RU117512U1 - ELECTRIC POWER AND HEAT INSTALLATION - Google Patents

Abstract

1. An installation for generating electricity and heat, containing a source of high-pressure gaseous fuel, a turbine and mechanically connected to the turbine, at least one power consumer, an ejector with high-pressure and low-pressure inputs, a consumer of a gas-air mixture and a valve, where the high-pressure inlet of the ejector is connected through tap to the source of gaseous fuel, the turbine is connected with the inlet to the atmosphere, and the outlet - with the low-pressure inlet of the ejector, the outlet of the ejector is connected to the consumer of the gas-air mixture, characterized in that the installation additionally contains a room, a water-heating boiler with a hot gas inlet and water inlet and outlet, a consumer heat, a room heater, shut-off valves and a pumping device, and the consumer of the gas-air mixture is made in the form of a combustion chamber, an ejector with high-pressure and low-pressure inputs, a turbine with a power consumer and a room heater are located in the room, the outlet of the combustion chamber is connected to the input ohm of the hot gas of a water heating boiler, the water inlet of the water heating boiler is connected to the outlets of the heat consumer and the room heater, and the water outlet of the water heating boiler through the pumping device and shut-off valves is connected to the inlets of the heat consumer and the room heater. ! 2. Installation according to claim 1, characterized in that the power consumer is made in the form of an electric generator. ! 3. Installation according to claim 1, characterized in that the power consumer is made in the form of a compressor. ! 4. Installation according to claim 1, characterized in that the power consumer is made in the form of a water pump. ! 5. Installation according to claim 1, different

Description

The proposed utility model relates to power engineering, in particular, to the field of small energy.

Known gas ejector turbine unit for generating electricity and cold (see the journal "Conversion in mechanical engineering", No. 1, 2003, p. 42-45, Fig. 1). It uses compressed air as a working fluid, which is sent to the high-pressure inlet of the ejector. The low-pressure inlet of the ejector is connected to the atmosphere through a turbine. The turbine is connected to the electric generator along the shaft.

The unit allows you to receive electricity and cold air (at the outlet of the ejector). The disadvantage of the unit is its limited use, since it can use only compressed air as a working fluid.

Known installation for cooling the air of the room (Patent for utility model No. 35668, with a priority of 10/15/2003). In it, a turbine with a water pump driven by it and an ejector are placed indoors. Compressed air cooling cools the room air.

The installation has better efficiency, however, it can also use only compressed air as a working fluid and does not generate electricity.

The disadvantage of these solutions is eliminated in the universal installation for reducing the pressure of the working environment (RF Patent for utility model No. 15205 of 04/26/2000), adopted as a prototype. The installation comprises a source of high-pressure combustible gas, an ejector with high-pressure and low-pressure inlets, a turbine with a power consumer in the form of an air compressor, a gas-air mixture consumer, and a crane. The high-pressure inlet of the ejector is connected through a tap to a source of combustible gas. The low-pressure inlet of the ejector is connected through the turbine to the atmosphere. The outlet of the ejector is connected to the consumer of the gas-air mixture.

The installation allows you to use not only air, but also other high-pressure gas, for example, natural gas. However, the location of the turbine and ejector outside the premises can lead to:

- freezing of the flow part of the turbine and reducing its efficiency,

- unacceptably low temperature of the support nodes of the installation with deterioration of lubrication of the bearings,

- the formation of gas hydrate at the outlet of the ejector, which affects the reliability and efficiency of the installation.

The utility model is based on solving the problem of increasing the reliability of expanding the applicability range of a plant by generating thermal and mechanical energy from combustible gaseous waste of various types and using it, if necessary, in remote and inaccessible places in relatively small volumes.

The problem is solved in that the installation contains a source of gaseous high-pressure fuel, a turbine and mechanically connected with the turbine, at least one power consumer, an ejector with high-pressure and low-pressure inlets, a gas-air mixture consumer and a crane. The high-pressure inlet of the ejector is connected through a tap to a source of gaseous fuel. The input turbine is connected to the atmosphere, and the output is connected to the low-pressure input of the ejector. The ejector output is connected to the gas-air consumer.

New in the utility model is that the installation additionally contains a room, a water boiler with a hot gas inlet and a water inlet and outlet, a heat consumer, a room heater, shut-off valves and a booster device. The consumer of the gas-air mixture is made in the form of a combustion chamber. An ejector with high-pressure and low-pressure inputs, a turbine with a power consumer and a room heater are located in the room. The output of the combustion chamber is connected to the inlet of the hot gas of the boiler. The water inlet of the boiler is connected to the outputs of the heat consumer and the room heater. The water outlet of the boiler through the booster device and shut-off valves is connected to the inputs of the heat consumer and the room heater.

With this installation design:

- the presence of the room and the placement of a turbine, an ejector with high-pressure and low-pressure inputs and a room heater in it allows to supply elevated temperature air to the turbine input and to the low-pressure input of the ejector, which increases the mechanical energy supplied to the power consumer and increases the reliability of the installation;

- a water heating boiler with hot gas inlet, water inlet and outlet allows heating water in the boiler due to the heat coming from the combustion chamber and directing it to the heat consumer, which increases the efficiency of the installation;

- the room heater allows you to provide a room air temperature greater than in the environment, which increases the energy received by the power consumer at the same gaseous fuel consumption, and also increases the reliability of the installation;

- shut-off valves allow you to adjust the temperature in the room and the amount of heat entering the heat consumer, which allows more rational use of gaseous fuel to obtain the amounts of heat and energy required by consumers;

- a booster device provides water circulation, ensuring the reliability of heat supply to the heat consumer and the room heater.

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

The power consumer can be made in the form of an electric generator.

The power consumer can be made in the form of a compressor. The power consumer can be made in the form of a water pump. The water heating boiler can be made in the form of a submersible water heating boiler.

The source of gaseous fuel may contain natural gas, in particular, the source of gaseous fuel may be a high-pressure natural gas pipeline.

The gaseous fuel source may comprise gas generated from solid fuels, such as wood.

The gaseous fuel source may contain gas from refinery waste.

The gaseous fuel source may contain gas from chemical waste.

The source of gaseous fuel may contain gas from waste from waste processing.

The pumping device can be made in the form of a pump.

All the above signs expand the consumer properties of the installation.

Thus, the problem posed in the utility model is solved.

The design of the installation for generating electricity and heat has been developed. The range of applicability of the installation has been expanded by generating thermal and mechanical energy from gaseous waste of various types and its use, if necessary, in remote and inaccessible places in relatively small volumes.

The present utility model will be better understood after consideration and subsequent description of the circuit shown in the drawing.

The installation for generating electricity and heat (see FIG.) Comprises a source of high pressure gaseous fuel 1, a turbine 2 and mechanically connected to the turbine 2, at least one power consumer 3, an ejector 4 with a high-pressure 5 and low-pressure 6 inputs, a gas-air mixture consumer 7 and valve 8. The high-pressure input 5 of the ejector 4 is connected through the valve 8 to the source of gaseous fuel 1. The turbine 2 is connected to the atmosphere by the input and the output to the low-pressure input 6 of the ejector 4. The output of the ejector 4 is connected to the consumer of the gas mixture 7 The installation additionally contains a room 9, a water boiler 10 with a hot gas inlet 11 and an inlet 12 and a water outlet 13, a heat consumer 14, a room heater 15, shut-off valves 16, 17 and a booster device 18. The gas-air mixture consumer 7 is made in the form of a combustion chamber 7, an ejector 4 with a high-pressure 5 and a low-pressure 6 inputs, a turbine 2 with a power consumer 3 and a room heater 15 are placed in the room. The output of the combustion chamber is connected to the inlet of the hot gas 11 of the boiler 10. The water inlet 12 of the boiler 10 is connected to the outputs of the heat consumer 14 and the room heater 15. The outlet of the water 13 of the boiler 10 through the booster device 18 and shut-off valves 16 and 17 are connected to the consumer inlets heat 14 and space heater 15.

Installation for generating electricity and heat operates as follows.

Before starting the installation, the taps 16 and 17 are opened and the pumping device 18 is turned on. The valve 8 is opened and gaseous fuel from the source 1 through the valve 8 and the high-pressure inlet 5 enters the ejector 4, where, due to the vacuum, the heated air is sucked through the turbine 2 and the low-pressure inlet 6 from rooms 9 with atmospheric pressure. The pressure drop generated by rarefaction on the turbine 2 spins it, work on the shaft is formed, which is transmitted to the power consumer 3. In the ejector 4, gaseous fuel and air are mixed with the formation of a combustible mixture, which is sent to the combustion chamber 7. In the combustion chamber 7 is combustible the mixture is ignited and hot gas is formed that enters through the inlet 11 into the boiler 10, where it heats the water. The water heated in the boiler 10 through the water outlet 13, the booster device 18 and the taps 16 and 17 enters the heat consumer 14 and the room heater 15, from where, through the inlet 12, the cooled water again enters the boiler 10 - this is how the water circulates in the installation.

By adjusting the crane 8, the flow of gaseous fuel is a change in the amount of power supplied to the consumer 3, and the available heat, which can be obtained by the heat consumer 14 and the space heater 15.

By adjusting the taps 16 and 17, the flow of water can provide an optimal distribution of heat between the heat consumer 14 and the room heater 15.

The proposed technical solution can find useful application for the modernization of boiler plants (KU) operating on natural gas (GHG) with a pressure of about 0.2-0.25 MPa. This level of GHG pressure in typical cases is achieved using gas control points (HF) with an inlet pressure of natural gas equal to 0.6 MPa. When upgrading the KU, part of the GHG flow rate with a pressure of 0.22 MPa can be used to additionally generate electricity and heat.

Calculations show that it is possible to achieve the power of an electric generator mechanically coupled to a turbine equal to 1 kW and thermal power equal to 1 MW, with a rarefaction of air behind the turbine equal to 0.03 MPa, with the following parameters:

- the total pressure of the steam generator at the inlet to the high-pressure inlet of the ejector is 0.22 MPa,

- the total pressure of the gas-air mixture at the outlet of the ejector is 0.11 MPA,

- GHG mass flow rate - 0.025 kg / s,

- indoor air temperature - 288 K,

- air temperature behind the turbine - 265 K,

- air flow through the turbine - 0.05 kg / s.

It should be noted that the gas-air mixture has an excess pressure (against atmospheric) equal to ≈7 kPa, which is sufficient to overcome the hydraulic resistance of the line from the ejector to the boiler with immersion heating of the water and to overcome the column of the water layer with a height of 0.3 m. In addition, the gas-air mixture is already partially (12%) prepared for homogeneous combustion, since an additional 90% of air flow is required.

The widespread introduction of the proposed utility model in the national economy can increase the level of reliability of boiler plants and their effectiveness.

Claims (11)

1. Installation for generating electricity and heat, containing a source of gaseous high-pressure fuel, a turbine and mechanically connected to the turbine, at least one power consumer, an ejector with high-pressure and low-pressure inputs, a gas-air mixture consumer and a crane, where the high-pressure input of the ejector is connected through the tap to the source of gaseous fuel, the turbine is connected to the atmosphere by the inlet, and the outlet is connected to the low-pressure inlet of the ejector, the outlet of the ejector is connected to the consumer of the gas-air mixture, characterized in the installation further comprises a room, a hot water boiler with hot gas inlet and outlet, a heat consumer, a room heater, shut-off valves and a booster device, the gas-air mixture consumer being made in the form of a combustion chamber, an ejector with high-pressure and low-pressure inputs, a turbine with a consumer power and a room heater are located in the room, the output of the combustion chamber is connected to the inlet of the hot gas of the boiler, the water inlet of the boiler and connected to the heat consumer and the heater outputs the room and the outlet of water through a hot water boiler booster device and the lock shield valves connected with the heat consumer inputs and heater premises. 2. Installation according to claim 1, characterized in that the power consumer is made in the form of an electric generator. 3. Installation according to claim 1, characterized in that the power consumer is made in the form of a compressor. 4. Installation according to claim 1, characterized in that the power consumer is made in the form of a water pump. 5. Installation according to claim 1, characterized in that the boiler is made in the form of a submersible water heating boiler. 6. Installation according to claim 1, characterized in that the source of gaseous fuel contains natural gas, in particular, the source of gaseous fuel is a high-pressure natural gas pipeline. 7. Installation according to claim 1, characterized in that the source of gaseous fuel contains gas generated from solid fuels, such as wood. 8. Installation according to claim 1, characterized in that the source of gaseous fuel contains gas from waste oil refining. 9. Installation according to claim 1, characterized in that the source of gaseous fuel contains gas from chemical waste. 10. Installation according to claim 1, characterized in that the source of gaseous fuel contains gas from waste from waste processing. 11. Installation according to claim 1, characterized in that the booster device is made in the form of a pump.