generation according to the present invention accelerates the running water when the plant is moored in the river and the sea to produce power and uses the produced power In the system for generating green hydrogen, the system is equipped with an internal fixed acceleration generator 200 and a variable accelerator 300, which are the core technologies of the present invention, in an underwater cabin 180 configured to allow running water to flow in and accelerate. Consisting of an acceleration inflow chamber 181, a variable acceleration inflow chamber 182, a fixed acceleration channel room 183, a fixed acceleration power generation room 184, and a variable acceleration outflow chamber 185, the flowing water is accelerated step by step and power is produced. When it is, it is characterized in that it is discharged to the outside without the influence of external running water.

In the present invention, unlike the prior art, a ship-type plant moored in rivers and seas accelerates the flow rate of natural flowing water step by step, but in particular, the flow rate is constantly accelerated according to the opening and closing angles of the inflow variable accelerator and the outflow variable accelerator, thereby generating power generation operation time and power It has the advantage of high utilization in rivers and seas by maintaining a constant production volume, and the portability and maintenance of the plant are easy, so the plant is moved and operated to the optimal location where cost-effectiveness is useful depending on the season. The country can obtain the effect of realizing a new and renewable energy producer or exporter by securing renewable power or green hydrogen technical resources on its own.

In addition, in the case of power generation in territorial waters or open seas that cannot be connected to the onshore power system, green hydrogen can be produced by purifying seawater and using a water electrolyzer. It realizes the effect of acquiring energy.

1 is a conceptual diagram of a lower deck, an inner wall, and a first deck according to the present invention
2 is a conceptual diagram of a fixed acceleration inclined wall, a double deck, and an outer wall according to the present invention
3 is a conceptual diagram of an upper deck, a first-floor cabin, and an upper deck facility according to the present invention
4 is a conceptual diagram and an assembly view of an internal fixed accelerator according to the present invention
5 is a conceptual diagram and an assembly view of a cylinder according to the present invention
6 is an assembly diagram and a conceptual view of opening and closing variable inflow and outflow accelerators according to the present invention
7 is an assembly view of a lower deck, inner wall, outer wall, and first deck according to the present invention
8 is an assembly diagram of a fixed acceleration inclined wall, an internal fixed accelerator, an inflow variable accelerator, and an outflow variable accelerator according to the present invention
9 is an assembly view of a double deck, a first floor cabin, and an upper deck according to the present invention
10 is an assembly diagram of an upper deck facility according to the present invention and a conceptual diagram of completed assembly of a plant hull, an internal fixed accelerator, and a variable accelerator
11 is a plan view of the underwater cabin structure of the horizontal axis accelerator generator according to the present invention and
Water flow acceleration flow chart according to the variable accelerator operation example
Figure 12 is a conceptual diagram of a plant installed on land and in the sea as a representative diagram according to the present invention.
13 is a power generated by a water flow acceleration system moored at sea in accordance with the present invention
The water electrolysis green hydrogen plant changes its direction according to the flow of the tide.
An example diagram showing how to turn

Hereinafter, other objects and features of the present invention in addition to the above objects will be clearly revealed through the description of the embodiments with reference to the accompanying drawings, and unless otherwise defined, all terms used herein, including technical or scientific terms, are the meaning of the present invention. It has the same meaning as commonly understood by a person of ordinary skill in the art to which it pertains.

Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and are not interpreted in an ideal or excessively formal meaning unless explicitly defined in this application.

Hereinafter, with reference to the accompanying drawings, a water electrolysis green hydrogen production system plant using a ship generating electric power by a running water accelerator system according to the present invention will be described in detail.

1 is a conceptual diagram of a lower deck, an inner wall, and a first deck according to the present invention, from a top view

The lower deck 110 is a basic flooring material of the plant hull 100, and is provided with a lower deck inlet surface 111, a lower deck inner wall surface 112, and a lower deck hole 113,

If the inner wall 120 is mounted on the left and right ends of the lower deck 110 to match the inner front and rear ends of the outer wall 160 and the lower deck 110, between the inner wall 120 and the outer wall 160, the lower deck A cylinder chamber 114 is formed in 110 to serve to mount the cylinder 330 on the outer wall 160 of the inlet and outlet.

In the lower deck hole 113, rising water flow is formed between the inner wall surface 112 of the lower deck and the first deck 130, and serves to buoy the back of the plant hull 100, so that the plant hull 100 together with the mooring device 400 is stably moored on the surface of the land and in the sea of the sea. (See Figs. 6 and 7)

The inner wall 120 is provided with an inner wall inflow fixed acceleration surface 121, an inner wall straight surface 122, and an inner wall rear surface 123, and the cylinder hole 124 is formed, but the upper end of the inner wall inflow fixed acceleration surface 121 is the inner wall straight surface ( 122) It is formed higher than the upper end and engaged with the second floor inflow downslope 151 of the second deck 150, mounted on both sides of the inner side of the lower deck 110, and by mounting the first deck 130 between the inner walls 120, the second deck ( 150) and the underwater cabin 180 are formed to accelerate the flowing water primarily in the fixed acceleration inflow chamber 181 of the inner wall inflow fixed acceleration surface 131, which is the inlet, and by opening and closing the inflow variable accelerator 310, the inner wall ( 120) The running water is drained to the outside through the outer surface and the outer side of the fixed acceleration slope 140 and the outer waterway chamber 186. (See FIGS. 7 and 11)

The first deck 130 is provided with a first floor inflow rising slope 131, a first floor inflow horizontal plane 132, a first floor fixed acceleration upward slope 133, and a first floor outflow horizontal plane 134, so that the lower deck inflow surface of the lower deck 110 ( 111) Mounted on the outer end and inside the inner wall 120, a fixed acceleration inclined wall 140 and an internal fixed acceleration system generator 200 on the inner top, and an inflow variable accelerator 310 and an outlet on the inflow and outflow surfaces, respectively The first-floor fixed acceleration surface 131, which is equipped with a variable accelerator 320 and rises with the inlet of the inner wall 120, the cone acceleration chamber 211 and the inclined acceleration chamber 212 of the internal fixed acceleration system generator 200, and a straight line Along the lower surface of the acceleration chamber 213, the flow of water accelerated firstly in the fixed acceleration inflow chamber 181 and secondly in the inflow variable accelerator 310 is accelerated in 3rd and 4th stages in the internal fixed accelerator (210 ) After being accelerated to the 5th by the reaction type blade rotor 222 installed in the impulse recoil type blade state 216 and the flow acceleration system generator 220 fixed outside, the first floor flow by opening and closing the outflow variable accelerator 320 It serves to drain the running water to the outside to the horizontal surface 132. (See Figs. 7 and 11)

2 is a conceptual view of a fixed acceleration inclined wall, a double deck, and an outer wall according to the present invention from an upper view

The fixed acceleration inclination wall 140 is located at both ends of the fixed acceleration inclination wall 140 between the upper inflow variable accelerator 310 and the outflow variable accelerator 320 inside the first deck 130 so that the mutual distance is wider at the inlet and narrower toward the outlet. fitted to match

The fixed acceleration inflow chamber along the inner surface of the fixed acceleration inclined wall 140 and the left and right sides of the cone acceleration chamber 211, the inclined acceleration chamber 212, and the straight acceleration chamber 213 of the internal fixed acceleration system generator 200 It serves to accelerate the flowing water first accelerated in 181 and second in inflow variable accelerator 310 in 3rd and 4th steps.

The second deck 150 is provided with a second floor inlet downslope 151, a second floor inlet horizontal surface 152, a second floor fixed acceleration downslope 153 and a second floor outflow plane 154, and a second floor slope hole 154 is perforated in the inner wall ( 110) When mounted on the top and inside the outer wall 160, the fixed acceleration inclined wall 140, the internal fixed acceleration system generator 200, the inlet variable accelerator 310 and the outlet variable accelerator 320 are installed at the bottom of the double deck 150 Inlet of the inner wall 120 by installing a water purifier 191, a water flow accelerator system, a water electrolyzer 192, a warehouse 193, and a balance tank 195 equipped with a winch 194 at the top. Fixed acceleration inflow along the upper surface of the double-decker fixed acceleration descent slope 152 and the cone acceleration chamber 211, slope acceleration chamber 212, and straight acceleration chamber 213 of the internal fixed acceleration system generator 200 descending with the unit It plays a role in accelerating the flowing water that has been accelerated firstly in the chamber 181 and secondly in the inflow variable accelerator 310 in the third and fourth stages (see FIGS. 7, 9, and 11).

The outer wall 160 is mounted at the outer end of the lower deck 110 at equal intervals on the left and right sides and the front and rear sides of the center line of the upper deck 170, so that the cylinder room 114, the underwater cabin 180, and the first floor cabin 190 ) plays a role in forming (see Figs. 7 and 9).

3 is a conceptual diagram of an upper deck, a first-floor cabin, and an upper deck facility according to the present invention, from an upper view

The upper deck 170 is mounted on the top of the plant hull 100 at equal intervals on the left, right, front, and rear, and is underwater along with the lower deck 110, the first deck 130, the outer wall 160, and the second deck 160. It forms the cabin 180 and the single cabin 190, and serves to mount the upper deck facility 1701 on the upper part. (See Fig. 9)

The first-floor cabin 190 has a water purifier 191 equipped with a winch 194 at the bottom of both sides, a distribution warehouse 173 equipped with a water flow accelerator system power generation power electrolyzer 192 and a winch 194, and a lower As a conceptual diagram equipped with a balance tank 195

The flow-acceleration system generated by the internally fixed acceleration system generator 200 of the submersible cabin 180 is supplied with power 223, and the water purified in the water purifier 191 through the balance tank 195 is supplied to the flow-acceleration system. The role of generating green hydrogen (1921) from the power generation power water electrolyzer (192)

The hoisting machine 194 serves to moor the plant hull 100 to the water surface by tying the hoisting rope 1941 to the part ring 421 of the mooring device 400 previously installed on the water surface, and

The balance tank 195 serves to maintain the balance of the plant hull 100 by filling water on the water and at sea and supplying water to the water purifier 191.

The upper deck facility 1701 is a conceptual diagram consisting of a control room 171, a green hydrogen tank 172, a crew room 173, and a green hydrogen supply device 174.

The control room 171 serves to control all facilities and devices of the plant hull 100 and

The green hydrogen tank (172) and the green hydrogen supply device 174 store the green hydrogen 1921 generated by the flow acceleration system generated by the flow acceleration system power water electrolyzer 192 of the first floor cabin 190 and It plays a role in sending out the green hydrogen (1921), which is stored in the flow-through acceleration system.

4 is a conceptual diagram and an assembly view of an internal fixed accelerator according to the present invention from a top view

In the upper left view, a cone acceleration chamber 211, an inclined acceleration chamber 212, and a linear acceleration chamber 213 are provided, an internal acceleration mechanism 214 is formed, and an internal acceleration support 215 and an impulse reaction tongue blade are formed on the outside. The internally fixed accelerator 210 with the stage 216 fixed

The upper right view is a water flow acceleration system generator 220 composed of a generator main body 221 and a recoil type blade rotor 222.

The generator main body 221 is built into the internal accelerator hole 214 of the internally fixed accelerator 210, and the recoil type blade rotor 222 is connected with the impulse recoil type bladestay 216 of the internally fixed accelerator 210 to the outside An internal acceleration system power generation device in which an impulse recoil type blade stay 216 is protruded and interlocked with a plurality of internal accelerator supports 215 and an impulse recoil type blade stay 216 outside the internal fixed accelerator 210 ( 200), each internal accelerator support 215 is a water flow acceleration system generator 220 mounted on the fixed acceleration inclined wall 140, the upper part of the first deck 130, and the lower part of the second deck 150.

The circular surfaces of the cone acceleration chamber 211, the inclined acceleration chamber 212, and the linear acceleration chamber 213 of the internal fixed accelerator 210 are along with the inner surface of the inflow variable accelerator 310 and the fixed acceleration inclined wall 140. The underwater cabin 180 is formed to accelerate the first accelerated flowing water in the fixed acceleration inflow chamber 181 in the second, third, and fourth stages, and finally, the impulse recoil type blade stay 216 and the recoil type blade It serves to improve the power generation rate of the generator 220 installed as a key element that is accelerated in the 5th order in the rotor 222 by doubling it.

In the flow-acceleration system generator 220 mounted on the internal fixed accelerator 210, only the recoil type blade rotor 222 is mounted in the stationary acceleration power generation room 184, and the flow-acceleration system generated power by the flow of water accelerated over 5 times ( 223) and drains the exhausted running water kinetic energy to the outside of the plant hull 100 without internal and external influences according to the opening and closing angle of the outflow variable accelerator 320 adjusted to suit the external situation.

In the case of the previous case, since the generator blades are arranged in front of the generator body and the outflow accelerator is placed at the rear of the generator, the drain passage is narrow, causing a problem in the process of accelerating water flow producing power and exhausted running water vortexing and draining to the outside. The present invention has solved the problem of making the installation of the internally fixed accelerator, which is a key technology, meaningless since the fatal disadvantage of low power generation efficiency occurred, and also the impulse recoil type bladestay 216 of the internally fixed accelerator 210 and the flowing acceleration system generator The effect of maximizing the kinetic energy of the flowing water was added by accelerating the flowing water in the 5th order by interlocking the recoil type blade rotor 222 of (220) with each other.

5 is a conceptual and assembled view of a cylinder according to the present invention from a top view;

In the upper left view, the cylinder fixing plate 331 is mounted on one end of the cylinder 300 composed of three stages, and the cylinder fixing plate 331 is horizontal to the position of the cylinder sphere 124 formed on the inner wall 120 of the inlet and outlet. Each is mounted and fixed to the matching outer wall 160,

In the upper right view, a pair of cylinder bracket plates 3321 with cylinder bracket holes 3322 perforated are mounted at regular intervals from the center line of the cylinder bracket 332 so that the cylinder wheel 333 can move. ( 332), a cylinder wheel 333 having a cylinder wheel sphere 3331, and a connecting bolt nut 334 for mounting the cylinder wheel 333 to the cylinder bracket 332.

The lower right view is an assembly concept view in which a cylinder fixing plate 331 is mounted on one side of the cylinder 330 and a cylinder bracket 332 and a cylinder wheel 333 are mounted on the opposite side.

The lower right view shows the accelerator bracket 340 mounted on the inflow variable accelerator 310 and the outflow variable accelerator 320, and the inlet variable accelerator 310 and the outflow variable accelerator 320 are mounted on the fixed acceleration inclined wall 140. As a schematic diagram of the mounting of the accelerator hinge 350

In the case of the previous case, the cylinder was equipped with only the cylinder fixing plate and the cylinder bracket, and when the cylinder is operated, the cylinder bracket inserted into the accelerator bracket is not operated, resulting in a fatal disadvantage that water flow acceleration is stopped, and the present invention is a cylinder bracket The previous problem was solved by installing a pair of cylinder bracket plates with cylinder bracket plate holes formed on the cylinder wheels.

6 is an assembly diagram and an opening/closing conceptual diagram of an inflow and outflow variable accelerator according to the present invention, wherein the upper two drawings are an inlet opening and closing diagram and the lower two drawings are an outlet opening and closing diagram.

The cylinder fixing plate 331 of the cylinder 330 is mounted on the outer wall 160 that coincides horizontally with the position of the cylinder hole 124 formed on the inner wall 120 of the inlet and matches the position matching the fixed cylinder 330. The accelerator bracket 340 is mounted on the outside of the inlet variable accelerator 300, and the inlet variable accelerator 310 is fixed to coincide with the inlet-side fixed acceleration inclined wall 140 with the accelerator hinge 350 to make the cylinder 330 A conceptual diagram of secondary acceleration of flowing water by opening and closing the inflow variable accelerator 310 by controlling it in the control room 171

The cylinder fixing plate 331 of the cylinder 330 is mounted on the outer wall 160 that coincides horizontally with the position of the cylinder hole 124 formed on the inner wall 120 of the outlet and matches the position matching the fixed cylinder 330. Mount the accelerator bracket 340 on the outside of the outflow variable accelerator 320 and fix the outflow variable accelerator 320 to coincide with the outflow-side fixed acceleration inclined wall 140 with the accelerator hinge 350 to move the cylinder 330 to the control room. It is a conceptual diagram of secondary acceleration of flowing water by opening and closing the outflow variable accelerator 320 by controlling in (171).

7 is an assembly view of a lower deck, an inner wall, an outer wall, and a first deck according to the present invention, from a top view

The outer wall 160 and the inner wall 120 are mounted on the left and right ends of the lower deck 110 to match the inner front and rear ends of the lower deck 110, and the lower deck inlet surface 111 of the lower deck 110 It is an assembly view of mounting the one-story deck 130 on the inside of the inner end and the inner wall 120.

8 is an assembly view of a fixed accelerating inclined wall, an internal fixed accelerator, an inflow variable accelerator, and an outflow variable accelerator according to the present invention, from a top view.

In the pre-assembled lower view of FIG. 7 , the inlet variable accelerator 310 and the inflow variable accelerator at the upper part of the first deck 130 are symmetrical to each other at the center line so that the mutual distance is wide at the inlet and narrow at the outlet side of the fixed acceleration inclined wall 140. (320), the internal fixed acceleration system generator 200 is mounted on the inside of the fixed acceleration inclined wall 140 and the upper part of the first deck 130, and the fixed acceleration inclined wall 140 on the inlet and outlet sides It is an assembly diagram for installing the inflow variable accelerator 310 and the outflow variable accelerator 320 at the end.

9 is an assembly view of a double deck, a first floor cabin, and an upper deck according to the present invention, from a top view

In the pre-assembled lower view of FIG. 8, the second deck 150 is attached to the inner wall 110, the top of the fixed acceleration inclined wall 140, and the inside of the outer wall 160. A water purifier (191), a running water accelerator system generator, a water electrolyzer (192), a warehouse (193), and a balance tank (194) equipped with a hoist (194) are installed, and at the top of the outer wall (160) before, after, It is an assembly view in which the upper deck 170 is mounted symmetrically on the center line at equal intervals on the left and right sides.

10 is an upper deck facility assembly diagram according to the present invention, a plant hull, an internal fixed accelerator, and a conceptual diagram of complete assembly of a variable accelerator, from the top view

In the pre-assembled lower view of FIG. 9, the plant hull 100 assembled by installing the control room 172, the water flow acceleration water electrolysis green hydrogen tank 172, and the crew room 173 on the upper deck 170 is the water surface of the land It is the plant main body 100 completed with the mooring device 400 installed on the sea and the sea. (See Fig. 14)

11 is a plan view of an underwater cabin structure of a horizontal axis acceleration generator and a vertical axis acceleration generator according to the present invention and a flowchart of flow of water acceleration according to an example of operation of a variable accelerator device.

The top view is a plan view and cross-sectional view illustrating the horizontal axis flow acceleration system generator 220 type in which the internal fixed acceleration system generator 200 equipped with the flow acceleration system generator 220 is mounted in the underwater cabin 180.

The intermediate power generation main body 221 is mounted on the balance tank 194, and the reaction type blade rotor 222 is installed in the fixed acceleration power generation room 184 using the second floor inclined hole 154 of the second deck 150. It is a plan view and cross-sectional view illustrating the vertical axis flow acceleration system generator 220 type.

The lower diagram shows the horizontal axis and vertical axis flow rate acceleration system generator 220, the inlet variable accelerator 310 and the outlet variable accelerator 320, and the water flow is fixed and accelerated by the operation of the inlet and outlet cylinders 330. In the inflow chamber 181, through the inflow variable accelerator 310 of the primary variable acceleration inflow chamber 182 and the cone acceleration chamber 211 surface of the internal fixed accelerator 210, the secondary, fixed acceleration channel chamber 183 In the 3rd, fixed acceleration generation room 184, the 4th and internal fixed accelerator 210 of the impulse recoil type blade stay 216 and the flow acceleration system generator 220 of the recoil type blade rotor 222 are interconnected. is accelerated in 5 stages, and the generator body 221 produces the power generated by the flow acceleration system 223 and supplies it to the land, or in the case of land and distant seas, the power generated by the flow acceleration system 223 is generated by the flow acceleration system It is an example of generating and supplying electrolytic green hydrogen 11921 by supplying it to the electrolyzer 192.

In detail from the third drawing, when the inflow variable accelerator 310 and the outflow variable accelerator 320 are closed, the plant main body 100 is moved by a tugboat, repaired, or the flow acceleration system generator 220 is above or below the behavior limit. As a measure when the flow rate changes with the flow rate, the water flow is drained from the inlet to the outside through the outer waterway chamber 186,

The 4th and 5th drawings are measures when the flow rate is ideal for the behavior of the flow acceleration system generator 220, and some of the flow water is drained to the outside through the outer waterway chamber 186

Most of the water flow is accelerated in the 1st, 2nd, 3rd, 4th, and 5th stages through the variable acceleration inflow chamber 182, the fixed acceleration channel chamber 183, and the fixed acceleration generation chamber 184, and the fixed acceleration generation chamber 184 ) Rotates the recoil-type blade rotor 222 installed in the flow acceleration system to produce power 223 and drains to the outside through the variable acceleration outflow chamber 185

The sixth drawing shows a fixed acceleration inflow chamber 181, a variable acceleration inflow chamber 182, a fixed acceleration channel room 183, and a fixed acceleration power generation room (184 It is accelerated step by step through ) and rotates the recoil type blade rotor 222 installed in the fixed acceleration power generation room 184 to produce the flow-through acceleration system power generation 223, and through the variable acceleration discharge room 185 As a plan view illustrating drainage with

By digitizing the 6th and 7th drawings (water flow natural flow rate 0.3m/s, generator blade diameter 2.5m same standard), the theoretical flow rate and power generation amount are calculated, and the internal fixed acceleration system generator (200 ) to know the importance of

In the case of the 7th drawing, the area of the fixed acceleration inflow room 181 is 100m2 (10mX10m), the area of the variable acceleration inflow room 182 is 64m2 (8mX8m), and the area of the fixed acceleration power generation room 184 is 9m2 (3mX3m). case

According to the continuity equation (A1*V1=A2*V2), as V2=A1*V1/A2, the flow velocity V1=0.3m/s*100㎡/64㎡=0.46m/s in the fixed acceleration inflow chamber 181 and variable acceleration The flow velocity V2 of the inlet chamber 182 becomes V2 = 0.46 * 64 / 9 = 3.27 m/s, and according to the ocean current generation formula, P (kw) = 0.5ρAV^3, so P (kw) = 0.5 * 1.0 ton * (π * (1.25m^2)*(3.27m/s^3)=85kw

In the case of the sixth drawing, the area of the fixed acceleration inflow chamber 181 is 100 m2 and the area of the variable acceleration inflow chamber 182 is 64 m2-(π*2^2)=51.44 m2 by the internal fixed acceleration system generator 200 .

The flow velocity V1 of the fixed acceleration inflow chamber 181 is = 0.3m/s * 100m2 / 51.44m2 = 0.58m/s and the flow velocity V2 of the variable acceleration inflow chamber 182 = 0.58 * 51.44 / 28.93 = 1.03m/s The flow velocity V3 of the fixed acceleration channel 183 is =1.03 * 28.93 / 5.86 = 5.08 m/s, and P (kw) = 0.5 * 1.0 * (π * (1.25 ^ 2) * (5.08 ^ 3) = 321 kw It can be seen that the 7th power generation is more than 3.7 times.

This is the case for small plants, and when large plants or natural flow rates increase, the gap in power generation is expected to double several times.

Finally, when the flow rate accelerated to the 5th in the reaction type blade rotor 222 in conjunction with the impulse recoil type blade stay 216 is determined by an actual experiment, the flow acceleration is expected to be further doubled.

As described above, the plant hull 100 can be used in a wide area in rivers and seas of 0.3 m / s or more, and based on the inflow variable accelerator 310 and the outflow variable accelerator 320, the power generation time is stably extended by maintaining a constant flow rate for a long time It is a technical resource energy production facility that accelerates the flow rate with the internal fixed acceleration system power generation device 200 to produce cost-effective renewable power and green hydrogen due to an increase in power generation.

12 is a conceptual diagram of a mooring device installed on land and in the sea according to the present invention, and is a representative view of the present invention.

The top view is a mooring device 400 installed on a water surface flowing in one direction, such as land water or sea current flowing in one direction, with a part ring 421, part light 422, and part rope 423 on the upstream water surface. Two sets are installed in which the constructed part 420 and the part foundation 410 equipped with the base ring 411 in the underwater ground are connected with the part rope 423, and the part 420 connected with the part rope 423 on the downstream water surface It is an exemplary view in which one set of part foundations 410 is installed.

The lower part is a mooring device (400) installed on the sea where the water flow flows in this direction due to the presence of high tide and low tide. It is an exemplary view of a mooring device in which three sets of the part 410 and the part foundation 420 are respectively installed.

13 is a conceptual diagram of a water flow acceleration system power generation electric power electrolysis green hydrogen plant mooring installed on land on land and on the sea in accordance with the present invention.

The top view is an exemplary view in which the plant main body 100 is installed on the water surface of the land and the sea current flowing in one direction. The hoisting rope (1941) of the hoisting machine (194) mounted on the water purifier (191) is tied to the part ring (421) of the side part (420), and the hoisting rope (1941) of the hoisting machine (194) mounted on the balance tank (194) ) is tied to the site ring 421 of the downstream site 420, and the mooring is completed.

The lower diagram is an example of the plan body 100 installed on the tidal sea of the sea where high tide and low tide work. On both sides of the water purifier 191 on the part ring 421 of the water flow inflow direction part 420 at high tide Tie the winch rope 1941 of the installed winch 194 and tie the winch rope 1941 of the winch 194 mounted on the balance tank 194 to the part ring 421 of the part 420 in the direction of running water It is also an example of a completed mooring

In the ebb cycle, before the water flow direction changes, unfasten the outlet hoisting rope (1941), untie one of the inlet hoisting ropes (1941), connect it, close the inlet variable accelerator (310), and loosen the remaining inlet hoisting rope (1941). When the flow direction is changed and the inlet of the plant hull 100 is turned in the direction of the water flow, the remaining inlet hoist rope (1941) is tied to the part loop (421), and the outlet hoist rope (1941) is also the outlet part hook (421) When the preparation for power generation is completed by tying it to, it is a conceptual diagram illustrating that the inlet variable accelerator 310 is opened and the flowing water is accelerated step by step to resume power generation.

In the case of the past, a plant operated with one mooring device without a ballast tank in the plant has a problem of being vulnerable to various external influences. It was designed to operate safely and stably 365 days a year from external influences.

As described above, the present invention has been described with specific details such as specific components and limited embodiments and drawings, but these are only provided to help a more general understanding of the present invention.

The present invention is not limited to the above embodiments, and various modifications and variations can be made from these descriptions by those skilled in the art.

Therefore, the spirit of the present invention should not be limited to the described embodiments and should not be determined, and all things equivalent or equivalent to the claims as well as the following claims belong to the scope of the present invention.

100: plant hull
110: lower deck 111: lower deck inlet surface
112: lower deck inner wall surface 113: lower deck hole
114: cylinder chamber
120: inner wall 121: inner wall inflow fixed acceleration surface
122: Inner wall straight surface 123: Inner wall rear
124: cylinder sphere
130: first deck 131: first floor inflow ramp
132: first floor inflow horizontal surface 133: first floor fixed acceleration rising slope
134: first floor outflow level
140: fixed acceleration inclined wall
150: double deck 151: double inlet down horizontal surface
152: second floor inflow horizontal surface 153: second floor fixed acceleration downward slope
154: second floor outflow horizontal surface 155: second floor slope hole
160: outer wall
170: upper deck 1701: upper deck facility
171: control room 172: green hydrogen tank
173: crew room 174: green hydrogen supply device
180: underwater cabin 181: fixed acceleration inflow room
182; Variable acceleration inflow chamber 183: fixed acceleration channel chamber
184; Fixed acceleration power generation room 185: Variable acceleration outflow room
186: outer waterway room
190: first floor cabin 191: water purifier
192: flow rate acceleration system power water electrolyzer
1921; Water Acceleration System Power Generation Electricity Water Electrolysis Green Hydrogen
193: warehouse
194 : Kwon Yang-ki 1941 ; winch rope
195: balance tank
200: internal fixed acceleration system generator
210: internally fixed accelerator 211: cone accelerator
212: inclined acceleration room 213: straight acceleration room
214: internal acceleration mechanism 215: internal acceleration base support
216: impulse recoil type blade state
220: flow-acceleration system generator 221: generator main body
222: recoil type blade rotor 223: flow-acceleration system power generation
300: variable accelerator
310: inlet variable accelerator 311: inlet accelerator bracket
312: inflow accelerator hinge
320: spillover variable accelerator
330: cylinder 331: cylinder fixing plate
332: cylinder bracket 3321: cylinder bracket plate
3322: cylinder bracket section
333: bracket wheel 3331: bracket wheel hole
334: connection bolt nut
340: accelerator bracket
350: accelerator hinge
400: mooring device
410: site base 411; base ring
420: part 421: part ring
422: part light 423: part rope
500: Green hydrogen generating means
600: Flowing Acceleration System Power Water Electrolysis Green Hydrogen Plant

Claims (13)

In a system for generating electric power by inducing acceleration of flowing water flowing into the plant when the plant is moored on the water surface to be installed by a tugboat and generating green hydrogen using the produced electric power,
The system
A plant hull 100 that has the shape of a plant that can be moved or moored by floating on land rivers or seas, but is provided so that flowing water with an accelerated flow rate can flow in the moving direction;
An internal fixed acceleration system power generation device 200 installed inside the plant hull 100 so that flow-accelerated power generation 223 can be produced using accelerated running water; and
It is installed in the plant hull 100 to be electrically connected to the internal fixed price system-in-generation device 200, but receives the generated flow-acceleration system generation power 223 and generates green hydrogen by water electrolysis (water decomposition) (500 ); Water electrolysis green hydrogen generation system using a plant that produces power generated by a running water accelerator system, characterized in that it comprises a first floor cabin (190) equipped with According to claim 1,
The plant body 100 is
A lower deck 110 that floats to be movable and moored on the sea so that accelerated running water can flow in; and inner wall 120; and a first deck (130); and a fixed acceleration inclined wall 140; and a double deck (150); and an outer wall 160; And an upper deck (170); consists of;
A mooring device 400 provided so that the plant body 100 can be moored on the surface of the water; Water electrolysis green hydrogen generation system using a plant that produces power generated by a running water accelerator system, characterized in that it comprises According to claim 2,
The lower deck 110 is
It is made of a plate material and has a lower deck inlet surface 111 and a lower deck inner wall surface 112, and a lower deck hole 113 is perforated.
A pair of outer walls 160 installed facing each other to have a predetermined height at both outer ends of the lower deck inflow surface 111 and the lower deck inner wall surface 112 of the lower deck 110; and
A pair of inner walls 120 installed facing each other to have a lower height than the outer wall 160 at both inner ends of the lower deck inflow surface 111 and the lower deck inner wall surface 112 of the lower deck 110; and
a second deck 150 installed to face each other in a vertical direction with the lower deck 110 so as to be supported on the upper end of the inner wall 120; and
A first deck 130 is disposed on the upper part of the lower deck 110 so as to face each other under the second deck 150 so as not to connect with the second deck 150, but between them, the internal fixed acceleration system generator 200 and an underwater cabin 180 in which a fixed acceleration inclined wall 140 is disposed; Water electrolysis green hydrogen generation system using a plant that produces power generated by a running water accelerator system comprising a According to claim 2,
The inner wall 120 is provided with an inner wall inflow acceleration surface 121, an inner wall straight surface 122, and an inner wall rear surface 123, but a cylinder hole 124 is formed at the inlet and outlet, and the inner wall inflow acceleration surface 121 ) Water electrolysis green hydrogen generation system using a plant that produces power generated by a running water accelerator system, characterized in that the top is higher than the top of the inner wall straight plane (122) According to claim 2,
In the water flow acceleration system, characterized in that the first floor deck 130 is provided with a first floor inlet rising slope 131, a first floor horizontal inflow surface 132, a first floor fixed acceleration upward slope 133 and a first floor horizontal outflow surface 134 Water electrolysis green hydrogen generation system using a plant that produces electricity by According to claim 2,
In the water flow acceleration system, characterized in that the second deck (150) is provided with a two-story inlet downslope (151), a second-floor horizontal inflow surface (152), a double-floor fixed acceleration downslope (153) and a second-floor horizontal outflow surface (154) Water electrolysis green hydrogen generation system using a plant that produces electricity generated by According to claim 3,
The underwater cabin 180 is
The fixed acceleration inlet room composed of the lower deck inflow surface 111 of the lower deck 110 and both sides of the inner wall inflow fixed acceleration surface 121 of the inner wall 120 and the second floor horizontal inflow surface 151 of the second deck 150 (181); and
Both sides of the first floor horizontal inflow surface 131 of the first deck 130 and the inner wall straight plane 121 of the inner wall 120 and the second floor horizontal inflow surface 151 of the second deck 150 and a pair of inflow variable accelerators 310 ); A cone accelerator chamber 211 among the internally fixed accelerators 210 of the face and variable accelerator 300; A variable acceleration inlet chamber 182 composed of; and
The first floor fixed acceleration surface 131 of the first deck 130 and both sides of the inner surface of the fixed acceleration inclined wall 140, the second floor fixed descent acceleration surface 151 of the second deck 150, and the variable acceleration device 300 Among the internal fixed accelerators 210, a fixed acceleration channel 182 consisting of a gradient acceleration chamber 212; and
The first floor fixed acceleration surface 131 of the first deck 130 and both sides of the inner surface of the fixed acceleration inclined wall 140, the second floor fixed descent acceleration surface 151 of the second deck 150, and the variable acceleration device 300 A fixed acceleration generation room 182 composed of a linear acceleration room 213 of the internal fixed accelerator 210; and
Both sides of the first floor horizontal outflow surface 133 of the first deck 130 and the inner wall straight surface 121 of the inner wall 120 and the second floor horizontal outflow surface 153 of the second deck 150 and a pair of variable outflow accelerators 320 ); A variable acceleration outflow chamber 185 composed of; and
By opening and closing the inflow accelerator 310 of the variable acceleration inflow chamber 182 and the outflow accelerator 320 of the variable acceleration outflow chamber 320, water flows to the inner straight surface 121 and the outer surface of the fixed acceleration inclined wall 140. Water electrolysis green hydrogen generation system using a plant that produces power generated by a running water accelerator system, characterized in that it passes through and is drained to the outside According to claim 1,
The internal fixed acceleration system generator 200; Is
It consists of the internal fixed accelerator 210 and the flow-acceleration system generator 220,
The internal fixed accelerator 210 is provided with a cone acceleration chamber 211, an inclined acceleration chamber 212, and a linear acceleration chamber 213 inside, an internal acceleration mechanism 214 is formed, and an internal acceleration support 215 on the outside. ) and the internally fixed accelerator 210 in which the impulse recoil type blade stay 216 is fixed
Characterized in that the generator main body 221 is mounted in the linear accelerator chamber 213 through the internal accelerator hole 214 through the accelerator hole 214. Water electrolysis green hydrogen generation system using a plant that produces power generated by a running water accelerator system According to claim 7,
The inflow variable accelerator 310 is
Composed of an accelerator bracket 340 and an accelerator hinge 350, the accelerator bracket 311 is mounted on one side of the inflow variable accelerator 310, and the mounted surface faces the side of the cylinder sphere 124 created on the inner wall 120 Cylinder 330 inside the inlet accelerator bracket 340 by mounting it on both ends of the inlet fixing accelerator inclined wall 140 using accelerator hinges 350; Water electrolysis green hydrogen generation system using a plant that produces power generated by a running water accelerator system, characterized in that the cylinder bracket 332 is mounted According to claim 7,
The outflow variable accelerator 320
Consisting of an accelerator bracket 340 and an accelerator hinge 350, the accelerator bracket 311 is mounted on one side of the outflow variable accelerator 320, and the mounted surface faces the side of the cylinder sphere 124 created on the inner wall 120 Cylinder 330 inside the outlet accelerator bracket 340 by mounting it on both ends of the inlet fixing accelerator inclined wall 140 using accelerator hinges 350; Water electrolysis green hydrogen generation system using a plant that produces power generated by a running water accelerator system, characterized in that the cylinder bracket 332 is mounted In paragraphs 7 and 8
The cylinder 330 includes a cylinder fixing plate 331 and a cylinder bracket 332; is composed of
In the cylinder bracket 332, a pair of cylinder bracket plates 3321 having cylinder bracket holes 3322 perforated are symmetrically attached at the center line of the cylinder bracket 332, and the cylinder bracket plate holes 3322 of the cylinder bracket 332 ), the cylinder bracket 332 equipped with the bracket wheel 333 with a bolt nut (3340) is mounted on the cylinder 330 opposite the cylinder fixing plate 331
The cylinder fixing plate 331 is attached to the outer wall 160 through the cylinder sphere 124 of the inner wall 120 and the cylinder bracket 332 of the cylinder 330 mounted in the cylinder chamber 124 and the variable acceleration inlet chamber 182 go
Water electrolysis green hydrogen generation system using a plant that produces power generated by a running water accelerator system, characterized in that mounted inside the accelerator bracket 340 According to claim 2,
The mooring device 400 is
site base 410; And consists of a part 420
A base ring 411 is attached to the part base 410, and
The part 420 has a part ring 421 and a part etc. 422, characterized in that water electrolysis green hydrogen generation system using a plant that produces power generated by a running water accelerator system According to claim 1,
A water purifier 191, a water flow accelerator system, a water electrolyzer 192, a winch 194, a warehouse 193, and a balance tank 195 are installed in the first floor cabin 190, and the inside The flow-acceleration system generation power (223) produced by the fixed acceleration system generator (200) is supplied, and the flow-acceleration system generation power green hydrogen (1921) produced by the flow-acceleration system generation power water electrolyzer (192) is supplied to the upper deck facility Water electrolysis green hydrogen generation system using a plant that produces power generated by the flowing water acceleration system of the green hydrogen generation means 500, characterized in that it is stored in the green hydrogen tank 173 of (1701)

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