SU1694939A1 - Geothermal power plant - Google Patents

Abstract

The invention relates to geothermal energy. The goal is to increase the reliability of the geothermal power plant by preventing CaCO3 deposits on the surfaces washed by geothermal water. The power plant contains a degasser 1, a sludge trap 2 with sludge collector 3, an evaporator 4, a turbine 5 with a generator 6 and a condenser 7 Line with a pump 9 for draining condensate to the heat exchanger 10, the second circuit of which is connected to the production well 13 and the inlet of the injection pump 8, combustion chamber 11 connected to degasser 1 and the atmosphere, and an ejector 12 connected to the combustion chamber 11 and the inlet of the sludge accumulator 3 at the solid phase outlet, and the outlet to the sludge trap 2, allows for the extraction, heating and supply of condensate lamoulovilit 2 and to intensify the process of formation of a solid phase on the seed, which prevents the formation of deposits on the heat exchange equipment of the geothermal power plant. 1 il.

Description

The invention relates to geothermal energy and can be used in the design and operation of geothermal power plants using geothermal water of high salinity

The drawing shows a geothermal power plant.

A geothermal power plant contains a degasser 1 connected in series, a sludge trap 2 · with a sludge collector 3, an evaporator 4, a turbine 5 with a generator 6, a condenser 7, and pressure pumps 8. A pump 9 connected to a heat exchanger 10 is connected to the condensate drain line, after which a combustion chamber 11 is installed, connected via a condensate line to the ejector

12. The production well 13 is connected to the injection well 14 by a heat pipe 15 and through a second circuit of the heat exchanger 10.

The power plant operates as follows.

Geothermal water from the production well 13 enters the degasser 1, where methane and its homologues are mainly separated. Then the coolant is fed into the sludge trap 2, where, due to a decrease in pressure, the formation of the CaCO3 solid phase begins. The separation of the solid phase occurs in pipelines connecting the sludge trap 2 and the evaporator 4, m in the evaporator 4. A part of the condensate in the amount of 5-10% of the mass of the coolant flows through the pump 9 to the heat exchanger 10, where it is heated to a temperature close to the original. Next, the condensate enters the combustion chamber 11, where the gas discharged from the degasser 1 is burned. Superheated condensate is fed through the ejector to the sludge trap 2.

The high temperature of the condensate, the circulation of the seed, and most importantly, the high pH intensifies the process of crystallization of CaCO3 on the seed, removes saturation, thereby preventing the formation of deposits on the surfaces of the heat exchange equipment of the power plant washed by water.

Claims (1)

Claim A geothermal power plant containing a degasser connected to the production well and a sequentially installed sludge trap with a sludge collector, an evaporator, a turbine with a generator, a condenser with a condensate discharge line, and a pressure pump, heat exchanger, combustion chamber and ejector, while the input and output of the heat exchanger on the heating medium are connected respectively with the operational well the inlet and suction of the injection pump, the combustion chamber is inlet with the degasser and the atmosphere, and the ejector is connected to the combustion chamber by a confuser, to the sludge collector by a diffuser, and to the sludge trap by the mixing chamber.