RU90543U1 - COMBINED SYSTEM FOR PRODUCING ELECTRICITY, COLD AND HEAT - Google Patents

Abstract

1. A combined system for generating electricity, cold and heat, comprising an air turbine mechanically connected to an electric generator, and an air compressor with a drive, characterized in that the system additionally includes an ejector with high-pressure and low-pressure inputs, a storage tank, a power unit and an electricity consumer, when In this case, the drive is made in the form of a wind turbine and is connected to the air compressor through the power unit, the air compressor is connected inlet to the atmosphere, and the outlet to the storage tank, the high-pressure inlet of the ejector is connected to the storage tank, and the low-pressure inlet is connected to the outlet of the air turbine, in addition, the electric generator is connected with an electricity consumer. ! 2. The system according to claim 1, characterized in that the consumer of electricity contains a distributor, a battery and an electric heater, while the electric generator is connected through the distributor to the battery, an electric heater and an external network. ! 3. The system according to claim 1, characterized in that the power unit is made in the form of a shaft line mechanically connecting the compressor with the wind turbine. ! 4. The system according to claim 1, characterized in that the power unit is made in the form of an electric motor and an additional electric generator, electrically connected to each other, while the electric motor is mechanically connected to the air compressor, and the additional electric generator is mechanically connected to the wind turbine.

Description

The proposed utility model relates to autonomous energy devices and is intended for the environmentally friendly supply of electricity, cold and heat to consumers in places where there is no fuel and energy sources.

A gas turbine power plant is known (RF Patent No. 2145386 dated December 23, 1997), comprising a gas turbine engine with an inlet, an electric generator mechanically coupled to it and a device for supplying cooled air to a gas turbine engine, including an autonomous air compressor (AVK) with a drive, a turboexpander and a heat exchanger, where the output of the turboexpander is connected gasdynamically with the entrance to the gas turbine engine, and the input through the heat exchanger with the output of the autonomous compressor.

The technical solution allows to increase the efficiency of a gas turbine installation to generate electricity during its operation in a hot period due to the supply of cold air to the inlet of the installation. However, it does not allow providing the infrastructure with cold and heat.

A gas turbine power plant is known (Positive decision of November 25, 2008 according to application No. 2007142364 of November 19, 2007), which contains a gas turbine engine with an inlet, an electric generator and a device for supplying cooled air to a gas turbine engine, including an autonomous air compressor with a drive, a turboexpander and a heat exchanger, where the output of the turboexpander is connected gasdynamically to the inlet of the gas turbine engine, and the inlet through the heat exchanger to the outlet of the autonomous compressor. The device is also equipped with an additional electric generator, mechanically connected with the turboexpander, an additional reversible type heat exchanger (the chamber is a heated room or a refrigerating chamber), connected to the inlet with the outlet of the turbine expander, and the outlet to the inlet of the stand-alone compressor with separate lines with shut-off valves.

The technical solution allows providing consumers with electricity, cold and heat. The disadvantages of this installation is environmental pollution with harmful impurities of exhaust gases, as well as the need for fuel for the operation of the installation.

The technical task of the proposed solution is the environmentally friendly generation of electricity and cold, as well as heat in the absence of fuel and external energy supply.

The problem is solved in that the combined system for generating electricity, cold and heat contains an air turbine connected mechanically to an electric generator, and an air compressor with a drive.

In accordance with the utility model, the system additionally includes an ejector with high-pressure and low-pressure inputs, storage capacity, a wind turbine, an energy center, and a consumer of electricity. The drive is made in the form of a wind turbine and is connected to the air compressor through the energy center. The air compressor is connected to the atmosphere by the inlet, and the output is connected to the storage tank. The high-pressure inlet of the ejector is connected to the storage tank, and the low-pressure inlet is connected to the output of the air turbine. The generator is connected to a consumer of electricity.

What is new in the utility model is that the system additionally includes an ejector with high-pressure and low-pressure inputs, a storage capacitor, an energy center, and a power consumer, while the drive is made in the form of a wind turbine and is connected to the air compressor via an energy center, the air compressor is connected to the atmosphere by the input and the output - with storage capacity, the high-pressure input of the ejector is connected to the storage capacity, and the low-pressure input is connected to the output of the air turbine, in addition, the electric generator is connected to the consumer m of electricity.

The use of an ejector with high-pressure and low-pressure inputs allows for the generation of cold air by an air turbine.

The storage capacity is a wind turbine energy accumulator, it allows you to smooth out the unevenness of the parameters of the air entering it and, accordingly, reduce the fluctuations of the energy parameters produced by the system.

Using the energy center allows you to transfer power from the wind turbine to the air compressor.

Using a consumer of electricity allows you to transfer electrical energy to consumers, as well as provide consumers with heat.

Using a wind turbine allows you to create environmentally friendly and cheap energy needed to drive the compressor.

The development and refinement of the above set of essential features is given below.

A power consumer may include a distributor, a battery, and an electric heater. In this case, electric power from the generator is supplied through a distributor to an external network, to a battery or an electric heater, providing the consumer with heat.

The battery makes it possible to accumulate electricity during periods of incomplete consumption.

The energy center can be made in the form of a shaft shaft, in the simplest way connecting a wind turbine and an air compressor mechanically.

The power unit may contain an electric motor and an additional electric generator, while the electric motor is mechanically connected to the air compressor, and the additional electric generator is connected to a wind engine. This allows you to optimize the rotational speeds of the shafts of the air compressor and wind turbine, which provides a combination of a minimum size and high efficiency of the units.

The present utility model will be better understood after considering the following description of the combined system for generating electricity, cold and heat with reference to the attached diagrams in FIGS. 1-3, where FIG. 1 shows a system diagram, FIG. 2 is a diagram of an electric power consumer, figure 3 is a diagram of a variant of the energy center.

The combined system for generating electricity, cold and heat contains (see FIG. 1) an air turbine 1 connected mechanically to an electric generator 2, and an air compressor 3 with a drive 4 made in the form of a wind turbine. In accordance with the utility model, the system additionally includes an ejector 5 with a high-pressure 6 and low-pressure 7 inputs, an accumulation capacity 8, an energy node 9, and an electricity consumer 10. The air compressor 3 is connected to the atmosphere by an input and an output 8 to the storage capacity and is energetically connected through the energy node 9 with a wind turbine 4, and the generator 2 is connected to the consumer of electricity 10. The high-pressure inlet 6 of the ejector 5 is connected to a source of compressed air 8, and the low-pressure inlet 7 is connected to the output of the air turbine 1.

The consumer of electricity 10 (figure 2) may include a distributor 11, a battery 12 and an electric heater 13, while the electric generator 2 is electrically connected through a distributor 11 with a battery 12, an electric heater 13 and an external network.

The power unit 9 (Fig. 3) may include an electric motor 14 and an additional electric generator 15, while the electric motor 14 is mechanically connected to the air compressor 3, and the additional electric generator 15 is connected to a wind turbine 4.

The system is as follows.

The air from the storage tank 8 (Fig. 1) through a high-pressure inlet 6 enters the ejector 5, where its temperature and pressure decreases, which becomes lower than atmospheric, which creates a vacuum at the low-pressure inlet 7. An air turbine 1, the inlet of which is connected to the atmosphere, and output - with a low-pressure input 7 of the ejector 5, due to the resulting pressure drop begins to rotate, giving up the generated power to the generator 2.

The flow of compressed air from the storage tank 8 is compensated by the supply of compressed air to the storage tank 8 from the air compressor 3, which through the power unit 9 receives power from the wind turbine 4 fed by wind energy.

In the electricity consumer 10 (FIG. 2), electric energy from the generator 2 enters the distributor 11, which directs the electric current to the external network, to the heat heater 13 or the battery 12.

In the energy center 9 (Fig. 3), the mechanical energy of the wind turbine 4 is transmitted to an additional electric generator 15, the generated electricity of which is supplied to the electric motor 14, the power of which is communicated to the air compressor 3. In this case, the rotational speeds of the wind turbine and the air turbine can be different.

As an example, we consider the results of a combined system for generating electricity, cold and heat with the following initial data:

1. The power of the air compressor is 8 kW.

2. The air pressure behind the compressor is 0.4 MPa.

3. The ambient temperature is 288K.

4. The compressor efficiency is 0.8.

The calculation results show that for given initial data, the accumulated capacity 8, and through it, to the input 6 of the ejector (Fig. 1), compressed air up to 0.4 MPa with a flow rate of 0.04 kg / s. Under the condition of continuous operation of compressor 3 and at a given air temperature in the storage tank, an electric generator generates 1 kW of electricity, and cold air with a cooling capacity of 1 kW (relative to the ambient temperature) leaves the ejector 5. The speed of cold air at the outlet of the ejector is close to 30 m / s, and the flow rate of this air is 0.12 kg / s, since the turbine passes air from the atmosphere with a flow rate of 0.08 kg / s.

Obviously, the generated electricity can be accumulated in the battery 12 with the help of the consumer, converted into heat using the heat heater 13, or fed into an external network.

It should be emphasized that the presence of the storage capacity allows the accumulation of wind energy and the use of compressed air for its intended purpose, regardless of the presence or absence of wind, which is difficult to ensure when a wind turbine generates electricity.

As a result of the operation of the combined system, for given parameters of the air compressor 3, 1 kW of electricity and 1 kW of cold air can be obtained, and if necessary, 1 kW of electricity can be converted into 1 kW of heat.

Thus, with the help of the proposed combined system, three energy flows can be obtained absolutely autonomously and environmentally friendly without using fuel: electricity, cold and heat.

The system is of interest to geologists, military, various remote regions with a high level of wind potential.

Claims (4)

1. A combined system for generating electricity, cold and heat, comprising an air turbine connected mechanically to an electric generator, and an air compressor with a drive, characterized in that the system further includes an ejector with high-pressure and low-pressure inputs, a storage capacitance, an energy center, and a power consumer, In this case, the drive is made in the form of a wind turbine and is connected to the air compressor through the energy center, the air compressor is connected to the atmosphere by the input, and the output is connected to the storage capacity, you the high-pressure input of the ejector is connected to the storage tank, and the low-pressure input is connected to the output of the air turbine, in addition, the electric generator is connected to the consumer of electricity. 2. The system according to claim 1, characterized in that the consumer of electricity contains a distributor, a battery and an electric heater, while the electric generator is connected through a distributor to a battery, an electric heater and an external network. 3. The system according to claim 1, characterized in that the power unit is made in the form of a shaft line, mechanically connecting the compressor to a wind turbine. 4. The system according to claim 1, characterized in that the power unit is made in the form of an electric motor and an additional electric generator, electrically connected to each other, while the electric motor is mechanically connected to the air compressor, and the additional electric generator is mechanically connected to the wind turbine.