Bi₂Te₃-based materials prepared by traditional zone melting often have poor mechanical properties. Although powder metallurgy followed by hot extrusion can effectively enhance mechanical strength, this approach involves a lengthy, multi-step processes including powdering, sintering, and extrusion. Such a complex procedure s hinders the development of polycrystalline Bi₂Te₃-based materials and their application in micro-thermoelectric devices. In this work, p-type Bi₂Te₃-based ribbons are first fabricated via melt spinning. Subsequently, a series of highly textured, fine-grained p-type Bi₂Te₃-based bulk materials are prepared by directly tiling these ribbons and consolidating them through spark plasma sintering (SPS). The as-spun ribbon has a strong texture, as well as numerous nanostructures and defects. The subsequent consolidation, achieved by directly tiling these ribbons and applying SPS without any pulverization, effectively preserves their intrinsic preferred orientation. This results in a strong (110) texture perpendicular to the pressing direction, which is different from those obtained via the traditional ball-milling and SPS routes. The sample sintered at 743 K exhibits an orientation factor of 0.37, comparable to those of hot-extruded counterparts. Owing to this strong texture, the sample exhibits superior electrical transport properties along the direction parallel to the pressing direction. A high power factor of 3.79 mW·m^–1·K^–2 is achieved at room temperature. Furthermore, grain refinement leads to a significant reduction in thermal conductivity. Consequently, a peak ZT value of 1.30 is obtained at 398 K for the sample sintered at 743 K, representing a 46% enhancement over the ZT values of traditional zone-melted samples. This study provides a rapid and facile strategy for fabricating highly textured, fine-grained, high-performance Bi₂Te₃-based materials, thereby laying a solid foundation for their engineering applications in micro-thermoelectric devices.