This paper establishes a theoretical engineering framework for instantaneous, non-local digital data transfer. The proposed system utilizes a coupling mechanism between topological Skyrmion states and the discrete vacuum lattice at the Planck scale. The research details the use of Skyrmions as stable topological bits integrated within the Planck lattice to ensure data integrity under extreme conditions. It further explains the implementation of 3-6-9 vortex geometry to define force vectors within the core, preventing informational blurring and decoherence. The described protocol enables zero-latency communication by utilizing the non-local properties of the Planck-scale spin network, bypassing the limitations of the constant c. Additionally, the paper provides a comprehensive cost estimation for a non-local backbone node, covering specialized hardware such as Planck-scale cryogenic interferometers and Berry phase state emitters. This module provides the essential foundation for the transmission of complex binary structures, which is further explored in the subsequent research.