CRT Transport Application - a demonstration Project

CRT and its industrial applications.

Carbon Recycling Technology

Advancing a 135 MW Carbon Recycling Technology Demonstration One of the key challenges of the energy transition is reliability. Solar and wind are expanding rapidly, yet power systems still require firm generation capacity to maintain grid stability and support industrial demand. At Clean Energy and Water Technologies Pty Ltd (CEWT) we are advancing a 135 MW Carbon Recycling Technology (CRT) demonstration project in Australia. The project integrates: • renewable hydrogen production • carbon recycling methanation • high-efficiency gas turbine generation • closed-loop CO₂ recycling The objective is to demonstrate a scalable architecture for reliable carbon-neutral energy. Key project parameters: Net dispatchable power: 135 MW Electrolyser capacity: 274 MW Total project CAPEX: ~A$1.6 billion The project is designed to support industrial decarbonisation and firm renewable power generation. We are currently engaging with strategic partners, infrastructure investors, and industrial collaborators interested in participating in the development of this first-of-a-kind project. #EnergyInfrastructure #IndustrialDecarbonisation #Hydrogen #SyntheticFuels

CEWT invites investors and strategic Partnership.

Carbon Recycling Technology CRT integrates renewable electricity, hydrogen production, carbon recycling, and high-efficiency power generation into a closed-loop energy system. The process works as follows: 1. Renewable electricity produces hydrogen via electrolysis. 2. Hydrogen reacts with captured CO₂ in a methanation reactor. 3. The reaction produces renewable methane (RNG). 4. RNG fuels high-efficiency combined-cycle turbines. 5. The CO₂ produced is captured and recycled back into the system. This creates a circular carbon energy cycle. Carbon atoms circulate within the system rather than being emitted to the atmosphere. Demonstration Project CEWT is advancing a 135 MW Carbon Recycling Technology demonstration project in Australia. Key parameters Net dispatchable power output 135 MW Electrolyser capacity 274 MW Total estimated CAPEX A$1.624 billion Technology integration • Renewable hydrogen production • Methanation fuel synthesis • Gas turbine combined cycle generation • Closed carbon recycling loop The project is designed to demonstrate a scalable architecture for firm renewable energy. Strategic Importance CRT addresses several critical needs of the global energy transition. Reliable Renewable Power CRT converts intermittent renewable electricity into firm dispatchable generation. Carbon Neutral Fuel Cycles Carbon is continuously recycled, eliminating ongoing fossil carbon inputs. Infrastructure Compatibility CRT can leverage existing: • gas turbines • gas pipelines • LNG infrastructure • industrial fuel systems Industrial Decarbonisation CRT can support: • green iron and steel • desalination • chemicals • industrial heat • grid-scale energy storage Why This Matters Now Three major trends are accelerating the need for new energy system architectures: 1. Renewable energy expansion Large volumes of renewable electricity require reliable system balancing. 2. Industrial decarbonisation Heavy industries need carbon-neutral fuel solutions. 3. Energy security Countries are seeking alternatives to fossil fuel imports while maintaining reliable energy systems. CRT addresses all three simultaneously. Investment Opportunity CEWT is currently engaging with strategic investors, industrial partners, and infrastructure developers to support the deployment of Carbon Recycling Technology. Potential collaboration areas include: • project equity participation • strategic industrial partnerships • technology licensing • infrastructure investment The 135 MW demonstration project represents the first commercial-scale implementation of CRT. Contact Clean Energy and Water Technologies Pty Ltd (CEWT) Strategic partnership and investment enquiries welcome.

Clean Energy and Water Technologies Pty Ltd (CEWT) Carbon Cartridge Loop for LNG Prime Movers This concept proposes a closed carbon logistics loop for LNG‑fuelled long‑haul prime movers. Carbon dioxide emitted during vehicle operation is captured onboard and unloaded periodically at a service facility (“works”), and recycled into renewable methane using hydrogen produced from renewable electricity. In this architecture, carbon atoms circulate in a managed loop while renewable electricity provides the energy input. Methane (LNG) acts as the recyclable carrier molecule, enabling long‑range heavy transport without new fossil fuel inputs. Operating Principle 1. LNG is combusted in the vehicle, producing CO2 and water. 2. An onboard capture cartridge collects CO2 from the exhaust stream. 3. At approximately 200 km intervals, the cartridge is swapped at a works facility. 4. Captured CO2 is combined with renewable hydrogen in a methanation reactor. 5. The resulting methane is liquefied to renewable LNG and used to refuel vehicles. Example Energy Balance (Prime Mover – 200 km) Parameter (200 km Prime Mover Leg) Value LNG consumed ≈ 60 kg CO2 generated ≈ 165 kg Hydrogen required for recycling ≈ 30 kg Electrolyser electricity required ≈ 1.65 MWh Methane regenerated ≈ 60 kg Key Infrastructure Elements Vehicle • LNG prime mover engine • Exhaust CO2 capture cartridge • Cartridge swap interface Works Facility • Carbon cartridge receiving and handling system • CO2 conditioning and compression • Renewable electricity powered electrolyser • Methanation reactor system • LNG liquefaction and storage • LNG refuelling station Strategic Advantages • Utilises existing LNG heavy‑transport engine platforms • Converts CO2 from waste into fuel feedstock • Renewable electricity becomes the true energy input • Carbon atoms circulate as a reusable carrier molecule • Suitable for freight corridors, mining fleets and logistics hubs Clean Energy and Water Technologies Pty Ltd (CEWT) | ABN 61 691 320 028 | ACN 691 320 028