RU2097727C1 - Method of nondestructive test of quality of ready reinforced concrete articles - Google Patents

Abstract

FIELD: production of reinforced concrete articles. SUBSTANCE: method is based on determination of resonant frequency and logarithmic decrement of oscillations at article forced longitudinal oscillations excited within the range of frequencies being in resonance field of article under test. Article is secured on supports in compliance with operating instructions. Quality of articles under test is determined by comparing the obtained dynamic parameters with respective parameters of standard article obtained under the same conditions of test. EFFECT: integral estimation of quality determination. 3 cl, 1 dwg

Description

 The invention relates to construction, namely to the production of reinforced concrete products and can be used for selective or continuous non-destructive testing of finished building products from reinforced concrete.

 There is a method of non-destructive quality control of a finished reinforced concrete product (Temporary construction for quality control of finished reinforced concrete products, parts and structures by a non-destructive method. VSN-6630-72. USSR Ministry of Construction, 1976), which includes fixing the controlled product on supports in accordance with operating conditions, excitation in bending vibrations, determining the product vibration frequency, comparing the obtained value of the dynamic parameter of the controlled product with the same indicator obtained on the reference edition Eli.

 The known method allows an integral assessment of the stiffness and bearing capacity of a controlled product, but does not make it possible to evaluate its crack resistance and the value of prestressing of the reinforcement. In addition, the disadvantage of this method is that it can only be used to control products subjected to bending loads under operating conditions, and cannot be applied to products that experience other types of deformations, including complex resistance: eccentric compression (columns), bending with torsion (crossbars with one-sided support of plates on them), etc.

 There is also a method of non-destructive quality control of a finished reinforced concrete product (Methodological recommendations for assessing the strength, stiffness and crack resistance of finished prestressed products and serial production structures by the non-destructive dynamic method, TbilZNIIEP, Metsniereba, 1973, pp. 7-29), including fixing the controlled product on supports in accordance with operating conditions, the excitation of bending vibrations in it, determination of the frequency of oscillations and the logarithmic decrement, comparison of the obtained values Nij dynamic parameters monitored items with values of the same parameters obtained in the reference item in the same control mode and determining based on the comparison of quality parameters of the finished product. The known method allows an integral assessment of the bearing capacity, stiffness and crack resistance of the controlled product.

The main disadvantages of this method are:
the method cannot be applied to products experiencing complex resistance;
the method has a low sensitivity to local defects and uneven tension of the reinforcing bars and does not allow to evaluate the actual stress in the finished product;
for real structures (plates, beams, etc.), the method is implemented at the infrasonic range frequency, which is very detrimental to the health of operators and does not allow the organization of continuous vibration control, especially in the mode of forced vibrations;
when using the method, mainly sections of the middle zone of the product (the zone of action of the greatest bending moments) are involved in the work; supporting sections of the product (together with its possible defects) to a lesser extent affect the value of dynamic parameters (Krylov N.A. et al. Radio engineering methods for quality control of reinforced concrete. L. Stroyizdat, 1966. p. 251; Berdichevsky GI and others Non-destructive methods of quality control of reinforced concrete structures / NIIZhB Gosstroy USSR. M. Publishing House of Building Literature, 1972. P. 12-13.), Therefore, the application of the method to quality control of products of variable length stiffness does not provide reliable consideration of this geometric factor;
when testing flat products (for example, floor slabs, road slabs), it is difficult to tightly fit them to supporting devices, which creates significant errors in determining the actual dynamic parameters of the controlled products;
the method involves the use of only elastic physical and mechanical characteristics, while their actual work allows the appearance of zones of elastic-plastic state;
when using the method, there are severe restrictions on the magnitude of the initial deviations or excitation energy (Sekhniashvili EA Integrated assessment of the quality and reliability of prestressed structures. M. Nauka, 1988. S. 153-155);
hardware implementation of the known method involves the use of expensive non-standard or highly specialized devices, high energy consumption and does not provide high accuracy due to low noise immunity.

 The objective of the invention is to develop a method of non-destructive quality control of a finished reinforced concrete product with such operational parameters of control operations, in which it would be possible to expand the scope of the non-destructive dynamic control method, simplify the hardware implementation of the method, reduce the cost of testing while improving the accuracy of measurements and improving working conditions.

 The solution to this problem is provided by the fact that in the method of non-destructive quality control of the finished reinforced concrete product, including fixing the controlled product on supports mainly in accordance with the operating conditions, excitation of vibrations in it, determining the frequency and logarithmic decrement of vibrations, comparing the obtained values of the dynamic parameters of the controlled product with values corresponding parameters of the reference product obtained under the same control modes and fixing conditions And determining based on the comparison of quality indicators controlled products according to the invention is carried out in the excitation product forced longitudinal oscillation. Forced longitudinal vibrations excite in the frequency range lying in the resonance region of the controlled product.

 It is advisable to additionally measure the dependence of the values of the dynamic parameters of the products on the magnitude of the level of excitation energy in them of longitudinal vibrations, for which it is necessary to compare the magnitude of the change in the values of the corresponding dynamic parameters depending on the level of excitation energy of longitudinal vibrations.

 It is advantageous to sequentially measure the dynamic parameters in the forced and free oscillation modes, and the dynamic parameters corresponding to the free oscillation mode are measured at the stage of the transition process that takes place after the termination of the action on them, exciting the forced longitudinal vibrations.

The advantages of the proposed method are as follows:
the possibility of an integrated assessment of the quality indicators of products of variable stiffness, as well as products working not only in conditions of a simple stress-strain state, but also in conditions of complex resistance (this is achieved due to the possibility of taking into account the effect on the overall stress-strain state of the product of each reinforcing bar separately);
to increase the accuracy and reliability of determining controlled quality parameters due to a more complete account of the influence of all product sections, including support parts;
in weakening the requirements for fulfilling strict boundary conditions, since in the case of longitudinal vibrations the influence of a loose fit of the lower face of flat products to supporting devices is less significant;
the sensitivity of the method to individual defects of the product increases, especially to the presence of cracks (which is manifested in a sharp change in the shape of the recorded vibrations), as well as under-stressing of reinforcing bars and violation of the compatibility of concrete with reinforcement (this is detected during the diagnosis of each reinforcing bar);
in the absence of any significant restrictions on the magnitude of the input energy, since the magnitude of the excitation energy of the vibrations has a significantly smaller effect on the values of the dynamic parameters determined by the fundamental harmonic of the longitudinal vibrations compared with the prototype method;
the ability to conduct research for products under loading and working in the elastic-plastic stage;
to simplify hardware implementation, reduce the cost of testing while improving measurement accuracy and improving working conditions. (Indeed, an increase of 1.5–2 orders of magnitude of the measured resonance frequencies of oscillations when non-destructive testing of products according to the parameters of longitudinal vibrations occurs in the mid-frequency sound range helps to save: firstly, spurious network interference, that is, it allows to increase noise immunity, and therefore, the accuracy of measurement of controlled dynamic parameters of products; secondly, from the use of expensive non-standard or highly specialized primary conversion devices vibration displacements, measuring and recording instruments designed for low-frequency sound or infrasound frequency ranges; in addition, the energy and material consumption of vibration exciters is reduced, since longitudinal vibrations in products require significantly lower energy, and the vibration exciters of the above range have significantly less energy mass compared to low-frequency for bending vibrations).

 The method involves the identity of the boundary conditions of the controlled and reference products. If it is necessary to control the products standing in the structure, then the serial and reference products must have boundary conditions corresponding to the operating conditions.

 The drawing shows a block diagram of a device that implements the proposed method.

 A device for implementing the method of non-destructive quality control of a finished reinforced concrete product includes an investigated reinforced concrete product 1, mounted on supports 2 in accordance with operating conditions, a mechanical vibration emitter 3 and a mechanical vibration receiver 4 mounted on opposite ends of the product 1, and a generator 5, amplifier 6, frequency meter 7, electronic oscilloscope 8, switch 9, digital voltmeter 10, storage electronic oscilloscope 11. The output of the generator 5 through amplifier 6 is connected to to the oscillator 3 of mechanical vibrations, and the output of the receiver 4 of mechanical vibrations through the switch 9 is connected in the forced oscillation mode to the electronic oscilloscope 8 and the digital voltmeter 10, and in the free oscillation mode to the storage electronic oscilloscope 11. The output of the generator 5 is also connected to the frequency meter 7 and the second input electronic oscilloscope 8.

 The method is implemented as follows.

 The controlled product 1 is installed on the supports 2 mainly in accordance with the operating conditions, and after reconciling the density of the support, it is mounted on the supports 2 at the opposite ends of the product 1, the emitter 3 of mechanical vibrations and the receiver 4 of mechanical vibrations. Then, longitudinal vibrations are excited in the product 1 by applying mechanical vibrations to the emitter 3 amplified by the amplifier 6 an electric signal from the generator 5, while the amount of energy supplied to the emitter 3 is set at a predetermined level. The excitation of mechanical vibrations in the product 1 is carried out in the mid-frequency sound range of 0.2-10 kHz. The oscillations of the product 1 are converted using the receiver 4 of mechanical vibrations into an electrical signal, the magnitude of which (measured by a digital voltmeter 10) is used to judge the amplitude of the vibrations of the product 1. Using the electronic oscilloscope 8, the shape of the mechanical vibrations in the product 1 is monitored.

 The frequency of the signal of the generator 5 is smoothly or stepwise changed, and for each frequency value (measured by the frequency meter 7), the amplitude of the longitudinal vibrations of the product 1 is measured. The resonant frequency and the logarithmic decrement are determined from the obtained amplitude-frequency characteristic of the longitudinal vibrations of the controlled product 1.

 Then, using the switch 9, the power of the emitter 3 of mechanical vibrations is turned off, as a result, free damped oscillations are established in the product 1, which are recorded using a storage electronic oscilloscope 11. Two modes of free damped oscillations of the product 1 are also determined, the oscillation frequency and the logarithmic decrement.

 The above procedure is repeated when the emitter 3 is subjected to mechanical vibrations of electric energy of another predetermined level, the number of energy levels being set at least three.

 The obtained values of the dynamic parameters of the controlled product and / or changes in these values depending on the levels of excitation energy of longitudinal vibrations are compared with the values of the corresponding dynamic parameters and / or changes in these values depending on the level of excitation energy of the reference product obtained with the same operating parameters. Based on a comparison of the values and / or changes in the values of the dynamic parameters of the reference and controlled products, a judgment is made about the strength, stiffness, crack resistance and the prestressing value of the reinforcement of the tested product.

 The proposed method can be used in the manufacture of reinforced concrete products at the construction industry enterprises for the integrated assessment of strength, stiffness, crack resistance and the prestressing value of reinforcement of products of constant and variable length stiffness, working both under transverse bending and any other stressed state. This method allows you to more carefully control the quality of the product, which works both in the elastic and in the elastic-plastic stages at various stages of loading.

Claims (3)

 1. A method of non-destructive quality control of a finished reinforced concrete product, including fixing the controlled product on supports in accordance with the operating conditions, exciting vibrations in it, determining the resonant frequency and logarithmic decrement of vibrations, comparing the obtained values of the dynamic parameters of the controlled product with the values of the corresponding parameters of the reference product obtained under the same control modes and fixing conditions, and the determination of the quality indicators by comparison the state of the controlled product, characterized in that they excite forced longitudinal vibrations in the product in the frequency range lying in the resonance region of the controlled product.  2. The method according to claim 1, characterized in that they measure the dependence of the dynamic parameters of the products on the magnitude of the level of excitation energy of longitudinal vibrations in them, while additionally comparing the magnitude of the change in the values of the corresponding parameters depending on the level of excitation energy of longitudinal vibrations.  3. The method according to p. 1, characterized in that the dynamic parameters of the products are measured sequentially in the forced and free oscillation modes, and the dynamic parameters corresponding to the free oscillation mode are measured at the stage of the transient process that occurs in the products after the termination of the stimulating longitudinal fluctuations.