• Energy Research
• Restricted close
• Open Source close
• IT close
• NL close
• US close
• ES close
• BE close

Waste management contributes to sustainable development since waste can be transformed into valuable resources and commodities. Moreover, it helps resolve the concerns related to the limitation and scarcity of natural resources. Improving waste management means carrying out activities such as prevention, reuse, recycling and recovery, in the perspective of circularity, to minimize waste. Some methodologies and indicators may support sustain and monitor waste, such as the material flow and cost accounting, the life cycle assessment, and the carbon and water footprint.

Abstract Mediterranean islands have the advantage of favourable climatic conditions to use different marine renewable energy sources. Remote sensing can provide data to determine wind energy production potential and observational activity to identify, assess and detect suitable points in large marine areas. In this paper, a new combined model has been developed to integrate wind speed assessment, mapping and forecasting using Sentinel 1 satellite data through images processing and Adaptive Neuro-Fuzzy Inference System and the Bat algorithm. Synthetic Aperture Radar (SAR) satellite images from the Sentinel 1 satellite have been used in order to detect offshore and nearshore wind potential. Particularly, Sentinel 1 images have been analysed by means of the SNAP software. Then, to extract data about wind speed and direction, a GIS software for mapping the wind climate has been used. This new methodology has been applied to the North-Central coasts of Sardinia Island and then focused on six main small islands of La Maddalena archipelago. Furthermore, ten Hot Spots (HSs) have been identified as interesting because of their high-energy potential and the possibility to be considered as sites for future implementation of Wind Turbine Generators (WTGs). Finally, the ten identified HS have been used as input data to train and test the proposed forecast model.

L’articolo affronta gli aspetti generali della riqualificazione energetica degli edifici esistenti, mettendo in luce come le politiche di incentivazione e la strutturazione di alcuni percorsi tecnologici abbiano prodotto un circolo vizioso del retrofit, che agisce come un freno alla diffusione delle riqualificazioni energetiche. La prima parte si focalizza sulla letteratura internazionale, isolando alcune dimensioni utili alla ricostruzione dello stato dell’arte in Italia; la seconda parte analizza le politiche nel contesto italiano, i meccanismi che ne depotenziano gli effetti e le motivazioni della assenza di interventi di riqualificazione su scala medio-grande nelle città italiane; la terza parte affronta il tema dal punto di vista dei percorsi tecnologici, mettendo in luce alcuni aspetti inerenti la difficile strutturazione del campo organizzativo del retrofit energetico e la perdurante incertezza attorno ai dispositivi di efficienza e risparmio. Nelle conclusioni vengono fornite alcune indicazioni di policy, mettendo in luce come le politiche urbane agiscano in modo più marcato sull’efficienza energetica che sul risparmio energetico, depotenziando i sistemi di incentivazione adottati su scala nazionale.

In the present work, the supercritical water gasification (SCWG) of biomass is analyzed with a view to outlining the possible thermodynamic constraints that must be taken into account to develop this new process. In particular, issues concerning the formation of solid carbon and the process heat duty are discussed. The analysis is conducted by means of a two-phase non-stoichiometric thermodynamic model, based on Gibbs free energy minimization. Results show that char formation at equilibrium only occurs at high biomass concentrations, with a strong dependence on biomass composition. As regards the process heat duty, SCWG is mostly endothermic when biomass concentration is low, although a very small amount of oxidizing agent is able to make the process exothermic, with only a small loss in the heating value of the syngas produced.

Doubly-fed induction generators (DFIGs) are widely used in wind turbine systems. Traditionally, they rely on the grid voltage to operate. However, the increasing penetration of renewables necessitates wind turbines that can contribute to grid stability, and grid-forming control (GFM) has emerged as an attractive solution. Traditionally, the GFM control of DFIGs has been proposed as a single-loop control of the rotor flux magnitude and orientation, while double-loop schemes based on virtual impedance or virtual admittance have been scarcely investigated. This paper analyzes the operation and small-signal stability of a virtual-impedance-based dual-loop GFM control for DFIG. The small-signal impedance-model is derived and used to analyze the system stability in case of strong and weak grid connection. Electromagnetic transient simulations on a 1.5 MW wind turbine system are presented to validate the analysis.

Abstract Thermal energy storage (TES) will improve the efficiency and output of solar power plants. TES based on thermochemical cycles is an interesting option as thermochemical cycles can provide high energy storage densities and allow longer heat storage time. The use of multivalent solid oxide reduction–oxidation (REDOX) reactions for thermochemical heat storage is a promising option. Several concepts are feasible for coupling solar energy to the redox reaction. Among those a directly irradiated rotary kiln is one of the most interesting because it is able to provide high mass flow rates and high amounts of active material. A solar-heated rotary kiln was set-up and operated in the solar furnace of DLR for thermal reduction and oxidation of cobalt oxide. The redox material was fed into the reactor batch wise and reduced on-sun at temperatures of about 900 °C and re-oxidized off-sun in the same rotary kiln. Both steps were carried out in an air atmosphere. Thirty cycles were performed with one batch showing no evident degradation of the material. The results confirm that the rotary kiln is a feasible reactor set-up for the solar reduction of metal oxides and, hence, for thermochemical energy storage.

Thermokinetics of Biochar production.