Foundational Technologies for Aerospace, Energy, Defense, Autonomy
At Reinventy, patents are not ancillary assets—they are the core infrastructure of the company’s technology ecosystem.
Over the past years we have initiated an intensive and highly structured innovation program, developing multiple patent families that are now converging into a coherent, modular and synergistic technological architecture.
Our inventions are not isolated blocks: each patent strengthens and expands the functional perimeter of the others. Materials, propulsion, energy systems, electromechanics, cybersecurity, and autonomous intelligence are engineered to interconnect seamlessly—forming a single, scalable technological platform.
As part of this strategic program, Reinventy has already launched several cornerstone patent filings, and our roadmap for 2025–2026 includes the planned submission of several dozen additional patents, covering advanced materials, solid-state energy systems, high-efficiency propulsion, secure autonomy, and sovereign AI architectures.
Our approach is based on three principles:
1. Sovereign Innovation – All critical technologies are conceived, engineered and protected in-house.
2. Integrated Patent Architecture – Every invention is designed to interlock with adjacent patents in materials, energy systems, propulsion, AI, and autonomous control.
3. Dual-Use Readiness – All patented technologies are engineered for applicability in both civilian and defense-grade environments.
Below is a curated overview of the primary patent families that constitute Reinventy’s emerging IP platform.
Canadian Patent Application No. 3,281,244 – Filing Date: 26 Jul. 2025 (CIPO)
Extreme Performance, Intelligent Monitoring, Stealth Innovation
XHT™ represents a breakthrough class of ultra-high-temperature ceramic composites engineered to operate where conventional materials fail.
By combining refractory diborides, nano-scale SiC, carbon-nanotube/graphene percolation networks, and optionally metallic sensing or stealth inserts, XHT™ establishes an entirely new multifunctional architecture for aerospace, energy and defense.
The XHT™ family is structured into three synergistic variants—ULTRA™, PRO-SENSE™, and STEALTH ARMOR™—each designed to interoperate within the broader Reinventy materials platform.
XHT ULTRA™ — Unmatched Ultra-High-Temperature Ceramic Composite
Description:
Formulated for continuous operation above 2 800–3 000 °C, XHT ULTRA™ integrates HfB₂/ZrB₂ refractory phases with nano-SiC and CNT/graphene networks, delivering exceptional oxidation resistance, high tensile strength, low thermal conductivity, and compatibility with embedded tungsten filament networks for high-temperature autosensing.
Key Applications:
– Hypersonic vehicles and glide bodies
– Thermal protection systems (TPS)
– Rocket nozzle and scramjet components
– Fusion and concentrated-solar high-flux receivers
XHT PRO-SENSE™ — Precision Structural Health Monitoring
Description:
XHT PRO-SENSE™ incorporates nickel micro-filaments and advanced piezoresistive pathways within the ceramic matrix, enabling continuous structural-health monitoring up to 1 500 °C.
This variant is optimized for early detection of micro-fractures, fatigue onset, strain accumulation and thermal-gradient stress.
Ideal for:
– High-performance automotive components
– Aerospace structural elements
– UAV and drone hot-structures
– Industrial sensing under extreme conditions
XHT STEALTH ARMOR™ — High-Temperature Radar-Absorbent Composite
Description:
A unique combination of multifunctional ceramic phases and embedded titanium stealth mesh, providing broadband radar-cross-section attenuation (−20 to −30 dB) while maintaining mechanical strength and thermal integrity up to 1 500 °C.
Target domains:
– Stealth airframes and UAVs
– Missile and glide-body outer skins
– Naval and land-based defense systems
– High-temperature low-observable structures
Canadian Patent Application No. 3,266,570 – Filing Date: 02 Mar. 2025 (CIPO)
Solid-State Safety, High Energy Density, Self-Healing Metal Interface
LIMAXA™ introduces a fundamentally new electrochemical architecture that merges a semi-liquid gallium–aluminum (Ga–Al) anode, a UV-photopolymerized ionic-liquid solid electrolyte, and a high-capacity MnO₂–Si composite cathode.
The result is a high-performance, fully solid-state aluminum-ion system offering unprecedented safety, recyclability, and volumetric energy density.
LIMAXA™ is engineered as a modular platform, enabling multiple future embodiments and ensuring direct integration with Reinventy’s next-generation energy storage roadmap.
Core Technical Innovation
1. Semi-Liquid Ga–Al Xtreme Anode (Self-Healing Behavior)
Unlike conventional aluminum-based systems, the LIMAXA™ anode incorporates a gallium-rich phase that becomes partially fluid within the 60–80 °C operating range.
This enables:
– Continuous self-healing of micro-protrusions
– Suppression of dendritic aluminum growth
– Stable cycling under high current densities
– Uniform charge distribution and reduced internal stress
The Ga–Al alloy is structurally stabilized by a minimal polymer matrix, ensuring full solid-state integrity while retaining the benefits of controlled liquefaction.
2. UV-Cured Ionic-Liquid Solid Electrolyte
The electrolyte is formed by photopolymerizing a mixture of (EMIM Cl + AlCl₃), methacrylate monomers, and conductive additives.
This creates a fully solid, nonvolatile, nonflammable ionic-conduction matrix, eliminating any need for:
– Liquid sump
– Fluid circulation
– External reservoirs
– Pumping systems
Any by-products, including Al(OH)₃, remain micro-encapsulated within the polymer structure.
3. MnO₂–Si Composite Cathode
A tailored combination of manganese oxide and silicon nanoparticles provides:
– High areal capacity
– Mechanical stability
– Compatibility with the Al-ion chemistry
– Superior electron-conduction reinforcement through carbon and copper nanostructures
Key Performance Attributes
– Volumetric Energy Density: 600–700 Wh/L (with potential 900–1000 Wh/L in advanced configurations)
– Cycle Life: > 2 000 cycles with <20% capacity fade
– Operating Temperature: 60–80 °C for optimal Ga liquidity and stability
– Failure Modes: Intrinsically safe, no thermal runaway, no liquid leakage
– Environmental Profile: Fully recyclable system based on abundant materials (Al, Ga, Si, Mn)
Target Applications
– Aerospace & UAV power modules
– Defense-grade solid-state energy systems
– High-safety industrial storage
– Electric mobility & portable power applications
– Energy-dense battery packs with thermal stability constraints
Canadian Patent Application No.3,293,296 – Filing Date: 24 Nov. 2025 (CIPO)
Sovereign Autonomy, Deterministic Safety, Hardware-Enforced Control Integrity
The Synthetic Pilot Architecture™ defines a new class of safety-critical embedded intelligence, designed to integrate generative AI into autonomous platforms while maintaining deterministic, certifiable behavior.
Its structure is based on a tri-core cognitive-safety hierarchy—Prefrontal, Guardian, Realtime—which isolates probabilistic reasoning from physical actuation and ensures that no command can ever bypass deterministic validation.
This architecture is modular, interoperable and scalable across UAVs, AGVs, maritime systems, industrial robotics, and defense platforms.
Core Architectural Framework
1. Prefrontal Core — Generative Intent Engine
Executes high-level reasoning using LLMs, VLMs and multimodal generative models.
Responsible for:
– Interpreting mission goals and environmental context
– Producing structured “Action Intents”
– Engaging retrieval-augmented grounding through an embedded Memory Core
– Operating asynchronously, isolated from hardware controls
The Prefrontal Core never interfaces directly with actuators.
2. Guardian Core — Deterministic Validation Layer
A dedicated supervisory unit that evaluates every AI-generated intent through deterministic logic, ensuring:
– Semantic coherence and absence of hallucinated references
– Temporal validity and freshness of reasoning
– Compliance with safety envelopes, mission policies and domain regulations
– Guaranteed fallback directives when ambiguity or risk is detected
Only intents validated by the Guardian Core can propagate downstream.
3. Realtime Core — Hardware-Isolated Control Authority
Operates on hard real-time cycles, maintaining continuous monitoring and emergency reflexes.
It is the only module allowed to generate actuator commands.
Safety functions include:
– Instant override of any pending command
– Collision avoidance, stabilization and emergency braking/hovering
– Execution guarantees independent of generative AI load
– Deterministic reflexes preserved even during cognitive failure
This separation creates a fail-safe, certifiable autonomy pipeline.
Supporting Subsystems
Digital Retina™ — Structured Perception Layer
A hardware-accelerated preprocessing pipeline that transforms raw sensor data into deterministic perceptual events, enabling:
– Low-latency object recognition
– Motion vectors and segmentation
– Event-driven activation of multimodal reasoning
– Temporal gating to prevent uncontrolled VLM invocations
Memory Core — Forensic Intelligence & RAG Engine
Stores:
– Episodic mission logs
– Sensor embeddings and contextual memories
– Validation histories and rule activations
– Audit-grade “Intent → Validation → Action” chains
Ensures sovereignty, transparency and regulatory compliance across EU AI Act, ISO 13849, aerospace and defense frameworks.
Key Advantages
– Deterministic safety regardless of AI model complexity
– Hardware-enforced control isolation (actuation cannot be corrupted)
– Sovereign on-device autonomy, no cloud dependency
– Fail-operational behavior under degraded sensors, EMI, or model failures
– Full forensic auditability
– Scalable to swarms, fleets, industrial cells and cross-domain robotics
Target Domains
– Unmanned Aerial Vehicles (UAVs)
– Maritime autonomy (surface & subsea)
– Logistics AGVs and industrial robotics
– Defense ISR and high-risk mission autonomy
– Critical-infrastructure inspection platforms
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