RU2810329C1 - Geothermal power supply plant - Google Patents

Abstract

FIELD: energy.

SUBSTANCE: autonomous power and heat supply installations using the geothermal energy of the Earth, used to supply electrical and thermal energy. A geothermal power supply installation for consumers contains a first pump located in a well, the output of which is connected by pipelines through a filter for purifying geothermal water from rock and salt impurities to an evaporator, which is connected to an economizer, the output of which is connected to the input of the second pump, which is connected to a pipeline through a fine filter, the end of which is intended for immersion into the injection well. The output of the second pump through the first valve is connected to the first input of the heat supply circuit heater, the first output of which is connected through the second valve to the input of the fine filter. The evaporator is connected by a pipeline to a turbine, the output of which is connected to an extraction heater, the outputs of which are connected by pipelines to an economizer and to an air-cooled condenser, the output of which is connected to a third pump, the output of which is connected to the second input of the extraction heater. The second outlet of the circuit heater is used to supply heated water to the consumer of thermal energy. The input of the fourth pump is intended to receive cooled water from the thermal energy consumer, and the output of the fourth pump is connected by a corresponding pipeline to the second input of the heat supply circuit heater.

EFFECT: increased reliability of the geothermal installation.

1 cl, 1 dwg

Description

The invention relates to the field of energy, namely to autonomous power and heat supply installations using the geothermal energy of the Earth and can be used to supply electrical and thermal energy.

A known geothermal installation for power supply to consumers [RU 112749 U1, IPC F24J 3/08 (2006.01), publ. 01/20/2012], containing diesel generators and a geothermal binary thermal power plant, consisting of a production well connected by a pipeline to a geothermal separator. The separator is connected to pipelines for supplying separated water to the heat exchanger for preheating the coolant of the binary power plant and to the heat exchanger of the heating system, as well as a steam line for supplying separated steam to the evaporator of the binary power plant. A binary power plant that generates electrical energy consists of a steam turbine with a generator, a recuperator, a condenser, a circulation pump, a heat exchanger for preheating the coolant and an evaporator. A three-way valve is installed on the pipeline for supplying separated water to the heat exchanger of the heating system to regulate the supply of geothermal water to the heat exchanger circuit and the heating network by allowing the separated water to be divided into two controlled flows. The three-way valve is connected by one pipeline to the preheating heat exchanger of the binary power plant, and by a second pipeline to a mixing unit additionally installed on the pipeline for supplying separated water to the heat exchanger of the heat supply system, connected by a pipeline to the preheating heat exchanger of the binary power plant.

Such a geothermal installation for energy supply to consumers can only be used with high water parameters in the well, and the lack of water purification filters leads to the fact that untreated geothermal water is used in the preheating heat exchanger and evaporator.

A known geothermal installation for power supply to consumers [RU 2330219 C1, IPC F24J3/08 (2006.01), publ. 07/27/2008], selected as a prototype, which contains a circuit for removing the Earth’s heat, including a circulation pump, a riser and a downpipe located in the well, and a heat exchanger, an evaporation and condensation circuit of the turbine working fluid, containing an evaporator, a pump, a condenser, connected to the input to a turbine connected to an electric generator connected to a power consumer, a condenser cooling circuit with a cooler, a heat exchanger and a pump. The consumer's heat supply circuit contains circulation pumps, shut-off, control and intermediate valves, outlet and supply pipelines, which are connected to the output of the heat exchanger of the Earth's heat removal circuit, to the input of the thermal energy consumer and the output of the shut-off valve, the input of which is connected to the output of the high-potential heat exchanger of the heat pump, the input which is connected to the output of the circulation pump of the heat supply circuit of consumers, the input connected to the output of the thermal energy consumer. The input of the high-potential heat exchanger of the heat pump is connected to the input of the control valve, the output of which is connected by an outlet pipeline to the input of the circulation pump and the output of the valve of the Earth's heat removal circuit. The output of the circulation pump of the said circuit is connected to the downpipe. The input of the low-grade heat exchanger of the heat pump is connected to one end of the circuit formed by an intermediate valve and a circulation pump connected in series. The other end of this circuit is connected at the output of the condenser heat exchanger of the evaporation and condensation circuit of the working fluid of the turbine and at the input of the condenser cooling circuit valve, the output of which is connected to the cooler input, the output of the heat pump connected to the output of the low-potential heat exchanger and the input of the circulation pump of the condenser cooling circuit, and the output of this The pump is connected to the inlet of the condenser heat exchanger. The output of this condenser is connected to the input of the circulation pump of the evaporation and condensation circuit of the turbine working fluid, the input connected to the evaporator of this circuit. The riser pipe of the Earth's heat removal circuit is located inside a hermetically sealed downpipe. The outer surface of the riser pipe is thermally insulated and the outlet is connected to the inlet of the heat exchanger.

When operating such a geothermal installation, unprepared geothermal water is used, since it does not have water purification filters, which leads to corrosion and contamination of the heat exchanger, reducing the efficiency of heat exchange and the service life of the installation. In addition, a cooler is needed to operate the condenser.

The technical result of the invention is the creation of a geothermal installation for power supply to consumers with increased operational reliability.

The geothermal installation for power supply to consumers, as in the prototype, contains an evaporator, four pumps, a heat exchanger, two valves, a condenser, a turbine connected to an electric generator, and pipelines.

According to the invention, the output of the first pump located in the well is connected by pipelines through a filter for purifying geothermal water from rock and salt impurities to an evaporator, which is connected to an economizer, the output of which is connected to the input of the second pump, which is connected through a fine filter to a pipeline, the end of which is intended for for immersion into an injection well. The output of the second pump is connected through the first valve to the first input of the heat supply circuit heater, the first output of which is connected to the input of the fine filter through the second valve. The evaporator is connected by a pipeline to a turbine, the output of which is connected to a regenerative heater, the outputs of which are connected by pipelines to an economizer and to an air-cooled condenser, the output of which is connected to a third pump, the output of which is connected to the second input of the regenerative heater. The second output of the heat supply circuit heater serves to transfer heated water to the thermal energy consumer. The input of the fourth pump is intended to receive cooled water from the thermal energy consumer, and the output of the fourth pump is connected by a corresponding pipeline to the second input of the heat supply circuit heater.

Compared with the prototype, the use of a filter for purifying geothermal water from rock and salt impurities, and a filter for fine sediment purification makes it possible to increase the service life of the heat exchange equipment of the primary circuit of the binary cycle, as well as to reduce the amount of impurities entering the injection well. The installation does not require a cold water supply to condense the working fluid (refrigerant) of the second circuit of the binary cycle, due to the use of an air-cooled condenser.

The amount of used thermal energy of the coolant in the primary circuit of the binary cycle increases due to the use of a heater for the heating circuit.

In the second circuit of the binary cycle, thermal energy losses in the air-cooled condenser are reduced through the use of a regenerative heater.

Thus, the proposed design makes it possible to increase the reliability of the geothermal installation and provide consumers with thermal and electrical energy.

When using the invention, the service life of the economizer and evaporator is increased, and the geothermal source is not contaminated with scale and corrosion products due to the filtration of water from the well. Compared to the prototype, the installation can operate without a condenser circuit cooler, since air is used to remove residual thermal energy in the condenser, which significantly expands the use of the installation.

In fig. Figure 1 shows a technological diagram of a geothermal installation for power supply to consumers.

A geothermal power supply installation for consumers contains three technologically interconnected functional circuits.

The first circuit of the binary cycle contains a first pump 2 located in well 1, the output of which, through a filter for purifying geothermal water from rock and salt impurities 3, is connected by a pipeline to the evaporator 4 (I), which is connected to the economizer 5 (E). The output of the economizer 5 (E) is connected to the input of the second pump 6, at the output of which a fine filter 7 is installed, after which the end of the pipeline is immersed in the injection well 8.

The output of the second pump 6 through the first valve 9 is connected to the first input of the heat supply circuit heater 10 (PKT), the first output of which is connected through the second valve 11 to the input of the fine filter 7.

The second circuit of the binary cycle contains a series-connected economizer 5 (E) and an evaporator 4 (I), which is connected by a pipeline to a turbine 12, which is connected to an electric generator 13. The output of the turbine 12 is connected to a regenerative heater 14 (RP), the outputs of which are connected by pipelines to the economizer 5 (E) and with an air-cooled condenser 15. The output of the air-cooled condenser 15 is connected to the third pump 16, the output of which is connected to the second input of the regenerative heater 14 (RP).

The third circuit of the binary cycle contains a heat supply circuit heater 10 (PKT), the output of which is connected to a thermal energy consumer 17, after which a fourth pump 18 is installed, the output of which is connected by a pipeline to the input of the heat supply circuit heater 10 (PKT).

Before launching a geothermal installation to supply consumers with energy, the first circuit of the binary cycle is filled with coolant - high-temperature water from well 1, the second circuit is filled with a low-boiling medium - a refrigerant, for example, freon, the third circuit is filled with water from the heat supply circuit.

When the first pump 2 operates, the pressure necessary for circulation in the first circuit of the binary coolant cycle is created - high-temperature water from well 1, from the deep layers of the earth. The coolant through the pipeline from well 1 enters the filter for purifying geothermal water from rock and salt impurities 3. After cleaning, the coolant through the pipeline enters the evaporator 4 (I), where due to its thermal energy the working fluid evaporates in the second circuit of the binary cycle. From the outlet of the evaporator 4 (I), the coolant flows through the pipeline into the economizer 5 (E), where, during the heat exchange process, it heats the refrigerant to the saturation temperature. Next, the coolant is supplied through the pipeline to the inlet of the second pump 6, after which, under the required pressure, it is supplied to the fine filter 7 to remove impurities. After cleaning, the coolant is sent through the pipeline to the injection well 8.

The refrigerant, after being heated to a state of saturation in the economizer 5 (E) and converted into steam in the evaporator 4 (I), is sent through a pipeline to turbine 12, where the potential energy of the refrigerant is converted into mechanical rotation of the turbine shaft 12, which is connected to an electric generator 13, which converts the mechanical energy of shaft rotation into electrical energy. After the turbine 12, the refrigerant is sent to the regenerative heater 14 (RP), where, due to the residual thermal energy, the refrigerant condensed in the air-cooling condenser 15 is heated, and the third pump 16 is supplied through the regenerative heater 14 (RP) to the input of the economizer 5 (E), closing the second binary cycle circuit.

To supply the consumer of thermal energy 17, the first valve 9 is opened, through which the coolant enters the heater of the heat supply circuit 10 (PKT), where, in the process of heat exchange, the coolant gives up its heat to the working fluid of the third circuit of the binary cycle - water. After this, the coolant is directed through the open second valve 11 to the fine filter 7, and from there to the injection well 8. The water heated in the heat supply circuit heater 10 (PKT) is supplied through the pipeline to the thermal energy consumer 17, and then returned back to the heater by the fourth pump 18 heat supply circuit 10 (PKT), closing the third circuit of the binary cycle.

If there is no need to supply the thermal energy consumer 17, the valves 9 and 11 are closed, and the fourth pump 18 is turned off.

Claims (1)

Geothermal installation for power supply to consumers, containing an evaporator, four pumps, a heat exchanger, two valves, a condenser, a turbine connected to an electric generator, pipelines, characterized in that the output of the first pump located in the well is piped through a filter for purifying geothermal water from rock and salt impurities by pipelines connected to an evaporator, which is connected to an economizer, the output of which is connected to the input of a second pump, which is connected through a fine filter to a pipeline, the end of which is intended to be immersed in an injection well, and the output of the second pump is connected through the first valve to the first input of the heater of the heating circuit, the first output of which is connected through the second valve to the input of the fine filter, and the evaporator is connected by pipeline to the turbine, the output of which is connected to the regenerative heater, the outputs of which are connected by pipelines to the economizer and to the air-cooled condenser, the output of which is connected to the third pump, the output of which is connected to to the second input of the regenerative heater, while the second output of the heat supply circuit heater is used to transfer heated water to the thermal energy consumer, the input of the fourth pump is intended to receive cooled water from the thermal energy consumer, and the output of the fourth pump is connected by a corresponding pipeline to the second input of the heat supply circuit heater.