RU2330219C1 - Geothermal installation for supply of energy to consumers - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: geothermal installation comprises an Earth heat extraction line, a fume and condensation line of a working body of a turbine, a condenser cooling line and a consumer heat supply line. Out of the Earth heat extraction line heat is transferred into the fume and condensation line of a working body of a turbine and also is directly transferred to the consumer heat supply line. The consumer heat supply line is connected with a condenser cooling line via a heat pump.

EFFECT: invention expands features and improves processing characteristics of a power cycle considering fluctuations in modes of energy load consumption.

1 dwg

Description

The invention relates to the field of energy, in particular to installations of autonomous electric and heat supply based on the deep heat of the Earth by consumers of facilities where there is no possibility of supplying heat and electric energy from an external power system.

A device is known that implements a method of extracting geothermal heat (see US Pat. RU No. 2288413, IPC ⁷ F24J 3/08, published November 27, 2006), comprising a heat pump, a heat consumer, a cold consumer, and a well with a casing inside it, inside a lifting pipe is installed.

The disadvantage of this device is that the device does not allow the generation of electrical energy, that is, it has limited functionality.

Known steam turbine installation for a geothermal station (see US Pat. RU No. 2246010, IPC ⁷ F01K 21/04, published 02.10.2005), which contains the Earth heat removal circuit, including a circulation pump, a lifting production pipe, located in one well, and a lowering pipe an injection pipe located in another well, and a heat exchanger, an evaporator, an evaporation and condensation circuit of a turbine working fluid, comprising an evaporator, a pump, a condenser inlet connected to a turbine connected to an electric generator to connect an electrical supply to a consumer eniya, condenser cooling circuit with coolant, a heat exchanger and a pump, downhole heat exchanger, circulation pump, heat exchanger, an expander inlet and outlet conduit of the cooling water. The removal of deep heat occurs in an open cycle, production and injection wells are at a distance from each other.

The disadvantage of this installation is that it has limited functionality, as it is designed to produce only electric energy, the installation also has high corrosion rates and can only work in the presence of hydrothermal deposits.

An object of the invention is to expand the functionality, improve the technological characteristics of the energy cycle, taking into account changes in consumer load conditions.

This problem is solved by the fact that the well-known geothermal installation containing the Earth’s heat removal circuit, including a circulation pump, a lift pipe and a drain pipe located in the borehole, and a heat exchanger, an evaporation and condensation circuit of the turbine’s working fluid, containing an evaporator, a pump, and a condenser connected to a turbine connected to an electric generator connected to a power supply consumer, a condenser cooling circuit with a cooler, a heat exchanger and a pump, it is equipped with a consumer heat supply circuit, neighing circulation pumps, shutoff, control and intermediate valves, outlet and supply pipelines, while the supply pipe is connected to the heat exchanger output of the heat removal circuit of the Earth, to the input of the heat energy consumer and the output of the shutter valve, the input of which is connected to the output of the high-potential heat pump heat exchanger, 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 consumer of thermal energy, while the input is high a potential heat exchanger of the heat pump is connected to the input of the control valve, the outlet of which is connected by a discharge pipe to the input of the circulation pump and the output of the valve of the earth heat removal circuit, while the output of the circulation pump of this circuit is connected to the down pipe, the input of the low-potential heat pump heat exchanger is connected to one end of the circuit, formed by a series-connected intermediate valve and a circulation pump, while the other end of this circuit is connected to the heat exchange output the condenser nickel of the evaporation and condensation circuit of the turbine’s working fluid and the gate valve’s inlet of the condenser cooling circuit, the output of which is connected to the cooler’s input, the output connected to the output of the low-grade heat exchanger of the heat pump and the input of the circulation pump of the condenser cooling circuit, and the output of this pump is connected to the input of the condenser heat exchanger, output this condenser is connected at the inlet of the circulation pump of the evaporation and condensation circuit of the turbine working fluid, the input connected to the evaporator m of this circuit, the lifting pipe of the Earth's heat removal circuit is located inside a hermetically sealed lowering pipe, while the external surface of the lifting pipe is thermally insulated and connected to the inlet of the heat exchanger.

The invention is illustrated in the drawing, which shows the technological scheme of a steam turbine installation for a geothermal power plant.

A geothermal installation for energy supply to consumers contains a heat removal circuit of the Earth, an evaporation and condensation circuit of the turbine working fluid, a condenser cooling circuit and a consumer heat supply circuit.

The heat removal circuit of the Earth contains a downcomer 1 located in the well 2 and hermetically closed, for example, by a partition 3 from the deep soil side of the well 2. Inside the downcomer 1, there is a coaxial lift tube 4, the outer side of which has a heat-insulated layer 5. The lift tube 4 is piped 6 is connected to the input of the heat exchanger 7, the output of which is connected to the input of the valve 8. The output of the valve 8 is connected to the input of the circulation pump 9, the output of which is connected to the lowering pipe 1.

The evaporation and condensation circuit of the working fluid of the turbine contains an evaporator 10, the output of which is connected to the turbine 11, on the shaft 12 of which there is a generator 13 connected to consumers of electric energy 14, while the output of the turbine 11 is connected to the input of the condenser 15, the output of which is connected to the circulation pump 16 connected to the input of the evaporator 10.

The consumer heat supply circuit includes a heat pump 17 having low potential 18 and high potential 19 heat exchangers. The output of the high potential heat exchanger 19 is connected to the input of the control valve 20 and the output of the circulation pump 21 connected to the consumer of thermal energy 22, the input of which is connected to the output of the shutoff valve 23 connected to the output of the high potential heat exchanger 19 of the heat pump 17. The input of the consumer of thermal energy 22 by the supply pipe 24 connected to the inputs of the heat exchanger 7 and the valve 8 of the circuit heat removal of the Earth. The control valve 20 by a return pipe 25 is connected to the output of the valve 8 and the input of the circulation pump 9 of the heat removal circuit of the Earth. The output of the low-potential heat exchanger 18 of the heat pump 17 is connected to the inlet of the circulation pump 26 and the output of the cooler 27 of the condenser cooling circuit, which further comprises a heat exchanger 28, the output of which is connected to the input of the valve 29, the output of which is connected to the input of the cooler 27.

At the input of the low-potential heat exchanger 18, one end of the circuit formed by the intermediate valve 30 and the circulation pump 31 of the consumer heat supply circuit connected in series is connected, the other end of the circuit is connected at the output of the heat exchanger 28 and the inlet of the valve 29 of the condenser cooling circuit.

Geothermal installation of energy supply to consumers works as follows.

Before starting, the Earth's heat removal circuit is filled with a liquid heat carrier, for example, water; the circuit of evaporation and condensation of the working fluid of the turbine is filled with a low-boiling working agent, for example, freon or its mixture; the condenser cooling circuit is filled with water, the consumers heat supply circuit is filled with the same coolant as the Earth heat removal circuit.

When the circulation pump 9 is formed, the circulation of the coolant in the heat removal circuit of the Earth. On the lowering pipe 1, the coolant moves to the baffle 3 and is heated from the deep soil of the well 2, then the coolant rises up the lift pipe 4.

Thermal insulation 5 significantly reduces heat transfer between the warm coolant stream located in the riser pipe 4 and the cold coolant stream located in the lower pipe 1. Next, the heated coolant flows through the pipe 6 to the heat exchanger 7, where heat is exchanged between the coolant of the Earth’s heat removal circuit and the working fluid turbines 11 of the evaporation and condensation circuit. From the output of the heat exchanger 7, the coolant enters the circulation pump 9 of the Earth's heat removal circuit, after which it returns to the lowering pipe 1.

In the evaporator 10, steam is generated from the turbine’s working fluid, which, from the output of the evaporator 10, enters the turbine 11 input, which drives the shaft 12 connected to the generator 13, from which electric power is supplied to the electric energy consumer 14.

From the turbine 11, the spent steam of the turbine working fluid is supplied to the input of the condenser 15, in which the steam condenses. The resulting condensate of the working fluid of the turbine from the output of the condenser 15 enters the circulation pump 16 of the evaporation and condensation circuit of the working fluid of the turbine, and after it is fed to the evaporator 10.

When you turn on the pump 26, the circulation of water in the cooling circuit of the condenser begins. The water heated in the heat exchanger 28 through an open valve 29 enters the cooler 27, after which it is supplied to the circulation pump 26 and then to the heat exchanger 28.

To provide the consumer of thermal energy 22, the heat pump 17 is simultaneously turned on, the intermediate valve 30 opens, the pump 31 is turned on, the valve 29 is partially closed and the pump 21 is turned on. Heated water from the heat exchanger 28 enters the pump 31, then flows through the valve 29 and is supplied to the low-potential heat exchanger 18 of the heat pump 17, where it is cooled. Chilled water enters the pump 26 and then is supplied to the heat exchanger 28 of the condenser 15.

When the pump 21 is in circulation, a consumer circulates in the heat supply circuit. From the pump 21, water is supplied to a high-potential heat exchanger 19, where it is heated, heated water flows through the shutoff valve 23 and is supplied to the consumer of thermal energy 22.

If there is a lack of heat at the consumer, the valve 8 partially closes and the shutter valve 23 closes completely, the control valve 20 opens, the valve 29 opens, the heat pump 17 is turned off and the intermediate 30 is closed, the pump 31 is turned off, which leads to the cessation of water movement in low-potential 18 and high-potential 19 heat exchangers. Then, the valve 8 of the Earth’s heat removal circuit is partially closed, the heat carrier from the heat exchanger 7 enters through the supply pipe 24 to the consumer of heat energy 22, after which the cooled heat carrier is directed to the pump 21, then passes the control valve 20 and returns via the return pipe 25 through the pump 9 from the circuit thermal energy consumer into the Earth heat removal circuit.

In such an installation, the selection of the Earth's deep heat proceeds in a closed loop.

The use of the invention can significantly reduce the cost of pumping the coolant and increases the shelf life of the heat exchange equipment on the surface, the installation can work outside of hydrothermal deposits. Such an invention allows to expand the functionality of the installation due to the simultaneous environmentally friendly production of two types of energy - thermal and electrical. In addition, there is a useful use of residual heat after the evaporation and condensation circuit of the turbine working fluid, taking into account the changing modes of heat energy consumers.

Claims (1)

A geothermal installation for supplying energy to consumers, comprising the Earth’s heat removal circuit, 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’s working fluid, containing an evaporator, pump, condenser connected inlet to a turbine connected to an electric generator connected to the consumer of power supply, the cooling circuit of the condenser with a cooler, heat exchanger and pump, characterized in that it is equipped with a heat supply circuit a fuse containing circulating pumps, a shutoff, regulating and intermediate valve, a discharge and a supply pipe, while the supply pipe is connected to the output of the heat exchanger of the heat removal circuit of the Earth, to the input of the heat energy consumer and the output of the shutter valve, the input of which is connected to the output of the high-potential heat pump heat exchanger the input of which is connected to the output of the circulation pump of the consumer heat supply circuit, the input connected to the output of the consumer of thermal energy, while the input of the high potential heat exchanger of the heat pump is connected to the input of the control valve, the outlet of which is connected by a discharge pipe to the input of the circulation pump and the output of the valve of the Earth heat removal circuit, while the output of the circulation pump of this circuit is connected to the down pipe, the input of the low potential heat exchanger of the heat pump is connected to one end of the circuit formed by series-connected intermediate valve and circulation pump, while the other end of this circuit is connected to the output ode to the condenser heat exchanger of the evaporator and condensation circuit of the turbine’s working fluid and at the inlet of the valve of the condenser cooling circuit, the output of which is connected to the cooler inlet, connected to the output of the low-grade heat exchanger of the heat pump and the input of the circulation pump of the condenser cooling circuit, and the output of this pump is connected to the input of the condenser heat exchanger , the output of this condenser is switched on at the inlet of the circulation pump of the evaporation and condensation circuit of the turbine working fluid, at the input In the case of the evaporator of this circuit, the lifting pipe of the Earth's heat removal circuit is located inside a hermetically sealed lowering pipe, while the external surface of the lifting pipe is thermally insulated and the output is connected to the heat exchanger inlet.