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    • br Experimental design materials and methods The experimenta

    2018-10-25


    Experimental design, materials and methods The experimental campaign was conducted at the Politecnico di Milano (IT) large scale wind tunnel, characterized by a working section of 4.00m width and 3.84m height. The wind tunnel was operated in a “free jet” (open) configuration with a central section of 6.00m length. Rotor torque and thrust measurements were taken using a high precision test bench, which was instrumented using a precision torquemeter (to provide rotor aerodynamic torque), an absolute encoder (to provide rotor angular velocity) and 2 full strain gauge bridges (to provide rotor aerodynamic thrusts in both the longitudinal direction and in the transversal one). Both upright and 15° tilted rotor configurations were tested in the open jet wind tunnel, as schematized in Fig. 1, showing also the local coordinate system for the longitudinal (X) direction adopted during thrust measurements. It is worth observing that only the aerodynamic thrust is provided in all tables and graphs, i.e. no corrections have been introduced in order to avoid the rotor tower drag force. Furthermore, for tilted tests, the strain gauge offset has been recorded with tilted rotor: it phospholipase a2 inhibitor was therefore possible to measure the wind thrust avoiding the component due to rotor weight bending moment. See [1,2] for more details regarding data acquisition and data processing techniques.
    Acknowledgments The present work is a result of the contributions from the DeepWind project, supported by the European Commission, Grant 256769 FP7 Energy 2010 – Future emerging technologies, and by the DeepWind beneficiaries: DTU(DK), AAU(DK), TUDELFT(NL), TUTRENTO(I), DHI(DK), SINTEF(N), MARINTEK(N), MARIN(NL), NREL(USA), STATOIL(N), VESTAS(DK) and NENUPHAR(F). The authors would like to thanks the colleagues of Università di Trento (I) for their support in performing the measurement campaign.
    Data
    Experimental design, materials and methods The “future hot summer years” are created using the output from UKCP09 weather generator [2]. UKCP09 weather generator offers future weather time series. The outputs incorporates the UKCP09 climate projections. The “future hot summer years” are selected based on the weighted cooling degree hours and physiologically equivalent temperature. They can represent hot summer years to be used in assessing the risk of overheating and thermal discomfort or heat stress. The procedure of the creation is as follows (Fig. 1). The detailed method is presented in [1].
    Acknowledgments All data created during this research are available from the University of Bath data archive at http://doi.org/10.15125/BATH-00190.
    Data Data analysis indicated that MSP particles had a BET multipoint surface area of 2.34m2/g and a total pore volume at 0.9925P/P0 of 0.0002cm3/g. The FTIR of the fresh and Hg2+-loaded MSP particles at wave numbers from 400 to 4000cm−1 are shown in Fig. 1. The data of the effects of solution pH on the adsorption percentage of mercury ions by CTP and MSP is presented in Fig. 2. The data acquired for adsorption of mercury ions by different doses of CTP and MSP is also depicted in Fig. 3.
    Experimental design, materials and methods
    Acknowledgments Authors would like to thank Bushehr University of Medical Sciences, Iran for providing the financial support (Grant No.: E94-102) to conduct this work.
    Data Data include fungal DNA amplicon sequences, OTUs, and taxonomic data from fermenting must in a winery, in a laboratory microcosm experiment, and in control communities. Associated experimental and metadata are provided in separate tables. Experimental data include microcosm biomass and glucose concentrations, plus the data needed to calculate a \"keystone index,\" described in [1]below, for twenty microcosm yeast isolates. Metadata include winery vat identity, fermentation age, microcosm treatment, microcosm age, and microcosm replicate.
    Experimental design, materials and methods