br Data The data in this

Data The data in this data article has been gathered under a ‘Direct geothermal melanocortin receptor research and demonstration project’ run under the Sustainable Energy Pilot Demonstration (SEPD) program funded by the state government of Victoria, Australia. Under this project, around 20 buildings were selected for the installation of vertical GSHP systems as less expensive horizontal systems were not an option due to land space limitations. Most of these buildings are typical residential properties of 130–160m2 with 2–3 bedrooms, and their thermal energy consumptions were monitored and recorded using various instruments as described in the table above. Figs. 1–3 illustrate the hourly thermal loading of three monitored residential properties. Table 1 shows the capital cost of the installed Ground Heat Exchanger (GHE).
Experimental design, materials and methods The collected installation cost data was categorized into five main components. The ground loop installation includes drilling of boreholes, grouting, purchasing and installing geothermal loop. The head pipe installation includes digging trenches, connecting geothermal loops to head pipes and installation of head pipes. The mechanical room installation includes the installation of the circulation pump, expansion tank and the connection of the header pipes to the heat pump unit. The fittings cost includes the purchase and installation of all connectors and fittings. More details can be found in [1].
Acknowledgments The authors would like to acknowledge the support provided to this project by the Sustainable Energy Pilot Demonstration (SEPD) Program funded by the Department of Economic Development, Jobs, Transport and Resources of the Government of Victoria, the owners of the monitored GSHP systems, the Melbourne Energy Institute, and the Australian Research Council (FT140100227).
Data The datasets were acquired from the each SiMW solar cell. The repeating measurements (10 times) were performed on each solar cell to provide the accuracy of parameters. The measurement was obtained by an interval time of 1min by changing of contact position. The accuracy of data is given for the open circuit voltage () for Fig. 1, short-circuit current () for Fig. 2, fill-factor (FF) values for Fig. 3, and overall efficiency (n) values for Fig. 4. The error bars are marked in each data figure. The overall accuracy of measurement is summarized in Table 1.
Experimental design, materials and methods
Acknowledgments The authors acknowledge the financial support of the Korea Institute of Energy Technology Evaluation and Planning by the Ministry of Knowledge Economy (KETEP-20133030011000) and Basic Science Research Program through the National Research Foundation (NRF) of Korea by the Ministry of Education (NRF-2015R1D1A1A01059165).
Data The shared data describes the behavior of the LIBs (10Ah) and ultracapacitors (3000F) under the DST [1] and UDDS [2] profiles at room temperature in August, 2016 (in Appendix A.). Contents include the measured voltage, the load current (we define benthic zone the load current is negative when discharging, and positive when charging), and the sampling time. Those data can be used to analyze the dynamic behavior of the LIBs and ultracapacitors, and also can be used to predict the SOC or state-of-energy (SOE) [3].
Experimental design, materials and methods In order to test the performance and dynamic behavior of the LIBs and ultracapacitors, the Neware BTS-8000 (produced by the Shenzhen Neware Technology Co., LTD.) is used to provide programmable DC power supply and electrical load functions for charging and discharging. A personal computer is used for data record and storage. The type of the LIB we tested is IFP-1665130-10Ah (produced by Fujian Brother Electric CO., LTD of China) and the type of the ultracapacitor is BCAP3000-P270 2.7V/3.0Wh (produced by Maxwell Technologies, Inc.). The LIB pack is series connected by four batteries.