RU2754716C1 - Ultrasonic locator measurement error compensation device - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: invention relates to ultrasonic location meters for the level of liquid and bulk products. The ultrasonic locator measurement error compensation device contains an ultrasonic pulse generator connected to an emitter, a receiver connected to an amplifier, to the output of which two threshold devices with different threshold voltages are connected, two reference voltage sources connected to the inputs of the corresponding threshold devices, the outputs of the threshold devices are connected to the corresponding time interval generation units, the outputs of which are connected to the control and display unit, the outputs of which are connected to the input of the generator and to the input of the first time interval generation unit. As reference voltage sources, adjustable reference voltage sources with variable voltage are used, the inputs of which are connected to the outputs of the corresponding regulators, the inputs of which are connected to the control and display unit. In this case, the output of the first time interval generation unit is connected to the second input of the second time interval generation unit.

EFFECT: reduction of measurement errors.

1 cl, 2 dwg

Description

The invention relates to ultrasonic location meters for liquid level in tanks at gas stations and oil depots, bulk products in granaries, distance in robotics and other sectors of the national economy.

Known device for compensating the measurement error of an ultrasonic level gauge [RU 75034 U1, IPC G01F23 / 28 (2006.01), publ. 07/20/2008], containing an ultrasonic pulse generator connected to the emitter, a receiver connected to an amplifier, to the output of which two threshold devices with different threshold voltages are connected. A reference voltage source is connected to the input of each threshold device. The output of the first threshold device is connected to the first and second blocks for generating the time interval. The output of the second threshold device is connected to the second block for generating the time interval. The outputs of the first and second blocks for forming the time interval are connected to the control and display unit, the outputs of which are connected to the generator and the first block for forming the time interval.

This device has a low measurement accuracy due to the arbitrary choice of the threshold voltage.

The technical result of the invention is to create a device that reduces the measurement error.

The proposed device for compensating the measurement error of an ultrasonic locator, as in the prototype, contains an ultrasonic pulse generator connected to the emitter, a receiver connected to an amplifier, to the output of which two threshold devices with different threshold voltages are connected, two reference voltage sources connected to the inputs of the corresponding threshold devices, the outputs of the threshold devices are connected to the corresponding blocks for the formation of the time interval, the outputs of which are connected to the control and display unit, the outputs of which are connected to the input of the generator and the input of the first block of the formation of the time interval.

According to the invention, adjustable reference voltage sources with variable voltage are used as reference voltage sources, the inputs of which are connected to the outputs of the corresponding regulators, the inputs of which are connected to the control and display unit. In this case, the output of the first block for generating a time interval is connected to the second input of the second block for forming a time interval.

In contrast to the prototype, instead of two reference voltage sources with a fixed voltage, two adjustable reference voltage sources with a variable voltage are used, which provides a more accurate determination of the time coordinate of the echo signal, and, accordingly, reduces the measurement error of the ultrasonic locator.

FIG. 1 shows a functional diagram of the device for compensating the measurement error of an ultrasonic locator.

FIG. 2 shows the echo signal diagrams, the threshold voltages U1 and U2, as well as the time intervals between the emitted pulse and the triggering of the first threshold device and between the triggering of the first and second threshold devices.

The device for compensating the measurement error of the ultrasonic locator contains a control and display unit 1, the output of which is connected to the generator of ultrasonic pulses 2 and the first input of the first unit for forming the time interval 3 (Fig. 1). The generator of ultrasonic pulses 2 is connected to the ultrasonic emitter 4. The ultrasonic receiver 5 is connected to the amplifier 6, the output of which is connected to the inputs of the first 7 and second 8 threshold devices. The output of the first adjustable reference voltage source 9 (RION 1) is connected to the other input of the first threshold device 7. The output of the second adjustable reference voltage source 10 (RION 2) is connected to the input of the second threshold device 8. The output of the first threshold device 7 is connected to the second input of the first block for forming the time interval 3. The output of the second threshold device 8 is connected to the first input of the second block for forming the time interval 11 The control and display unit 1 is connected to the output of the second block for forming the time interval 11. The output of the first block for forming the time interval 3 is connected to the input of the control and display unit 1, which is connected to the input of the first regulator 12 and to the input of the second regulator 13. The output of the first regulator 12 connected to the input of the first adjustable reference voltage source 9 (RION1). The output of the second regulator 13 is connected to the input of the second adjustable reference voltage source 10 (RION2). The output of the first block for generating the time interval 3 is connected to the second input of the second block for forming the time interval 11.

The control and display unit 1 can be implemented on the ATMEGA16 microcontroller and DA56-11SRWA indicators, in which two internal timer-counters are used to count the time intervals. The first 3 and second 11 blocks for forming the time interval are made on standard K1554TM2 microcircuits. As the first 7 and second 8 threshold devices, K521SA3 microcircuits are used. The generator of ultrasonic pulses 2 can be made according to the scheme with the discharge of the storage capacity on thyristors of the KU104G type. Receiver 5 and emitter 4 can be made of any piezoceramic, for example, from TsTS-19. Amplifier 6 can be performed on an operational amplifier, for example, 544UD2. The first 9 and second 10 adjustable voltage reference sources can be performed on TL431 microcircuits. The first 12 and second 13 controls can be performed on a digital potentiometer, for example AD5260BRUZ20 from Analog Devices.

от первого регулируемого источника опорного напряжения 9 (ИОН 1). Выходное напряжение

первого регулируемого источника опорного напряжения 9 (ИОН 1) соответствовало цифровому коду, поступившему от блока управления и индикации 1 на первый регулятор 12. Как только напряжение на выходе усилителя 6 превысило напряжение

, выход первого порогового устройства 7 переключился в состояние логической 1, которая сбросила первый блок формирования временного интервала 3 в состояние логического нуля (точка

на фиг. 2), а второй блок формирования временного интервала 11 установился в состояние логической единицы. Одновременно сигнал с выхода усилителя 6 поступил на вход второго порогового устройства 8, на другой вход которого подано напряжение

от второго регулируемого источника опорного напряжения 10 (ИОН 2), выходное напряжение которого соответствовало цифровому коду, поступившему от блока управления и индикации 1 на второй регулятор 13. Второе пороговое устройство 8 переключилось в состояние логической единицы, когда входное напряжение превысило напряжение

(точка

на фиг. 2). Логическая единица на выходе второго порогового устройства 8 установила второй блок формирования временного интервала 11 в состояние логического нуля. Таким образом, на выходе первого блока формирования временного интервала 3 сформировался импульс, длительность которого равна времени (

-

), а на выходе второго блока формирования временного интервала 8 импульс длительностью (

-

). The proposed device was used to determine the level of a liquid, which was placed in a tank measuring 2000 × 200 × 200 mm. The reservoir was filled with water to a level of 1800 mm. When determining the liquid level, the control and display unit 1 generated a trigger pulse for the ultrasonic pulse generator 2. With the same pulse, the first block for forming the time interval 3 was set to the state of a logical unit. The generator of ultrasonic pulses 2 transmitted an excitation pulse to the emitter 4. The emitted ultrasonic pulse propagated through the water to the upper level, from which there was a reflection and returned to the receiver 5. After amplification by amplifier 6, the signal entered the input of the first 7 and second 8 threshold devices. Voltage was applied to the second input of the threshold device 7

from the first adjustable reference voltage source 9 (RON 1). Output voltage

of the first adjustable reference voltage source 9 (RON 1) corresponded to the digital code received from the control and display unit 1 to the first regulator 12. As soon as the voltage at the output of the amplifier 6 exceeded the voltage

, the output of the first threshold device 7 switched to the state of logical 1, which reset the first block of the formation of the time interval 3 to the state of logical zero (point

in fig. 2), and the second block for forming the time interval 11 is set to the state of a logical unit. At the same time, the signal from the output of the amplifier 6 entered the input of the second threshold device 8, the other input of which was energized

from the second adjustable reference voltage source 10 (RON 2), the output voltage of which corresponded to the digital code received from the control and display unit 1 to the second regulator 13. The second threshold device 8 switched to the state of logical unity when the input voltage exceeded the voltage

(point

in fig. 2). A logical unit at the output of the second threshold device 8 has set the second block for generating the time interval 11 to a state of logical zero. Thus, at the output of the first block of the formation of the time interval 3, a pulse was formed, the duration of which is equal to the time (

-

), and at the output of the second block for forming the time interval 8 is a pulse of duration (

-

).

от первого регулируемого источника опорного напряжения 9 (ИОН 1) равнялось 1,1 вольта, напряжение

второго регулируемого источника опорного напряжения 10 (ИОН 2) равнялось 2,2 вольта, период колебаний ультразвуковой волны Т = 8 мкс, временной интервал (

-

) равнялся 1216 мкс. Затем блок управления и индикации 1 через первый регулятор 12 уменьшил напряжение

до 1,09 вольта, временной интервал (

-

) равнялся 1215,6 мкс. Затем блок управления и индикации 1 через первый регулятор 12 уменьшил напряжение

до 1,04 вольта, измеренный временной интервал

равнялся 1209 мкс. Изменение временного интервала составило:

Это больше, чем

.At the beginning, the threshold voltage

from the first adjustable reference voltage source 9 (ION 1) was 1.1 volts, the voltage

the second adjustable reference voltage source 10 (ION 2) was 2.2 volts, the oscillation period of the ultrasonic wave T = 8 μs, the time interval (

-

) was equal to 1216 μs. Then the control and display unit 1 reduced the voltage through the first regulator 12

up to 1.09 volts, time interval (

-

) was equal to 1215.6 μs. Then the control and display unit 1 reduced the voltage through the first regulator 12

up to 1.04 volts, measured time interval

equaled 1209 μs. The change in the time interval was:

It is more than

...

-

) составил 15 мкс.In this case, the time interval (

-

) was 15 μs.

до 2,19 вольта, измеренный временной интервал (

-

) равнялся 14,6 мкс. Затем блок управления и индикации 1 через второй регулятор 13 уменьшил напряжение

до 2,12 вольта, измеренный временной интервал (

-

) равнялся 8 мкс. Изменение временного интервала составило:

Это больше, чем

.Then the control and display unit 1 through the second regulator 13 reduced the voltage

up to 2.19 volts, measured time interval (

-

) was equal to 14.6 μs. Then the control and display unit 1 through the second regulator 13 reduced the voltage

up to 2.12 volts, measured time interval (

-

) was equal to 8 μs. The change in the time interval was:

It is more than

...

The calculated time interval for the propagation of an ultrasonic pulse was:

,

,

the calculated water level was:

.

...

The error in measuring the level Δh was:

It has been experimentally established that the level measurement error does not exceed λ / 6.

Claims (1)

An ultrasonic locator measurement error compensation device containing an ultrasonic pulse generator connected to the emitter, a receiver connected to an amplifier, to the output of which two threshold devices with different threshold voltages are connected, two reference voltage sources connected to the inputs of the corresponding threshold devices, the outputs of the threshold devices are connected to the corresponding blocks for the formation of the time interval, the outputs of which are connected to the control and display unit, the outputs of which are connected to the input of the generator and to the input of the first block of the formation of the time interval, characterized in that adjustable reference voltage sources with variable voltage are used as reference voltage sources, inputs which are connected to the outputs of the corresponding regulators, the inputs of which are connected to the control and display unit, while the output of the first block for forming the time interval is connected to the second input of the second block setting the time interval.

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