RU2731263C1 - Electric power generation system during liquefaction of natural gas at gas distribution station - Google Patents

Abstract

FIELD: heat power engineering.

SUBSTANCE: electric power generation system is mounted on gas distribution station (GDS) and connected to natural gas liquefaction unit. System includes heat exchanger-waste heat generator, expander-generator connected by pipelines of supply, removal of natural gas, cleaning unit in natural gas liquefaction unit with gas heaters and air cooling device. Natural gas flow supplied via main gas line is divided into two branches: the first one is connected to the first input of heat exchanger-heat exchanger and further to input of expander-generator, after passage of which gas along first branch is directed to consumers of gas distribution station, and the second branch is connected to the cleaning unit inlet in the natural gas liquefaction unit, and the purification unit output is connected to the second heat exchanger-heat exchanger inlet, second output of which is connected to input of air cooling device, at outlet of which gas is supplied to consumers of gas-distributing station. Electrical connection is established with generator of expander-generator.

EFFECT: higher energy and environmental efficiency of GDS, provision of its energy independence, production of liquefied natural gas of high quality.

1 cl, 1 dwg

Description

The invention relates to the field of heat power engineering, more precisely, to the production of electricity using technological pressure drops of transported natural gas at gas distribution stations of main gas pipelines, as well as to heat recovery when liquefying natural gas at gas distribution stations.

The invention can find application in organizing the process of natural gas liquefaction in a gas distribution station (GDS).

The idea of using technological pressure drops of transported natural gas at the gas distribution station is well known. Almost all well-known projects of using excess energy of gas pressure during its reduction in gas distribution and consumption systems are aimed at generating electrical energy.

For example, there is a known device for using the energy of excess gas pressure at a gas distribution station of a gas pipeline to generate electricity: V.P. Malkhanov. “On the UTDU-2500 utilization turboexpander unit at the GDS-7 in Dnepropetrovsk”, “Energy Saving and Water Treatment” magazine No. 4, 2002, p. 45-47, containing a turbo expander kinematically connected to an electric generator, connected by an inlet pipe to a high pressure pipeline to the gas distribution station, an outlet pipe to a low pressure pipeline behind the gas distribution station, as well as gas heaters installed in the high pressure pipeline in front of the expander, which provide gas heating due to burning part of the gas pumped through the expander. The disadvantage of the known device is the need to use an energy source, which indirectly or directly uses the process of burning fuel, for example, natural gas. This requires the consumption of fossil fuels, thus impairing the economic and environmental performance of the known device.

Also, there is a known installation for combined electricity and cooling at a gas distribution station, protected by RF patent No. 2665752, IPC F17D1 / 04, publ. 09/04/2018, patent holder Gazholodtekhnika LLC (RU). The known installation is mounted between a high-pressure gas pipeline and a low-pressure gas pipeline and contains a main line for supplying natural gas to the expander, kinematically connected to an electric generator, a drying unit installed in front of the expander, and a heat exchanger whose inlet is connected to the expander outlet. The installation contains a main gas heater connected to the high pressure gas pipeline in front of the dehydration unit, and an additional natural gas supply line that runs from the second outlet of the main gas heater through a pressure regulator and is connected to the main natural gas supply line in the low pressure gas pipeline, while, an additional gas heater with a regulator is connected to the outlet of the heat exchanger to regulate the temperature of the gas supplied to the low pressure gas pipeline, and the heat exchanger is connected by pipelines for supplying and removing refrigerant to the cold consumer. The known installation makes it possible to efficiently utilize the potential energy of natural gas at the gas distribution station. However, the presence of a drying unit in front of the expander complicates the design of the known installation, and the need to use a main gas heater connected to the high-pressure gas pipeline in front of the drying unit reduces its energy efficiency.

Technologies and systems of natural gas liquefaction are widely known with the location of plants and complexes for the production of liquefied natural gas (LNG) at the GDS, which makes it possible to use the gas pressure in the gas pipeline for the implementation of the technological cycle. A major element of natural gas liquefaction systems is the purification unit from the CO _2. In the unit regeneration mode, hot gas is supplied with a temperature of up to + 300 ° C. After desorption, as a rule, hot gas, without utilizing its heat, is cooled, for example, in an air cooler and sent to the consumer.

Solving the problem of utilizing the heat of hot gas after desorption will improve the environmental parameters of the operation of natural gas liquefaction systems, and directing the hot gas after desorption to ensure the efficient operation of various GDS systems will improve the economic parameters of the GDS operation as a whole.

The aim of the invention is to increase the energy and environmental efficiency of the gas distribution station, ensure its energy independence, as well as ensure the energy independence of a natural gas liquefaction unit operating on the basis of such a gas distribution station to obtain high quality liquefied natural gas.

The technical result of the invention is the development of a system for the production of electricity by liquefying natural gas at the gas distribution station of the main gas pipeline, which ensures complete energy independence of both the gas distribution station and the liquefaction unit operating on it, obtaining high quality liquefied natural gas.

The set goal and the required technical result are achieved due to the fact that the power generation system is mounted at the gas distribution station and connected to the natural gas liquefaction unit supplied to the gas distribution station via the main gas pipeline. The system includes a heat exchanger-utilizer, an expander-generator, a purification unit in a natural gas liquefaction unit with gas heaters and an air cooler connected by pipelines for supplying and removing natural gas. The natural gas flow supplied through the main gas pipeline is divided into two branches: the first is connected to the first inlet of the heat exchanger-utilizer and then to the inlet of the expander-generator, after which the gas passes through the first branch to the consumers of the gas distribution station. The second branch is connected to the inlet of the purification unit in the natural gas liquefaction unit, and the outlet of the purification unit is connected to the second inlet of the heat exchanger-utilizer, the second outlet of which is connected to the inlet of the air cooler, at the outlet of which the gas is directed to consumers of the gas distribution station. An electrical connection has been established with the expander-generator generator for directing electrical energy to power supply and ensuring energy independence of the natural gas liquefaction unit at the gas distribution station.

When implementing the invention, the installation of an expander generator and the connection to its input of a branch of the natural gas flow supplied through the main gas pipeline to the gas distribution station makes it possible to generate electrical energy and send it to power supply to the gas distribution station and all units operating as part of the gas distribution station. A waste-heat exchanger in the power generation system is installed to preheat the natural gas stream with the heat of the regeneration gases, utilizing the heat of the regeneration gases and ensuring the rejection of additional electric and gas heaters for gas supplied through the main gas pipeline to the expander-generator inlet to ensure optimal operation of the expander-generator , no moisture condensation, no slag. For disposal in the heat exchanger-utilizer, the regeneration gases are supplied from the purification unit of the liquefaction unit operating at the GDS.

Heat recovery contributes to an increase in the economic and environmental efficiency of the gas distribution station, as well as all the units operating within it.

The present invention and its advantages will be better understood by reference to the following description and the accompanying drawing. The drawing shows a structural diagram of a power generation system at a gas distribution station. Various ancillary systems required such as valves, flow mixers, control systems and sensors are excluded from the drawing for simplicity and clarity of presentation.

The power generation system, mounted at the gas distribution station and connected to the main gas pipeline 1, includes a heat exchanger-utilizer 2, an expander-generator 3, and an air cooler 9. The system is connected to the inlet of the purification unit 8 in the natural gas liquefaction unit with gas heaters 6, 7. Regeneration gas is fed through stream 5 to purification unit 8 in the liquefaction unit. Through streams 4 and 10, gas is directed to consumers of the gas distribution station, along stream 11, gas is directed to liquefaction.

In one particular implementation, in accordance with the accompanying drawing, the power generation system operates as follows.

The power generation system is installed at the gas distribution station, which, in turn, has a unit for liquefying natural gas supplied through the main gas pipeline. The natural gas stream 1 coming from the main gas pipeline with a temperature from 0 ° C to 10 ° C and a pressure of 5.5-7.3 MPa is divided into two branches: the first branch is connected to the first inlet of the heat exchanger-utilizer 2, where the main gas is heated to temperatures not lower than + 80 ° C and then fed to the inlet of the expander-generator 3. For normal operation of the expander-generator 3, it is necessary to heat the inlet gas to a temperature not lower than + 80 ° C. This is necessary so that there is no moisture condensate and slag at the outlet, which can disrupt the normal operation of the expander-generator 3. After the expander-generator 3, gas flow 4 is sent to the consumers of the gas distribution station with a pressure of 1.2 MPa and a temperature of at least 0 ° C. At the same time, the regeneration gas is supplied to the inlet of the purification unit 8 into the liquefaction unit, also mounted on this gas distribution station. Regeneration gas supplied by stream 5 is heated in gas heaters 6, 7. In this particular embodiment, an oven (gas burner) acts as a heater 6, and a heater 7 is an electric gas heater.

A major element of natural gas liquefaction unit is a cleaning unit of the CO _2. In the regeneration mode, hot gas with a temperature of up to + 300 ° C is supplied to the unit. After desorption, the hot gas is cooled and sent to the consumer. According to the specifics of the operation of the liquefaction unit, hot gas is continuously supplied to the CO ₂ purification unit. In the power generation system, one of the outputs of the purification unit 8 is connected to the second inlet of the heat exchanger-utilizer 2, making it possible to utilize the excess heat of the gas and heating the gas supplied from the main gas pipeline with it. As a result, the gas going to the inlet of the expander-generator 3 is heated to the required temperature of + 80 ° C using the recovered heat.

The second outlet of the heat exchanger-utilizer 2 is connected to the inlet of the air cooling apparatus 9, in which the gas is additionally cooled and supplied to consumers of the gas distribution station with a pressure of 1.2 MPa and a temperature of at least 0 ° C.

In addition, an electrical connection was established with the generator of the expander-generator 3 for directing electrical energy to power supply and ensuring the energy independence of the natural gas liquefaction unit at the gas distribution station. Electric energy is directed to the liquefaction unit to ensure the operation of electric gas heaters, compressor drives, etc., as well as for the auxiliary needs of the gas distribution station.

Warm, heated gas is directed to the inlet of the expander-generator for its efficient operation. Usually such gas is heated either with electricity or with a gas burner. In the power generation system, the gas supplied to the inlet of the expander-generator is heated with the heat of the regeneration gases from the purification unit in the liquefaction unit, i.e. we recycle, we save this heat.

This arrangement of the power generation system at the gas distribution station in the process of liquefying natural gas supplied to the gas distribution station, which makes it possible to recover heat and uses the heat of the regeneration gases to heat the gas in the expander-generator, while ensuring the possibility of obtaining a guaranteed quality product - liquefied natural gas, significantly increases the energy and environmental the efficiency of the gas distribution station, ensures its energy independence and non-volatility of all units operating as part of such a gas distribution station.

Claims (1)

An electric power generation system mounted at a gas distribution station and connected to a natural gas liquefaction unit supplied to a gas distribution station via a main gas pipeline, including a heat exchanger-utilizer, an expander-generator, a purification unit in a natural gas liquefaction unit with gas heaters and an air cooler, while the natural gas flow supplied through the main gas pipeline is divided into two branches: the first is connected to the first inlet of the heat exchanger-utilizer and then to the inlet of the expander-generator, after passing through the first branch the gas is sent to the consumers of the gas distribution station, and the second branch is connected to the inlet of the purification unit in the natural gas liquefaction unit, in addition, the outlet of the purification unit is connected to the second inlet of the waste heat exchanger, the second outlet of which is connected to the inlet of the air cooler, at the outlet of which gas sent to consumers of the gas distribution station, at the same time, an electrical connection was established with the expander-generator generator to direct electric energy to power supply and ensure the energy independence of the natural gas liquefaction unit at the gas distribution station.

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