RU2354977C2 - Method of determining reinforcement ratio of objects made from steel fibre reinforced concrete - Google Patents

Abstract

FIELD: physics; measurement.

SUBSTANCE: present invention relates to quality control of construction materials, particularly to steel fibre reinforced concrete. The method involves pre-measurement of parametres of current, flowing through an electromagnetic contour lying on the surface of a sample of steel fibre reinforced concrete with a known reinforcement ratio. A calibrated graph of the current parametres versus the reinforcement ratio is plotted. After that, parametres of current flowing through the same contour on the surface of a steel fibre reinforced concrete object with an unknown reinforcement ratio are measured, and using the calibrated graph, the reinforcement ratio of these samples is determined. The reinforcement ratio is determined for steel fibre reinforced concrete with known thickness of the object and known distance between the surface of the object and the part of the object reinforced by the fibres. The electromagnetic contour is made in form of a multiple-turn circular coil, whose diametre is at least twice longer than the fibres. The length of the coil is at least 10 times shorter than its diametre. The frequency of current flowing through the coil lies in the range from 2 kHz to 50 kHz.

EFFECT: determination of the reinforcement ratio of objects made from steel fibre reinforced concrete.

4 cl, 1 dwg

Description

The invention relates to the field of quality control of building materials, namely steel fiber concrete.

The closest analogue of the invention is a method of controlling the distribution of steel fibers using a meter of a protective layer of reinforcement in concrete [Sergeev VA, Khegay ON Control the distribution of steel fibers with the IZS device. - In the book: The use of fiber-reinforced concrete in construction. - L .: Knowledge, 1985. - p.63-67]. However, the readings of the IZS device strongly depend not only on the reinforcement coefficient, the distance between the sensor and the fiber-reinforced part of the product, the thickness of the product, but also on the diameter of the fibers and their orientation.

The technical problem solved by the invention is to determine the coefficient of reinforcement in products made of steel fiber concrete.

The essence of the invention lies in the fact that preliminary measure the parameters of the current passing through the electromagnetic circuit located on the surface of the samples of steel fiber reinforced concrete with a known coefficient of reinforcement, build a calibration dependence of the current parameters on the coefficient of reinforcement, then measure the parameters of the current passing through the same circuit located on the surface steel fiber reinforced concrete products with an unknown reinforcement coefficient, and using the calibration dependence determine the reinforcement coefficient in these samples. In this case, the reinforcement coefficient is determined in steel fiber concrete products with a known thickness of steel fiber concrete and with a known distance from the surface of the product to the fiber-reinforced part of the product.

The invention is based on the fact that when steel-reinforced concrete is introduced into the alternating field of the electromagnetic circuit, the steel fibers are magnetized and induction currents arise in them and Joule-Lenz heat is released. Therefore, the inductance and active resistance of the electromagnetic circuit varies depending on the reinforcement coefficient of steel fiber reinforced concrete. Accordingly, the parameters of the alternating current passing through the circuit change.

The electromagnetic circuit is made in the form of a round multi-turn coil to exclude the influence of the orientation of the fibers. In IZS, the contour is linear in shape [passport of the measuring device of the protective layer IZS-10N of the Bobruisk plant of weighing instruments VESOPribor, 1988]. The length of the coil should be less than its diameter by at least 10 times, since in this case the largest part of steel fiber concrete is in the magnetic field of the coil. The diameter of the coil must exceed the fiber length by at least two times, so that the number of fibers sufficient for reliable measurement is in the magnetic field of the coil. The maximum diameter of the coil is determined by the size of the area of the steel fiber concrete sample in which it is necessary to determine the reinforcement coefficient. The frequency of the current through the coil should be in the range from 2 to 50 kHz (V ISS 500 Hz). At a lower frequency, the sensitivity of the method greatly depends on the diameter of the fibers, at a higher frequency, the sensitivity decreases due to a decrease in the capacitance of the coil.

The current parameters are measured by any microammeters or millivoltmeters of alternating current or voltage using electrical circuits intended for such measurements.

The proposed method illustrates the installation scheme for measuring the reinforcement coefficient (drawing), where 1 is a sample of steel fiber concrete, 2 is a coil, 3 is an electric capacity, 4 is an alternating voltage generator, 5 is a microammeter, 6 is a resistor.

Example.

Samples of steel fiber concrete are formed with a thickness of 2, 4, 6 cm with reinforcement coefficients of 20, 40, 60, 80, 100, 120, 140, 160, 180, 200 kg / m ³ . After hardening, a thin multi-turn coil with a diameter of 12 cm is applied to the samples. Using a series-connected capacitance, the coil is tuned to the resonant frequency of a 20 kHz alternating voltage generator. A microammeter with a resistor measures the current value. The table shows the results of measurements of current in μA. According to the data obtained, the microammeter scale is graduated in units of measurement of the reinforcement coefficient. A specimen of steel fiber reinforced concrete 4 cm thick with an unknown reinforcement coefficient is made. The coefficient of reinforcement is determined by the proposed method 53 kg / m ³ , the sample is destroyed, the number of fibers and the coefficient of reinforcement 51 kg / m ³ are calculated. The accuracy of determining the coefficient is 4%.

The proposed method allows to determine the coefficient of reinforcement in steel fiber concrete with a known thickness of the product and a known distance between the surface of the product and the fiber-reinforced part of the product. It can be used to control the distribution of fibers in the manufacture of steel fiber concrete products.

Table The distance from the coil to the sample, cm Sample Thickness, cm The coefficient of reinforcement, kg / m ³ 0 twenty 40 60 80 one hundred 120 140 160 180 200 0
0
0
one
2 6
four
2
four
four 80 74 68 62 56 fifty 44 38 32 36 twenty 80 75 70 65 60 55 fifty 45 40 35 thirty 80 76 72 67 63 59 54 fifty 46 41 37 80 - 74 - 68 - - - 56 - - 80 - 77 - 74 - - - 68 - -

Claims (4)

1. A method for determining the coefficient of reinforcement in products made of steel fiber concrete, characterized in that the parameters of the current flowing through an electromagnetic circuit located on the surface of the samples of steel fiber concrete with a known coefficient of reinforcement are pre-measured, a calibration dependence of the current parameters on the reinforcement coefficient is built, and then the parameters of the current flowing are measured through the same circuit located on the surface of a steel fiber concrete product with an unknown reinforcement coefficient and using a calibration curve values determine the reinforcement coefficient in these samples. 2. The method according to claim 1, characterized in that the reinforcement coefficient is determined in steel fiber concrete with a known thickness of the product and a known distance between the surface of the product and the fiber-reinforced part of the product. 3. The method according to claim 1, characterized in that the electromagnetic circuit is made in the form of a multi-turn round coil, and the frequency of the current passed through the coil lies in the range from 2 to 50 kHz. 4. The method according to claim 3, characterized in that the diameter of the coil is more than the length of the fiber at least 2 times, and the length of the coil is less than its diameter at least 10 times.