RU2580907C1 - Ultrasonic waveguide level meter for liquid - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: level gauge has sensitive element made up of two waveguides with fixed in their upper part of receiving-transmitting transducers, and reflector acoustic pulses arranged in parallel to waveguide. Reflector throughout its length comprises ledges oriented horizontally. Sealing of waveguides bending waves is provided by means of tubular suspensions. Electric circuit level gauge has pulse generator, amplifier and indicator. Indicator consists of delayed gate pulses generator, level comparator, selector level and time intervals meter. Indicator is configured to determine time of acoustic signal passing from moment of sending pulse by generator to moment of its occurrence at output of amplifier.

EFFECT: high measurement accuracy.

2 cl, 4 dwg

Description

The present invention relates to instrumentation, and in particular to devices for determining the liquid level in various, including aggressive environments, operating both under normal conditions and at elevated temperatures and pressures. It can be used in chemical and petrochemical industries, in the energy, fuel and other industries.

The known design of an ultrasonic waveguide liquid level meter includes a sensor containing a sensing element made in the form of a waveguide rod (waveguide), with an electro-acoustic transducer fixed in its upper part, and an acoustic pulse reflector located parallel to the waveguide rod immersed in a controlled liquid [1] . The sensor Converter is connected to an electrical circuit containing a pulse generator, amplifier and indicator. The liquid level is determined by measuring the travel time of acoustic pulses along the path: the upper drained portion of the waveguide rod, the surface of the liquid from the waveguide rod to the reflector and vice versa. That is, it operates in the "radiation - reception" mode using a single converter.

The disadvantage of this level gauge is the very low reliability of the sensor due to the low level of the received signal and the presence of spurious re-reflected signals in the waveguide rod, masking the useful signal.

The closest in combination of features and the achieved technical result to the claimed device is an ultrasonic liquid level meter, including an improved waveguide sensor [2].

The known level gauge contains a waveguide sensor, consisting of a sensitive element made in the form of a vertically oriented waveguide, with an electro-acoustic transducer fixed in its upper part, and an acoustic impulse reflector, in the form of a plate located parallel to the waveguide rod and containing uniform wedge-shaped protrusions. The presence of protrusions on the reflector increases the amplitude of the reflected and, accordingly, received acoustic pulses. The well-known level gauge also operates in the "radiation-reception" mode, that is, the acoustic pulse generated by the transducer passes through the waveguide to the surface layer of the controlled fluid into which the wave is emitted, then the latter is reflected from one of the protrusions on the reflector located in the coverage area wave, returns back to the waveguide and is received by the same transducer.

A significant drawback of the known level gauge is the occurrence of a multitude of spurious re-reflected signals in the waveguide upon activation of the transducer, which is due, inter alia, to the mutual transformation of longitudinal and bending waves of zero order and the appearance of waves of higher orders. These spurious signals, falling on the receiver, significantly degrade the quality of the received useful signal, as a result of which there are serious problems in its selection, which reduces the reliability of the device and reduces the accuracy of the measurements.

The developer is faced with the task of increasing the accuracy of measurements and the reliability of the level gauge when used in various liquids in a wide range of temperatures and pressures.

The problem is solved thanks to the ultrasonic waveguide liquid level gauge containing the sensing element, made in the form of a vertically oriented waveguide, with an electro-acoustic transducer fixed in its upper part, and an acoustic pulse reflector located parallel to the waveguide, while the sensor transducer is connected to an electrical circuit containing pulse generator, amplifier and indicator, characterized in that the sensitive element is equipped with a second waveguide with fixed With an electro-acoustic transducer located in its upper part parallel to the first one, the reflector along its entire length contains protrusions oriented horizontally, while one of the transducers is connected to a pulse generator, the other to an amplifier, and the indicator is configured to determine the acoustic signal propagation time from the moment the pulse is sent by the generator to the moment it is received at the amplifier output.

The indicator consists of a delayed strobe generator, a level comparator, a level switch and a time interval meter, the input of the strobe delay generator being connected to a pulse generator, the output to the comparator strobe input, two inputs of the level comparator connected to the amplifier output and a level setter, respectively, and a time interval meter is connected to the output of the comparator and the generator.

In contrast to the well-known level gauge, the proposed level gauge operates in the “full light” mode: one of the waveguides is an emitter of acoustic pulses, the other is a receiver.

Distinctive features of the claimed device, in conjunction with the known, provide a solution to the problem - improving the accuracy of measurements and the reliability of the level gauge when used in various liquids and conditions.

The proposed device uses bending waveguides. Due to the physical properties of zero-order bending waves, when they propagate through a waveguide immersed in a liquid, acoustic energy is effectively emitted into the liquid. At the same time, with a waveguide diameter of 2 mm at a frequency of 800 kHz, to completely transfer the energy of a bending wave into a liquid, it is sufficient to immerse the waveguide to a depth of 30-50 mm. The wave radiation occurs at an angle φ determined by the triangle of sound velocities: a bending wave in the waveguide and a longitudinal wave in the liquid (Fig. 1). Moreover, for common liquids (water, oil products), the angle of entry of the wave into the liquid is approximately 60 ° relative to the axis of the waveguide. Due to the polarization of the bending waves in the waveguide, a directivity pattern is formed in the liquid, which consists of two wave beams that are symmetrical about the axis of the waveguide in the oscillation plane. In connection with the foregoing, the vibrational plane in the waveguides is selected, provided by the orientation of the electro-acoustic transducers, so as to obtain the maximum amplitude of the reflected received signals from one of the wave beams (the second is not used).

The transfer of acoustic energy from the radiating waveguide to the liquid begins immediately below the media line and ends almost completely after 30-50 mm. The generated wave beam in the near-surface liquid layer falls at an angle downward onto the reflector and, reflecting from its horizontally oriented protrusions, returns at the same angle upward to the receiving waveguide, forming a received signal, which is illustrated by the figure (Fig. 2).

Separation of the waveguide sensitive element into the emitting and receiving ones prevents significant internal spurious (rereflected) signals from reaching the receiving transducer, which significantly improves the reception conditions and the quality of the received pulses. As a result, the accuracy of level measurement is increased, as well as the reliability of the level gauge during operation in various liquids. Additionally, the reliability of the level gauge increases the use of a time-gated comparator of the received signals.

Thus, the proposed device has greater accuracy and reliability in various liquid media in a wide range of temperatures and pressures.

The construction of the level gauge is illustrated in the drawing of FIG. 3.

The ultrasonic waveguide liquid level gauge consists of a housing 1 with waveguides 2 and 3 located in it, equipped with electro-acoustic transducers 4 and 5, and a reflector of acoustic pulses 6. The sealing of the waveguides is provided using tubular suspensions 7 and 8. The electrical circuit consists of a pulse generator 9 connected to the Converter 4, the amplifier 10 connected to the second Converter 5, and the indicator 11.

The level gauge works as follows. Electrical pulses from the output of the generator 9 are supplied to the transducer 4, where they are converted into ultrasonic pulses and transmitted through the waveguide 2 to a controlled fluid 12. The use of bending waveguides provides an efficient transmission of acoustic energy to the liquid in a surface layer about 3 cm high. The wave is incident on reflector 6 is reflected from one of its protrusions and enters the second waveguide 3, and then transmitted to the converter 5. Electrical pulses from the output of the converter 5 through the amplifier 10 are received and the input indicator 11, which determines the transit time of the acoustic signal from the moment of its formation to the time of reception. A change in the liquid level proportionally changes the length of the acoustic path (path of ultrasonic pulses), which is fixed by the indicator.

The indicator includes a delayed strobe generator 13, a gated comparator 14, a level adjuster 15 and a time interval meter 16 (Fig. 4).

His work is as follows (illustrated by the time chart in Fig. 4). The pulse from the output of the generator 9 starts the delayed strobe pulse former 13, which generates a video pulse with the duration of the expected arrival time of the acoustic pulses in the range of the liquid level from the maximum value to the minimum. The gated comparator 14 generates video pulses at those times when the amplitude of the signal at the output of the amplifier 10 exceeds a predetermined discrimination level generated by the level adjuster 15 in the time interval specified by the delayed strobe pulse former 13. The time interval meter 16 generates an output signal proportional to the pulse delay the output of the comparator 14 relative to the output pulse of the generator 9. The output signal can be generated in the form of a potential level, current level or digital yubom known standards, such as RS-485.

Prototype level gauges were manufactured and tested.

The level gauges used waveguides 600 mm long, made of wire with a diameter of 2 mm. Used steel wire grade 12X18H10T. Acoustic transducers were made of PZT-19 piezoceramics. The operating frequency of ultrasound is 900 kHz. The frequency of sending electrical pulses of the generator is 1 kHz.

Typical microcircuits and a microprocessor manufactured by Atmel were used in the electrical circuit.

The operation of the level gauges was tested in various liquids, in particular, in water, petroleum products, solvents, chemicals, liquefied gases, in the temperature range from 20 to + 350 ° C, at a medium pressure of up to 20 MPa.

Stable and reliable operation of devices in all tested environments is shown.

Information sources

1. USSR author's certificate, No. 310120, filed on 06/19/1969.

2. USSR author's certificate, No. 510648, claimed on 02.01.1974.

Claims (2)

1. An ultrasonic waveguide liquid level gauge containing a sensing element made in the form of a vertically oriented waveguide, with an electro-acoustic transducer fixed in its upper part, and an acoustic pulse reflector located parallel to the waveguide, while the sensor transducer is connected to an electrical circuit containing a pulse generator , amplifier and indicator, characterized in that the sensing element is equipped with a second waveguide with electro-acoustically fixed in its upper part a transducer located parallel to the first, the reflector along its entire length contains protrusions oriented horizontally, while one of the transducers is connected to a pulse generator, the other to an amplifier, and the indicator is configured to determine the transit time of the acoustic signal from the moment the pulse was sent by the generator to the moment its reception at the output of the amplifier. 2. The ultrasonic waveguide liquid level gauge according to claim 1, characterized in that the indicator consists of a delayed strobe pulse shaper, a level comparator, a level switch and a time interval meter, the input of the delayed strobe pulse shaper connected to the pulse generator, the output from the strobe the input of the comparator, two inputs of the level comparator are connected to the output of the amplifier and the level setter, respectively, and the time interval meter is connected to the output of the comparator and the generator.

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