RU2605878C1 - Turbo-expansion system of heat utilization of circulating water on condensation units of steam turbines of thermal power station - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: invention relates to power engineering. Turbo-expansion system of heat utilization of circulating water running after a condensation steam turbine condenser to a cooling tower or a spray cooling pond comprising a circulating pump, circulating water pipelines, a condenser, cooling towers or a spray cooling pond, a heat exchanger, a turbine expander, an electric generator. Herewith the heat exchanger installed after the turbine expander is connected via the heating heat carrier to the pipeline of circulating water discharge from the condenser. Also, the system includes a gas-turbine plant, the air compressor of which is connected to the turbine expander and the gas turbine is connected with the electric generator, a main gas heater connected via the heating medium to the pipeline of waste gases discharge from the gas-turbine plant and a delivery water heater also connected to the pipeline of waste gases discharge from the gas-turbine plant.

EFFECT: invention allows reducing heat emissions of a thermal power station into the atmosphere at simultaneous generation of additional electric power.

1 cl, 1 dwg

Description

The invention relates to the field of power engineering, and in particular to expander-generator units, and can be used to cool the circulating water leaving the steam turbine condenser using a natural gas turbine expander that feeds the power boiler of the steam turbine unit.

Known heat power installation containing a boiler, a steam turbine, a condenser to which are connected pipelines for supplying and discharging circulating water, a turboexpander included between the pipelines of high and low pressure, and a heater for gas burned in the boiler [1] (Arakelyan E.K., Arakcheev E .P., Zaitsev A.N. Thermal power plant of the USSR AS No. 47874, 1981 Bull. No. 18, publ. 04.01.85).

The main disadvantage of the prototype in this case is that the gas is heated after the turboexpander installation with water, which is supplied to the condenser and, accordingly, the amount of heat removed from the condenser of the steam turbine to the atmosphere does not change. In addition, according to the prototype under consideration, circulating water is used to heat only part of the gas going to the boiler, and the remaining part continues to be throttled on the throttle valve. Such a solution is a consequence of the fact that the prototype [1] solves the problem associated only with increasing the efficiency of the heat power plant.

The technical task of the invention is to cool the circulating water leaving the thermal power station (TPP), and in this regard, the gas is heated not by the heated circulating water leaving the condenser, but by allowing it to heat the gas in front of the power boiler to a higher temperature. When solving this problem, all natural gas supplied to the power plant must pass through the turbo-expander, since the cooling effect of the circulation water is directly proportional to the gas flow through the turbo-expander.

The technical result obtained due to the proposed turboexpander system for utilizing the heat of circulating water is to reduce thermal emissions of thermal power plants into the atmosphere while generating additional electricity and is achieved by the fact that in the known turboexpander system for utilizing the heat of circulating water on the condensing units of steam turbines of a thermal power plant, going after the condenser of the steam turbine to the cooling tower or spray tank containing a circulation pump, circuits water, a condenser of a steam turbine, a cooling tower or a spray pool, a heat exchanger, a turboexpander, an electric generator according to the invention, a heat exchanger installed after the turbine expander is connected through a heating medium to a pipe for circulating water from the condenser, the system includes a gas turbine unit, an air compressor which is connected to a turboexpander, and a gas turbine is connected to an electric generator, a main gas heater connected to a pipe via a heating medium Gadfly removing flue gases from the gas turbine unit, and the heater heating water, also connected to the conduit outlet flue gases from the gas turbine plant.

The drawing shows a schematic diagram of a turbo-expander cooling system for circulating water based on an autonomous gas turbine with a turbo-expander compressor drive.

The proposed system of turbo-expander cooling of circulating water based on an autonomous gas turbine with a turbo-expander compressor drive, which contains a turbo-expander 1, an electric generator 2, a regenerative heat exchanger 3, a steam turbine condenser 4, a circulation pump 5, a condensation pump 6, a throttle valve 7, a throttle-control valve 8, GTU 9 air compressor, GTU 10 combustion chamber, GTU gas turbine 11, main gas heater 12 and network water heater 13.

The system of turbo-expander cooling of circulating water based on an autonomous gas turbine with a turbo-expander compressor drive operates as follows.

As in the first embodiment, the additional cooling of the circulation water after the condenser is carried out by low-temperature natural gas after the turbine expander 1 in the heat exchanger 3. However, now high-pressure natural gas is supplied not only to the turboexpander 1, but some of it is also supplied to the combustion chamber 10 of the gas turbine 11 connected with an electric generator 2. In the scheme under consideration, a turboexpander 1 is used to drive an air compressor 9, which makes it possible to realize a gas turbine cycle at zero power consumption AZOV turbine to drive the compressor. After the gas turbine, the exhaust gases are used either to heat the main gas in the heat exchanger 12 if the heat exchanger 3 is shut down, or to heat the mains water in the heater 13 during normal operation of the circulating water cooling system.

As a result, evaluating the efficiency of a gas turbine in the form of the ratio of the net power of a gas turbine N _e to the amount of heat Q _ks supplied in the combustion chamber, we obtain that at an initial gas temperature in front of a gas turbine T _C = 503 ° C, the gas turbine's efficiency reaches 64%. Note that in standard gas turbine units at an initial gas temperature T _C = 1500 ° C their efficiency does not exceed 40%. It should be noted that when implementing such a solution, in comparison with the first option for cooling circulating water, it is possible to increase the generation of electric energy based on natural gas by a factor of 1.5, while maintaining its flow rate through the turboexpander.

Bibliography

1. Arakelyan E.K., Arakcheev E.P., Zaitsev A.N. Thermal power plant of the USSR AS No. 47874, 1981 Bull. No. 18, publ. 1/4/.85

Claims (1)

A turbo-expander system for utilizing the heat of circulating water on the condensing units of steam turbines of a thermal power station, which goes downstream of the steam turbine condenser to a cooling tower or spray pool, containing a circulation pump, circulating water pipelines, a condenser, cooling towers or a spray pool, a heat exchanger, a turboexpander, and an electric generator, characterized in that the heat exchanger installed after the turboexpander is connected via a heating coolant to the pipe for circulating water from of the steam turbine’s condenser, the system includes a gas turbine installation, the air compressor of which is connected to the turbine expander, and the gas turbine is connected to the electric generator, a main gas heater connected via a heating medium to the exhaust gas pipe from the gas turbine installation, and a network water heater, also connected to the exhaust gas pipe from the gas turbine unit.

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