RU117504U1 - NATURAL GAS PRESSURE RECOVERY SYSTEM - Google Patents

Abstract

1. A system for utilizing excess pressure of natural gas between high and low pressure lines, containing a turbo expander and an electric generator, mechanically connected to each other and located in a sealed housing with inlet and outlet nozzles, and an internal heating source, where the inlet nozzle is connected to the high pressure line, and an outlet pipe through a source of internal heating - to a low pressure line, characterized in that it additionally contains heat exchangers for heating and cooling, a source of external heating, a cold consumer and shut-off and control valves, and the inlet pipe is connected to the high pressure line through a heating heat exchanger, a cooling heat exchanger is installed between the outlet pipe and the source of internal heating, and the heating heat exchanger is connected through a tap to the source of external heating. ! 2. System for utilization of excess pressure of natural gas according to claim 1, characterized in that the source of internal heating comprises an air compressor with a drive and a device for partial combustion of natural gas. ! 3. System for utilization of excess pressure of natural gas according to claim 1, characterized in that the source of external heating is made in the form of a system for supplying exhaust gases from a piston engine. ! 4. The natural gas overpressure utilization system according to claim 1, characterized in that the external heating source is made in the form of a system for supplying exhaust gases from a gas turbine engine. ! 5. System for utilization of excess pressure of natural gas according to claim 1, characterized in that the source of external heating is made using heat from geothermal

Description

The invention relates to devices for utilization of potential excess pressure energy of natural gas (GHG) when installing them in a piping system between high and low pressure pipelines with electricity generation. There is a known tendency to replace pressure regulators at gas distribution stations (gas distribution stations) and gas control points (gas distribution stations) with turbine expanders to generate electricity by using a pressure differential across gas distribution stations or hydraulic fracturing, which can reach 5 MPa. The pressure drop is due to the difference between the pressures in the main gas pipeline and the consumer gas pipeline.

One of these installations, adopted as an analogue, is described in the book “Energy-saving turbo-expander units”, Stepanets AA, Moscow, Nedra, 1999, p.11, where the turbo-expander is connected to the electric generator through a mechanical gearbox. As a result, a decrease in the GHG pressure in the turboexpander gives a positive effect - electric energy due to the power generated by the turboexpander. The disadvantage of this technical solution is the use of a mechanical gearbox, which reduces the efficiency of power generation and reliability

installation work.

To eliminate these shortcomings in another analogue (Turbo expander installation, patent for invention RU 2317430 C1, MKP F02C 7/28 of 06/09/2006) the use of a mechanical gearbox is excluded due to the use of a high-speed electric generator. In addition, the operation efficiency of the installation is enhanced by the use of magnetic bearings and the efficient disposal of external GHG leaks. However, in the absence of the need to heat the GHG in front of the expander, the presence of external leaks reduces the efficiency of power generation.

The disadvantages of this analogue are eliminated by a technical solution according to the patent of the Russian Federation No. 2386818 dated November 29, 2007, adopted as a prototype.

The gas turbine generator is placed in a sealed enclosure with inlet and outlet nozzles connected respectively to the high and low pressure natural gas pipelines. The outlet pipe is gasdynamically coupled to an internal heating source. The capsule design of the gas turbine generator made it possible to exclude leaks of natural gas into the atmosphere. The disadvantage of this technical solution is that it does not use the “cooling power” generated at the outlet of the sealed enclosure, the cost of which is twice the cost of electric energy.

The technical task of the proposed technical solution is the most efficient use of the potential energy of the overpressure of natural gas to provide consumers with electricity and cold with the expansion of consumer properties.

The problem is solved in that the system for utilization of excess pressure of natural gas contains high and low pressure lines, a turboexpander and an electric generator, mechanically interconnected and located in a sealed enclosure with inlet and outlet pipes, and an internal heating source. The inlet pipe is connected to the high-pressure line, and the outlet pipe is through an internal heating source to the low-pressure line.

What is new in the utility model is that the system additionally contains heating and cooling heat exchangers, an external heating source, a cold consumer and shut-off valves. The inlet pipe is connected to the high-pressure line through a heating heat exchanger. A cooling heat exchanger is installed between the outlet pipe and the source of internal heating. The heat exchanger is connected through a tap to an external heating source.

The presence of a heating heat exchanger together with an external heating source makes it possible to heat natural gas coming from a high-pressure line to a turboexpander and, accordingly, increase the power of a turboexpander and an electric generator to provide the consumer with electricity.

The presence of a cooling heat exchanger allows you to take away cold from the natural gas leaving the turbo-expander to provide the consumer with the necessary cold resource.

The presence of shut-off valves allows you to adjust the temperature level of natural gas in front of the expander and the amount of cold resource selected by the consumer of cold.

The development and refinement of the above set of essential features is given below.

The internal heating source may contain an air compressor with a drive and a device for partial combustion of natural gas, which increases the environmental performance of the system, as there are no emissions of combustion products into the atmosphere.

The source of external heating can be made in the form of an exhaust system from a piston engine, which increases the efficiency of the system.

The source of external heating can be made in the form of an exhaust system from a gas turbine installation, which increases the efficiency of the system.

The source of external heating of natural gas can be performed using the heat of a geothermal source, which increases the efficiency of the system.

The source of external heating can be made in the form of an autonomous source of heat, the use of which can lead to minimal costs of natural gas, for example, by using a boiler with immersion heating of water, in comparison with other sources of heating of the steam generator.

A refrigerator can be a consumer of cold, which expands the consumer properties of the system.

The consumer of cold can be an air-conditioned room, which extends the consumer properties of the system.

The difference in the consumers of cold is determined by the temperature level in the outlet pipe of the housing, which is ultimately determined by the degree of decrease in the pressure of natural gas on the turbine expander and its level of efficiency

Thus, the problem posed in the utility model is solved. A constructive scheme of an effective system for the utilization of excess natural gas pressure with the provision of electricity and cold to consumers was developed.

The present utility model will be better understood after considering the following description of the circuit shown in the drawing.

The natural gas overpressure utilization system, schematically shown in the figure, contains high-pressure and high-pressure lines of natural gas 1, a turbo expander 3, an electric generator 4, a sealed housing 5 with an inlet 6 and an outlet 7, and an internal heating source 8. A turbo expander 3, mechanically coupled a shaft with an electric generator 4 is located in a sealed housing 5. The inlet pipe 6 is connected to the high-pressure pipe 1. The output pipe 7 is connected to the low-pressure pipe through an internal heating source 8 Lenia 2.

The system further comprises a heating heat exchanger 9, a cooling heat exchanger 10, an external heating source 11, a cold consumer 12 and taps 13, 14. The high-pressure pipe 1 is connected to the inlet pipe 6 through a heat exchanger 9. The outlet pipe 7 is connected to an internal heating source 8 through a heat exchanger cooling 10. An external heating source 11 is connected in heat to a heating heat exchanger by a crane 13, and a cold consumer 12 is connected to a cooling heat exchanger 10 by a crane 14.

The system of utilization of excess pressure of natural gas, shown in the figure, operates as follows.

Natural gas from the line enters through a high-pressure line 1 to a heat exchanger 9, where it is heated from an external heat source 11. The heated gas through the inlet pipe 6 of the sealed housing 5 enters the turboexpander 3, generating power transmitted to it mechanically coupled to it through the shaft to an electric generator 4. In a turboexpander, the gas expands, its pressure and temperature decrease. Cold gas leaves the outlet pipe 7 of the sealed housing 5 and enters the cooling heat exchanger 10, where it gives part of the refrigerant to the cold consumer 12. The gas heated in the cooling heat exchanger 10 enters the source of internal heating 8, where it is additionally heated and enters the low-pressure line with a temperature of a given level 2. Setting the desired temperature level of the gas in front of the expander 3 is carried out by changing the amount of heat taken from the source of external heating 11 using the crane 13 depending spices from the required level of cold consumption. The regulation of the magnitude of the supplied cold to the consumer of the cold 12 is carried out by a crane 14.

As an example, we estimate for the case of lack of cold consumption the required amount of heat Q necessary for the system to work with the characteristic values of the parameters of gas distribution stations in Russia:

- turboexpander power - N _TD = 1 MW,

- natural gas consumption - G _PG = 13 kg / s,

- the degree of decrease in the total pressure of the turboexpander - π _T = 2.0,

- heating of natural gas in front of a turboexpander - ΔТ = 40K. The amount of heat is determined by the expression Q = СрG _ПГ ΔТ, where С _р is the heat capacity of natural gas.

When used as a source of external heating of exhaust gases, for example, from an internal combustion engine with its efficiency η _ICE = 0.42 and calorific value of the fuel used by him

N _U = 45MJ / kg fuel consumption required Given the inevitable entrainment of part of the heat into the atmosphere, such an engine should have a power of N _ICE = 1.1-1.3 MW.

Obviously, with the maximum use of the natural gas cold resource after the turboexpander, there is no need to preheat the GHG using either an internal heating source 8 or a heat exchanger 9. In this case, using a valve 13, the heat exchanger 9 is excluded from the system and the source is excluded from the system 8. The consumer 12 at the same time uses the entire cold resource of the system.

The proposed system has the ability to autonomously provide electricity and cold to various consumers located near the gas distribution station or hydraulic fracturing due to overpressure of natural gas, and with high efficiency.

Claims (8)

1. The system of utilization of excessive pressure of natural gas between high and low pressure lines, containing a turboexpander and an electric generator, mechanically interconnected and located in a sealed enclosure with inlet and outlet pipes, and an internal heating source, where the inlet pipe is connected to the high pressure pipe, and the outlet pipe through an internal heating source to a low-pressure line, characterized in that it further comprises heating and cooling heat exchangers, an external source about heating, a consumer of cold and shut-off and control valves, the inlet pipe being connected to the high-pressure line through a heating heat exchanger, the cooling heat exchanger is installed between the outlet pipe and the internal heating source, and the heating heat exchanger is connected through the tap to the external heating source. 2. The system for utilizing excess pressure of natural gas according to claim 1, characterized in that the source of internal heating comprises an air compressor with a drive and a device for partial combustion of natural gas. 3. The system for utilizing excess natural gas pressure according to claim 1, characterized in that the external heating source is made in the form of an exhaust gas supply system from a reciprocating engine. 4. The system for utilizing excess natural gas pressure according to claim 1, characterized in that the external heating source is made in the form of a system for supplying exhaust gases from a gas turbine engine. 5. The system for utilizing excess natural gas pressure according to claim 1, characterized in that the external heating source is made using the heat of a geothermal source. 6. The system for utilizing excess natural gas pressure according to claim 1, characterized in that the external heating source is made in the form of an autonomous heat source. 7. The system for utilization of excessive pressure of natural gas according to claim 1, characterized in that the consumer of the cold is made in the form of a refrigerator. 8. The system for utilization of excessive pressure of natural gas according to claim 1, characterized in that the consumer of cold is made in the form of an air-conditioned room.