RU2776086C1 - Device for intelligent control of gas distribution point performance and prevention of emergencies in gas distribution equipment - Google Patents

Abstract

FIELD: gas reduction devices.

SUBSTANCE: invention relates to gas reduction devices with control of technological parameters and can be used to supply consumers with natural gas. The device contains gas reduction units, filters, regulators, pressure and temperature sensors, an access identifier, a memory block for current variables, adjustable blocks of different levels, a memory block for current variables, a memory block for network settings coefficients, adjustable time delay lines for high and low pressure, blocks for dynamic comparisons of high and low pressure, scaling temperature blocks of pressure dynamics, adjustable blocks of the fourth level, a controller and a block for transmitting information to the control room of a gas distribution organization.

EFFECT: invention provides an increase in the reliability of the device through intelligent control of the operation of the gas distribution point and the prevention of emergency situations in gas distribution equipment in real time.

1 cl, 1 dwg

Description

The invention relates to a technique for distributing natural gas through pipelines, namely to gas reduction devices, and can be used to supply settlements, industrial facilities and individual consumers with natural gas from main gas pipelines.

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

This device does not provide intelligent control of the operation of gas distribution equipment in real time, which reduces the reliability of its operation.

It is known a device containing fixed on a common frame blocks of reduction and gas heater 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 reducing lines connected in parallel, each of which has a filter, two regulators installed in series pressure, elements of protection against overpressure and a relief valve, the gas heater contains a gas heating heat exchanger 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 (RU Patent for utility model 68648 U1, class F 17 D 1/05, published 11/27/2007).

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

Known automatic gas-reducing point, containing blocks of reduction and gas heater, separated by an air gap and connected by airtight ducts, the reduction unit contains parallel-connected reducing lines, each of which has a filter, two serially installed pressure regulators, elements of protection against overpressure and a relief valve, a heater gas heater contains a gas heating heat exchanger with a gas burner and an additional heat exchanger made in the form of a flat box located along the side wall of the gas heater cabinet; an independent power source with a built-in backup battery, in the cabinet of the reduction unit there are additionally installed series-connected filter, gas supply regulator, expander with a built-in electric generator and a second stabilization unit connected to an autonomous power source, the control input of the gas supply regulator is connected to the pressure sensor in the low pressure network, the gas temperature sensor in the low pressure network is connected to the gas supply regulator to the gas burner of the combustion chamber, the access identifier is connected to the burglary sensors and the controller, the controller output is connected to the information transmission unit, the built-in pressure drop sensor of the inlet filter (RU Patent for invention 2613772, cl. F17D 1/05, publ. 03/21/2017).

The disadvantage of the device is the lack of control and intelligent processing of the data flow of the technological parameters of the operation of the automatic intelligent gas distribution point in real time for diagnosing and improving the reliability of its operation.

Closest to the claimed device is an automatic intelligent gas distribution point containing blocks of gas reduction and heater, pressure regulators, protection elements, a relief valve, a gas heater, a filter, a gas supply regulator, pressure sensors in the low and high pressure network, gas temperature sensors, a sensor differential pressure, access identifier, memory block for current variables, blocks of the first, second and third levels, memory block for network settings coefficients, timer, controller and information transmission block (RU Patent for invention 2732277, cl. F17D 1/05, publ. ).

The disadvantage of the device is the lack of intelligent control of the operation of the gas distribution point and the prevention of emergencies in the gas distribution equipment in real time, which reduces the reliability of its operation.

The objective of the invention is to improve the reliability of the device by intelligent control of the operation of the gas distribution point and the prevention of emergencies in the gas distribution equipment in real time.

The technical result is to increase the reliability of the operation of the device through intelligent control of the operation of the gas distribution point and the prevention of emergencies in gas distribution equipment in real time.

To achieve a technical result in a device for intelligent control of the performance of a gas distribution point and prevention of emergency situations in gas distribution equipment, containing blocks of gas reduction and a heater separated by an air gap and connected by sealed air ducts, the reduction unit contains reducing lines connected in parallel, each of which has a filter, two in series installed pressure regulators, overpressure protection elements and a relief valve, the gas heater contains a gas heating heat exchanger with a gas burner and an additional heat exchanger made in the form of a flat box located along the side wall of the gas heater cabinet, a thermoelectric converter is installed in the cabinet of the gas heater unit, attached to the chimney of the combustion chamber, the output of which, through the first stabilization unit, is connected to an autonomous power source with a built-in battery reserve external power supply, a series-connected filter, a gas supply regulator, an expander with a built-in electric generator and a second stabilization unit connected to an autonomous power source are additionally installed in the reduction unit cabinet, the control input of the gas supply regulator is connected to a pressure sensor in the low-pressure network, a gas temperature sensor in of the low pressure network is connected to the gas supply regulator to the gas burner of the combustion chamber, the access identifier is connected to the burglary sensors and the controller, the controller output is connected to the information transmission unit, the built-in pressure drop sensor of the inlet filter, the output of the gas temperature sensor in the low pressure network is connected to the inputs of the unit memory of current variables and the first adjustable block of the first level, the output of the gas temperature sensor in the high pressure network installed on the high pressure line is connected to the inputs of the memory block of current variables and the second adjustable block of the first level, the output of the sensor the pressure cable in the high pressure network installed on the high pressure line is connected to the inputs of the current variables memory block and the third adjustable block of the first level, the output of the built-in pressure drop sensor of the input filter is connected to the inputs of the current variables memory block and the fourth adjustable block of the first level, the sensor output pressure in the low-pressure network is connected to the inputs of the memory block of current variables and the fifth adjustable block of the first level, the inputs of the settings of the first, second, third, fourth and fifth adjustable blocks of the first level are connected to the outputs of the memory block of the network settings coefficients, the outputs of the first and second adjustable blocks of the first levels are connected to the first and second inputs of the first adjustable block of the second level, respectively, the outputs of the third, fourth and fifth adjustable blocks of the first level are connected to the first, second and third inputs of the second adjustable block of the second level, respectively, the inputs of the The first and second adjustable blocks of the second level are connected to the outputs of the network settings coefficients memory block, the outputs of the first and second adjustable blocks of the second level are connected to the first and second inputs of the third level adjustable block, respectively, the settings input of the third level adjustable block is connected to the output of the settings coefficients memory block network, the output of the third-level adjustable block is connected to the controller input, the timer is connected to the controller input, the current variables memory block is connected to the controller input, the controller output is connected to the network settings coefficients memory block, an adjustable high pressure time delay line, a high dynamic comparison block high pressure dynamic temperature scaling block, low pressure adjustable time delay line, low pressure dynamic comparison block, low pressure dynamic temperature scaling block, first and second adjustable blocks of the fourth level, the information input of the corrected high pressure time delay line is connected to the output of the pressure sensor in the high pressure network, and the output of the corrected high pressure time delay line is connected to the second input of the high pressure dynamic comparison block, the first input of the high pressure dynamic comparison block is connected to connected to the output of the pressure sensor in the high pressure network, the control input of the correctable high pressure time delay line is connected to the output of the network settings coefficients memory block, the output of the high pressure dynamic comparison block through the high pressure dynamic scaling temperature block and the first adjustable block of the fourth level is connected to the controller input , the control inputs of the high pressure dynamic comparison block, the high pressure dynamics scaling temperature block and the first adjustable block of the fourth level are connected to the outputs of the memory block coefficients of the network settings, the information input of the corrected low pressure time delay line is connected to the output of the pressure sensor in the low pressure network, and the output of the corrected low pressure time delay line is connected to the second input of the low pressure dynamic comparison unit, the first input of the low pressure dynamic comparison unit is connected to the connected with the output of the pressure sensor in the low-pressure network, the control input of the low-pressure time delay line being adjusted is connected to the output of the network settings coefficients memory block, the output of the low-pressure dynamic comparison block is connected to the controller input through the scaling temperature block of the low-pressure dynamics, and the second adjustable block of the fourth level is connected to the controller input, the control inputs of the low pressure dynamic comparison block, the low pressure dynamics scaling temperature block and the second adjustable block of the fourth level are connected to the outputs of the tuning coefficients memory block ek network.

The figure 1 shows a block diagram of a device for intelligent control of the operability of a gas distribution point and prevention of emergencies in gas distribution equipment.

The device for intelligent control of the operability of a gas distribution point and prevention of emergency situations in gas distribution equipment consists of reduction cabinets 1 and a gas heater 2, fixed on a common frame 3 and separated from each other by an air gap to ensure safety. In the cabinet of the reduction unit there are two parallel working lines of the same capacity and an expander line. Each line has 4 filters, two pressure reducers 5 installed in series and a gas pressure regulator 6. A cut-off valve 7 is located between the filter and the reducer, connected through a throttle 11 to the outlet of the pressure regulator 6. A safety valve 8 is connected between the pressure regulators. A relief valve 9 is installed at the outlet of the reducing lines to remove excess gas through the candle 10 to the atmosphere.

In the cabinet of the gas heater 2 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 the 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 piece of 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 gas heater cabinet 2 and the combustion chamber 12.

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

A valve 19 and an inlet filter 20 with a built-in pressure drop sensor for supplying the reduced gas to the heat exchanger 14 are installed at the inlet of the gas heater.

On the pipelines of the reducing lines, taps and valves are installed to connect the line and its individual elements, as well as to service these lines.

A thermoelectric converter 21 is installed in the gas heater cabinet 2, attached to the chimney 16 of the combustion chamber 12. The output of the thermoelectric converter 21 through the first stabilization unit 22 is connected to an autonomous power source 23 with a built-in backup battery.

The expander line is a filter 4 connected in series, a gas supply regulator 24, an expander with a built-in electric generator 25 and a second stabilization unit 26 connected to an autonomous power source 23 with a built-in backup battery. The control input of the gas supply regulator 24 is connected to the pressure sensor 27 in the low pressure network.

The gas temperature sensor 28 in the low gas pressure network is connected to the gas supply regulator 29 to the gas burner 13 of the combustion chamber 12.

The access identifier 30 is connected to the burglary sensors 31 and the controller 32, the output of which is connected to the information transmission unit 33, which, through the antenna 34, transmits information about the operation of the automatic reducing point to the control point of the gas distribution organization.

The output of the gas temperature sensor 28 in the low pressure network is connected to the inputs of the current variables memory block 35 and the first adjustable block of the first level 36, the output of the gas temperature sensor in the high pressure network 37, installed on the high pressure line, is connected to the inputs of the current variables memory block 35 and second custom block of the first level 38.

The output of the pressure sensor in the high pressure network 39, installed on the high pressure line, is connected to the inputs of the current variables memory block 35 and the third adjustable block of the first level 40, the output of the built-in differential pressure sensor of the input filter 20 is connected to the inputs of the current variable memory block 35 and the fourth adjustable block of the first level 41, the output of the pressure sensor 27 in the low pressure network is connected to the inputs of the memory block of the current variables 35 and the fifth adjustable block of the first level 42.

The inputs of the settings of the first 36, second 38, third 40, fourth 41 and fifth 42 adjustable blocks of the first level are connected to the outputs of the memory unit of the settings coefficients 43 network.

The outputs of the first 36 and second 38 custom blocks of the first level are connected to the first and second inputs of the first custom block of the second level 44, respectively. The outputs of the third 40, fourth 41 and fifth 42 custom blocks of the first level are connected to the first, second and third inputs of the second custom block of the second level 45, respectively. The inputs of the settings of the first 44 and second 45 adjustable blocks of the second level are connected to the outputs of the memory unit of the coefficients of the settings 43 of the network.

The outputs of the first 44 and second 45 custom blocks of the second level are connected to the first and second inputs of the custom block of the third level 46, respectively. The settings input of the customizable block of the third level 46 is connected to the output of the memory block of the coefficients of the settings 43 of the network.

The output of the custom block of the third level 46 is connected to the input of the controller 32.

The timer 47 is connected to the input of the controller 32. The memory block of the current variables 35 is connected to the input of the controller 32. The output of the controller 32 is connected to the memory block of the coefficients of the settings 43 of the network.

The information input of the correctable high pressure time delay line 48 is connected to the output of the pressure sensor in the high pressure network 39.

The output of the high pressure adjustable time delay line 48 is connected to the second input of the high pressure dynamic comparison unit 49, the first input of the high pressure dynamic comparison unit 49 is connected to the output of the pressure sensor in the high pressure network 39.

The control input of the correctable high pressure time delay line 48 is connected to the output of the network settings coefficients memory block 43 .

The output of the high pressure dynamic comparison block 49 is connected to the input of the controller 32 via the high pressure dynamic scaling temperature block 50 and the first adjustable block of the fourth level 51.

The control inputs of the high pressure dynamic comparison block 49, the high pressure dynamic scaling temperature block 50 and the first adjustable fourth level block 51 are connected to the outputs of the network settings coefficients memory block 43.

The information input of the correctable low pressure time delay line 52 is connected to the output of the pressure sensor in the low pressure network 27.

The output of the adjustable low pressure time delay line 52 is connected to the second input of the low pressure dynamic comparison unit 53.

The first input of the low pressure dynamic comparison block 53 is connected to the output of the pressure sensor in the low pressure network 27.

The control input of the correctable low pressure time delay line 52 is connected to the output of the network settings coefficient memory block 43 .

The output of the low pressure dynamic comparison block 53 is connected to the input of the controller 32 via a scaling temperature low pressure dynamics block 54 and a second adjustable fourth level block 55.

The control inputs of the low pressure dynamic comparison block 53, the low pressure dynamics temperature scaling block 54, and the second adjustable fourth level block 55 are connected to the outputs of the network settings coefficients memory block 43.

The device works as follows.

The high-pressure gas is fed through the pipeline to the gas heater 2, where the reduced gas is generally heated to prevent hydrate formation. The valve 19 at the inlet of the device is open and the gas through the inlet filter 20 with a built-in 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 powered through the solenoid valve 17 and a gas supply regulator 29, which changes the gas flow rate depending on the gas temperature in the low pressure network, measured by the gas temperature sensor 28.

Combustion products through the chimney 16 are discharged into the atmosphere. The heated gas enters the inlet 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 purified from mechanical impurities, passes through the cut-off 7 and enters the reducer 5, where the pressure is reduced to 6 kg/cm ² . Next, the gas enters the regulator 6, which reduces the pressure to a predetermined value.

After the pressure regulator 6, the gas passes into the outlet pipeline and enters the consumer. Overpressure protection elements are triggered by an increase in pressure in certain sections of the reducing lines. The cut-off 7 controls the gas pressure at the outlet of the reducing lines through the throttle 11. When the outlet pressure increases above the allowable limit, the cut-off 7 is activated and blocks the passage of gas into the reducing line. The safety valve 8 controls the gas pressure at the outlet of the reducer 5. When the pressure rises above the allowable pressure, the safety valve 8 releases gas into the impulse line of the cut-off 7, which is triggered and shuts off the gas supply to the faulty reducing line. Relief valve 9 is triggered when the outlet gas pressure is exceeded and discharges excess gas through candle 10 into the atmosphere in the event of a faulty reducing line in the event of a cutoff 7 failure, as well as gas leakage when the reducing line is turned off.

The cabinet of the reduction unit 1 is heated from an additional heat exchanger 15 located in the cabinet of the gas heater 2. In the metal box, due to the high temperature in the cabinet of the gas heater 2, the air entering through the air duct 18 into the cabinet of the reduction unit 1 is heated. Cold air from the cabinet of the reduction unit 1 also enters the metal box of the additional heat exchanger 15 through the air duct, where it is heated. Thus, there is an air exchange of 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 not possible for gas to leak from the reduction unit 1 into the combustion chamber of the gas heater 2 containing the gas burner, which eliminates an explosive situation.

Excess heat in the gas heater 2 is converted into electrical voltage by means of a thermoelectric converter 21. The value of the received voltage is stabilized at the required value by means of the first stabilization unit 22. The electric voltage thus obtained charges the autonomous power supply 23 with a built-in backup battery.

The excess pressure of the gas supplied through the filter 4 and the gas supply regulator 24 to the expander with a built-in electric generator 25 is used as a backup power. The value of gas pressure in the low pressure network is measured by pressure sensor 27, which, through the gas supply regulator 24, controls the gas flow through the expander with a built-in electric generator 25.

To control authorized access to the device, access identifier 30 is used, which is an electronic card reader; in case of unauthorized access to the device, burglary sensors 31 are triggered.

The controller 32 collects signals from the access identifier 30 and the tampering sensors 31. These signals are transmitted through the information transmission unit 33 with the antenna 34 to the control room of the gas distribution organization to take prompt security measures.

During operation of the device, signals from pressure sensors 27 and gas temperature 28 in the low gas pressure network, gas temperature sensors 37 and pressure in the high pressure network 39, pressure drop sensor of the inlet filter 20 enter the current variable memory block 35 with an adjustable interval of 1 second and more, as a result, the time series of the main technological parameters of the device operation are accumulated in the memory block of the current variables 35.

On a signal from the timer 47, the controller 32, at an adjustable interval of 1 hour or more, reads the accumulated time series of the main technological parameters of the device from the memory block of the current variables 35 and transmits it through the information transmission unit 33 with the antenna 34 to the control room of the gas distribution organization (not shown in the figure). ). The obtained time series of the main technological parameters are added, respectively, to the time series of parameters obtained earlier, and are processed on the control room server with the construction of a neural network of technological parameters of an automatic intelligent gas distribution point.

The parameters of the constructed neural network are transmitted from the server of the control room to the controller 32 of the automatic intelligent gas distribution point through the information transmission unit 33 with the antenna 34 and are recorded in the memory unit of the network settings coefficients 43. These coefficients are intended for setting the elements of the levels of the neural network.

The first level of the network consists of the first 36, the second 38, the third 40, the fourth 41 and the fifth 42 custom blocks of the first level.

The input of the first 36 adjustable block of the first level receives a signal from the temperature sensor 28 in the network of low gas pressure. The setting input of the first 36 adjustable block of the first level receives a tuning signal from the memory unit of the coefficients of the settings 43 of the network. If the corresponding technological parameter of the device operation deviates, a signal is generated at the output of the first 36 adjustable block of the first level, informing about the onset of the moment of deviation of this parameter from normal operation.

The input of the second 38 adjustable block of the first level receives a signal from the gas temperature sensor 37 in the high pressure network. The setting input of the second 38 customizable block of the first level receives a tuning signal from the memory unit of the coefficients of the settings 43 of the network. When the corresponding technological parameter deviates, a signal is generated at the output of the second 38 adjustable block of the first level, informing about the onset of the moment of deviation of this parameter from normal operation.

The input of the third 40 adjustable block of the first level receives a signal from the gas pressure sensor 39 in the high-pressure network, and the tuning input receives a tuning signal from the memory unit of the coefficients of the settings 43 of the network. When the corresponding technological parameter deviates, a signal is generated at the output of the third 40 adjustable block of the first level, informing about the onset of the moment of deviation of this parameter from normal operation.

The input of the fourth 41 adjustable block of the first level receives a signal from the differential pressure sensor of the inlet filter 20, and the setting input receives a tuning signal from the memory unit of the coefficients of the settings 43 of the network. When this technological parameter deviates, a signal is generated at the output of the fourth 41 adjustable block of the first level, informing about the onset of the moment of deviation of this parameter from normal operation.

The input of the fifth 42 customizable block of the first level receives a signal from the pressure sensor 27, and the tuning input receives a tuning signal from the memory unit of the coefficients of the settings 43 of the network. If this technological parameter deviates, a signal is generated at the output of the fifth 42 adjustable block of the first level, informing about the onset of the moment of deviation of this parameter from normal operation.

Signals informing about the onset of the moments of deviation of technological parameters from normal operation, generated by the first 36 and second 38 tunable blocks of the first level, are fed to the information inputs of the first tunable block of the second level 44, the setting input of which receives the setting signal from the memory unit of the settings coefficients 43 , and a signal is generated at its output, informing about the onset of moments of deviation of technological parameters from the normal operation mode of the device.

Signals informing about the onset of the moments of deviation of technological parameters from normal operation, generated by the third 40, fourth 41 and fifth 42 tunable blocks of the first level, are fed to the information inputs of the second tunable block of the second level 45, the setting input of which receives the setting signal from the memory unit coefficients of settings 43, and a signal is generated at its output, informing about the onset of moments of deviation of technological parameters from the normal operation mode of the device.

Signals informing about the onset of the moments of deviation of technological parameters from normal operation, generated by the first 44 and second 45 tunable blocks of the second level, are fed to the information inputs of the tunable block of the third level 46, the setting input of which receives the setting signal from the memory block of the settings coefficients 43, and a signal is generated at its output, informing about the onset of moments of deviation of technological parameters from the normal operation mode of the device.

A signal informing about the occurrence of moments of deviation of one or more technological parameters in their totality from the normal operation mode of the device is sent to the controller 32. The controller 32 generates a warning signal about violation of the normal operation mode of the device, generates a signal for reading the recorded time series of the main technological parameters in the memory block current variables 35 and through the information transmission unit 33 with antenna 34 transmits information about the violation of the normal operation of the device to the control center of the gas distribution organization for making prompt decisions to prevent the possible development of emergencies.

To improve the reliability of the device and prevent emergency situations in gas distribution equipment, the pressure increase in the high and low pressure network is monitored in real time.

At the information input of the corrected high pressure time delay line 48 and the first input of the high pressure dynamic comparison unit 49, a signal is received from the pressure sensor in the high pressure network 39. As a result, a high pressure increase or decrease signal is generated at the output of the high pressure dynamic comparison unit 49 for a certain period time. The value of the time interval is set through the control input of the corrected high pressure time delay line 48 by means of the memory unit of the coefficients of the settings 43 of the network. The change in the time interval of the corrected high pressure time delay line 48 is made by the operator of the control center of the gas distribution organization (not shown in the figure) by transferring the appropriate settings to the network settings coefficients memory block 43 through the controller 32 connected via the information transmission unit 33 to the antenna 34 with the control point of the gas distribution organizations.

If the high pressure rise or fall signal exceeds or falls over a certain period of time above or below the set limits, a trigger signal is generated at the output of the high pressure dynamic comparison unit 49, informing about the manifestation of an emergency situation on the gas distribution equipment.

The setting of the operation limits of the high pressure dynamic comparison unit 49 when the increase or decrease in the high pressure network is exceeded or decreased is carried out by means of the network settings coefficients memory block 43, the data in which is entered by the operator of the control center of the gas distribution organization by transferring the corresponding settings to the network settings coefficients memory block 43 via a controller 32 connected via an information transmission unit 33 with an antenna 34 to a control room of a gas distribution organization.

The signal of excess or decrease in the increase or decrease in pressure in the high pressure network through the scaling temperature block of the high pressure dynamics 50 and the first adjustable block of the fourth level 51 is fed to the controller 32 and through the information transmission unit 33 with antenna 34 to the control room of the gas distribution organization for making operational decisions on prevention of possible development of emergencies.

The high pressure dynamics temperature scaling block 50 provides input of temperature correction values to correct for an over or under increase or decrease in pressure rise or fall in the high pressure network.

The value of the temperature correction values is recorded in the scaling temperature block of the high pressure dynamics 50 through the control input from the network settings coefficient memory block 43 transmitted from the control room of the gas distribution organization through the controller 32 and the information transmission unit 33 with the antenna 34.

The first adjustable block of the fourth level 51 provides the formation of operational messages to the control center of the gas distribution organization for making decisions to prevent the possible development of emergencies. At the same time, the threshold for generating operational messages is set by means of the control input of the first adjustable block of the fourth level 51 from the memory block of the coefficients of the network settings 43 transmitted from the control center of the gas distribution organization through the controller 32 and the information transmission unit 33 with the antenna 34.

As a result, when the high pressure rises or falls, exceeding the allowable limits, taking into account temperature correction, the adjustable fourth level unit 51, through the controller 32 and through the information transmission unit 33 with the antenna 34, transmits a warning signal to the control room of the gas distribution organization for making operational decisions to prevent possible development emergency situations, which ensures an increase in the reliability of the gas distribution equipment.

Similarly, the rise or fall of pressure in the low pressure network is monitored in real time.

The information input of the adjustable low pressure time delay line 52 and the first input of the low pressure dynamic comparison block 53 receives a signal from the pressure sensor in the low pressure network 27. As a result, a low pressure rise or fall signal is generated at the output of the low pressure dynamic comparison block 53 for a certain period time. The value of the time interval is set through the control input of the corrected low pressure time delay line 52 by means of the network settings coefficients memory block 43 .

The change in the time interval of the low pressure time delay line 52 being adjusted is made by the operator of the gas distribution organization control center by transferring the appropriate settings to the network settings coefficients memory block 43 through the controller 32 connected via the information transmission block 33 to the antenna 34 with the control center of the gas distribution organization.

When the low pressure rise or fall signal exceeds or falls over a certain period of time above or below the set limits, a trigger signal is generated at the output of the low pressure dynamic comparison unit 53, informing about the occurrence of an abnormal situation on the gas distribution equipment.

The setting of the operation limits of the low pressure dynamic comparison unit 53 when the increase or decrease in the low pressure network is exceeded or decreased is carried out by means of the network settings coefficients memory block 43, the data in which is entered by the operator of the control center of the gas distribution organization by transferring the corresponding settings to the network settings coefficients memory block 43 via a controller 32 connected via an information transmission unit 33 with an antenna 34 to a control room of a gas distribution organization.

The signal of excess or decrease in the increase or decrease in pressure in the low pressure network through the scaling temperature unit of the low pressure dynamics 54 and the second adjustable block of the fourth level 55 is fed to the controller 32 and through the information transmission unit 33 with antenna 34 to the control room of the gas distribution organization for making operational decisions on prevention of possible development of emergencies.

The low pressure dynamics temperature scaling block 54 provides input of temperature correction values to correct for an over or under pressure increase or decrease signal in the low pressure network.

The value of the temperature correction values is recorded in the scaling temperature unit of the low pressure dynamics 54 through the control input from the network settings coefficient memory unit 43 transmitted from the control room of the gas distribution organization through the controller 32 and the information transmission unit 33 with the antenna 34.

The second customizable block of the fourth level 51 provides the formation of operational messages to the control center of the gas distribution organization to make decisions to prevent the possible development of emergencies. At the same time, the threshold for the formation of operational messages is set by means of the control input of the second adjustable block of the fourth level 51 from the memory block of the coefficients of the network settings 43 transmitted from the control center of the gas distribution organization through the controller 32 and the information transmission unit 33 with the antenna 34.

As a result, when low pressure rises or falls, exceeding the allowable limits, taking into account temperature correction, the adjustable fourth level unit 51 through the controller 32 and through the information transmission unit 33 with antenna 34 transmits a warning signal to the control center of the gas distribution organization for making operational decisions to prevent possible development emergency situations, which ensures an increase in the reliability of the gas distribution equipment.

This technical solution provides an increase in the reliability of the device through intelligent control of the operation of the gas distribution point and the prevention of emergencies in gas distribution equipment in real time.

Claims (1)

A device for intelligent monitoring of the operability of a gas distribution point and prevention of emergency situations in gas distribution equipment, containing blocks of gas reduction and a heater separated by an air gap and connected by sealed air ducts, the reduction block contains reducing lines connected in parallel, each of which has a filter, two pressure regulators installed in series, elements protection against overpressure and a relief valve, the gas heater contains a gas heating heat exchanger with a gas burner and an additional heat exchanger made in the form of a flat box located along the side wall of the gas heater cabinet; a thermoelectric converter is installed in the cabinet of the gas heater unit, attached to the combustion chamber chimney , the output of which is connected through the first stabilization unit to an autonomous power source with a built-in backup battery, in the cabinet of the reduction unit I additionally installed a filter connected in series, a gas supply regulator, an expander with a built-in electric generator and a second stabilization unit connected to an autonomous power source, the control input of the gas supply regulator is connected to a pressure sensor in the low pressure network, the gas temperature sensor in the low pressure network is connected to the regulator gas supply to the gas burner of the combustion chamber, the access identifier is connected to the burglary sensors and the controller, the controller output is connected to the information transmission unit, the built-in pressure drop sensor of the inlet filter, the output of the gas temperature sensor in the low pressure network is connected to the inputs of the current variable memory block and the first adjustable block of the first level, the output of the gas temperature sensor in the high pressure network, installed on the high pressure line, is connected to the inputs of the memory block for current variables and the second adjustable block of the first level, the output of the pressure sensor in the high pressure network, set installed on the high pressure line, connected to the inputs of the current variables memory block and the third adjustable block of the first level, the output of the built-in pressure drop sensor of the inlet filter is connected to the inputs of the current variables memory block and the fourth adjustable block of the first level, the output of the pressure sensor in the low pressure network is connected to the inputs of the memory block of current variables and the fifth adjustable block of the first level, the inputs of the settings of the first, second, third, fourth and fifth adjustable blocks of the first level are connected to the outputs of the memory block of the network settings coefficients, the outputs of the first and second adjustable blocks of the first level are connected to the first and second inputs of the first adjustable block of the second level, respectively, the outputs of the third, fourth and fifth adjustable blocks of the first level are connected to the first, second and third inputs of the second adjustable block of the second level, respectively, the inputs of the settings of the first and second adjustable blocks of the second level are connected to the outputs of the network settings coefficients memory block, the outputs of the first and second adjustable blocks of the second level are connected to the first and second inputs of the third level adjustable block, respectively, the settings input of the third level adjustable block is connected to the output of the network settings coefficients memory block, the output of the third level adjustable block level is connected to the input of the controller, the timer is connected to the input of the controller, the memory block of current variables is connected to the input of the controller, the output of the controller is connected to the memory block of the coefficients of the network settings, characterized in that the device additionally includes an adjustable high pressure time delay line, a high dynamic comparison block high pressure dynamic temperature scaling block, low pressure adjustable time delay line, low pressure dynamic comparison block, low pressure dynamic temperature scaling block, first and second settings 4th level blocks, wherein the information input of the corrected high pressure time delay line is connected to the output of the pressure sensor in the high pressure network, and the output of the corrected high pressure time delay line is connected to the second input of the high pressure dynamic comparison unit, the first input of the high pressure dynamic comparison unit is connected with the output of the pressure sensor in the high pressure network, the control input of the corrected high pressure time delay line is connected to the output of the network settings coefficients memory block, the output of the high pressure dynamic comparison block through the high pressure dynamic scaling temperature block and the first adjustable block of the fourth level is connected to the controller input, the control inputs of the high pressure dynamic comparison block, the high pressure dynamics scaling temperature block and the first adjustable block of the fourth level are connected to the outputs of the coefficient memory block network settings, the information input of the corrected low pressure time delay line is connected to the output of the pressure sensor in the low pressure network, and the output of the corrected low pressure time delay line is connected to the second input of the low pressure dynamic comparison unit, the first input of the low pressure dynamic comparison unit is connected to the output pressure sensor in the low pressure network, the control input of the corrected low pressure time delay line is connected to the output of the network settings coefficients memory block, the output of the low pressure dynamic comparison block through the scaling temperature block of the low pressure dynamics and the second adjustable block of the fourth level is connected to the controller input, the control inputs the low pressure dynamic comparison block, the low pressure dynamics scaling temperature block, and the second adjustable fourth level block are connected to the outputs of the network settings coefficients memory block.

Images