CS254714B1 - Measuring device for small horizontal velocities of streaming - Google Patents

Abstract

The solution lies in the field of anemoraetry. It solves flow rate measuring device in the range of 0.5 to 20 cm / s. Equipment it has a probe in which it is located resistance marker transmitter and two temperature sensors. The transmitter is connected to voltage-current converter. The sensors are connected to a constant source current that are further coupled to the amplifier and memory integrators. All these circuits are connected to a control microcomputer via bus and digital-analog or analog-to-digital converters. They are also connected to the bus blocks of binary inputs - outputs and counters. The device probe has three identical ones sieves in the shape of vertically oriented meanders of a resistive wire forming a transmitter and two sensors.

Description

The present invention relates to a device for measuring low horizontal flow rates, e.g.

There is known a device for measuring the velocity of a flowing fluid, i.e. a gas or a liquid, a mixture thereof, true and false solutions and melts, provided with means for generating thermal impulses transmitted to portions of the flowing fluid, e.g. in the direction of movement of a portion of the fluid, thus affected as a so-called temperature mark, two temperature-sensitive sensors are mounted in series. These sensors are shown in the known device as a point, for example, a thermistor, a thermocouple, a resistance thermometer, a semiconductor sensor, and are located in the axis of the affected fluid flow. The sensor electrical connections are connected via amplifiers to two counter inputs, which are connected to an oscillator.

The inverse value in the binary system, which is available in the counter, is fed to a binary-decodic decoder with digitron tubes. This device is intended in particular for measuring the flow velocity of liquids at high temperatures and at high pressures. It is not suitable for the measurement of said small velocities. First of all, it is not possible to use a heating coil as a temperature tag transmitter, which heats only a narrow strip of air mass and the temperature tag thus formed disintegrates into immeasurable temperature differences before its forehead passes by both sensors.

However, even when the heat tag is formed by passing air through the heating grid, there is a problem of thermal flow. Within the range of flow velocities considered, the temperature tag is plotted upward and its passage through the point sensors is not reproducible. Therefore, it is necessary to select a small temperature elevation of the mark in order to avoid a relatively significant thermal flow. However, even under this condition, point temperature sensors do not comply. Furthermore, it is necessary to precisely compensate the ambient temperature of the sensors and eliminate the influence of temperature and current fluctuations in their surroundings.

These problems are eliminated by a device for measuring low horizontal flow velocities, for example a breeze of air, provided with a probe, in which a temperature tag transmitter is placed downstream and successively first and second temperature sensors according to the invention are based on the fact that the temperature tag transmitter is connected to the output of the voltage-current converter, the input of which is connected to the output of the third digital-analog (D / A) converter, which is connected to the microcomputer for controlling measurement and data processing via bus. with inputs of the first D / A converter with outputs of the first A / D converter i with inputs of the second D / A converter with outputs of the second A / D converter with inputs - outputs of programmable counter block and with inputs of block of binary inputs - outputs.

The first temperature sensor is connected by the power input of its temperature-dependent resistor to the current output of the first constant current source, the voltage output of which is connected to the second input of the first amplifier, the output of which is connected simultaneously to the input of the first analog-digital (A / D) converter and the first input. a first memory integrator whose output is coupled to a third input of the first amplifier, the first input of which is coupled to the output of the first D / A converter. The second temperature sensor is connected by the power input of its temperature-dependent resistor to the current output of the second constant current source, the voltage output of which is connected to the second input of the amplifier, the third input of which is connected to the output of the second memory integrator. binary inputs - outputs with the second input of the first memory integrator, the third input of which is connected simultaneously with the second output of the binary inputs - outputs block and the third input of the second memory integrator, the first input of which is connected simultaneously with the input of the second A / D converter whose first input is connected to the output of the second D / A converter

The third output of the block of binary inputs - outputs is connected to the input of the attestation block, whose output is connected to the input of the block of binary inputs - outputs. The probe is provided with a sheath consisting of a horizontally situated open insulator tube between which three shape-identical gratings form a resistance temperature transmitter, a first sensor and a second temperature sensor in the form of vertically oriented meanders, the ends of which are conductively connected to the foils insulated on the outer surface of the shell.

The advantages of the device according to the invention are that the effect of temperature and current temperature fluctuations is eliminated by measuring the set of values and statistical processing it. The attestation curves are stored in the microcomputer memory, so that the microcomputer evaluates the actual flow rate in both measurement modes by the device as an anemometer or flowmeter. The microcomputer enables to automate the procedure of attestation of the device.

This is very advantageous because many time-consuming measurements are needed and processed statistically. Attachment of attestation track block enables block of inputs - outputs. The arrangement of the temperature sensor transmitter and the two temperature sensors as identical grids allows the probe to be miniaturized so that the distance between the two sensors can only be one order of magnitude greater than their flatness tolerance value. The vertical orientation of the grid meanders will ensure reproducibility of the measurement even when the thermal stroke of the mark is applied, since all vertical parts of the sensor grid meanders are always affected by its face.

An exemplary embodiment of the device according to the invention is shown in the accompanying drawings. Figure 1 is a side view of the probe of the device; Figure 2 is a plan view thereof;

FIG. 3 is a view of the probe in the flow direction. Giant. 4 shows a plan view of the front of the temperature mark and its disintegration under conditions of low flow velocities comparable to the thermic flow, where the source is a heating coil oriented axially perpendicular to the surface of the drawing.

Giant. 5 shows a plan view of the front of the temperature mark and its disintegration under the same flow conditions, but the source of which is a set of parallel heating wires oriented perpendicular to the surface of the drawing, which is the physical nature of the probe. Giant. 6 shows the wiring of the device according to the invention.

In a particular example, a device for measuring low horizontal flow rates, such as a breeze of air, is provided with a probe. 1, in which a temperature tag transmitter 22 is placed downstream, followed by a first sensor 34 and a second temperature sensor 44, respectively. The power input 223 of the RTD 22 is coupled to the output 213 of the voltage / current converter 21, whose input 212 is coupled to the output 202 of the third D / A converter 20, which is coupled to the microcomputer 10 via the bus 10. which is simultaneously connected to inputs 301 of the first A / D converter 30 and outputs 351 of the first A / D converter 35 i to inputs 401 of the second D / A converter 40 and outputs 451 of the second A / D converter 45 i with inputs - outputs 501 of programmable block counters 50 i with inputs - outputs 601 of binary-inputs block, »outputs 60.

The first temperature sensor 34 is coupled to the temperature output 332 of its first constant current source 33 by its power input 342, its voltage output 333 being coupled to the second input 313 of the first amplifier 21, whose output 314 is coupled to the input 354 of the first A / D. and the first input 324 of the first memory integrator 32, whose output 327 is coupled to the third input 317 of the first amplifier 31, whose first input 312 is coupled to the output 302 of the first D / A converter 30. The second temperature sensor 44 is connected to the power input 442 of its temperature-dependent resistance to the current output 432 of the second constant current source 43, whose voltage output 433 is coupled to the second input 413 of the second amplifier 41, the third input 417 is coupled to the output of the second memory interconnector 42, the second input 425 is coupled to the first output 605 block of binary inputs - v steps 60 with the second input 325 of the first memory integrator 32, whose third input 326 is coupled simultaneously with the second output 606 of the binary input-output block 60 and the third input 426 of the second memory integrator 42, whose first input 424 is connected simultaneously with input 454 of the second A / The D converter 45 is also output 414 of the second amplifier 41, the first input 412 of which is coupled to the output 402 of the second D / A converter 40.

The third output 602 of the binary input / output block 60 is coupled to the input of the attestation track block 70, the output of which is connected to the input 603 of the binary input / output block 60.

The probe p is provided with an open insulating pipe jacket 2 between which three grids 4 are stretched between the upper and lower parts, forming a temperature sensor 22, a first sensor 34 and a second temperature sensor 44 in the form of vertically oriented meanders, the ends of which are conductively connected with sheets 5 insulated to each other on the outer surface of the sheath 2, preferably made of cuprextite. To the films left after etching, the leads of the resistance transmitter 22 as well as the first sensor 34 and the second sensor 44 are soldered or welded by discharge.

The probe holder 13 is brazed to the films 5 on the top of the housing 2. All three grids 6 are identically shaped, only the wire diameter of the transmitter 22 is one order of magnitude higher than the wire diameter of the first sensor 34 and the second sensor 44. For example, a wire of 0.1 mm diameter was chosen for the transmitter 22, 0.02 mm.

In operation of the device according to the invention, the microcomputer 10 for the selected measuring range of the device programmatically adjusts the level of the temperature increase of the mark by a third D / A converter 20 whose voltage signal is converted to current in the voltage-current converter 21 operating as a constant current source. Also, the first sensor 34 and the second sensor 44 also operate as constant current resistors from the current outputs 332, 432 of constant current sources 33, 43 of the order of tens of mA, the change in resistance of the sensors 34 44, depending on the change in the temperature of the air stream by the flow probe, is converted in the sources 34, 43 to a voltage level change at their voltage outputs 333, 433.

Temperature compensation is performed before each measurement. The microcomputer 10 senses the output voltage of the amplifiers 31, 41 via A / D converters £ 5, £ 5. If the voltages are not approximately zero, it calculates a new digital compensation value and stores it in the D / A converters £ 0, £ 0. The entire process is repeated after a time delay necessary to stabilize the analogue ratios until the output voltages of the amplifiers 31, 41 are within a certain range of about zero. The following is an analogue analogue compensation using the memory integrators 32, 42.

The microcomputer 10, via the first output 605 of the I / O block, commands the memory integrators 32, 42 to integrate and cancel the reset mode that was introduced by the second output 606 of the I / O block. The outputs 314, 414 of the amplifiers 31, 41 are connected to the inputs 324, 424 of the memory integrators 32, 42, so that the output voltage of the amplifiers 31 is integrated and its inverse integrated value is fed back to the inputs 317, 417 of the amplifiers 46, 41. The integration mode takes sufficient time to fully compensate the ambient temperature of the sensors 34, 44.

The microcomputer 10 commands the memory integrators 42, 42 to enter memory mode. The actual measurement starts by writing a certain value corresponding to the size of the mark into the third D / A converter 20, whose output voltage is converted to the corresponding current in the voltage-current converter 21 and it starts to heat the mark transmitter. The microcomputer 30 now monitors the digitized output of the first amplifier 31 via the first A / D converter 35 and compares it to the selected value. Once the temperature mark is drawn by the flowing fluid to the first sensor 34, it heats up considerably and the output of the amplifier 31 changes. When it reaches the selected value, programmable counter block counters 50 are programmed to measure the mark's flight time.

Now the microcomputer 10 monitors the output of the second amplifier of the mark 41. When it reaches the specified value, the counters of the programmable counter block 50 are stopped and the mark flight time is read. Now the microcomputer 10 monitors the cooling of the probe. At certain intervals, e.g.

s, measure the output voltage of amplifiers 31, 41 many times and calculate the average. This compares with the past average. If the temperature of the sensors 34, 44 decreases, the process is repeated until the temperature of the sensors 34, 44 starts to fluctuate for the first time due to the fluctuation of the outside temperature. From this point on, the sensors 44, 44 are considered to be cold, the ambient temperature is compensated and a new measurement is started. All time intervals are measured using a programmable counter block 50.

Use of the device according to the invention is possible either for spatial flow anemometry, for example in air-conditioned rooms, or for measuring air flow through a cross-sectional area of the probe housing, for example for measuring filtering speeds.

Claims (3)

Apparatus for measuring low horizontal flow velocities, such as an air breeze, provided with a probe, in which a temperature tag transmitter is placed downstream, followed successively by first and second temperature sensors, characterized in that the power input (223) of the resistance transmitter (22) is connected to the output (213) of the voltage-current converter (21), the input (212) of which is connected to the output (202) of the third D / A converter (20), which is connected to the microcomputer (10). ) by means of a bus (101) which is simultaneously connected to the inputs (301) of the first D / A converter (30) as well as the outputs (351) of the first A / D converter (35) and the inputs (401) of the second D / A converter 40) with outputs (451) of the second A / D converter (45) i with inputs-outputs (501) of the programmable counter block (50) and with inputs-outputs (601) of the binary I / O block (60), while the first sensor ( 34) temperature is p connected by the power input (342) of its temperature-dependent resistance to the current output (332) of the first constant current source (33), the voltage output (333) of which is coupled to the second input (313) of the first amplifier (31) connected simultaneously to the input (354) of the first A / D converter (35) and the first input (324) of the first memory integrator (32), the output (327) of which is coupled to the third input (317) of the first amplifier (31) (312) is coupled to the output (302) of the first D / A converter (30), wherein the second temperature sensor (44) is connected to the current output (432) of the second constant current source (43) whose voltage output (433) is coupled to the second input (413) of the second amplifier (41), whose third input (417) is coupled to the output (427) of the second memory integrator (42), whose second input (425) is coupled simultaneously with the first out the binary I / O block (605) with the second input (325) of the first memory integrator (32), the third input (326) of which is connected simultaneously with the second output (606) of the binary I / O block (60) with the third an input (426) of a second memory integrator (42), the first input (424) of which is connected simultaneously to the input (454) of the second A / D converter (45), and the output (414) of the second amplifier (41) it is coupled to the output (402) of the second D / A converter (40). Device according to claim 1, characterized in that the third output (602) of the binary input-output block (60) is connected to the input of the attestation block block (70) whose output is connected to the input (603) of the binary input-output block (60). ). Device according to claim 1, characterized in that the probe (1) is provided with a jacket (2) formed by an open insulating tube, between whose upper and lower parts are stretched three grids (4) forming resistance temperature transmitters (22), the first a sensor (34) and a second temperature sensor (44) in the form of vertically oriented meanders, the ends of which are conductively connected to the foils (5) mutually insulated to each other on the outer surface of the housing (2).