Green Technology

OUR SERVICES

GREEN TECHNOLOGY

Onshore Hydrocarbon Recovery (OHRS)

Trinova deploys a state-of-the-art, closed-loop methodology for onshore hydrocarbon recovery and sludge treatment. Our three-stage process is engineered to maximize the recovery of valuable oil from complex waste matrices while neutralizing environmental hazards, ensuring our clients achieve both high resource yields and strict environmental compliance.

Advanced Nano-Biodegradable Chemical Treatment

Together with ACME Chemical, We initiate the recovery process using proprietary, eco-friendly nano-surfactants rather than harsh, traditional solvents. These biodegradable nano-chemicals penetrate dense sludge and emulsions at the molecular level, effectively breaking the hydrocarbon bonds and lowering surface tension.

3 phase mechanical separation (Tri-Canter)

In a single pass, the system precisely divides the mixture into distinct streams of recovered oil, process water, and residual solid sludge, allowing for immediate hydrocarbon harvesting with minimal footprint.

Total Resource Recovery: Pyrolysis & Water Treatment
Hydrocarbon and Wastewater further recovery by combining our modular pyrolysis and wastewater treatment module. Recovered oil achieve 5% BS&W while Standard B quality of water achievable.

Quantum Catalytic Pyrolysis: The Next Frontier in Waste to Energy

Quantum Catalytic Pyrolysis is an advanced thermochemical process that utilizes specialized catalysts designed at the molecular level to break down complex polymers (like plastics or biomass) into high-value fuels and chemicals. Unlike traditional pyrolysis, which relies solely on brute-force heat, QCP leverages quantum-mechanical interactions between the catalyst surface and the feedstock.

Lower Energy Barrier

In standard pyrolysis, molecules require a massive “push” of thermal energy to break their chemical bonds. Quantum catalysts act as molecular “shortcuts.” By providing an alternative reaction pathway, they lower the threshold of energy required for the reaction to begin.

Increased Throughput

Reaction constant (k) increase exponentially according to Arrhenius Equation. This result in faster conversion rates allowing more feedstock in the same amount of time

Thermal Efficiency & Cost Saving

Lower OPEX (reduce fuel and electricity)
Longer Equipment Lifespan: Reduced carbon fouling and heat degradation
Higher Product Quaility: Prevent overcracking of oil into low value gases

Modular Gasification Technology: Scalable, Fast, and Flexible

Trinova’s Modular Gasification Technology represents a breakthrough in decentralized energy production. Our proprietary systems are engineered to convert a wide array of organic waste and biomass into high-purity syngas, providing a sustainable, carbon-neutral alternative to fossil fuels. By integrating advanced gasification kinetics into a mobile, scalable architecture, Trinova enables industries to transform “waste liability” into “energy assets” with unprecedented efficiency.

Rapid Deployment Architecture:
Factory Tested – Fully assembled and commissioned at our facility to ensure performance.
Plug-and-Play – Housed in standardized containers for easy transport and minimal onsite civil works.
Scalable – Modular building block design allows you to increase capacity seamlessly.

High-Purity Syngas Generation:
At the heart of our technology is a sophisticated multi-stage filtration and cooling process.

Tar-Cracking Excellence – Internal reactor geometry is optimized to break long hydrocarbon chains.
Engine-Ready Output – The resulting syngas is cleaned to meet the stringent requirements of high-performance gas engines and thermal boilers.

Dual Reactor Biochar Production Equipment: Continuous & High Output.

By integrating advanced gasification kinetics into a mobile, scalable architecture, Trinova enables industries to transform “waste liability” into “energy assets” with unprecedented efficiency.

Advanced Thermal Recirculation (One-Fire, Two Steps)
Trinova’s unique “One-Fire Two-Steps” design maximizes thermal efficiency. The heat source simultaneously dries the raw material in the outer chamber while carbonizing it in the inner chamber. This dual-use of energy significantly reduces fuel consumption and operational costs.

Syngas Self-Sufficiency
Our systems are designed to be energy-autonomous. After the initial heating phase, the combustible gases (Syngas) produced during carbonization are captured, scrubbed, and redirected back into the combustion chamber to fuel the process resulting in near zero external fuel

Continuous 24/7 Operation
Unlike batch-style kilns, Trinova’s horizontal rotary design allows for simultaneous feeding and discharging. This ensures high throughput and a streamlined industrial workflow without the downtime associated with cooling and reloading.

TRI-BESS – Intelligent Battery Storage System

Our Battery Energy Storage Systems (BESS) represent the pinnacle of modern energy management. Designed to bridge the gap between intermittent renewable generation and reliable power delivery, our proprietary BESS architecture offers a safe, scalable, and high-efficiency solution for grid-scale, industrial, and commercial application.

Advanced Liquid Cooling Architecture
Trinova BESS units utilize a sophisticated liquid-cooling system rather than traditional HVAC-based air cooling.

Thermal Uniformity: By maintaining a temperature variance of less than 3°C across all cells, we significantly extend battery lifecycle and enhance round-trip efficiency.
Compact Footprint: High thermal management efficiency allows for higher energy density within a smaller physical enclosure, saving valuable site space.

Intelligent Battery Management System (BMS)
At the heart of every unit is our multi-tier Trinova-IQ BMS. This system monitors every cell in real-time to ensure peak performance and safety.

Active Balancing: Maximizes usable capacity by ensuring all cells remain at optimal charge levels.
Predictive Analytics: AI-driven algorithms identify potential cell failures before they occur, reducing maintenance downtime