The use of binary A15 systems as low-Tc superconductors is of great importance for the development of many modern engineering and technological solutions. As a typical representative of this family, we chose the Nb₃Sn system for our structural studies. Our presentation will focus on two main results: The first is the atomic-scale modeling of Nb chain formation in the condensation of the 3:1 binary combination of Nb and Sn atoms. We will discuss reconstruction in the context of the symmetry of the cubic structure, specifically the transformation of the bcc-type superlattice with Im-3m space symmetry and the crystal phases arising along the Im-3m→Pm-3n symmetry-lowering pathway. We argue that, when Nb and Sn are condensed as Nb₃Sn in the Pm-3n cubic structure, the stabilization of the chains of Nb atoms running parallel to the main cubic axis is caused by their periodic off-center displacements. Change in the point symmetry of the Nb positions is a necessary condition for stable charge ordering. The other effect we will discuss relates to the crystallographic orbits of the Nb sites in the Nb₃Sn Pm-3n lattice geometry. The point symmetry microstructure is caused by the 6c→6d shift in the change of occupation of the 6c Wyckoff positions. Such an occupation shift induces the phenomenon of structural modulation between niobium chain orientations and, thus, defines the bulk structure as composed of subsystems, where the orientation of the niobium chains induces anisotropy caused by the distinct chain patterning in the neighboring lattice regions. Translational symmetry of the Pm-3n space group begins to hold only through the partitioned subsystems. This allows us to predict that the crystallographic equivalence in the point symmetry of Nb sites may be removed when the alloy microstructure is assembled as adjacent grains.