RU2354023C1 - Integrated power system - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: integrated power system comprises multiple electric energy generators integrated in common power system, multiple electric energy consumers connected to common power system. Electric energy consumers maintain separated group of consumers-regulators joined by centralised control system. Each consumer-power regulator has electric machine enabled to work in the mode of electric motor or electric generator, unit for conversion electric energy into thermal energy made as hydrodynamic thermal generator capable to be connected to electric machine shaft, thermal energy accumulation unit connected with hydrodynamic thermal generator and made as liquid accumulator of thermal energy with separated liquid and steam phases.

EFFECT: providing stable operation mode of electric generating aggregates irrespective of generated and consumed powers in power system.

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Description

The invention relates to the field of energy, in particular to integrated power systems with many generators and consumers of electric energy, combined into a single energy network. It can be used in power systems to adjust the ratio of generated and consumed capacities in various modes of operation of power systems.

In large power systems, there is the task of maintaining the so-called “standby power”. This is due to the need for constant support in the availability of activated electric power in the event that unforeseen power shortages arise on the side of the energy producer, for example, as a result of a power plant failure.

In the European Unified Power Grid (UCPTE), each enterprise must hold 2.5% of the instantaneous grid load as “standby power”. In Germany, this “standby power” must be half activated within 5 seconds and the remainder in the next 25 seconds in order to be able to compensate for the power shortage in the common network.

The problem of maintaining "reserve power" is closely related to the stability of the frequency of the electric current in the power system - one of the main indicators of the quality of electric energy. Currently, the main means of maintaining the frequency of an electric current in a power system is to change the generation power carried out by primary control systems of power units. The operation of primary control systems of large power units is associated with the loss of their effectiveness. In addition, the technical characteristics of the control systems of existing equipment are not always able to provide frequency support within the limits of current standards (50 Hz ± 0.2 Hz), not to mention the norm of 50 Hz ± 0.02 Hz according to the requirements of the European Energy System (UCTE).

It is widely known that “standby power” is maintained by accumulating energy in the normal mode of operation of the power system, followed by transferring the stored energy to the integrated grid in cases of unforeseen power shortages on the side of the energy producer. Inertial storage devices (flywheels), energy storage devices in the form of compressed gas, thermal energy storage devices, superconducting magnetic energy storage devices, etc. are used as energy storage devices.

An example of holding "reserve power" by energy storage is a load balancer known according to the patent of the Russian Federation RU 2119708, IPC ⁶ H02J 3/30, H02J 15/00, Н02К 31/00, Н02К 13/00, Н02К 25/00, filing date applications 1997.02.25. The load balancer for bringing power consumption modes in accordance with the structure of generating capacities contains a flywheel energy storage device, a charge-discharge electric machine body and a control system. A feature of the energy storage device is that in a sealed enclosure in which a deep vacuum is created, on a radial-axial self-centering magnetic support, which simultaneously serves as the hub of the rim super-flywheel, wound from high-strength filaments, a vertically single explicit pole armature of two combined disk unipolar electromagnetic excitation machines with a common central thermionic or sliding current collectors and separate peripheral thermionic current collectors with grid frequency control.

Another example of retaining “reserve capacity” through energy storage is a renewable energy power plant in the energy system and the method of its operation, known by the patent of the Russian Federation RU 2035821, IPC ⁶ H02J 15/00, filing date 1991.07.01.

A power plant contains an electric generating device in the form of a renewable energy source, an electric power accumulator, electric switches, and also power lines connecting the elements of the power plant with each other and with the power system.

Installation works as follows.

During high electrical loads, the battery delivers electricity to the energy system. The battery input at this time is connected to the installation of a renewable energy source, replenishing the energy reserves in the battery. During low electrical loads, the battery input is disconnected from the installation of a renewable energy source and connected to the energy system for several hours to recharge in such a way that the battery is fully charged by the time of the morning rise in electrical load.

The duration of recharging is determined by the degree of charge of the energy accumulator. For example, if the battery is fully charged at the time of the failure of the schedule of electrical loads, then that night it does not connect to the power system at all and all half-peak stations are unloaded, as usual, for the entire period of low electrical loads.

There are many more examples of the use of various energy storage batteries to compensate for power shortages in power systems. Their common drawback is the limited capacity of energy storage devices, which limits the duration of the compensation of load peaks to tens of seconds or several seconds, which is not enough to start other backup energy carriers, such as pumped storage power plants or gas turbine power plants.

It is also widely known to maintain “standby power” by throttling turbine control valves in steam turbine power plants that feed the combined grid. Such steam turbine power plants are normally operated with the indicated throttling. With a load peak on the network side or, in other words, with a deficit in the total commissioned capacity of power plants, throttling is removed and the capacity of steam turbine power plants increases accordingly.

The operation of steam turbine power plants in the throttle mode of turbine control valves leads to a decrease in the efficiency, increases operating costs at a separate power plant. This type of compensation for the power shortage requires the construction of more powerful steam turbine power plants than is required for energy supply to consumers in the normal operation of the power system, causing an increase in investment costs.

To compensate for power shortages in the duration range from 30 seconds to 5 minutes or more, short-term interruption of steam supply to devices heated by intermediate selection steam is known. At the same time, an increased amount of thermal energy is supplied to the steam turbine, and the turbine power increases. The time thus gained is, in most cases, sufficient to bring the heating power in the steam generator to an acceptable boundary power when counting on long load peaks, or in order to activate accumulating power plants.

For example, a steam turbine power plant is known (US Pat. No. 3,523,421) with a steam turbine driving a generator and an intermediate selection steam pipe connected to a steam turbine with a valve controlled by a control unit. The method of operating such a steam turbine power plant involves, depending on the load, increasing the supply of steam to the steam turbine by controlling the selection of intermediate steam from the turbine. Regulation is carried out by means of a control unit controlling a valve mounted on a steam pipe of intermediate selection.

The peculiarity of this type of regulation is expressed in the fact that the system is triggered with a significant delay time. Therefore, such regulation is not suitable for compensating peak loads so quickly that there is no power failure or frequency decrease in the power grid. In addition, the power plant with such regulation most of the time operates in the underload mode, which leads to a decrease in the efficiency, increases operating costs, requires the construction of more powerful steam turbine power plants than is necessary to supply consumers in normal operation of the power grid.

As a prototype of the claimed integrated power system, the combined power system is selected, known according to the patent of the Russian Federation RU2121746, IPC ⁶ H02J 15/00, H02J 3/06, F01K 7/34, filing date 1992.11.20.

The unified power system includes many electric power generators connected by a common energy network, as well as consumers of electric energy connected to a common energy network. Electric power generators are made in the form of steam turbine power plants. Part of the steam turbine power plants is equipped with devices for regulating the steam supply to steam turbines by controlling the flow rate of steam of intermediate selection. Part of the steam turbine power plants is equipped with superconducting magnetic energy storage devices.

Each steam turbine power plant contains a reservoir of feed water, a steam generator with an economizer, an evaporator and a superheater, turbines, and an electric energy generator. The steam generator input (economizer input) is connected to the feed water tank. A steam turbine is connected to the steam generator output (superheater output) through a high pressure steam pipeline. The output of the high pressure steam turbine is connected to a two-line low pressure steam turbine, which is connected in series with the high pressure steam turbine. The turbines are connected to the shaft of an electric energy generator. Both low-pressure stages of the low-pressure steam turbine are connected through the exhaust steam pipe to the condenser. The condenser output through the condensate pump and the condensate heater is connected to the feed water tank. The feed water tank through the feed water pump and feed water heater is connected to the input of the steam generator (economizer input).

Steam turbine power plant operates as follows. Feed water is supplied to the steam generator, where it turns into superheated high pressure steam. High-pressure steam enters the inlet of the high-pressure steam turbine, then to the two-flow low-pressure steam turbine. In turbines, the thermal energy of steam is converted into mechanical energy, which drives an electric energy generator connected to the turbines. The exhaust steam after the turbines enters the condenser, where it turns into condensate, which is sent to the feed water tank.

Some steam turbine power plants, which are equipped with devices for regulating the supply of steam to steam turbines, have the following design features.

The first intermediate-pressure steam pipeline is connected to the output of the high-pressure steam turbine, which is connected to the feed water tank through the first control valve and feed water heater. To one of the stages of the low pressure steam turbine is connected a second intermediate-extraction steam pipe, which is connected to the condenser inlet through a second control valve and condensate heater. A steam turbine power station also contains a control unit with measuring lines that measure electric current and / or parameters depending on it, such as frequency, voltage, power in a common power network, determining the ratios of generated and consumed powers in a common power system. The control unit is connected by control lines to the first and second control valves in the steam pipelines of intermediate selection.

In normal operation, when backup power is not required, the intermediate steam from the low-pressure turbine is sent through the second control valve to the condensate heater and from there to the condenser. Due to this, the condensate entering the feed water tank is heated. Further heating of the feed water is carried out by intermediate extraction steam from a high-pressure turbine, which is sent through the first control valve to the feed water heater and from there to the steam generator.

If there is a shortage of generated power, for example, if one of the steam turbine power plants fails, the control unit-controller simultaneously controls both control valves in the intermediate steam pipelines in the direction of their closure. The consequence of this is that more steam is supplied to the low pressure steam turbine, the turbine power is increased, the electric power generator generates and transfers additional energy to the common electric network, compensating for the deficit of the generated power. With a decrease in demand for power in the common electric network, both control valves in both pipelines of the intermediate selection steam are controlled in the opening direction, putting the unit into normal operation mode.

Part of the steam turbine power plants can be equipped with superconducting magnetic energy storage devices.

A superconducting magnetic electric energy storage device comprises a superconducting magnetic coil, a cooling magnetic coil, a refrigeration unit, a control system providing an electric energy storage mode or a mode of transmitting stored energy to a common electric network. The superconducting magnetic storage device is controlled by a control unit-regulator, which measures the parameters of the general energy network and determines the ratio of generated and consumed capacities in the general energy system. With a deficit of generated power, a superconducting magnetic storage device transfers stored energy to a common electrical network. In the normal operation of the power system, energy is accumulated by the superconducting magnetic storage device.

Interrupting the selection of intermediate steam using superconducting magnetic energy storage devices allows you to compensate for load peaks with a duration in the range from 0.1 second to 5 minutes. This time interval is sufficient to start other backup energy carriers, such as pumped storage power plants or gas turbine power plants.

Common features of the prototype and the claimed integrated power system are: a combined power system, including many generators of electric energy connected by a common energy network, many consumers of electric energy connected to a common energy network.

Under such regulation, the generating units of the integrated energy system most of the time operate in under load mode, which leads to a decrease in efficiency, increases operating costs, and requires the construction of more powerful steam turbine power plants than is necessary to supply consumers with normal operation of the power grid. In addition, when regulating the intermediate extraction of steam from the turbines, the system operates with a significant delay time, which, with sudden peak loads, can lead to a power failure or a frequency drop in the power grid.

The basis of the invention is the task of improving the integrated power system, in which due to the features of building a power system and selecting control parameters, a stable mode of operation of power generating units is ensured regardless of the ratio of generated and consumed capacities in the power system.

The problem is solved in that in a combined power system comprising a plurality of electric power generators connected by a common power network, a plurality of electric power consumers connected to a common power network, according to the invention, electric power consumers comprise a dedicated group of control consumers combined by a centralized control system, each the consumer energy controller contains an electric machine configured to operate in electrode mode driver or in the mode of an electric generator, a unit for converting electric energy into thermal energy, made in the form of a hydrodynamic heat generator with the ability to connect to the shaft of an electric machine, a thermal energy storage unit associated with a hydrodynamic heat generator and made in the form of a liquid heat accumulator with separated liquid and vapor phases , a unit for converting thermal energy into mechanical energy associated with the vapor phase of the liquid accumulator and made in the form ApoB steam turbine or piston engine to couple with the shaft of the electrical machine.

These signs make up the essence of the claimed integrated power system.

The essential features of the invention are in causal connection with the achieved technical result.

So, if in a unified energy system that includes many electric power generators connected by a common energy network and many electric energy consumers connected to a common energy network, we select among consumers of electric energy a group of consumer regulators, united by a centralized control system, each consumer regulator perform in the form of an electric machine that can operate in electric motor mode or in electric generator mode, a conversion unit electric energy into thermal energy, made in the form of a hydrodynamic heat generator with the possibility of connecting to the shaft of an electric machine, a heat energy storage unit associated with a hydrodynamic heat generator and made in the form of a liquid heat energy accumulator with separated liquid and vapor phases, a thermal energy to mechanical energy conversion unit energy associated with the vapor phase of the liquid accumulator and made in the form of a steam turbine or a steam piston machine with ozhnostyu compound with the shaft of the electric machine, it becomes possible to adjust the ratio of power generated and consumed during steady state operation of power generating units.

This is explained by the fact that with this approach, the control objects for the purpose of adjusting the ratio of generated and consumed capacities can be consumers of electric energy (a dedicated group of consumer regulators). At the same time, electric energy generators are transferred to the stationary, most efficient operating mode with maximum load.

So, in normal operation, all electric power generators operate in the most efficient mode of operation with maximum load. Consumer regulators operate in the mode of electricity consumption with the generation of thermal energy, which is accumulated and / or transmitted to the heating network.

With a load peak, in other words, with a deficit in the total commissioned capacity of generating power plants, some of the selected consumer regulators are automatically taken out of the mode of electricity consumption. Moreover, each of these consumer controllers can operate in the mode of transferring the accumulated thermal energy to the heating system, or in the mode of converting the stored thermal energy into electrical energy with its transmission to the general electric grid, or in a combined mode with the transfer of the stored thermal energy to the heating system and with transmission electric energy to the general electric grid. In this case, the operation mode of the electric energy generators does not change.

When normalizing the generated and consumed capacities, these consumer regulators are transferred to the normal mode of consumption of electric power.

In this way, the ratios of the generated and consumed capacities in the integrated power system are corrected without changing the operating mode of the electric energy generators.

When converting electric energy to thermal energy in the form of hydrodynamic heat generators with an electric drive, they are switched off or on almost instantly, which solves the problem of holding "second reserve power".

The following is a detailed description of the integrated power system with reference to the drawings, in which:

Figure 1 - United power system, block diagram.

Figure 2 - United power system, the scheme of the consumer-regulator.

The combined power system includes a plurality of electric power generators 1 connected by a common power network 2, a plurality of consumers of electric power 3 connected to a common power network 2.

Electric energy consumers contain a dedicated group of consumer regulators 4, combined by a centralized control system 5 with the ability to switch operating modes of these consumer regulators 4.

The integrated power system contains a dispatch center 6, which is connected by control lines 7 to electric power generators 1, control lines 8 with electric power consumers 3, control line 9 with power network 2, control line 10 with a centralized control system 5 by consumer regulators 4. Centralized system control 5 is connected by control lines 11 with consumer regulators 4.

Each consumer regulator includes an electric machine 12, made in the form of an electric asynchronous machine with a phase rotor with the ability to work in the electric motor mode or in the electric generator mode, a unit for converting electric energy into thermal energy, made in the form of a hydrodynamic cavitation heat generator 13 with the possibility of connection with the shaft 14 electric machine 12 through a controlled clutch 15, the thermal energy storage unit, made in the form of a liquid thermal energy accumulator 16 with section liquid 17 and steam 18 phases and connected to the heat generator 13 by pipelines 19, 20 with controlled valves 21, 22, a unit for converting thermal energy into mechanical energy, made in the form of a steam turbine 23 (or a steam piston machine) with the possibility of connecting to the shaft 14 of an electric machine 12 through a controlled coupling 24. A steam turbine 23 is connected to the vapor phase 18 of the thermal energy accumulator 16 by a pipeline 25 with a controlled valve 26 and with a condenser 27 through the pipeline 28. The liquid phase 18 of the thermal energy accumulator 16 is a pipeline 29 with a controlled valve 30 is connected to a heat exchanger 31. A heat exchanger 31 and a condenser 27 are connected to a heat generator 13 by a return water pipe 32 with a controlled valve 33 and to the heating network pipelines 34. Water is fed to the system through a pipe 35 with a controlled valve 36. Each consumer regulator also contains a control unit 37 connected by power lines 38, 39, respectively, to the electrical machine 12 and to a common electrical network 2, control lines 40, 41, 42, respectively, to the electrical machine 12, a removable clutch 15, controlled by a clutch 24, as well as control lines (not shown to simplify the drawing) with controlled valves 21, 22, 26, 30, 33, 36.

Each consumer regulator operates as follows.

Depending on the characteristics of the common electric network 2, which is controlled by the control unit 37, the consumer-regulator can automatically be transferred and operate in the following main modes by the command of the control unit 37 or using manual control.

1. The mode of energy consumption from a common electrical network 2, the conversion of electrical energy into heat with the accumulation of thermal energy

In this mode, the electric machine 12 at the command of the control unit 37 is transferred to the operating mode of the "engine". Clutch 15 is included. Clutch 24 is excluded. Controlled valves 21 and 22 are open. Controlled valves 26, 30, 33 are closed. The working fluid (water) is supplied from the heat energy accumulator 16 through the valve 22 to the input of the heat generator 13. From the output of the heat generator 13, the water through the valve 21 enters the heat energy accumulator 16. The water circulates in the specified closed loop and heats up as a result of the conversion of electric energy into thermal. Thermal energy (heated water) is accumulated in a liquid thermal energy accumulator 16 with the formation of steam 18 and liquid 17 phases. The design features of this type of thermal energy accumulator make it possible to provide the required battery power without any special technical problems.

2. The mode of use of accumulated thermal energy with the transfer of electrical energy to a common electrical network 2

In the indicated mode, the electric machine 12 is transferred to the operating mode of the “generator” upon the command of the control unit 37. Clutch 15 is off. Clutch 24 is included. The controlled valves 26, 33, 22 are opened by the corresponding signals of the control unit 37. The steam from the steam zone 18 of the battery 16 enters through the valve 26 to the inlet of the steam turbine 23, the output of the steam turbine 23 is connected to the condenser 27 through a pipe 28. The output of the condenser 27 through the open valves 33 , 22 is connected to the liquid zone 17 of the thermal energy accumulator 16. In this mode, the steam turbine 23 transfers mechanical energy to the electric machine 12, which operates in the “generator” mode. The electric energy generated by the electric machine 12 is transmitted through power lines 38, 39 to a common electrical network 2 under the control of a control unit 37.

3. The mode of use of accumulated thermal energy with its transfer to the heating system 34

In this mode, the electric machine 12 is turned off. Clutch 15 is off. Clutch 24 is off. The controlled valves 21, 26 are closed, and the controlled valves 30, 33, 22 are opened by the corresponding signals of the control unit 37. Heated water from the liquid zone 17 of the battery 16 enters through the valve 30 to the heat exchanger 31 and then through the return water pipe 32, the valves 33, 22 enter in the liquid zone 17 of the thermal energy accumulator 16. In this mode, thermal energy from the accumulator 16 is transmitted through the heat exchanger 31 to the heating network 34.

4. The mode of use of accumulated thermal energy with the transfer of electrical energy to a common electrical network 2 and with the transfer of thermal energy to the heating system 34

In the indicated mode, the electric machine 12 is transferred to the operating mode of the “generator” upon the command of the control unit 37. Clutch 15 is off. Clutch 24 is included. The controlled valves 22, 26, 30, 33 are opened by the corresponding signals of the control unit 37. The steam from the steam zone 18 of the accumulator 16 enters through the valve 26 to the input of the steam turbine 23, the output of the steam turbine 23 is connected to the condenser 27 through a pipe 28. The output of the condenser 27 open valves 33, 22 are connected to the liquid zone 17 of the thermal energy accumulator 16. The steam turbine 23 transfers mechanical energy to the electric machine 12 operating in the “generator” mode. The electric energy generated by the electric machine 12 is transmitted through power lines 38, 39 to the common electric network 2 under the control of the control unit 37. Heated water from the liquid zone 17 of the battery 16 enters through the valve 30 to the heat exchanger 31 and then through the return water pipe 32, valves 33, 22 enters the liquid zone 17 of the thermal energy accumulator 16. Thermal energy from the heat exchanger 31 and the condenser 27 is removed to the heating network 34.

It is clear that the consumer-regulator circuit allows the implementation of various combined operating modes. Said, as well as other possible operating modes are implemented within the framework of the invention by known means, for example, by connecting to the system the corresponding circuits with the corresponding adjustable valves, which are controlled automatically or manually by the control unit. Such agents are widely known and are not the subject of the invention.

The combined power system is operated as follows.

Continuously monitor the electrical parameters of the integrated power system (voltage, frequency, generated and consumed power). The number of controlled parameters should be sufficient to assess the ratio of generated and consumed capacities. Correct the ratio of generated and consumed capacities according to the results of monitoring the electrical parameters of the integrated power system. The adjustment is performed by switching the operating modes of the consumer controllers 4, united by the centralized control system 5. The electrical parameters of the common energy network are controlled by the dispatch center 6 of the integrated power system, and the switching of the operating modes of the consumer controllers 4 is performed through the centralized control system 5 by the commands of the control center 6.

In the normal operation mode of the integrated power system, consumer regulators 4 consume electrical energy, generate thermal energy, accumulate thermal energy, and provide consumers with thermal energy.

With a load peak (with a deficit in the introduced capacity of electric energy generators 1), part of the consumer controllers 4 are automatically taken out of the mode of consumption of electric energy in one of the possible modes of operation: the mode of using accumulated thermal energy with the transfer of electric energy to the general electric network 2; the mode of use of accumulated thermal energy with its transfer to the heating system 34; the mode of use of accumulated thermal energy with the transfer of electrical energy to a common electrical network 2 and with the transfer of thermal energy to the heating network 34.

When normalizing the generated and consumed capacities, these consumer regulators 4 include or are transferred to the normal mode of consumption of electric power.

Thus, the ratio of generated and consumed capacities in the integrated power system is adjusted. In this case, the operation mode of the electric energy generators does not change. Electric power generators are constantly operating in the stationary, most economical mode of operation with minimum fuel consumption and maximum load.

The combined power system, which is claimed, provides:

1. Qualitative satisfaction of demand for thermal energy.

A significant number of heating and industrial boiler houses of various types and purposes are operating in the existing combined power systems. Most of them are in a state of physical deterioration. In addition, there are a large number of thermal power plants built in the 50s - 70s of the last century. Most of them have obsolete, uneconomical equipment.

Given the high moral and physical demolition of the main heat-generating capacities, as well as the increase in prices for the main types of fuel, especially natural gas, the high-quality satisfaction of the demand for thermal energy with existing district heating systems based on CHP plants and natural gas boiler houses is problematic due to the inefficiency and unreliability of their work . The situation is also complicated by the unsatisfactory condition of worn-out heating networks, most of which are characterized by high accident rates, significant losses of thermal energy in the processes of transport and heat distribution.

The experience of using consumer controllers made in the form of converters of electric energy to thermal energy indicates the possibility of a twofold reduction in the annual energy costs of heating. On this basis, the introduction of these consumer regulators in full will allow, for example, Ukraine, to provide heat to 20% of the housing stock. Natural gas savings will amount to 2-8 billion m ³ per year.

2. Improving the reliability and energy security of the integrated energy system.

One of the problems of ensuring the reliability of the energy system is the prevention of systemic accidents that may occur as a result of a sudden sharp increase in electrical load or emergency shutdown of large power units of nuclear power plants and thermal power plants. Currently, this problem is being solved by disconnecting electrical consumers, which leads to economic losses for electricity consumers.

The introduction of consumer regulators made in the form of converters of electric energy into thermal energy will allow more efficiently performing the tasks of balancing the power imbalance without significant losses for consumers of electric and thermal energy and will provide:

- automatic regulation of the consumed electric power without regulation of power units due to the high speed of loading and unloading of consumer regulators;

- increasing the level of electrical energy consumption during the hours of night dips of electrical load, which will ensure the operation of power units in the conditions of uniform most effective power;

- increase the utilization factor of the installed capacity of power units of thermal power plants by 1.5-1.7 times due to the effective alignment of daily schedules of electrical loads of the power system;

- the use of consumer regulators as synchronous compensators of 0.4-10.0 kV networks, where today there is a significant shortage of such compensators.

Global trends in rising gas prices, the dependence of prices and supply conditions on fluctuations in the global market, as well as on destabilizing non-economic factors, necessitate a reduction in the absolute and relative levels of natural gas use in thermal power. The introduction of consumer regulators as highly efficient heat generating capacities will lead to the economical and efficient use of natural gas.

3. Reducing environmental pollution.

The use of consumer regulators, made in the form of converters of electric energy into thermal energy, will allow to receive thermal energy at capacities that do not pollute the environment, reduce emissions of nitrogen oxides into the atmosphere, for example, Ukraine, by 1.6-6.4 thousand tons in year.

4. The ability to integrate with other integrated energy systems, such as the European Energy System.

For example, Ukraine has significant opportunities to increase export of electric energy, including among European countries, in case of switching to parallel operation with the European energy system (LJCTE). Nevertheless, for full integration it is necessary to solve the problem of improving the quality of electricity that is exported, in particular, the problem of increasing the accuracy of frequency support by 10 times. The introduction of consumer controllers, made in the form of converters of electrical energy into thermal energy and possessing the properties of a high-speed frequency controller, largely solves this problem.

Claims (1)

A combined power system including a plurality of electric power generators connected by a common power grid, a plurality of electric power consumers connected to a common power grid,
characterized in that the consumers of electric energy contain a dedicated group of consumer regulators, united by a centralized control system, each consumer energy regulator contains an electric machine configured to operate in electric motor mode or in electric generator mode, a unit for converting electric energy into thermal energy, made in in the form of a hydrodynamic heat generator with the ability to connect to the shaft of an electric machine, a block of thermal energy storage, unit with a hydrodynamic heat generator and made in the form of a liquid heat accumulator with separated liquid and vapor phases, a unit for converting thermal energy into mechanical energy associated with the vapor phase of the liquid accumulator and made in the form of a steam turbine or steam reciprocating machine with the possibility of connecting to the shaft of an electric machine .

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