Abstract:
The results of concrete hardening due to nanomodification using graphene of a mixture
of sand and Portland cement, activated in a magnetofluidized layer, are presented. The
magnetofluidized layer is a suspension of needle-shaped ferromagnetic elements in a
rotating electromagnetic field. As a result of intensive movement and constrained impact
between ferromagnetic elements and concrete particles, sand and cement are finely
ground. The results of studies of structural changes in quartz sand and Portland cement
during mechanical activation in a magnetically fluidized layer are presented and analyzed.
Changes in the surface physical and mechanical properties of sand and cement in
comparison with the initial samples were determined by X-ray diffractometry and IR
spectroscopy. During the nanomodification of concrete, difficulties arise in the uniform
distribution of graphene in the total volume due to the very small size of nanoparticles and
its small amount. The magnetofluidized layer provides a high degree of mixing, which
makes it possible to evenly distribute graphene in the volume of the concrete mixture
components, while exerting an electromagnetic effect and crushing the raw components.