UA52261C2 - System for recording gas flow rate - Google Patents

Abstract

The proposed system for recording gas flow rate contains gas volume flow rate meters, which are installed at the branches of the main gas pipeline with different carrying capacity, a computing unit, and an automatic programmable control unit with a switch for selecting the branches of the gas pipeline. The gas volume flow rate meters are designed to operate in overlapping measurement ranges. The switching of the branches of the gas pipeline is accomplished according to the algorithm for determining gas flow rate by the output data of the gas flow rate meters.

Description

Description of the invention

The invention relates to the field of metrology, namely means for continuous automatic measurement and 2 calculation of gas consumption and volume. The device can be used for commercial accounting of gas consumption by consumers in the gas, oil and gas production, oil refining, petrochemical industries as part of automated systems, as well as in utilities.

The well-known multi-threaded measuring microprocessor complex "Zyreg Riom/PI", (prospect of the company "Mipi

Vaze Zuziet"| is intended for continuous automatic measurement and calculation of flow rates and volume of gas, 710 reduced to normal conditions, by the method of variable pressure drop on standard narrowing devices (diaphragms) on one, two or three measuring pipelines of a gas measuring point.

The complex consists of a flow calculator, a terminal, pressure, pressure drop, and temperature sensors and provides automatic continuous measurement, calculation and display of gas flow rates for a certain period of time, which has passed through one, two or three pipelines (depending on the execution of the complex). 12 Calculation of gas consumption is carried out based on the values of pressure drop, pressure and temperature at the moment of measurement, which are entered into the measuring circuit manually, since the design does not provide for automatic engagement of the data processing algorithm. In addition, measurement by this complex requires the use of additional special devices to correct the measured value of the gas volume, since the accuracy of the measurement by this complex depends on the flow coefficient of the narrowing device (diaphragm), and the relative error of the measurement of the gas volume reduced to normal conditions will be significantly change depending on the range of temperature and pressure transducers in which these errors are normalized.

The well-known ultrasonic gas meter "Hoboy-1" |Technical passport for "Ultrasonic gas meters "Hoboy-1", ZAO Centropribor, Moscow, 2001). The meter consists of a primary flow converter with two piezoelectric converters installed along the axis of flow, pressure and temperature transducers with a computer with a liquid crystal indicator. Piezoelectric transducers alternately emit and (U) receive ultrasonic oscillations for and against the gas flow, the signals from them enter the accounting and calculation node, where, due to the difference in propagation time the volume of gas is determined by ultrasonic vibrations, and the volume of gas reduced to standard conditions is calculated based on the temperature and pressure of the gas obtained from the pressure and temperature transducers. These meters are used in residential, administrative and industrial buildings (37 rooms for accounting and calculation operations. However, they cannot be applied for accurate accounting "of costs in cases where the range you cost measurement (the ratio of the maximum cost to the minimum) is more than 250 : 1 due to the following reasons. According to the method of measuring the volume flow of gas under working conditions, the time-impulse method is implemented in the meter. The principle of its operation is based on measuring the time of passage of pulses of ultrasonic vibrations in the direction of gas flow in the pipeline. The 3o correction factors of this device depend on the speed of sound. The influence of the speed of sound depends on the physical properties of the gas, and is mainly manifested at low flows. Therefore, when measuring small flows, for example, in residential metering, where the flow rate can be less than 0.rpm/h, the reliability of the metering will be incorrect already at the stage of measurement by primary converters. In addition, there is no automatic adjustment of parameters in this meter when the volume flow rate is reduced to standard conditions, which worsens its economic characteristics. c The well-known measuring-controlling complex "Floutek-TM" 421443.001 ROZI is selected as a prototype, which is used as part of variable pressure drop flowmeters with a standard narrowing device (diaphragm) and measures the medium passing through two or three pipelines. The complex includes such devices as sl 395 absolute and differential pressure and temperature measuring transducers (pressure and temperature measuring instruments), a multi-parameter measuring calculator (corrector), a counter (flow meter), and a pressure measuring transducer. The complex is used for accounting, including commercial, of gases and liquids in the gas, oil and gas extraction, oil refining industry in the communal economy and is effective in the implementation of (o) 50 software-logical control and management algorithms and automatic maintenance of the specified operating mode of each object , where high precision accounting is unnecessary. However, the complex is unsuitable (due to the limitations of the range of flow measurements that can be satisfied by the existing measuring equipment) for example, for measuring and accounting for the volume of gas flowing through one pipeline, which can vary in a wide flow range from 0.016 to 250 mZ/h.

The task that was set when creating the invention was to improve the device for accounting for gas consumption, including (F) commercial accounting, by changing the structural scheme of the measuring and computing nodes, and in this way, to create an information-measuring gas accounting system, to increase its accuracy and reliability, to expand the range of measurements to ensure the required multiplicity of the range of measurements and to meet the requirements of the sufficiency of the lower and upper limits of the range of measurements and to perform gas accounting with a certain differentiation of the range of measurements and with a normalized error in the given range.

The problem is solved by the fact that in the gas consumption accounting system, which includes a measuring circuit, which consists of channels for measuring the volume flow of gas in working conditions, measuring absolute (excess) pressure, measuring temperature, as well as a computing circuit, which includes a computing device with temperature and pressure transducers, and, according to the invention, the measuring circuit holds a flow divider with the formation of branches of different throughputs connected to the divider at one point. In each of the branches there is a gas meter of the corresponding measurement range, and the measurement ranges of the meters are chosen so that they overlap each other. The measuring circuit also contains the means of switching the gas flow into the corresponding branch, which is carried out by an automatically comparing selective switching device, which is part of the computer circuit of the system, the mode of operation of which is set by the accounting calculation algorithm taking into account the signals received from the channels for measuring the volume flow of gas in working conditions, absolute pressure measurement and temperature measurement.

High-accuracy gas volume accounting requires high-accuracy accounting in units adjusted to normal conditions. Accordingly, the system for commercial accounting should consist of a 7/o basin counter and a corrector or computing device with temperature and pressure converters. Rotary or turbine type gas meters can be used for the proposed system. But in order to perform the function of bringing the volume measured by the gas meter to normal conditions, it is necessary to use a correcting device, the functions of which in the proposed system are performed by a comparative selective switching device, which simultaneously performs the functions of a calculator and a control node of the system's operation mode.

The implementation of a measuring circuit in the form of a flow divider with the formation of branches of different throughput and the location in each branch of the gas volume meter of the corresponding measurement range allows you to keep track of gas consumption in real time with the provision of measurement of gas consumption of the corresponding measurement range. The requirement of the sufficiency of the lower and upper limits of the flow measurements of the corresponding range is satisfied by the switching of the gas flows into the corresponding branch by means of 2o flow switching, which is carried out by an automatically comparing sampling device.

The reliability of accounting is also achieved by the fact that the measurement ranges of the flow rate counters are selected with an overlap, i.e. the lower limit of the measurement range of each subsequent counter is in the measurement range of the previous one, which allows for continuous accounting and avoids the delay of information entering the computing circuit due to inertial operation means of switching flows. with

The proposed replaced calculation and measurement schemes favorably distinguish the proposed gas consumption accounting system from the prototype by allowing to reduce the relative errors of both temperature and) absolute pressure channels, gas meters, and the system as a whole.

Since the relative error of measuring the volume of gas brought to normal conditions varies depending on the measurement range of the converters, in which the aggregated errors are normalized, then according to the value of "- zo Relative errors of the calculations of the correction factor for the entered input data obtained from each measuring channel, the maximum value of the relative error is entered, which characterizes the accuracy of the corrector in the measurement range of the parameter change, which will allow normalizing the errors in several sub-ranges of the correction.

The developed gas consumption accounting algorithm, on which the automatic control program with the system is built, also provides for the introduction of normalized characteristics of the volume flow measurement channel together with (in gas meters, temperature and pressure measurement channels, as well as linearization of the normalized characteristics of these channels.

The essence of the proposed invention is explained by the drawing, which shows the block diagram of the gas consumption accounting system. "

As shown in the figure, the gas consumption accounting system consists of a gas flow separator into uneven parts with a part made in the form of a main gas pipeline 1, with branches 2, 3, 4, which are connected to the main one at one point. In each of the branches, corresponding 5, 6, 7 switching valves and elements 8, 9, 10 are installed;" control of the state of the switching valves in the corresponding branches. A volume measuring device (volume counter) 11 of the lower limit of measurements is installed in branch 2. In branched Z - counter 12 with a lower limit of measurements, in branched 4 - counter 13 with an upper limit of measurements, the outputs of which, as well as a pressure measuring device 14 at the entrance of the main pipeline and a temperature measuring device 15 at the outlet of the main gas pipeline, are connected to of the control output 16 of the comparing sampling device (corrector).

The AI system works as follows.

When there is no gas flow through the system, due to which there are no signals from volume measuring devices 11, 12,

Me, 13, which are supplied to the comparative selective device (corrector) 16, which by means of switching valves 5, 6, 7 issues a command to connect 2, 3, 4 branches of the pipeline.

When gas is supplied to pipeline 1, it enters the system for measurements through one of the branches 2, 3, 4.

The selection of a specific branch is carried out by an automatically comparing sampling device (corrector) 16, the mode of operation of which is set by a special program developed in accordance with the gas consumption accounting algorithm. Switching is carried out depending on the operation of one of the switching valves 5, 6, 7, which (Ф) are connected to the corresponding means of measuring the volume 11, 12, 13, installed in the branches 2, 3, 4, according to the command that comes from 8, 9, 10 - control elements of the state of the switching valves. The corrector controls the switching valves in such a way that only one channel is on. Therefore, boron gas flows through only one branch, in which the cost accounting is carried out with the appropriate measuring instrument with a certain limit of the measurement range.

In cases where the flow rate is within the measurement range of the meter with the lower limit 11, the corrector is connected to the branching measuring circuit 2. The corrector 16 receives signals from the meter 11 as long as the flow rate is within its measurement range. When the costs increase, exceeding b5 the upper limit of the measurement range of the meter 11, the corrector 16 automatically disables the measuring circuit of the branch 2 and connects the measuring circuit of the branch 3, through which the flow that is in the measurement range of the meter 12 and the meter 11 passes, since the measurement ranges of these counters are selected with an overlap.

With a further increase in gas consumption to the value of the upper limit of the measurements of the counter 12, the corrector 16 disconnects the branch C from the calculating circuit of the corrector and simultaneously connects the measuring circuit of the branch 4 with the counter 13 through the switching valve 7. At the same time, the same flow passes through the counter 13 as and through the counter 12, since the measurement ranges of these counters are selected with an overlap, the cost value is in the measurement range of the counter 13.

When the costs are reduced to the lower limit of the measurement range of the counter 13, the corrector sends a command to the control element of the state of the switching valve 10 to turn off the measuring circuit of branching 4 and at the same time to the control element of the state of the switching valve ZU to connect the measuring circuit of the branching with the counter 12. to reduce costs, switching to the measuring scheme of branching 2 is carried out in the same way.

To convert the result of the measurement in the operating conditions of the volume flow into standard conditions, the pressure value measured at the inlet of the pipeline 1 by the pressure measuring device 14 and the temperature value measured at the system outlet by the temperature measuring device 15 are received at the input 7/5 of the Corrector.

Claims (1)

Formula of the invention , , , , , I . A gas flow accounting system containing a measuring circuit that consists of channels for measuring the volume flow of gas in working conditions, measuring absolute pressure, measuring temperature, as well as a computing circuit containing a computing device with temperature and pressure converters, which is characterized by that the measuring circuit contains a flow divider with the formation of branches of different throughput capacity, in each branch there is a gas consumption volume meter of the corresponding measurement range, while the measuring ranges of the meters are selected with an overlap, and the measuring circuit (o) contains means of switching the gas flow in the corresponding branching, which is carried out automatically by a comparative selective switching device, which is part of a computer circuit, the mode of operation of which is set by a calculated accounting algorithm, taking into account the signals coming from the channels "from the measurement of the volume flow of gas in working conditions, the measurement of absolute pressure and in temperature measurement. is), c c Is) - and? 1 name) name) (o) - name) 60 b5