RU2665764C1 - Aggregate gas-oil unit with pressure reducer valve and generator (options) - Google Patents

Abstract

FIELD: machine building; heating engineering.SUBSTANCE: invention relates to machine building and heating engineering, namely to preparation means of fuel gas. Aggregate gas-oil unit is located in a separate transportable frame and contains gas filter skids, gas flow meters, two connected consistently among themselves gas-oil heat exchangers and additional gas-oil heat exchanger for heating start-up gas. Between consistently connected gas-oil heat exchangers pressure reducer valve and generator with gas reduction function is installed. Alternatively, aggregate gas-oil unit contains gas filtration units, gas flow meters, two connected consistently among themselves gas-oil heat exchangers and additional gas-oil heat exchanger for heating start-up gas. Between consistently connected gas-oil heat exchangers pressure reducer valve and generator with gas reduction function is installed. At the same time and in addition, to the output of gas-oil heat exchanger, which uses hot oil of gas turbine drive of GPA as a heating coolant, fuel gas electric heater is connected in series.EFFECT: increase efficiency of GPA.2 cl, 2 dwg

Description

The invention relates to the field of engineering and heat engineering, and in particular to means for preparing fuel gas, and can be used as a part of gas pumping units (GPU), namely for heating fuel gas with simultaneous cooling of compressor oil and a gas turbine drive of GPU.

Known aggregate unit for the preparation of fuel gas according to patent RU No. 92934 "Aggregate unit for the preparation of fuel gas", publ. 04/10/2010, in which the gas reduction system contains two threads of reduction.

The use of a gas reduction system in the design of the aggregate unit leads to the need to "bleed" the pressure and generally reduces the efficiency of the aggregate unit for the preparation of fuel gas.

The closest in technical essence to the claimed technical solution is an aggregate gas-oil unit (AGMB), protected by patent RU No. 158482, publ. 01/10/2016, containing a gas filtration unit with filters - gas coalescers, two gas-oil heat exchangers connected together in series with controlled ball valves to maintain oil temperature, an additional gas-oil heat exchanger for heating the starting gas, a gas flow metering unit and a safety valve block. A gas reduction unit is connected between two gas-oil heat exchangers. In the gas reduction unit, the gas pressure is reduced from the input value to the required values.

The disadvantage of this technical solution is the reduced efficiency of the gas compressor unit due to the use of a gas reduction unit in the design of the gas-pressure generator, since the gas pressure in the reduction unit is simply "vented" to the required values and the energy spent on gas compression is not used. Also, a situation may arise when the cold reserve after gas reduction may not be sufficient to cool the oil of the gas turbine drive of the gas compressor unit and it may be necessary to additionally cool the oil, for example, using a radiator with a fan, which also generally reduces the efficiency of the gas compressor unit.

The purpose of the invention is to increase the efficiency of the gas pumping unit (GPA

This goal is achieved in the aggregate gas-oil unit (AGMB), located in a separate transportable frame and designed for heating fuel and starting gas, for cooling compressor oil and a gas turbine drive of a gas pumping unit (GPU), containing gas filtration units, gas flow metering, two connected between a series gas-oil heat exchanger and an additional gas-oil heat exchanger for heating the starting gas. Between the gas-oil heat exchangers connected in series, an expander-generator with a gas reduction function is connected to them in series, connected to the fuel gas supply pipe with a gas-oil heat exchanger using GPA compressor hot oil as a heating medium, and connected to the gas-gas exhaust pipe to a gas-oil heat exchanger as a heating medium, hot oil of a gas turbine drive of a gas compressor unit. Alternatively, the goal is achieved in an aggregate gas-oil unit (AGMB), located in a separate transportable frame and designed to heat fuel and starting gas, for cooling compressor oil and a gas turbine drive of a gas pumping unit (GPU), containing gas filtration units, measuring gas flow, two gas-oil heat exchangers connected in series with each other and an additional gas-oil heat exchanger for heating the starting gas. Between the gas-oil heat exchangers connected in series, an expander-generator with a gas reduction function is connected to them in series, connected to the fuel gas supply pipe with a gas-oil heat exchanger using GPA compressor hot oil as a heating medium, and connected to the gas-gas exhaust pipe to a gas-oil heat exchanger as a heating medium, hot oil of a gas turbine drive of a gas compressor unit. At the same time, the fuel gas electric heater is connected in series to the outlet of this gas-oil heat exchanger.

The design of the AGMB with the connection of an expander generator with a gas reduction function between gas-oil heat exchangers connected in series allows energy-saving technologies to be used, for example, to use the generated electricity for the needs of a gas compressor and to heat fuel gas, to use the cold received from the expander-generator, for example, to cool air in summer period.

Embodiments of the invention are illustrated in the drawings of FIG. 1 and FIG. 2, which schematically shows the location of the main blocks AGMB, where:

1 - gas-oil heat exchanger compressor GPA,

2 - controlled ball valves,

3 - expander generator

4 - gas-oil heat exchanger gas turbine drive GPA,

5 - electric fuel gas heater.

According to the first embodiment (Fig. 1), an aggregate gas-oil unit with an expander-generator is located in a separate transportable frame, it contains gas filtration units, gas flow metering (not shown in the figure), two gas-oil heat exchangers connected in series: gas-oil heat exchanger 1 of the compressor GPU and gas-oil heat exchanger 4 of a gas-turbine drive GPA with controlled ball valves 2 for maintaining oil temperature, as well as an additional gas-oil heat exchanger for heating gas (not shown). Between the gas-oil heat exchangers 1 and 4 connected in series, an expander-generator 3 with a gas reduction function is installed in series with them. The compressor and gas turbine drive of the GPU are not shown in the figure.

According to the second embodiment (Fig. 2), the aggregate gas-oil unit with an expander-generator is located in a separate transportable frame, contains gas filtration units, gas flow metering (not shown in the figure), two gas-oil heat exchangers connected in series: gas-oil heat exchanger 1 of the compressor GPU and gas-oil heat exchanger 4 of a gas-turbine drive GPA with controlled ball valves 2 for maintaining oil temperature, as well as an additional gas-oil heat exchanger for heating gas (not shown). Between the gas-oil heat exchangers 1 and 4 connected in series, an expander-generator 3 with a gas reduction function is installed in series with them. The gas-oil heat exchanger 4 is connected in series to the output of the gas-oil heat exchanger 5. The compressor and the gas turbine drive of the gas compressor are not shown in the figure.

When the aggregate gas-oil unit with the expander-generator according to the first embodiment (Fig. 1), the fuel gas after the filtration unit passes into the gas-oil heat exchanger 1 of the GPA compressor, where it is heated by cooling the hot lubricating oil entering the gas-oil heat exchanger 1 from the oil supply system GPA compressor. Controlled ball valves 2 serve to maintain the temperature of the oil. Next, the heated gas passes to the expander generator 3 with the function of gas reduction, where in addition to throttling, the gas pressure is also reduced from the input value to the required values, and then it is sent to the gas-oil heat exchanger 4 of the gas turbine drive, where it is additionally heated by the heat of hot lubricating oil supplied from the oil supply system of the GPA gas turbine drive. The part of the fuel gas used as starting gas is heated by hot lubricating oil in an additional gas-oil heat exchanger (not shown in the figure).

When the main gas supply systems are functioning at gas distribution stations, the pressure of the transported fuel gas is reduced from 5.5 MPa to 2.5 MPa. At new compressor stations, reduction is possible from a pressure of 10 MPa or more. Throttling is a direct loss of energy. The task of the expander generator is useful to use the "waste" gas pressure, converting the expansion energy into electrical energy. Installed between the gas-oil heat exchangers 1 and 4 connected in series, the expander-generator 3 with the gas reduction function allows you to use the electricity received for the needs of the gas compressor, for heating the room, and for powering the gas air coolers.

Since the initial temperature of the fuel gas is from -10 ° C to + 20 ° C, and after the final expansion in the expander-generator 3 can reach unacceptable values, approximately, to -100 ° C, which can disrupt the operation of the equipment, the fuel gas before entering the expander -generator 3 undergoes heating in the gas-oil heat exchanger 1 with hot lubricating oil coming from the oil supply system of the GPA compressor. Such preheating also leads to an increase in the work obtained in the expander generator 3.

When the aggregate gas-oil unit with the expander-generator according to the second embodiment (Fig. 2), the fuel gas after heating in the gas-oil heat exchanger 1 of the GPA compressor, after passing the expander-generator 3 and heating in the gas-oil heat exchanger 4 of the gas turbine drive, is additionally heated in the electric heater 5 fuel gas. The part of the fuel gas used as starting gas is heated by hot lubricating oil in an additional gas-oil heat exchanger (not shown in the figure).

Additional heating of the fuel gas in the electric heater 5 leads to an almost twofold increase in the temperature of the fuel gas in front of the GPU combustion chamber, leading to an increase in efficiency up to 0.5%, which significantly increases the GPU efficiency.

The design options for the gas-oil aggregate unit with the expander generator are calculated and applied in the design of the GPA-16 Ural, GPA-25 Ural and GPA-32 Ladoga aggregates. The effective heating of fuel gas before entering the GPU combustion chamber is shown.

Thus, by connecting an expander generator with pre-heating of the fuel gas supplied to it, as well as, according to the second embodiment, with the simultaneous heating of the fuel gas by an electric heater immediately before the fuel gas enters the GPU combustion chamber, they achieve high efficiency of reducing fuel gas pressure, directing the energy received, for example, to the GPA's own needs, for space heating, for powering the devices during stuffy cooling (ABO) gas significantly improve the efficiency of SBS as a whole.

Claims (2)

1. Aggregate gas-oil unit (AGMB) in a separate transportable frame designed for heating fuel and starting gas, for cooling compressor oil and a gas-turbine drive of a gas pumping unit (GPU), containing gas filtration units, measuring gas flow, two gas-oil heat exchangers connected to each other in series and an additional gas-oil heat exchanger for heating the starting gas, characterized in that between the series-connected gas-oil heat exchangers is installed with by connecting them to an expander-generator with a gas reduction function, connected to the fuel gas supply pipe with a gas-oil heat exchanger using GPA compressor hot oil as a heating medium, and connected to a fuel gas removal pipe to a gas-oil heat exchanger using hot gas-turbine drive oil as a heating medium GPA. 2. Aggregate gas-oil unit (AGMB) in a separate transportable frame designed for heating fuel and starting gas, for cooling compressor oil and a gas-turbine drive of a gas pumping unit (GPU), containing gas filtration units, measuring gas flow, two gas-oil heat exchangers connected to each other in series and an additional gas-oil heat exchanger for heating the starting gas, characterized in that between the series-connected gas-oil heat exchangers is installed with by connecting them to an expander-generator with a gas reduction function, connected to the fuel gas supply pipe with a gas-oil heat exchanger using GPA compressor hot oil as a heating medium, and connected to a fuel gas removal pipe to a gas-oil heat exchanger using hot gas-turbine drive oil as a heating medium GPA, at the same time, to the outlet of this gas-oil heat exchanger a fuel heater is connected in series wow gas.

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