31 research outputs found
Lessons Learnt in Implementation of Coordinated Voltage Control Demonstration
publishedVersionPeer reviewe
The Choice of the Best Surgery After Single Level Anterior Cervical Spine Discectomy: A Systematic Review
1D model for investigation of energy consumption and wear in die designs used for biomass pelleting
Cloud droplet activation and surface tension of mixtures of slightly soluble organics and inorganic salt
International audienceCritical supersaturations for internally mixed particles of adipic acid, succinic acid and sodium chloride were determined experimentally for dry particles sizes in the range 40-130nm. Surface tensions of aqueous solutions of the dicarboxylic acids and sodium chloride corresponding to concentrations at activation were measured and parameterized as a function of carbon content. The activation of solid particles as well as solution droplets were studied and particle phase was found to be important for the critical supersaturation. Experimental data were modelled using Köhler theory modified to account for limited solubility and surface tension lowering
Practical Implementation of Optimal Voltage Control in Distribution Network : System Verification, Testing and Safety Precautions
acceptedVersionPeer reviewe
En revurdering af den danske mund- og klovesygeepidemi i 1982-1983 baseret pĂĄ stammeidentifikation ved sekvensbestemmelse
Gas-phase advanced oxidation as an integrated air pollution control technique
Gas-phase advanced oxidation (GPAO) is an emerging air cleaning technology based on the natural self-cleaning processes that occur in the Earth’s atmosphere. The technology uses ozone, UV-C lamps and water vapor to generate gas-phase hydroxyl radicals that initiate oxidation of a wide range of pollutants. In this study four types of GPAO systems are presented: a laboratory scale prototype, a shipping container prototype, a modular prototype, and commercial scale GPAO installations. The GPAO systems treat volatile organic compounds, reduced sulfur compounds, amines, ozone, nitrogen oxides, particles and odor. While the method covers a wide range of pollutants, effective treatment becomes difficult when temperature is outside the range of 0 to 80 °C, for anoxic gas streams and for pollution loads exceeding ca. 1000 ppm. Air residence time in the system and the rate of reaction of a given pollutant with hydroxyl radicals determine the removal efficiency of GPAO. For gas phase compounds and odors including VOCs (e.g. C6H6 and C3H8) and reduced sulfur compounds (e.g. H2S and CH3SH), removal efficiencies exceed 80%. The method is energy efficient relative to many established technologies and is applicable to pollutants emitted from diverse sources including food processing, foundries, water treatment, biofuel generation, and petrochemical industries