SU1716421A1 - Method of ultrasonic testing of change of building construction characteristics - Google Patents

Abstract

This invention relates to acoustic methods for non-destructive material testing. The aim of the invention is to increase the sensitivity and accuracy of control of building structures. In the structure under study, pulses of ultrasonic vibrations are excited. The vibration pulses passed through a predetermined base of the structure receive and measure their time and amplitude parameters. The complex coefficient of relative variability, which includes the measured parameters, is calculated, and its variation in the characteristics of building structures is determined from its value. 2 hp f-ly, 1 ill. Yo

Description

The invention relates to non-destructive testing and can be used to control the quality of materials of concrete and reinforced concrete structures with varying characteristics using ultrasonic pulsed oscillations.

A known method of ultrasonic testing of structures during bending tests, in which a pair of transducer emitter-receiver units is installed in the zone of maximum stretch, the transit time of the longitudinal wave ti is recorded and the dependence of ti change on load P is plotted. 30% of destructive, change of time ti in the process of microcracking is about 5%.

The same method is based on the method for monitoring and evaluating the crack resistance of pressure reinforced concrete pipes.

There is a known method of monitoring the condition of a hard airfield pavement, using the dependence of the attenuation coefficient of ultrasound in concrete a on the loading of the slab.

The disadvantage of this method is the low sensitivity of the information parameter a to changes in the characteristics of concrete under the influence of the load.

With bilateral access to the structure, it is possible to apply the method of testing reinforced concrete products for crack resistance, in which measurement is carried out by two pairs of transducers,

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mounted on opposite side surfaces of structures. By the change in the time difference ti between two pairs, the occurrence of cracks is recorded.

The sensitivity of this method is somewhat higher than the previous ones, but it also makes it possible to record the change in the acoustic characteristics only from the beginning of the active microcracking.

Also known is the method of controlling concrete and reinforced concrete structures under load on threefold measurement of the velocity of ultrasonic vibrations in a dangerous section of the structure in the unloaded condition and at two load values (20 and 60% of the expected maximum).

Based on changes in speed relative to the initial value and special plots, the maximum permissible load is calculated. During the whole cycle of measurements, the transducers are glued to the surface of the structure. In this case, the change in a single parameter of the longitudinal wave — its propagation time in concrete up to 3% —is analyzed, so the measurement error can be quite high.

A common disadvantage of these methods is their low sensitivity to changes in the characteristics of materials due to the use of a single acoustic characteristic of an acoustic signal as an informative parameter.

The closest to the proposed method according to the technical essence is an ultrasonic method for monitoring changes in the characteristics of building materials, using the in-phase change of two component characteristics (propagation time ti and rise time of the leading edge TL of the longitudinal wave in the pulse signal) when the material characteristics change .

The sensitivity of this method is higher than the previous one, but the informative capabilities of the acoustic pulsed signal are not fully utilized.

The aim of the invention is to increase the sensitivity and accuracy of non-destructive testing by simultaneously additional measuring the amplitude characteristics of the received signal and using as an information parameter characterizing the change in the integral physicomechanical and structural characteristics of materials and structures of the complex coefficient.

the relative variability of the pulse signal Ki, determined from the expression

.ti.) (tNrtL) (td (-tMt} AMoA-, o Ui tofti7 o-t0) (M0-te) ftdo-tMo) Alv,; H1

where ti and to are the propagation times of ultrasonic vibrations in the structure in the current and initial states, respectively;

tmi and tm0 are the times for the first half-wave of the received oscillations of the maximum value in the current and initial state, respectively;

tMi and tM0 are the times to reach the amplitude envelope of the received oscillation pulses at the maximum value in the current and initial state, respectively;

tdo is the point in time at which the envelope of the received oscillation pulses in the initial state reaches a fixed level Ado,

Adi is the amplitude of the envelope of the received oscillation pulses in the current state at the time instant tdi td + ti - to;

AMI and Amd are the maximum of the amplitude envelope of the received oscillation pulses in the current and initial states, respectively;

Ai | and AIO is the amplitude of the first half-wave of the received oscillations in the current and initial state, respectively, while normalizing the maximum of the amplitude envelope of the received oscillation pulses.

Thus, in the coefficient Ki, the parameters of the received signal are combined, related to the propagation velocity of the oscillations in the material ti, its spectral characteristic (tmi - ti) and the shape of the amplitude envelope of the received oscillation pulses: (tMi-ti). AMI, AT, Adi. The nature of the change in temporal and amplitude parameters is compiled into the overall complex coefficient of relative variability of the parameters of the Kitak pulse signal, which, when the physicomechanical and structural characteristics of the material change under load, these two types of single parameters of the pulse signal change simultaneously in the practical phase.

For example, when determining the change in design characteristics by surface sounding in the stretchable zone during the growth of the tensile stress and the number of microcracks, the time of passage of the surface wave in the layer of material ti increases, the time of reaching the maximum of the TMI envelope and

the rise time of the leading edge of the pulse tmi - ti due to the shift of the frequency spectrum of the pulse signal to the lower frequency region. At the same time, a change occurs in the reverberation process, the corresponding spreading of the pulse amplitude envelope, i.e. an increase in the magnitudes (twi - ti) and a decrease in the amplitudes AI and AM, especially noticeable when normalizing the maximum of the AM envelope to the original value. This, in turn, leads to an increase in the sensitivity and accuracy of the proposed information parameter to changes in the characteristics of the material compared to other acoustic control methods.

In monitoring changes in the characteristics of a material associated with its hardening or compaction, longitudinal wave pulses are used predominantly.

In monitoring changes in the characteristics of building structures under load, the pulses of ultrasonic oscillations are mainly used as surges of surface waves as excited and received pulses, and measurements are carried out on the construction site in the area of maximum stresses.

If there is a possibility of two-way access to a structure that is in a stressed state, measurements are carried out at two sites, the stresses in which are opposite in sign and maximum in magnitude, and the change in characteristics of building structures is determined by the change in the ratio of the values of the complex coefficients Ki received at both sites.

The advantage of the proposed method is the more complete use of the parameters of ultrasonic signal pulses, the change in temporal and amplitude parameters when the structural characteristics of the material are usually antiphase. In addition, the parameters of surface waves propagating in the surface layers of concrete are used as the source of information up to one and a half wavelengths. Thus, when a pair of transducers emitter-receiver is installed on a structure in the zones of maximum stress, these waves propagate in precisely those material layers that are most sensitive to compression or tension, i.e. to load effect.

In addition, with this arrangement of transducers, the intensity of the surface waves is much higher than that of the pro0

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longitudinal, which allows, at a constant power of ultrasonic devices, increase the measurement base relative to the base when measuring the parameters of longitudinal waves and, accordingly, the volume of the material involved in the measurement process with varying characteristics, which, in turn, increases the sensitivity of the parameter, as it increases the probability changes in the microstructure of the material on the signal path.

If it is possible to install on opposite surfaces of the structure in the zones of maximum expansion and compression of two pairs of transducers with preferably identical measurement bases, it is possible to further increase the sensitivity of the proposed complex relative variability coefficient to changes in material characteristics. To do this, the variability coefficients Ki are measured in each of these zones, their ratio is found to be t, and it is judged by its change that the characteristics of the material change. The sensitivity is increased due to antiphase Ki change in these zones under the influence of the load,

The drawing shows the oscillogram of the received oscillation pulse and its measured parameters.

Example. One-way access control of the structure.

- A pair of ultrasonic transducers; a transmitter-emitter is fixed on the surface of the structure under study in the zone of maximum stretching or compression so that there are no visible structural disturbances between the transducers and the contact conditions of the transducers with the surface do not change during the tests. In this case, an oscillogram shown in the drawing is formed on the cathode-ray tube of the ultrasonic device, with all characteristic parameters: ti is the arrival time of the longitudinal wave; tr is the arrival time of the transverse wave; ts -. arrival time of the surface wave; tsm is the time to reach the first half cycle of the surface wave; tsj is the time to reach the trailing edge of the amplitude envelope of the received pulses of a fixed level from the maximum value; ISM is the time to reach the amplitude envelope of the received surface wave pulses, the maximum value; Am is the amplitude of the envelope of the received pulses of the surface wave; Am is the amplitude of the first half period of the surface wave; Ad is the fixed attenuation level of the received pulse envelope (for example,

.ZAM.

Then, after a certain time of action of the load, or after the load reaches the specified levels, all the above parameters are measured, the necessary values (ts ml - tS |), (C Ml t Si) are determined. RELATED TO THEIR

the initial values determine the complex coefficient of the relative variability of the surface wave in the pulse signal KI | and by the nature of its change it is judged to change the characteristics of the material of the structure. In this example, when measuring the signal parameters, it is necessary to take into account a number of features.

In practice, it makes no sense to rigidly divide surface waves into species or to emit transverse waves. In the pulsed mode, all of them are practically in the same time range and, overlapping one another, give a total signal, which is conventionally taken as the signal of the surface wave, i.e. the arrival of the surface wave ts is determined by the characteristic curve break and a sharp increase in the amplitude of a part of the overall waveform of the received signal and then all points of the waveform are considered to belong to the surface wave as prevailing in intensity over the others.

When re-defining the changed parameters, it is necessary to pay attention to the following circumstance. Under the influence of the load and the corresponding change in the stress state and microstructure of the surface layers of the construction material, the shape of the envelope signal of the surface wave changes, therefore, to correctly determine the amplitude parameters of the signal, the amplitude of the envelope is normalized to the initial value (the ratio of the amplitude values of the envelope Am (/ Am0)

A further increase in the number of temporal and amplitude parameters is impractical, since it leads to a significant increase in the complexity of the tests, not leading to a significant increase in sensitivity and measurement accuracy. For example, it is possible to introduce temporal and amplitude parameters of the longitudinal wave L into the complex coefficient, but due to its low intensity and large attenuation with surface sounding, the error in determining these parameters is large.

Methods for determining parameters and obtaining private information about the changes in each parameter in a form relative to the initial value are available for

operator of any qualification. In addition, depending on the type of material, design and test conditions, the number of single parameters can be reduced after preliminary determination

sensitivity of each of them to changes in the characteristics of the material in the structure.

Claims (3)

1. The method of ultrasonic monitoring of changes in the characteristics of building structures, which consists in the fact that in the structure under study excitation pulses of ultrasonic vibrations are excited, they receive those passed through a given base oscillation pulses, measure the temporal parameters of the received oscillation pulses and the complex parameter, which includes measured in the initial state and in the current state the temporal parameters of the oscillation pulses determine the changes in the characteristics of building structures, distinguishing them and so that, in order to increase the sensitivity and accuracy of the control, the amplitude parameters of the received oscillation pulses are additionally measured, and the changes in the characteristics of the building structures are determined by the change in the complex the ratio of whale relative variability, calculated from the expression 1: CM; - MA „0..A4s sh Mtmo-toHWle) .AM; -A4; .. Ad; -. where ti, to is the propagation time of ultrasonic vibrations in the structure in the current and in the initial state, respectively; tmi and tm0. are the times when the first half-wave of the received vibration pulses reaches the maximum value in the current and in the initial state, respectively; W | and tM0 is the time to reach the amplitude envelope of the received oscillation pulses of the maximum value in the current and in the initial state, respectively; AMI and AMO maximum of the amplitude envelope of the received oscillation pulses in the current and in the initial state respectively; Ai | and Ai0 is the amplitude of the first half-wave of the received oscillation pulses, reduced to AMO 1 in the current and in the initial state, respectively; Adi is the amplitude of the envelope of the received oscillation pulses in the current state at the moment of time td | td + ti. -ten ; tdo is the point in time at which the envelope of the received oscillation pulses in the initial state reaches a fixed level Ado. 2. The method according to claim 1, about t l available in that. In order to increase the sensitivity and accuracy of control of building structures under load, pulses of surface contact are mainly used as excited and received ultrasonic vibration pulses. five The measurements are carried out at the construction site in the area of maximum stresses. 3. The method according to claim 2. characterized in that the measurements are additionally carried out at the second section of the structure, the stresses in which are opposite in sign to the stresses in the first section and are maximum in magnitude, and the change in the characteristics of building structures is determined by the ratio of the values of the complex coefficients relative to the variability of Ki1 obtained at the first and in the second sections of the structure. ffnD A, |  -  5M0