RU2261996C1 - Thermal power station - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: in proposed thermal power station containing steam generator, steam turbine, electric generator, and condenser, well tubes are arranged in vertical plane in lower layers of Earth's crust and are made to release thermal energy from lower layers of Earth's crust and receive renewable thermal energy. Tubes of well are installed under sea or ocean bottom in deep water chutes or cracks of Earth's crust or cavities on sea bottom or land. Well tubes can be arranged on sea bottom or land in parallel rows or in form of rectangular rings or spirals, shuttle, stars or radially. Tubes are connected in pairs at angle. Tubes connected to each other form together with pumps, turbine, condenser and deaerator, a closed system. Pump, turbine, generator, vacuum pump are installed on platform under bell housing. Platform is rigidly and hermetically connected with belt housing. Outer surfaces of turbine and condenser are provided with thermal elements of thermoelectric generator. Condenser is combined with platform, being made in form of vertical and horizontal communicating tubes connected with vacuum pump and vacuum regulator. Deaerator is provided with liquid level regulator.

EFFECT: reduced cost and consumption of materials at production of cheap renewable fuel, conversion of heat into electric energy.

8 dwg

Description

The invention relates to the electrical industry.

Known thermal power plant containing a steam generator, condenser, fan. Made with the possibility of converting fuel into the heat of the working fluid using a pore boiler, then converting the heat of the working fluid into mechanical energy using a pore turbine, then converting mechanical energy into electrical energy using an electric generator / cm. Great Soviet Encyclopedia. 2 ed., 42, p. 250-253 /.

A disadvantage of the known thermal power plant is the high cost of fuel. High costs of cash and materials for the extraction and delivery of fuel to places of consumption. During the operation of a thermal power plant, harmful toxic gases that pollute the atmosphere are released into the atmosphere.

The aim of the invention is to reduce the cost of money and materials in obtaining cheap renewable fuel and converting it into electrical energy.

The goal is achieved in that every two pipes of the well are located in a vertical plane next to each other and parallel to each other at an appropriate depth below the bottom of the sea, ocean or located in different places, connected to each other at the proper depth at an angle of inclination under the bottom of the sea or ocean in deep-sea trenches or fissures of the earth’s crust or depressions on the sea, ocean or land, they are capable of supplying cold water through the end of the borehole pipe and receiving steam from another using internal thermal energy uu earth parateplovogo convert the working fluid to mechanical energy by a turbine, converting mechanical energy into electrical energy using a generator. An electric pump, a turbine, a generator, a vacuum pump are installed on the platform under the bell. The platform is rigidly and hermetically connected to the bell, made with the possibility of protecting machines from high water pressure and creating normal conditions for the operation of the machines. The outer surfaces of the turbine and condenser are equipped with thermocouples of the thermionic generator. Made with the possibility of direct conversion of heat from the surface of the turbine and condenser into electrical energy. The capacitor is made in the form of vertical supporting communicating pipes, interconnected by horizontal pipes at a suitable equal interval and with a vacuum pump and a vacuum regulator. They are made with the possibility of cooling water vapor - obtaining condensate, moving it by gravity from the condenser to the deaerator, creating and maintaining the proper reduced pressure in the pipe cavity, removing oxygen and other gases from the deaerator, and using the condensate in a closed cycle. In the tank of the deaerator there is a float chamber equipped with a float, on which plates of a permanent magnet are located in the upper and lower bases. In the chamber at different levels are reed switches connected to an electric pump using an electric circuit. Well pipes may be located on the bottom of the sea or on the surface of the land in the form of parallel rows or a rectangular ring, or spiral, or shuttle, or stars, or in radial form located at different places interconnected at an appropriate angle at an appropriate depth below the bottom of the sea or on the land surface of well pipes connected in series with each other through pumps, turbines, and a condenser. deaerator in a closed system. They are configured to concentrate all thermal energy for conversion into mechanical energy by one turbine and converting mechanical energy into electrical energy by one generator and sequential supply of cold condensate to several well pipes from the deaerator using one electric pump.

The novelty of the claimed technical solution is due to the fact that due to the installation of wells on the bottom of the sea, ocean in deep trenches and cracks in the earth's crust or hollows in the sea or ocean, located in a vertical or inclined plane by pairs interconnected at the proper depth or located in different places interconnected at an appropriate angle of inclination, cold water is supplied into the well, the heat of the working fluid is obtained at the steam outlet using the Earth’s internal energy, and steam is converted into fur thermal energy using a turbine, the conversion of mechanical energy into electrical energy using a generator, and the supply of electrical energy to land to consumers via cable.

Due to the wells located in different places, connected by honey in pairs at the proper depth at an angle of inclination, the serial connection of these wells together through a pump, turbine, condenser, deaerator installed on the bottom of the sea or land, provides the concentration of all thermal energy to convert it into mechanical energy by one turbine and the conversion of mechanical energy into electrical energy by one generator and the condensate supply in a closed cycle using one pump simultaneously into several pipes important.

By using thermoelectronic generator thermocouples on the surface of the turbine and the condenser tubes, direct conversion of the heat of the working fluid into electrical energy is ensured, and the productivity of the thermal power plant is increased.

Due to the condenser, made in the form of vertical supporting communicating pipes connected to horizontal pipes at an appropriate interval, a vacuum pump, a vacuum regulator, water vapor is cooled in the pipe cavity, the condensate is received and moved by gravity to the deaerator, and proper pressure is created in the pipe cavity condenser and deaerator, the removal of oxygen and other gases and the use of condensate in a closed cycle.

By combining the capacitor with the structural elements of the support pipes of the platform, money and steel are saved.

Due to the heat radiated from the surface of the turbines and the condenser, favorable artificial conditions are created in the water area of the sea or ocean, which positively affect the flora and fauna of the sea and ocean.

Through the use of different options for the location of borehole pipes / annular, shuttle, spiral, star-shaped, radial and parallel / expanding the technological possibilities of using pipe wells for thermal power plants.

Due to the use of a bell lowered to the bottom of the sea, under the cap of which a turbine, generator, pump are located, reliable protection is provided from the influence of high pressure and the creation of normal conditions for their operation.

Due to the location of the float chamber in the tank of the deaerator, equipped with a float in its lower and upper base, permanent magnet plates are located that interact with the reed switches, automatic control of the supply of the missing volume of condensate to the deaerator is provided.

Due to the location of pipe wells near cities, villages, industrial enterprises, all consumers are provided with electric energy and thermal energy for heating residential buildings, industrial premises and industrial enterprises.

In a patent study of the claimed technical solution for patent, scientific, scientific and technical materials, such a combination of features was not found that allows us to judge the novelty of the essential features.

The invention is illustrated by drawings, where:

figure 1 shows a thermal power plant, a cross section;

figure 2 shows the location of the turbine, generator, pump, vacuum pump under the bell cap / top view, side view /;

figure 3 shows a diagram of the use of options for wells, cross section;

figure 4, 5, 6 is the same, top view;

in Fig.7 shows the device of a thermal power plant on the land surface / cross section /;

Fig. 8 shows a connection diagram of vertical wells for closed loop operation / top view /.

A thermal power plant (Fig. 3/) consists of vertically arranged pipes installed in pairs next to each other, parallel to each other or located well pipes in different places, connected to each other at an appropriate depth at an angle of inclination under the bottom of the sea or ocean, in deep-sea trenches or cracks in the earth's crust or hollows on the sea or land. Made with the possibility of supplying cold water to one end of the pipe 1 of the well using an electric pump 3 for receiving steam at the other end of the pipe 2 of the well. In this case, cold water under the influence of the internal thermal energy of the Earth is converted into steam. The pipe 2 is connected to a steam turbine 4. The turbine 4 is connected to an electric generator 5 by means of a shaft 6. Made with the possibility of converting a thermal working fluid - steam into mechanical energy by means of a turbine 4. Converting mechanical energy into electric energy by means of a generator 5. Electric pump 3, turbine 4, generator 5 is installed on a metal platform 7. The platform 7 is rigidly and hermetically connected to the bell 8. The bell 8 is connected to the floating vessel 9 using a flexible hose 10 of the cable 11, flexible rod 12. The vessel 9 could to be used for drilling at great depths, as well as in the operation of thermal power plants at great depths. Vessel 9 is held in place by anchors. Bell 8 is made with the possibility of reliable protection of machines from high water pressures and the creation of normal working conditions of machines. On the vessel 9 there is a tube 13 connected to a flexible hose 10. The electric generator 5 is connected to consumers 14 of electric energy via cable 15. The turbine 4 is connected to a steam condenser 16. The capacitor 16 is made in the form of a pipe of the appropriate length and diameter, located at the bottom of the sea, ocean, deformed in the form of a ring. The condenser 16 is connected to the vacuum pump 17 and the vacuum regulator 18 located under the bell bell 8. Condensed by cooling the water vapor and moving it with the pump 3 into the pipe 1, wells. The vacuum regulator 18 / Fig. 1/ is made of a conical chamber 19, inside which a cone 20 is mounted, connected to the suspension 21 through an opening. On the bell 8 are pipes 22 with couplings 23.

The device can be performed in the second embodiment. The second option is the same as the first option, differs from it in that the pipes 1 and 2 are located in different places, interconnected at the proper depth at an angle below the bottom of the sea or ocean. The pipes 1 of the well are connected to the electric pump 3 with the turbine 4. The pipe 2 is connected through the walls of the bell 8 to the turbine 4. The turbine 4 converts the steam into mechanical energy. Mechanical energy is converted into electrical energy using a shaft 6 connecting the turbine 4 to the generator 5. Waste steam from the turbine 4 is supplied to the well 1 using an electric pump 3. Steam from the pipe 2 of the second well is supplied through the walls of the bell 8 to the turbine 4. Turbine 4 converts steam to mechanical energy. Mechanical energy is converted using the second generator 5 into electrical energy. The spent steam is again fed into the well 1 using the pump 3. Further, all operations are repeated. Through the walls of the last bell 8 from the turbine 4, the spent steam is supplied to the condenser 16 into the pipe 25, where it is cooled and converted into condensate. The condensate is moved by gravity from the condenser 16 to the deaerator 24. From the deaerator 24 it is supplied to the pipe 1 of the well by means of the pump 3. The pipes 1 and 2 can be arranged (Fig. 4/) in the form of a rectangular ring or spiral, or in the form of a shuttle and connected in a closed contour. Moreover, each pair of tubular wells 1, 2 has its own turbine 4, pump 3, generator 5, located under the bell 8, and a common steam condenser 16. The steam condenser 16 is made in the form of vertical platform supports containing vertical pipes 25 interconnected by horizontal communicating pipes 26 at an appropriate interval and with the vacuum pump 17, the vacuum regulator 18. The platform and the capacitor are combined. Made with the possibility of cooling the water vapor, obtaining condensate and moving it by gravity from the condenser 16 to the tank 24 of the deaerator, create the proper low pressure and remove oxygen and other gases and use the condensate in a closed cycle. The pipes 25 and 26 are equipped with thermocouples of the thermionic generator 27, are configured to directly convert thermal energy from the surface of the turbines and pipes 25 and 26 of the condenser 16 into electrical energy to increase productivity and increase the efficiency of use of thermal energy into electrical energy. The platform is movable and equipped with running wheels 28.

The device / Fig. 5/ can be performed in the third embodiment. The third option is the same as the second option, differs from it in that the pipes of 1 and 2 wells are located in different places, connected in pairs at an appropriate depth below the bottom of the sea, ocean. The ends of the pipes 1 and 2 of the wells are located at the bottom of the sea in parallel rows. The ends of the pipes 1 are connected to each other and the tank 24 of the deaerator by means of a water pipe and an electric pump 3. The ends of the pipes 2 of the wells are connected to each other and the steam turbine 4 by means of a steam pipe, configured to supply cold condensate from the tank 24 of the deaerator to the ends of the pipes 1 of the wells when using an electric pump 3 and moving all the steam from the pipes 2 of the well to the turbine 4, moving the spent steam to the pipes 25 of the condenser 16, cooling the steam and turning it into condensate. The movement of condensate from the pipes 25, 26 into the capacity of the deaerator 24 by gravity. Using a vacuum pump 17, oxygen and other gases are removed from the pipes 25, 26 of the condenser 16 and the deaerator 24, the condensate is accumulated and transferred by the pump 3 to all wells 1 of one or two circuits. The turbine 4 is connected to the generator 5 by means of a shaft 6. The heat energy of all wells is converted into mechanical energy by means of a turbine 4. Mechanical energy is converted into electrical energy by means of a generator 5. In the thermal power station there is a desalination plant 29 containing a reserve well, consisting of pipes 1 and 2. The pipe 2 is connected directly to the pipes 25 and 26 of the condenser 16. Made with the possibility of obtaining fresh distilled water from the salt water of the sea to replenish the missing volume of condensate in deaerator 24 and other purposes. In the capacity of the deaerator 24 is located a float chamber 30, equipped with a float 31, on which in the upper and lower base plates 32 / Fig. 1/ of a permanent magnet are located. In the chamber 30, at different levels, reed switches 33 and 34 are located, connected by an electric circuit to the electric pump 35 of the desalination plant 29. The reed switch 33 works to open, and the reed switch 34 works to close the electric circuit supplying the electric pump 35.

The device can be made in the fourth embodiment / 5/5. The fourth option is the same as the third option, differs from it in that the pipes 1 and 2 are located radially around the bell 8 of the condenser 16 the ends of the pipes 2 of the wells located in the inner circle line, the ends of the pipes 1 of the wells are located in the outer circle line. The deaerator 24 and the pump 3, mounted under the bell, are located outside the circumference of the wells of the pipe 1. Made with the possibility of sequential supply of cold condensate from the tank of the deaerator 24 to the pipe 1 of the wells using a water pipe located around the circumference, and an electric pump 3 and receive steam from the pipes 2 wells and moving it along a steam line located along the inner circle line.

The device can be performed in the fifth embodiment / 6 /. The fifth option is the same as the fourth option, differs from it in that the pipes 1 and 2 are arranged in the form of four, five, six and multi-pointed stars. The ends of the pipes of the wells 1 are located at the ends of the stars, and the ends of the pipes 2 of the wells are located on the inner side of the stars. The pipes 1 are connected to the deaerator 24 using the inner annular 36 and radial water pipes 37, and the ends of the pipes 2 of the wells are connected to the annular external steam pipe 38 and the radial steam pipes 37. They are capable of moving cold water / condensate / from the deaerator 24 to the pipe 1 of the wells with using an electric pump 3 and receiving steam from the pipes 2 of the wells and moving it to the turbine 4.

The device can be made in the sixth embodiment / 5/5. The sixth option is the same as the fourth option, differs from it in that the pipes 1, 2 of the wells are arranged in a vertical plane in pairs parallel to each other, connected at an appropriate depth below the bottom of the sea, ocean or below the surface of the Earth. In the horizontal plane, the ends of the pipes 1, 2 are mounted in the form of a circle in several lines, rows, for example in two, coaxial to each other. Coaxial to their location is a water pipe 40 and a steam pipe made in the shape of a circle. The deaerator 24 is connected to the pipes 1 of the wells using a pump 3 of the water supply 40 and radial pipes 41. The pipes of 2 wells are connected to the pipes 4 by means of a steam pipe 42, made in the form of a circle and a radial steam pipe 43. Made with the possibility of supplying cold water / condensate / from the tank deaerator 24 into the well of pipes 1 using an electric pump 3 and receiving steam in the pipes 2 of the wells and moving it to a steam turbine 4. Converting steam into mechanical energy using turbines 4. Converting mechanical energy to electrical energy ergy with a generator 5.

The device can be made in the seventh embodiment / 7 /. The seventh option is the same as options 1-6, differs from them in that the ends of pipe 1, 2 are located on the land surface on continents or islands, are located near cities, villages, industrial enterprises. The steam condenser is made of radiator batteries 44, which are located in residential buildings, industrial premises, industrial plants, greenhouses. The turbine 4 is connected to the capacity of the deaerator 24, the vacuum pump 17, the vacuum regulator 18 through the steam pipe 45, radiator batteries 44 and the water pipe 46. They are configured to supply cold condensate from the tank of the deaerator 24 to the well 1 using an electric pump 3, to produce steam from pipes 2 of the well and moving it to the turbine 4. The conversion of thermal energy / steam / into mechanical energy using the turbine 4, the conversion of mechanical energy to electrical energy using the generator 5. The supply of exhaust steam through the steam pipe 45, adiatornye batteries 44, 46 in the water tank 24 deaerator. The vacuum pump 17 creates a reduced pressure in the capacity of the deaerator 24. The vacuum moves through the water pipe 46, the steam pipe 45, accelerates the movement of steam through the steam pipe. Water vapor in vacuum, in contact with the inner surface of the batteries 44 and steam pipe 45, are converted into condensate water.

Condensate flows by gravity into the capacity of the deaerator 24. Oxygen bubbles and other gases are removed from the capacity of the deaerator 24, while the oxidation of the equipment is prevented. The vacuum regulator 18 automatically maintains the proper low pressure parameters.

The device can be made in version 8. The eighth option is the same as the sixth option, differs from it in that the pipes 1, 2 of the well in a vertical plane are arranged in pairs adjacent and parallel to each other, connected to each other at the proper depth. On the soil surface, the ends of pipes 1, 2 of the wells in the horizontal plane are arranged in rows in a straight line. The ends of the pipes 1 are connected to the capacity of the deaerator 24 by means of a pump 3 and a water pipe 47. The pipe 2 is connected to the capacity of the deaerator 24 through a steam turbine and steam pipe 48, radiator batteries 49 water pipe 50 and an electric pump 3.

The device operates as follows. Using drilling rigs, wells are drilled and pipes 1 and 2 are installed in a vertical plane, installed side by side parallel to each other or placed in different places, connected to each other at the proper depth under the bottom of the sea or ocean in deep trenches or cracks in the earth’s crust or in hollows at sea or on land at specified locations. After the manufacture of the wells, installation is made and the pipes 1, 2 of the wells are connected to the nozzles located on the bell 8 using robots controlled from a vessel or platform. The bell is located near the pipes of 2 wells for ease of installation and dismantling of equipment. The electric circuit supplying the electric pump 3 is closed, the vacuum pump 17 by means of the electric pump 3, the condensate moves cold water into the pipe 1 of the well. From the high temperature of the Earth’s internal energy, the water in well 1 and 2 heats up to a high temperature, turns into steam. Steam from the pipe 2 of the well moves through the walls of the bell into the turbine 4, steam - the thermal body is converted into mechanical energy by means of the turbine 4.

Mechanical energy is converted into electrical energy by means of a generator 5. Electric energy from the generator is transferred via cable 15 to consumers 14 located on land and sea. Air is supplied from the vessel to the bell 8. Bell 8 protects the machine: pump 3, turbine 4, generator 5 from high water pressure at the bottom of the sea and creates normal conditions for the operation of the machines. The spent steam is transferred from the turbine 4 to the condenser pipe 16. From the action of cold sea water, the water vapor is cooled and converted into condensate, it is transferred to the well pipe using pump 3. If one of the machines breaks down in the bell, the robots are lowered from the ship to the bottom of the sea, using the control panel they control the work of the robots, unscrew the couplings, separate the nozzles connected to the bell 8 and the pipes 1 and 2 of the wells. Using lifting means, the bell is hoisted onto the vessel or platform, the bell is separated from the platform 7, the worn parts or machine parts are dismantled, repaired or replaced, and the site 7 is tightly and sealed to the bell 8. Then the bell 8 is moved to its original position on bottom of the sea. Using robots / not shown / we connect pipes using couplings and again close the electric circuit supplying electric pump 3, vacuum pump 17. Then all operations are repeated. As soon as the reduced pressure of the proper parameter reaches the excess of permissible parameters, the cone 20 moves from bottom to top, moving up the suspension 21, the hole in the valve opens, air moves into the pipe. The pressure in the pipe is normalized. The cone 20 with the suspension 21 moves from top to bottom in its original position. The valve closes. Further, all operations are repeated.

The device can work in the second embodiment. The second option is the same as the first option, it differs from it in that we close the electric circuit supplying all the electric pumps 3, the vacuum pump 17 located under the bell cap 8. In this case, the electric pumps 3 from the tank 24 of the deaerator pump cold water into the wells 1 under the influence of high temperature of thermal energy in the lower layers of the Earth, the water in wells 1 and 2 is heated and turns into steam. The steam is transferred from the well 2 to the steam turbine 4 located under the bell 8. The steam is converted into mechanical energy by means of a turbine 4. Mechanical energy is converted into electrical energy by means of a shaft 6 and an electric generator 5. Electric energy is transferred via wires to consumers 14 via cable 15 The spent steam is moved by an electric pump 3 into the well 1. Under the action of high thermal energy in the lower layers of the Earth, the steam in the wells 1, 2 heats up even more and moves from the well 2 through c a tenk of bell 8 into a steam turbine 4. The steam is again converted into mechanical energy by means of a steam turbine 4. Mechanical energy is converted into electrical energy by means of an electric generator 5. Electric energy is transmitted to consumers 14 via cable 15. Waste steam is again transferred using an electric pump 3 to the pipe 1 of the well 1. Next, all operations are repeated until one of the pumps 3 moves the spent steam from the turbine 4 to the condenser 16 into the pipe 25. Steam through the communicating pipes 25 and 26 p spredelyaetsya in cavities of pipes. Under the influence of cold sea water, the steam cools, turns into condensate and flows by gravity from the cavity of the pipes 25 and 26 of the condenser 16 into the tank 24 of the deaerator. The vacuum pump 17 creates a vacuum, low pressure in the pipes 25 and 26, while oxygen and other gases are removed from the deaerator 24 and pipes 25 and 26, this prevents oxidation of the equipment - corrosion, accelerates the process of cooling and converting steam into water - condensate and its use in a closed loop. The outer surface of the turbine 4 and the condenser 16 of the pipes 25 and 26 is provided with thermocouples of the thermionic generator 27. In this case, the thermocouples of the thermionic generator 27 convert the thermal energy from the surface of the turbines 4 and pipes 25 and 26 directly into electrical energy. This improves productivity. In the water area of the sea, ocean, where thermal power plants are located, heat loss occurs, water heats up and favorable conditions for the flora and fauna of the sea are created. The capacitor 16 is combined with the structural elements of the mobile platform, this saves money and materials. Due to the running wheels 28, it is possible to move the platform along the bottom of the sea and install it in an appropriate section of the sea, ocean.

The device can work in the third embodiment. The third option is the same as the second option, differs from it in that the ends of the pipes 1, 2 of the wells are located in different places, interconnected at the proper depth under the bottom of the sea, ocean. The ends of the pipes 1 and 2 of the wells are located on the bottom of the sea, ocean in parallel rows. The ends of the pipes 1 are connected to each other and to the capacity 24 of the deaerator by means of a water pipe and an electric pump 3. The ends of the pipes 2 are connected to each other and a steam turbine 4 by means of a steam pipe. We close the electric circuit supplying the electric pump 3, the condensate moves from the tank 24 of the deaerator to the pipe 1 of several wells simultaneously. In the lower layers of the earth's crust, water heats up and turns into steam, steam from the pipes 2 of the wells moves through the walls of the bell 8 to the steam turbine 4. Steam - the thermal working fluid with the help of the turbine 4 is converted into mechanical energy. Mechanical energy using the shaft 6 and the generator 5 is converted into electrical energy. Electrical energy via cable 15 is transmitted to consumers 14 on land of an island or continent. The exhaust steam from the turbine 4 from under the bell 8 is transferred to the pipe 25 of the condenser 16. The steam in the pipes 25 and 26 is cooled by cold sea water and turns into condensate. The condensate moves from the pipes 25 and 26 of the condenser 16 into the tank 24 of the deaerator by gravity. Using a vacuum pump 17 from the pipes 25 and 26 of the condenser 16 from the tank 24 of the deaerator is removed oxygen and other gases. In pipes 25 and 26, a reduced pressure of the proper parameter is created and maintained by means of a vacuum regulator 18. Condensate accumulates and moves by pump 3 into all wells of pipes 1 of one or two circuits. The desalination plant 29 replenishes the missing volume of condensate 24 in the tank of the deaerator 24. When the condensate level in the tank 24 of the deaerator 24 decreases, the float 31 moves from top to bottom in the float chamber 30. As soon as the float 31 moves to the level of the reed switch 34, the reed switch 34 interacts with the permanent magnet 32 of the plate, the reed switch 34 closes the electric circuit supplying the electric pump 35. The electric pump 35 moves water into the pipe 1 of the well, steam comes out, steam moves from the pipes 2 into the pipe 25 of the condenser 16. The steam is distributed in pipes 25 and 26, in vacuum, with the help of cold sea water, the steam is cooled and converted into condensate. Condensate flows by gravity from the pipes 25 and 26 into the tank 24 of the deaerator. As soon as the condensate level rises to the level of the reed switch 33, the float 31 pops up and the permanent magnet plate 32 interacts with the reed switch 33. The reed switch 33 opens the electrical circuit supplying the electric pump 35. The operation of the pump 35 is stopped.

The device can work in the fourth embodiment / 5/5. The fourth option is the same as the third option, differs from it in that the supply of cold condensate from the tank 24 of the deaerator into the pipes 1 of the wells is carried out using an electric pump 3 through a water supply system located around the circumference of the lines of the wells, steam flows from the pipes of the 2 wells through the bell walls 8 into a turbine 4. Steam - a thermal working fluid with the help of a turbine is converted into mechanical energy. Mechanical energy using the shaft 6 and the generator 5 is converted into electrical energy. Electrical energy via cable 15 is transmitted to consumers 14 on land of an island or continent. The exhaust steam from the turbine 4 of the bell 8 is transferred to the pipe 25 and 26 of the condenser 16. The steam in the pipes 25 and 26 is cooled by cold sea water and converted into condensate and moves from the pipes 25 and 26 of the condenser 16 to the tank 24 of the deaerator by gravity. Using a vacuum pump 17 and a vacuum regulator 18 from the pipes 25 and 26 and the tank 24 of the deaerator, oxygen and other gases are removed and optimal low pressure parameters are maintained.

The device can operate in the fifth embodiment / 6 /. The fifth option is the same as the fourth option, differs from it in that the ends of the pipes 1 and 2 are arranged in the form of four, five, six and multi-pointed stars. The ends of the pipes 1 of the wells are located at the ends of the stars, and the ends of the pipes of 2 wells are located on the inner concave side of the stars. When the electrical circuit supplying the electric pump 3 is closed, the pump 3 moves the cold condensate from the deaerator 24 to the pipe 1 of the wells using the inner ring 36 and radial 37 water pipes. Using the internal thermal energy of the Earth, water is heated to a high temperature and turns into steam. The steam from the pipes 2 of several wells along the annular steam pipe 38 moves through the wall of the bell 8 into the steam turbine 4. Steam - the thermal working fluid with the help of the turbine 4 is converted into mechanical energy. Mechanical energy is transmitted to the generator 5 via a shaft, where it is converted into electrical energy. Electric energy is transported through the cable to consumers 14. Waste steam from the turbine 4 from under the bell 8 is transferred to the pipe 25 of the condenser 16, where it is cooled by cold sea water and converted into condensate. The condensate moves from the pipes 25 and 26 into the tank 24 of the deaerator by gravity. Further, all operations are repeated.

The device can work in the sixth embodiment. The sixth option (Fig. 5/) is the same as the fourth option, differs from it in that the pipes 1 and 2 are arranged in a vertical plane in pairs, parallel to each other and interconnected at an appropriate depth below the bottom of the sea, ocean and below the surface of the earth islands and continents. In the horizontal plane, the ends of the pipes 1 and 2 are installed in the form of a circle, an oval or a polygon in several lines of rows, are located coaxially to each other, coaxially to their location there is a water supply 40 located in the form of a circle, oval, triangle. The capacity 24 of the deaerator 24 is connected to the ends of the pipes 1 of the wells using a pump 3 of the water supply 40 of the radial pipes 41. The pipes of 2 wells are connected to the pipes 4 by means of a steam pipe 42, made in the form of a circle or oval or polygon and radial steam pipes 43. When the electrical circuit is closed, the electric pump 3 from the tank 24 of the deaerator with the help of an electric pump 3, cold condensate moves into the pipe 1 of the well through an annular water supply 40, radial water supply 41. Under the influence of the Earth’s internal energy, the water heats up to juice temperature and turns into steam. The steam from the pipes 2 of several wells moves through an annular steam line through the wall of the bell 8 to the steam turbine 4. Steam - the thermal working fluid with the help of the turbine 4 is converted into mechanical energy. Mechanical energy using the shaft 6 is transmitted to the generator 5 and it is converted into electrical energy. The spent steam from the turbine 4 through the wall of the bell 8 is transferred to the pipe 25 of the condenser 16, where it is cooled by cold sea water and converted into condensate. The condensate moves from the pipes 25 and 26 into the tank 24 of the deaerator by gravity. Further, all operations are repeated.

The device operates in the seventh embodiment. The seventh option (Fig. 7/) is the same as options 1-6, differs from them in that the ends of pipes 1, 2 are located on the land of the continents of the islands near the towns and villages and industrial enterprises. The capacitor 16 is made of radiator batteries 44. We close the electric circuit supplying the electric pump 3. Pump 3 moves the condensate from the tank 24 of the deaerator to the pipe 1 of the well. Under the influence of the Earth’s internal energy, the water heats up and turns into steam. The steam from the pipes 2 of one or more wells with the help of the turbine 4 is converted into mechanical energy. Mechanical energy with the help of the shaft 6 is transferred to the generator 5, they it is converted into electrical energy. Electric power is transmitted by cable to 15 consumers in 14 cities, villages, towns and industrial enterprises. The spent steam is moved from the turbine 4 through the steam line 45 to the radiator batteries 44 to the apartments of residential buildings, industrial premises. The vacuum pump 17 creates a reduced pressure in the pipes 45, 46, radiator batteries 44 and in the capacity of the deaerator 24. The vacuum regulator 18 maintains reduced pressure in optimal parameters. Vacuum-steam heating occurs in residential buildings and industrial premises. Vapors in vacuum, in contact with the inner surface of the batteries 44, steam pipe 45, turn into condensate. Condensate flows by gravity into the tank 24 of the deaerator. Oxygen and other gases are removed from the deaerator vessel 24 and oxidation of pipes and equipment and metal corrosion are prevented. The device can work in the eighth version / Fig.8/. The eighth option is the same as the sixth option, differs from it in that the pipes 1, 2 of the wells in a vertical plane are arranged in pairs, mounted side by side and parallel to each other, connected to each other at the proper depth. On the soil surface, the ends of pipes 1, 2 of the wells in the horizontal plane are arranged in rows in a straight line. The ends of the pipes 1 are connected to the capacity of the deaerator 24 by means of a pump 3 and water supply 47. The pipe 2 is connected to the capacity of the deaerator 24 through a turbine 4, steam line 48, radiator batteries 49, water supply 50, electric pump 3. We close the electric circuit supplying the electric pump 3. Cold condensate from the tank 24 with the help of the pump 3 is transferred to the pipe 1 of several wells. In the lower layers of the Earth, under the influence of the Earth’s internal energy, the water heats up and turns into steam. The steam from the pipes 2 of several wells moves to a steam turbine 4. Steam - a thermal working fluid with the help of a turbine 4 is converted into mechanical energy. Mechanical energy with the help of the shaft 6 is transferred to the generator 5, they it is converted into electrical energy. Electric energy via cable 15 is transmitted to consumers in residential buildings, industrial premises. The spent steam from the turbine 4 is transferred to the radiator batteries 49 through the steam line 48. The battery 49 is heated by residential premises, workshops. In radiator batteries 49, pipes 48, 50 and in deaerator 24 there is a vacuum obtained by means of a vacuum pump 17. Proper low pressure is automatically maintained by means of a vacuum regulator 18. Vacuum-steam heating is carried out in the rooms. In batteries, the steam cools and turns into condensate. The condensate is transported by an electric pump 3 into the tank 24 of the deaerator.

Claims (1)

A thermal power plant containing a well connected by paired pipes, one end of which is located on the surface of the earth, and the other ends of the pipes are interconnected and located in the lower layers of the earth's crust, with a turbine connected to an electric generator by a shaft, a condenser and an electric pump installed with the possibility of supplying cold condensate through one end of the well pipe and receiving on the other a pair, characterized in that it comprises a platform hermetically connected to the bell, a vacuum pump, a vacuum the regulator and deaerator, the borehole pipes are installed under the bottom of the sea or ocean, in deep-sea trenches or cracks in the earth's crust or hollows on the sea or land, the pipes are located on the bottom of the sea or land in parallel rows or in the form of rectangular rings, or spirals, or shuttle, or stars , or radial arrangement, are paired together at an angle and make up a closed system with the pump, turbine, condenser, deaerator, and the electric pump, turbine, generator, vacuum pump are installed on the platform and are made with possible in order to protect machines from high water pressure, the outer surface of the turbine and condenser is equipped with thermoelements of a thermionic generator for direct conversion of heat from their surface into electrical energy, the condenser is combined with the platform and is made in the form of vertical interconnected pipes connected by a vacuum pump and a vacuum regulator, a deaerator equipped with a liquid level regulator and configured to automatically move the missing volume of condensate into the deaerator using a pump.

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