RU2805564C1 - Solar-wind power plant - Google Patents

Abstract

FIELD: renewable power sources.

SUBSTANCE: solar-wind power plant contains a pipe and a turbine with a generator. The turbine is located at the outlet of the pipe, which has a heat-absorbing coating. Along the working gas flow behind the pipe there is a heat exchanger-condenser cooled by ambient air with a drain pipeline for dumping the condensed liquid by gravity and creating a vacuum in the heat exchanger-condenser. An additional tank for collecting precipitation is connected to the drain pipeline, and an ejector is also installed to reduce the pressure in the heat exchanger-condenser.

EFFECT: simplification of the design and increase in the efficiency of the solar-wind power plant.

7 cl, 5 dwg

Description

The invention relates to renewable energy sources.

The “Mountain Air Traction Power Plant” is known, where warm air is heated in a vertical air duct deep in the earth and on the surface [1]. The vertical air duct, and the engine with the generator in it, is made in the form of a mine working, isolated from the entry of groundwater into it, the mouth of which on the earth's surface is the outlet of the air duct, and the heater is a geothermal reservoir, represented by dry warm rocks. The device is equipped with an additional heat-insulated air duct. The disadvantage of this device is the need to drill a well to great depths and organize heat exchange between the rock and the air duct at great depths.

A known device is the “Energy Tower”, located in the center of a greenhouse heated by the sun, in the center of which there is a tower (pipe) 800 m high. Electrical energy is generated by generators with turbines rotating due to the difference in the density of air heated by a solar collector and atmospheric pressure at an altitude of 800 m [2]. The disadvantage of the invention is the complexity and high cost of constructing a pipe 800 m high.

The purpose of the invention is to simplify the design and increase the efficiency of a solar-wind power plant

A solar-wind power plant contains a pipe and a turbine with a generator, the turbine is located at the outlet of a pipe having a heat-absorbing coating; downstream of the working gas flow behind the pipe there is a heat exchanger-condenser cooled by external air with a drain pipeline for discharging the condensed liquid by gravity and creating a vacuum in the heat exchanger-condenser , an additional container for collecting sediment is connected to the drain pipeline, and an ejector is installed to reduce the pressure in the heat exchanger-condenser. A diffuser is located behind the condenser heat exchanger. The drain pipeline is located inside the working gas pipeline. Fuel injectors are installed in front of the turbine, supplying fuel for combustion, an air blower is installed at the entrance to the pipe, which is cooled by condensed liquid through the blower cooling pipeline connected to the drain pipe through shut-off and control valves, a fairing and an inlet guide vane are located in front of the turbine, and behind The turbine houses the output guide vane.

A decrease in temperature in the heat exchanger-condenser leads to a decrease in pressure, an increase in the degree of expansion at the turbine, which increases its power, and at sufficiently high temperatures, moisture condensation occurs, which, in turn, further reduces the pressure after the turbine and further increases the degree of expansion at the turbine and its power. The use of additional capacity also leads to a decrease in pressure after the turbine and an increase in the expansion ratio and power of the turbine, and the installation of an ejector enhances the process of increasing the expansion ratio at the turbine and its power. Taking some of the liquid to cool the supercharger will increase its efficiency. The supply of fuel to the injectors and its combustion will lead to an increase in the efficiency of the turbine and a continuous supply of electricity to the consumer.

The technical result is to simplify the design and increase the efficiency of the solar-wind power plant.

In fig. Figure 1 shows the proposed device for a solar-wind power plant, containing a mountain slope 1, supports 2, pipe 3, fairing 4, inlet guide vane 5, turbine 6, generator 7, exhaust pipe 8, fuel injectors 9, fuel supply pipeline 10. On the slope 1 on the supports 2 there is a solar collector 3, inside of which there is a fairing 4 with an inlet guide vane 5, behind which a turbine 6 is installed connected by a generator 7, and then an exhaust pipe 8 is installed behind it. Fuel injectors 9 connected to a pipeline can be installed in front of the turbine 6 fuel supply 10.

The solar-wind power plant operates as follows (Fig. 1): outside air enters pipe 3, which has a heat-absorbing coating on the outside, located on supports 2, and is heated. The air is accelerated due to the location of the fairing 4 in front of the inlet guide vane 5, swirls in it, and enters the turbine 6, which rotates the generator 7. After the pipe 3 behind the generator, the air enters the exhaust pipe 8, and then into the atmosphere. If necessary, fuel injectors 9 can be used to supply fuel to the pipeline 10 and further burn it in order to ensure stable power generation. In addition, during combustion, the temperature of the air used for combustion increases, which increases the efficiency of its use, because it operates on turbine 6 with a higher utilization factor. On a conventional wind turbine, its utilization factor is 0.3-0.45, and on turbine 6 with high gas temperatures it is 0.8 or more [3].

This device allows you to avoid the construction of a high-rise expensive pipe, simplify and reduce the cost of a solar-wind power plant; reduce the area used for a solar-wind power plant, eliminate the multiplier, increase the efficiency of using solar rays in the morning and evening due to their perpendicular incidence on the pipe and the constancy of the area that receives the rays as the product of diameter and length.

In fig. 2, in contrast to FIG. 1, an air blower 11 is installed at the inlet of pipe 3.

Outside air enters the inlet pipe 3, is compressed in the air blower 4, then, passing through the pipe 3, is heated and, already in a heated state, enters the inlet guide vane 5, and then into the turbine 6, which rotates the generator 7, after which the air enters into the exhaust pipe 8. If necessary, fuel injectors 9 can be used to ensure stable power generation. Ejector-type injectors and the fuel torch from them further accelerate the working gases. Air blower 11 increases the air flow through the pipe. Installing an air blower in front of pipe 3, in contrast to its direct location in front of turbine 6, provides the compressor with a lower air temperature, which reduces its power. Thus, when the temperature drops by 5°C, the compressor power decreases by 2%. The air temperature after pipe 3 is about 140°C, which will provide a significant increase in compressor power, in contrast to installing it in front of the pipe.

In fig. Figure 3 shows the air blower 11, pipe 3, inlet guide vane 5, turbine 6, output guide vane 12, heat exchanger-condenser 13, drain pipe 15, blower cooling pipe 17, shut-off and control valves 16, diffuser 14.

According to FIG. 3 the device operates as follows.

The air enters the air blower 11, is heated in the pipe 3, then enters the input guide vane 5, then into the turbine 6, the output guide vane 12, then enters the heat exchanger-condenser 13, which is cooled by external cold air, as a result of which the air temperature inside decreases heat exchanger-condenser, its volume decreases and pressure drops in accordance with the equation of state pv=RT. Reducing the air temperature after the turbine in the heat exchanger-condenser 13 from 373 K to 300 K results in a decrease in pressure by 1.25 times. Then, during the cooling process, vapor condenses, which also reduces the air pressure behind the turbine and, in turn, increases its power. The condensed liquid from the heat exchanger-condenser 13 through the drain pipeline 15 is discharged by gravity to the lower level, additionally creating a vacuum in the heat exchanger-condenser 13 and in front of the turbine 3, thereby increasing the power of the turbine 6 (generator 7). Thus, a decrease in pressure occurs in the condenser heat exchanger due to a decrease in the air temperature in it, and, in addition, condensation of moisture vapor, which improves with a decrease in pressure and temperature.

If necessary, this liquid can be used through one of the shut-off and control valves 16 to cool the air blower 11 and can then be supplied through the blower cooling pipeline 17 through the discharge pipeline 18 for technical needs. The amount of liquid for cooling the supercharger is regulated by shut-off and control valves 16.

In fig. Figure 4 shows a diagram of the use of atmospheric air and additional rarefaction of air (gases) in the heat exchanger-condenser 13 and in front of the turbine 6 due to the additional vacuum after the turbine 6 created by the flow of water flowing from the additional tank for collecting sediment 19. This increases the space occupied by workers gases 22 and the pressure in the heat exchanger-condenser decreases.

The device contains an air blower 11, a pipe 3, an input guide vane 5, a turbine 6, an output guide vane 12, a heat exchanger-condenser 13, a drain pipeline 15, a supercharger cooling pipeline 17, shut-off and control valves 16, a diffuser 14, fuel injectors 9, an additional a container for collecting sediment 19, connected to a drain pipeline 15.

The air enters the supercharger 11, is heated in the pipe 3, then enters the input guide vane 5, then into the turbine 6, the output guide vane 12, then enters the heat exchanger-condenser 13, which is cooled by external cold air, as a result of which the air in the heat exchanger is cooled - condenser and moisture loss and, then, through the diffuser 14, which increases the pressure, is released into the atmosphere. A decrease in air temperature in the heat exchanger-condenser 13 and moisture condensation leads to a decrease in air pressure behind the turbine and an increase in its power. The condensed liquid from the heat exchanger-condenser 13 through the drain pipeline 15 is discharged by gravity to the lower level, additionally creating a vacuum in the heat exchanger-condenser 13 in front of the turbine 6 and, additionally, increasing the power of the turbine 6 (generator 7). The heat from the exhaust gases is used in winter to melt snow in the atmosphere and in an additional tank that provides liquid flow.

A scheme using the heat of exhaust gases to heat and collect atmospheric precipitation makes it possible to increase the vacuum behind the turbine and, as a result, its power. The sediment collection tank 19 can have large dimensions, which will increase the efficiency of the installation and its power.

With large sizes of the sediment collection tank 19, the installation can operate continuously due to year-round collection. For example, an average of 960 mm of precipitation falls on Ai-Petri per year. On a fenced surface, which plays the role of an additional tank 19, with an area of 1 km ² , almost 10 ⁶ m ³ of water can be collected per year and water can be drained from it into the drain pipeline 15, and, accordingly, the creation of a vacuum in front of the turbine can be year-round. The solar-wind installation will also operate at night without the sun due to a decrease in pressure behind the turbine created by the flow of water from tank 19 into the drain pipeline 15.

In addition to FIG. 4, the device contains an ejector 20 and a gas pipeline 21 for working gases 22.

In fig. 5 shows a diagram of the use of the ejector 20 to create additional vacuum in the gas pipeline 21 of the working gases 22 at the outlet of the turbine 6, which increases its efficiency. The location of the drain pipeline 15 inside the gas pipeline 21 of the working gases 22 will allow the working gases to be cooled like a “pipe-in-pipe” heat exchanger, which will also help to increase the vacuum due to a decrease in temperature.

The ejector 20 creates additional vacuum in the gas pipeline 21 of the working gases 22, and, as a result, behind the turbine, which will also increase its efficiency.

Links to sources

1. RF patent RU 2 444 645 “Mountain air-traction power plant”.

2. https://ru.wikipedia.org/wik;i/Energy tower

3. Special issues of renewable energy: / V.A. Safonov, P.N. Kuznetsov, V.V. Kuvshinov and others; edited by Professor Doctor of Technical Sciences V.A. Safonova. - Sevastopol: Kolorit, 2017. - 358 p.

Claims (7)

1. A solar-wind power plant containing a pipe and a turbine with a generator, characterized in that the turbine is located at the outlet of a pipe having a heat-absorbing coating; downstream of the working gas flow behind the pipe there is a heat exchanger-condenser cooled by external air with a drain pipeline for discharging the condensed liquid by gravity and creating a vacuum in the heat exchanger-condenser, an additional container for collecting sediment is connected to the drain pipeline, and an ejector is installed to reduce the pressure in the heat exchanger-condenser. 2. Solar-wind power plant according to claim 1, characterized in that a diffuser is located behind the heat exchanger-condenser. 3. Solar-wind power plant according to paragraphs. 1, 2, characterized in that the drain pipeline is located inside the working gas pipeline. 4. Solar-wind power plant according to paragraphs. 1-3, characterized in that fuel injectors are installed in front of the turbine, supplying fuel for combustion. 5. Solar-wind power plant according to paragraphs. 1-4, characterized in that an air blower is installed at the entrance to the pipe. 6. Solar-wind power plant according to paragraphs. 1-5, characterized in that the air blower is cooled by condensed liquid through the blower cooling pipeline connected to the drain pipeline through shut-off and control valves. 7. Solar-wind power plant according to paragraphs. 1-6, characterized in that a fairing and an inlet guide vane are located in front of the turbine, and an output guide vane is located behind the turbine.