TECHNIQUES FOR MAKING ASPHALT-CONCRETE AND ROAD SURFACES MORE DURABLE

INTERNATIONAL MULTIDISCIPLINARY JOURNAL FOR

RESEARCH & DEVELOPMENT

SJIF 2019: 5.222 2020: 5.552 2021: 5.637 2022:5.479 2023:6.563 2024: 7,805

eISSN :2394-6334 https://www.ijmrd.in/index.php/imjrd Volume 12, issue 08 (2025)

243

TECHNIQUES FOR MAKING ASPHALT-CONCRETE AND ROAD SURFACES

MORE DURABLE

Mirzaev Abdikhannon

Teacher of Transport logistic’s department,

Andijan State Technical Institute, Andijan, Uzbekistan

Abstract.

The problem of making asphalt concrete pavements more durable in the current high-

speed automobile environment is taken into consideration. It is demonstrated how asphalt

concrete pavements function across a broad frequency range. Test results for asphalt concrete's

fatigue life at various loading frequencies are shown. In order to extend the fatigue life of

asphalt concrete pavements, design solutions are suggested.

Keywords:

solutions. pavements, asphalt concrete fatigue life, testing, design

INTRODUCTION

The continuous increase in traffic intensity on highways, the increase in the load-bearing

capacity of vehicles and axles, and the increase in speed limits require a new approach to

considering the issues of road surface strength. The main factors determining the strength of

asphalt concrete pavements are traffic loads, the design and condition of the road surface, and

climatic conditions. The development of effective methods for increasing the strength of asphalt

concrete pavements should be based on the study of the properties of asphalt concrete taking

into account real loading conditions.

Experimental research

Experimental studies conducted at stationary observation points made it possible to obtain

information about the real dynamic stress-strain state of road structures and to conclude that the

asphalt-concrete pavement is subject to dynamic effects in a wide frequency range. When the

bucket moves from the wheel of the machine, bending deformations do not develop in the

asphalt-concrete layer. The components of the asphalt-concrete mixture perform high-frequency

vibrations that vary in phase and amplitude, and destruction occurs with the appearance of

cracks in the voids formed as a result of the decomposition of the mineral material. In this

process, the role of the elastic properties of bitumen decreases, and the role of adhesion

between the components of asphalt-concrete increases [1-4].

To establish the effect of polymer and adhesive additives on the fatigue failure mechanism,

asphalt concrete samples No. 1 (asphalt concrete mixture of type B without additives),

composition No. 2 (asphalt concrete mixture of type B with 0.3% RTEP of polymer additive)

and asphalt concrete mixture of type B with surfactant additive of composition No. 3 were

tested. The tests were conducted at low (17 Hz) and high (50 Hz) loading frequencies.

Comparison of test results at low frequencies shows a significant increase in the failure time by

samples with polymer additives (2.6 times). The effect of SAW on fatigue strength, in contrast

to low frequencies, was more pronounced when tested at high frequencies.

In order to objectively assess the durability of asphalt-concrete pavements in modern conditions

of intensive high-speed traffic, it is necessary to switch to new methods of testing asphalt-

concrete, corresponding to the repeated impact of vehicles on loading conditions. and the

selection of asphalt-concrete composition taking into account the estimated number of

applications of the calculated load over the entire service life.

To increase the fatigue life of asphalt-concrete pavements on roads with high traffic intensity,

new design solutions are required: the use of asphalt-concrete mixtures with polymer-bitumen

binders in the lower layers of the pavements; the use of an organic binder with high adhesive

INTERNATIONAL MULTIDISCIPLINARY JOURNAL FOR

RESEARCH & DEVELOPMENT

SJIF 2019: 5.222 2020: 5.552 2021: 5.637 2022:5.479 2023:6.563 2024: 7,805

eISSN :2394-6334 https://www.ijmrd.in/index.php/imjrd Volume 12, issue 08 (2025)

244

properties in the upper (closed) layers of the pavement (if they are absent, the introduction of

surfactant additives into the bitumen is mandatory); the use of dense mixtures with a high

bitumen content in the composition at the highest tensile stresses (the lower layer of the asphalt-

concrete layer "package"), as well as reinforcing layers [5-7].

The use of modified bitumen

- bitumen reinforced with polymers or rubber increases the

elasticity and resistance to cracking of asphalt.

Additional fillers

- adding mineral powder, fibers or other reinforcing materials - increase the

wear and deformation resistance of asphalt.

Improving the production and laying process

Laying at optimal temperature

- the quality of asphalt concrete depends on temperature, and

improper laying in extremely cold or hot conditions leads to rapid deterioration of the coating.

High-quality mixing

- asphalt and filler materials must be evenly distributed.

Compaction by pressure

- compaction of the asphalt coating using special roller and vibratory

equipment, making it strong and durable.

Reinforcement of the main layer

Preparing a solid and dense base

- the gravel, sand and geogrid layers under the asphalt

concrete layer must be of high quality.

Improving the drainage system

- the accumulation of water can corrode the asphalt, causing

cracking and deformation. Therefore, the water drainage system must be well planned.

Maintenance and prevention

Regular maintenance

- if small cracks and potholes are closed in a timely manner, they will

not be allowed to grow larger.

Protective coatings

- special protective coatings can be applied to the asphalt to protect it from

water, UV light and chemical effects.

Preventing scratches and cracks

- durability is increased by controlling the weight of vehicles

and using protective layers on the asphalt surface.

CONCLUSION

In order to objectively assess the durability of asphalt-concrete pavements in modern conditions

of intensive high-speed traffic, it is necessary to switch to new methods of testing asphalt-

concrete, corresponding to the repeated impact of vehicles on loading conditions. and the

selection of asphalt-concrete composition taking into account the estimated number of

applications of the calculated load over the entire service life.

To increase the fatigue life of asphalt-concrete pavements on roads with high traffic intensity,

new design solutions are required: the use of asphalt-concrete mixtures with polymer-bitumen

binders in the lower layers of the pavements; the use of an organic binder with high adhesive

properties in the upper (closed) layers of the pavement (if they are absent, the introduction of

surface-active additives into the bitumen is mandatory); the use of dense mixtures with a high

bitumen content in the composition at the highest tensile stresses (the lower layer of the asphalt-

concrete layer is the "package"), as well as reinforcing layers.

REFERENCES

1.Abramov Yu.V. "Yo'l sirtlari va poydevorlari" - Moskva, Transport, 2001 yil.

2.Miroshnichenko A.I. "Asfalt-beton qoplamalar texnologiyasi" - Moskva, Stroyizdat, 1990 yil.

3.Kozlov V.V. "Asfalt-beton aralashmalari va ularni qo'llash" - Moskva, Transport, 1985 yil.

4.P. S. Kandhal "Asfalt qoplamalari: muhandislar va arxitektorlar uchun dizayn, ishlab

chiqarish va texnik xizmat ko'rsatish bo'yicha amaliy qo'llanma" - CRC Press, 2016 yil.

5.Hiks R. G., Scholz T. V. "Polimer bilan o'zgartirilgan bog'lovchilar bilan asfalt qoplamasining

ishlashini yaxshilash" - Qurilish muhandisligi materiallari jurnali, 2003 yil.

6.Malygin V.I. "Yo'l sirtlari uchun polimer qo'shimchalari" - Moskva, Transport, 2005 yil.