RU2013652C1 - Power plant - Google Patents

Abstract

FIELD: power generation. SUBSTANCE: power plant has vertical windmill with blades mounted on cylindrical float in tank filled with liquid and kinematically linked with working machine mounted on base. Rotor is assembly of coupled triangular frames whose apexes are relatively shifted circumferentially. Blades are installed in pairs on edge of each frame and hinged to them. Area of each pair of blades equals that of frame side. Float is provided with rolling members arranged on its vertical generating line and with counter-poise. Inner surface of tank is spherical and contacts rolling members. EFFECT: improved design. 11 cl, 8 dwg

Description

 The invention relates to energy and can be used to provide consumers with energy stored in water and air.

 A wind power installation is already known, comprising a wind turbine and a driving air compressor, the compressed air of which feeds the air motor. A pneumatic accumulator and an electric generator were used in the circuit (application of Great Britain N 2112463, class F 03 D 9/02, 1983). However, a piston air motor is used in this installation and therefore, heat is not taken from the liquid when an expanding gas volume emerges inside the bell float, which reduces the efficiency.

 A known solar installation using the greenhouse effect and representing a solar collector for heating water in a solar collector used for heat supply. The efficiency of such an installation is close to 100%. But the heat accumulated in water with the existing conversion methods is not used to generate energy.

Finally, a plant is known comprising a pneumatic hydraulic motor connected to a source of compressed air. Although the prototype used a float pneumatic hydraulic motor containing a floating cylindrical body with a bell-shaped float fixed in it using flexible couplings, capable of making vertical movements inside the body for the length of the ties and at the same time perform work, but the float’s travel is limited by flexible couplings and there is no calculation formula for the effective compressed volume air initially supplied under the float does not allow to determine the installation parameters and lead to a decrease in efficiency
In the proposed installation, it is essential that, in addition to the traditional conversion of various manifestations of energy, the most efficient extraction of solar energy accumulated in water and air is provided. Energy-extracting properties are due to the following facts.

 The properties of chemical elements are also used from compounds (a mixture of gases that make up air and a compound of hydrogen and oxygen that make up water), which determine both their initial and acquired unevenness, a necessary condition for creating a constantly operating machine.

 Archimedes law is considered as a consequence of the energy conservation law, when a buoyant force at equal temperatures of a liquid and a body is considered as a result of the difference in the energy expenditures for creating or phase transition from one state to another with a change in the density of the body at a constant liquid density and which determines the degree of buoyancy - positive when the buoyancy force is greater than the traction force, zero when the buoyancy force and the retraction force are equal and negative, when the buoyancy force is less than s s retraction. The formula of the Archimedes law is proposed in the following wording: "A force immersed in a liquid is affected by a force determined by the difference in the energy expenditures for creating a liquid and a body or in a transition to another aggregate state, accompanied by a change in densities (if the liquid is not water), as well as the amount of energy accumulated liquid and body within the temperature of formation or transition to another state of aggregation (melting, solidification, gas formation ".

 The buoyant force acting on the initial volume of gas or air with positive buoyancy supplied under a column of water or other liquid is greater than the force required to overcome the liquid pressure above the pressure port of the compressed gas source by the amount of force providing positive buoyancy.

 The buoyant force acting on a volume of gas with a positive buoyancy, supplied under a column of water at equal temperatures of water and gas, increases as it ascends and decreases pressure with increasing gas volume by the amount of the initial volume every 10 m of ascent (1 at).

The buoyant force increases practically unchanged when the density of water at the temperature range from 0 ^to 100 ° C, while the gas increases its volume in 1/273 the original volume for each degree increase in temperature, ie. E. Density changes depending on the amount of consumed energy intensive water , violating the equilibrium of the energy potentials of water and air and is observed when there is a temperature difference between the liquid and gas.

The buoyant force increases, ie. K. Air supply practically occurs in isolated water system with low its thermal conductivity (an adiabatic process), when the pressure drop at 1 atm air is lowering the temperature about 24 ^o C, t. E. Air almost always supplied under water with a temperature below the water temperature, which allows you to effectively extract energy at equal temperatures of water and air and close to 0 ^o C.

1+

.Useful work is done by the average effective volume of air, which when interacting with water is determined from the ratio
V _g = V _n (1 + 0.5P)

1+

.

1+

) - приобретенную, где V_д - действующий объем газа, V_п - объем сжатого газа при абсолютном давлении, Р - коэффициент давления, зависящий от высоты столба воды, t - температура воды, t₁ - температура воздуха.In this case, the coefficient (1 + 0.5 P) reflects the initial nonequilibrium, and (

1+

) - acquired, where V _d is the effective volume of gas, V _p is the volume of compressed gas at absolute pressure, P is the pressure coefficient depending on the height of the water column, t is the water temperature, t ₁ is the air temperature.

 All of the above is confirmed by the following conclusions and experiments.

 Let's pay attention to the location of chemical elements in the periodic system. It is impossible not to notice that they are all located as their atomic weights increase, i.e., according to nonequilibrium. It is impossible to deny that a different amount of energy was spent on their creation by nature and this difference determined the properties of elements such as density, heat capacity and thermal conductivity. This series contains hydrogen, iron and mercury. Both hydrogen and iron will float in the mercury, but the amount of work done in doing so will be greater for hydrogen than for iron. But they do not stand nearby in the system and have different densities, heat capacities and thermal conductivities. This is an example of when work is done at the expense of the original disequilibrium.

 But when the volume of air brought under a water column increases not only due to an increase in pressure above it during ascent, but also due to a positive temperature difference between water and air, then in this case the work is done due to both the initial nonequilibrium and the acquired one.

It is known that the arrangement of 1 g of ice, taken at ^0, 80 must be expended calories. At 1 T the melted ice, taken at ^0, 93 kWh is required, the water will be at a temperature close to 0 ° ^C (point phase transition from solid to liquid and vice versa). This means that in 1 t of water at a temperature close to ⁰ ° C, accumulated at least 93 kW / h energy.

What is water? This is one of the states of water as a substance (liquid), but water is also a melt of ice, and ice floats in it. But in its melt both lead and iron float, the solid state of the substance floats in its melt. In both cases, energy was expended on the preparation of the melt, creating a difference in the energies of the liquid and solid state of the substance. If we spend artificially obtained energy on preparing a lead melt, then nature prepared the melt of ice (water) and ice itself, which maintains the necessary energy regime in which water is in a liquid state and the amount of energy is accumulated in 1 m ^{3 of} water at a temperature close to to 0 ° ^C is comparable to the amount of energy released during the combustion of 1 ^m3 wood.

1+

t

, где t - разность температур воды и воздуха;
V_о - первичный объем воздуха.Tie a load to the neck of the bottle so that the bottle floats in water and occupies a vertical position. Let’s let out part of the air by replacing it with water and we will achieve a situation when the bottle just starts to sink and plug the bottle under the water with a stopper, turning it into a sealed float. Changing the water to hot, lower the bottle into the water. Cold water temperature ^{20 °} C, hot - 45 ^C. The bottle as well as in the first case where the water is cold sink. At the same time, the air volume, mass, density remained unchanged, but the internal energy of the air changed. We take out the cork under the water, turning the bottle into a bell float, the bottle will pop up and protrude about 10 mm above the water. Before lowering the bottle into the water with a rubber ring, we note the water level in the bottle. We plug the cork under hot water and remove the bottle from the water. The expanding volume of air displaced water from the bottle. Knowing the initial volume of air in the bottle, the obtained volume and temperature of cold and hot water, when calculating, we get that the increase in the primary air volume was 1/273 for every degree of increase in air temperature, and this is the formula of the Gay-Lussac law, which is as follows:
V = v

1+

t

where t is the temperature difference between water and air;
V _about - the primary volume of air.

When we adjusted the bottle at the beginning of the moment of immersion, creating the conditions for occupying the bottle with an indifferent position, we thus leveled two forces - the force of attraction and the force of extrusion, i.e., brought these conditions closer to the conditions of weightlessness. Adjusted so that the bottle or container with an open bottom part omit the morning in cold water natural reservoir (water for night time to cool down, and the temperature drops, for example, in the steppes of Kazakhstan, 25-30 ^{° C,} which we can increase by connecting a solar collector, heating water in the daytime and cooling in the night). The bottle or container will sink. As the reservoir warms up by the sun, and the solar radiation power is on average 1 kW / m ² , the air in the bottle or container along with the reservoir’s water will start to warm up and will begin to increase in volume due to the difference in the heat capacities of water and air and the associated volume expansion coefficient more than water, pushing it out of the bottle. The bottle or container will pop up and depending on the size of the bottle or container, the temperature difference will do the job. In the evening, the water will begin to cool, and by morning the bottle or container will not just sink, but will be drawn into the water. In this case, if the temperature difference is equal, then an equal amount of energy will be produced, as with the expulsion. As the reservoir begins to warm up, the ascent will begin, and the cycle will repeat. We will get a fairly effective permanent solar installation such as a working perpetual motion machine of the second kind, in which the energy difference of two initially nonequilibrium media helps to extract solar energy, which created the acquired nonequilibrium of interacting substances and media.

 When we adjusted the bottle in cold water at the beginning of the moment of immersion, replacing part of the air with water, we thus removed part of the buoyancy force that provides ascent (positive buoyancy), and at the same time equalized the amount of substance displaced by the bottle of water and the bottle itself with the cargo attached to it and its contents (water, air), i.e., the weight of a bottle of water, cargo and air in it is equal to the weight of the displaced water, i.e., the buoyancy force is zero (zero buoyancy), the energy potential difference of the external water and the system is g bonds, glass bottles, air and water in the bottle is also zero. But in order to achieve this situation, we removed not part of the force of attraction, but part of the buoyancy force, which means that if the force of gravity existed in this case, then for a body with positive buoyancy it would still be less than the buoyancy force, i.e. e. it is not in this case, and it cannot occur while the bottle adjusted for zero buoyancy is in water, and the energy potential difference is zero, because the buoyancy force acting on the unchanged body volume does not depend on the depth of immersion , especially, when a gas with its positive buoyancy is used instead of a solid, the ability to increase in volume as it ascends and changes in temperature.

 Two oppositely directed and equal forces act on a body under conditions of zero buoyancy - the pushing force directed upward and the pulling force directed downward. The pushing force increases with an increase in the positive difference in the energy potentials of water and air with the complete absence of the attractive force, and the force of retraction with its negative difference. We trace the conclusions made on the formulas.

On the Earth's surface, the attractive force is F = mq, where m is the mass of the body, q is the gravitational acceleration equal to 9.81 m / s ² .

On the Earth's surface, the buoyancy force is F = V˙ D˙q, where V is the volume of the body, D is the density of the liquid (in this case, water), q is the gravitational acceleration equal to 9.81 m / s ² . But VD is equal to m. Thus, a buoyant force equal to the force of attraction acts at any volume of liquid in the column of this liquid at any depth, and this is the same indifferent position of the body in the liquid, as in the case of a bottle, and this is the case if we pumped under a column water and when returning the displaced water through a turbine having an efficiency of = 1, we received an amount of energy equal to the spent, but we do not pump water under the water, but air with positive buoyancy.

 Let us consider in more detail the corollary arising from the law of Archimedes. A floating body is immersed in some part of it in a liquid: the immersed part displaces as much liquid by weight as the whole body weighs. We can say that a buoyant force equal to the weight of the liquid displaced by the immersed part acts on the floating body, and we make a mistake. After all, the air above the surface of the water, which also has positive buoyancy, can be mistaken for a floating body. However, with a constant amount of air dissolved in water (drawn in), there is no immersion of air in water, but it is pushed out of it without a trace, that is, with greater force, although the column of air above this body can exceed the weight of the body. But if you immerse a floating body and a column of air above this body at some depth, then much more energy is closed to immersion of the air column than to immersion of the body. In both cases, the buoyancy force (positive) would have to be overcome, i.e., when the buoyancy force is greater than zero. And we were convinced that the buoyancy force at the ascent stage at equal temperatures of water and air is greater than the attractive force. Nonequilibrium is a necessary condition for creating a periodically operating machine, which does not contradict the second law of thermodynamics and the law of conservation of energy. But if a solid body cannot be brought under a column of liquid without overcoming force (we are forced to immerse the body from the surface of the reservoir), then air can be supplied without energy consumption to overcome buoyancy. This is another proof of why less energy is required to supply an air volume under a column of water than to overcome water pressure above the pressure port of a compressed air source, which is clearly seen in FIG. 8. Since the initial supplied air volume has positive buoyancy, it is clear that when we ascend we get a gain in energy due to the heat selected from the water and the difference in the energy expenditures for creating a fluid and a body.

·

= P, где V_о - объем воздуха первичного заполнения на глубине Н при одинаковых температурах воды и воздуха;
Н - высота столба воды,
Р - коэффициент давления, зависящий от высоты столба воды (Нм/10 м = Р) на уровне нижнего поплавка-колокола или кольцевого распределителя сжатого воздуха.Take a funnel, turn it upside down and lower it into the water so that the lower expanded part does not reach the bottom, and the upper one is at the water level or slightly higher. We’ll bring air under the funnel with a tube. We will make sure that the water displaced from the funnel does not simply overflow from the nipple, but flows out to a considerable height, i.e., the almost not increasing air volume due to the buoyancy force creates a buoyancy force that is not observed when the same volume of water is supplied when Efficiency = 1, we could get an amount of energy equal to the spent. But we spend less energy on air supply than on water supply, nevertheless we get a gain in energy. This is not the principle on which the action of the injector or ejector is based, but the phenomenon due to the difference in energy expenditures for the creation of water and air (the initial nonequilibrium), which determines their properties. It is known that the air volume when the pressure drops by 1a increases by the value of the initial volume, i.e., the initial increase in air volume occurs or, rather, is equal to a 2-fold increase, but the average effective air volume works for energy production (Fig. 8), which is expressed by the equation
V _g = V _o +

·

= P, where V _о is the volume of primary filling air at a depth of H at the same temperatures of water and air;
H - the height of the water column,
P - pressure coefficient, depending on the height of the water column (Nm / 10 m = P) at the level of the lower float-bell or ring distributor of compressed air.

P =

+

=

= V_o(1+0,5P).Then
V _g = V _o +

P =

+

=

= V _o (1 + 0.5P).

 The resulting equation allows us to calculate the production of energy due to the initial nonequilibrium at equal temperatures of water and air, and the Gay-Lussac law - the calculation of additional energy due to the acquired nonequilibrium, when the temperatures of water and air are not equal. The above findings relate to pneumatic motors, but to start them you need an additional source of energy, a kind of starter. Such an energy source could be one of the environmentally friendly converters of alternative energy sources. In this case, a wind power installation with an increased wind load removal area, representing a vertical rotor, was chosen as such a converter.

 It is known that in an equilateral triangle, the intersection point of the bisector is 1/3 of the height of the triangle, and if we make a frame representing a prism whose bases are an equilateral triangle, and cover part of the sides of the prism with air-impermeable material and let the axis pass through the intersection of the bisectors, then we get rotor element of a wind farm. By installing several of these elements on top of each other with mixing in the radial direction around the axis, we get a rotor, we get a rotor, and by installing additional spring-loaded sail blades that are able to open when the wind is exposed, we get an additional area for removing the wind load . By installing such a rotor on the float, we obtain a wind power plant capable of operating at drilling wind speeds. We connect the upper platform of the float with a wheel mounted on a rack with the possibility of vertical and circumferential movement, with a copressor installed on it and connected by an intermediate gear to the wheel, which is connected by a pipeline to an energy-extracting pneumatic hydraulic motor, the energy in which is replenished by the solar collector connected to it using the greenhouse effect. An energy-extracting pneumatic hydraulic motor is also connected to a compressor, which is connected by a pipe to an energy-extracting water-jet type installation, which rotates on rolling bearings in an external cylindrical fixed body fixed to the bottom of the reservoir, closed in the upper and open in the lower part, having a nozzle in the upper part and in the upper part lower on the inside - angularly fixed plates that act as turbine blades, and located in a river or canal closed with a reservoir, which removed sakkumulirovannuyu an energy in the reservoir.

 Thus, the main distinguishing features of power plants are energy-extracting properties, in contrast to converters from one manifestation of energy to another.

 In FIG. 1 shows a diagram of a power plant; in FIG. 2 - element of the rotor of a wind power installation; in FIG. 3 - multi-stage rotor of a wind power installation; in FIG. 4 - wind power installation; in FIG. 5 - the same, with a spring-loaded platform and counterweights; in FIG. 6 is a view A in FIG. 5; in FIG. 7 - energy-extracting installation of water-jet type; in FIG. 8 is a diagram of the operation of the volume of air supplied under a column of water at equal temperatures (the right side is a graph of the average effective volume of air).

 An energy-extracting wind power installation 1.1 is connected by an air duct 1 to an energy-extraction plant of a water-jet type 1.2 installed in a channel 2 closed to a water reservoir 3 connected to an energy consumer, for example, a compressor station 4 and a fan 5. A compressor is connected by an air duct 6 to a refrigeration unit 7 located above the channel and intended for condensation of water vapor of atmospheric air. Sailing blades 8 and 9 (Fig. 2) between which there is an elastic element 10, pivotally connected to the vertical generators 11 of the spatial prismatic frames 12, representing a triangular prism and connected by bases with each other offset relative to each other around the geometrical axis 13 of the prism and constituting a vertical rotor 14 (Fig. 3) mounted on a cylindrical float 15 (Fig. 4), having rolling elements 16 on a vertical generatrix and placed in a reservoir 17 filled with liquid and having an internal spherical surface 18. At the bottom of the float, a rod 19 is fixed with a load of 20 at the end. The upper surface of the float interacts with the wheel 21, mounted in the supports 22 on a vertical rack 23, with the possibility of vertical movement in the annular guide 24 with simultaneous movement in the circumferential direction. On the top of the rack is a platform 25 with a compressor 26, which through an intermediate gear 27 interacts with the wheel. The compressor through the non-return valve 29 is connected through a non-return valve 29 to a compressed air accumulator 30, which through the on-off distributor 32 and valves 33 and 34 is connected alternately with bells 35 and 36, each of which is divided into two equal by volume hollow horizontal baffle parts. Bell bobbers are asymmetric about the vertical axis. The bell floats interact with the guiding parts 38 and 39 of the body of the air hydraulic engine filled with water and passing into the expanded unloading part 40 in the upper part of the body. The bell floats interact with those fixed in the upper part of the body at the boundary of the transition of the guide part to the unloading one with elastic return elements 41 and 42 and pivotally mounted on the floats at the center of gravity point with frames 43 and 44, which are connected by a cable transfer 45 with each other by a common cable. The cable of the block transmission interacts with the drums 46 and 47, freely set on two parallel axes and interacting with the drums through the freewheels 48 and 48. The drums interact through the gear wheel 50 and the spurious gear 51, and through the intermediate gear 52 with the compressor 53. Filled with water the housing of the pneumatic motor is connected to the solar collector 54. Depending on the operating conditions, the rotor 14 can be mounted on a platform 56 rotating on the rolling elements 55 (Fig. 5), interacting with the base 57. Fundamentals It is supported by springs 58 and has counterweights 59, which are connected to the cable via a block 60 through it. The compressed air accumulator 61 through the inlet valve 62 and the stem 63 with the initial start pedal 64 through the cam gear 65 connected via the intermediate gear 66 through the overrunning clutch 67, gear 68 with gear rack 69 and inertial flywheel 70. The gear rack is integral with the frame 71, pivotally connected to the float-bell 72, divided by a partition 73 into two parts of equal volume. The bell float interacts through the pins 74 (Fig. 6) with box-shaped guides 75, with the walls of the housing 76 filled with water and the elastic return elements 77 installed at the boundary of the transition of the guide part to the unloading part 78. The fluid-filled hydraulic actuator body is connected to the solar collector 79, a bell float with a pipeline 80 - with an inlet valve, and an inertial flywheel - with a compressor 53. The compressor 53 interacts with an annular pipe air spray through the air duct 80 (Fig. 7) with a non-return valve 81 m 82 and a multi-ring tube air distributor 83 located inside and above the lower part of the cylindrical housing 85 closed in the upper part and located at the lower water level supported on the rolling elements 84, having a total transverse area in the upper closed part on the vertical generatrix on the outside of the nozzle 86 sections of which are not less than the cross-sectional area of the housing. In the lower part of the casing 85, plates 87 are fixed at an angle forming on the inside from the inside. The casing 85 interacts via rolling elements with the stationary outer cylindrical casing 88 open in the upper and lower parts, fixed by piles 89 in the channel bottom and having a water outlet at the level of the nozzles of the inner casing interacting with an electric energy generator 91. The upper part of the housing 85 is higher and the lower is lower than the upper and lower parts of the inner housing. Consumers of electric energy can be, for example, compressor 4 and fan station 5, operating in a complex with a refrigeration unit 7.

 Power installation works as follows.

 An energy-extracting wind energy installation 1.1 (Fig. 1), generating compressed air through a pipe 1 is connected to an energy-extracting installation of a water-jet type 1.2 installed in a channel 2 closed to a reservoir 3. The ability to obtain an unlimited amount of energy allows connecting compressor 4 and a fan station 5 as energy consumers working in combination with a refrigeration unit 7 in order to obtain fresh water due to the condensation of atmospheric air vapor. The energy necessary to ensure the operation of the compressor and fan or other consumers is obtained by converting wind energy into compressed air energy with a further increase in the amount of compressed air due to the energy extracted in energy-extracting pneumatic motors connected to the wind power plant and solar collector, due to the use of compressed air in an energy-extracting installation of a water-jet type, in which the energy accumulated in the water of the reservoir is extracted. The electricity obtained by the proposed method is environmentally friendly.

Wind power installation works as follows. Sailing blades 8 and 9, between which there is an elastic element 10, pivotally connected to the vertical generators 11 of the spatial frames 12, representing a triangular prism and interconnected by bases with offsets relative to each other around an imaginary geometric axis 13, and constituting a vertical shaftless rotor 14, fixed on a cylindrical float 15, which has rolling elements 16 on a circumferential vertical wall and placed in a reservoir 17 filled with a liquid having an internal spherical surface 18, and the float has a rod 19, on the end of which the load 20 is fixed, simultaneously with the float acting as an inertial flywheel, the construction of a shaftless vertical rotor is presented, in which sailing blades are opened under the action of the air flow and the elastic element, causing the assembly of a vertical rotor and a float connected to it, which, when the wind is amplified, can tilt without leaving the spherical surface of the tank, and when the wind is weakened due to the reduced center of gravity, we provide loaded, again takes upright position. Thus, the load on the rotor is self-regulating, which ensures the operation of the installation at drilling wind speeds. The upper surface of the float is in contact with the wheel 21 mounted in the rolling bearings 22 on the rack 23, which has the possibility of a vertical and circumferential movement of the guide 24 under its own weight. On the upper part of the rack there is a platform 25 with a compressor 26, which interacts with the wheel shaft through the intermediate gear 27. Thus, the rotation of the float is transmitted to the wheel, which transfers it through the intermediate gear to the compressor drive, which is connected via a check valve 29 to the compressed air accumulator 30, from which air is supplied through the on-line distributor 32 through the on-off valve 32 and the valves 33 and 34 are alternately supplied under the floats of the bell 35 and 36, having a supply of usable volume, each of which by a partition 37, the cavity of which is filled with air, is divided into two parts of equal volume. The air in the cavity of the partition balances the weight of the float and the installation elements connected to it. The lower part submerged float is filled with air so that by the time the entire volume of the ascent portion filled with air and at the outlet of the guide portion allows it to roll ¹⁸⁰ and gulp freed from air and filled with water again submerged in the extended discharge part 40. When At the same time, having a supply of usable volume, the float-bell, as it ascends and decreases the liquid pressure and the temperature difference between the water and the supplied air, increases the ascent force by increasing the air volume, ovozhdayuschegosya less heat capacity of heat extraction air from a heat capacity of water (Fig. 8). The pop-up and overturned bobber-bell with elastic return elements 41 and 42 is fixed in a vertical working position. The bell floats are interconnected through a frame 43 and 44 pivotally connected to the floats, which are connected by a cable block 45 to each other by a common cable. The cable block interacts with the drums 46 and 48 freely rotating on two parallel shafts and interacting with the drums through overrunning clutches 47 and 49. The drums interact with each other through the gear wheel 50 and the spurious gear 51, which provides one-way rotation of the gear wheel. Rotation of the gear is transmitted through the intermediate transmission 52 to the compressor 53. To replenish the energy in the water pnevmogidrodvigatelya latter is connected with the solar collector 54 in which the water can be heated to a temperature close to 100 ° ^C. Installation of the rotor 14 (FIG. 5) on the spring-loaded platform the role of the liquid is played by compression springs 58, the load on which is reduced by the counterweights 59. The advantage of this design is that the wheel transmitting rotation to the compressor is in contact with the dry surface of the platform, which will increase the force friction, and when using the installation with a shortage of water, for example in the desert. Due to the fact that a single-float pneumatic hydraulic motor is used, the air inlet under the bell float is carried out by an automatic cam distributor, the stem of which is connected to the inlet valve. To replenish energy reserves, the air hydraulic motor is also connected to the solar collector. When the valve 81 is opened, the compressor 53 of the wind power plants through the air duct 80 supplies air to the annular pipe fish separator 82 and the multi-ring pipe air distributor 83 (Fig. 7) located inside and above the lower open part, supported by rolling elements 84, closed in the upper part and located below the water level of the cylindrical body 85, having a nozzle 86 in the upper closed part on a vertical generatrix on the outer side. The total cross-sectional area is not less than the cross-sectional area of the body, and in the lower part, plates 82 are fixed at an angle from the inside of the casing 85. The casing 85 interacts through the rolling elements with the stationary outer cylindrical casing 88 open in the upper and lower parts, fixed by piles 89 in the bottom of the reservoir and having a water outlet 90 at the level of the nozzles of the inner casing interacting with the electric energy generator 91. When air enters the annular fish trap, the air exits from it through the holes, forming an air curtain that repels the fish, preventing the fish from getting into the mouth new. The air entering the multi-ring distributor located inside the inner body, leaving the hole, having buoyancy, increases its volume by the value of the initial volume every 10 m of ascent and by 1/273 for every degree of temperature increase, it begins to float, increasing its volume until exit from water, while displacing water through nozzles. Thus there is a selection of heat by water on the basis that by lowering the air pressure is not at 1 atm air temperature drops to 24 ^° C Outlet air and water from under the barrel observed, ie. K. Multiring air outlet of the distributor is performed above the lower parts of the casing, and the total cross-sectional area of the nozzles is not less than the area of the transverse casing, i.e., the water pressure to the lower part of the casing is greater than the water pressure to the distributor, and an equal or larger cross-sectional area of the nozzles and casing ensures equal Valuable entry and exit of water from the housing. Water ejected from the nozzles rotates the housing and the associated generator. The rotation of the body will have a constant speed. The water thrown into the gap between the outer and inner shells is discharged into the reservoir through the directional outlet available in the outer shell, creating a directed surface flow of aerated water. At the same time, a near-bottom current is created, directed inside the rotating inner casing, and acting on inclined plates, the water flow creates additional torque. In this case, a constant replacement of the energy carrier occurs, which makes it possible to obtain a uniform flow of electricity. Calculation of additional power due to bottom currents can be made using formulas for hydraulic turbines. Air divided into small volumes in a multi-ring distributor has a large contact area with water, which contributes to the most complete heat removal from water, which means that according to Gay-Lussak law and the largest increase in air volume, which increases the amount of work performed, which means that the quantity increases extracted energy.

 Technical and economic efficiency will be expressed in the use of almost ready-made energy for the needs of the national economy, the cheapness, inexhaustibility and absolute purity of which allows not only to restore the lost balance on the planet, but also to improve it.

Claims (11)

 1. ENERGY INSTALLATION, comprising a vertical wind turbine with blades mounted on a cylindrical float located in a tank with liquid, and kinematically connected with a working machine placed on the base, characterized in that, in order to increase the efficiency of use of wind energy, the rotor is made in the form of connected triangular frames, the vertices of which are shifted in the circumferential direction one relative to the other, the blades are mounted in pairs on the edge of each frame using hinges with an elastic connection, and the area of each Each pair of blades is equal to the area of the side of the frame, the float is equipped with rolling elements placed on its vertical generators, and a counterweight, the inner surface of the tank is made spherical, and the rolling elements are in contact with the latter.  2. The power plant according to claim 1, characterized in that it is equipped with a rack with a wheel mounted for vertical movement along an annular guide, the working machine is made in the form of a compressor fixed to the site and kinematically connected with a wheel mounted to interact with the surface of the float .  3. Power installation according to paragraphs. 1 and 2, characterized in that it is equipped with a liquid-filled tank with guides and an upper unloading part, elastic return elements, two cable-connected float bells installed in the tanks on the guides, a solar collector connected to the tank, two parallel drums interacting with a block transmission associated with an intermediate compressor, a pipeline with a check valve connected to the compressor, and a compressed air accumulator connected with the pipeline ohm with on-off distributors with bells floats.  4. Power installation according to paragraphs. 1 to 3, characterized in that each bell float is equipped with a horizontal partition installed with the formation of two chambers of equal volume, and is located asymmetrically relative to the vertical axis.  5. Power plant according to claim 4, characterized in that the horizontal partition is hollow.  6. Power installation according to paragraphs. 1 to 5, characterized in that each bell float is equipped with hinged frames connected to a cable block, and elastic return elements.  7. Power installation according to paragraphs. 1 - 6, characterized in that the rotor is placed on a platform that interacts through the rolling elements with a base made spring-loaded and connected to the counterweights using a cable block transmission.  8. Power installation according to paragraphs. 1 to 7, characterized in that it is provided with an outer cylindrical body located in a pond and an inner cylindrical body fixed at the bottom, mounted for rotation about a vertical axis and connected to a generator and a compressed air accumulator.  9. Power plant according to claim 8, characterized in that the upper part of the outer casing is provided with a horizontal outlet pipe, the lower part is located above the bottom of the reservoir, and the casing are interconnected by bearings.  10. Power plant according to claim 9, characterized in that the inner casing is provided with nozzles and vanes located tangentially to the outer surface of the casing, fixed in the lower part of the inner surface of the casing, while the cross-sectional area of the nozzles is larger than the cross-sectional area of the casing, and the lower part of the casing connected to a compressed air battery.  11. Power plant according to claim 10, characterized in that it is equipped with an annular air enclosure associated with a compressed air accumulator and located at the bottom of the reservoir around the inner case.

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