SU1288531A1 - System for sampling and analyzing air from flat ground pollution sources - Google Patents

Abstract

The invention relates to a system for sampling and analyzing air samples from flat ground-based sources of pollution, can be used in the chemical and petrochemical industry, and allows to increase the accuracy of control and reduce the time of analysis. The system comprises a wind direction measuring instrument 10 connected in series and a selection point selection unit 7 comprising a multi-level comparator 8 and a code converter 9. The outputs of the latter are connected to switching devices 2, 3, the inputs of which are connected to samplers 1, and the outputs respectively to valves 4 and 5, which are connected to the common collector of sensors 6 and connected to an inducer-16 flow. The outputs of the sensors 6 are connected to a computing device 17 connected to a wind speed meter 18. The inlets of the valves 4, 5 are also connected to the gate device 11, which contains the reference source 12, the pulses, the frequency divider 13, connected to the output amplifiers 14, 15. 2, or 2 tabl. (L LfSpoc 1 omMoaptpy Flash

Description

The invention relates to instrumentation, in particular to the means of selecting and analyzing industrial emissions into the atmosphere, and can be used in the chemical, petrochemical, nitrogen-fertilizer and other industries to control emissions from the refining zone: oil traps, basins, non-collectors and other flat land sources.

The purpose of the invention is to improve the accuracy, control while reducing the time of analysis.

FIG. 1 shows a flowchart 5 of the sampling and analysis system for air samples from flat ground-based sources of charge J in FIG. 2 - conditional image of the emission source and collection points.

The system consists of. samplers 1, the inputs are located around the perimeter of the source of pollution, switching devices 2 and 3; solenoid valves 25 and 4 and 5 and connected in parallel to a common collector of automatic sensors 6 concentrations. The selection of sampling points required for control is carried out with jjj using the block 7 for selecting sampling points consisting of a multilevel comparator 8 and a converter of 9 codes,

The input of the selection point selection unit 7 is connected to the output of the automatic ,,,, gauge 10 wind direction. Selection point selection block 7 has two code outputs, one of which is designed to transmit the code of the required selection point from the lee of the source to the switching device 2, and the other output to transfer the code of the selection point from the upstream side of the source to the switching device 3, The gateway 45 device 115, consisting of a source 12 of reference pulses, a frequency divider 13 and two output amplifiers 14 and 15j connected to the direct and inverse outputs of a frequency divider 13 eg, is connected to control inputs of the electromagnetic x valves 4 and 5 are mounted on the outputs of the first 2 and second 3 switching devices. One of the outputs, 55 of the solenoid valve, is connected to the collector in parallel: the inputs of the automatic sensors 6 concentrations, and the other output of each

solenoid valves 4 and 5 are connected to the inlet of the flow driver 16. The outlets of the automatic x concentration sensors 6 can be connected to the inputs of the computing device 17. associated with the wind speed meter 18.

Blocks 2 and 3 (switching devices) are mounted on commercially available electropneumatic valves of type SKN installed in blocks in parallel. The pneumatic outputs of the pneumatic valves are connected to the gas intake line m 1, the outputs are interconnected and connected to the input of the solenoid valves 4 and 5, and the control inputs through the connector are connected to the converter 9 codes.

As an automatic meter of 10 wind directions, a commercially available instrument is used — an anemorumbograph MBZ-MR, which has an analog output with a level of -. spins from 0-100 mV.

Selection point selection block 7 consists of two subblocks — a multilevel comparator 8 and a converter of 9 codes. The multilevel comparator 8 is built according to the standard scheme, which is a series-connected serial differential amplifiers of the type 521CA1, the outputs of which are connected in pairs to the Exclusive-OR elements — serial chips of the type 155LI5.

The setpoints are controlled by adjusting the reference voltages at the inputs of the differential amplifiers,. The code converter is executed on parallel-connected microcircuits AND of type 155 LAZ, the outputs of which are connected in parallel to microcircuits of OR type LEZ. The number of parallel-connected microcircuits corresponds to the number of signaling subbands coming from block 10 (that is, the number of amplifiers 521Ca1). The implementation of the correspondence table is ensured by the appropriate switching of the chip outlets, i.e. connecting the inputs of the chips And to a logical zero or one.

The system works as follows:

From the code of the automatic gauge 10 of the direction of the wind, there comes an e, a spectral signal proportional to the angle to the mellada wind direction and

north direction. This signal enters the selection point selection block 7, where it is compared with a set of settings (specified voltages) in multi-level comparator 8 (a correspondence table is compiled). This selects a subrange whose upper limit (setpoint) limits the signal from above and the lower limit from below.

The correspondence table is set as follows: the image is constructed: the source, emissions and selection points, taking into account its orientation relative to the direction to the north, the selection points are numbered (figure 2 for different wind directions in the range 0-360 conditional planes are determined and the most The closest and furthest sampling points, the numbers of the closest and furthest points are given in Table 1.

Assigning a sequence number to each of the sub-ranges of wind direction, a table is obtained corresponding to VIY in the form of Table 2.

The subrange code enters the code converter 9, where it is converted into the code of the leeward sampling point code and the code of the windward sampling point. The correspondence table, which determines the code conversion, depends on the number and location of control points on the source source orientation relative to the north direction and The number of subbands of the signal from the wind direction meter 10 is determined by switching the leads of the converter chips 9 of the codes.

The selection of the nearest and furthest points in this case is made from the in-depth views. With a complex source configuration, this selection is made using ordinary geometric ratios by calculating distances from each selection point to a conditional plane and choosing the maximum and minimum distances.

The code of the leeward sampling point number is fed to the first switching device 2, and the code of the Windward sampling point number to the second switching device 3. In this case, the gas sampling lines of samplers 1 corresponding to the selected numbers of sampling points are connected to the inputs of the switching devices.

samples. A strobing device 11 with a predetermined frequency connects the input of each solenoid valve 4 and 5 either to a measuring output connected to automatic concentration sensors .6 or to a reset output connected to a flow booster 18 and further to the atmosphere.

The switching frequency can be varied over a wide range using a frequency divider 13. The output amplifiers 14 and 15, installed in the output circuits of the gate device, are used to match the electrical parameters of the frequency divider 13 to the load characteristics of the control windings of the solenoid valves 4 and 5.

When the input of the solenoid valve 4 is connected to the measurement output, the sample from the output of the first switching device (subtraction sampling point) enters the input of the automatic concentration sensors 6, where the content of various contaminating components in the sample is analyzed. The output of the reset of the first solenoid valve 4 is cut off from its input. At the same time, the inlet of the second solenoid valve is connected to the outlet of the discharge, and the sample from the output of the second switching device 3 (windward sampling point) is discharged into the atmosphere through the flow booster 16. When the polarity of the signal coming from the gate device 11 changes, the input of the second electromagnetic valve 5 is connected to the measurement output, and the reset output is cut off from the input of valve 5, and the sample from the wind selection point goes to the automatic concentration sensors 6 . In this case, the inlet of the first solenoid valve 4 is connected to the discharge outlet, and the measurement output of the first solenoid valve 4 is cut off from its inlet, and the sample from the leeward sampling point enters the booster T6. This measurement cycle is repeated at a predetermined frequency.

The signals from the automatic sensors 6 concentrations are fed to the computing device 17, where, according to the concentrations of pollutants from the windward and leeward sides of the source, and also the information coming from the automatic wind speed meter 18 and the geometric dimensions of the emission source This calculates the mass emission from the source of the contaminants.

Claims (1)

Invention Formula A system for sampling and analyzing air samples from flat ground-based sources of pollution, containing samplers located at predetermined points of the source of pollution and connected to a switching device, concentration sensors connected to a common collector, and a flow rate stimulator, characterized in that, in order to increase accuracy of control with simultaneous reduction of analysis time, it is equipped with a second transducer n - o (90 ° o (. + 180 ° dL + 270 ° d. + 270 otp 360 1 2 3 4 5 a switching device connected by inputs to samplers parallel to the first switching device, solenoid valves, a wind direction meter, a control point selection unit connected by an input to a wind direction meter, and the first and second outputs are to control inputs, respectively, of the first and second switching devices, and gating by a device, one output of which is connected to the control input of the first electromagnetic valve, and the other output to the control input of the second electromagnetic valve, while the output of each switching device alternately through the corresponding The solenoid valve is connected to the common collector of the concentration sensors or to the flow booster. Table 1 5 7 1 3 5 1 3 5 7 1 five 7 1 3 5  Ain Editor A. Shishkin Compiled by N, Romannikova Tehred L. Oleynik Proofreader A. Tsk Order 7798/39 Circulation 799 Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., d, 4/5 Production and printing company, Uzhgorod, st. Project, 4 Wus.Z