BRMU8901223U2 - hydropneumoelectric power plant with immersed cylindrical powerhouse and ground platform - Google Patents

Abstract

HYDROPNEUMOELECTRIC PLANT WITH HOUSE OF IMMERSE CYLINDERIC STRENGTH AND TERRESTRIAL PLATFORM belonging to the electric sector, solving problems of state-of-the-art thermal, atomic and hydroelectric plants, comprised of a hydropneumaelectric plant (1), immersed cylindrical power house (210) and land platform (260), the hydro-pneumatic plant (1) being installed inside the cylindrical powerhouse immersed (210) in the water of a well, tank, box, pool, cistern, deposit, reservoir, weir, dam, lake, lagoon, river, sea and ocean of the terrestrial globe, being the hydro-pneumatic power plant (1) comprised of a hydraulic turbine (10) with an electric generator (60) and a pump (42) of an electric motor (63) installed inside the powerhouse immersed cylindrical (210), and compressor (66) with electric motor (72), electric generator (75) with blast motor (78), electric control panel (90) and pole or tower (121) of electrical network installed in the platform terres tre (260), the hydro-pneumatic plant (1) being moved with the use and reuse of the water captured and returned to the bottom of the water resource and with the use and reuse of the air captured and returned to the atmosphere, using the pressure of the pump (42) and compressor (66) to create water movement that moves the hydraulic turbine (10) and electric generator (60), forming a current of water and air bubbles in the hydraulic turbine outlet pipe and into the water of the water resource, which rise for surface being reused, generating electricity for self-consumption of the plant and consumption of populations and economic activities, with the use of water and air as sources of reusable natural resources of energy.

Description

"FFLDROPNEUMOELECTRIC POWER PLANT WITH IMMERSE FORCE HOUSE AND EARTH PLATFORM" of this Utility Model Patent Filing, which consists of a power-generating hydropneumatic hydropower plant, comprising a hydraulic turbine with electric generator, an electric pump and a two-compressor compressor pump with electric motor, installed inside an immersed cylindrical powerhouse built into the well water, tank, box, pool, cistern, deposit, reservoir, dam, dam, lake, pond, river, sea and ocean of the globe combined with a terrestrial platform built on the waterfront, shore or shore, used as a base for the operation and support of machines, equipment and installations, being the hydropneumoelectric plant moved with the use and reuse of water captured and returned to the bottom. water resources and with the air captured and evolved in the atmosphere , using the force of the booster pump and the compressor, generating renewable electric energy for self consumption of the plant and consumption of the populations and the economic activities.

Descriptive Report of this Patent Application:

This descriptive report is presented in a manner, order and manner that allows its concise understanding and presentation.

This report describes the hydropneumoelectric power plant of this Patent Application, so that it can be realized following the report itself and the drawings.

Background Art:

The prior art electrical energy history is described as follows: a) The word electricity derives from electron or amber, which means the fossilized pine tree stone of an already extinct species;

b) Static electricity was discovered in Greece by Tales of Miletus, who rubbed an amber stone on a cloth, attracting hair in 641 BC;

c) The electric generator was made in England by Michael Faraday in 1831;

d) The electric generator was also invented in the United States by Joseph Henry in 1831;

e) The incandescent lamp was manufactured in series in the United States by Thomas Edison in 1878;

f) The first thermal power plant was coal-fired, being built in New York, in the United States by Thomas Edison, in 1881;

(g) The first power grid was built with iron bars at the coal plant in New York, United States, by Thomas Edison in 1881;

h) The first hydroelectric power plant was built on the Niagara River, Canada, designed by Nicola Tesla in 1886;

(i) The biphasic induction electric motor was invented in the United States by Nicola Tesla in 1887;

j) The dynamo-electric principle was discovered in Germany by Fernand von Siemens in 1896;

l) Electricity is used for lighting, driving motors, machines, equipment and appliances for use by populations and for extractive economic, agricultural, industrial, commercial and service activities.

The history of the main hydraulic turbines of the technical state is described as follows:

(a) The hydraulic turbine was invented in France by Claude Burdin in 1824;

b) The Centripetal Machine was invented in the United States by SamuelHowd in 1838;

c) The Francis hydraulic turbine was developed in the United States on the Samuel Howd Centripetal Flow Machine by James Bicheno Francis in 1874;

d) The Michel-Banki hydraulic turbine was invented in 1896;

e) The Banki hydraulic turbine was invented in 1903;

f) The Kaplan hydraulic turbine was invented in Austria by VitorKaplan in 1912;

g) The Straflow hydraulic turbine was installed at the Fundy plant in Canada in 1984;

h) There are currently millions of state-of-the-art hydraulic turbines used to power hydroelectric power plants.

The history of prior art power plants is as follows:

a) The first coal-fired thermal power plant was built in New York, USA by Thomas Edison in 1881. (b) The first hydroelectric power plant was built on the Niagara River in Canada, designed by Nicola Tesla in 1886;

c) The first atomic power plant was built at Obninski, Russia, in54.

State of the art power plant problems:

The technical and environmental problems of state-of-the-art thermal, atomic and hydroelectric plants are highlighted as follows:

a) Problem of the need for large physical structure for extraction, processing and transportation of coal, oil and gas for power plants;

b) Problem of the high cost of coal, oil and gas for power plants;

c) Problem of limitation of mineral reserves of coal, oil and gas;

d) Problem of atmospheric pollution, greenhouse effect and global warming of the smoke emitted in the burning of coal, oil and gas thermal godines;

e) Problem of the need for a large technical and scientific structure for uranium extraction, transport and enrichment for atomic power plants;

f) Problem of the high cost of construction and operation of atomic power plants;

g) Long time problem needed to build the nuclear power plants h) Problem of radiation leaks from reactors and deuranium deposits;

i) Bus problem and alteration of the normal course of the rivers;

j) Problem of flooding of forest lands, agriculture and livestock;

1) Problem of relocation of riverine populations;

m) Problem of methane emission from flooded vegetation giving greenhouse effect;

n) Problem of the only use of water by the same conventional hydroelectric plant used to move the hydraulic turbine and generate power;

o) Problem of limiting the amount of potential hydroelectric sites in the rivers to increase the power generation capacity;

p) Problem of the energy supply crisis to guarantee the economic and social growth of populations and economic activities.

Solutions to state of the art power plant problems:

The solutions to the technical and environmental problems of the conventional thermal, atomic and hydroelectric power plants of the technical state, which are proposed by the creation of the hydropneumoelectric power plant in this patent application, are indicated as follows:

a) Solution of the construction and installation of hydropneumoelectric plants moved with the use and use of water collected and returned from the bottom of water resources from wells, tanks, boxes, swimming pools, cisterns, deposits, reservoirs, dams, dams, lakes, lakes, rivers , seas and oceans of the globe, as a source of reusable natural energy resources;

b) Solution of the construction and installation of hydropneumoelectric plants moved with the use and reuse of air collected and returned in the atmosphere as a source of reusable natural energy resources;

c) Solution for the construction and installation of hydropneumoelectric plants to promote economic and social development, through the use of large scale industrial and commercial electric power for the consumption of populations and extractive, agricultural, industrial, commercial and services;

d) Solution for the construction and installation of hydropneumoelectric plants for the generation of clean and renewable electric energy, with low environmental impact, shorter implementation time, lower construction cost and safe for the environment, populations and extractive economic, agricultural, industrial, commercial and services.

Improvements and functional improvements of the hydropneumoelectric plant:

The immersed cylindrical powerhouse and ground platform hydropneumoelectric power plant of this Patent Application was created by introducing functional improvements in the use and manufacturing of state-of-the-art conventional hydropower plants, powerhouses and oil rigs, which are indicated. as follows:

(a) Improvement and functional improvement of the installation of an electric motor booster pump in the hydraulic turbine outlet pipe, used to pull and squeeze water from within the hydraulic turbine, creating a water displacement movement of a hydraulic turbine with a coupled electric generator; generating renewable electric energy;

b) Improvement and functional improvement of the installation of an electric motor compressor used to capture air into the atmosphere and produce a jet of compressed air injected into the hydraulic turbine outlet piping, creating a water displacement movement that moves the hydraulic turbine with a coupled electric generator generating renewable electric energy;

c) Improvement and functional improvement of the installation of a hydraulic turbine outlet T-pipe, where it disconnects a compressor pipe, which injects a jet of compressed air into the hydraulic turbine outlet pipe;

(d) Improvement and functional improvement of the installation of the reversed downward-facing hydraulic turbine outlet pipe dipped at the bottom of the water resource, to direct the water stream that moves the hydraulic turbine also upwards, returning the water at the bottom of the water feature and allowing the reuse of water that moves the hydraulic turbine;

(e) Improvement and functional improvement of the installation of the outlet nozzle of the open turbine outlet pipe open from the bottom up and dipped into the bottom of the water feature to direct the water stream that moves the hydraulic turbine also upwards; returning water to the bottom of the water resource and allowing the reuse of water that drives the hydraulic turbine; (f) Improvement and functional improvement of the hydropneumoelectric power plant installation within the immersed cylindrical powerhouse constructed within the water resource of the well, tank, box, pool, cistern, deposit, reservoir, dam, dam, dam, lake, pond, river, sea and ocean of the globe, for use and reuse of water collected and returned from the bottom of the water resource, which moves the hydro turbine of the hydropneumoelectric plant, generating renewable energy, using water as a source of reusable natural resources from energy;

g) Improvement and functional improvement of the construction of immersed cylindrical powerhouse combined with one of terrestrial platform, which is used as the base of operation and support of machines, equipment and facilities of the hydropneumoelectric plant;

h) Improvement and functional improvement of the installation on the ground platform, of the machines, equipment of the hydropneumoelectric plant, comprised of an electric motor compressor, electric motor with generator, electric control board and pole of electric grid tower.

Novelty and inventiveness of the hydropneumoelectric plant creation:

The novelties and inventiveness of the hydropneumoelectric power plant creation of this Patent Application are indicated as follows:

a) Novelty and inventiveness of installing a small hydraulic turbine water turbine outlet piping pump, being used to pull and squeeze water into the hydraulic turbine, creating a water-displacement movement that moves this hydraulic turbine and the electric generator coupled, generating renewable electric energy;

b) Novelty and inventiveness of the compressor installation on the ground platform, for use and reuse of air collected and returned in the atmosphere, producing a jet of compressed air injected into the water outlet of the hydropneumatic hydro turbine, creating a movement of water displacement that moves the hydraulic turbine and electric generator, generating renewable electric energy;

c) Novelty and inventiveness of the installation of the hydropneumoelectric plant inside a cylindrical powerhouse immersed within the water resource of a dam, dam, lake, pond, river, sea or ocean of the globe;

d) Novelty and inventiveness of the construction and installation of the hydropneumoelectric plant with a terrestrial platform used as the base and operation of machines, equipment and facilities dausina;

e) Novelty and inventiveness of the construction and installation of hydropneumoelectric godine units at thousands of geographical points located in water resources of weir, dam, dam, lake, lagoon, river, sea and ocean of the globe;

f) Novelty and inventiveness of the use and reuse of water captured and returned at the bottom of the water resource to move the hydraulic turbine of the hydropneumoelectric plant, using water as a source of reusable natural energy resources; g) Novelty and inventiveness of the use and reuse of captured and developed air. in the atmosphere to move the hydraulic turbine of the hydropneumatic plant, using air as a source of reusable natural energy resources;

h) Novelty and inventiveness of the allocation of the first part of 10% to 40% (ten to forty percent) of the electric power generated by the hydropneumoelectric plant for the self-consumption of the plant, driving the electric pump of the booster pump and the electric motor of the compressor, maintaining the operation. permanent and continuous hydropneumoelectric dausine;

i) Novelty and inventiveness of the construction and installation of the hydropneumoelectric power plant in frozen regions of the globe, being moved with the use and reuse of water collected and returned to the bottom of water resources where the surface waters freeze and the lower waters remain liquid.

Industrial applications of hydropneumoelectric power plant:

The intended industrial applications for the creation of the immersed cylindrical powerhouse hydropneumoelectric plant with ground platform of this patent application are as follows:

a) Industrial application by the fact that it can be manufactured in any type of industry;

(b) Industrial application by the fact that the first part of 10% to 40% (ten to forty per cent) of the electric power generated by the electric generator is to be used for the self-consumption of the plant in the drive of the booster pump electric motor and the compressor electric motor, maintaining the continued operation of the power generation plant;

c) Industrial application due to the fact that 60% to 90% (sixty to ninety percent) of the second part will be used for the electric power generated by the plant's electric generator, for the consumption of the populations and the extractive economic, agricultural, industrial and commercial services.

Technical effects, results achieved and objectives of the hydropneumoelectric plant:

The technical effects, results achieved and objectives of the creation of the hydropneumoelectric power plant with immersed cylindrical powerhouse and terrestrial platform of this Patent Application are shown as follows:

(a) construction and installation of hydropneumoelectric power plant units to generate renewable electrical energy using water and to donate as sources of reusable natural energy resources;

b) Construction and installation of hydropneumoelectric power plant units to generate clean and renewable electricity with low environmental impact, reducing air pollution and global warming, benefiting the environment, populations and economic activities;

c) Construction and installation of hydropneumoelectric plant units on an industrial and commercial scale, generating electricity to promote the economic and social development of populations and economic activities.

Advantages of the hydropneumoelectric power plant: The advantages of the hydropneumoelectric power plant with immersed cylindrical powerhouse and ground platform of this Patent Application are outlined as follows:

a) Advantage of the use and reuse of water collected and returned from the globe's water resources fund to move the hydropneumoelectric plant, generating clean and renewable electric energy, with low environmental impact and safe for the environment, populations and economic activities;

b) Advantage of the use and reuse of air collected and returned in the atmosphere to move the hydropneumoelectric plant, generating clean and renewable energy, with low environmental impact and safe for the environment, populations and economic activities;

c) Advantage of the possibility of building and installing units of the hydropneumoelectric power plant in thousands of localized geographical points of water resources of dams, dams, lakes, lakes, rivers, seas and oceans of the terrestrial;

d) Advantage of the shorter construction and installation time of the hydropneumoelectric plant;

e) Advantage of the construction and installation of the hydropneumoelectric power plant for the generation of electricity in arid regions of the globe, being moved with the use and reuse of the waters of the artificial or natural water resources in places with water scarcity;

f) Advantage of the construction and installation of the hydropneumoelectric plant of electric power generation in frozen regions of the globe, being moved with the use and reuse of the bottom waters of the water resources where the surface waters freeze and the lower waters remain liquid.

State of the art hydroelectric power plants:

State-of-the-art conventional hydroelectric power plants consist of power generation plants intended for the consumption of populations and extractive economic, agricultural, industrial, commercial and service activities.

The state-of-the-art hydraulic turbines of conventional hydroelectric power plants are powered by the simple use of water stored in reservoir lakes of dams or river dams.

The size of state-of-the-art conventional hydroelectric gods and hydraulic turbines and power generators ranges from 1 KWA to 700 MWH (one kilo-Watt to seven hundred Mega-Watts per hour) of energy.

The largest state-of-the-art hydroelectric power plant is the Itaipu Plant on the Paraná River, between Brazil and Paraguay, with 20 860-cm diameter rotor turbines, with 10-meter-diameter, 196-meter-high water intake pipes. 645,000 liters of water per second, with 20 700MWH (seven hundred Mega-Watts per hour) electric generators each, totaling 14,000MW of electricity generation per hour.

Patents for conventional state-of-the-art hydroelectric power plants are in the public domain because they have been built for over 20 years. Machines, equipment and installations of state-of-the-art hydroelectric power plants:

State-of-the-art hydroelectric power plants, equipment and installations are indicated as follows:

a) hydraulic turbine;

b) electric generator;

c) Hydraulic turbine inlet piping;

d) Hydraulic turbine discharge suction pipe;

e) Electric network of the electric generator;

f) Electric pole or tower.

Technical composition of conventional hydroelectric plants of the technical state:

State-of-the-art conventional hydroelectric power plants are built in dams or reservoirs of river reservoir lakes, installed inside powerhouses, consisting of a dam or river dam, a powerhouse where the electric turbine hydraulic turbine, forced water pipe is installed. water inlet, drainage discharge piping, and electric generator mains, where powerhouses are located lower downstream of the river dams or dams, having at the dam or dam a water catchment station where it is captured the water that moves the hydraulic turbine, having a forced pipe running through the dam-or-dam wall-opening, and the forced-pipe is extending across a slope, through the ceiling-through opening, or into the powerhouse side wall, the forced piping is connected to the hydraulic turbine, and the turbine The hydraulic turbine contains a rotor or propeller attached to a rotary shaft coupled to the rotary axis of the electric generator, and the hydraulic turbine is connected to a downwardly oriented water discharge suction pipe, and the water discharge suction pipe is extending into the final nozzle of the water discharge suction pipe, which is plunged or drowned into the water of the escape channel where water is developed in the normal course of the river, having in the conventional power plant an electric generator, which contains an electromagnetic rotor attached to a shaft. rotary, which rotates with the power of the mechanical energy of the hydraulic turbine, forming a magnetic field of electricity, generating electrical energy, having in the conventional hydroelectric power plant an electric network connected to the electric generator and extended until it is connected to the electric network of consumption of the populations and extractive economic activities. agricultural indus business, and services.

State of the art hydraulic turbines:

State-of-the-art hydraulic turbines are hydraulic machines that transform the kinetic energy of water movement into mechanical energy.

The main types of state-of-the-art hydraulic reaction turbines of conventional hydroelectric plants are indicated as follows:

(a) Francis vertical hydraulic turbine;

(b) Francis horizontal hydraulic turbine;

c) Horizontal Kaplan hydraulic turbine;

d) Horizontal Straflow hydraulic turbine.

The materials used in the manufacture of the state-of-the-art hydraulic turbine used in conventional hydroelectric power plants are iron and steel.The state-of-the-art hydraulic turbines are installed inside the powerhouse of conventional hydroelectric plants.

The size of state of the art hydraulic turbines varies with the size of the rotors, from 15 to 860 centimeters in diameter.

The largest state-of-the-art hydraulic turbines are Francis vertical turbines used at the Itaipu Hydroelectric Power Plant, the Itaipu Usinade on the Paraná River, between Brazil and Paraguay.

State-of-the-art hydraulic turbine patents belong to the public domain because they have been manufactured for over 20 years.

The conventional state-of-the-art hydraulic turbine contains a rotor or propeller attached to the rotary shaft coupled to the rotary shaft of the hydroelectric power plant generator.

State of the art electric generator:

State of the art electric generators are machines that transform mechanical energy into electrical energy.

State-of-the-art electric generators are mechanical water-wheel powered machines, blast motor, coal, oil and gas turbines, nuclear reactor turbines, water hydraulic turbines, tidal hydraulic turbines, rigs and propeller hydraulic machines Wind

The hydraulic turbine contains a rotor or propeller attached to a rotary shaft that rotates the rotary shaft of the electric generator, creating a magnetic field of electricity and generating electrical energy. State of the art electric generators are used atomic, hydroelectric and thermal power generators and power plants electricity generation, for the consumption of the population and the extractive, agricultural, industrial, commercial and service activities.

The manufacturing materials of the state-of-the-art electric generators of conventional hydroelectric power plants are iron, steel, copper and aluminum.

State-of-the-art conventional hydroelectric godine power generators range in size from 1 KWA to 700 MWH (one kilowatt ampere to seven hundred Mega-Watts per hour) of electric power generation power.

The largest electric generators in the state of the art of conventional hydropower plants are used at the Itaipu Power Plant, on the Paraná River, between Brazil and Paraguay.

State-of-the-art patents for conventional hydroelectric godines are in the public domain because they have been manufactured for over 20 years.

The state-of-the-art electric generator of conventional hydroelectric power plants contains an electromagnetic rotor attached to an eixogiratory coupled to the rotary axis of the conventional turbine hydraulic turbine.

State of the art water inlet pipes:

Hydraulic turbine state of the art water inlet pipes are forced pipes that conduct water that deflects from the force of gravity, dams or rivers dams, which is used to move the hydraulic turbine and electric generator from the conventional hydroelectric power plant.

The materials used in the manufacture of state-of-the-art water turbine pipes of conventional hydroelectric power plants are iron and steel.

The size of the state-of-the-art water inlet pipes varies from 10 centimeters to 10 meters in diameter, depending on the size of the conventional turbine's hydraulic turbine.

The largest water inlet pipes of the state of the art, from a hydroelectric dam to a hydroelectric dam, are used at the Itaipu Dam, on the Paraná River, between Brazil and Paraguay.

Patents on water turbine water inlet pipes from conventional hydroelectric power plants belong to the public domain because they have been manufactured for over 20 years.

The water inlet pipe of the state-of-the-art hydraulic turbine of the conventional hydropower technique has the inlet nozzle connected to the water inlet pipe that goes through the opening of the dam, downhill, through the opening in the ceiling or side wall, entering inside the powerhouse, with the water inlet pipe connected to the hydroelectric turbine.

State of the art water discharge suction pipes:

State-of-the-art water discharge suction pipes consist of pipes used to conduct the discharge of water that drives the hydraulic turbine of conventional hydroelectric plants. State-of-the-art water discharge pipes used in conventional turbine hydraulic turbines are called pipelines. water discharge suction, because of the similarity with water suction pipes of prior art water booster pumps.

The state-of-the-art water discharge suction pipes of conventional turbine hydraulic turbines are iron and steel.

Hydraulic turbine-type water discharge suction pipes from conventional hydroelectric power plants are connected to the hydraulic turbine, with the back bent with an upward downwardly directed water discharge end to orient the water stream from hydraulic turbine discharge also from top to bottom.

The back of the state-of-the-art water turbine suction duct suction pipes has a tapered shape with a maximum opening at an angle of 6o (six degrees) to facilitate water discharge.

State-of-the-art water turbine water discharge suction piping from conventional hydroelectric power plants has the top downward open discharge water vented or drowned in the drainage channel, where water is returned to the river's cursonormal.

The diameter size of the prior art hydraulic turbine water discharge suction pipes varies according to the size of conventional hydroelectric turbines. The largest state-of-the-art water discharge suction pipes are used in the Itaipu Plant hydraulic turbines, Paraná River, between Brazil and Paraguay.

State-of-the-art hydraulic turbine water discharge suction pipes patents are in the public domain because they have been manufactured for over 20 years.

The state-of-the-art water turbine discharge suction pipe from a conventional hydroelectric power plant is connected to the hydraulic turbine, being extended until it is plunged into the escaped river channel.

State of the art power grids:

State-of-the-art power grids are power grids used to conduct electric power from generation, transmission, distribution and consumption of populations and economic activities.

State-of-the-art electrical wires consist of cords or sheaths of electrically conductive metals.

The materials used in the manufacture of state-of-the-art electric wires are conductive metals such as copper, aluminum and metal alloys.

State of the art electric wire types are presented as hooded electric wires and metal apparent electric wires.

The largest state-of-the-art hydroelectric power grids are used at the Itaipu Plant on the Paraná River, between Brazil and Paraguay. Patents for state-of-the-art electric wires belong to the public domain because they have been manufactured for over 20 years.

State of the art electric generator electric networks:

Power grids used to conduct power generated in the state of the art hydroelectric power plants are connected to the power generator and are extended until they are attached to a power grid or tower embedded in the ground surface, the power grid being connected to the utility grid. populations and economic activities.

State of the art electric grid posts or towers:

State-of-the-art electric network pylons or towers are upright rods or structures, with their feet nailed to the earth's surface, used to secure the electrical networks above ground and out of reach of people.

The materials of manufacture of the technique state power poles are wood, iron, steel or reinforced concrete.

The fabrication materials of the technical state power grid towers are steel in the form of steel trusses.

The patents of state of the art electric poles or towers belong to the public domain because they have been manufactured for over 20 years.

State of the art powerhouses:

State-of-the-art powerhouses are called this because they house the installation of conventional thermal, atomic, or hydroelectric power plants, also known as electric power. State-of-the-art powerhouse powerhouses consist of buildings comprised of foundation, floor, side walls and ceiling wood, reinforced concrete, masonry built in a lower level and downstream of the dams or dams of the rivers, being of small, medium and large size according to the size of the hydroelectric plants installed inside.

The largest powerhouse in the state of the conventional hydroelectric power plant houses the Itaipu Power Plant, on the Paraná River, between Brazil and Paraguay.

State of the art powerhouse types of conventional hydropower plants are indicated as follows:

(a) conventional surface force houses;

(b) houses of underground forces near rivers.

State of the art powerhouse patents belong in the public domain because they have been built and used for over 20 years.

Also known is the powerhouse wedged in the armed deconcrete cave of the dam or river dam, having filed for Patent Application filed with the National Institute of Industrial Property in Brazil.

State of the art electric power terrestrial platform:

State-of-the-art ground power platforms consist of locations above ground surface for the installation of power stations and substations, with pole or power grid towers and power transformers. of the technique belong to the public domain because they have been used for over 20 years.

Other state of the art machines used in the hydropneumoelectric plant:

In addition to the machines and equipment used in conventional hydropower plants, the creation of the hydropneumoelectric plant of this Patent Application foresees the use of other state-of-the-art machines and equipment, which are indicated as follows:

(a) electric motor booster pump;

b) Compressor with electric motor;

c) Electric generator with explosion engine;

d) Electrical control board.

State of the art booster pumps:

State-of-the-art electric motor booster pumps consist of water lifting machines for use and consumption by the population and for extractive economic, agricultural, industrial, commercial and service activities.

The main types of booster pumps of the technical state are indicated as follows:

(a) rotary booster pumps;

(b) centrifugal booster pumps;

c) Axial booster pumps;

d) Turbo-bomb booster pumps. The materials used to manufacture booster pumps of the technical state are iron, steel, aluminum, metal alloys and plastics.

The size of state of the art booster pumps will vary within the booster capacity of 1 to 50,000 (one to fifty) liters of water per second.

Some of the largest state-of-the-art booster pumps used to transpose water from the Colorado River to the BigThompson Canal in the United States, which pump 50,000 liters per second to a height of 110 meters with 4-meter-diameter engine-driven pipes. 65,000 HP each installed in 1938.

State-of-the-art booster pump patents belong to the public domain because they have been manufactured for over 20 years.

The state of the art booster pump contains a rotor or propeller attached to a rotary shaft coupled to the rotary shaft of the booster pump electric motor.

State of the art electric motors:

State-of-the-art electric motors consist of electric-powered machines, which are used to move other machines, equipment and appliances for use by populations and for extractive, agricultural, industrial, commercial and service economic activities.

The main types of state-of-the-art electric motors are single-phase, two-phase and three-phase, alternating current or low-speed or high-speed motors.

Manufacturing materials for state-of-the-art electric motors are iron, steel, copper, aluminum and metal alloys. The largest state-of-the-art electric motors are used to transpose water from the Colorado River to the Big Thompson Channel in the United States by moving pumps. 50,000 liters of water per second, to a height of 110 meters, with pipes of 4 meters in diameter, each with a capacity of 65,000 HP, installed in 1938.

State-of-the-art electric motor patents belong to the public domain because they have been manufactured for over 20 years.

The state-of-the-art electric motor used to move a discharge pump contains an electromagnetic rotor fixed to a rotary axis coupled to the rotary axis of the machine, equipment or implement powered by the electric motor.

State of the art electric motor moving booster pump:

State-of-the-art electric motors are also used to move booster pumps for use by populations and for extractive, agricultural, industrial, commercial and service activities.

The state-of-the-art electric motor used to move the booster pump contains an electromagnetic rotor mounted on a rotary shaft coupled to the booster pump rotary shaft.

State of the art compressor:

State-of-the-art air compressors consist of machines or pneumatic pumps powered by an external power source that capture air into the atmosphere, producing compressed air blast for vehicles, machinery, equipment, apparatus and facilities for use by people and extractive economic activities, agricultural, industrial, commercial and service.The first waterwheel driven roller was invented in England by John Semeaton in 1762, perfected by John Wilkinson, creating the primitive model of today's air compressors in 1776. The main types of State of the art compressor are indicated as follows:

(a) piston compressor;

b) Screw compressor;

c) Reel compressor;

d) centrifugal compressor;

e) Turbine compressor or turbocharger.

The materials of manufacture of air compressors of the technical state are iron and steel.

The size and capacity of state-of-the-art air compressors varies with the size of the machines, equipment, and installations in which the compressor is used.

The largest state-of-the-art air compressors are used in industrial economic activities, producing up to 100,000 m3 (100,000 cubic meters) of compressed air per hour or 27,000 (twenty seven thousand) liters of compressed air per second powered by 900 HP electric motors. (nine hundred Horse Power).

State-of-the-art air compressor patents belong to the public domain because they have been manufactured for over 20 years.

The state-of-the-art compressor has an air-pressure chamber with an atmosphere air inlet nozzle containing a piston, bolt, reel or rotor mounted on a rotary shaft coupled to the rotary axis of the air compressor electric motor .

State of the art electric motor moving compressor:

State-of-the-art electric motors are also used to move air compressors used in vehicles, machines, equipment, appliances and facilities for use by populations and for extractive economic, agricultural, industrial, commercial and service activities.

The state-of-the-art electric motor used for moving the compressor contains an electromagnetic rotor attached to a rotary shaft coupled to the rotary axis of the compressor.

State of the art compressed air pipes:

State of the art compressed air pipes are reinforced pipes conducting compressed air blast produced by the use compressor of populations and economic activities.

State-of-the-art compressed air pipe materials are rubber, plastics, copper, iron, steel and alloys.

The diameter size of the technical state compressed air pipes varies with the size of the compressors.

Patents on state-of-the-art compressed air piping used in air compressors are in the public domain because they have been manufactured and used for over 20 years.

State-of-the-art compressed air tubing is connected to the compressor compression chamber and is extended until it is connected to the compressed air drum until it is connected to a machine, equipment or implement used with compressed air.

State of the art electric generator powered by explosion-proof motor:

State of the art electric generators are machines that transform mechanical energy into electrical energy.

State-of-the-art electric generators powered by water wheels, blast motors, coal, oil and gas turbines, nuclear reactor turbines, water hydraulic turbines, tidal power turbines, wave-powered hydraulic machines and power propellers. wind.

Also available in the state of the art are independent electric power generator sets that are powered by blast motors.

The manufacturing materials of the state-of-the-art electric generators powered by an explosion motor are iron, steel, copper and aluminum.

State-of-the-art electric-powered electric generators patents are in the public domain because they have been manufactured for over years.

The state-of-the-art electric generator powered by blasting motor is used for independent electric power generation, and the electric generator contains an electromagnetic rotor attached to an axle coupled to the crankshaft shaft of the blasting motor.

State of the art blasting motor:

State-of-the-art blast engines consist of machines that transform heat energy into mechanical energy. State-of-the-art blast motors are used to move automobiles, trucks, motorcycles, tractors, trains, boats, ships, electric generators and other machines of use. populations and economic activities.

The materials of manufacture of the state-of-the-art explosion engines are iron, steel and alloys.

State-of-the-art explosion engines are powered by internal combustion of gasoline, ethanol, diesel and biodiesel.

The size of state-of-the-art explosion engines ranges from 1 HP to 108,000 HP (one Horse Power up to one hundred and eighth Horse Power).

The largest state-of-the-art explosion engine is used for a 108,000 HP (one hundred and eight thousandHorse Power) freighter.

State of the art blast engine patents belong to the public domain because they have been manufactured for over 20 years.

The state-of-the-art blast motor used for state-of-the-art electric generator also contains a set of piston rods and connecting rods attached to a crankshaft shaft coupled to the electric generator eixogiratory.

State of the art electrical switchboard:

State-of-the-art electrical switchboards consist of switchboards used for centralizing and distributing electrical networks connected to switch switches for the activation of lamps, motors, machines and electrical appliances for the use of populations and economic activities. of the prior art are wood, masonry, reinforced concrete, iron, steel or plastics.

The size of the state-of-the-art electrical switchboards varies with the size of centralized and distributed electrical networks as well as the switch switches installed on the switchboards.

Patents on electrical control panels of the state of the art belong to the public domain because they have been manufactured for over 20 years.

The state of the art electrical switchboards are comprised of four side walls, which are interconnected and interlocked, where a back wall of the electrical switchboard is also attached.

Prior Art Toggle Switches:

State-of-the-art breaker switches consist of mechanical or electronic devices used to interrupt and activate the conduction of energy from electrical networks connected to light bulbs, motors, machines and electrical appliances for use by populations and economic activities.

The manufacturing materials of the technical state switch keys are copper, iron, steel, aluminum, metal alloys, wood, rubber and plastics.

The size of the state of the art key switches varies according to the size of the mains and the size of the lamps, motors, machines and electrical appliances where such switch keys are used. Patents for state of the art key switches belong to the public domain because They have been manufactured for over 20 years.

State of the art utility pole or tower:

State-of-the-art electric network pylons or towers consist of upright rods or structures used to secure and support the electric grids above ground and beyond the reach of people.

State-of-the-art utility poles or towers are embedded in the ground surface soil.

The materials used in the manufacture of the state of the art electric network pole are wood, reinforced concrete, iron or steel.

The materials used in the manufacture of the state of the art electric network tower are steel trusses.

The patents of state of the art electric poles or towers belong to the public domain because they have been manufactured for over 20 years.

Creation of the hydropneumoelectric plant:

The hydropneumoelectric plant created by this Patent Application consists of a group of interrelated objects comprised of a hydropneumoelectric plant installed within an immersed cylindrical powerhouse combined with a terrestrial platform and base for the operation of said machines and equipment. hydropneumoelectric plant.

The hydropneumoelectric power plant of this patent application is installed within the immersed cylindrical powerhouse.

The immersed cylindrical powerhouse of this Patent Application is constructed within the well water, well, tank, box, pool, cistern, reservoir, reservoir, dam, dam, lake, pond, river, sea and ocean of the globe. .

The machines used in the hydropneumoelectric power plant of this Patent Application, installed inside the immersed cylindrical powerhouse, are an electric generator hydraulic turbine and an electric motor booster pump.

The machines and equipment located on the ground platform of operation and support of machines, equipment and facilities of the hydropneumoelectric plant are a motor compressor, an electric generator with an explosion motor, a pole or electric tower.

The hydropneumoelectric plant of this Patent Application is moved by the use and reuse of water collected and returned from the water resources of dams, reservoirs, dams, dams, lakes, lakes, rivers, seas and oceans of the globe.

The hydropneumoelectric plant in this patent application is also powered by the use and reuse of air collected and returned to the atmosphere.

Working principle of hydropneumoelectric power plant:

The principle of operation of the hydropneumoelectric power plant of this Patent Application is based on the artificial creation of a displacement movement of the water captured and returned at the bottom of the globe's water resource, which is used and reused to move the hydro turbine of the hydropneumoelectric plant, using the power of an electric motor driven booster pump and an electric motor powered compressor.The hydropneumoelectric power plant of this Patent Application is installed inside the immersed cylindrical powerhouse located at the bottom of the well, tank, box, pool, cistern, reservoir, reservoir , reservoir, dam, dam, lake, pond, river, sea and ocean of globoterrestre.

Thus, the hydropneumoelectric plant of this patent application is located at a lower level than the surface of the water resource of the globe.

Thus, the hydraulic turbine of the hydropneumoelectric power plant of this Patent Application is moved by harnessing the energy potential existing in the weight of the water column of the globe's water resource.

Also the hydropneumoelectric plant of this patent application is powered by the artificial force of the motor driven booster pump, used to pull and repress water from within the hydraulic turbine, forming a stream of water that moves the hydraulic turbine with a coupled electric generator, generating renewable electric energy.

In addition, the hydropneumoelectric power plant of this Patent Application is powered by the artificial force of the electric motor driven compressor used to produce a compressed air jet injected into the hydraulic turbine exhaust pipe, forming a water stream and moving air bubbles. the hydraulic turbine with a coupled electric generator generating renewable electric energy.

Utilization and reuse of water from the hydro resource in the hydropneumoelectric plant:

The hydropneumoelectric plant of this Patent Application is moved with the use and reuse of water collected and returned from the water resource of a dam, dam, lake, pond, river, sea of the globe where the plant is installed.

Water from the water resource used and reused to move the hydraulic turbine from the hydropneumoelectric plant is captured at the bottom of this water resource, using the force of an electric motor driven booster pump, which pulls and represses water from inside the turbine to form a current. of water that moves this hydraulic turbine, forming an upward stream of water within the exhaust pipe of the hydraulic turbine, the water being returned to the bottom of the watercourse, forming an upward stream of water that rises to the surface, and is reused to move the hydraulic turbine again. hydropneumoelectric dausine, generating renewable electric energy with the use of water as a source of reusable natural energy resources.

The flow rate of water used and reused to move the hydropneumoelectric plant's turbine ranges from 30 to 1,500,000 (thirty to one million five hundred thousand) liters of water per second, according to the size of said hydraulic turbine.

The speed of the water stream used and reused for moving the hydropneumoelectric plant's hydraulic turbine ranges from 4 to 100 (four to one hundred) meters per second.

The hydraulic turbine rotor rotating speed of the hydropneumoelectric plant ranges from 15 to 2,700 RPM (RPM).

The greater the water depth of the water resource where the hydropneumoelectric plant of this patent is installed, the greater the amount of electricity that can be generated at this location. The greater the depth of the water resource of the hydropneumoelectric plant of this patent is installed. The lower the amount of electricity intended for self-consumption of the plant to maintain the continued operation of this hydropneumoelectric plant.

The water depth and height of the globe water column recommended for the construction or installation of the hydropneumoelectric powerhouse with immersed cylindrical powerhouse of this Patent Application ranges from 4 to 200 (four to two hundred) meters.

Utilization and reuse of atmospheric air in the hydropneumoelectric plant:

The hydropneumoelectric plant in this patent application is also powered by the use and reuse of air collected and returned to the atmosphere where the plant is installed.

Atmospheric air is used to move the hydropneumatic power plant through the use of a motor-driven compressor, which captures air into the atmosphere and produces a jet of compressed air injected into the hydraulic turbine's water outlet pipe, forming an upward stream of water and bubbles. inside the hydraulic turbine water outlet pipe and forming an upward stream of air bubbles into the water resource that rises to the surface, the air being returned to the atmosphere and reused to move the hydropneumoelectric plant's turbine, generating power renewable energy using air as a source of reusable natural energy resources.

The flow rate of air used and reused to move the hydropneumoelectric plant's turbine ranges from 10% to 30% (up to 30%) of the volume of water used and reused to move the hydropneumoelectric plant's hydraulic turbine in this Order.

The flow of air used and reused to move the hydropneumoelectric plant's turbine ranges from 3 to 500,000 (three to 500,000) liters of air per second.

The speed of the compressed air jet produced by the compressor to move the hydraulic turbine of the hydropneumoelectric plant varies from 9 to 360 (nine to three hundred and sixty) meters per second.

The upstream velocity of air bubbles within the water feature varies from 9 to 100 (nine to one hundred) meters per second, according to the strength of the compressor and the height of the water feature water column.

Physical forces used in the hydropneumoelectric plant:

The physical forces used to drive the hydraulic turbine and electric generator of the hydropneumoelectric power plant are indicated as follows:

a) Natural physical force of the weight of the water column of the water resource, having vector with direction and downward direction;

(b) Artificial physical force of the motor-driven booster pump having an upward direction and direction vector;

c) Artificial physical force of the compressor driven by electric motor, having vector with direction and upward direction;

(d) the natural physical force of the thrust of the water feature of the water resource exerted on the water stream drawn and repressed by the water pump from within the hydraulic turbine, having an upwardly directed vector;

e) Natural physical force of the water resource buoyancy of the water resource exerted on the bubble stream formed by the compressed air jet producing by the motor driven compressor, having direction and upward vector.

Size of hydropneumoelectric plants:

The number of sets of hydraulic turbines and electric generators installed in units of the hydropneumoelectric plant of this Patent Application may be of one or several sets as required.

The size of the hydraulic turbine and electric generator sets installed in the hydropneumoelectric power plant of this Patent Application ranges from 3 KWA up to 1,500 MWH (three kilo-watt-ampere to up to 1,500 Mega-Watts per hour) of electrical power.

Accordingly, the hydropneumoelectric power generation plants of this Patent Application are classified as follows:

(a) hydropneumoelectric micro plants;

(b) hydropneumoelectric mini-plants;

c) small hydropneumoelectric plants;

d) Medium hydropneumoelectric plants;

e) Large hydropneumoelectric plants;

f) Mega hydropneumoelectric plants. Parts and parts of the machinery, equipment and facilities of the hydropneumoelectric plant:

Parts and pieces of machinery, equipment and installations of the hydropneumoelectric plant, installed in the cylindrical powerhouse immersed in the terrestrial platform, with the numerical references of the drawings are indicated as follows:

(a) hydraulic turbine (10);

b) Electric generator (60) of the hydropneumoelectric plant (1);

(c) electric motor booster pump (42);

d) Compressor (66) with electric motor (72);

e) Electric generator (75) with blast motor (78);

(f) electrical switchboard (90);

(g) utility pole or tower (121);

(h) inlet nozzle (2) open from bottom to top;

(i) inlet pipe (3) of the hydraulic turbine (10);

j) Pipe bending (4);

l) Inlet pipe (6) of the hydraulic turbine (10) through the opening (215) in the side cylindrical wall (213) into the immersed cylindrical force housing (210);

m) Inlet line (8) containing a check valve (9);

n) Check valve (9);

(o) hydraulic turbine (10);

p) Rotor or propeller (11) of the hydraulic turbine (10); q) Swivel shaft (12) of the hydraulic turbine (10);

r) Electric generator (60);

s) Electromagnetic rotor (61) of the electric generator (60);

t) Rotary shaft (62) of electric generator (60).

Pipe Arrangement Parts and Parts:

The parts and pieces of the hydropneumoelectric power station backflush hydraulic outlet pipe, compressor, and backflow pipe of this Patent Application, with the numerical references of the drawings are as follows:

(a) hydraulic turbine outlet pipe (41);

(b) electric motor booster pump (42);

c) Outlet pipe (45) containing check valve (46);

d) Hydraulic turbine outlet line (47) running through the wall opening out of the immersed cylindrical powerhouse (210);

e) Hydraulic turbine outlet pipe (48) bend (10);

(f) T-connection pipe (49) for hydraulic turbine output (10);

g) Compressor tubing (71) (66);

h) Compressor (66) with electric motor (72);

(i) inverted suction pipe (53) from the hydraulic turbine outlet (10), oriented upwards;

j) Outlet nozzle (54) Outlet reverse suction pipe (53) Outlet hydraulic turbine (10), open bottom-up. Parts and machinery of the hydropneumoelectric power plant's ground platform of this Order , with the numerical references of the drawings are given as follows:

a) Compressor (66) with electric motor (72);

b) Compression chamber (67) of the compressor (66);

c) Inlet nozzle (70) of the compression chamber (67) of the compressor (66);

d) Piston, screw, reel or rotor (68) of the compressor (66);

e) Rotary shaft (69) of the compressor (66);

f) Electric motor (72) of the compressor (66);

g) Rotary shaft (74) of the electric motor (72) of the compressor (66);

(h) electric generator (75) with blast motor (78);

(i) the electromagnetic rotor (76) of the electric generator (75) with an exploding motor (78);

j) Rotary shaft (77) of electric generator (75) with explosion-proof motor (78);

(l) blasting motor (78);

m) Crankshaft shaft (79) of the engine in explosion (78).

The parts and pieces of the state-of-the-art electrical switchboard used in the hydropneumoelectric power plant of this Patent Application, with numerical references in the drawings, are indicated as follows:

(a) electrical switchboard (90);

(b) side wall (91) of the electrical switchboard (90) c) side wall (92) of the electrical switchboard (90);

(d) side wall (93) of the electrical switchboard (90);

e) Side wall (94) of the electrical switchboard (90);

f) Back wall (95) of the electrical switchboard (90).

State-of-the-art power grids and switch switches installed on the electrical switchboard of the hydropneumoelectric plant of this Patent Application, with the numerical references in the drawings, are as follows:

a) Electric network (100) from start-up of hydropneumoelectric plant (1) fixed to pole or tower (121), connected to electrical network (96) for the consumption of populations and economic activities, being extended electric network (100) until it is centralized in the table. electric control (90) and connected to the switch (97);

(b) Power line (101) from start-up of hydropneumoelectric plant (1) connected to electric generator (75) powered by explosion-proof motor (78) and extended until centered on electrical switchboard (90) and connected to switch switch (98) );

c) Electricity network (102) of the first part of 10% to 40% (ten to forty percent) of the electric power generated by the electric generator (60) of the hydropneumoelectric power station (1) of this Patent Application, destined for the self-consumption of the plant, being the mains (102) connected to the electric generator (60) and extended until it is centered on the electric control board (90) and connected to the switch (99);

d) Switching switch (97) of the power grid (100) fixed to the other pole (121) and connected to the power supply (96) of the population and economic activities used to start the hydropneumoelectric plant (1); e) Switching switch (98) ) from the mains (101) connected to the electric generator (75) with blast motor (78), used to start the hydropneumoelectric plant (1);

(f) 10 (40) to 40% (ten to forty per cent) of the first part mains switch (102) of the mains electricity (60) of the hydropneumoelectric plant (1) used to maintain the continued operation of the plant ;

g) Mains (103) connected to the switch switch (97) and extended until connected to the upper horizontal mains (106) of the electrical control board (90);

h) Mains (104) connected to the switch (98) and extended until connected to the upper horizontal mains (106) of the electrical control board (90);

(i) mains (105) connected to the switch switch (99) and extended until connected to the upper horizontal mains (106) of the electrical control board (90);

(j) upper horizontal mains (106) of the electrical control cabinet (90);

(l) central vertical mains (107) connected to the upper horizontal mains (106) and extended until connected to the lower horizontal mains (108) of the electrical switchboard (90);

m) Lower horizontal electrical network (108) of the electrical control cabinet (90);

n) Mains (109) connected to the lower horizontal mains (108) and extended until it is connected to the switch switch (111) of the electrical control board (90); o) Mains (114) connected to the lower horizontal mains (108) ) and extended until it is connected to the switch (112) of the electrical control board (90);

p) Mains (115) connected to the lower horizontal mains (108) and extended until it is connected to the switch (113) of the electrical control board (90);

(q) Electric motor actuation switch (111), repression pump (42);

r) Electric motor drive switch (112) and compressor (66);

s) Mains (116) distributed on the electric control board (90), connected to the switch (111) and extended until the electric motor (63) of the booster pump (42) is connected;

t) Mains (117) distributed on the electrical control board (90), connected to the switch (112) and extended until the electric motor (72) of the compressor (66) is connected.

The electricity consumption network (96) of the populations and economic activities that drives the first option's electric power from the start-up power to the hydropneumoelectric power plant and drives the second part of 60% to 90% (sixty to ninety percent) of the electric power of the electric generator hydropneumoelectric plant, is indicated as follows:

(a) Electricity network (96) of population and economic activity consumption, which is extended until it is fixed to the pole or tower (121) of the electric network installed on the terrestrial platform (260). hydropneumoelectric, to drive the electric motor which moves the booster pump and the electric motor that moves the compressor, as numerical references of the drawings, are indicated as follows:

(a) Electricity network (96) of population consumption and extended economic activities until it is fixed to the grid post or tower (121), installed on the terrestrial platform (260);

(b) Electric network (101) from start-up of hydropneumoelectric power plant (1) connected to electric generator (75) powered by explosion-proof motor (78) and installed on terrestrial platform (260), extending until centralized on electrical switchboard (90) ) and connected to the switch (98).

The electric grids that conduct the electric power generated by the electric generator of the hydropneumoelectric plant, with the numerical references of the drawings are indicated as follows:

a) Electricity network (102) which conducts the first part of 10% to 40% (sixty forty percent) of the electrical energy generated by the electric generator (60) of the hydropneumoelectric plant (1) of this Patent Application, intended for self-consumption by the Company. power plant, being the mains (102) connected to the electric generator (60) and extended until it is centered in the electric control frame (90) and connected to the switch (99);

(b) Electricity network (120) which conducts the second part of 60% to 90% (sixty to ninety per cent) of the electrical energy of the electric generator (60) of the hydropneumoelectric plant (1), with the electrical network (120) connected to the electric generator (60) and extended until it is fixed to the pole or power grid tower (121) installed on the ground platform (260), where it is connected to the power grid (96) of the population and economic activities.

Immersed cylindrical powerhouse of hydropneumoelectric power plant:

The immersed cylindrical powerhouse of this patent application was created with improvements introduced in the state-of-the-art hydropower powerhouses, resulting in functional improvements in use and manufacture.

The hydropneumoelectric power plant-immersed cylindrical powerhouse consists of a powerhouse constructed or installed within the water resource of a well, tank, box, pool, cistern, reservoir, reservoir, dam, dam, lake, pond. , river, sea and ocean of terrestrial globe.

The immersed cylindrical powerhouse is used for the installation in its interior of the hydropneumoelectric power plant of this patent application.

The materials used in the construction of the immersed strength house are masonry, reinforced concrete, iron, steel, marine steel, plastics or fiberglass.

The immersed cylindrical powerhouse has the upper edges of the sidewalls higher than the water surface and above the far-reaching waves.

The immersed cylindrical powerhouse is sealed against the water inlet, having an aerated and dry internal environment.

The size of the immersed cylindrical powerhouse of this Patent Application varies according to the size of the hydropneumoelectric power plant installed within it. The parts and pieces of the immersed cylindrical powerhouse construction, with the numerical references of the drawings are as follows:

(a) immersed cylindrical powerhouse (210);

b) Cylindrical foundation (211);

c) Floor (212);

d) Side cylindrical wall (213);

e) Ceiling (214);

(f) opening (218) in the side cylindrical wall (213) for passing through an inlet pipe (6) of the hydraulic turbine (10) of the hydropneumoelectric plant (1);

(g) opening (219) in the cylindrical side wall (213) for crossing a hydraulic turbine outlet pipe (47) from the hydropneumoelectric plant (1);

(h) Opening (217) in the roof (214) for access into the immersed cylinder house (210).

List of hydropneumoelectric power plant equipment:

The machinery and equipment of the hydropneumoelectric plant installed in the immersed cylindrical powerhouse, with the numerical references of the drawings, are indicated as follows:

(a) hydraulic turbine (10);

b) Electric generator (60) of the hydropneumoelectric plant (1);

(c) electric motor booster pump (42);

d) Compressor (66) with electric motor (72);

e) Electric generator (75) with blast motor (78) .The immersed cylindrical powerhouse is constructed in combination with a ground platform used as the base of operation and support of machines, equipment and facilities of the hydropneumoelectric plant.

Ground platform of hydropneumoelectric plant:

The hydropneumoelectric power plant terrestrial platform of this Patent Application was created with improvements made to state of the art terrestrial electric power platforms, resulting in functional improvements in use and manufacturing.

The hydropneumoelectric power plant terrestrial platform consists of a platform constructed or installed on the ground surface of the well, tank, box, pool, cistern, reservoir, reservoir, dam, dam, lake, pond water surface , river, sea and ocean of terrestrial globe.

The ground platform is used as the base of operation and support of machines, equipment and facilities of the hydropneumoelectric plant of this Patent Application.

The materials used in the construction of the hydropneumoelectric power plant terrestrial platform are masonry, reinforced concrete, iron, steel, plastics or fiberglass.

The size of the terrestrial platform varies according to the size of the hydropneumoelectric plant.

Parts and pieces of the construction of the hydropneumoelectric godine terrestrial platform, with the numerical references of the drawings, are indicated as follows: (a) terrestrial platform (260);

b) Floor (261).

List of ground platform machines, equipment and installations:

The machinery and equipment of the ground platform of operation and support of the hydropneumoelectric plant, with the numerical references of the drawings are indicated as follows:

a) Compressor (66) with electric motor (72);

(b) electric generator (75) with blast motor (78);

c) Electric control board (90);

d) Power pole or tower (121).

Hydraulic turbine of hydropneumoelectric power plant:

Prior art hydraulic turbines are also used in the hydropneumoelectric plant of this Patent Application.

The main types of hydro turbines of the hydropneumoelectric plant are described as follows:

(a) Francis vertical hydraulic turbine;

(b) Francis horizontal hydraulic turbine;

c) Horizontal Kaplan hydraulic turbine;

d) Horizontal Straflow hydraulic turbine.

The hydraulic turbine of the hydropneumoelectric plant is powered by the use and reuse of water collected and returned at the bottom of the globe's water resources, and is used to transform the kinetic energy of water movement into mechanical energy. that transforms mechanical energy into electrical energy.

The materials used in the manufacture of the hydropneumoelectric turbine hydraulic turbine are iron, steel, marine steel or stainless steel.

The size of the hydraulic turbine of the hydropneumoelectric plant varies according to the rotor, from 15 to 1000 (fifteen to one thousand) centimeters in diameter and according to the water inlet and outlet piping, which varies from 10 centimeters to 15 meters in diameter, having 30 to 1,500,000 (thirty to one million five hundred thousand) liters of water per second.

The hydraulic turbine rotor rotating speed of the hydropneumoelectric plant ranges from 100 to 2,700 RPM (RPM).

The patents for the hydropneumoelectric plant's hydraulic turbines are in the public domain because they have been manufactured for over 20 years.

The hydraulic turbine (10) of the hydropneumoelectric plant contains a rotor or propeller (11) fixed to the rotary shaft (12), coupled to the rotary shaft (62) of the electric generator (60) of the hydropneumoelectric plant (1).

Electric generator of hydropneumoelectric power plant:

State of the art electric generators are also used in the hydropneumoelectric power plant of this patent application to generate electric energy.

The hydraulic turbine of the hydropneumoelectric plant is powered by the use and reuse of water collected and returned to the bottom of the globe's water resources, rotating the rotor attached to the eixogiratory of the electric generator, creating a magnetic field of electricity and generating electrical energy.

The manufacturing materials of the electric power plants of the hydropneumoelectric plant are iron, steel, copper and aluminum.

The size of the power station's electric generators ranges from 3 KWA up to 1,500 MWH (three kilo-watt-amps up to 1,500 Mega-Watts per hour) of electrical power.

The patents for the power generators of the hydropneumoelectric plant are in the public domain because they have been manufactured for over 20 years.

The electric generator (60) used in the hydropneumoelectric power plant (1) contains an electromagnetic rotor (61) fixed to a rotary axis (62) coupled to the rotary axis (12) of the hydro turbine (10) of the hydropneumoelectric power plant (1).

Water turbine water inlet pipes of hydropneumoelectric power plant:

State-of-the-art hydraulic turbine water inlet piping from the conventional hydropower technique is also used in the hydropneumoelectric power plant hydraulic turbine.

The water turbine water inlet pipe of the hydropneumoelectric power plant is used to conduct the water collected and returned from the well resource, tank, box, pool, cistern, reservoir, reservoir, dam, dam, lake, pond, river. , sea and ocean of the terrestrial globe, where the hydropneumoelectric power plant is installed.The hydraulic turbine water inlet pipe consists of a pipe dipped into the bottom of the water resource, which crosses the passage opening in the side wall of the powerhouse, extended until it is connected to the hydraulic turbine of the hydropneumoelectric plant.

The materials used to manufacture the hydraulic turbine water inlet pipe of the hydropneumoelectric plant are iron, steel, marine steel or stainless steel.

The size of the hydropneumoelectric plant's hydraulic turbine water inlet piping ranges from 10 centimeters to 15 meters in diameter, depending on the size of the hydraulic turbine, with a volume of 30 to 1,500,000 (thirty to one million five hundred thousand) liters of water. per second.

The hydraulic turbine water inlet piping of the hydropneumoelectric power plant is installed in hydraulic turbines that drive electric generators with generation power of 3 KWA up to 1,500 MWH (three kilo-watt-amps up to one thousand five hundred Mega-Watts per hour) of electrical energy.

Inverted suction water outlet of the hydro turbine of the hydropneumoelectric plant:

The reverse turbine water outlet suction pipe of the hydraulic turbine of this patent application was created with the introduction of improvements and functional improvements in the use and manufacture of state-of-the-art conventional hydroelectric power plant water discharge suction pipes. Turbine-discharge water discharges from conventional hydroelectric power plants are thus called, because of their similarity to the state-of-the-art water booster suction pipe.

The major improvement is the installation of the inverted suction tubing of the hydraulic turbine water outlet, inverted from the bottom upwards, to direct the water outlet that moves said hydraulic turbine, forming a rising stream of water and rising air bubbles. to the surface.

The hydropneumoelectric power plant inverted water discharge inverted suction pipe has a tapered shape with a maximum opening angle of 6o (six degrees).

Thus the upward streams of water and the formed bubbles at the bottom of the water of the globe's water resource rise from the surface direction, completing the cycle of water and air utilization, which are again reused to move the hydro turbine of the hydropneumoelectric plant.

In the inverted water turbine water outlet suction pipe, the open hydraulic turbine water outlet nozzle is connected from the bottom upwards.

The manufacturing materials of the hydropneumoelectric power station water turbine inverted reverse suction pipe are offer, steel, marine steel or stainless steel.

The size of the water turbine hydro-turbine power plant inverted inverted suction pipe ranges from 10 centimeters to 15 meters in diameter, depending on the size of the hydraulic turbine, with a flow rate of 30 to 1,500,000 (thirty to one million one hundred thousand). liters of water per second.

Electric networks of hydropneumoelectric power plant electric generator:

Electric networks using state-of-the-art electrical wires are also used in the hydropneumoelectric plant of this patent application.

The patents of the power grids and the electrical wires of the hydropneumoelectric power plant are in the public domain because they have been manufactured and used for over 20 years.

The electric grids used to conduct the electric energy generated by the electric generator of the hydropneumoelectric plant, with numerical references of the drawings are indicated as follows:

a) Electricity network (102) of the first part of 10% to 40% (ten to forty percent) of the electric power of the electric generator (60) of the hydropneumoelectric plant (1), destined for the self-consumption of the plant, being the electric network (102 ) connected to the electric generator (60) and extended until it is centered in the electric control board (90) and connected to the switch (99);

b) Electricity network (120) of the second part of 60% to 90% (sixty one hundred percent) of the electric power of the electric generator (60) of the hydropneumoelectric power station (1) destined for the consumption of the population and the economic activities, being the electrical network (120) connected to the electric generator (60) and extended until it is attached to the grid or tower (121) installed on the ground platform (260) and connected to the electrical network (96) of the population and economic activities. hydropneumoelectric power plant:

State of the art booster pumps are also used in the hydropneumoelectric plant of this Patent Application.

The hydropneumoelectric power station booster pump is used to pull and squeeze water from inside the hydraulic turbine, creating a water displacement movement that moves this hydraulic turbine.

The booster pump of the hydropneumoelectric plant is powered by an electric motor.

The booster pump of the hydropneumoelectric plant is installed in the hydraulic turbine water outlet pipe, located inside the immersed cylindrical force housing.

The main types of booster pumps used in the hydropneumoelectric plant are indicated as follows:

(a) rotary booster pumps;

(b) centrifugal booster pumps;

c) Axial booster pumps;

d) Turbo-pump booster pumps.

The manufacturing materials of the booster pumps of the hydropneumoelectric plant are iron and steel and stainless steel.

The size of the booster pump of the hydropneumatic power plant varies according to the size of the hydraulic turbine water outlet pipe, being from 10 centimeters to 15 meters in diameter.

The size of the hydropneumatic booster booster pump varies within the ability to pull and repress from 30 to 1,500,000 liters of water per second.

The patents of the booster pumps of the hydropneumoelectric plant are in the public domain because they have been manufactured for over 20 years.

The hydropneumoelectric power station booster pump (42) contains a rotor (43) attached to a rotary shaft (44) coupled to the exogiratory (65) of the electric motor (63) of the booster pump (42).

Hydropneumoelectric power station booster pump electric motor:

State of the art electric motors are also used in the hydropneumoelectric power plant of this Patent Application.

The electric motor is used to move the hydropneumoelectric booster pump.

The booster pump is used to pull and squeeze water into the hydraulic turbine, creating a water displacement movement that moves this hydraulic turbine from the hydropneumoelectric plant.

The types of electric motors of the hydropneumoelectric power station booster pump are single-phase, two-phase or three-phase motors, alternating current or direct current and low or high speed.

The manufacturing materials of the electric pump pump motors, hydropneumoelectric power plant are iron steel, steel, copper, aluminum and metal alloys.

The power supply options for driving the power pump of the hydropneumoelectric power station's booster pump are indicated as follows: (a) In the first option, the electric power from the population and economic activities is used during the start-up time of the hydropneumoelectric plant;

(b) In the second option, the electric energy of the explosion-proof electric generator installed on the ground platform is used during the start-up time of the hydropneumoelectric plant;

c) In the third option, the first part of 10% to 40% (ten ninety percent) of the electric power of the electric power plant of the hydropneumoelectric plant, used for self-consumption, is used, maintaining the continuous operation of the plant and generating renewable energy.

The electric power consumption of the electric pump pump may reach up to 30% (thirty percent) of the electric power generated by the electric generator of the hydropneumoelectric plant, which is intended for the self consumption of this plant.

The size of the electric motor of the booster pump of the hydropneumoelectric plant varies within the power of 3 to 500,000 HP (three to five hundred thousand Horse Power).

The patents of the electric motors of the hydropneumoelectric booster pump are in the public domain because they have been manufactured and used for over 20 years.

The electric motor (63) used to move the hydropneumoelectric power station (1) pump (42) contains an electromagnetic rotor (64) attached to a rotary shaft (65) coupled to the eixogiratory (44) of the booster pump (42) .Compressor of hydropneumoelectric power plant:

Prior art air compressors are also used in the hydropneumoelectric plant of this Patent Application.

The hydropneumoelectric power plant compressor is used to capture air into the atmosphere and produce a jet of compressed air injected into the water outlet of the hydraulic turbine, creating a water-displacement movement that moves the hydraulic turbine.

The compressor of the hydropneumoelectric plant is powered by the electric motor.

The hydropneumoelectric power plant compressor is installed on the ground platform used as the base for the operation and support of the hydropneumoelectric power plant machines, equipment and facilities of this patent application.

The main types of compressors of the hydropneumoelectric plant are indicated as follows:

(a) piston compressor;

b) Screw compressor;

c) Reel compressor;

d) centrifugal compressor;

e) Turbine compressor or turbocharger.

The materials of manufacture of the compressors of the hydropneumoelectric plant are iron and steel.

The size and capacity of the hydropneumatic compressors varies within the ability to produce compressed air blast from 10 to 500,000 liters per second.

The patents of the hydropneumoelectric power plant compressors belong to the public domain because they have been manufactured for over 20 years.

The compressor (66) of the hydropneumoelectric plant has a compression chamber (67) with an inlet nozzle (70), containing in the compression chamber (67) a piston, bolt, reel or rotor (68) fixed to a rotary shaft (69). , coupled to the rotary axis (74) of the electric motor (72) of the compressor (66).

Electric compressor engine of hydropneumoelectric power plant:

State of the art electric motors are also used in the hydropneumoelectric power plant of this Patent Application.

The types of compressor electric motors of the hydropneumoelectric power plant are single-phase, two-phase or three-phase motors, alternating current or direct current and low or high speed.

The manufacturing materials of the hydropneumoelectric power plant's electric motors are iron, steel, copper, aluminum and metal alloys.

The options for powering the electric motor of the hydropneumoelectric plant compressor are indicated as follows:

(a) In the first option, the electricity from the power grid for the consumption of populations and economic activities shall be used during the start-up of the hydropneumoelectric plant, (b) In the second option, the electricity from the explosion-proof electric generator installed on the ground platform shall be used. during the start-up time of the hydropneumoelectric plant;

c) In the third option, the first part of 10% to 40% (ten ninety percent) of the electric power of the hydroelectric power station generator is used for the self-consumption of the plant, maintaining the continued operation of this hydro power plant, generating renewable electric power.

The electric power consumption of the compressor electric motor can reach up to 10% (ten percent) of the electric power generated by the electric generator of the hydropneumoelectric plant, which is destined for the self consumption of the plant.

The size of the compressor's electric motor at the hydropneumatic power plant ranges from 1 to 150,000 HP (one hundred and fifty thousand Horse Power).

The patents of the electric motors of the power station compressor belong to the public domain because they have been manufactured for over 20 years.

The electric motor (72) of the compressor (66) of the hydropneumoelectric plant contains a rotor (73) fixed to a rotary shaft (74) coupled to the rotary shaft (69) of the compressor (66).

Compressed air pipes of the hydropneumoelectric plant:

Compressed air pipes are also used in the hydropneumatic power plant of this patent application to conduct compressed air produced by the compressor. The types of compressed air pipes used in the hydropneumatic power plant are hard pipes and flexible pipes.

The materials used in the manufacture of compressed air pipes of the hydropneumoelectric power plant compressor are rubber, plastics, copper, iron, steel and alloys.

The size of the compressed air piping of the hydropneumoelectric compressor ranges within the ability to conduct from 10 to 500,000 (ten to five hundred thousand) liters of compressed air per second, depending on the size of the compressor.

The patents on the compressed air piping of the hydropneumoelectric plant are in the public domain because they have been manufactured for over 20 years.

The compressed air piping of the hydropneumoelectric plant is comprised of a tubing (71) connected to the compression chamber (67) of the compressor (66), and the tubing (71) is extended to be connected to the T-connection tubing (49). hydraulic turbine output (10).

Electric generator with blast motor from hydropneumoelectric power plant start-up:

The state-of-the-art electric generator powered by blasting motor is also used from the hydropneumoelectric plant of this patent application.

The blast motor electric generator is used as the second power source option of the hydropneumoelectric power plant of this Patent Application, driving the electric motor of the booster pump, the electric motor of the compressor only during the time of the hydropneumatic power plant startup.

The explosion-driven electric generator of the hydropneumoelectric plant is installed on the ground platform.

The manufacturing materials of the electric power generators with explosion-proof hydropneumoelectric power plant are iron, steel, copper and aluminum.

The size of the hydropneumoelectric blast-powered electric generators varies within the generation power of 3 KWA up to 500 MWH (three kilo-watt-amps up to five hundred Mega-Watts per hour) of electric power.

The patents for hydropneumoelectric blast-powered electric generators are in the public domain because they have been manufactured for over 20 years.

The state-of-the-art electric generator (75) powered by the explosion-proof motor (78) contains an electromagnetic rotor (76) attached to a rotary shaft (77), coupled to the crankshaft shaft (79) of the blast motor (78).

Explosion engine of electric generator at start of hydropneumoelectric plant:

State-of-the-art blast motors are also used in the hydropneumoelectric power plant of this Patent Application.

The blast motor is used to move the electric generator from the second power source option from the hydropneumoelectric power plant start-up to the booster pump electric motor and the compressor electric motor only during the hydropneumoelectric power plant start-up time.

Explosion engines are thermal motors powered by internal propulsion of gasoline, ethanol, diesel and diesel.

The blast motor is coupled to the electric generator installed on the ground platform.

The manufacturing materials of explosion engines are iron, steel and alloys.

The size of the blasting motor of the electric generator of the second hydropneumoelectric power plant start-up varies within the power range of 3 to 500,000 HP (three to five hundred thousand Horse Power).

The patents on the electric generator blast motors of the second hydropneumoelectric power plant start-up option belong to the public domain because they have been manufactured for over 20 years.

The blast motor (78) of the electric generator (75) of the hydropneumoelectric power plant's second starter power option (1) contains a crankshaft shaft (79) coupled to the rotary shaft (77) of the electric starter generator (75) hydropneumoelectric plant (1).

Electric grid of electric generator with starter motor of hydropneumoelectric starter:

The power grid of the hydropneumoelectric blast-powered electric generator of this Patent Application, which conducts the power of the second power plant start-up option, with the numerical references of the drawings is as follows: a) Power line (101) connected to the electric generator (75) driven by explosion-proof motor (78), being extended until it is centered in the electric control quadrode (90) and connected to the switch switch (98), the electric power being used to drive the electric motor (63) of the pump ( 42) and the electric motor (72) of the compressor (66) during the start-up time of the plant.

Electrical switchboard of the hydropneumoelectric plant:

State-of-the-art electrical switchboards are also used in the hydropneumoelectric power plant of this Patent Application.

The electrical switchboard is used for centralizing and distributing power grids and toggles of start-up power supply options and continued operation of the hydropneumatic plant.

Thus, the electric control cabinet is used to control the electric motor of the booster pump and the electric motor of the hydropneumoelectric power plant.

The electrical switchboard is installed on the ground platform used as the base of operation and support of machines, equipment and facilities of the hydropneumoelectric plant.

The fabrication or construction materials of the hydropneumoelectric power plant's electric control panel are wood, masonry, reinforced concrete, iron, steel or plastics.

The size of the electrical switchboard varies according to the size of the electrical grids and switch switches of the electric motor of the booster pump and compressor electric motor of the hydropneumatic power plant of this patent. Patents for electric control panels of the hydropneumatic power plant belong to the public domain, because they are manufactured over 20 years ago.

The electrical control panel (90) of the hydropneumoelectric plant is composed of a side wall (91), a sidewall (92), side wall (93) and side wall (94) which are fixed between them, where the bottom wall ( 95) of the electrical switchboard (90).

Switch electrical switches of the electrical switchboard of the hydropneumoelectric plant:

Prior art electric switch switches are also used in the hydropneumoelectric power plant of this Patent Application.

The electrical switch switches of the hydropneumoelectric plant are installed on the electrical switchboard on the ground platform.

The electric switch switches are used to drive the electric motor of the booster pump and the electric motor of the hydropneumoelectric power plant.

The manufacturing materials of the hydropneumoelectric power switch are copper, iron, steel, aluminum, metal alloys, wood, rubber and plastics.

The size of the hydropneumatic power switch switches varies according to the size of the electric motor, the booster pump, and the electric motor of the compressor.

The patents of the hydropneumatic power switch keys are in the public domain because they have been manufactured for over 20 years. The electric hydropneumatic power switch keys that are installed on the electrical control board installed on the ground platform, with the numerical references of the drawings are as follows:

(a) switch (97) of the mains (100) fixed to the other pole (121) and connected to the mains (96) of consumption of the population and the economic activities used in the start-up of the hydropneumoelectric power station (1);

(b) mains disconnect switch (98) (101) connected to the generator (75) with blast motor (78) used for starting the hydropneumoelectric plant (1);

c) Switching switch (99) of the first mains power (102) from 10% to 40% (ten to forty percent) of the electric power from the power generator (60) of the hydropneumoelectric plant (1), used to maintain the continued operation of the plant ;

(d) electric motor actuation switch (111), hydropneumoelectric power station discharge pump (42);

e) Electric motor drive switch switch (112) and compressor (66) of the hydropneumoelectric plant (1);

Power grid pole or tower of hydropneumoelectric plant:

State-of-the-art utility poles or towers are also used in the hydropneumoelectric plant of this Patent Application.

The power grid pole or tower of the hydropneumoelectric plant is used as follows:

a) Used to fix the power grid of the populations and economic activities that conduct the power of the first option of the hydropneumoelectric plant start-up b) Used to fix the power grid of the second part from 60% to 90% (sixty to ninety per cent). percent) of the electric power of the electric generator of the hydropneumoelectric plant, destined for the consumption of the population and the economic activities.

The materials used in the manufacture of the hydropneumoelectric power plant electric pole are wood, reinforced concrete, iron or steel.

The materials used in the manufacture of the hydropneumoelectric power plant electric network tower are steel trusses.

The patents on the power pylons or towers of the hydropneumoelectric plant belong to the public domain because they have been used for over 20 years.

The power grid post or tower (121) of the hydropneumoelectric power plant is composed of a vertical rod of wood, reinforced concrete and steel or a structure of nailed steel truss (261) of the ground platform (260).

Electricity consumption network of the populations and economic activities of the hydropneumoelectric dam:

The state-of-the-art power grid conducting the power consumption of populations and economic activities is also used in the hydropneumoelectric power plant of this Patent Application.

The power grid (96) consists of a grid connected to the interconnected system of power generation, transmission, distribution and consumption of populations and economic activities.

Electricity consumption network (96) of populations and economic activities is used in the hydropneumoelectric power plant as follows: a) Electricity network (96) used to conduct the electric power from the first power source option of the hydropneumoelectric power plant startup (1), driving the electric motor (63) of the electric emotor booster pump (42) of the compressor (66);

b) Electricity network (96) used to conduct the 60% to 90% (sixty to ninety percent) second part of the electrical power generated by the hydropneumoelectric power plant of this Patent Application, which is intended for consumption for the consumption of populations and economic activities. .

The parts and pieces of the power grid of the populations and economic activities used in the hydropneumoelectric power plant of this Patent Application, with the numerical references of the drawings are indicated as follows:

a) Electricity network (96) for the consumption of populations and economic activities, connected to the interconnected system of electricity generation, transmission, distribution and consumption of populations and economic activities, and the electrical network (96) extended until fixed to the pole or tower ( 121) from the power grid installed on the ground platform (260) of the hydropneumoelectric plant (1) of this Patent Application;

b) Mains (100) from the fixed to the pole or tower (121) of the mains where it is connected to the mains (96), being the mains (100) extended until it is centralized in the electric control board (90) and connected to the switch. switch (97), used at start-up of the hydropneumoelectric plant (1), driving the electric motor (63) of the booster pump (42) and the electric motor (72) of the compressor (66); c) Secondary power network (120) 60% to 90% (sixty one hundred percent) of the electricity generated by the electric generator (60) of the hydropneumoelectric plant (1), destined for the consumption of the population and economic activities, with the electric grid (120) connected to the electric generator (60) and extended until it is fixed to the pole or tower (121) of the power grid, installed on the ground platform (260), where it is connected to the power grid (96) of population consumption and economic activities.

Technical characteristics of the hydropneumoelectric power plant with immersed cylinder house and terrestrial platform:

The hydropneumoelectric power plant with immersed cylindrical powerhouse and ground platform, with the numerical references of the drawings, consists of an electric power generation plant comprising a hydropneumoelectric power plant (1) installed inside an immersed cylindrical powerhouse (210) combined with a ground platform (260), the hydropneumoelectric plant (1) comprising a hydraulic turbine (10) with coupled electric generator (60) and an electric motor decal pump (42) installed inside the immersed cylinder house (210) and a compressor (66) with electric motor (72), an electric generator (75) with blast motor (78), an electric switchboard (90) and a power pole or tower (121) installed on the ground platform (260) , the immersed cylindrical powerhouse (210) comprising a cylindrical foundation (211), floor (212), lateral wall (213) and roof (214), the terrestrial platform (260) comprising by a floor (261), existing in the state of the art conventional hydroelectric power plants, comprising a turbine with coupled electric generator, built and installed in the dams or dams, existing in the state of the art machines, equipment and installation such as repression with electric motors, electric motor compressors, electric generators with blast motors, electric motor aerators, electrical switchboards, power grid posts or towers, hydraulic turbine inlet pipes, hydraulic turbine outlet pipes, electrical wiring networks and switches electric switches, existing in the technical state the power houses of conventional thermal power plants, atomic plants and hydroelectric power plants, existing in the technical state the electric platforms of power stations and substations, networks and electrical transformers, being ca of immersed cylindrical force (210) characterized by the fact that the floor (212) is constructed within the perimeter of the cylindrical foundation (211), and the lateral cylindrical wall (213) is built on the perforated cylindrical wall (211). lateral cylinder (213) the roof (214) is supported, having an opening (218) in the lateral cylindrical wall (213) of the immersed cylindrical powerhouse (210) to traverse a turbine (10) inlet pipe (10) of the hydropneumoelectric plant (1) having an opening (219) in the side cylindrical wall (213) of the immersed cylindrical powerhouse (210) to pass an outlet pipe (47) of the hydraulic turbine (10) of the hydropneumoelectric dam (1) having an opening (217) in the ceiling (214) of access into the immersed cylindrical powerhouse (210), being the terrestrial platform (260) characterized by the fact that the floor (261) is constructed or installed on the ground surface ground, being the hydroelectric plant pneumatic power station with immersed cylindrical powerhouse and ground platform characterized by the fact that the inlet nozzle (2) is opened from the bottom up and connected to the hydraulic turbine inlet pipe (3), and inlet pipe (3) a pipe bend (4) is connected, where an inlet pipe (6) is connected through an opening (218) in the side cylindrical wall (213) into the immersed cylindrical powerhouse (210), with the natubulation (6) Inlet port is connected to an inlet line (8) containing a check valve (9), and the inlet line (8) is connected to the hydraulic turbine (10), and the hydraulic turbine (10) contains a rotor or propeller (11). ) fixed to a rotary shaft (12) coupled to the rotary shaft (62) of the electric generator (60), and the electric generator (60) contains an electromagnetic rotor (61) attached to this rotary shaft (62) of that electric generator (60), being q In the hydraulic turbine (10) an outlet pipe (41) is connected to the booster pump (42), and the booster pump (42) contains a rotor (43) attached to the rotary shaft (44) coupled to the rotary shaft. (65) the electric motor (63) of the booster pump (42), and the booster pump (42) is connected to an outlet pipe (45) containing a check valve (46), and to the pipe (45) The outlet pipe is connected to an outlet pipe (47) through the opening (219) in the cylindrical side wall (213) out of the immersed cylindrical powerhouse (210), and the outlet pipe (47) is connected to a pipe ( 48) outlet, to which an outlet T-connection pipe (49) is connected, and to the outlet T-connection pipe (49) an inverted outlet suction pipe (53) is connected to which the nozzle is connected. outlet (54) of the hydraulic turbine (10), open downwards The T-connection pipe (49) of the hydraulic turbine outlet (10) is also connected to a pipe (71) of the compressor (66) installed on the ground platform (260), having a common nozzle (66) on the compressor (66). 70) the inlet of the compression chamber (67) containing a piston, bolt, reel or rotor (68) fixed to the rotary shaft (69) coupled to the rotary shaft (74) of the electric motor (72) of the compressor (66), wherein in the compression chamber (67) an extended pipe (71) is connected until it is connected to said T-connection pipe (49) out of the hydraulic turbine (10), having in the terrestrial platform (260) an electric generator (75) powered by a blast motor (78), the electric generator (75) containing an electromagnetic rotor (76) attached to a rotary shaft (77) coupled to the crankshaft shaft (79) of the blasting motor (78), having on the ground platform ( 260) an electrical switchboard (90) comprised of a sidewall (91), a a side wall (92), a side wall (93) and a side wall (94), which are interconnected and fixed to one another, where the bottom wall (95) is also fixed, and in the electrical switchboard (90) centralized and distributed the electrical networks and switches of the electric power of the options of energy sources of the hydropneumoelectric plant, being centralized the electric network (100), electric network (101) and electric network (102), being installed the interrupter switch (97), switch switch (98), switch switch (99), switch switch (111) and switch switch (112), being distributed the electric network (116) and electric network (117) of the booster pump (42) and electric motor (72) and the compressor (66), having the centralization of the electric network (100) connected to the electrical network (96) of consumption of the populations and economic activities attached to the pole or tower (121) of the electric network installed on the ground platform (260), being the electric grid (100) extended until it is centered on the electrical control board (90) where it is connected to the switch switch (97), with the centralization of the electric network (101) connected to the electric generator (75) with an explosion-proof motor (78) installed on the platform. (260), the power grid (101) being extended until it is centralized in the electric control quadrode (90) where it is connected to the switch (98), with the power grid (102) centralizing the first part of the electric power of the electric generator (60) from the hydropneumoelectric power plant (1), being the electric net (102) connected to the electric generator (60) and extended to the electric control frame (90) installed on the ground platform (260) where it is connected to the switch (99), having a mains (103) connected to the switch (97) and extended until it is connected to the upper horizontal mains (106), having a mains (104) connected to the switch (98) and extended until it is connected in the upper horizontal mains (106), having an electrical mains (105) connected to the switch switch (99) and extended until connected to the upper horizontal mains (106), having an upper horizontal mains (106), having a central mains (107) connected to the upper horizontal mains (106) and extended until it is connected to the lower horizontal mains (108), having a lower horizontal mains (108), having an electric mains (109) connected to the lower horizontal mains (108) and extended until it is connected to the switch (111), having a mains (114) connected to the lower horizontal mains (108) and extended until it is connected to the switch (112), having the mains distribution (116) connected to the switch (111) ) and extended until it is connected to the electric motor (63) of the booster pump (42), with the mains distribution (117) connected to the switch (112) ) and extended until the electric nomotor (72) of the compressor (66) is connected, having on the terrestrial platform (260) a power pole or tower (121) where the population and activities consumption electric network (96) is fixed. the electric generator (60) of the hydropneumoelectric plant (1) has an electric grid (102) from the first part of the electric power of the hydropneumoelectric plant (1), the electric grid (102) being connected to this electric generator (60) and extended to the electric control (90) where it is connected to the switch (99), having in the electric generator (60) of the hydropneumoelectric plant (1) an electric grid (120) of the second part of the electric power of the hydropneumoelectric plant (1), being the electric network ( 120) connected to the generator (60) and extended until it is fixed to the pole or tower (121) of the grid installed on the terrestrial platform (260), with the grid (120) connected to the grid (96) of consumption of the populations and of extractive economic activities, agricultural, industrial, commercial and services.

Start-up and operation phases of the hydropneumoelectric plant:

The start-up phases of the hydropneumoelectric plant using the first power source option (96) of the population and economic activities are indicated as follows:

a) First phase: Opening of the check valve (9), filling the hydraulic turbine (10);

b) Second phase: Opening of the check valve (46), also filling the hydraulic turbine (10);

c) Third phase: Switching of the switch (97) of the electric control panel (90);

e) Fourth phase: Switching the switch (111) of the electric control panel (90), activating the electric motor (63) of the booster pump (42);

f) Fifth Phase: Switching of the switch switch (112) of the electric switchboard (90), driving the electric motor (72) of the compressor (66) air; g) Sixth phase: Switching of the switch switch (99) of the switchboard ( 90), using the first part of 10% to 40% (ten to forty percent) of the electric power of the electric generator (60), destined for self-consumption of the hydropneumoelectric power plant (1), keeping the electric motor drive (63) of the pump (42) discharge and electric motor (72) of the compressor (66), maintaining the continued operation of the hydraulic turbine (10) and the electric generator (60) of the hydropneumoelectric plant (1), generating renewable electric energy;

h) Seventh phase: Switching off the switch (97) of the electric control panel (90), maintaining the continued operation of the hydropneumoelectric power station (1), generating renewable electric energy.

The start-up phases of the hydropneumoelectric power plant with the use of the second power generator option (75) with an explosion-driven electric generator (78) installed on the ground platform (260), are indicated as follows:

a) First phase: Opening of the check valve (9), filling the hydraulic turbine (10);

b) Second phase: Opening of the check valve (46), also filling the hydraulic turbine (10);

c) Third phase: Explosion motor connection (78) driving the electric generator (75) generating electric power to start the hydropneumoelectric power plant (1);

d) Fourth phase: Switching the switch (98) of the electric switchboard (90) e) Fifth phase: Switching the switch (111) of the switchboard (90), driving the electric motor (63) of the pump ( 42) of repression;

f) Sixth phase: Switching the switch (112) of the electric control panel (90), activating the electric motor (72) of the compressor (66);

g) Seventh phase: Switching of the switch switch (99) of the electric switchboard (90), using the first part of 10% to 40% (ten to forty percent) of the electricity generated by the electric generator (60), destined to consumption of the hydropneumatic power plant (1), maintaining the drive of the electric motor (63) of the booster pump (42) and the electric motor (72) of the compressor (66), maintaining the continuous operation of the hydraulic turbine (10) and the electric generator ( 60) from the hydropneumoelectric plant (1), generating renewable electric energy;

h) Eighth phase: Switching off the switch (98) of the electric control panel (90), maintaining the continued operation of the hydropneumoelectric power station (1), generating renewable electric energy;

i) Ninth phase: Explosive motor shutdown (78), paralyzing the movement of the electric generator (75), maintaining the continued operation of the hydropneumoelectric plant (1), generating renewable electric energy.

Flow of water, air and electricity at the hydropneumoelectric plant:

The flow of water, air and electric power in the immersed cylindrical powerhouse with ground platform and ground platform of this Patent Application begins with the abstraction of water through an inlet (2) open, bottom-up, vented into the water of the resource. water flowing through an inlet pipe (3) of the hydraulic turbine (10), through a pipe bend (4), through an inlet pipe (6) through the opening (218) in the cylindrical wall side (213) inwardly of the immersed cylindrical powerhouse (210), the water stream passing through an inlet pipe (8) with an open check valve (9), and the water stream entering the hydraulic turbine (10). ) by rotating the rotor or propeller (11) fixed to a rotary shaft (12) coupled to the rotary shaft (62) of the electric generator (60), while also rotating the electromagnetic rotor (61) fixed to that rotary shaft (62) dogera (60), creating a magnetic field of electricity and generating electrical energy, with the water flowing through an outlet tubing (41) connected to the electric motor driven booster pump (42), passing inside the pump (42) through an outlet pipe (45) containing an open check valve (46), through an outlet pipe (47) through the opening (219) in the side cylindrical wall (213) out of the immersed cylinder house (210) passes through an outlet pipe bend (48), goes through an outlet T-connection pipe (49), goes through an outlet inverted suction pipe (53) and passes through the final nozzle (54) The hydraulic turbine outlet (10) is opened from the bottom upwards and the water is returned to the bottom of the water resource, forming an upward stream of water that rises to the surface, while the water remains within the water resource. again The hydraulic turbine (10) of the hydropneumoelectric power plant (1) has been reused, having on the terrestrial platform (260) a compressor (66) powered by an electric motor (72), and the air from the atmosphere is captured by the inlet nozzle (70) of the chamber. compression air (67), whereby the air passes into the compression chamber (67), where this air is compressed by the piston, screw, rotor, or rotor (68) attached to the rotary shaft (69), coupled to the rotary shaft (74) of the electric motor (72) of the compressor (66), wherein the pressure chamber (67) produces a jet of compressed air which passes through an extended tubing (71) until it is connected to the turbine outlet T-connection tubing (49) (10), wherein the jet of compressed air is injected into said T-connection tubing (49) of the hydraulic turbine (10), forming a stream of air bubbles within the hydraulic turbine outlet tubing, the current being from dear bubbles goes through a pipe (47) through the opening (219) through the side cylindrical wall (213) exiting outside the immersed cylindrical powerhouse (210), the stream of air bubbles passing through an inverted outlet pipe (53) and passes through the bottom end nozzle (54) of the hydraulic turbine outlet (10) open from the bottom upwards, where the stream of air bubbles is driven into the bottom water by the water course, forming an upward stream of air bubbles rising to the bottom. the surface, with air being returned to the newly reused atmosphere to power the hydropneumoelectric power plant (1), the terrestrial platform (260) an electric generator (75) with an exploding motor (78), from the second starter power source option hydropneumoelectric plant (1), where the electric power generated by the electric generator (75) is conducted by the electric network (101) extended until it is connected to the switch (98), from where it is taken to start hydropneumoelectric plant (1), driving the electric motor (63) of the booster pump (42) and the electric motor (72) of the compressor (66), having on the terrestrial platform (260) an electric control board (90) with nets and switches the electric motor (63) of the pump (42) and the electric motor (72) of the compressor (66), where the electric power of the first power source option of the hydropneumoelectric power plant (1) is conducted by the electric network (96) populations and economic activities fixed on the power pole or tower (121), from where it is led by the power grid (100) connected to the power line (96) and extended until it is connected to the switch (97), with the The electrical power of the second hydropneumoelectric power station start-up power supply option (1) is generated by the electric generator (75) powered by an explosion-proof motor (78) and installed on the ground platform (260), from which it is driven by the electrical grid. (101) connected to the electric generator (75) and extended until it is connected to the electric switch (98), and the electricity intended for self-consumption is generated by the electric generator (60) powered by the hydraulic turbine (10) of the hydropneumatic plant (1). ), where it is led by the mains (102) connected to the electric generator (60) and extended until it is connected to the electric switch (99), and the electric power is carried by an electric network (103) connected to the switch (97) ) and extended until it is connected to the upper horizontal mains (106), the power being driven by a mains (104) connected to the switch switch (98) and extended until it is connected to the upper horizontal mains (106), where the power The power is driven by a power grid (105) connected to the switch switch (99) and extended until it is connected to the upper horizontal power grid (106), where the power is The power supply is conducted by a central vertical mains (107) connected to the upper horizontal mains (106) and extended until the lower horizontal mains (108) is connected, and the electric power is carried by a mains (109) connected to the mains. lower horizontal (108) and extended until it is connected to the toggle switch (111), and the electrical power is conducted by a mains (114) connected to the lower horizontal mains (108) and extended to be connected to the toggle switch (112), whereby the electric power is conducted by an electric network (116) connected to the switch switch (111) and extended until it is connected to the electric motor (63) of the booster pump (42), and the electric power is conducted by an electric network (117) connected to the switch (112) and extended until the electric motor (72) of the compressor (66) is connected, having on the ground platform (260) an electric pole or tower (121) This is where the electricity grid (96) for the consumption of populations and economic activities is fixed, with the electric generator (60) having an electricity grid (102) of the first part of 10% to 40% (ten percent to forty percent) of the energy. generated by the hydropneumoelectric plant (1) and destined for the self-consumption of the plant, where the first part of the electric energy is conducted by the electric network (102) connected to the electric generator (60) and extended until it is centralized in the electric control frame (90) and connected to the switch switch (99), and the electric power is conducted to drive the electric motor (63) of the booster pump (42) and the electric motor (72) of the compressor (66), having in the electric generator (60) a grid 60% to 90% (sixty to ninety percent) of the electrical energy generated at the hydropneumoelectric plant (1), and the electrical energy is conducted by the electrical network (120) connected to the electrical generator (60) and extends until it is fixed to the power pole or tower (121), and the power grid (120) is connected to the power grid (96) for the consumption of populations and extractive, agricultural, industrial and service activities.

Figures with numerical references of the drawings: Figures (FIG.) With the numerical references of the drawings show the parts parts of the objects, machines, equipment and installations of the hydropneumoelectric power plant with immersed cylindrical powerhouse and terrestrial platform, indicated as follows:

Figure (FIG. 1) shows the drawing of the hydropneumoelectric power plant (1) with immersed cylindrical powerhouse (210) and terrestrial platform (260).

The figure (FIG. 2) shows the drawing of the hydropneumoelectric plant (1) with inlet and outlet nozzles on opposite sides, with the main machines, equipment and installations indicated as follows:

(a) hydraulic turbine (10);

b) Electric generator (60) of the hydropneumoelectric plant (1);

(c) electric motor booster pump (42);

c) Compressor (66) with electric motor (72);

(d) electric generator (75) with blast motor (78);

e) Electrical switchboard (90);

f) Power pole or tower (121).

Figure (FIG. 3) shows the drawing of the immersed cylindrical powerhouse (210) of hydropneumoelectric power plant (1);

Figure (FIG. 4) shows the drawing of the ground platform (260) of hydropneumoelectric power plant (1);

The figure (FIG. 5) shows the drawing of the electrical control board (90) with the centralization and distribution of electrical networks and the installation of the switch keys. Patent filings:

Previous searches were carried out through INPI, through the Internet, and no results were found for the hydropneumoelectric power plant with immersed cylindrical powerhouse and ground platform, as well as the hydropneumoelectric power plant of this Patent Application, as attached documents, as follows:

a) INPI Patent Consultation Documents;

b) INPI Database Consultation Documents;

c) Important Notice Document, Note on the digitized Publications acquis.

Constructive variants:

Constructive variants of Utility Model objects of hydropneumoelectric power plants, which are not part of the state of the art or the public domain, and appearing in this Depositor's Industrial Property Registration Patent Applications, are indicated as follows:

• Hydroelectric plant dam or dam;

• WATER TANK OF HYDROPNEUMOELECTRIC SURFACE;

CYLINDRICAL SURFACE WATER TANK OF USINAHYDROPNEUMOELECTRIC;

• HYDROPNEUMOELECTRIC POWER SURFACE HOUSE;

• HYDROPNEUMOELECTRIC POWER PLANT IMMERSE FORCE;

• IMMERSE CYLINDRIC POWER PLANT OF USINAHYDROPNEUMOELECTRIC;

• IMMERSE FORCE HOUSE WITH PLATFORM ON THE HYDROPNEUMOELECTRIC DEUSINE CEILING;

• HYDROPNEUMOELECTRIC POWER UNDERGROUND POWER HOUSE • HYDROPNEUMOELECTRIC POWER UNDERGROUND POWER HOUSE;

• HYDROPNEUMOELECTRIC PLANT GROUND PLATFORM;

• FLOATING HYDROPNEUMOELECTRIC PLATFORM;

• PLATFORM ABOUT USINAHYDROPNEUMOELECTRIC POWER HOUSE CEILING;

• FIXED AQUATIC, MARITIME OR OCEANIC PLANTFORM OF HYDROPNEUMOELECTRIC;

• SEMI-SUBMERSIBLE PLANTFORM OF HYDROPNEUMOELECTRIC;

FLOATING BOAT OR USINAHYDROPNEUMOELECTRIC PLATFORM;

• BOAT OR SHIP WITH HYDROPNEUMOELECTRIC GENERATOR GROUP;

• BOAT OR SUBMARINE SHIP WITH HYDROELECTRIC GENERATOR GROUP;

INVERTED SUCTION PIPE ARRANGEMENT OF HYDROPNEUMOELECTRIC POWER DETURBINE OUTPUT;

• HYDROPNEUMOELECTRIC PLANT WITH INPUT AND OUTPUT NOZZLE;

• Hydroelectroelectric plant with nozzle inlet and outlet on opposite sides;

• HYDROPNEUMOELECTRIC POWER PLANT WITH SURFACE WATER TANK;

• Hydro-pneumatic power plant with powerhouse and surface water deposit;

HYDROPNEUMOELECTRIC PLANT DAM OR SURFACE COMCASA DAM;

• HYDROPNEUMOELECTRIC POWER PLANT WITH IMMERSE FORCE HOUSE AND EARTH PLATFORM;

• HYDROPNEUMOELECTRIC POWER PLANT WITH IMMERSE DECILINDRIC POWERFORCE AND GROUND PLATFORM • HYDROPNEUMOELECTRIC POWER PLANT WITH IMMERSE POWER PLATFORM OVER THE CEILING;

• HYDROPNEUMOELECTRIC POWER PLANT WITH SUBMERSE FORCE HOUSE AND EARTH PLATFORM;

HYDROPNEUMOELECTRIC PLANT WITH SUBMERSE FORCE HOUSE FLOATING PLATFORM;

• HYDROPNEUMOELECTRIC PLANT WITH SUBMERSE FORCE HOUSE FIXED AQUATIC, MARITIME AND OCEANIC PLATFORM;

• HYDROPNEUMOELECTRIC POWER PLANT WITH SEMI-SUBMERSIBLE SUBMERSE POWER PLANT;

• HYDROPNEUMOELECTRIC POWER PLANT WITH SUBMERSE FORCE HOUSE FLOATING BOAT OR SHIP;

• HYDROPNEUMOELECTRIC PLANT WITH UNDERGROUND FORCE HOUSE AND GROUND PLATFORM;

SHIELD SUBMERSED HYDROPNEUROELECTRIC PLANT;

• BOAT OR SHIP HYDROPNEUM ELECTRIC GENERATOR GROUP;

• HYDROELECTRIC GENERATOR SET OF BOAT OR UNDERWATER SHIP.

Claims (2)

1. "HYDROPNEUROELECTRIC POWER PLANT WITH IMMERSE CYLINDRICAL DEFORMANCE HOUSE AND GROUND PLATFORM" of this Patent Application, which consists of an electric power generation plant, comprised of a hydropneumoelectric power plant (1) installed within a combined cylindrical powerhouse (210) ground platform (260), the hydropneumoelectric plant (1) comprising a hydraulic turbine (10) with coupled electric generator (60) and an electric motor booster pump (42) (63) installed within the immersed cylindrical powerhouse ( 210) and a compressor (66) with an electric motor (72), an electric generator (75) with a blast motor (78), an electrical switchboard (90) and a power pole or tower (121) installed on the ground platform (260), the immersed cylinder house (210) comprising a cylindrical foundation (211), floor (212), side cylindrical wall (213) and ceiling (214), the ground platform (260) comprising by a floor (261), existing in the technical state conventional hydroelectric power plants, comprised of a hydraulic turbine with coupled electric generator, built and installed in dams or dams, existing in the technical state machines, equipment and installation such as pump with electric motors, electric motor compressors, electric generators with blast motors, electrical switchboards, electric network pylons or towers, hydraulic turbine inlet pipes, hydraulic turbine outlet pipes, electrical wire networks and electrical switch switches, existing in the state of the art are the powerhouses of thermal power plants, atomic plants and conventional hydroelectric power plants, existing in the state of the art the electrical platforms of stations and substations of electrical networks and transformers, being the immersed cylindrical powerhouse (210) c characterized by the fact that the floor (212) is constructed within the perimeter of the cylindrical foundation (211), and that on the cylindrical foundation (211) is constructed the lateral cylindrical wall (213), and on the lateral wall (213) the (214) having an opening (218) in the side cylindrical wall (213) of the immersed cylindrical powerhouse (210) to traverse an inlet pipe (6) of the hydraulic turbine (10) of the hydropneumoelectric dam (1) having a opening (219) in the lateral wall (213) of the immersed cylindrical powerhouse (210) to traverse an outflow pipe (47) of the hydraulic turbine (10) from the hydropneumatic plant (1), having an opening (217) in the ceiling (214) access into the immersed cylindrical powerhouse (210), being the terrestrial platform (260) characterized by the fact that the floor (261) is constructed or installed on the ground surface ground, being the hydropneumoelectric power plant with cylindrical powerhouse immersed induction and ground platform characterized in that the inlet nozzle (2) is opened in the bottom-up direction and connected to the hydraulic turbine inlet pipe (3), and inlet pipe (3) a pipe bend is connected (4), where an inlet tubing (6) is connected through an opening (218) in the side cylindrical wall (213) into the immersed cylindrical powerhouse (210), and the inlet port (6) is connected to one. inlet tubing (8) containing a check valve (9), the inlet tubing (8) being connected to the hydraulic turbine (10), and the hydraulic turbine (10) containing a rotor or propeller (11) attached to a shaft (12) coupled to the rotary shaft (62) of the electric generator (60), and the electric generator (60) contains an electromagnetic rotor (61) attached to this rotary shaft (62) of this electric generator (60), and in the hydraulic turbine ( 10) is conec outlet pipe (41) that connects to the booster pump (42), the booster pump (42) contains a rotor (43) attached to the rotary shaft (44) coupled to the rotary shaft (65) and electric motor (63) ) of the booster pump (42), where the booster pump (42) is connected with an outlet pipe (45) containing a check valve (46), and in the outlet pipe (45) a pipe (47) is connected. ) through the opening (219) in the cylindrical lateral wall (213) exiting outside the immersed cylindrical powerhouse (210), where the outlet pipe (47) is connected to an outlet pipe curve (48) into which connects an outlet T-connection tubing (49), and the outlet T-connection tubing (49) connects an inverted outlet suction tubing (53), to which the outlet end nozzle (54) is connected to the outlet. hydraulic turbine (10), open from below to above, and in the connection pipe The T-outlet (49) of the hydraulic turbine (10) is also connected to a compressor pipe (71) (66) installed on the ground platform (260), having in the compressor (66) a common inlet (70) of the (67) containing a piston, bolt, reel or rotor (68) fixed to the rotary shaft (69) coupled to the rotary shaft (74) of the electric motor (72) of the compressor (66), and in the compression chamber ( 67) an extended pipe (71) is connected until it is connected to said T-connection pipe (49) out of the hydraulic turbine (10), having on the terrestrial platform (260) an electric generator (75) driven with an explosion motor (78). ), wherein the electric generator (75) contains an electromagnetic rotor (76) fixed to a rotary shaft (77) coupled to the crankshaft shaft (79) of the blasting motor (78), having on the ground platform (260) an electric switchboard ( 90) comprised of a sidewall (91), a sidewall (92), a sidewall (93) and a sidewall (94) which are interconnected and fixed to each other, where also the bottom wall (95) is fixed, and the electrical control board (90) is centralized and distributed the electrical networks and switch keys power options from the hydropneumoelectric power plant options, which are centralized to the power grid (100), the power grid (101) and the power grid (102), and the switch switch (97), switch switch (98), switch switch (99) are installed. ), switch switch (111) and switch switch (112), being distributed the mains (116) and mains (117) of the electric motor (63) of the booster pump (42) and electric motor (72) of the compressor (66) having the centralization of the mains (100) connected to the mains power (96) fixed to the pole or tower (121) of the mains installed on the ground platform (260), the mains (100) being extended until centralized in the electric control board ( 90) where is it connect switch center (97), with the centralization of the electric grid (101) connected to the electric generator (75) with an explosion-proof motor (78) installed on the terrestrial platform (260), and the electric grid (101) extended until it is centralized in the switchboard. electrical control (90) where the switch key (98) is connected, with the centralization of the electrical network (102) connected to the electric generator (60) and extended to the electrical control board (90) installed on the ground platform (260), where it is connected to the switch switch (99), having a mains (103) connected to the switch switch (97) and extended until it is connected to the upper horizontal mains (106), having an electrical network (104) connected to the switch switch (98) and extended until connected to the upper horizontal mains (106), having a mains (105) connected to the switch switch (99) and extended until connected to the upper horizontal mains (106), having a horizontal mains (106) has a vertical central power grid (107) connected to the upper horizontal power grid (106) and extended until it is connected to the lower horizontal power grid (108) having a lower horizontal power grid (108) having a power grid ( 109) connected to the lower horizontal mains (108) and extended until it is connected to the switch switch (111), having an electrical network (114) connected to the lower horizontal mains (108) and extended until it is connected to the switch switch (112), having The distribution of the mains (116) connected to the switch switch (111) and extended until it is connected to the electric motor (63) of the pump (42) and the distribution of the mains (117) connected to the switch (112) and extended until connected to the electric motor (72) and the compressor (66), having on the terrestrial platform (260) a power pole or tower (121) where the electric network (96) is fixed, having on the electric generator (60) an electrical network (102) extended to the electrical control board (90) where it is connected to the switch switch (99), having in the electrical generator (60) an electrical network (120) extended until it is fixed to the other pole (121) of the electrical network. installed on the ground platform (260) being the electric net (120) connected to the electric network (96).