RU116199U1 - REMOTE MONITORING CABINET GAS DISTRIBUTION POINTS - Google Patents

Abstract

A device for remote monitoring of cabinet gas distribution points, containing a gas pressure sensor on the inlet pipeline, a gas purification unit pressure sensor, a pressure reduction unit pressure sensor, gas contamination and door opening sensors through an OR element connected to a cellular controller with a set of information inputs and outputs, a gas supply shut-off valve characterized in that the device additionally includes the first, second, third and fourth memory blocks, the first, second, third and fourth data transfer blocks from the memory, the first, second and third OR elements, a forced polling timer, a block for setting the exceeding of technological limits, the first, second, third and fourth comparators of exceeding the technological limits, the first, second, third and fourth comparison units, the first, second, third and fourth process parameters setters, a differential sensor, a solar battery, an adapter and a battery, and the output of the gas pressure sensor at the input pipes the wire is connected to the first inputs of the first comparison unit and the differential sensor and through the first memory unit and the data transfer unit from the memory with the information input of the cellular controller, the output of the differential sensor is connected to the first input of the second comparison unit and through the second memory unit and the data transfer unit from the memory with the information input of the cellular controller, the pressure sensor output of the gas purification unit is connected to the second input of the differential sensor and through the third memory unit and the data transfer unit from the memory with the information input of the cellular controller, the pressure sensor output

Description

The utility model relates to techniques for the distribution and transportation of natural gas, namely, to cabinet gas distribution points and can be used for remote monitoring of operating parameters, tracking excess of permissible limits and the possibility of emergency situations.

Known gas distribution point for the supply of gas to individual consumers, industrial and agricultural facilities, as well as settlements, containing a reduction unit, a gas purification unit, a monitoring and control unit (RF Patent No. 2177584, Cl. F17D 1/04, 2001).

The disadvantage of this device is the lack of remote monitoring of the technological parameters of the device.

A known gas distribution unit comprising a process unit with a gas purification and reduction unit, a gas pressure sensor at the inlet pipe, a gas purification unit pressure sensor, a pressure reducing unit pressure sensor, a gas supply shut-off valve, a gas detection sensor and a door opening sensor. (RF patent No. 2035655, CL. F17D 1/04, 1995).

The disadvantage of this device is the lack of remote monitoring of the technological parameters of the device and the occurrence of emergency situations.

The closest is a device for remote monitoring of cabinet gas distribution points, containing a gas pressure sensor at the inlet pipe, a pressure sensor for the gas treatment unit, a pressure sensor for the reduction unit, gas and gas door sensors through an OR element connected to a cellular controller with a set of information inputs and outputs, a valve shut off the gas supply. (RF patent No. 85553, CL. F01D 1/04, 2009).

The disadvantage of the device is the lack of constant remote monitoring of the technological parameters of the device with fixing their changes, the ability to track exceeding the permissible limits and the occurrence of emergency situations, which reduces the reliability and safety of operation of the equipment.

The purpose of the utility model is to increase the reliability and safety of cabinet gas distribution points by providing continuous remote monitoring of technological parameters, the ability to track exceeding permissible limits, emergency situations and remote interruption of gas supply.

This goal is achieved by the fact that in the device for remote monitoring of cabinet gas distribution points containing a gas pressure sensor at the inlet pipe, pressure sensor of the gas treatment unit, pressure sensor of the reduction unit, gas and gas door sensors through an OR element connected to the cellular communication controller with a set of information inputs and outputs, gas shutoff valve, additionally introduced first, second, third and fourth memory blocks, first, second, third and fourth transmission blocks and data from memory, the first, second and third elements “OR”, forced polling timer, unit for exceeding technological limits, first, second, third and fourth comparators for exceeding technological limits, first, second, third and fourth comparison units, first, second , the third and fourth process parameter setters, a differential sensor, a solar battery, an adapter and a battery, wherein the output of the gas pressure sensor at the input pipe is connected to the first inputs of the first comparison and differential unit sensor and through the first memory block and the data transmission unit from the memory with the information input of the cellular controller, the output of the differential sensor is connected to the first input of the second comparison unit and through the second memory block and the data transmission unit from the memory with the information input of the cellular controller, the sensor output the pressure of the gas purification unit is connected to the second input of the differential sensor and through the third memory block and the data transmission unit from the memory with the information input of the cellular controller, the sensor output is the reduction unit is connected to the first inputs of the third and fourth comparison blocks and through the fourth memory block and the data transmission unit from the memory is connected to the information input of the cellular communication controller, the outputs of the first, second, third and fourth process parameters controllers are connected to the second inputs of the first, second, the third and fourth comparison blocks, respectively, the outputs of the first and second comparison blocks through the first inputs of the first and second comparators exceeding the technological limits of the connection s with the inputs of the first and second OR elements, respectively, the outputs of the third and fourth comparison blocks through the first inputs of the third and fourth overflow comparators are connected to the inputs of the third OR element, the second inputs of the first, second, third and fourth overflow comparators connected to the output of the unit for exceeding technological limits, and the outputs with the inputs of the element "OR", the output of the timer forced polling is connected to the inputs of the first, second and third “OR” elements and with the control input of the third data transmission unit from memory, the outputs of the first, second and third “OR” elements are connected to the control inputs of the first, second and fourth data transmission units from memory, respectively, the output of the “OR” element is connected to the information input the cellular communication controller, inputs of the timer of forced polling, the unit for exceeding technological limits are connected to the information outputs of the cellular communication controller, the solar battery is connected via an adapter and the battery to power and information inputs of the cellular controller

The figure shows a diagram of a device for remote monitoring of cabinet gas distribution points.

The device comprises a gas pressure sensor at the inlet pipe 1, a pressure sensor for the gas treatment unit 2, a pressure sensor for the reduction unit 3, a gas shutoff valve 4, a gas pollution sensor 5, a door opening sensor 6, a cellular communication controller 7 with a set of information inputs and outputs, the first 8, second 9, third 10 and fourth 11 memory blocks, first 12, second 13, third 14 and fourth 15 data transmission blocks from memory, first 16, second 17, third 18 and fourth 19 “OR” elements, forced polling timer 20 , techno excess installation unit limits 21, the first 22, the second 23, the third 24 and the fourth 25 comparators for exceeding the technological limits, the first 26, the second 27, the third 28 and the fourth 29 comparison blocks, the first 30, the second 31, the third 32 and the fourth 33 setpoint process parameters, differential sensor 34, solar panel 35, adapter 36, and battery 37.

The remote monitoring device cabinet gas distribution points works as follows.

The gas pressure is measured by the gas pressure sensor at the inlet pipe 1, the pressure sensor of the reduction unit 3, the pressure sensor of the gas treatment unit 2 and the differential sensor 34.

If all technological parameters are within acceptable limits, the gas pressure value at the inlet pipeline is recorded in the first 8 memory block, the differential pressure value is recorded in the second 9 memory block, the gas pressure value at the gas purification unit is recorded in the third 10 memory block, the gas pressure value at the reduction unit is recorded in the fourth 11 memory block. As a result, the values of all parameters are fixed in time in memory blocks. These values can be read by means of the first 12, second 13, third 14 and fourth 15 blocks of data transmission from memory by commands from the compulsory polling timer 20, which at certain intervals generates read signals. As a result, the control room (not shown in the figure) through the cellular controller 7 with a set of information inputs and outputs receives data on the values of the parameters for a certain time interval. The time interval for the frequency of data polling is set from the control center through the cellular communication controller 7 by writing a certain value to the compulsory polling timer 20.

At the output of the first 26 comparison unit, a signal is generated equal to the difference of the current values from the gas pressure sensor at the inlet pipe 1 and from the first 30 setpoint process parameters. In case of exceeding the signal at the output of the first 26 unit for comparing the permissible value set by the first 22 comparator for exceeding the technological limits, a signal is generated at its output, which, through the first 16 “OR” element, opens the first 12 data transmission unit from the memory and data is sent to the control room reflecting the output of this technological parameter beyond the established limits. At the same time, through the fourth 19th “OR” element and the cellular communication controller 7, an alarm signal is received at the control room by this technological parameter. As a result, the dispatcher has the ability to remotely monitor the excess of the permissible pressure at the inlet pipe.

At the output of the second 27 comparison unit, a signal is generated equal to the difference of the current values from the differential sensor 34 and from the second 31 setpoint process parameters. In case of exceeding the signal at the output of the second 27 unit for comparing the permissible value set by the second 23 comparator for exceeding technological limits, a signal is generated at its output, which opens the second 13 data transmission unit from memory through the second 17 “OR” elements. The control room receives data reflecting the state of contamination of the gas treatment unit. At the same time, through the fourth 19th “OR” element and the cellular communication controller 7, an alarm signal is received at the control room by this technological parameter. As a result, the dispatcher has the ability to remotely monitor the state of contamination of the gas treatment unit.

At the output of the third 28 comparison unit, a signal is generated equal to the difference between the current values from the pressure sensor of the reduction unit 3 and from the third 32 process parameter setter, which sets the maximum allowable value of the gas pressure at the outlet pipe. In case of exceeding the signal at the output of the third 28 unit for comparing the permissible value set by the third 24 comparator for exceeding technological limits, a signal is generated at its output, which opens the fourth 15 data transmission unit from memory through the third 18 “OR” elements. At the control room receives data reflecting the excess of the maximum allowable gas pressure at the outlet pipe. At the same time, through the fourth 19 “OR” element and the cellular communication controller 7, an alarm signal is received at the control room. As a result, the dispatcher has the ability to remotely monitor the excess of the maximum allowable gas pressure at the outlet pipe.

At the output of the fourth 29 comparison unit, a signal is generated that is equal to the difference between the current values from the pressure sensor of the reduction unit 3 and from the fourth 33 process parameter setter, which sets the minimum allowable gas pressure value at the outlet pipeline. In case of exceeding the signal at the output of the fourth 29 unit for comparing the allowable value set by the fourth 25 comparator for exceeding the technological limits, a signal is generated at its output, which opens the fourth 15 data transmission unit from the memory through the third 18 “OR” element. At the control room receives data reflecting a decrease in gas pressure at the outlet pipe below the permissible value. At the same time, through the fourth 19 “OR” element and the cellular communication controller 7, an alarm signal is received at the control room. As a result, the dispatcher has the ability to remotely monitor the decrease in gas pressure at the outlet pipe below an acceptable value.

The values of the permissible excess of technological parameters relative to the set are set by the dispatcher through the cellular controller 7 through the installation block exceeding the technological limits 21.

Through the cellular controller 7, the dispatcher has the opportunity in the event of an emergency to stop the gas supply by remote control of the gas shut-off valve 4.

When the gas pollution sensor 5 or the door open sensor 6 is triggered, signals are generated that through the fourth 19 “OR” element and the cellular communication controller 7 are sent to the control room. As a result, the dispatcher has the ability to remotely monitor gas contamination and unauthorized access to the cabinet gas distribution point.

The power of all elements of the cabinet gas distribution point is produced from the solar battery 35 through the adapter 36 and the battery 37. The discharge of the battery 37 and the efficiency of the solar battery 35 is monitored by the dispatcher through the cellular controller 7 with a set of information inputs and outputs.

Thus, the device for remote monitoring of cabinet gas distribution points provides constant monitoring of the technological parameters of the device, controls the excess of permissible limits with the possibility of remote interruption of gas supply in emergency conditions, which increases the reliability and safety of operation of gas distribution points.

Claims (1)

A device for remote monitoring of cabinet gas distribution points, containing a gas pressure sensor at the inlet pipe, a gas purification unit pressure sensor, a pressure reducing unit sensor, gas and gas door sensors through an OR element connected to a cellular communication controller with a set of information inputs and outputs, a gas supply shut-off valve characterized in that the first, second, third and fourth memory blocks, the first, second, third and fourth data transmission blocks are additionally introduced into the device memory, the first, second and third OR elements, a compulsory polling timer, a unit for exceeding technological limits, the first, second, third and fourth comparators for exceeding technological limits, the first, second, third and fourth comparison blocks, the first, second, third and the fourth setters of technological parameters, a differential sensor, a solar battery, an adapter and a battery, and the output of the gas pressure sensor at the input pipe is connected to the first inputs of the first unit of comparison and differential the sensor and through the first memory block and the data transmission unit from the memory with the information input of the cellular controller, the differential sensor output is connected to the first input of the second comparison unit and through the second memory block and the data transmission unit from the memory with the information input of the cellular controller, the pressure sensor output the gas purification unit is connected to the second input of the differential sensor and through the third memory block and the data transmission unit from the memory with the information input of the cellular communication controller, the output of the pressure sensor A reduction unit is connected to the first inputs of the third and fourth comparison units and through the fourth memory block and data transmission unit from the memory it is connected to the information input of the cellular communication controller, the outputs of the first, second, third and fourth process parameters units are connected to the second inputs of the first, second, third and the fourth comparison blocks, respectively, the outputs of the first and second comparison blocks through the first inputs of the first and second comparators exceeding technological limits are connected to the input With the first and second OR elements, respectively, the outputs of the third and fourth comparison units through the first inputs of the third and fourth overflow comparators are connected to the inputs of the third OR element, the second inputs of the first, second, third and fourth overflow comparators are connected to the output of the excess setup block technological limits, and the outputs with the inputs of the OR element, the output of the forced polling timer is connected to the inputs of the first, second and third elements OR and with the control input of the third data transmission unit from memory, the outputs of the first, second, and third elements of OR are connected to the control inputs of the first, second, and fourth data transmission units from memory, respectively, the output of the OR element is connected to the information input of the cellular controller, inputs of the timer forcing interrogation , the unit for exceeding technological limits is connected to the information outputs of the cellular controller, the solar battery through the adapter and the battery is connected to the power and information the inputs of the cellular controller.