RU52477U1 - ULTRASONIC LEVEL METER - Google Patents

Abstract

The utility model relates to the field of measurement technology and can be used to measure and control the level of liquid and granular media in open and closed tanks. The problem the utility model aims to solve is to increase the explosion protection, reliability and accuracy of the conversion. The goal is achieved in that an ultrasonic level gauge containing a dielectric tube with a sound duct made of a material with a pronounced magnetoelastic effect, a measuring winding wound on the sound duct and connected to the block of secondary electronic equipment, a piezo emitter located on the sound duct and connected to the generator of the block of the secondary electronic device ry, as well as a float with a magnetic system located in it, mounted concentrically on a dielectric tube with the ability to move along it, a matching unit, a keyboard and display controller connected to a single-chip microcomputer, which is connected to the interface unit, are introduced. In order to increase explosion protection, a reed relay is used in the switch unit.

Description

The utility model relates to measuring equipment, namely to ultrasonic level gauges, and can be used to measure and control the level of liquid and granular media in open and closed tanks with high accuracy and reliability.

A known ultrasonic level gauge containing a waveguide, an ultrasonic emitting element connected to a generator and installed at the end of the waveguide placed in a sealed tube, a float with a permanent magnet fixed on it, mounted concentrically with a sealed tube, and also a winding distributed along the waveguide and covering it , an amplifier connected to the ends of the winding, and a deciding unit connected to the outputs of the amplifier and generator [USSR Author's Certificate No. 838381, G 01 F 23/28, 1981].

The disadvantage of this ultrasonic level gauge is that the change in the speed of sound propagation in the waveguide, which occurs under the influence of ambient temperature, leads to an additional change in the time intervals between the pulses at the output of the generator and the pulses induced in the measuring winding and further amplified by the receiving amplifier. Since in the decisive unit the measurement of the indicated time intervals is carried out, the influence of temperature is manifested in this level gauge c. as a significant temperature error of measurements. The disadvantages of this device for measuring the liquid level are also a relatively narrow measuring range and low accuracy when measuring large levels.

Also known is a magnetostrictive level gauge, the action of which is based on the formation and supply of an alternating electric signal, converting it to ultrasonic vibrations, by means of a piezoelectric effect, on the subsequent conversion of ultrasonic vibrations into an electric pulse by means of a magnetoelastic effect, measuring the time intervals between the time of delivery of the generated alternating signal and receiving converted electrical pulse, determining the level from the measured interval in Yemeni and the propagation velocity of ultrasonic vibrations in the acoustic line [RC-transmitter PT, Ryazanskiy plant "Teplopribor"].

It is possible to slightly improve the characteristics of liquid level measuring devices by installing amplifiers directly on the sensor, which is done in the RU-PT level meter of the same Ryazan Teplopribor plant. With a communication line length of up to 400 m, such a device in the level measurement range from 0 to 12 m has an absolute error of no more than ^± 4 mm. However, the cost of such a level gauge rises sharply. At the same time, further increasing the accuracy of measurement or increasing the range of measurement of the liquid level is already becoming problematic [RU-PT Level Gauge, Ryazan Teplopribor Plant].

However, this level measuring device has the same limitations as mentioned above.

A device for controlling the liquid level, comprising a generator, emitting and receiving ultrasonic transducers, a prohibition unit connected by inputs to the output of the receiving ultrasonic transducer, the output of the generator and the inputs of the first and second triggers and a summing counter, a pulse shaper connected to the output of the prohibition unit, the input of the element And and the output of the second trigger, a crystal oscillator connected to the input of the circuit And, a reversible counter connected to the inputs of the outputs of the summing counter, circuit And and

the second trigger, and the output to the input of the first trigger, as well as the recorder connected to the output of the first trigger [USSR Copyright Certificate N 1315815, cl. G 01 F 23/28, 1987].

A disadvantage of the known device is the influence of temperature changes in the physical characteristics of the medium through which ultrasonic vibrations are transmitted on the measurement result. In particular, the temperature drift of the velocity of propagation of ultrasound in the medium leads to a change in the time interval between the pulses generated by the generator and the pulses at the output of the receiving ultrasonic transducer, which directly gives the temperature measurement error.

Also known magnetostrictive level gauge [RF Patent No. 2083956, IPC 6 G 01 F 23/28, 1997], selected as a prototype, containing a sensing element placed in a dielectric tube, which is sealed in the lower part and is resistant to interaction with a liquid whose level measured; a sound pipe from a wire (rod) made of a material with a significant magnetoelastic effect: evenly wound coil to coil on a sound pipe, a measuring winding, the length of which determines the range of level measurement h; a piezo-emitter, a float with a block of n permanent magnets, where n = l, 2 ... i, placed evenly around the sound duct on an insulating shell with the possibility of movement along it; a communication line connecting the measuring winding to the block of secondary electronic equipment (calculators), as well as a second communication line connecting the output ends of the piezoelectric emitter to the block of secondary electronic equipment with an ultrasonic oscillator included in the block.

Level measurement is often necessary in hazardous areas, such as oil and gas producing and processing plants. Therefore, devices are needed that could be

use under specified conditions. In connection with the requirements for limiting the values of the used voltages and total capacitances when measuring levels in hazardous areas (GOST R 51330.10-99 "Intrinsically safe electrical circuit i"), it is necessary to reduce the values of the used voltages, since it does not seem to reduce the total capacitances when implementing known level measuring methods possible. Given the above, it is necessary to use a voltage below 15 V.

Magnetostrictive devices for measuring liquid level have a number of disadvantages, including the following.

The need to supply high voltages (above 20 V) to the piezo emitter to ensure stable operation of the device complicates the development of explosion-proof equipment.

The need to shield the measuring winding due to the fact that the length of the measuring winding can be significant (20 meters or more along the length of the measured level), which makes it possible to consider the measuring winding as an antenna, and the useful signal removed by the measuring winding has a small amplitude (units and tens of millivolts) , comparable with the amplitude of the induced air noise, complicates the task of processing the electrical signal of the measured level. Due to the proximity of the conductors with a significant length (over 20 m) of the sensing element, distributed L, C, R are present in the cable of the sensing element, and therefore the line requires coordination. Each additional line complicates the coordination procedure (the process is time-consuming and time-consuming), leading to the introduction of additional elements, which is undesirable for small cable diameters.

One of the most urgent tasks in the design is the development of such a device for measuring the liquid level, which would increase the explosion and intrinsic safety of measuring the liquid level by providing the possibility of reducing the used

voltage during the measurement and provide the ability to measure at more remote distances.

When measuring the level and the phase separation level of liquid products, there is no need to use voltages higher than 12 V in the sensor, the need for shielding the windings, and noise level is reduced due to the possibility of reducing the length of the conductors through which the useful and then amplified signal passes.

The technical result of the invention is to increase the resolution, simplify the design, increase the explosion safety and reliability of the conversion.

The problem is achieved in that in an ultrasonic level gauge containing a dielectric tube with a sound duct made of a material with a pronounced magnetoelastic effect, a measuring winding wound on the sound duct and connected to the secondary electronic unit, a piezo emitter located on the sound duct and connected to the generator of the secondary unit electronic equipment, as well as a float mounted concentrically on a dielectric tube with the ability to move along it, unlike prot type matching block is entered, the keyboard and display controller associated with the single-chip microcomputer, which is connected to the block interface.

Using the RS-232 interface, communication with an external computer is organized. To increase the explosion protection in the switch unit, which includes the key unit, a reed relay is used.

Ultrasonic level gauge works as follows.

The essence of the utility model is illustrated by figures 1 and 2. Figure 1 shows a diagram of the installation of the level gauge on the object. Figure 2 presents the functional diagram of the secondary Converter.

The ultrasonic level gauge contains an ultrasonic receiving-emitting element 1, a waveguide 2, made in the form of a ferromagnetic rod with a magnetoelastic effect, a winding 3,

wound evenly along the entire length of the waveguide, a float 4 mounted concentrically with a sealed tube 5, into which a waveguide 2 with a winding 3 is placed, a clock 6, the output of which is connected to a frequency divider 7 connected to a single-chip microcomputer 8, which is connected to the multiplexer 9 , with a start block 10, with a keyboard and display controller 11, with an interface block 12, which in turn transmits computer information, a comparator 13, a switch 14, to which a signal is transmitted directly from the sensors 15 themselves and the block and amplification 16, the matching unit 17 allows you to display information about the levels on the display 18 and is connected to the keyboard 19, the line of reference voltages 20, which is connected with the multiplexer 9. U _p - buoyancy level, L _d - sensor length, L _w - liquid level, H is the distance from the bottom of the tank to the body of the piezoelectric transducer, D is the current distance from the body of the piezoelectric transducer to the float, P is the tank.

The principle of operation is to measure the time interval t, the passage of an ultrasonic wave (USW) distance from the emitter 1, located at the level of the hatch of the tank 5, to the float 4, the position of which is determined by the liquid level L _W in the tank 5, and recalculation of this interval in the liquid level .

When a piezoelectric element is exposed to a current pulse, the piezoelectric element mechanically acts on the end of the wire along the entire length of which a coil 3 with the number of turns W is wound. As a result, an elastic deformation wave propagates along the wire. In this case, a change in the magnetic permeability of the wire material occurs in the wave passage (magnetostrictive effect). EMF at the terminals of the winding W is proportional to dμ / dt and is equal to:

E = -W * S * μ ₀ * ((dμ / dt) * H + (dH / dt) * μ),

(dH / dt) * μ = 0,

where W is the number of turns of the coil, H is the magnetic field of the earth, S is the area, μ is the magnetic permeability of the medium, μ ₀ is the magnetic constant.

When an elastic deformation wave propagates over a site at the location of the float with a magnet, a signal surge in amplitude is observed on the winding as a result of the interaction of the ultrasonic ultrasonic wave energy with the magnetic field of the float:

E = -W * S * μ ₀ * (dμ / dt) * (N _ground + H _float ),

Thus, the electric signal of the sensor logically consists of absolutely identical measurement cycles (DIs) sequentially following each other. The structure and shape of the signal during any QI is the same, unchanged and consists of:

1) Trigger impulse (ZI) - initiates the sending of an ultrasound to the waveguide;

2) The response signal (OS) - is a package of sinusoidal oscillations, the phase arrangement of which relative to the ZI characterizes the desired value.

For measurement purposes, only two signal elements are used - ZI and OS. The sought quantity is the distance (in units of time or in units of length) between ZI and OS.

The liquid level L ^ is determined by the difference between the distance from the bottom of the technological apparatus to the piezoelectric transducer body H (determined based on the design characteristics of the technological apparatus) and the current distance from the piezoelectric transducer body to the float D.

L _W = HD,

The error of level measurement is mainly determined by the inaccuracy of setting the value of N.

The function of automatic control of the level measurement process is performed by a microcontroller, for example, KR1816BE51. Synchronization

the controller is provided by a clock generator via a frequency divider. The microcontroller works according to the built-in program.

The scheme works as follows: the signal from the sensor 15 through the switch 14 and the amplification unit 16 is fed to the comparator 13 with a variable threshold. The operation thresholds are set through the multiplexer 9 by means of commands with a single-chip microcomputer 8 (OMEVM). OMEVM 8 sequentially analyzes the response-pulse response time at different levels and thereby determines the time from the start to the moment of the response pulse from the maximum value of the pulse. The trigger pulse is also generated by means of OMEVM 8 through the switch 14 and the trigger unit 10. Information about the levels from the keyboard controller and display 11 is displayed on the built-in display 18, and also through the interface unit 12 can be transferred to a computer. Settings management is provided by the built-in keyboard 19.

Claims (1)

An ultrasonic level gauge containing a dielectric tube with a sound duct made of a material with a pronounced magnetoelastic effect, a measuring winding wound on the sound duct and connected to the secondary electronic equipment unit, a piezo emitter located on the sound duct and connected to the generator of the secondary electronic equipment unit, as well as a float, mounted concentrically on a dielectric tube with the ability to move along it, characterized in that a matching block is inserted into it; Weller keyboard and display associated with the single-chip microcomputer, which is connected to the block interface.