RU176799U1 - GAS DISTRIBUTION STATION WITH A DETANDER-COMPRESSOR GAS TURBINE POWER INSTALLATION - Google Patents

Abstract

The utility model relates to expander-generator and gas turbine power plants and relates to expansion plants for the production of compressed air using the excess pressure energy of natural gas transported through gas pipelines, followed by the use of compressed air in the combustion chamber of a gas turbine power plant. A useful model can be used in gas distribution stations with a power plant. The essence of a utility model: a gas distribution station contains a mag a gas pipeline 1 with a reducing device 2, a gas pipeline of reduced gas pressure 3, a turboexpander 4 kinematically connected to an air compressor 5, a power gas turbine 6, a power generator 7, a combustion chamber 8, a heat exchanger-utilizer 9 of the exhaust gases of a power gas turbine, and also an input a gas pipeline 10, an outlet gas pipe 11, a suction 12 and a pressure pipe 13, air pipes, a gas pipe to the combustion chamber 14, a pipe of combustion products 15, an exhaust gas pipe 16, a pressure regulator valve 17 supporting a predetermined level, the pressure of natural gas in the outlet gas line after the turboexpander.

Description

The utility model relates to expander-generator and gas turbine power plants and relates to expander plants for the production of compressed air using the overpressure energy of natural gas transported through gas pipelines, followed by the use of compressed air in the combustion chamber of a gas turbine power plant. The utility model can be used at gas distribution stations with a power plant.

A known power plant (patent for invention No. 2009389, Russian Federation), the main elements of which are a turboexpander for driving an electric generator, a kinematically associated gas turbine engine, a heat exchanger-heat exchanger of exhaust gases of a gas turbine engine, and a heat exchanger-regenerator for preheating the natural gas stream before expanding it in a turboexpander. Due to the heating of the gas of the main gas pipeline in the heat exchanger-utilizer of the known installation, the heat of the gas exhausted in the turboexpander increases the efficiency and efficiency of the installation.

The following disadvantages of this installation should be noted.

1) If there is a single kinematic connection between the four units - a compressor, a gas turbine gas turbine, an electric generator and a turboexpander - it is impossible to provide optimal conditions and parameters for their joint operation.

2) The turbo expander is used to partially compensate for the power costs of the turbine unit of the gas turbine unit for the compressor drive, which means that the power potential of the fuel gas is used without taking into account the operating mode of the installation. With possible limitations of its power, it will be necessary to limit the passage of gas through the expander.

3) The operation mode of the gas turbine unit is in no way consistent with the operation modes of the gas transmission system and gas consumption system. For the operation of gas turbines with high power and efficiency, a significant increase in the temperature of the combustion products at the entrance to the gas turbine is required. Moreover, the higher this temperature, the higher the temperature of the exhaust gases after the turbine, which means that in all operating modes the absolute consumption of natural gas for electricity generation is high.

4) To partially reduce the heat loss of the exhaust gases, it is envisaged to use two heat exchangers that perform the same function of preheating the natural gas stream before the turbine expander. This complicates the design of the installation, makes it more bulky and expensive and less reliable, while you can do with only one heat exchanger-heat exchanger exhaust gas turbine engine.

5) It is assumed that the flow of natural gas leaving the turboexpander and entering the reduced pressure gas pipeline can be overheated relative to the gas temperature in the main gas pipeline to 50 ° C. Since gas distribution systems, as a rule, are located at a considerable distance from the technological and energy units consuming natural gas (up to 1.5 km or more), its heat will inevitably be dissipated into the environment (atmosphere or soil), which means that this supply of physical heat natural gas is lost uselessly.

6) The work according to the proposed scheme does not comply with the conditions for complete environmental friendliness of the installation, in which the temperature of the natural gas stream after the turboexpander is equal to the gas temperature in the main gas pipeline.

The objective of this utility model is to maximize the use of the power potential of fuel gas in the production of electricity based on a power plant (combining turboexpander and gas turbine technologies) by reducing the associated fuel consumption for gas preheating to a level that ensures compliance with the full environmental friendliness condition.

This task is achieved by the fact that in the proposed power plant comprising a main gas pipeline with a reducing device, a gas pipeline of reduced gas pressure, an inlet gas pipeline with a gas pressure regulator valve, a heat exchanger-utilizer of heat of exhaust gases of a power gas turbine installed in the course of natural gas, an outlet gas pipeline, a turbine expander kinematically associated air compressor, suction and pressure air ducts, gas pipeline to the combustion chamber, hot gas pipeline to power g a gas turbine, an associated electric generator, and a pipeline supplying exhaust gases to a heat exchanger-heat exchanger for preheating the natural gas stream before the turboexpander, the mechanical load of rotation of the air compressor is provided by the expansion of the natural gas stream in the turbine expander, and the power gas turbine rotates only the electric generator. The power potential of fuel gas in all modes is completely spent on the production of compressed air. The air heated during compression enters the gas turbine combustion chamber, where exactly so much fuel is burned that, upon leaving the gas turbine (rotating electric generator), the heat of the exhaust gases remains sufficient to preheat the natural gas stream to such a temperature that, after its expansion in the turbine expander, the condition full environmental friendliness of the power plant. This ensures the maximum reduction in specific fuel consumption for electricity generation with a minimum consumption of fuel gas in the combustion chamber of a power plant.

The figure shows a schematic diagram of the proposed gas distribution station with an expander-compressor gas turbine power plant.

The gas distribution station comprises a gas main 1 with a reducing device 2, a gas low pressure gas pipeline 3, a turboexpander 4 kinematically connected to an air compressor 5, a power gas turbine 6, a power generator 7, a combustion chamber 8, an exhaust gas heat exchanger-exhaust gas exchanger 9, as well as the inlet gas pipe 10, the outlet gas pipe 11, the suction 12 and pressure 13 air pipes, the gas pipe to the combustion chamber 14, the pipeline of combustion products 15, the exhaust pipe 16, valve en 17 of the pressure regulator, maintaining a predetermined level of gas pressure in the outlet manifold after the turbo expander.

The device operates as follows.

Natural gas is taken from the main gas pipeline 1 in front of the reducing device 2, through the inlet gas pipe 10 it enters a heat exchanger-utilizer 9, in which it is heated by hot exhaust gases of a power gas turbine 6, supplied to it through an exhaust gas pipe 16. From the heat exchanger-utilizer, the natural gas stream enters the turboexpander 4, in which it expands and produces the power transmitted to the air compressor 5. After expansion in the turboexpander, the flow of natural gas is directed to the gas pipeline from below ennogo gas pressure. The constant pressure of natural gas in the outlet gas line after the turboexpander 4 is supported by a valve 17 of the gas pressure regulator. In an air compressor that draws in atmospheric air through the suction line 12, the air stream is compressed and through the pressure line 13 enters the combustion chamber 8, into which fuel gas is supplied through the gas line 14, during the combustion of which the amount of heat in the exhaust gases is provided that is necessary for preliminary heating the flow of natural gas in front of the turboexpander and maximum cooling of the exhaust gases. The combustion products and excess air formed in the combustion chamber through a pipe 15 enter a power gas turbine 6 leading an electric generator 7. The exhaust gases exhausted in a power gas turbine are discharged through a pipe 16 to the atmosphere with a minimum temperature.

The power of a gas turbine is completely spent on generating only electricity. The drive of the air compressor is provided only due to the excess pressure of the fuel gas. The minimum possible amount of fuel is spent on its preliminary heating, since the heating of the combustion products in front of the gas turbine is limited by a temperature that allows gas to be supplied to the consumer at the same temperature as in the main gas pipeline. Thus, a minimum specific fuel consumption is generated for electricity generation, and compliance with the conditions of complete environmental friendliness allows avoiding the loss of physical heat of the gas flow through the reduced pressure pipeline behind the gas distribution system. Due to the lack of kinematic connection between the air compressor and the power gas turbine, both units can operate with different speeds, reaching their optimal internal relative efficiency.

Claims (2)

A power plant comprising a main gas pipeline with a reducing device, a gas pipeline of reduced gas pressure, an inlet gas pipeline with a gas pressure regulator valve, a heat exchanger-utilizer of heat of exhaust gases from a power gas turbine installed in the course of natural gas, an outlet gas pipeline, a turboexpander, a kinematically associated air compressor, suction and pressure air ducts, gas pipeline to the combustion chamber, hot gas pipeline to the power gas turbine, associated electric generator OR and a pipeline supplying exhaust gases to a heat exchanger-heat exchanger for preheating a natural gas stream in front of a turboexpander, characterized in that the expander rotates an air compressor of a gas turbine unit (GTU), which is kinematically not connected to a power gas turbine, while the gas turbine an electric generator is activated, and a gas heat exchanger-heat exchanger is installed in front of the turboexpander to heat the exhaust gas from the gas turbine. .

Images