RU65627U1 - GEOTHERMAL POWER PLANT OF AN ISOLATED POWER SYSTEM - Google Patents

Abstract

The utility model relates to the field of electric power industry, in particular to the field of geothermal electric power industry, and can be used at geothermal power plants of isolated power systems. The technical problem solved by the proposed utility model is to significantly increase the efficiency of use of the extracted geothermal coolant and, thereby, to improve the economic and environmental indicators of the geothermal power plant of an isolated power system. The problem is solved in that a well-known geothermal power plant containing a production well, a separator, a condensing steam turbine with a condenser and a condensate pump, a turbine rotor speed regulator, a fresh steam pressure regulator with a silencer, an electric generator that is kinematically connected to the turbine rotor, and electrically with a complete switchgear through which electricity is supplied to an external power supply and an external electric load meter, additional A hydrogen production facility through water electrolysis, consisting of n identical electrolytic modules, and a hydrogen storage system are being introduced. To ensure the operation of the hydrogen production installation, a water treatment device is also introduced into the power station to obtain the parameters necessary for the process of water electrolysis and a power cabinet through which power is supplied to the modules-electrolyzers of the hydrogen production installation. Maintaining the nominal mode of operation of a geothermal power plant is ensured by an automatic control device for turning on (turning off) the power supply of the modules-electrolyzers of a hydrogen production unit, which makes it unclaimed

The external consumer uses the excess electric power of the geothermal power plant of the isolated power system in the process of water electrolysis. In this case, the control signal is generated as the difference between the rated electrical load of the power plant and the current external electrical load of the power plant, and the duty cycle of switching on (off) the power supply of the modules-electrolyzers of the hydrogen production unit, carried out by the power cabinet upon the command of the control device, is equal to the rated load of a single electrolyzer module.

Description

The utility model relates to the field of electric power industry, in particular to the field of geothermal electric power industry and can be used at geothermal power plants of isolated power systems.

The analogues of the proposed geothermal power station are geothermal power plants with steam turbines. (F03G 7/00, No. 94043757; F24J 3/08, No. 2000111435; F01K 21/04, No. 2003126819; F03G 7/00, No. 2044924).

The disadvantage of these analogues is the inefficient use of geothermal coolant.

Known adopted for the prototype geothermal energy complex (F24J 3/08, No. 95119668).

In this energy complex, the geothermal coolant produced in a productive geothermal well is separated in a separator into a separator, which is discharged into the injection well, and fresh steam entering the generator’s drive turbine. The fresh steam pressure is maintained by a station controller, which, depending on the load (steam flow) of the turbine, more (or less) the steam discharges through the silencer into the atmosphere. This is explained by the fact that the production well’s production rate during its operation is practically independent of the turbine load; therefore, the steam produced in the separator is mainly redistributed between the turbine and the station controller. At the same time, when the turbine load corresponds to the nominal, then the minimum amount of steam is discharged into the atmosphere through the station controller, while the turbine load falls, the difference between the nominal and current steam consumption for the turbine is reset by the station controller through the silencer to the atmosphere.

At the same time, for an isolated energy system in which the geothermal energy complex is system-forming, the operation of the energy complex with partial use of the steam supplied after the separator is a typical operation mode, determined by the schedule of the external electric load. In isolated power systems, where thermal power plants act as backbones, it is not always possible to ensure the nominal operation of the geothermal power complex regardless of the daily, weekly and seasonal fluctuations of the external electrical load of the power system, because the level of permissible unloading of thermal power plants is limited for technological reasons. As a result, the geothermal power station is transferred to the partial load mode, which in this case also leads to irretrievable losses of a part of the geothermal coolant.

Thus, the main disadvantage of the known geothermal energy complex during its operation in an isolated power system is the irretrievable loss of the geothermal coolant due to the inability to provide a nominal mode of operation regardless of the schedule of the external electrical load of the isolated power system. As a result, the coefficient of utilization of the installed capacity of a geothermal power plant is significantly reduced, accordingly, its specific electricity generation per unit of produced geothermal coolant is reduced, the cost of electricity production is increased, and at a fixed tariff, the economic performance of the power plant as a whole is reduced.

Another disadvantage of this energy complex is the environmental degradation due to the discharge into the atmosphere of large quantities of geothermal steam containing H ₂ S, CO ₂ and other gases during the operation of the energy complex in partial modes.

These shortcomings are eliminated by the proposed utility model.

The technical problem solved by the proposed utility model is to significantly improve the economic and environmental indicators of a geothermal power plant in an isolated energy system.

The problem is solved in that in a well-known geothermal power plant containing a production well, a separator, a condensing steam turbine with a condenser and a condensate pump, a turbine rotor speed regulator, a fresh steam pressure regulator, a silencer, an electric generator with a complete switchgear and an external electric load meter, additionally introducing a plant for the production of hydrogen obtained by electrolysis of water, consisting of n identical electrolytic modules, water preparation for electrolyzers, a power cabinet for supplying power to the modules-electrolyzers of a hydrogen production unit, an automatic control device for turning on / off the power of the modules-electrolyzers of a hydrogen production unit and a hydrogen storage system.

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

A geothermal power plant contains a productive geothermal well 1, a separator 2, separating the geothermal coolant produced in the well 1 into a separate and fresh steam, a fresh steam pressure regulator 3, a silencer 4, a turbine rotor speed controller 5, a condensing steam turbine 6 with a condenser 7, an electric generator 8 , which is kinematically connected with the rotor of the turbine 6, and electrically with the complete switchgear 9, through which electricity is supplied to the external electric network and to its own e needs of the power plant, and meter 10 external electrical load. To pump steam condensate from the condenser 7 of the turbine 6, the power plant is equipped with a condensate pump 11.

The power plant also includes a device for preparing water for electrolytic cells 12, which is connected inlet to the discharge line of the condensate pump 11, a hydrogen production unit 13 through electrolysis of water, consisting of n identical electrolytic modules, each of which is connected to the water preparation device 12 at the input, a cabinet power 14, connected at the input to the complete switchgear 9, and at the output independently with each module-electrolyzer of the hydrogen production unit 13, the automatic control device 15 for prison (disconnecting) the power-setting electrolysers modules 13, 16 hydrogen storage system.

The power plant operates as follows.

The geothermal coolant from the well 1 enters the separator 2, where it is separated into a separator and fresh steam. Fresh steam through the control valve of the regulator 5 enters the turbine 6. The steam spent in the turbine 6 is discharged to the condenser 7, from where the condensate pump 11 is pumped through the pipe 17 into the injection well. Part of the condensate from the discharge pump 11 enters the device 12 for the preparation of water for electrolyzers. Separate through pipeline 18 is discharged into the injection well. Cooling water to the condenser 7 enters through pipeline 19.

The generator 8 is kinematically connected with the rotor of the turbine 6, and electrically with the complete switchgear 9 and through it with an external electrical network and a power cabinet 14, through which the power supply of the electrolytic modules is carried out. The current external electrical load of the power plant is measured by meter 10.

The apparatus 15 automatically control switching (switching off), power modules electrolytic hydrogen production facility 13 maintains nominal load power by automatic loading (unloading) Fitting 13 depending on the external load N _ext power within a daily, weekly or seasonal load curves. With external

N _ext power load equal to the nominal value of load power all the electrolyzers modules disabled. If the external load N _ext power below its nominal load N _n, the device 15 through the rack power 14 connects the power supply such quantity setting-electrolysers modules 13 at which the load power generator 8 power remains at a level close to the nominal, regardless of the external electrical load power plants. The control signal of the device 15 is formed as the difference between the rated and current external electrical load of the power plant.

In this case, the duty cycle of turning on (turning off) the power supply of the modules-electrolyzers of the hydrogen production unit 13, implemented by the device 15 in the power cabinet 14, is equal to the rated electric load of one electrolyzer module.

Hydrogen generated at the facility 13 is transported to the hydrogen storage system 16, from which it is supplied to an external consumer.

Thus, the use of a hydrogen production unit 13 in conjunction with a water treatment device 12, a power cabinet 14 and an automatic control device 15 for turning on / off the power supply of the electrolytic cells of the installation 13 makes it possible to maintain the load of the electric generator 8 close to the nominal value regardless of the external electrical load schedule isolated power systems and, thus, to manage the extracted geothermal coolant as efficiently as possible, eliminating the discharge of excess fresh steam and in an atmosphere formed by the turbine at partial modes, and using steam turbine at maximum efficiency.

This allows you to generate all the electricity at maximum turbine efficiency and bring the utilization rate of the installed capacity of the power plant to almost a theoretical maximum, i.e. get the maximum possible amount for the year at the power plant

electricity. In this case, the difference between the actually generated electricity and the electricity supplied to the external electric network, minus the own needs of the power plant, will go to the production of an environmentally friendly product - hydrogen.

Thus, the proposed utility model allows:

- transfer the power plant to the nominal (basic) mode of operation regardless of the external electrical load with the highest possible annual generation of electricity;

- to produce hydrogen on the basis of unclaimed excess electricity for external consumers, which can be used in the fuel cells of vehicles, in stationary fuel cells for the production of electricity and heat, etc. Thanks to the implementation of hydrogen, the economic performance of the power plant as a whole is substantially increased.

In addition, the operation of the turbine in the nominal operating mode, regardless of the external load schedule, minimizes the discharge of steam into the atmosphere and, thereby, reduces the technogenic load on the environment.

Claims (1)

A geothermal power plant of an isolated energy system containing a productive well for extracting a geothermal coolant, a coolant separator, a fresh steam pressure regulator, a silencer, a condensing steam turbine, a turbine condenser, a condensate pump, a turbine rotor speed regulator, an electric generator kinematically connected with the turbine rotor, and electrically with complete switchgear of a power plant, an external electric load meter, which differs from the known ones in that the electric The power plants additionally introduced a hydrogen production unit consisting of n identical electrolytic modules, a water treatment device for electrolytic modules, which is connected at the input to the discharge line of the condensate pump, and at the output it is connected independently to each electrolyzer module of the hydrogen production installation, a power cabinet, which at the input is connected to the complete switchgear of the power plant, and at the output - independently with each module-electrolyzer of a hydrogen production installation, a hydrogen storage system, with a unit at the input to the hydrogen production unit, an automatic control device for turning on / off the power supply of the modules of the electrolysers of the hydrogen production unit by a signal generated as the difference between the rated and current external electric load of the power plant, while the duty cycle of switching on (off) the power supply of the modules-electrolyzers of the production unit hydrogen, sold in a power cabinet, is equal to the rated electrical load of one electrolyzer module.