Determination of the specific surface area of non-porous stone materials obtained by milling asphalt concrete

Introduction. The paper considers methods for determining the specific surface area of porous stone materials formed during milling of asphalt concrete pavements with road cutters. The specific surface area is a key parameter affecting the adhesive properties, compactness and durability of secondary asphalt concrete mixtures.
Materials and methods. The paper presents a method for determining the specific surface area of nonporous stone materials. The method is based on three-dimensional scanning followed by the construction of a point cloud. The resulting polygonal models of individual particles are used to calculate the area and volume.
Results. As a result, the values of the surface area and volume of particles of stone material have been obtained. The stone material was previously partitioned into fractions according to the particle size by sieving it through sieves with variable cross-section sizes. In addition, a method for determining the specific surface area of non-porous stone materials has been proposed, which allows for increased accuracy.
Discussion and conclusion. The method for determining the specific surface area of non-porous stone materials described in this paper can be used not only in the road and construction industries, but also in the metallurgical, chemical, and mining industries. The key result of the work is that the method can be used to determine, for example, the bitumen content or consumption of bitumen emulsion in the preparation of asphalt and cement mixtures during recycling. Additionally, the method provides assessment of the energy expended both during the milling and the grinding of other solid materials.

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