RU129245U1 - INSTALLATION FOR EVALUATING THE FATIGUE OF ASPHALT CONCRETE DURING CYCLIC DYNAMIC INFLUENCES - Google Patents

Abstract

1. Installation for assessing fatigue of asphalt concrete under cyclic dynamic influences, comprising a frame, a lifting table made with the possibility of changing the height, a node for positioning the beam specimen, a node for loading the beam specimen, made with the possibility of applying a cyclic dynamic load and the ability to measure displacements and loading forces comprising a connecting rod-slider mechanism, characterized in that the positioning unit of the sample beam contains clamping grips installed at the ends of the sample beam parallel to the transverse axis of symmetry of the frame, and an intermediate elastic base made in the form of a container filled with model soil with the possibility of tight contact with the plane of the sample beam facing it, while the loading element of the loading unit of the sample beam is made with the possibility of its positioning in the middle of the beam sample 2. Installation for assessing fatigue of asphalt concrete under cyclic dynamic effects according to claim 1, in which the measurement of the loading force is performed using a force sensor in the form of a beam of equal resistance. The apparatus for assessing fatigue of asphalt concrete under cyclic dynamic influences according to claim 1, wherein the displacements are measured using strain gauges and springs, the free ends of the springs being fixed to the frame. Installation for assessing fatigue of asphalt concrete under cyclic dynamic effects according to claim 1, in which a screw pair is used to change the height of the lifting table. Installation for assessing fatigue of asphalt concrete under cyclic dynamic effects according to claim 1, which is additional

Description

The utility model relates to the field of road construction, namely, equipment for testing materials, in particular asphalt concrete, for fatigue under cyclic dynamic effects, and can be used in the road economy, construction of airfields, and the construction industry.

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 is known according to the method for assessing fatigue of asphalt concrete under cyclic dynamic influences, comprising a base, a sample positioning unit in the form of a pair of clamping forks, a sample loading unit configured to measure displacements and loading forces and consisting of two connected consoles driven in oscillatory motion using a bipolar electromagnet (see RU No. 2299417, IPC G01N 3/32, publication date 05/20/2007).

The disadvantage of this technical solution is the lack of reliability of measurements during cyclic dynamic influences due to rigid pinching of the sample beam, which creates additional internal forces at the ends and the influence of the action of the bipolar electromagnet on the magnitude of the applied force and vibration characteristics.

As the closest analogue, a device for determining dynamic creep deformations of road building materials is adopted, comprising a frame, a lifting table configured to change height, a sample positioning unit in the form of a lifting table, a sample loading unit containing a connecting rod-sliding mechanism and adapted to be applied cyclic dynamic load and the ability to measure displacements and loading forces (RU No. 111293, IPC G01N 3/36, publication date 10.12.2011).

As the disadvantages of the closest analogue, one can point out the insufficient reliability of measurements under cyclic dynamic influences, as well as the increased material consumption of the structure.

The task to which the proposed utility model is directed is to increase the reliability of the estimation of the parameters of strength fatigue of asphalt concrete under cyclic dynamic effects.

The technical result achieved by solving the stated problem is expressed in increasing the reliability of estimating the strength fatigue parameters of asphalt concrete under cyclic dynamic impacts by providing a more accurate simulation of the actual operating conditions of the asphalt concrete coating during testing (calculation model “underlay - asphalt concrete”), as well as reducing the material consumption of the structure.

The problem is solved in that in the installation for assessing fatigue of asphalt concrete under cyclic dynamic influences, comprising a frame, a lifting table made with the possibility of changing height, a node for positioning the beam sample, a node for loading the beam sample, made with the possibility of applying a cyclic dynamic load and the ability measurements of displacements and loading force, comprising a connecting rod-slider mechanism, the positioning unit of the sample beam contains clamping grips installed at the ends the sample beam parallel to the transverse axis of symmetry of the frame and the intermediate elastic base, made in the form of a container filled with model soil with the possibility of tight contact with the plane of the sample beam facing it, while the loading element of the loading unit of the sample beam is made with the possibility of its positioning in the middle of the beam -sample, in addition, the measurement of the loading force is performed using a force sensor in the form of a beam of equal resistance, the displacement measurements are performed using a strain gauge and a spring, wherein the free ends of the springs are secured to the chassis to change the height of the lifting table using a pair of helical and installation structure further provided with a number of loadings counter.

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."

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.

The drawings show a test setup including a frame 1, a lifting table 2, a positioning unit for a sample beam 3 containing clamping grips 4 and an intermediate elastic base 5, a loading unit containing a connecting rod-sliding mechanism 6, a force sensor 7, strain gauges 8 and springs 9 , screw pair 10, counter of the number of loads 11.

Frame 1 consists of frame structures assembled mainly from a metal profile in the form of corners.

The lifting table 2 is made with the possibility of changing the height using a screw pair 10.

Clamping grips 4 allow you to fix the beam-sample 3 at the ends both articulated and rigidly.

The intermediate elastic base 5 is made in the form of a tank filled with model soil and allows you to use the calculation model "underlying layer - asphalt concrete".

The connecting rod-sliding mechanism 6 allows you to convert the rotational motion into translational.

The force sensor 7 is made in the form of a beam of equal resistance.

Strain gages 8 provide the ability to register bending deformations of the sample beam 3 and the intermediate elastic base 5.

The springs 9, the free ends of which are fixed on the frame 1, provide the ability to register the vertical movement (deflection) of the sample beam 3 and the intermediate elastic base 5.

The counter of the number of loads 11 allows you to register the number of cycles to failure (destruction) of the beam sample 3.

The inventive design works as follows.

Preliminarily, a number of beams-samples 3 of size 10 × 10 × 50 cm are made of asphalt concrete of various types (there may be other sizes). Then, the sample beam 3 is laid on the intermediate elastic base 5 with the possibility of tight contact and fixed at the ends (edges) on the frame 1 using clamping jaws 4. The position of the intermediate elastic base 5 is regulated by the lifting table 2 using a screw pair 10.

Next, loading with a bending load occurs using a connecting rod-slider mechanism 6, which transmits vibrations and force to the sample beam 3. During testing, the load is applied to the middle of the sample beam 3 to failure under sequential loading in certain modes, while controlling the temperature and the reported sample force using a force sensor 7. The duration and amplitude of the load are determined by the frequency spectrum of the effects of vehicles on asphalt pavement. Also, during the test, at each loading mode, bending deformations of the beam-sample 3 and intermediate elastic base 5 are recorded using strain gauges 8, the number of cycles to failure (failure) of the beam-sample 3 using the counter of the load number 11, the vertical displacement (deflection) of the beam sample 3 and the intermediate elastic base 5 using springs 9, the formation of cracks and their development.

Next, an analysis is made on the basis 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 of stress - strain, energy of dissipation in each particular cycle and throughout tests, 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 (5)

1. Installation for assessing fatigue of asphalt concrete under cyclic dynamic influences, comprising a frame, a lifting table made with the possibility of changing the height, a node for positioning the beam specimen, a node for loading the beam specimen, made with the possibility of applying a cyclic dynamic load and the ability to measure displacements and loading forces comprising a connecting rod-slider mechanism, characterized in that the positioning unit of the sample beam contains clamping grips installed at the ends of the sample beam parallel to the transverse axis of symmetry of the frame, and an intermediate elastic base made in the form of a tank filled with model soil with the possibility of tight contact with the plane of the sample beam facing it, while the loading element of the loading unit of the sample beam is made with the possibility of its positioning in the middle of the beam sample. 2. Installation for assessing fatigue of asphalt concrete under cyclic dynamic effects according to claim 1, in which the measurement of the loading force is performed using a force sensor in the form of a beam of equal resistance. 3. Installation for assessing fatigue of asphalt concrete under cyclic dynamic influences according to claim 1, in which the measurement of displacements is performed using strain gauges and springs, and the free ends of the springs are fixed on the frame. 4. Installation for assessing fatigue of asphalt concrete under cyclic dynamic effects according to claim 1, in which a screw pair is used to change the height of the lifting table. 5. Installation for assessing fatigue of asphalt concrete under cyclic dynamic effects according to claim 1, which is additionally equipped with a counter of the number of loads.

Images