RU101104U1 - COMBINED ENERGY SYSTEM - Google Patents

Abstract

 1. A combined power system for generating electricity, cold and heat, comprising a wind turbine aggregated with a compressor driven by it through the eperotode, an air storage unit, a heat exchanger with hot and cold circuits, a warm air consumer, a turbo expander aggregated with an electric generator driven by it, and a cold air consumer, in this case, the air accumulator is made in the form of a flexible shell, the compressor is connected gas-dynamically by the inlet to the atmosphere, and the outlet through a hot heat exchanger circuit from the an air storage device, a turboexpander is connected in gasdynamically by an input to an output of an air storage device, and an output with an input of a consumer of cold air, the input and output of a cold circuit of a heat exchanger are interconnected through a consumer of warm air, characterized in that the power system further comprises a gas turbine installation and a line with a control valve connecting a gasdynamic gas turbine installation with an output of a turboexpander, the gas turbine installation consisting of a gas generator and a power unit, while the generator includes a gas generator compressor, a combustion chamber and a gas generator turbine interconnected gasdynamically in series, where the gas generator turbine and compressor are also mechanically interconnected, and the power unit consists of a block turbine and a block generator mechanically connected to it, while the main is connected to a gas turbine installation through the inlet of the compressor of the gas generator, and the turbine outlet is connected to the atmosphere through the turbine of the power unit. ! 2. The combined power system according to claim 1, characterized

Description

The proposed utility model relates to autonomous energy devices and is intended for the stable supply of electricity, cold and heat to consumers of a guaranteed level of technical indicators in a wide temperature range of atmospheric air in the field in the presence of a noticeable wind potential.

It is known that with increasing ambient air temperature, the degree of increase in the total pressure and air flow of the GTEU compressor decreases, which reduces the output power of the GTEU and can lead to an unacceptable limitation of the electric power received by the consumer.

The well-known "gas turbine power plant" (RF Patent No. 2354838 dated November 19, 2007 according to application No. 2007142364), comprising a gas turbine plant with an electric generator, as well as an autonomous circuit with a turbogenerator, an electric air compressor, heat exchangers and heat and cold consumers.

The technical solution makes it possible to provide a guaranteed level of generated electric power at elevated ambient temperatures or it is possible to produce cold air, for example, for conditioning rooms or cold rooms, and at lower ambient temperatures to provide consumers with thermal energy, for example, for heating rooms. However, a gas turbine power plant can operate only with continuous supply of fuel.

The well-known "Windmill system for generating electricity, cold and heat" (RF Patent No. 91743 dated November 25, 2009 according to application No. 200914320), comprising a turbine with an electric generator, a compressor with a wind engine, an air storage device, a heat exchanger with a hot circuit and a cold circuit with a coolant , energy center, heat consumer, consumer of cold, consumer of electricity and control valve. In this case, the air storage device is made in the form of a flexible shell. The drive is made in the form of a wind turbine and is connected to the compressor through the energy center. The compressor is gas-dynamically connected to the atmosphere by the inlet, and through the hot contour of the heat exchanger with the air storage inlet through the outlet. The turbine is gas-dynamically inlet connected through the control valve to the outlet of the air storage unit, and the outlet to the inlet of the cold consumer. The cold circuit of the heat exchanger is connected to a heat consumer. The generator is connected to a consumer of electricity.

The technical solution allows you to independently provide the consumer with electricity, cold and heat without fuel consumption. However, the cost of a wind turbine system at high power levels (comparable to a gas turbine power plant) is excessively large. The volatility of the wind potential over time and the limited reserves of compressed air in the drive limit the time to ensure the supply of energy in the right amount.

The technical task of the proposed solution is the stable provision of consumers with sufficient electricity, cold and heat in remote areas with a lack of power supply while increasing the efficiency and reliability of a gas turbine installation.

The problem is solved in that the combined power system contains a wind turbine aggregated with a compressor, an air storage unit, a heat exchanger with hot and cold circuits, a warm air consumer, a turbo expander aggregated with an electric generator driven by it, and a cold air consumer, while the air storage made in the form of a flexible shell, the compressor is connected with the gasdynamic inlet to the atmosphere, and the output through a hot circuit of the heat exchanger with the input of the drive of air, the turboexpander is connected gasdynamically by the inlet to the outlet of the air storage unit, and the outlet from the inlet of the consumer of cold air, the inlet and outlet of the cold circuit of the heat exchanger are interconnected through a consumer of warm air.

New in the utility model is that the system additionally contains a gas turbine installation and a line with a control valve connecting the gas-dynamic gas turbine installation with the output of the turbo expander, the gas turbine installation consisting of a gas generator and a power unit, while the gas generator includes a gas generator compressor, a combustion chamber and a gas generator turbine, interconnected gasdynamically in series, where the turbine and compressor are also mechanically interconnected, and the power unit consists of Urbina bloc and mechanically associated electric generator unit, wherein the line is connected to the gas turbine compressor through the gas generator inlet and outlet of the gas generator turbine is connected with the atmosphere through the turbine of the power unit.

A gas turbine installation maintains the required level of electricity supply to consumers with a significant change in ambient temperature.

The line allows you to supply cold air to the inlet of the compressor of the gas generator to increase the power of the gas turbine unit at an elevated level of ambient temperature.

The control valve allows you to change the supply of cold air to the consumer of cold air, depending on its needs.

The gas generator provides heat power to power the power unit.

The power unit, using the energy of the increased pressure of the hot gas leaving the gas generator, creates mechanical energy in the turbine of the unit, which is used by the unit's electric generator to generate electricity supplied to consumers.

The combined power system may include a switching device (for example, a clutch), which makes it easier to start the gas generator of a gas turbine installation by reducing the moment of inertia of the rotating parts.

Thus, the problem posed in the utility model is solved. A constructive scheme of the power system was developed for an economical and time-constant total generation of electricity, cold and heat in the absence of external power supply and a significant change in ambient temperature.

The present utility model will be better understood after considering the following description and operation of the combined power system for generating electricity, cold and heat with reference to the attached diagrams in FIGS. 1-3, where FIG. 1 is a power system diagram, and FIGS. 2-3 are options modernization of the power system circuit.

The combined power system for generating electricity, cold and heat contains (Fig. 1) a wind turbine 1, aggregated with a compressor 3, an air storage unit 4, a heat exchanger 5 with hot 6 and cold 7 circuits, a warm air consumer 8, a turbine expander 9 aggregated with the electric generator 10 brought by it, and a consumer of cold air 11. In this case, the cold air storage 4 is made in the form of a flexible shell. Compressor 3 is connected in a gasdynamic way with the atmosphere and the outlet through a hot circuit 6 of the heat exchanger 5 with the inlet of the air storage unit 4. The turbo expander 9 is connected in gasdynamic way with the output of the air storage unit 4 and the output with the inlet of the cold air consumer 11. Inlet and outlet of the cold circuit 7 of the heat exchanger 5 are interconnected through a consumer of warm air 8.

In accordance with the utility model, the combined power system further includes a gas turbine unit 12 and a line 13 with a control valve 14, connecting the gasdynamic gas turbine unit 12 with the output of the turboexpander 9. The gas turbine unit 12 consists of a gas generator 15 and a power unit 16, while the gas generator 15 includes a gas generator compressor 17 , a combustion chamber 18 and a turbine of a gas generator 19 connected gasdynamically in series with each other, where the turbine 19 and compressor 17 are also mechanically connected between by itself, and the power block 16 consists of a turbine of the block 20 and a power generator of the block 21 mechanically connected with it, while the line 13 is connected to the gas turbine unit 12 through the inlet of the compressor of the gas generator 17, and the output of the turbine of the gas generator 19 is connected to the atmosphere through the turbine of the power block 20.

The turboexpander 9 aggregated with the electric generator 10 driven by it (FIG. 2) can be mechanically connected to the shaft of the gas generator 15.

The turboexpander 9 and the electric generator 10 (Fig. 3) are mechanically interconnected via a switching device 22.

The combined power system is as follows.

Air (see figure 1) from the atmosphere (when the wind turbine 1, coupled with the power center 2) enters the compressor 3, where its temperature and pressure rises. Then the air passes through the hot circuit 6 of the heat exchanger 5, where in the cold circuit 7 it transfers heat to the refrigerant going to the heat consumer 8, and the cooled enters the air accumulator 4. In the air accumulator 4, the air is additionally cooled to a temperature close to the ambient temperature, and leaving it, it enters the Turbo expander 9. In the turbo expander 9, the air expands, its pressure decreases almost to the ambient pressure, and the temperature drops to a value substantially lower than the ambient temperature; the differential pressure of air in the turboexpander 9 creates a torque on its shaft, it starts to rotate and the generated power is transmitted to a power generator 10 mechanically connected to it. Cold air from the turboexpander 9 enters the consumer of cold air 11 and, in parallel, passes through the line 13 with the control valve 14 to the input the compressor of the gas generator 17, where mixing with atmospheric air lowers its temperature. In the gas generator 15, air is compressed in the compressor of the gas generator 17 and enters the combustion chamber 18, where when mixed with the injected fuel (not shown) it forms a combustible mixture that burns. The resulting hot gas of high pressure enters the turbine of the gas generator 19, where its pressure is partially reduced; in this case, a torque is generated on the shaft of the turbine 19 and the generated power is given to the compressor of the gas generator 17 driven by the turbine 19. Next, the gas enters the power unit 16, where in the turbine of the unit 20 its pressure decreases to atmospheric level and the gas is released into the atmosphere; in this case, power is generated that is supplied mechanically connected to the turbine 20 to the electric generator of the block 21.

In the combined power system according to the scheme of figure 2, the turbine expander 9 and the turbine of the gas generator 19 mechanically connected with it give their power to the electric generator 10 and the compressor of the gas generator.

In the combined power system according to the scheme of figure 3, the switching device 22 can mechanically shut off the power supply to the generator 10.

Connecting a turboexpander to the shaft of the gas generator can significantly simplify the launch of a gas turbine installation, which increases its reliability and efficiency, since it does not consume additional fuel for launching, and the launch is more smooth than auxiliary power plants. The disconnection of the electric generator from the turboexpander in this case speeds up the start-up process.

For example, consider the operation of the system with the following parameters.

1. The volume of the accumulator of compressed air V = 10000 m ³ .

2. As a gas turbine, we consider PAES-2500 with a nominal capacity of 2.0 MW.

3. In the drive, the air pressure decreases from 0.25 to 0.15 MPa.

4. The flow rate of compressed air from the drive is 2.0 kg / s.

5. The ambient temperature is 310 K.

6. The average air temperature behind the turboexpander is 270 K.

7. The decrease in air temperature at the inlet to the compressor of the gas generator compared to the ambient temperature is 4 K.

Moreover, the total power increment developed by the turboexpander and gas turbine is 200 kW, which leads to an increase in efficiency. GTU at 10%.

Thus, the implementation of the presented technical solution allows us to fulfill the task of providing the consumer with stable electricity, cold and heat, while increasing the efficiency and reliability of the gas turbine unit by using the capabilities of a wind turbine and the widespread use of a turboexpander.

Claims (3)

1. A combined power system for generating electricity, cold and heat, comprising a wind turbine aggregated with a compressor driven by it through the eperotode, an air storage unit, a heat exchanger with hot and cold circuits, a warm air consumer, a turbo expander aggregated with an electric generator driven by it, and a cold air consumer, in this case, the air accumulator is made in the form of a flexible shell, the compressor is connected gas-dynamically by the inlet to the atmosphere, and the outlet through a hot heat exchanger circuit from the an air storage device, a turboexpander is connected in gasdynamically by an input to an output of an air storage device, and an output with an input of a consumer of cold air, the input and output of a cold circuit of a heat exchanger are interconnected through a consumer of warm air, characterized in that the power system further comprises a gas turbine installation and a line with a control valve connecting a gasdynamic gas turbine installation with an output of a turboexpander, the gas turbine installation consisting of a gas generator and a power unit, while the generator includes a gas generator compressor, a combustion chamber and a gas generator turbine interconnected gasdynamically in series, where the gas generator turbine and compressor are also mechanically interconnected, and the power unit consists of a block turbine and a block generator mechanically connected to it, while the main is connected to a gas turbine installation through the inlet of the compressor of the gas generator, and the turbine outlet is connected to the atmosphere through the turbine of the power unit. 2. The combined power system according to claim 1, characterized in that the turboexpander is mechanically connected to the shaft of the gas generator. 3. The combined power system according to claim 2, characterized in that the turboexpander and the electric generator are mechanically interconnected via a switching device, such as a clutch.