RU209886U1 - DEVICE FOR MEASURING INTENSE PRECITATION DROPS FROM WATER EMISSIONS INTO THE ATMOSPHERE - Google Patents

Abstract

The utility model relates to the field of measuring technology, namely to devices for the analysis of intensive precipitation of drops from water emissions into the atmosphere and can be used in systems for environmental monitoring of the atmosphere and industrial safety control. The technical result is the unification of the design of the device and the expansion of its functionality by increasing the accuracy of measuring the amount of intense precipitation of drops from water emissions with the simultaneous determination of their size in precipitation due to a significant expansion of the upper range of analysis of the amount of intense precipitation compared to the prototype device. To achieve it, a device is proposed for measuring intense droplet precipitation from water emissions into the atmosphere, including a droplet precipitation accumulator in the form of a dielectric bath installed horizontally, at the bottom of which there are parallel flat and mesh electrodes connected to an electronic unit, fixed on the upper end of the droplet precipitation accumulator. in the form of a dielectric bath, a set of string gratings for measuring the size of drops with a variable pitch from 1 to 10 mm from parallel and conductive threads with a diameter of 100 to 200 μm, connected in turn to a voltage divider and to ground, with each thread connected to the voltage divider connected with an individual channel of the analog-to-digital converter of the electronic unit of a set of string gratings, while parallel flat and mesh electrodes are installed vertically at the bottom of a horizontally located dielectric bath of the droplet sediment accumulator, the flat electrode is assembled from a set of identical, conductive plates fixed in parallel and separately from each other on a dielectric plate, and each conductive plate is connected to a voltage divider and connected to an individual channel of the analog-to-digital converter of the electronic unit of a set of identical conductive plates and a grid electrode, while the conductive plates are closed to the grid electrode through high resistance resistors. 2 ill.

Description

Technical field

The utility model relates to the field of measuring technology, namely to devices for analyzing intense droplet precipitation from water emissions into the atmosphere, and can be used in systems for environmental monitoring of the atmosphere and industrial safety control.

State of the art

Known devices for the analysis of precipitation, realizing their collection in special containers and determining the volume or mass of precipitation per unit time (Sternzat M.S. Meteorological instruments and observations, Gidrometeoizdat, 1968, pp. 166-172; I.V. Litvinov, Precipitation in the atmosphere and on the surface of the earth, Gidrometeoizdat, Moscow, 1980, 208 s). However, these devices do not allow remotely obtaining data on the intensity and amount of precipitation from clouds and water emissions with the determination of the size of large drops in precipitation.

An optical-acoustic-electronic device for determining the analysis of precipitation is known, in which the number of precipitation drops is converted into the number of electrical impulses due to the interruption of the laser beam by the drops, as well as the sound signal using a membrane and a microphone into an electrical signal (US Patent No. 3882381). Its disadvantage is the possibility of clouding the optics from precipitation, as well as the inability to simultaneously measure the amount of precipitation of large drops and their size in the atmosphere.

Known radar devices for remote analysis of precipitation of drops from clouds in the atmosphere, including a radar station (RLS) for sensing the atmosphere connected to an automatic data processing unit, and a precipitation gauge for its calibration (A.M. Borovikov, V.V. Kostarev, I.P. Mazin et al., Radar measurements of precipitation, Leningrad, Hydrometeorological Publishing House, 1967, 139 pp; IV Litvinov, Precipitation in the atmosphere and on the earth's surface, Gidrometeoizdat, Moscow, 1980, 208 pp). Using the data obtained, the coefficients of correlation functions are found taking into account the types of cloudiness and precipitation, which are then used to analyze precipitation. Their disadvantage is the presence of a "dead zone" and the impossibility of simultaneous analysis of the amount of precipitation of drops and their sizes.

A precipitation indicator is known, containing a measuring capacitor made in the form of a sectional winding with a distributed capacitance formed by two insulated conductors, signal processing units and a recorder (USSR Author's certificate No. 607168). In the indicator of atmospheric precipitation, the change in the capacitance of the capacitor under the influence of precipitation falling into the winding is converted into a sequence of electrical impulses, the frequency of which is proportional to the intensity of precipitation. However, this device is characterized by a low accuracy in measuring the intensity of precipitation, since the intensity of precipitation is determined both by the number of drops per unit time and by the size of the drops. In the same device, the precipitation intensity is determined only by the variable repetition rate of electrical impulses of equal duration. Therefore, the measurement result does not depend on the size of the droplets, which leads to significant errors in the analysis of precipitation.

A precipitation indicator is known in the form of an electrodynamic ratiometer, containing a first measuring capacitor open for free passage of precipitation through the space between the plates, made in the form of a sectional winding with a distributed capacitance formed by two insulated conductors, a second measuring capacitor identical to the first, but closed from the penetration of precipitation , and a block for converting changes in the capacitance of the first measuring capacitor into an output signal (RF patent No. 2097797). Its disadvantage is that it is not possible to determine the amount of intensive precipitation of drops from water emissions with simultaneous analysis of the size of large drops in sediments.

A device is known for analyzing intensive precipitation of drops from water emissions into the atmosphere, described in the article by A.V. Zagnitko, I.D. Matsukov, D.Yu. Fedin, Analyzers of intense precipitation of drops of fuel liquids and water, RF, Instruments and Experimental Techniques, 2019, No. 4, p. 153-154. The device contains two parallel electrodes of a flat electric capacitor, located vertically at the bottom of a horizontal sediment accumulator in the form of a dielectric bath, an electronic unit for measuring the electrical resistance between the plate electrodes during the accumulation of precipitation of water drops and transmitting data to a computer remote at a distance of up to 1200 m. Resistance change between the plate electrodes from time to time is proportional to the amount or intensity of filling the interelectrode volume with a deposit of water droplets. The disadvantage of this device is the impossibility of simultaneous analysis of precipitation and the size of large droplets in precipitation from water emissions into the atmosphere.

The closest in technical essence to the claimed utility model is a device for analyzing intense precipitation of water droplets in the atmosphere (RF patent for utility model No. 198802), including a droplet precipitation accumulator in the form of a dielectric bath at the bottom of which there are two flat solid and mesh electrodes of an electric capacitor, connected to the electronic unit to measure its electrical capacitance C during the accumulation of droplet precipitation with data transmission to a computer installed horizontally on the upper end of the precipitation accumulator in the form of a dielectric bath; up to 200 µm, alternately connected to the voltage divider and to the ground, and each thread connected to the voltage divider is connected to an individual channel of the analog-to-digital converter (ADC) of the electronic unit of the set of string gratings for measuring droplet sizes and transmitting data to a computer. This device allows you to simultaneously measure the distribution of large droplet diameters in precipitation and the amount of precipitation V by changing the capacitance C from time. Its value is proportional to V.

The disadvantage of the prototype device is the need to calibrate it for different types of water that differ significantly in electrical resistance (for example, sea and tap water), as well as a limited range of measuring the amount of intense precipitation during their long-term analysis, since the measured amount V is limited by the volume of the interelectrode space. The optimal distance between the electrodes is H(k) = 5-10 mm, and the maximum does not exceed 15 mm, since with increasing distance H(k) the capacitance C decreases inversely proportional to H(k), the influence of edge effects and electrical wires on the measurement accuracy increases small values С<100 pF. Finally, when the volume of the electric condenser is completely filled with water sediment, its analysis stops and, further, more than 100% error in their measurement takes place.

The technical problem to be solved by the claimed utility model is the unification of the design of the device for the analysis of intense droplet precipitation from water emissions into the atmosphere and the expansion of its functionality.

Disclosure of the essence of the utility model

The technical result of the claimed utility model is the unification of the design of the device for the analysis of intensive precipitation of drops from water emissions into the atmosphere and the expansion of its functionality by increasing the accuracy of measuring the amount of intense precipitation of drops from water emissions while simultaneously determining their size in precipitation due to a significant expansion of the upper range of analysis of the amount intense precipitation compared with the prototype device.

To achieve a technical result, a device for measuring intensive droplet precipitation from water emissions into the atmosphere, including a droplet precipitation accumulator in the form of a dielectric bath installed horizontally, at the bottom of which there are parallel flat and mesh electrodes connected to an electronic unit, fixed on the upper end of the droplet precipitation accumulator in the form of a dielectric bath, a set of string gratings for measuring the size of drops with a variable pitch from 1 to 10 mm from parallel and conductive threads with a diameter of 100 to 200 μm, connected in turn to a voltage divider and to ground, with each thread connected to the voltage divider connected with an individual channel of the analog-to-digital converter of the electronic unit of a set of string gratings, characterized in that parallel flat and mesh electrodes are installed vertically at the bottom of a horizontally located dielectric bath of the droplet sediment accumulator, the flat electrode is assembled from a set of the same new, conductive plates fixed in parallel and separately from each other on a dielectric plate, and each conductive plate is connected to a voltage divider and connected to an individual channel of the analog-to-digital converter of the electronic unit of a set of identical conductive plates and a mesh electrode, while the conductive plates are closed to mesh electrode through high-resistance resistors.

Vertical installation of parallel flat and mesh electrodes at the bottom of a horizontally located dielectric bath of a droplet sediment accumulator, manufacturing a flat electrode in the form of a set of horizontal, identical, conductive plates installed in parallel and separately from each other on a dielectric plate, connecting each conductive plate to a voltage divider and its connection with an individual channel of an analog-to-digital converter (ADC) of an electronic unit of a set of identical conductive plates and a grid electrode with data transfer to a computer, allows you to expand the functionality of the claimed utility model by increasing the accuracy of measuring the amount of intensive precipitation of drops from water emissions into the atmosphere with simultaneous determination of their sizes in precipitation due to a significant expansion of the upper range of the analysis of the amount and intensity of precipitation compared with the prototype device.

The optimal distance between vertical and parallel flat and grid electrodes does not exceed 5 mm. Horizontal, parallel and identical, conductive plates in the amount of 20 to 50 pieces are fixed on the dielectric plate separately at a distance of 1 to 2 mm from each other. Their length is 5-15 cm.

The sediment of water droplets through the mesh electrode enters the interelectrode space, which is closed from above by an umbrella to prevent drops from falling on the flat and mesh electrodes from above, which distorts the results of precipitation measurements.

The analyzed sediment of water droplets, as its level increases due to the accumulation of sediment between vertical and parallel flat and mesh electrodes, sequentially closes parallel, identical and +3.3 V voltage divider current-carrying plates, to the mesh electrode through high-resistance resistors. As a result, the voltage on the mesh electrode is proportional to the water level, and high-resistance resistors neutralize the effect of water resistance of various chemical compositions (sea, ground, water, etc.) on the voltage of the mesh electrode. The voltage from the grid electrode is fed to a follower with a high input impedance on the operational amplifier. From its output, the signal goes to a multichannel ADC, and, further, through an RS485 interface to a remote computer. Operational amplifier with high input impedance type AD8615, power supply up to +3.3 V, ADC and RS485 interface are part of the electronic unit of a set of conductive plates and a grid electrode with data transfer to a computer for their processing. Thus, the water level or the amount of droplet precipitation is determined by the number of closed contacts of parallel and identical conductive plates on the grid electrode and the selected distance between them, and the intensity of droplet precipitation is determined by the speed of measuring the closure of contacts of parallel and identical conductive plates to the grid electrode.

A technically reliable measured water level between vertical, parallel flat and grid electrodes can reach a height of more than 100-150 mm, depending on the distance between horizontal, parallel and identical conductive plates and their number, which significantly exceeds the distance between the electrodes of the capacitor H(k) ≤15 mm in the prototype device. As a result, the claimed device significantly expands the upper range of precipitation measurement and, accordingly, increases the accuracy of their measurement compared to the prototype.

The sensitivity of the proposed device when measuring precipitation drops is determined by the ADC capacity and the number of resistors in the voltage divider. The number of resistors is several times less than the capacity of the ADC to obtain reliable readings of the closure of the contacts of parallel and identical conductive plates to the grid electrode. The claimed device uses a 20-bit ADC, which is part of the STM32F030K6T6 microprocessor. The voltage divider includes 50 to 100 resistors. With a step or distance of 1 mm between adjacent parallel and identical conductive plates in the amount of up to 50 pieces with a width of 1 mm, a change in the water level is measured within 100 mm. The microprocessor calculates its quantity and transfers the data to the computer. The speed of the device is τ ≈ 0.01 s per reading.

A set of parallel string gratings is located perpendicular to the direction of movement of water drops. In the initial state, a voltage close to the supply voltage + (3-3.3) V is set at all inputs of the multichannel ADC of the electronic unit of the set of string gratings. When the flow of drops passes through the string grating, each ADC channel closes to the ground through a certain resistance due to the conductivity of water and the size of drops that simultaneously touch two adjacent thin conductive filaments. The filament closing signal is recorded by a high-speed ADC of the electronic unit of the array of string gratings. At its input, a voltage appears that fluctuates in the range from three volts to zero. By varying the pitch of string gratings from 1 to 10 mm, it is possible to determine the distribution of droplets over the diameter with d ≥ 1 mm. The frequency of filament closures makes it possible to calculate the distribution of droplets in sediments.

As a result, different size fractions of droplets in sediments are simultaneously measured using a set of string gratings with different pitches, as well as their number and intensity using a vertical droplet storage accumulator installed at the bottom of a horizontally located dielectric bath, a grid electrode and a flat electrode assembled from a set of identical and separated conductive plates fixed in parallel and separately on the dielectric plate.

This makes it possible to improve the technical characteristics of the claimed utility model and expand its functionality by increasing the accuracy of measuring the amount and intensity of precipitation of drops from water emissions of various chemical compositions while simultaneously determining their size in precipitation by expanding the upper range of measuring the amount and intensity of precipitation by more than 5 times. compared with the prototype device.

Brief description of the drawings

In FIG. 1 shows a diagram of a device for analyzing intensive droplet precipitation from water emissions into the atmosphere, in Fig. 2 shows a schematic measurement diagram of a set of string gratings of electrically conductive threads, in Fig. 3 shows a side view of a flat electrode from a set of conductive plates on a dielectric plate, FIG. 4 shows the electrical circuit for measuring droplet precipitation between the electrodes, where:

1 - flat electrode installed vertically;

2 - grid electrode installed vertically;

3 - sediment droplets from water emissions into the atmosphere;

4 - drop sediment accumulator in the form of a rectangular bath;

5 - a set of identical conductive plates fixed in parallel and separately on the dielectric plate 6;

6 - dielectric plate;

7 - the end face of the water droplet sediment accumulator, on which the string grating 11 is fixed;

8 - electronic unit of a set of conductive plates 5 and mesh electrode 2 with data transfer to a computer;

9 - multi-channel analog-to-digital converter of the electronic unit of a set of string gratings 11;

10 - electronic unit of a set of string gratings;

11 - a set of string gratings of electrically conductive threads;

12 - an umbrella made of dielectric to eliminate the ingress of sediment drops from above into the interelectrode space of flat 1 and mesh 2 electrodes;

13 - computer connected to electronic units 8 and 10 and remote at a distance of up to 1200 m from the place of analysis of droplets; 5.7, 5.2 ... 5.48, 5.49 - parallel, identical and conductive plates in a set 5 of flat electrode 1, located horizontally;

8.1 - operational amplifier of the electronic unit 8 of a set of conductive plates 5 and a mesh electrode 2 with data transfer to a computer 13;

8.2 - analog-to-digital converter of the electronic unit 8 of a set of conductive plates 5 and a mesh electrode 2 with data transfer to a computer 13;

8.3 - RS485 interface of the electronic unit 8 of a set of conductive plates 5 and a mesh electrode 2 with data transfer to a computer 13;

V is the amount of precipitation of drops in the accumulator 4;

U ₁ \u003d +3.3 V - supply voltage of the divider of the set of conductive plates 5 and the mesh electrode 2 from the electronic unit 8;

d - distance between vertical and parallel electrodes 1 and 2;

r1, r3 ... r97 and r99 - resistance of the voltage divider U ₁ \u003d + 3.3 V.

Δ - distance or step between the same and conductive plates in their set 5, fixed in parallel and separately on the dielectric plate 6;

β is the width of the same and conductive plates in their set 5, fixed in parallel and separately on the dielectric plate 6.

In FIG. 2, a schematic measurement diagram of a set of string gratings 11 of electrically conductive threads includes the following elements:

14 - dielectric frame for fastening electrically conductive threads;

15 - voltage divider U, including the first set of identical, parallel electrical resistances r1 connected to the power supply of the electronic unit of the string lattice 10 and to thin electrically conductive threads, and the second set of parallel identical electrical resistances R2, through which thin and electrically conductive threads are grounded;

I - a lattice of thin threads 1.1 r; 1.1 and 1.2r on frame 14 with step h ₁ ;

II - lattice of thin threads 2.1r; 2.1 and 2.2r on frame 14 with step h ₂ ;

III - lattice of thin filaments 3.1r; 3.1 and 3.2r on frame 14 with step h ₃ ;

IY - lattice of thin threads 4.1r; 4.1 and 4.2r on frame 14 with step h ₄ ;

1.1r and 1.2r - electrically conductive threads connected to the resistances r1 of the voltage divider 15 and to the ADC 9, located on the frame 14 and grounded through the same resistance R2;

1.1 - grounded, thin and electrically conductive thread on the frame 14;

2.1r and 2.2r - parallel, thin, and electrically conductive threads connected to the resistances r1 of the voltage divider 13 and to the ADC 9; located on the frame 14 and grounded through the same resistance R2;

2.1 - grounded, thin and electrically conductive thread on frame 14;

3.1r and 3.2r - parallel, thin and electrically conductive threads connected to the resistances r1 of the voltage divider 15 and to the ADC 9; located on the frame 14 and grounded through the same resistance R2;

3.1 - grounded, thin and electrically conductive thread on the frame 14;

4.1r and 4.2r - parallel, thin and electrically conductive threads connected to the resistances r1 of the voltage divider 15 and to the ADC 9; located on the frame 14 and grounded through the same resistance R2;

4.1 - grounded, thin and electrically conductive thread on the frame 14;

A - connection points of thin electrically conductive threads 1.1r; 1.2r; 2.1r; 2.2r; 3.1r;

3.2r; 4.1r and 4.2r to individual channels of ADC 9;

L is the length of thin electrically conductive threads;

R2 - a set of grounded and identical voltage divider resistances

15 connected to thin electrically conductive threads;

r1 - a set of identical resistances of the voltage divider connected to the supply voltage U and to thin electrically conductive threads;

h ₁ - lattice pitch I of thin threads 1.1r; 1.1 and 1.2r on frame 14 s;

h ₂ - lattice pitch II of thin threads 2.1r; 2.1 and 2.2r on frame 14;

h ₃ - lattice pitch III of thin threads 3.1r; 3.1 and 3.2r on frame 14;

h ₄ - lattice pitch 1Y of thin threads 4.1r; 4.1 and 4.2r on frame 14;

U=+(3-3.3) V - supply voltage of the divider 15 of the grating 11 from the power supply of the electronic unit of the string grating 10.

Implementation of the utility model

In FIG. 1 shows a schematic diagram of the claimed device for the analysis of intensive droplet precipitation from water emissions into the atmosphere. The device contains a droplet precipitation accumulator 3 in the form of a dielectric bath 4 installed horizontally, at the bottom of which parallel flat 1 and mesh 2 electrodes are located vertically. Flat electrode 1 is assembled from a set of identical conductive plates 5 fixed in parallel, horizontally and separately on a dielectric plate 6, and each horizontal conductive plate is connected to a voltage divider and connected to an individual ADC channel of the electronic unit 8 of a set of conductive plates 5 and a grid electrode 2 with transferring data to a computer 13.

A rectangular dielectric frame 14 is installed on the end face 7 of the droplet precipitation accumulator 4, on which a set of string gratings 11 is fixed, connected through a multichannel ADC 9 of the electronic unit 10 of a set of string gratings for their supply with voltage U, registration of droplet diameters and data transmission. A set of string gratings 11 is made with a variable pitch from 1 to 10 mm from parallel and conductive threads with a diameter of 100 to 200 μm, connected in turn to the voltage divider R2 and to the ground, and each thread connected to the voltage divider is connected to an individual channel of the ADC 9 electronic unit of a set of string gratings 10 with data transmission to the computer 13 via twisted pair (Fig. 1 and 2).

The optimal distance between vertical and parallel flat 1 and mesh 2 electrodes is d ≤ 5 mm. Horizontal, parallel, identical, conductive plates in the set 5 in the amount of 20 to 50 pieces are fixed on the dielectric plate 6 at a distance of Δ=1-2 mm from each other. Their length is 5-15 cm, and the width is β=0.5-1 mm.

The sensitivity of the proposed device when measuring precipitation drops is determined by the ADC capacity and the number of resistors in the voltage divider. Their number is several times less than the capacity of the ADC to obtain reliable readings of the closure of the contacts of parallel and identical conductive plates 5.1, 5.2 ... 5.49 to the grid electrode 2. A 20-bit ADC is used, which is part of the STM32F030K6T6 microprocessor (ST Microelectronics) of the electronic unit 8 a set of conductive plates 5 and a mesh electrode 2 with data transfer to a computer 13. The voltage divider includes from 50 to 100 resistors. At β=1 mm and a distance Δ=1 mm between adjacent contacts of horizontal, parallel and identical conductive plates from set 5 in the amount of 49 pieces, the change in water level from 0 to 100 mm is measured. The STM32F030K6T6 microprocessor calculates its level and transmits data to a remote computer 13 via an 8.3 interface of the RS485 type. The speed of the device in the analysis of droplets is τ ≈ 0.01 s per reading.

The sediment of water drops 3 through the mesh electrode 2 enters their interelectrode space, which is closed from above by an umbrella 12 made of a dielectric to eliminate drops falling from above onto flat 1 and mesh 2 electrodes. This eliminates the error in measuring the amount of precipitation of drops when the conductive plates are closed due to the ingress of large drops from above onto the conductive plates of set 5. The mesh electrode 2 is made of a woven wire mesh with a live cross section of its square cells up to 90%.

The resistances r1, r3 ... r97 and r99 form a voltage divider with its value U ₁ \u003d + 3.3 V. The analyzed sediment 3 drops of water as its level increases due to the accumulation of liquid between the vertical and parallel flat 1 and mesh 2 electrodes in series closes the horizontal, parallel , identical and connected to a +3.3 V voltage divider, conductive plates 5.1, 5.2 ... 5.48, 5.49 in set 5 to grid electrode 2 through high-resistance about 100 kOhm resistors R2, R4 ... R96 and R98. Thus, the voltage on the mesh electrode 2 is proportional to the water level or the amount of sediment V, and the high-resistance resistors R2, R4 ... R96 and R98 neutralize the effect of water resistance of various chemical compositions (sea, soil, etc.) on the voltage of the mesh electrode 2. Voltage from grid electrode 2 is fed to a follower with a high input impedance on an operational amplifier 8. 1 type AD8615. From its output, the signal is transmitted to the ADC 8.2 and, further, using the interface 8.3 type RS485 to the computer 13 for processing and storing data. Operational amplifier 8.1, power supply up to +3.3 V (not shown in Fig. 1), ADC 8.2 and interface 8.3 are part of the electronic unit 8 of a set of conductive plates 5 and grid electrode 2 with data transfer to computer 13. Thus, the water level and the amount of precipitation is determined by the number of closed contacts of parallel and identical conductive plates 5.1, 5.2 ... 5.48, 5.49 in set 5 on the mesh electrode 2 and the selected distance Δ between them, and the intensity of droplet precipitation is determined by the speed of measuring the closure of contacts of parallel and identical conductive plates to the mesh electrode.

A technically reliable measured water level between vertical, parallel flat 1 and grid 2 electrodes can reach a height of more than 100 mm depending on the step Δ and the number of conductive and parallel plates in their set 5, which significantly exceeds the distance H(k) ≤ 15 mm between flat capacitor electrodes in the prototype device. As a result, the claimed device significantly expands the upper range of measuring the amount and intensity of sediment and, accordingly, increases the accuracy of their measurement over time compared to the prototype.

Installed on a rectangular dielectric frame 14, a set of string gratings 11 is assembled from parallel four string gratings I; II; III and IY, containing parallel and electrically conductive tungsten filaments with a diameter of 100 to 200 μm (Fig. 2). Lattice I includes threads 1.1r; 1.1 and 1.2r with step h ₁ . Lattice II contains threads 2.1r; 2.1 and 2.2r with step h ₂ . Lattice III includes threads 3.1r; 3.1 and 3.2r with step h ₃ . The lattice IY consists of threads 4.1r; 4.1 and 4.2r with step h ₄ . Voltage divider 15, to which the ends of a set of electrically conductive threads of string gratings 11 are connected, consists of resistance r1 connected to a +3.3 V power source and grounded resistance R2, the value of which is R2 >> r1. The value of r1 is chosen commensurate with the resistance of the analyzed water drops.

The length of thin and electrically conductive filaments of each string grating is L=10-20 cm and is significantly greater than their diameter D=100-200 μm and grating pitch h=1-10 mm. The optimal values of their step h _i =1; 2.5; 5 and 10 mm, where i=1; 2; 3 and 4. Technical fabrication of a string grating with a step h < 1 mm is difficult. Increasing h > 10 mm is impractical, since the diameters of water droplets in the atmosphere reaching the earth's surface, as a rule, are d ≤ 5-10 mm, due to their aerodynamic fragmentation by atmospheric air flows (Rist P. Aerosols, introduction to theory. Moscow. Mir. 280 pp. 1987). String grating step h _i >>D. Thin filaments are made of tungsten. The choice of their diameter from 100 to 200 microns is determined by the requirements of mechanical strength when the threads are tensioned on the dielectric frame and the ratio of h/D>>1.

A set of parallel string gratings 11 is located perpendicular to the direction of movement of water drops. In the initial state, a voltage close to the supply voltage + (3-3.3) V is set at all inputs of the multichannel ADC 9. When the flow of drops passes through the string grating, each channel of the ADC 9 closes to the ground through some resistance due to the conductivity of water and the size of the drops, simultaneously touching two adjacent thin conductive threads. The filament closing signal is recorded by a high-speed ADC 9 of the electronic unit 10 of a set of string gratings 11. At its input, a voltage occurs that fluctuates in the range from three volts to zero. By varying the pitch of string gratings from 1 to 10 mm, it is possible to determine the distribution of droplets over the diameter c d ≥ 1 mm. The claimed device used a microprocessor STM32L152RBT6A ST Microelectronics with a 20-channel ADC 9. Its speed was 1 ms with data transfer via the RS485 interface to the computer 13.

When analyzing the precipitation of droplets from water emissions into the atmosphere, the device is installed on a mast with a height of 0.5 to 3 m.

As a result, different fractions of droplet sizes in sediments 3 are measured using a set of string gratings 11 with different pitches h _i . At the same time, the amount of intense precipitation 3 is measured using a vertically installed at the bottom of a horizontally located dielectric bath 4 a rainfall accumulator 3, a mesh electrode 2 and a flat electrode 1, assembled from a set of identical and separated conductive plates 5, fixed horizontally, in parallel and separately on a dielectric plate 6. Thus, the technical result of the proposed device is achieved. Example.

We analyzed at a temperature of 5-7°C the precipitation of drops with a diameter of d ≈ 100-10000 μm from the release of groundwater with a volume of more than 10 ⁵ m ³ in the form of a submerged jet into the atmosphere. The signal from the device, located on a mast 0.5 m high and at a distance of 10 m from the center of water ejection, was synchronized with the start time of its ejection.

The optimal distance between the vertical and parallel flat 1 and mesh 2 electrodes d=4 mm. Horizontal, parallel, identical, conductive plates 5.1, 5.2 ... 5.49 made of copper in a set 5 in the amount of 49 pieces were fixed on a dielectric plate 6 made of caprolon. The distance between them Δ=1 mm, their length was 15 cm, and the width β=0.8 mm.

When registering droplet precipitation, a 20-bit ADC was used, which is part of the STM32F030K6T6 microprocessor (ST Microelectronics), electronic unit 8 of a set of conductive plates 5 and grid electrode 2 with data transfer to computer 13.

The sediment of water drops 3 through the mesh electrode 2 entered their interelectrode space, which was closed with an umbrella 72 made of caprolon to prevent drops from falling on flat 7 and mesh 2 electrodes from above. Grid electrode 2 was made of wire woven copper mesh with a live cross section of its square cells of about 52%.

Resistances r1, r3 ... r97 and r99 each with a value of 10 ohms were used to create a voltage divider with its value U ₁ \u003d + 3.3 V. The analyzed sediment is 3 drops of water as its level increases due to the accumulation of liquid between vertical and parallel flat 1 and mesh 2 electrodes in series closed parallel, identical and connected to a voltage divider +3.3 V conductive plates 5.1, 5.2 ... 5.48, 5.49 to the grid electrode 2 through high-resistance 100 kΩ resistors R2, R4 ... R96 and R98. Thus, the voltage at grid electrode 2 was proportional to the level of water or sediment, and 100 kΩ resistors leveled the influence of the electrical resistance of groundwater on the voltage of grid electrode 2. The voltage of grid electrode 2 was fed to a follower with a high input resistance on an AD8615 type operational amplifier 8.1. From its output, the signal was fed to the ADC 8.2 and, further, using the interface 8.3 of the RS485 type, it was transmitted to the computer 13 for processing and storing data. The STM32F030K6T6 microprocessor calculated the water level up to 80 mm and transmitted the data to a remote computer 13 via an 8.3 interface of the RS485 type. The speed of the device for measuring precipitation of water droplets was τ ≈ 0.01 s per reading. As a result, the amount of precipitation of droplets from the ejection of water was measured over time. It was found that during the first 20 s more than 80% of the mass of precipitation fell with a maximum intensity of about 2 mm/s. The recorded maximum water level was 80 mm.

On a rectangular dielectric frame 14 made of caprolon, the following four string gratings I were installed in parallel and in series; II; III and IY from thin and electrically conductive tungsten filaments 15 cm long and 200 µm in diameter:

I - lattice of thin filaments 1.1r; 1.1 and 1.2r with h ₁ =1 mm;

II - lattice of thin threads 2.1r; 2.1 and 2.2r with h ₂ = 2.5 mm;

III - lattice of thin filaments 3.1r; 3.1 and 3.2r with h ₃ =5 mm;

IY - lattice of thin threads 4.1r; 4.1 and 4.2r with h ₄ =10 mm.

In the process of data analysis, a microprocessor with a 20-channel ADC 9 of the STM32L152RBT6A type from ST Microelectronics was used. Its speed was 1 ms with data transfer via the RS485 interface to the computer 13. In the voltage divider 15, the resistance R2=10 ⁶ Ohm, and the value r1=1.2×10 ⁵ Ohm. Supply voltage U=+(3-3.3) V.

At optimal values h _i =1; 2.5; 5 and 10 mm diameters of droplets in their sediment were measured with d ≥ 1 mm; with d ≥ 2.5 mm and with d ≥ 5 mm, as well as droplets with a diameter of more than 10 mm. The frequency of filament closures in lattices I-IY made it possible to calculate the distribution of large droplets in the sediment. As a result, the maxima of their countable and mass size distributions were, respectively, drops with d ≈ 1–2.5 mm and with d ≥ 5 mm.

Thus, a comparison of the characteristics of the claimed device for the analysis of intense droplet precipitation from water emissions into the atmosphere with the prototype shows that the claimed utility model allows you to increase the accuracy of measuring the amount and intensity of droplet precipitation from water emissions of various chemical composition while simultaneously determining their size in precipitation due to expansion the upper range of measuring the amount and intensity of precipitation by more than 5 times compared with the prototype device.

Claims (1)

A device for measuring intense droplet precipitation from water emissions into the atmosphere, including a droplet precipitation accumulator in the form of a dielectric bath installed horizontally, at the bottom of which there are parallel flat and mesh electrodes connected to an electronic unit, fixed on the upper end of the droplet precipitation accumulator in the form of a dielectric bath a set of string gratings for measuring droplet sizes with a variable pitch from 1 to 10 mm from parallel and conductive filaments with a diameter of 100 to 200 µm, alternately connected to a voltage divider and to ground, with each filament connected to the voltage divider connected to an individual analog channel - a digital converter of the electronic unit of a set of string gratings, characterized in that parallel flat and mesh electrodes are installed vertically at the bottom of a horizontally located dielectric bath of a droplet sediment accumulator, a flat electrode is assembled from a set of identical conductive plates, fixed data in parallel and separately from each other on a dielectric plate, and each conductive plate is connected to a voltage divider and connected to an individual channel of the analog-to-digital converter of the electronic unit of a set of identical conductive plates and a grid electrode, while the conductive plates are closed to the grid electrode through high-resistance resistors.

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