Abstract
Depleting fossil fuel sources and worsening global warming are two of the most serious world problems. Many renewable energy technologies are continuously being developed to overcome these challenges. Among these technologies, high-concentration photovoltaics (HCPV) is a promising technology that reduces the use of expensive photovoltaic materials to achieve highly efficient energy conversion. This reduction process is achieved by adopting concentrating and tracking technologies. This study intends to understand and assess the carbon footprint and energy payback time (EPBT) of HCPV modules during their entire life cycles. The social benefit of carbon reduction is also evaluated as another indicator to assess the energy alternatives. An HCPV module and a tracker from the Institute of Nuclear Energy Research (INER) were applied, and SimaPro 8.0.2 was used for the assessment. The functional unit used in this study was 1 kWh, which is produced by HCPV, and inventory data was sourced from Ecoinvent 3.0 and the Taiwan carbon footprint calculation database. The carbon footprint, EPBT, and social benefit of carbon reduction were evaluated as 107.69 g CO2eq/kWh, 2.61 years, and 0.022 USD/kWh, respectively. Direct normal irradiation (DNI), life expectancy, and the degradation rate of HCPV system were subjected to sensitivity analysis. Results show that the influence of lifetime assumption under a low DNI value is greater than those under high DNI values. Degradation rate is also another important factor when assessing the carbon footprint of HCPV under a low DNI value and a long lifetime assumption. The findings of this study can provide several insights for the development of the Taiwanese solar industry.
Highlights
Energy scarcity and climate change have become critical problems worldwide in the 21st century
The total renewable energy capacity increased to 147 GW in 2015, and the solar PV capacity increased to 229 GW worldwide in the same year
Materials and Methods In this study, the carbon footprint of high-concentration photovoltaics (HCPV) systems, lifetime assumptions of, degradation rate, and the EPInBtThiosfsHtuCdyP,Vthwe ecraerbboansefodootpnritnhteogf uHiCdePlVinseysstoenmtsh, elifLeCtimAeoafsPsuVmspytsiotenms osfp, duebglirsahdeadtiobnyrIaEteA, [33]. and the energy payback time (EPBT) of HCPV were based on the guidelines on the LCA of PV systems published by IEA [33]
Summary
Energy scarcity and climate change have become critical problems worldwide in the 21st century. Energy demand is estimated to increase in the near future because of economic development. Greenhouse gas (GHG) emissions are expected to exceed the planetary capacity and lead to an unsustainable future if humans continue to rely on traditional fossil fuels [2]. China is facing an environmental crisis because of coal and other fossil fuels. Energy demand and environmental pollution have prompted the development of the PV solar-powered system in China [7]. This system has become a strategic energy source in Europe, and its contribution to the cumulative PV installation was equal to 49% in 2014 [3,8]. A large amount of energy is consumed in the manufacture of a solar-powered system, the operation of this system produces nearly zero GHG emission
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