R.E-expande.R bridges the gap between gas turbine ramp-up times and the dynamics of peak demands.
Its modular, scalable and robust design allows centralized, distributed, even temporary buffering.
Coupling a high-capacity buffer with fast AC conversion, optimizes energy arbitrage and negative prices.
Initially designed for integration into round tower, as reinforced concrete withstands static compression best.
Though mechanical, advanced composites or alloys could enhance performance and design configuration.
As an alternatives for chemical batteries this mechanical design replace a hugh amount of rare metals.
His high-density is based on the high energetic molecular /cristal bonds in alloys or composites.
A higher energy density per weight and per € than batteries while offering a substantially longer lifespan.
Strategic autonomy: Investing in capital goods that reduce costs improves competitiveness and resilience.
Seanergy.be establishes a new sector, leveraging existing shipbuilding expertise and craftsmanship.
It enables emerging carbon capture technologies and selective membranes to become profitable.
These WECs are not very expensive, can be build in a normal atelier by on the job trained workers.
EU shipbuilding capacity is still in place and can be deployed, scaled up and specialized.
Integration hydrogen with existing infrastructure reduces transition costs to society.
A diversified energy mix and infrastructure ensures that Europe's can absorb supply shocks.
Avoiding overcapacity will reduce energy costs, thereby boosting jobs and EU competitiveness.
Sea-wiggle.R operates in all wave conditions, irrespective of direction or profile.
Unlike anchored installations, our WECs operate without negative interference from proximity effects.
It self-adaptive hydraulics optimize energy capture across different wave heights.
Storms pose no operational risk, as it moves relative to wave rather than resisting them.
A built-in anti-fouling mechanism remove marine growth on some components, reducing maintenance.
Deployment will boost sensors industry, monitoring & AI systems for autonomous vessels.
Autonomous free-floating within designated international ocean zones is most productive.
Rough seas, Drifting challenge is alike as: Ship Autonomous Collision-Avoidance Strategies.
Resilience requires redundancy — failure in any part should not cascade into large-scale disruptions.
Given potential threats, MTTR/R is an essential factor in maintaining comfort and reactivity.
Grid stability depends also on diversified energy sources smoothing fluctuations and failures.
While WECs are smaller than cargo ships, maritime impact mitigation strategies remain essential.
Large-scale decentralized truly renewable energy source elimitates coal-based power plants.
Promote CO₂ capture to be converted into synthetic HC for a green chemical industries.
Enabling hybrid applications and e-fuels for logistics, relieving the grid from congestion.
Reduce reliance on rare metals, limites environmental and ethical concerns tied to mining.
More alternatives could avoid irreversible hasty sub-optimization during the transition.
Our H2 Limits Ni and Li extraction in valuable natural habitats of indigenous communities.
Seanergy.be does not compete with agricultural photosynthesis nor the eco-service of wind.
Deployment energy extraction within designated maritime zones has no land constraints.
An export proposal is in place to provide renewable fuels to regions undergoing energy transition.
As a complet fleet, 'Seanergy.be' offers B2B / N2N export potential for leasing energy generation.
The factory ship, with its conversion capacity, can function as a refueling station for marine vessels.
Seanergy.be revalues industrial assets if deep blue hydrogen and circular carbon strategies are used.
Fixed Sea.wiggle.Rs can share their hydrogen production with windmills during economical shutdowns.
Engines on e-fuels are most suited for ambulances, police, fire brigade, and military operations.
Prevent shutdowns during remote intervention, traffic jams, critical in cold seasons, tunnels, mountains.
To deal with ocean waves, a vectorial analysis must look at magnitude, direction, sense, and density of water.
In areas of interest, observed wave appearance show typically more random motion compared to wind flows.
The interplay among the forces and seabed relief shapes the stochastical behavior of waves and turbulent storms.
The wave dynamic is applified by local bathymetry, with circular or elliptical motion shifting in shallower waters.
Instead of resisting / altering this inescapable variability of waves, I exploit it as an asset.
Due to the local randomness no uniform pattern inamplitude, velocity, or direction can be assumed.
Switching mindset: by not forcing this behavior into even 360° rotations of a rotor in a generator.
Returning to the fundamental physical laws. Interprete the mathematical form of Maxwell equations.
Two distinct mechanisms exploites the irregular yet persistent motions between waves and the components.
The system does not require complete rotation nor linear start-end runs to induce electrical potential.
Full-cycle independency, makes this circuit highly adaptable to wave unpredictability with fewer converions.
Electrical resistance increases with the amount of adhering bubbles to the electrodes (beside precipitation).
For a seaworthy stand-alone electrolyzer, I exploit natural phenomena to accelerate bubble release.
My approach should enable water electrolysis to operate with to less buildup of migration resistance.
Due the salt content of seawater, direct electrolysis will contaminate the anode and form cloor.
To obtain purified water RO or different types of membranes and/or elctrolyte composition are applied.
Our 'Brine-barrie.R' brings in another electrochemical consideration that is probably cost effective.
The descriptions in the i-depot outlines the two physical laws behind the bubble release.
The i-depot outlines also the chemical principle behind the salt/brine barrier.
A laboratory or pilot test could be conducted swiftly, but first, a visit to an industrial installation would be beneficial to assess real-world integration, as my current knowledge is mainly theoretical.
Desalination by direct distillation during transport operating 24/24 & 365/365 without moving part.
Using direct solar energy and other heat sources in an uniquely configured pipeline.
Sol-d'eau.R provides both water and shade, making it ideal for arid regions facing water scarcity.
Synergies with semi-transparent solar panels, enabling vegetable cultivation underneath.
As a semi-closed system with minimal moving parts, it requires little maintenance beyond routine cleaning.
Integrated into some nice urban designs, Sol-d'eau.R could provide cooling and shade above future cities.
Costs can be offset by reduced air-conditioning demand and the recovery of residual heat.
International collaboration is mandatory to border ocean zones for wave energy harvesting. While Seanergy.be can contribute to synthetic fuel production, its large-scale role could be pivotal toward global decarbonization.
Global prosperity depends on fair access to and efficient use of scarce resources. Best achieved a well-balanced mix of centralized and decentralized energy systems and through optimized energy conversions.