American Journal of Renewable and Sustainable Energy
Articles Information
American Journal of Renewable and Sustainable Energy, Vol.1, No.3, Sep. 2015, Pub. Date: Jul. 20, 2015
Proposal of Integral Mounted Solar Charging and External Solar Charging Station for an Electric Rickshaw in Delhi
Pages: 86-89 Views: 3389 Downloads: 1884
Authors
[01] Lakshey Sehgal, Madanjeet School of Green Energy Technologies, Pondicherry University, Pondicherry, India.
[02] R. Arun Prasath, Madanjeet School of Green Energy Technologies, Pondicherry University, Pondicherry, India.
[03] Arvind Rehalia, Instrumentation and control department, Bharti Vidyapeeth College of Engineering, New Delhi, India.
Abstract
The paper proposes an economic feasibility study of integral mounted solar charging and external solar charging station for an electric rickshaw which is an already developed and marketable product in metropolitan cities of India. The project reveal that the integral mount solar PV charging system is financially feasible for a place like Delhi and it can be adopted immediately for gaining benefit of extra range and added ridership. The high return on investment and small payback period make this system a highly lucrative option for the consume The off grid charging method is having a long payback period and thus should only be adopted for places where grid reliability is very low and thus it can act as a good backup system for the running of domestic appliances as well as the EV.
Keywords
Grid, Solar Energy, Renewable Energy
References
[01] A. Roy, M. (2012). Relative life cycle economic analysis of stand alone PV and fossil fuel powered system in Bangladesh with regards to load demand and market controlling factors. Renewable and Sustainable energy review.
[02] Baert, D. (1999). Lead -acid Model for Derivation of Peuket's Law. Electrochemica Acta, 1-3.
[03] Chang, H.-C.-W. &.-I. (2013). Exploration of a mobile service business model for. Journal of Industrial and Production Engineering.
[04] Doerffel, D. (2005). A critical review of using the Peukert equation for determining the remaining capacity of lead-acid and lithium-ion batteries. Journal of Power Sources.
[05] DPCC. (2014). JANUARY DATA. DELHI.
[06] Hausmann, A. (2013). Expanding the Peukert equation for battery capacity modeling through inclusion of a temperature dependency. Journal of Power Sources.
[07] Hernandez, R. (2014). Environmental impacts of utility-scale solar energy. Renewable and Sustainable Energy Reviews.
[08] J ayakrisbnan R. Pillai. (2013). Integration of Solar Photovoltaics and Electric Vehicles in Residential Grids. IEEE.
[09] Jyotirmay Mathur, N. K. (2010). Analysis of Selected Renewable. Taylor & Francis.
[10] KPMG INDIA. (2010). INDIAN AUTOMOTIVE INDUSTRY.
[11] KPMG Internatinal. (2013). Tax and incentives for renewable energy.
[12] KPMG. (2011). The Rising Sun: Projection on grid parity.
[13] Kyle D. Flyod. (2007). Assesment of lead acid batteries by monitoring float charging current. IEEE.
[14] Li, Z. (2011). The pricing of charging for electric vehicles in China—Dilemma and solution. Energy.
[15] Liu, N. (2014). Multi-objective optimization for component capacity of the photovoltaic-based battery switch stations: Towards benefits of economy and environment. Energy.
[16] Ministry of Petoleum and Natural Gas. (Decmber 2013). Indian Petroleum and Natural Gas Statistics.
[17] Ministry of Statistics and Programme Implimentation. (2013). Energy Statistics.
[18] Munkhammar, J. (2013). Quantifying self-consumption of on-site photovoltaic power generation in households with electric vehicle home charging. Solar Energy.
[19] Mwasilu, F., (2014). Electric vehicles and smart grid interaction: A review on vehicle to grid and renewable energy sources integration. Renewable and Sustainable Energy Reviews.
[20] PHD CHAMBER. (2013). A analysis of power tariff across India.
[21] Richardson, D. B. (2013). Electric vehicles and ELectric grid: A review of modelling approches,Impacts and renewable energy integration. ElLSEVIER.
[22] Schroeder, A. (2012). The economics of fast charging infrastructure for electric vehicles. Energy Policy.
[23] Siang Fui Tie, C. W. (2013). A review if Energy sources and energy management system in electric vehicles. Renewable and Sustainable Energy Reviews.
[24] Tong, S. J. (2013). Off-grid photovoltaic vehicle charge using second life lithium batteries: An experimental and numerical investigation. Applied Energy.
[25] Tulpule, P. J. (2013). Economic and environmental impacts of a PV powered workplace parking garage charging station. Applied Energy.
[26] V. Coroban, I. B. (2014). A Novel On-line State-of-Charge Estimation. IEEE.
[27] Vermaak, H. J. (2014). Design of a photovoltaic–wind charging station for small electric Tuk–tuk in D.R. Congo. Renewable Energy.
[28] W.G, C. (2000). Market prospects, design features, and performance of fuel cell powered scooter. Journal of Power.
[29] Yap, W. K. (2008). Modeling and simulation of a hybrid scooter.
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