Abstract

This technical disclosure defines the architecture, calculated frequency bounds, and real-time telemetry protocols for an inline fluidic grid designed to execute non-thermal, non-chemical molecular decomposition of micro-plastic polymers (specifically Polyethylene Terephthalate [PET], High-Density Polyethylene [HDPE], and Polyvinyl Chloride [PVC]) via targeted mechanochemical shear. Bypassing traditional mechanical filtration and chemical depolymerization, the hardware configuration utilizes an inner-wall concentric cylindrical array of 960 independent lead zirconate titanate (PZT-5H) piezoelectric transducers driven with an engineered spatial phase-lag (Δ φ = π).

By generating a phase-locked radial Bessel beam profile \(J_0(k_r r)\) targeting the mechanical quality factors (Q) of specific polymer boundaries, the system concentrates destructive mechanical shear stress gradients (\(\nabla \sigma_{\text{shear}}\)) along the central axis of a borosilicate glass conduit. This induces localized viscoelastic fatigue directly within carbon-carbon aliphatic bonds (\(E_{\text{C-C}} \approx 348 \text{ kJ/mol}\)), forcing long-chain molecules to unspool into benign monomers.

Real-time telemetry and prevention of thermal fluid cavitation are maintained at ≥ 2.5 MHz via an FPGA-driven Phase-Locked Attention Gate (PLAG) tracking dynamic acoustic impedance shifts (Z(ω)). Operational frequency profiles are mathematically mapped for particle sizes ranging from 10 μm to 500 μm, bounding the destruction profiles between 3.39 MHz and 252.71 MHz under a non-turbulent laminar flow profile (Re ≤ 2100).

Finally, this disclosure provides the conceptual integration bridge linking physical macromolecular relaxation to the underlying viscoelastic substrate tension mechanics of the Dimensionally Extended Holographic Projection (DEHP) model.

Creative Commons License

Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 License.

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