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author Lius, Vesa Olavi
Lius, Vesa Olavi
Lius, Vesa Olavi
author_facet Lius, Vesa Olavi
Lius, Vesa Olavi
Lius, Vesa Olavi
contents <p><span>This defensive technical publication establishes prior art for the use of the ALLFROMAIR® wire-forest electrode geometry as an active fog water collector, integrated with passive radiative sub-cooling (SiO2/HfO2 selective coating on Al 6061-T6 substrate), DEP-field-enhanced droplet steering, and vibration-induced Rayleigh-resonance desorption. Quantitative analysis demonstrates collection flow rates of 1.0–6.0 L/m2/h during fog periods — 8–17x greater than standard mesh fog collectors — with combined daily yields of 4.0–7.5 L/m2/day across nine of ten global climate classes. No hardware modification to the existing system is required. Specific Energy Consumption: 0.007–0.052 kWh/m3. Published under CC BY-SA 4.0. Supplement to Defensive Technical Publication (December 2025) and Addenda 1–4 (March 2026).</span></p>
format Recurso digital
id zenodo_https___doi_org_10_5281_zenodo_18919006
institution Zenodo
language eng
publishDate 2026
publisher Zenodo
record_format zenodo
spellingShingle ALLFROMAIR® Addendum No. 5: Fog Integration — DEP-Enhanced Wire-Forest Fog Collection Combined with Passive Radiative Cooling for Atmospheric Water Harvesting (Defensive Publication, Prior Art Disclosure)
Lius, Vesa Olavi
Lius, Vesa Olavi
Lius, Vesa Olavi
atmospheric water harvesting fog collection radiative cooling passive cooling wire-forest electrode dielectrophoresis Modified Kelvin-Thomson effect DEP field selective IR emitting coating SiO2 HfO2 coating vibration desorption Rayleigh resonance droplet detachment Liquid Water Content advection fog prior art disclosure defensive publication CC BY-SA 4.0 open hardware water scarcity off-grid water supply
dew point condensation sub-cooling nucleation enhancement titanium wire electrode TiO2 nanostructure coating superhydrophilic surface HVDC field EC fan control IACU adaptive control coastal desert water Atacama fog Namib fog Benguela current Humboldt current LWC measurement fog frequency specific energy consumption SEC zero-energy water harvesting Garúa AWG alternative
<p><span>This defensive technical publication establishes prior art for the use of the ALLFROMAIR® wire-forest electrode geometry as an active fog water collector, integrated with passive radiative sub-cooling (SiO2/HfO2 selective coating on Al 6061-T6 substrate), DEP-field-enhanced droplet steering, and vibration-induced Rayleigh-resonance desorption. Quantitative analysis demonstrates collection flow rates of 1.0–6.0 L/m2/h during fog periods — 8–17x greater than standard mesh fog collectors — with combined daily yields of 4.0–7.5 L/m2/day across nine of ten global climate classes. No hardware modification to the existing system is required. Specific Energy Consumption: 0.007–0.052 kWh/m3. Published under CC BY-SA 4.0. Supplement to Defensive Technical Publication (December 2025) and Addenda 1–4 (March 2026).</span></p>
title ALLFROMAIR® Addendum No. 5: Fog Integration — DEP-Enhanced Wire-Forest Fog Collection Combined with Passive Radiative Cooling for Atmospheric Water Harvesting (Defensive Publication, Prior Art Disclosure)
topic atmospheric water harvesting fog collection radiative cooling passive cooling wire-forest electrode dielectrophoresis Modified Kelvin-Thomson effect DEP field selective IR emitting coating SiO2 HfO2 coating vibration desorption Rayleigh resonance droplet detachment Liquid Water Content advection fog prior art disclosure defensive publication CC BY-SA 4.0 open hardware water scarcity off-grid water supply
dew point condensation sub-cooling nucleation enhancement titanium wire electrode TiO2 nanostructure coating superhydrophilic surface HVDC field EC fan control IACU adaptive control coastal desert water Atacama fog Namib fog Benguela current Humboldt current LWC measurement fog frequency specific energy consumption SEC zero-energy water harvesting Garúa AWG alternative
url https://doi.org/10.5281/zenodo.18919006