RU2435982C1 - Belashov modular power plant - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: modular power plant includes at least one module, each of which includes two vertical axes of rotor with blades rotating about its vertical axis, which are installed between guiding and diverting casing on the support interacting with the base. Inside the base there installed is automatic tracking, control and adjustment device with system of input measuring devices, automatic adjustment system interacting with capacitive storage, and converter station equipped with DC high voltage converters. Axes of rotor of left and right row are connected to low-speed generators. Left and right rows of straight and spoon-shaped blades, which are arranged on rotor axes, rotate to opposite directions. Rows of blades are arranged on different levels, between which openings are located, and blades themselves are installed in gaps between guiding and diverting casing. Protective roof having system of measuring transmitters and fastening device is connected to inlet and diverting casing, inside which there located are shafts and switching channels. System of measuring transmitters is connected to comparator and PID control including power supply unit, integrator and logic devices, which are connected through control signals to controlled plant output devices, interact through commutator and adapter of communication interface with personal computer having systems of recording, diagnostics and monitoring, automatic process control and correction of programming and protection. Each high voltage converter is made in the form of electronic mechanical control device containing switching elements of valve system, reactive capacities and control electrodes of thyristors, which are electrically connected to step-down transformers having high voltage and step-down windings interacting with consumer load.

EFFECT: invention allows unifying manufacturing process of wind motors and other facilities of various capacity, increasing their capacity and reducing manufacturing costs.

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Description

The invention relates to installations for generating electrical energy from a fluid source consisting of wind, water, water vapor, exhaust gas flows in open or closed spaces. The modular power plant is a unified device for generating electrical energy from liquid, gas or air fluids and is intended for use in industry and the national economy as a wind turbine, damless hydroelectric power station and other structural technical structures of various capacities.

A Belashov screw is known, comprising a shaft with a hollow sleeve, an optimal rotation synchronization mechanism located in the inner cavity of the sleeve, and rotary blades with axes mounted by hinges fixed in the sleeve and kinematically connected via a synchronization mechanism with the drive shaft, where each blade is equipped with an installed in its end part, a streamlined guide plumage with an internal cavity, an axis of rotation fixed in the cavity, and a spring-loaded streamlined self-regulating flap (patent th Federation 2046996, CL, F03D 7/00 -. equivalent).

Known Belashov wind turbine containing a fixed tower, a head with an even or odd number of wind wheels of various diameters with rotary blades arranged in increasing diameter, and rolling elements. Mathematical formulas for calculating a wind engine (patent of the Russian Federation 2046996 class., F03D 7/00 - analogue).

Known Belashov damless hydroelectric power station of small and medium power, containing an even or odd number of threshold, floating and submersible modules installed at uniform or uneven intervals in the river channel (patent of the Russian Federation 2382232 class., F03B 13/00 - analogue).

A well-known universal electric Belashov machine containing a housing with an even or odd number of modules, each module includes a rotor with magnetic systems and magnetic circuits, a stator with multi-turn windings, an automatic tracking and regulation system, rolling or sliding elements (patent of the Russian Federation 2118036, cl. H02K 23/54 - analog).

Known modular power plant, operating from a source of geothermal steam, containing many combined power modules, each of which has a turbine running on a pair of this source to produce electric energy, working on organic fluid in a closed loop, where each module is equipped with control and management the amount of electricity produced by the generator (patent of the Russian Federation 2140545, class. H02K 23/54 - analogue).

Known wind turbine, including a rotor rotating around its vertical axis and containing a number of concave blades mounted on the rotor vertically in a circle at a distance from each other, characterized in that the rotor has an outer casing made in the form of a half cylinder mounted for rotation around a vertical axis of the rotor, the casing is equipped with at least two plates directed to one side, one of the plates being fixed to the central generatrix of the casing, and the plane in which it is located is parallel It is part of the plane of location of the extreme generators of the casing, and the other plate is mounted on one of the vertical edges of the casing, the choice of which is determined by the condition for ensuring the impact of air flow on the concave surface of the blades (patent for PM 72729 from 04/27/2008 - prototype).

The purpose of the invention is the unification of structural engineering structures, reducing the cost of their production and increasing the productivity of modular power plants operating from a fluid source consisting of wind, water, water vapor or exhaust gas flows in open or closed spaces, increasing the utilization rate of direct and concave blades of individual modules of a power plant.

This goal is achieved in that the modular power plant consists of at least one module, each of which contains two rows of straight and concave blades. The left row of straight and concave blades is placed on the vertical axis of the rotor, which rotates clockwise. The right row of straight and concave blades is placed on the vertical axis of the rotor, which rotates counterclockwise, while the left and right rows of straight and concave blades are placed at different levels, between which the windows are located. The left and right rows of straight and concave vanes are installed in the gaps between the inlet and outlet casing, which are mounted on a stand, interacting through the rolling elements with a base having a protective regulatory seal. The base through the rolling elements interacts with the shaft, which is rigidly connected to the stand, which has through holes for the rotor axes of the left and right rows associated with low-speed generators that are mounted on the shaft. The protective roof, which has a system of measuring sensors and a mounting device, is rigidly connected to the inlet and outlet casing. Through the elements of rolling or sliding, the protective roof interacts with the left and right axis of the rotor. Inside the inlet and outlet casing, rods are installed that are connected to the side members containing a communication channel that is connected to a shaft located inside the inlet and outlet casing. The automatic tracking, control and regulation device comprises a system of measuring sensors that are connected to comparators, a sensitivity controller, a proportional-integral-differential controller, including a power supply unit, an integrator, logical devices that are connected via control signals to the output devices of the control object. The control object interacts through a switch, an adapter for a communication interface with a personal computer having a data recording system, a diagnostic and control system, an automatic process control system, a correction, programming system and settings protection. Each converter of a high voltage direct current into an electrical signal of alternating current is made in the form of an electronic-mechanical control device, switching elements of a valve system, reactive capacities of thyristors with control electrodes, step-down transformers having high-voltage windings and lowering windings that are associated with the load of the consumer.

Figure 1 shows a General view of a modular power plant.

Figure 2 shows one module of a power plant.

Figure 3 shows a section aa module of a power plant.

Figure 4 shows a functional diagram of a modular power plant.

Figure 5 shows a schematic diagram of a device for reducing and converting a constant voltage source into an electrical signal of alternating current of a given frequency.

The modular power plant, Fig. 1, consists of at least one module 1. Inside the module, there is a left row of straight and concave vanes 2 and a right row of straight and concave vanes 3 that protrude from the guide casing 4. The left row of straight and concave the blades rotate around its vertical axis of the rotor 5, clockwise 6. The right row of straight and concave blades rotates around its vertical axis of the rotor 7, counterclockwise 8. Between the straight and concave blades of the left row 2 are windows 9, and between the straight and concave E blades 3 disposed right row window 10. By using the modular power plant as wind motor base 11 to be mounted on a rigid support 12. By using the modular power plant as damless hydroelectric base 11 must be located above the water flow. To increase the strength, the base 11 must be made of composite reinforcement, which is used in construction for monolithic and prefabricated structures, as well as for the use of structural elements of increased strength in the form of independent rods and restrictive grids. The inner part of the base through the rolling support element 13 interacts with the shaft 14. A low-speed generator 15, a low-speed generator 16 and a stand 17 are mounted on the shaft 14. The shaft of the low-speed generator 15 is connected to the axis of the rotor 5, and the shaft of the low-speed generator 16 is connected to the axis of the rotor 7, and the low-speed generator 15 and the low-speed generator 16 can be mounted on the stand 17. The stand 17 through the rolling elements 18 interacts with the base of the wind engine 11. Inside the base of the wind engine there is a device automatic tracking, control and regulation 19. Around the base 11 is a protective regulating seal, inside of which there is a brake and locking device 20. Above the modular power plant there is a protective roof 21 on which the system of measuring sensors 22 is located. On the protective roof 21, above measuring of sensors 22, there is a mounting device for fixing the modular power plant to the rigid support 12 using the fastening means made in the form of extensions.

Direct and concave blades of the modular power plant 1, figure 2, consist of collapsible parts having technological grooves and cuts. The left row of straight and concave blades 2 is placed between the fixing elements 23, and the right row of straight and concave blades 3 is placed between the fixing elements 24. In the manufacture of small modular power plants for wind engines and damless hydroelectric power stations, the transmission of mechanical energy from the left row of straight and concave blades 2 can be directly transmitted to a low-speed generator 15, and the right row of straight and concave blades 3 to a low-speed generator 16. When designing large, powerful and high x modular power systems for the wind turbine, where the air flow distribution in the different modules will be different, slow-speed generators are to be installed on each module separately. For example, for the left row of straight and concave vanes 2, a low-speed generator 25 must be installed on the axis of the rotor 5, in windows 9, and for the right row of straight and concave vanes 3, a low-speed generator 26 must be installed on the axis of the rotor 7, in windows 10.

A rod 27 is mounted inside the guide casing 4, Fig. 3, which is rigidly connected to the stand 17. A spar 28 is located around the rod 27, which is connected to the low-speed generator 25 and the casing 4. The outer rear surface of the guide casing 4 in the gap 29 repeats the configuration of the left row straight and concave blades 2, and in the gap 30 repeats the configuration of the right row of straight and concave blades 3 of module 1. The fixing elements 23 with many straight and concave blades 2 are located on the sleeve 31. The sleeve 31 has rolling or sliding elements, which They are located on the axis of the rotor 5. The movable part of the low-speed generator 25 is rigidly connected to the sleeve 31. The fixed part of the low-speed generator 25 is fixed to the spar 28. Inside the spar 28 there is a communication channel 32, which adjoins the shaft 33. The shaft 33 is equipped with a ladder for passage maintenance staff during the operation of a modular power plant, for repair and maintenance work of individual modules, as well as for laying communication cables. A rod 35 is mounted inside the outlet casing 34, which is rigidly connected with the stand 17. A spar 36 is located around the rod 35, which is connected to the low-speed generator 26 and the outlet casing 34. The outer front surface of the outlet casing 34 in the gap 37 repeats the configuration of the left row of straight and concave vanes 2, and in the gap 38 it repeats the configuration of the right row of straight and concave vanes 3 of module 1. The fixing elements 24 with a plurality of straight and concave vanes 3 are located on the sleeve 39. The sleeve 39 has rolling or sliding elements that some are located on the axis of the rotor 7. The movable part of the low-speed generator 26 is rigidly connected to the sleeve 39. The stationary part of the low-speed generator 26 is fixed to the spar 36. The design of the modules of the low-speed Belashov generators is such that they can be installed on both moving and fixed axes of the rotor 5 7. Inside the spar 36, there is a communication channel 40, which is adjacent to the shaft 41. The shaft 41 is equipped with a ladder designed for passage of maintenance personnel during operation of the modular power plant new for repair and maintenance of individual modules, as well as for laying communication cables. Moreover, for the partial redistribution of air flows and reduce turbulent flows of the current medium - water, air, water vapor or exhaust gases, the outer front surface of the guide casing 4 and the outer rear surface of the exhaust casing 34 can have profile gutters. If the modular power plant for a wind turbine is equipped with straight blades 2 and 3 only, the automatic tracking, control and regulation device 19 will respond more quickly to changing wind flows, since the guide casing 4 and the discharge casing 34 have an identical structure, which allows rotation of the straight blades 2 and 3 in different directions. If a modular power plant for a wind engine or damless hydroelectric power station is equipped with concave blades 2 and 3, then its efficiency increases, but this design responds more slowly to changing wind or water flows, and it has to constantly keep the guide casing 4 against the wind or water flow, so like concave vanes 2 and 3 can rotate in only one direction.

The device for automatic tracking, control and regulation 19, figure 4, contains a system of input measuring devices made in the form of primary and secondary sensors. The main sensors are:

- wind or water flow direction sensor 42,

- wind or water flow sensor 43,

- speed sensor rotation of the wind rings of the left row 44,

- speed sensor rotation of the wind rings of the right row 45,

- voltage sensor of the generators of the left row 46,

- voltage sensor of generators of the right row 47.

Auxiliary sensors are:

- vibration sensor 48,

- pressure sensor 49,

- temperature sensor 50.

The main and auxiliary sensors are designed to convert the measured value into an analog current signal 4 ... 20 mA. Further, the measured value from the system of input measuring devices is supplied to the on-off controllers (comparators) 51, 52, 53, 54, which compare the value of the measured value with the reference one and maintain the controlled value at a given level. The sensitivity regulator 55 serves to initially configure the range of operation of the measuring devices and subsequently allows you to change the sensitivity threshold of each input device. To ensure high accuracy of control and regulation of any technical processes, the most efficient - (PID) proportional-integral-differential controller 56, including a power supply 57, an integrator 58 for integrating analytic functions, and logical devices (LU) 59 working in one of three modes, such as a two-position controller, an analog P-controller or a meter-recorder, which, in accordance with user-defined parameters, generate control signals 60, which are received at Khodnev device 61, regulation of the object 62. The electrical signal from the proportional-integral-differential controller 56 is supplied to the switch 63, the device for changing the direction of electric current in switching a communication interface adapter 64 of the personal computer 65, having:

- a data recording system 66,

- a system of diagnostics and control 67,

- automatic process control system 68,

- system of correction, programming and protection of settings 69.

Key type output devices include:

- electromagnetic relays 70,

- transistor optocouplers 71,

- triac optocouplers 72,

- selsyn 73.

The key type output device is used to control (turn on / off) the load either directly or through more powerful control elements such as starters, solid state relays, thyristors or triacs. One of the main output devices 61 is selsyn 73. Selsin is a self-synchronizing electric machine for transmitting distance information about the angle of rotation between the wind or water flow sensor 42 and the shaft 14, which is the subject of regulation.

The object of regulation of a modular power plant using electromagnetic relays, transistor optocouplers or triac optocouplers is separate modules of left and right row generators, in which any one physical quantity or several physical quantities are controlled simultaneously by series or parallel connection of modules or separate multi-turn windings of each module .

Temperature control of multi-turn windings of electric machines and low-speed generators is carried out according to the signals of the internal sensor of the resistor type 50 installed inside the stators. The parameters of operation and release of temperature protection are entered by the user into the device during programming. If the set temperature of the thermal protection is exceeded, the electric machine or low-speed generator is immediately disconnected from the load and an alarm occurs. To control the rated voltage in the multi-turn stator windings of low-speed generators installed by the consumer, it is necessary to include means that ensure its adjustment, the zone of permissible deviation, the delay time for the emergency shutdown and the delay time for their inclusion.

When operating Belashov modular low-speed generators as a direct or alternating current generator, it becomes necessary to change the design value of low-speed generators, in particular, this applies to independent modules that can be connected in series or in parallel during operation of the machine, and when using an excitation system made of electromagnets enable or disable primary or secondary rotor magnetic systems.

Organization of the communication interface, personal computer 65 is carried out by special devices connected via an interface adapter or interface converter (in the form of an RS-232 current loop) capable of recording data on a computer, setting up the device configuration from a computer and performing the process of collecting data about all connected devices, displaying the results of this survey, as well as the saved user values in the log files.

For example, if a modular power plant designed for a wind turbine or damless hydroelectric power station is located close to the consumer, then the received electric energy from the rectifier 74 through the step-down device 75 of the wind turbine or damless hydroelectric power station via communication line 76 should go to the capacitive storage 77 and then to a device for converting a low DC voltage into an electrical signal of alternating current of a given frequency 78.

If a modular power plant designed for a wind engine or damless hydroelectric power station is located far from the consumer, then the received electric energy from the rectifier device 74 through a voltage multiplier 79 should be transported via high-voltage communication line 80 and fed to converter station 81. High-voltage communication line 80 consists of a single-wire circuit with earth return or a bipolar circuit that uses a pair of conductors that are used to transmit large electric ktricheskih capacities for long and short distances.

A single-wire and bipolar high-voltage direct-current high-voltage transmission circuit is used to reduce electrical losses in the resistance of wires. Here, the power is proportional to the current in the circuit, and the loss of heating wires is proportional to the square of the current. However, the power is also proportional to the voltage, so a predetermined power level can be provided with a higher voltage at lower currents. Moreover, the higher the voltage, the lower the power loss. The power of losses can be reduced by reducing the resistance of the line, which is usually achieved by increasing the diameter of the conductor, however, it must be taken into account that wires of a larger cross section have greater weight and cost. These circuits have lower electrical losses and greater advantages over the transmission of electric power by alternating current. Depending on the voltage level and circuitry, losses in single-wire or bipolar high-voltage transmission circuits of DC electric power will be approximately 3% per 1000 km. Since the DC line operates at an amplitude voltage, this allows 41% more power to be transmitted over an existing power line with conductors and insulation of the same size than AC, which reduces costs. However, it must be remembered that with a single-wire circuit with earth return and the absence of a second metal conductor, currents flow in the ground between the grounded electrodes of two power plants, there are problems that create a current flowing in the ground, including electrochemical corrosion of long metal objects laid in the ground, such as pipelines. When using water as a second conductor, the current flowing in seawater can produce chlorine or otherwise affect the aqueous composition. An unbalanced current can cause a magnetic field, which can affect the magnetic navigation compasses of ships passing over an underwater cable. These effects can be eliminated by installing a metal return conductor between the two ends of the monopolar power line. Since one of the terminals of the converters is grounded, there is no need to install the insulation of the return wire at the full transmission voltage, which makes the return wire less expensive than the high voltage conductor. The decision to use a metal return wire is based on economic, technical and environmental factors.

In a bipolar transmission, a pair of conductors is used, each under high voltage relative to earth of opposite polarity. Since the insulation of these conductors must be selected according to the full voltage, the cost of the power line is higher than a monopolar circuit with a return wire. However, the advantages of bipolar transmission make it more attractive compared to monopolar transmission. Under normal load conditions, insignificant currents flow in the ground, as in the case of a monopolar transmission with a metal return wire. This reduces land loss and environmental impact. When a short circuit occurs on one of the lines of the bipolar system, the circuit can continue to operate on the undamaged line in monopolar mode, transmitting approximately half the rated power using earth as a return conductor. Since for a given rated power only half of the current of the monopolar line flows through each conductor of the bipolar line, the cost of the second conductor is less compared to a monopolar line of the same power. In very unfavorable terrain, the second conductor can be run on an independent set of power transmission towers, so that if one of the lines is damaged, part of the power is transferred to the consumer.

The resulting high voltage, Fig. 5, from the high-voltage communication line 80 is supplied to a converter station 81. A device for converting a high voltage direct current 82 into an electrical AC signal is installed at the station. The AC signal is reduced to a value compatible with the end user, and give it a predetermined frequency. There is a great misconception of producers of electric energy from wind turbines or mini hydroelectric power stations, which locally receive electric energy, convert it into a finished product and supply it to consumers via communication line 80. The main function of a wind turbine or mini hydroelectric power station is the generation of electrical energy, which should be delivered to the consumer with low losses. Everyone knows that transportation of the finished product in the form of an alternating current of a given frequency carries great losses. If the electric energy of constant voltage is delivered to the consumer and converted into a finished product on the spot, then the high-voltage communication line through one wire 80 will be a natural storage of electric energy, for example, creating a high voltage from 10,000 to 20,000 V. Moreover, if there is a reduced signal in place AC will be converted by different converters and contain a different frequency, then the end user will not even feel the difference if, for example, in one village there is a voltage of 220 V with a frequency of 51 Hz, and in the second village there will be a voltage of 225 V and a frequency of 49 Hz, but it is impossible to add these two signals together, since they will give harmonics, which will reduce the power of the transmitted signal. AC power lines can only connect synchronized AC mains that operate at the same frequency and phase. The main advantage of Belashov 82 high-voltage DC / DC converter is that it is able to select only the specified amount of power needed for each village, and leave the excess voltage in the high-voltage communication line 80.

The high-voltage direct current converter 82 to an electrical alternating current signal consists of an electronic-mechanical control device 83, which controls the switching elements of the valve system 84 and the valve system 85. The electronic-mechanical control device 83 consists of electronic, mechanical, or a combination thereof, which produces set frequency signal for switching elements of an unlimited number of valve systems. The valve system 84 consists of a reactive capacitance 86 and a thyristor 87 having a control electrode 88, a reactive capacitance 89 and a thyristor 90 having a control electrode 91, a thyristor 92 having a control electrode 93, and a step-down transformer 94 having a high voltage winding 95 and a lower winding 96. The presence of a reactive component in the transducer helps filter harmonics. The step-down winding 96 is connected to the load of the consumer 97. The valve system 85 consists of a reactive capacitance 98 and a thyristor 99 having a control electrode 100, a reactive capacitance 101 and a thyristor 102 having a control electrode 103, a thyristor 104 having a control electrode 105, and also a step-down transformer 106, having a high-voltage winding 107 and a lowering winding 108. The valve system 84 is protected by a diode 109 from reverse currents, and the valve system 85 is protected by a diode 110. An electronic switch 111 having a control electrode 112 serves to isolation of the lowering winding 96, the transformer 94 and the lowering winding 108, the transformer 106, operating at a load of 97. Next, the spent current is supplied to the second conductor 113.

It must be emphasized that the electronic-mechanical device 83 used to turn on and off the thyristors must be galvanically isolated from the high voltages of the power line 80. Typically, this isolation is optical. In a hybrid control system, low-voltage monitoring electronics sends light pulses through the fiber to the high-voltage control electronics. Such switching elements are commonly referred to as gates.

There is a modular power plant, made in the form of a wind engine, as follows.

If the modular power plant 1 is not oriented in the direction of the wind, then even with a slight gust it begins to rotate the left row of straight and concave blades 2 or the right row of straight and concave blades 3, which with the help of generators of the left row 46 or generators of the right row 47 begin to generate voltage direct or alternating current. After receiving a signal from the wind direction sensor 42, the voltage sensor of the generators of the left row 46 and the voltage sensor of the generators of the right row 47, the automatic tracking, control and regulation device 19 transmits its signal to the proportional-integral-differential controller 56, which generates control signals 60 and provides them to the output devices 61 of the regulation object 62. In this case, the regulation object is a shaft 14, which is controlled by electromagnetic relays 70, transistor optocouplers 71, and whether triac optocouplers 72 and low-speed generators of the left or right row. The key output device 61 is selsyn 73 - a self-synchronizing electric machine for transmitting distance information about the angle of rotation between the wind direction sensor 42 and the shaft 14, which is the subject of regulation. With a further change in the direction of the wind and its pressure on the left or right row of straight and concave blades, the automatic adjustment of the orientation of the wind engine occurs due to more or less power take-off from the left or right row of low-speed generators. The sensitivity of this orientation to the wind is very high and therefore the maintenance of the wind engine in the right direction occurs due to the uniform power take-off from the low-speed generators of the right and left rows using the automatic tracking, control and regulation device 19 and low-speed generators of the left or right row. At the same time, in a modular power plant, as output devices, a braking and blocking system for any module individually or for the entire device is provided. Thus, the automatic orientation of the wind engine to the direction of the wind is carried out. If a modular power plant, made in the form of a wind turbine, is located in an area where the direction of the wind is changing rapidly, then the left row of blades 2 and the right row of blades 3 must be made of straight sheets. If a modular power plant, made in the form of a wind turbine, is located in the area where monsoon winds blow, then the left row of blades 2 and the right row of blades 3 need to be made of concave sheets or a concave profile should be made up of many straight sheets. For rigidity of the structure between the straight sheets of the blades, grooves are contained and technological cuts are installed. In this design of a modular power plant, made in the form of a wind turbine, the different shape of the blades does not significantly affect the utilization of the screw, but the noise figure of different forms of the blades will be very different. To simplify the design of a modular power plant, the device orientation to the wind can be made in the form of a weather vane.

A modular power plant operates, made in the form of a damless hydroelectric power station, as follows.

The main distinguishing feature of the damless hydroelectric power station from the wind engine is that the upper base of the modular power plant with the left and right row of straight or concave blades is placed in the water stream, and power is taken from the low-speed generators above the water stream.

The modular power plant 1 uses the Magnus effect, which was first described by the German physicist Heinrich Magnus in 1853. This effect is applicable to a modular power plant designed as a wind turbine or damless hydroelectric power station, where the straight and concave vanes of the left and right row on one side of the object, in which the direction of the vortex coincides with the direction of the flowing wind stream, and, accordingly, the velocity of the medium with this side is increasing. The Magnus effect is a physical phenomenon that occurs when a fluid or gas flows around a rotating body. A force is formed that acts on the body and is directed perpendicular to the direction of flow. This is the result of the combined effects of various physical phenomena, such as the Bernoulli effect and the formation of a boundary layer in the medium around the streamlined object. A rotating object creates a vortex motion around itself. On one side of the object, the direction of the vortex coincides with the direction of the flowing stream and, accordingly, the velocity of the medium increases on this side. On the other hand of the object, the direction of the vortex is opposite to the direction of flow and the velocity of the medium decreases. Thus, a pressure difference arises, generating a transverse force from the side of the rotating body on which the direction of rotation and the direction of flow are opposite, to the side on which these directions coincide.

If the modular power plant 1 is located close to the consumer, then the electric signal from the output device 61 of the control object 62 is supplied to the rectifier device 74 and the step-down device 75. Then, the electric signal through the communication line 76 arrives at the capacitive storage 77, where the DC voltage signal is converted into an electrical AC signal 78 of a given voltage and the required frequency.

If the modular power plant 1 is located far from the consumer, the electrical signal from the output device 61 of the control object 62 is supplied to the voltage multiplier 79 and through the high-voltage communication line 80 to the converter station 81, inside which a high-voltage DC / DC converter 82 is installed.

A high voltage DC / DC converter 82 operates as follows.

A high DC voltage through a high-voltage communication line 80 is supplied to the anodes of thyristors 87 and 99. The electronic-mechanical control device 83 consists of electronic, mechanical, or a combination of these means, which generates a signal of a given frequency for control electrodes of an unlimited number of valve systems. For example, if it is necessary to turn on the high-voltage DC / DC converter 82 and power the load 97, it is necessary to apply voltage to the control electrodes of the thyristors 88, 91 and 93, valve system 84 using the electronic-mechanical control device 83, while the electronic switch 111 must be closed. Further, the direct current electric signal passes to the high voltage winding 95 of the step-down transformer 94 and through the protective diode 109 the spent current is taken to the ground or fed to the second conductor 113. The action of the transformer is based on the phenomenon of electromagnetic induction. If a direct current pulse flows through the high-voltage winding of the transformer 94, which excites a magnetic flux in the core of the transformer 94, the magnetic flux, penetrating the turns of the secondary winding 96 of the transformer 94, will induce an emf in this winding, which enters the anode of the thyristor 90 and enters through the load 97 to the anode of thyristor 92, returning to the secondary winding of the transformer. Next, the electronic-mechanical control device 83 supplies voltage to the control electrodes 100, 103, 105 and 112 of the valve system 85, thyristors 99, 102, 104 and 111, while the electronic switch 111 must be open. Further, the direct current electric signal passes to the high-voltage winding 107 of the step-down transformer 106 and through the protective diode 110 the spent current is taken to the ground or fed to the second conductor 113. The action of the transformer is based on the phenomenon of electromagnetic induction. If a direct current pulse flows through the high-voltage winding of the transformer 107, which excites a magnetic flux in the core of the transformer 106, the magnetic flux, penetrating the turns of the secondary winding 108 of the transformer 106, will induce an emf in this winding, which enters the anode of the thyristor 104 and enters through the load 97 to the anode of the thyristor 102, returning to the secondary winding of the transformer. Thus, an alternating current arises at the load 97, the frequency of which will depend on the control signals of the electronic-mechanical control device 83 of the valve systems 84 and 85. It should be emphasized that the transformers 94 and 106 can be interconnected.

By using series or parallel connection of high-voltage DC / DC converters 82, it is possible to select a predetermined amount of power consumption from the high-voltage line 80, which existing types of converters cannot do.

This invention relates to an autonomous method for producing electrical energy from various independent sources of energy conversion having different voltages, different frequencies and different powers. Transmission of electrical energy over a distance. The conversion of electrical energy into an electrical signal of industrial frequency, the required power and the required number of phases, for use in any sectors of the economy, as an autonomous alternative source of electrical energy, which can interact with a large energy system.

The invention allows to unify the manufacturing process of wind engines and damless hydroelectric power plants and other structural technical structures of various capacities, to increase their productivity and reduce the cost of their production.

Reference materials:

The book "Units of Physical Quantities and Their Dimension", by L. A. Sena, Publishing House "Science", Main Edition of Physics and Mathematics, Moscow, 1988.

The book "Wind turbines and their application in agriculture", author Fateev EM, publishing house "Mash Gis", 1957.

The book "General Chemistry", author N.L. Glinka, publishing house "Chemistry", the city of Leningrad, 1988.

The book "Physics, reference materials", author O.F. Kabardin, publishing house "Enlightenment", Moscow, 1988.

Patent of the Russian Federation "Universal electric machine Belashova", 2118036 KL, H02K 23/54, 27/24, 27/00 for 1998.

Patent for PM 88372 "Composite reinforcement Astroflex", author Ponamarev A.N. and Beloglazov A.P., KL E04C 5/07 for 11/10/2009.

The book "Electrical Engineering with the Basics of Industrial Electronics," by V.E. Kitaev and L.S. Shlyapintokh, Higher School Publishing House, Moscow, 1973.

Claims (1)

A modular power plant comprising at least one module including a rotor rotating around its vertical axis and containing a series of concave blades mounted vertically in a circle on the rotor at a distance from each other, which are placed inside a guide casing made in the form of a half cylinder, characterized in that each module contains two vertical axis of the rotor with straight and concave blades rotating around its vertical axis, mounted between the guide and outlet casing which interacts through the rolling elements with a base having a protective regulating seal, an automatic tracking, control and regulation device with an input measuring device system, an automatic control system interacting with a capacitive storage device, and a converter station with many high-voltage DC converters are installed inside the base current interacting through the communication line with the consumer, where the base through the rolling elements interacts with the shaft of the stand, which has holes for the left and right row rotor axes, connected with low-speed generators, which can be installed on each module separately, where the left row of straight and concave blades placed on the first vertical axis of the rotor rotates clockwise, and the right row of straight and concave blades placed on the second vertical axis of the rotor rotates counterclockwise, while the left and right rows of straight and concave blades are placed at different levels, between which there are windows, and the blades themselves are installed in the gaps between the guide and outlet casing, where the protective roof, which has a system of measuring sensors and a mounting device, is connected to the inlet and outlet casing, inside which there are shafts and communication channels, where the system of measuring sensors is electrically connected to the comparator and proportionally an integral-differential controller, including a power supply unit, an integrator and logic devices, which are connected via control signals to the output devices of the control object interact with the commutator and adapter of the communication interface with a personal computer that has a registration system, a diagnostic and control system, an automatic process control system, a programming and protection correction system, and each high-voltage converter of a DC / DC converter is made in the form of an electronic-mechanical control devices containing switching elements of the valve system, reactive tanks and thyristor control electrodes in, which are electrically connected with step-down transformers having high voltage and step-down windings, interacting with the load of the consumer.

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