RU2613772C2 - Automatic gas reducing station - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: automatic gas reducing station contains mounted on a common frame reduction and gas heater blocks in the metal cabinets, separated by the air gap and connected by sealed air ducts, reducing lines, heat exchangers, thermoelectric converter, power stabilization blocks, gas supply regulator, expander with the integrated electric generator, gas pressure and temperature sensor, identifier, break-in sensors, controller and information transmission unit.

EFFECT: improving the reliability of the device operation by transmitting process parameters registrations and operational measures taking to ensure the security of gas supply and the device functioning independence from the weather conditions.

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Description

The invention relates to techniques for the distribution of natural gas through pipelines, and in particular to gas reduction devices, and can be used to supply settlements, industrial facilities and individual consumers with natural gas from main gas pipelines.

A utility model is known that contains a gas reduction device with inlet and outlet pipelines, pressure sensors, gas and gas door openers, a cellular communication controller, a unit for exceeding technological limits, a solar battery, an adapter and a battery (RU Patent for utility model 116199 U1, class F17D 1 / 04, published on 05.20.2012).

A disadvantage of the utility model is the dependence of the device’s functioning on weather conditions when using solar panels and the absence of gas heating, which reduces the reliability of gas supply.

Known automatic reducing point RP-10, consisting of a reducing part and a gas heater, located in a metal cabinet, and the reducing part contains two lines, the same settings and equipment, each line contains a filter, pressure regulator, shut-off valve, safety and relief valves, heater gas is a combustion chamber in which a gas burner of infrared radiation and a heat exchanger in the form of a section of the pipeline are installed (Kroshko A.N. Autonomous power plants on the gas pipeline odah. - M .: "Nedra", 1983, p. 81-89).

The device has low reliability when the gas heater and the reduction unit are located in the same cabinet and the time taken to take operational measures to ensure reliable gas supply due to the lack of timely transmission of information about the technological parameters of the device.

A device for gas distribution containing a shut-off, stop valves, process filter, a reduction unit mounted on the input manifold of high pressure, including several stages of reduction with a sequential arrangement of pressure regulators (Patent RU 2088838 C1, CL F17D 1/04, publ. 27.08 .1997).

This device is also not provided with a gas heating unit, which reduces the reliability of gas supply and the independence of the device from weather conditions.

Closest to the claimed device is an automatic gas reduction unit containing gas reduction units and a gas heater mounted on a common frame in metal cabinets separated by an air gap and connected by airtight ducts attached at one end to a metal flat box, the reduction unit contains parallel reducing lines, each of which has a filter, two sequentially installed pressure regulators, overpressure protection elements and safety valves an axial valve, a gas heater contains a gas heat exchanger with a gas burner and an additional heat exchanger made in the form of a metal flat duct located along the side wall of the gas heater cabinet (Patent RU for utility model 68648 U1, class F17D 1/05, publ. 27.11. 2007).

The disadvantage of the device is the lack of transfer of technological parameters for taking operational measures to ensure reliable gas supply and the dependence of the functioning of the device on weather conditions, which reduces the reliability of the device.

The objective of the invention is directed to the creation of an automatic gas reduction device, providing increased reliability of the device by transmitting technological parameters and taking operational measures to ensure reliable gas supply, as well as the independence of the functioning of the device from weather conditions.

The technical result is to increase the reliability of the device through the transfer of technological parameters and the adoption of operational measures to ensure reliable gas supply, as well as the independence of the functioning of the device from weather conditions.

To achieve a technical result, in an automatic gas reduction station containing gas reduction units and a gas heater mounted on a common frame in metal cabinets separated by an air gap and connected by airtight ducts attached at one end to a metal flat duct, the reduction unit contains reduction lines in parallel, each of which has a filter, two pressure regulators installed in series, overpressure protection elements and a relief valve en, the gas heater contains a gas heat exchanger with a gas burner and an additional heat exchanger made in the form of a metal flat duct located along the side wall of the gas heater cabinet, in addition to the cabinet of the gas heater block, there is a thermoelectric converter attached to the chimney of the combustion chamber, the output of which is through the first stabilization unit is connected to an autonomous power source with a built-in backup battery in the cabinet of the additional reduction unit A filter, a gas supply regulator, an expander with a built-in electric generator and a second stabilization unit connected to an autonomous power supply are installed in series, the control input of the gas supply regulator is connected to the pressure sensor in the low pressure network, the gas temperature sensor is connected to the gas supply regulator to the gas burner combustion chamber, the access identifier is connected to the burglar sensors and the controller, to which the outputs of the pressure sensor, temperature sensor and built-in sensor are connected Single input filter differential pressure controller output is connected to the block transmission of information.

The device is illustrated by drawings, where in FIG. 1 is a perspective view of an automatic gas reduction station; FIG. 2 is a structural diagram of a reduction unit and a gas heater unit.

Automatic gas reduction point (Fig. 1) consists of a reduction unit 1 and a gas heater 2, mounted on a common frame 3 in two metal cabinets. To achieve operational safety, the cabinets are separated from each other by an air gap of 100 mm.

Cabinets have internal thermal insulation. In the cabinet of the reduction unit (Fig. 2) there are two parallel working lines, the same in productivity, and the expander line. Each line has filters 4, two series-mounted pressure reducers 5 and pressure regulator 6 of the second stage.

Overpressure protection elements are located on separate sections of the reducing lines. Between the filter and the gearbox there is a shut-off valve 7 connected via an orifice 11 to the output of the pressure regulator 6. A pressure relief valve 8 is connected between the pressure regulators. At the output of the reducing lines, a relief valve 9 is installed to vent excess gas through the candle 10.

In the cabinet of the gas heater there is a combustion chamber 12 with a gas burner 13 and two heat exchangers - a heat exchanger for heating gas 14 and a heat exchanger for heating air 15. The combustion chamber 12 is a rectangular closed cavity with a chimney 16 removed from a metal cabinet. A gas burner 13 is located in the combustion chamber 12. To regulate the gas supply and control the flame, a solenoid valve 17 is connected to the gas burner 13.

The heat exchanger for heating gas 14 is a segment of a pipeline located along one of the walls of the metal cabinet, as well as around the chimney 16 of the combustion chamber 12. The additional heat exchanger for heating air 15 is a flat metal box in the form of a parallelepiped. This heat exchanger is installed between the side wall of the cabinet of the gas heater 2 and the combustion chamber 12.

The cabinets of the gas heater 2 and the reduction unit 1 are connected by two ducts 18. One end of the ducts 18 is hermetically welded to the flat duct of the additional heat exchanger 15 and led out through openings in the side wall of the cabinet of the gas heater. The other end of the ducts 18 through the holes in the side wall is led out into the cabinet of the reduction unit 1.

At the inlet of the gas heater there is a valve 19 and an inlet filter 20 with an integrated differential pressure sensor for supplying a reduced gas to the heat exchanger 14.

Cranes and valves are installed on the pipelines of the reducing lines to connect the line and its individual elements, as well as to service these lines. To control the pressure at the outlet of the reducing lines, a pressure gauge 21 is connected.

In the cabinet of the gas heater 2, a thermoelectric converter 22 is mounted attached to the chimney 16 of the combustion chamber 12. The output of the thermoelectric converter 22 through the first stabilization unit 23 is connected to an autonomous power supply 24 with a built-in backup battery.

The expander line is a series-connected filter 4, a gas supply regulator 25, an expander with a built-in electric generator 26 and a second stabilization unit 27 connected to an autonomous power supply 24 with a built-in backup battery. The control input of the gas supply regulator 25 is connected to a pressure sensor 28 in the low pressure network.

The gas temperature sensor 29 in the low gas pressure network is connected to the gas supply regulator 30 to the gas burner 13 of the combustion chamber 12.

The access identifier 31 is connected via the communication line with the tamper sensors 32 and the controller 33, to which the outputs of the pressure sensor 28, the temperature sensor 29 in the low gas pressure network and the built-in differential pressure sensor of the input filter 20 are also connected.

The output of the controller 33 is connected to the information transfer unit 33, which through the antenna 34 transmits information about the operation of the automatic reducing station to the control room of the gas distribution organization.

The device operates as follows.

High-pressure gas is piped into the gas heater 2, where the general reduction gas is heated to eliminate hydrate formation. The valve 19 at the inlet of the device is open and the gas through the inlet filter 20 with an integrated differential pressure sensor enters the heat exchanger 14, where the gas is heated by means of a gas burner 13 located in the combustion chamber 12. The gas burner 13 in the combustion chamber 12 is fed through an electromagnetic valve 17 and a gas supply regulator 30, which changes the amount of gas flow depending on the gas temperature in the low pressure network, as measured by the gas temperature sensor 29.

The combustion products through the chimney 16 are discharged into the atmosphere. The heated gas enters the input of the reducing lines, and the reduction is carried out by one line, while the second line is in reserve. The reducing line reduces the gas pressure to a predetermined level. In the filter 4, the gas is cleaned of mechanical impurities, passes through the cutter 7 and enters the gearbox 5, where the pressure decreases to 6 kg / cm ² . Next, the gas enters the regulator 6, which reduces the pressure to a predetermined value. Visually, the pressure can be controlled by pressure gauge 21. After pressure regulator 6, gas passes into the outlet pipe and enters the consumer. Elements of protection against excess pressure are triggered by an increase in pressure in individual sections of the reducing lines. The cutter 7 controls the gas pressure at the outlet of the reducing lines through the throttle 11. When the pressure at the outlet increases above the allowable limit, the cutter 7 is activated and blocks the gas passage into the reducing line. The safety valve 8 controls the gas pressure at the outlet of the reducer 5. When the pressure increases above the allowable pressure, the safety valve 8 discharges gas into the impulse line of the cutoff 7, which is activated and shuts off the gas supply to the faulty reducing line. The relief valve 9 is activated when the gas outlet pressure is exceeded and discharges excess gas through the candle 10 into the atmosphere with a faulty reducing line in the event of a cut-off 7, as well as gas leakage when the reducing line is turned off.

The heating of the cabinet of the reduction unit 1 is carried out from an additional heat exchanger 15 located in the cabinet of the gas heater 2. In a metal box, due to the high temperature in the cabinet of the gas heater 2, air is heated to a temperature of about 80 ° C, coming through duct 18 to the cabinet of the reduction unit 1. Cold air from the cabinet of the reduction unit 1 also enters the metal duct of the additional heat exchanger 15 through the duct, where it is heated. Thus, the air is exchanged between cooled and heated air in the cabinet of the reduction unit and the gas heater, heating the air in the cabinet of the reduction unit to the required value. In this case, it is impossible for gas to leak during leakage from the reduction unit 1 into the combustion chamber of the gas heater 2 containing a gas burner, which eliminates an explosive situation.

Excessive heat in the gas heater 2 is converted into electric voltage by means of a thermoelectric converter 22. The magnitude of the obtained voltage is stabilized at the desired value using the first stabilization unit 23. Thus obtained electrical voltage charges the autonomous power source 24 with a built-in backup battery.

As a backup power supply, the excess pressure of the gas supplied through the filter 4 and the gas supply regulator 25 to the expander with the built-in electric generator 26 is used. The obtained voltage is stabilized by the second stabilization unit 27 and is used to charge the autonomous power supply 24 with the built-in backup battery. The gas pressure in the low pressure network is measured by a pressure sensor 28, which through the gas supply regulator 25 controls the gas flow through the expander with an integrated electric generator 26.

To control authorized access to the device, an access identifier 31 is used, which is an electronic card reader; in case of unauthorized access to the device, hacking sensors 32 are triggered.

The controller 33 provides the collection of signals from the pressure sensor 28, the temperature sensor 29 in the low gas pressure network, the built-in differential pressure sensor of the input filter 20, the access identifier 31, and tamper sensors 32. These signals are transmitted through the information transfer unit 34 with the antenna 35 to the gas control room organizations to take operational measures to ensure reliable gas supply. The use of power to the elements of the device from excess heat by means of a thermoelectric converter 22 and pressure using an expander with an integrated electric generator 26 ensures the independence of the functioning of the device from weather conditions.

Such a technical solution provides increased reliability of the device by transmitting technological parameters and taking operational measures to ensure reliable gas supply, as well as the independence of the functioning of the device from weather conditions.

Claims (1)

An automatic gas reduction station containing gas reduction and gas preheater units mounted on a common frame in metal cabinets separated by an air gap and connected by airtight ducts attached at one end to a metal flat duct, the reduction unit contains reduction lines connected in parallel, each of which has a filter, two in series installed pressure regulator, overpressure protection elements and a relief valve, the gas heater contains heat exchange a gas heater with a gas burner and an additional heat exchanger made in the form of a metal flat box located along the side wall of the gas heater cabinet, characterized in that in addition to the cabinet of the gas heater block there is a thermoelectric converter attached to the chimney of the combustion chamber, the output of which is through the first the stabilization unit is connected to an autonomous power source with a built-in backup battery; in the cabinet of the reduction unit we are connected in series with a filter, a gas supply regulator, an expander with a built-in electric generator and a second stabilization unit connected to an autonomous power supply, the control input of the gas supply regulator is connected to a pressure sensor in the low pressure network, the gas temperature sensor is connected to the gas supply regulator for the gas burner of the chamber combustion, the access identifier is connected to burglar sensors and a controller to which the outputs of the pressure sensor, temperature sensor and built-in differential pressure sensor are connected th input filter, the controller output is connected to the information transfer unit.

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