RU2343368C1 - Geothermal power plant - Google Patents

Abstract

FIELD: heating systems.

SUBSTANCE: invention refers to heat engineering, and namely to geothermal power plants producing electric energy based on using the heat of geothermal sources. In a geothermal power plant with circuit of heat carrier which includes gas separator, and waste heat exchangers of gas-turbine plant exit gas heat, which are connected with a well, and heat exchangers installed in condensate feed path of steam-turbine circuit, the organic fuel combustion products after gas turbine enter immediately the direct-contact heat exchanger installed on gas separator discharge thermal water piping. Thermal water mixture together with organic fuel combustion products moves through heat exchangers installed in condensate feed path of steam-turbine plant.

EFFECT: improving operating efficiency of geothermal power plant due to preventing formation of carbonate deposits in geothermal equipment, eliminating hazard of blockage of back pumping well, improving energy potential of thermal water passing through heat exchangers, and complete elimination of pollution of the environment with organic fuel combustion products.

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Description

The invention relates to a power system, and in particular, to geothermal power plants that generate electricity based on the use of heat from geothermal sources.

Geothermal power plants are known using geothermal sources for generating thermal energy in which the geothermal medium from a production well enters sequentially installed stages of expanders, from which the generated steam enters the turbine [1].

The disadvantage of such installations is the low efficiency, determined by the low initial parameters of the steam entering the turbine, and the formation of intense deposits, usually calcium carbonate on the inner surface of geothermal equipment in violation of the calcium-carbon balance in the steps of expanders. This is one of the main reasons hindering the widespread use of medium and high potential geothermal sources for generating electricity (for example, Kayasula - Stavropol Territory, Tarumovka - Republic of Dagestan, etc.).

Medium- and high-potential geothermal energy sources can be more effectively used as suppliers of additional fuel through gas separators and as condensate and make-up water heaters for the main steam-turbine circuit of power plants.

The closest in technical essence and the achieved result when using it is a geothermal power plant with a coolant circuit, including a gas separator connected to the well, a gas exhaust line connected to the combustion chamber of fossil fuels, heat exchangers-heat exchangers for exhaust gas heat of a gas turbine installation connected to the combustion chamber of fossil fuels , and heat exchangers installed in the condensate-feed path of the steam turbine circuit containing the steam generator, pa flat turbine, condenser, deaerator, regenerative heaters of low and high pressure [2].

The disadvantages of such installations include the formation of intense deposits, usually calcium carbonate in geothermal equipment after a gas separator in heat exchangers as a result of a violation of the carbonate-calcium balance. At the same time, the presence of a large amount of the solid phase of calcium carbonate in the form of suspended particles poses a serious threat to the thermal water re-injection well.

These plants also have reserves to increase the efficiency of the use of thermal energy of a geothermal source due to the greater use of the thermal potential of combustion products.

The technical problem to which the invention is directed is to increase the efficiency of a geothermal power plant by making greater use of the thermal potential of combustion products and preventing scaling in heat exchangers installed in the geothermal coolant circuit, as well as reducing the risk of clogging re-injection wells.

The technical result is achieved in that in a geothermal power plant with a coolant circuit including a gas separator connected to the well, a gas exhaust line connected to an organic fuel combustion chamber, heat exchangers, exhaust gas heat exchangers of a gas turbine installation associated with an organic fuel combustion chamber, and heat exchangers installed in the condensate-feed path of the steam turbine circuit containing a steam generator, a steam turbine, a condenser, a deaerator, regenerative heaters of low and high pressure, combustion products of fossil fuels after a gas turbine installation and the surface type of a heat exchanger-heat exchanger enter the mixing type heat exchanger-heat exchanger installed on the thermal water outlet pipe from the gas separator, and the mixture of thermal water with combustion products passes through heat exchangers installed in the condensate feed path of the steam turbine circuit, and then into the re-injection well.

The drawing shows a schematic diagram of the proposed geothermal power plant.

A geothermal power plant contains a production well 1 of a geothermal medium, a pump 2 for supplying thermal water to a gas separator 3, from which a gas-vapor coolant enters the combustion chamber 4 of a gas turbine installation, consisting of a compressor 5, a gas turbine 6 and an electric generator 7. The output of the gas turbine 6 is connected to to a steam generator 8 and to heat exchangers utilizing heat of exhaust gases of a gas turbine unit of surface type 9 and mixing type 10, mounted respectively on the supply (between between the well 1 and the gas separator 3) and the outlet (between the gas separator 3 and the heat exchanger 19 installed in the feed water line of the steam turbine installation) thermal water pipelines.

The steam-powered installation includes a steam generator 8, a steam turbine 11, an electric generator 12, a condenser 13, a condensate pump 14, a deaerator 15, a feed pump 16 and a high pressure regenerative heater 17 (a low pressure regenerative heater in the steam turbine circuit is not shown). To supply thermal water after the gas separator 3, a transfer pump 18 is installed, which pumps thermal water together with the products of combustion of organic fuel in series through a heat exchanger 19 installed in the feed water line of the condensate-feed path of the steam turbine unit, a heat exchanger 20 installed in the condensate line of the condensate-feed path , to the reinjection well of re-injection 21. Pump 22 is used to feed the combustion products of organic fuel under pressure into the heat exchanger 10 mixing type.

Geothermal power plant operates as follows.

The geothermal medium from the production well 1 is pumped 2 to a surface-type heat exchanger-heat exchanger 9, where it is additionally heated by the cooling gases of the gas turbine 6 and then supplied to the gas separator 3. From the gas separator 3, the gas-vapor mixture enters the combustion chamber 4, where, with additional fuel supply, the atmosphere of oxygen is the combustion of combustible gases. After chamber 4, the combustion products together with water vapor from the gas separator 3 enter the gas turbine 6, which rotates the electric generator 7. After the gas turbine 6, part of the combustion products is sent to the steam generator 8, and part by a parallel stream to heat exchangers-utilizers 9 and 10 installed on the inlet and the discharge pipes of thermal water, respectively. Using the injection pump 22, the products of fuel combustion are mixed in the heat exchanger 10 with thermal water directed to the heat exchangers 19 and 20 installed in the condensate-feed path. Then this mixture enters the reinjection well 21.

Carbon dioxide (CO ₂ ) contained in large quantities in the combustion products when mixed with thermal water helps to stabilize it and dissolve suspended calcium carbonate particles formed in the gas separator. At the same time, the energy potential of thermal water passing through heat exchangers installed in the condensate-feed path increases.

Thus, the supply of fossil fuel combustion products after the gas turbine directly to the mixing heat exchanger increases the efficiency of the geothermal power plant by preventing the formation of carbonate deposits in geothermal equipment, removing the risk of clogging of the re-injection well, and increasing the energy potential of thermal water passing through heat exchangers installed in the condensate-feed path of the steam turbine unit, as well as the complete exception for Environmental pollution loads combustion products of fossil fuels.

Information sources

1. A.S. USSR No. 1035247, Cl. F01K 27/00, 1983.

2. Patent of the Russian Federation RU 02027867 C1, 19950127, F01K 27/00, F03G 7/00.

Claims (1)

A geothermal power plant with a coolant circuit including a gas separator connected to the well, a gas exhaust line connected to the combustion chamber of organic fuel, heat exchangers-heat exchangers of exhaust gas heat from a gas turbine installation connected to the combustion chamber of organic fuel, and heat exchangers installed in the condensate-feed path of the steam turbine circuit containing steam generator, steam turbine, condenser, deaerator, regenerative heaters of low and high pressure, about characterized by the fact that the products of combustion of fossil fuels after a gas turbine installation and the surface type of a heat exchanger-heat exchanger enter a mixing type heat exchanger-heat exchanger installed on the heat water removal line from the gas separator, and the mixture of thermal water with combustion products passes through heat exchangers installed in the condensate-feed the path of the steam turbine circuit, and then into the re-injection well.