RU2483290C2 - Method to assess fatigue of asphalt concrete under cyclic dynamic loads - Google Patents

Abstract

FIELD: test equipment.

SUBSTANCE: smallest size of a cross section of a sample made in the form of a bar makes at least three sizes of the largest fraction of the filler. The sample is rested against an elastic base that models the underlying layer of the road surface, and two supports at the ends of the sample. The sample is loaded with cyclic load by zero-to-tension stress cycle corresponding to the frequency range of 2-30 Hz and level of loading 0.3-200 kgf, with separate fixation of loading frequency and level of force action at a sample of asphalt concrete. In process of tests they ensure permanent contact of the sample and the elastic base, simultaneously, sample sagging is measured, its bending, stretching deformations and deformations of the elastic base are measured, afterwards they determine the module of elasticity, the coefficient of elastic base bed, the area of hysteresis loop in coordinates as, the density of internal energy depending on the number of deformation cycles up to sample damage.

EFFECT: increased validity of assessment of parameters of strength fatigue of asphalt concrete under cyclic dynamic actions.

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Description

The invention relates to techniques for testing fatigue, and in particular to methods of testing materials, in particular asphalt concrete, for fatigue under cyclic dynamic effects.

In recent years, on the roads of Russia, there has been a significant increase in traffic intensity, high-speed modes of vehicles and the carrying capacity of cars. In modern operating conditions, there is an increase in the number of applications of transport loads per unit time, which leads to the accelerated development of fatigue processes in asphalt concrete pavement. Fatigue strength of asphalt concrete - the ability of a material to resist the action of cyclic (re-alternating) loads, is the most important characteristic that determines the durability of asphalt concrete pavement and pavement in general.

Tests of asphalt concrete under cyclic loads (fatigue strength) allow us to simulate the actual loading conditions of asphalt concrete in the coating. As a result, one can determine both the stiffness (deformability) characteristics and the fatigue strength or endurance of asphalt concrete to failure. Moreover, the ranges of loading amplitudes in these test methods should be different.

A device for testing viscoelastic and plastic materials is known, including a housing fixed to the base, clamping grips with which an asphalt concrete sample is attached, and a loading mechanism in the form of a lever system with loads (RU No. 28250, IPC G01N 3/08, priority 05.08.2002 )

The disadvantages of this device are the following:

- increased complexity due to the need for suspension, removal and cyclic movement of calibrated goods;

- during testing, only deformations of the sample are recorded in time, which does not allow to reliably evaluate the parameters of strength fatigue of asphalt concrete.

As the closest analogue, a method for assessing the fatigue of asphalt concrete under cyclic dynamic effects was adopted, including attaching a specimen made in the form of a beam of rectangular cross section, loading it with a cyclic bending load until the specimen fails, recording the parameters of bending deformations with determining the value of the dissipation energy, which is used to judge the fatigue life asphalt concrete (RU No. 2299417, IPC G01N 3/32, priority 12.07.2005).

This technical solution does not allow to reliably evaluate the strength fatigue parameters of asphalt concrete under cyclic dynamic effects due to the following disadvantages:

- the geometric dimensions of the samples - beams (5 × 5 × 20 cm) are commensurate with the size of the largest fraction of aggregate, as a result do not allow to obtain reliable test results;

- the geometric parameters and natural frequency of the special consoles on which the bipolar electromagnet is mounted affect the magnitude of the applied force, the amplitude and shape of the vibrations of the test sample;

- rigid jamming of the samples creates additional internal forces at the ends of the beams;

- the inability to assess the separate effects of the frequency loading mode on the process of accumulation of damage to asphalt concrete and the level of force impact;

- the real asphalt concrete pavement operates in a zero cycle mode, but not in a symmetric cycle mode;

- the energy of dissipation (W ₃ ) is determined through the integral, which in practice complicates the assessment of fatigue strength.

The problem to which the invention is directed, is to increase the reliability of evaluating the parameters of strength fatigue of asphalt concrete under cyclic dynamic effects.

The technical result achieved by solving the problem is expressed in the following:

- providing a more accurate simulation of the actual operating conditions of the asphalt concrete pavement during testing, regarding the dimensions of the sample (take into account the scale factor), the conditions for its fastening (articulated bearing at the ends) and the calculation model (“underlying layer - asphalt concrete”);

- the use of a mechanical method of loading, allowing to evaluate the separate influence of the frequency mode of loading on the process of accumulation of damage to asphalt concrete and the level of force impact;

- testing on a zeroing cycle, corresponding to a frequency range of 2-30 Hz and a loading level of 0.3-200 kgf;

- the use of a simpler and more convenient formula for determining the energy of dissipation.

The problem is solved in that a method for assessing the fatigue of asphalt concrete under cyclic dynamic stresses, including fixing a sample made in the form of a beam of rectangular cross section, loading it with a cyclic bending load until the sample fails, recording the parameters of bending deformations with determining the magnitude of the dissipation energy, which is used to judge the fatigue the durability of asphalt concrete, characterized in that the smallest cross-sectional dimension of the beam is at least three sizes of the largest fractions of the aggregate, while the sample is supported on an elastic base modeling the underlying layer of the road surface, and two supports at the ends of the sample, and the sample is loaded with a cyclic load at a zero cycle corresponding to a frequency range of 2-30 Hz and a loading level of 0.3-200 kgf, with separate fixation of the loading frequency and the level of force acting on the asphalt concrete sample, in addition, during the tests they ensure constant contact of the sample and the elastic base, at the same time measure the deflection of the sample, its bending, p edpochtitelno tensile deformation and elastic deformation of the base, after which the modulus of elasticity of the elastic foundation bed coefficient hysteresis loop area of σ-ε coordinates internal energy density depending on the number of deformation cycles until failure of the sample.

A comparative analysis of the essential features of the proposed technical solution with the essential features of the closest analogue indicates its compliance with the criterion of "novelty."

Moreover, the features of the characterizing part of the claims provide the solution to the following functional tasks.

The sign “the smallest cross-sectional dimension of the beam is not less than three sizes of the largest aggregate fraction” provides a more complete account of the scale factor due to the large dimensions of the sample (thus excluding the formation of a sample with dimensions comparable with the sizes of asphalt fractions, which can lead to significant distortion test results).

The sign “the specimen is supported on an elastic foundation modeling the underlying layer of the pavement and two supports at the ends of the specimen” avoids additional internal forces (by means of hinging) and takes into account the compatibility of the work of asphalt concrete and the underlying layer (due to the use of the calculated model “underlying - asphalt concrete ”).

The sign “the sample is loaded with a cyclic load in a zero cycle corresponding to the frequency range of 2-30 Hz and the loading level of 0.3-200 kgf, with separate fixing of the loading frequency and the level of force acting on the asphalt concrete sample” allows us to simulate the actual operating conditions of asphalt concrete pavement, and the values the loads are selected taking into account the scale factor (due to the large size of the sample), the frequency range is taken from the standards.

» позволяет упростить и сократить продолжительность процесса расчета и анализа полученных результатов на практике.The sign "the value of the dissipation energy W ... is determined by the formula

»Allows you to simplify and reduce the duration of the process of calculation and analysis of the results in practice.

Figure 1 shows a General view of a test setup for loading cyclic bending load.

Figure 2 shows a side view of the installation, prepared for loading cyclic bending load.

Figure 3 shows the test results in the form of fatigue curves of asphalt concrete of two types - with rubber crumb and without it.

The drawings show a test installation, including a frame metal structure 1, clamping jaws 2, with which an asphalt concrete sample 3 with hinged supports (or pinched ends) is attached, an elastic base 4 of a certain thickness, the position of which is regulated by the lifting table 5 using a screw pair 6, node of mechanical vibrations, made in the form of a crank-connecting rod-slider mechanism 7 with an eccentric 8 and a drive consisting of an electric motor 9 and a belt drive 10, and the crank-floor unny mechanism 7 comprises a force sensor 11 in the form of beams of equal strength, the recording pattern imparted force displacement transducer in the form of a spring 12, a sensor 13 of the bending deformations in the form of strain gauges and the number of loadings counter 14.

The claimed method is implemented as follows.

Previously, a number of beam samples measuring 10 × 10 × 50 cm are made of asphalt concrete of various types (there may be other sizes). Then, the asphalt concrete sample 3 is laid directly on the surface layer of the elastic base 4, modeling the base of the multilayer medium, and then at the ends (edges) it is attached to the frame metal structure 1 using clamping grips 2, and the installed sample 3 during the test must be connected without interruption to elastic base 4 of a certain thickness, the position of which is regulated by the lifting table 5 with the help of a screw pair 6. Next, the electric motor 9 is turned on, and loading with a bending load occurs with using a crank-crank-slide mechanism 7, which transmits vibrations and force to the asphalt concrete sample 3. During the tests, the load is applied to the middle of the sample 3 to failure under sequential loading in certain modes, while monitoring the temperature and the force transmitted to the sample using the force sensor 11 Duration and amplitude of loading are determined by the frequency spectrum of the impact of vehicles on asphalt pavement. Also, during the test, at each loading mode, bending strains ε of sample 3 and elastic base 4 are recorded using a bending strain gauge 13, phase shift φ between stresses σ and strains ε, hysteresis loop area ΔW in coordinates σ-ε, number of cycles N to failure (destruction) of the sample 3 using the counter of the load number 14, the vertical displacement (deflection) of the sample 3 and the elastic base 4 using the displacement sensor 12, the formation of cracks and their development. Based on the test results, fatigue curves of the material are constructed, then the elastic modulus E of the sample 3 and the elastic base 4, the dissipation energy W, the bed coefficient of the elastic base 4 and the stress intensity factor are determined.

The value of the dissipation energy W, which characterizes the process of damage accumulation in road surfaces, is determined by the formula

, где

where

ΔW _i is the area of the hysteresis loop of the i-th sample in the coordinates σ-ε;

N _p - the number of cycles to failure (destruction) of the sample.

At the end, a fatigue curve is constructed in the natural coordinates σ - N and an analysis of various types of asphalt concrete is carried out according to the listed parameters and their energy states.

Thus, information on the behavior of asphalt concrete is obtained based on the analysis of the following indicators: frequency and temperature dependences of the elastic modulus, flexural, preferably tensile deformations of the sample and deformations of the elastic base, bed coefficient of the elastic base, area of the hysteresis loop in the coordinates σ-ε, energy of dissipation in each specific cycle and throughout the test, the number of cycles to failure of the sample.

Based on the test results, the design characteristics of the materials used in the design of the coating are prescribed. As a result, it is possible to determine both the stiffness (deformability) characteristics and the fatigue strength or endurance of asphalt concrete to failure.

Claims (1)

A method for assessing fatigue of asphalt concrete under cyclic dynamic effects, including attaching a sample made in the form of a beam of rectangular cross section, loading it with a cyclic bending load to failure of the sample, recording the parameters of bending deformations with determining the magnitude of the energy of dissipation, which is used to judge the fatigue life of asphalt concrete, characterized in that the smallest cross-sectional dimension of the beam is at least three sizes of the largest aggregate fraction, while the image ECs are supported on an elastic base simulating the underlying layer of the road surface and two supports at the ends of the sample, and the sample is loaded with a cyclic load in a zero cycle corresponding to a frequency range of 2-30 Hz and a loading level of 0.3-200 kgf, with separate fixing of the loading frequency and the level of force acting on the sample of asphalt concrete, in addition, during the tests they ensure constant contact of the sample and the elastic base, at the same time measure the deflection of the sample, its bending, preferably tensile deformations ation and the elastic deformation of the base, after which the modulus of elasticity of the elastic foundation bed coefficient square hysteresis loops in σ-ε coordinates internal energy density depending on the number of deformation cycles until failure of the sample.

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