A5022671504- Advancements in Battery Materials
- Extraction and Separation Processes
- Simulation and Modeling Applications
- Inertial Sensor and Navigation
- Embedded Systems and FPGA Design
- Engineering Diagnostics and Reliability
- Advanced Battery Materials and Technologies
- Robotic Path Planning Algorithms
- Advanced Battery Technologies Research
- Analysis of environmental and stochastic processes
- Advanced Sensor and Control Systems
Nanjing University of Information Science and Technology
2024
South China Agricultural University
2011
Recovering the electrochemical performance of waste lithium iron phosphate (LiFePO4) directly under unbroken conditions has become a research topic great concern. However, there are still severe challenges for current solid-phase approach in regenerating LiFePO4 with unsatisfactory battery performance. Herein, we propose highly efficient additive polyvinylpyrrolidone (PVP) to dramatically facilitate regenerated effect by simple mechanical ball milling and calcination process. The...
Waste LiFePO4 (LFP) batteries can be harmful to the environment and lead waste of resources if not properly disposed of. In this study, an efficient environmentally friendly method for solid-phase recycling LFP cathode material (W-LFP) is proposed. Most impurities in W-LFP are removed by air firing. The regenerated then obtained adding lithium carbonate triethanolamine repair during heat treatment. addition converts Fe3+ Fe2+ also allows formation N-doped modified carbon layer on surface...
For the traditional automatic-generation algorithm of electronic chart plan shipping route, it is difficult to achieve shortest route and least turning points at same time. In this article, optimal planned method based on rubber band was put forward. algorithm, elasticity principle adopted improve original basic path can be achieved The experimental results showed that quickly automatically generate an safe with good stability high searching efficiency so applied planning in complicated...