SU1472820A1 - Method of monitoring stressed state of concrete and ferroconcrete constructions - Google Patents

Abstract

The invention relates to the field of non-destructive testing of building structures and can be used to estimate the stress-strain state of loaded structures during their construction, reconstruction or operation using acoustic emission signals (AE). The aim of the invention is to expand the scope and increase accuracy by taking into account the response of the material of the structure to the additional load on the count rate of AE pulses in intervals where it exceeds the threshold level. The additional load is created by the value of 3-8% of the ultimate stress state of the structure. 2 Il.

Description

one

The invention relates to the field of non-destructive testing of building structures and can be used to estimate the stress-strain state of loaded structures during their construction, reconstruction or operation using acoustic emission signals (AE).

The aim of the invention is to expand the scope and increase accuracy by taking into account the response of the material of the structure to the additional load on the count rate of AE pulses in intervals where it exceeds the threshold level.

FIG. 1 shows a scheme for implementing the method for monitoring the stress state of concrete and reinforced concrete structures in FIG. 2 - schedule

dependencies between the relative level of the stress state 6 / R and the complex parameter N.

The sensor 1 AE, installed on the surface of the structure 2, is connected to the meter 3 of the pulse counting rate of the AE, the unit 4 of the time intervals is connected to the second input of the meter 3, the pulse counting speed of the AE, the second output is connected to the automatic recorder 5 of the complex parameter N. Output of the meter 3 pulse count rate AE is connected to the second input of the automatic recorder 5 of the complex parameter N.

The method of controlling the stress state of concrete and reinforced concrete

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structures is implemented as follows.

The structure 2, which is under load, causes voltage 6 in the material of structure 2, is subjected to an additional load, which creates a voltage 4R of 3-8% of the maximum stress state of the structure 2 (breaking voltage R). An additional load is created by one of the known methods (for example, the application of additional mass, torque, using power jacks). Record the counting rate of N pulses AE at regular intervals of time A t. Compare the count rate N with a predetermined threshold level NU and calculate the complex parameter

t

H IE n-utN-, i 1,2,3, ..., p, where i i Nj is the counting rate of AE in the i-th time interval, p. - the number of time intervals in which the count rate N; exceeded the threshold level (N, Y N0). According to the pre-established calibration dependence (Fig. 2), between the relative level of the stress state d / R and the complex parameter H is judged the stress state of the structure d.

Claims (1)

Thus, this method allows to increase the control accuracy and expand the field of application by taking into account the response of the material of the structure to the additional load and estimating the stress state by the complex parameter determined by the count rate of AE pulses in the intervals where it exceeds the threshold level. Invention Formula The method of monitoring the stress state of concrete and reinforced concrete structures, which consists in the fact that the load of the structure is received by acoustic emission signals and by their parameters judging the level of stress state, I differ y and, in order to expand the field of application and increase accuracy, create an additional load of 3-8% of the ultimate stress state of the structure, measure the counting rate of acoustic emission pulses at regular intervals from the time the additional load is applied and the stress state of the structure is determined by the pulse count rate of acoustic emission in the time intervals in which it exceeded the threshold level. /////// w ///// 1st / //////////////// figure 1 GO 15 FIG. g 20 H-1Q