RU2707984C1 - Method of determining fire resistance of construction materials and structural elements - Google Patents

Abstract

FIELD: monitoring and measuring equipment.

SUBSTANCE: invention relates to investigation of physical and mechanical properties of materials and can be used for determination of fire-resistance of construction materials. Disclosed is a method of determining fire resistance of building materials, characterized in that the test sample is fixed in a fire chamber, mechanically loaded, heated and determined crack formation time. Prior to mechanical loading of the test specimen, rods-sound ducts connected to piezoelectric transducers connected to the ultrasonic control device are attached to it. Ultrasonic wave passage time is measured through the test instrument through the test sample during the entire heating process.

EFFECT: calculating the ultrasonic wave velocity through the test specimen, and when the ultrasonic wave speed is sharply reduced in the test sample, which indicates the moment of crack formation, the fire resistance of the test specimen is determined.

1 cl, 1 dwg

Description

The invention relates to the field of studies of the physical and mechanical properties of materials, namely, to methods for determining the fire resistance of building materials and structural elements when exposed to high temperatures.

Currently, there is a need for strict consideration of such an important factor that determines the operational capabilities of various building materials, such as fire resistance. This factor acquires a significant role in cases where low-strength and brittle building materials are used, for example, foam blocks and gas blocks.

A known method for determining the fire resistance of compressed elements of reinforced concrete structures of a building, including testing compressed elements of reinforced concrete structures (RC) of a building (RF patent No. 2281482, "Method for determining the fire resistance of compressed elements of reinforced concrete structures of a building", IPC G01N 25/50, published on 08/10/2006).

The disadvantage of this method is the high complexity and duration of the tests, a large number of parameters necessary to determine the fire resistance of building structures: geometric dimensions of the reinforced concrete, heating scheme of dangerous sections in a fire, the degree of reinforcement of concrete of the compressed elements and the conditions for their fastening; density, humidity and thermal conductivity of concrete; the magnitude of the standard loads on the reinforced concrete and the degree of stress of dangerous sections of the compressed elements.

The prior art method for controlling internal defects based on the acoustic emission method (patent for invention No. 2141655, "Multifunctional acoustic emission system for diagnosing structures and a diagnostic method based on it", IPC G01N 29/14, published on November 20, 1999).

The disadvantage of this method is the complexity of the control process, including filtering interference, analysis of signal parameters and assessing the degree of danger of sources additionally determined from the calculated spectra taking into account the coordinates of the sources. In addition, the known method involves the use of sophisticated equipment, where operations are performed on processors distributed over a local area network of multichannel registration and signal preprocessing modules and signal analysis modules under the control of a real-time operating system.

The prior art methods for determining the fire resistance of building materials and structures, which consist in the fact that the material or structural element is placed in the fire chamber, is subjected to heat and its fire resistance is evaluated for time to failure (GOST 30247.0-94 (ISO 834-75) Test methods for fire resistance. General requirements).

The disadvantages of the known methods is the subjectivity and low accuracy of determining the moment of cracking and fracture of the material, because the crack formation is fixed visually or with the help of photo-video shooting when it comes to the surface of the sample.

The closest in technical essence to this invention is a method for determining the fire resistance of building materials and structural elements, which consists in the fact that the structural element is fixed in the fire chamber, subjected to mechanical stress, a predetermined thermal effect and its fire resistance is evaluated over time before destruction (A.S. 646219, "The method of determining the fire resistance of elements of building structures", IPC G01N 3/60, publ. 05.02.1979).

This technical solution is taken as a prototype, as the most approximate method for determining the fire resistance of building materials and structural elements.

The disadvantage of this method is its low accuracy as a result of visual determination of the moment of cracking.

The objective of the authors of the invention is to develop an effective method for determining the fire resistance of building materials and structural elements.

The technical result of the claimed invention is to improve the accuracy of determining the fire resistance of building materials and structural elements.

The specified technical result is achieved due to the fact that in the method for determining the fire resistance of building materials, characterized in that the test sample is fixed in the fire chamber, it is mechanically loaded, heated and the cracking time is determined according to the invention, rods are attached to it before mechanical loading of the test sample sound guides connected to piezoelectric transducers connected to an ultrasonic monitoring device measure the transit time from the monitoring device an ultrasonic wave through a test specimen during the heating process calculated the rate of passage of ultrasonic waves through a test specimen, and a sharp decrease in the speed of passage of the ultrasonic wave in the test sample, meaning the time of fracturing, determine fire resistance of the test sample.

The fastening of the sound guide rods connected to the piezoelectric transducers and the ultrasonic control device on the test specimen provides the possibility of the passage of the ultrasonic wave during its mechanical loading and thermal influence, and the determination of the time and speed of the ultrasonic wave propagation. The moment of cracking is determined by a sharp decrease in the speed of passage of an ultrasonic wave in an element of a building structure.

In the proposed method, the test samples of building materials are subjected to complex tests, as provided in the prototype, however, the cracking time is determined not visually, but by the parameters of the ultrasonic waves — the time and speed of passage of the ultrasonic wave through the test sample.

The principle of the ultrasonic control method is based on the fact that solid materials are a good conductor of sound waves, whereby waves are reflected not only from boundary surfaces, but also internal defects (cracks, various inclusions, etc.). The effect of the interaction of sound waves with the material increases as the wavelength decreases and, accordingly, the oscillation frequency increases.

The ability of the ultrasonic method to detect latent defects such as cracks is based on the fact that a plane defect (crack) located in the path of the ultrasonic pulse delays its arrival, since the path of the ultrasonic pulse is lengthened when the defect is enveloped. Therefore, the presence of an internal defect (crack) in the sample of building material can be detected by increasing the ultrasound transit time (lowering the ultrasound propagation speed) as compared to a defect-free section. The formation and advancement of a main crack in a sample of building material during heating is preceded by the propagation of microcracks directed in different directions. Under conditions of high temperatures, a microcrack that arose at the point where a dangerous combination of stresses was reached can spread very quickly over a large distance and lead to the destruction of the structure as a whole.

This approach, in contrast to the prototype, in the proposed method increases the reliability of tests, provides the ability to objectively, automatically determine the moment of crack formation in samples of building materials and structures, while the internal defect or network of cracks is fixed until a main crack is formed, i.e. until it reaches the surface of the sample.

In FIG. The experimental dependence of the speed of ultrasound transmission on temperature in samples of aerated concrete and foam concrete is presented.

The control parameter was the ultrasound transit time through the controlled sample, which was measured in microseconds (μs) using a portable ultrasonic device at an operating frequency of ultrasonic vibrations of 60 kHz with a relative error of ± 1%. An informative indicator was the speed of ultrasound passing through the test sample, which was determined with a relative error of not more than ± 2% according to the formula:

C = (L / (t ₁ -t ₂ )) ⋅10 ³ ,

where C is the speed of ultrasound, m / s; L - sound base (sample size in the direction of sound), mm; t ₁ is the transit time of the ultrasound, μs; t _{2 is the} travel time (delay) in the sound ducts, μs.

In the process of heating the samples (see Fig.), The speed of ultrasound slightly decreases due to thermal expansion. At the point in time corresponding to 500 ° C for foam concrete and 530 ° C for aerated concrete, there is a sharp decrease in the speed (increase in time) of ultrasound in the test sample, which indicates the beginning of the process of cracking inside the sample and a decrease in fire resistance.

The proposed method allows to achieve a technical result, which consists in achieving a higher efficiency of the method for determining the fire resistance of building materials and structural elements due to objective and accurate determination of the fact of violation of their integrity by ultrasonic testing, which allows to establish the cracking moment by a sharp increase in time and a decrease in the speed of ultrasonic wave propagation in the building structure element.

Claims (1)

A method for determining the fire resistance of building materials, characterized in that the test sample is fixed in the fire chamber, mechanically loaded, heated and crack formation time is determined, characterized in that before the mechanical loading of the test sample sound rods are connected to it, connected to piezoelectric transducers connected to ultrasonic control device, measure the transit time of the ultrasonic wave through the test sample by the control device throughout about the heating process, calculate the speed of passage of the ultrasonic wave through the test sample, and with a sharp decrease in the speed of passage of the ultrasonic wave in the test sample, indicating the time of cracking, determine the fire resistance of the test sample.

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