RU53002U1 - ELECTRONIC-ACOUSTIC LIQUID MEASUREMENT DEVICE - Google Patents

Abstract

The device relates to instrumentation and can be used to measure the level of liquids in tanks, ponds, non-pressure pipes. The device comprises a control unit 9, an emitter 2, the input of which is connected to the output of the pulse generator 1, two receivers of the acoustic signal 4, 5 spaced at a fixed distance, the outputs of which are connected to the electronic processing device 7, a device for calculating the speed of sound 6, characterized in that a counter of the number of reflections 14 is additionally introduced into the block diagram of the device, the input of which is connected to an acoustic signal receiver, and the output to an information processing device. The counter number of reflections 14 allows you to determine how many times the acoustic signal was reflected from the surface of the liquid. The signal sent by emitter 2 is reflected from the boundary of the media and returned to receiver 5. At the same time, part of the signal is reflected back from the device to the liquid side, from which it returns back to receiver 5. This process is repeated until the signal attenuates below the level required for trip comparator. Using the n-th reflection time to calculate the time level reduces the relative error of the device when measuring small distances from the device to the boundary of the media. Registration of the nth reflection allows the use of an inexpensive low-frequency element base, in contrast to devices that accept the first reflection.

Description

The device relates to instrumentation and can be used to measure the level of liquids in tanks, ponds, non-pressure pipes.

Known electronic-acoustic devices for measuring distances based on fixing the propagation time of the sent and reflected acoustic pulses in the direction of the controlled distance [Gorbatov AA, Rudashevsky G.E. Acoustic methods and means of measuring distances in the air, M., Energy, 1973; RU patent No. 20527686 G 01 B 17/00, 1996; Utility model RU No. 7492, G 01 B 17/00, 1998; Utility model RU 24550 G 01 B 17/00; G 01 F 23/28, 2002]. Level gauges are also known, the principle of which is based on the reflection of an acoustic signal from a controlled fluid [patents SU No. 1530927, G 01 F 23/28, 1989, SU No. 1813203, G 01 F 23/28, b.i. No. 16, 1993]

The prototype of the claimed utility model is an electronic acoustic device [utility model RU 24550 G 01 17/00; G 01 F 23/28, 2002]. The disadvantage of this device is the complexity and low accuracy of measuring small distances from the device to the liquid. Indeed, the small distance from the device to the liquid requires the use of high-frequency electronics and acoustics, which complicates the device and increases the relative error of the device.

The task is to increase the measurement accuracy at minimum distances from the device to the liquid by measuring the transit time of the repeatedly reflected acoustic signal from the liquid and the device.

The solution of this problem is achieved by the fact that in a known device containing an emitter, the input of which is connected to the output of the pulse generator and two receivers spaced at a fixed distance, the outputs of which are connected to an electronic processing device, according to the utility model, an additional number counter is introduced into the block diagram reflections, the input of which is connected to the receiver of the acoustic signal, and the output to the information processing device.

The essence of the utility model is illustrated in the drawing, where Fig. 1 shows a block diagram of the proposed device, and Fig. 2 is a diagram of received pulses.

The circuit includes a generator 1 connected to an acoustic emitter 2, connected to the end of the measuring tube (waveguide) 3, to which the reflected signal receiver 4 is connected, and a fixed distance “d” from it

additional receiver of the acoustic signal 5. The outputs of the receivers of the acoustic signal 4 and 5 are connected to the device for calculating the speed of sound in the medium 6 and the electronic processing device 7, the output of which is connected to the indicator 8 and the control unit 9. Receivers 4,5 are also connected to the counter of the number of reflections 14. The devices 1,2,4-9,14 are structurally placed in one housing and form a measuring module 10. The waveguide is installed in the tank or reservoir 11.

Measurement of the nth reflection allows n times to increase the resolution of the device, and hence the accuracy. Let C be the speed of sound, H is the distance from the device to the liquid. Time T _n from sending a pulse to accepting the nth reflection. will be:

Let the device have a resolution ΔT, _etc. (1) that the number of times bigger than n, so many times less impact on the measurement of delta _{T, etc.}

Figure 2 shows a diagram of the received pulses. The signal U _rad sent by the emitter 2 is reflected from the boundary of the media 13 and returns to the receiver 5. The receiver 5 registers the signal U ₁ . At the same time, part of the signal is reflected from the device back to the liquid side, reflected from which it is returned to receiver 5. The receiver registers the signal U ₂ . This process is repeated until the signal attenuates below the level necessary for the comparator to operate. The response level of the comparator is indicated by a horizontal dashed line. The electronic processing device 7 records the time of the last operation of the comparator Tn, and the counter of the number of reflections 14 captures its number n. The distance H is determined by the formula

The speed of sound C can be calculated according to the utility model RU 24550 G 01 17/00; G 01 F 23/28, 2002.

The device allows to increase the accuracy of measuring the liquid level when measuring small distances from the device to a controlled liquid level. The use of the device is effective for measuring the level in fully filled containers, small tanks, as well as when measuring the level of aggressive media.

Claims (1)

An electronic-acoustic liquid level measuring device comprising a control unit, an emitter, the input of which is connected to the output of a pulse generator, two acoustic signal receivers spaced at a fixed distance, the outputs of which are connected to an electronic processing device, characterized in that it is additionally introduced into the device’s block diagram a counter of the number of reflections, the input of which is connected to the receiver of the acoustic signal, and the output to the information processing device.