Environmental impact assessment of second life and recycling for
The result shows that the secondary application of retired LFP batteries in energy storage systems (ESSs) can effectively reduce the net environmental impact of
Environmental life cycle assessment of the production in China of
The reported GWP of 262.4 kg CO 2-eq (battery kWh) −1 was significantly higher than those of Hao et al. (2017) and Yu et al. (2018) focusing on LIB production in
Heterogeneous effects of battery storage deployment strategies
We improve a power system model, SWITCH-China, to examine three nationally uniform battery deployment strategies (Renewable-connected, Grid-connected, and Demand-side) and a heterogeneous
Investigating greenhouse gas emissions and environmental
The impact of global climate change caused by GHG emissions and environmental pollution has emerged and poses a significant threat to the sustainable development of human society (Pfeifer et al., 2020; Qerimi et al., 2020; Zhao et al., 2022).According to the International Energy Agency, global GHG emissions were as
Comparison of three typical lithium-ion batteries for pure electric
In the previous study, environmental impacts of lithium-ion batteries (LIBs) have become a concern due the large-scale production and application. The present paper aims to quantify the potential environmental impacts of LIBs in terms of life cycle assessment. Three different batteries are compared in this study: lithium iron phosphate
Life cycle assessment of a LiFePO4 cylindrical battery | Environmental
Reduction of the environmental impact, energy efficiency and optimization of material resources are basic aspects in the design and sizing of a battery. The objective of this study was to identify and characterize the environmental impact associated with the life cycle of a 7.47 Wh 18,650 cylindrical single-cell LiFePO4 battery. Life cycle
Environmental life cycle assessment of the production in China
Table 1 compares the GWP footprint (kg CO 2-eq. (battery kW h) - 1) for the battery manufacturing stage at different locations for reports that allowed the production footprint to be distinguished together with the battery mass and nominal capacity assumed in each study.The indication that despite the higher coal intensity in its electrical energy
Extended life cycle assessment reveals the spatially-explicit water
The functional unit of the Li-ion battery was chosen to ensure comparability to other electrical energy storage technologies and is the amount of usable electricity, which can be provided based on
Prospective life cycle environmental impact assessment of
According to the report from the National Energy Administration of China (NEA, 2023), China has 152 GW new installed capacity of renewable energy generation in 2022, accounting for more than 50% of the world, of which wind power and solar power accounts for 24.8% and 57.5%, respectively.
The Cobalt Supply Chain and Environmental Life Cycle Impacts of
Lithium-ion batteries (LIBs) deployed in battery energy storage systems (BESS) can reduce the carbon intensity of the electricity-generating sector and improve environmental sustainability. The aim of this study is to use life cycle assessment (LCA) modeling, using data from peer-reviewed literature and public and private sources, to
Optimization and enviro-economic assessment of hybrid
1. Introduction. With the increase of fossil energy consumption and the ensuing environmental pollution, recently, it is essential to develop renewable energy sources such as solar, biomass, wind, and hydro to replace the conventional energy sources [1, 2] cause of China''s large population and relative shortage of resources,
Environmental assessment of a new generation battery: The
However, this kind of information is scarce for emerging post-lithium systems such as the magnesium-sulfur (MgS) battery. Therefore, we use life cycle assessment following a cradle-to-gate perspective to quantify the cumulative energy demand and potential environmental impacts per Wh of the storage capacity of a
Journal of Energy Storage
In 2021, the number of new energy vehicles in China reached 7.84 million, of which 6.4 million were Further investigation into the relationship between degradation and cycle number during the energy storage battery usage phase is necessary. The three batteries exhibit a consistent trend in terms of toxic-related environmental
Comparative techno-economic evaluation of energy storage
The rated energy E R is used to represent the storage capacity of battery energy storage, while non-battery technologies assume a denominator of 1 for full charge and discharge cycles. The Levelized Cost of Storage (LCOS) represents the normalized cost, with a discount rate (r) set uniformly at 6 % based on China''s energy storage
Comparative life cycle greenhouse gas emissions assessment of battery
@article{Han2023ComparativeLC, title={Comparative life cycle greenhouse gas emissions assessment of battery energy storage technologies for grid applications}, author={Xiaoqu Han and Yanxin Li and Lu Nie and Xiaofan Huang and Yelin Deng and Jun Yan and D-S. Kourkoumpas and Sotirios Karellas}, journal={Journal of Cleaner Production}, year={2023
Life cycle environmental impact assessment for battery-powered
The battery pack of mini models running in China had the lowest value of abiotic depletion potential (ADP), while the battery pack of Japan had the highest value,
Environmental impact assessment of battery storage
The Impact 2002+, EcoPoints 97, and cumulative energy demand (CED) methods were utilized for assessing the overall impacts of the battery storage. The main contributions of this research are outlined below: . New comprehensive LCI formation for Li-ion, NaCl, and NiMH battery storage. .
Life Cycle Assessment of Lithium-ion Batteries: A Critical Review
This study assessed environmental impacts and supply risks associated with three post-LIBs, namely two sodium-ion batteries (NMMT and NTO) and one potassium-ion battery (KFSF), and three LIBs (NMC, LFP, and LTO) using life cycle assessment and criticality assessment. Post-LIBs showed comparable environmental
A comparative life cycle assessment of lithium-ion and lead-acid
An example of chemical energy storage is battery energy storage systems (BESS). Manufacture of battery cells - LFP: China: Seafreight: 9.3 × 10 −3: Peters and Weil (2018) Manufacture of battery cells – NMC: Energy and environmental assessment of a traction lithium-ion battery pack for plug-in hybrid electric vehicles.
Life cycle assessment of electric vehicles'' lithium-ion batteries
To maximize the use of batteries and reduce energy waste and environmental pollution, EoL lithium-ion batteries can be applied to scenarios with low battery energy density requirements, such as energy storage batteries. At present, renewable energy generation, such as wind power and solar power, is booming [8,9].
Energy and environmental assessment of a traction lithium-ion battery
In this study, the environmental assessment of one battery pack (with a nominal capacity of 11.4 kWh able to be used for about 140,000 km of driving) is carried out by using the Life Cycle Assessment methodology consistent with ISO 14040. A cascaded life cycle: reuse of electric vehicle lithium-ion battery packs in energy storage systems
Comprehensive energy, economic, environmental assessment of
2 Institute of Building Environment and Energy, China Academy of Building Research, Beijing 100013, Zhang S, et al. Comprehensive energy, economic, environmental assessment of a building integrated photovoltaic-thermoelectric system with battery storage for net zero energy building. Building Simulation, 2022, 15(11):
Comparative life cycle greenhouse gas emissions assessment
LCA of compressed air energy storage, pumped hydro, lead acid, sodium sulfur, lithium-ion, nickel–sodium-chloride batteries, and proton exchange membrane fuel cell
Environmental impact and economic assessment of
This paper creates a life cycle model based on the openLCA software (version1.11) ( GreenDelta, 2022) to calculate the environmental impacts and avoided
Journal of Energy Storage
In this paper, lithium nickel cobalt manganese oxide (NCM) and lithium iron phosphate (LFP) batteries, which are the most widely used in the Chinese electric vehicle market are investigated, the production, use, and recycling phases of power batteries are specifically analyzed based on life cycle assessment (LCA).
Environmental impact assessment of lithium ion battery
In this current research, cradle-to-grave analysis was conducted for an NMC 811 battery employing an open LCA tool. •. In conclusion, the findings of the study highlight several key points regarding the environmental impact and life cycle analysis of NMC811. The use stage has a significant influence on resource use (energy), with the
Comprehensive energy, economic, environmental assessment of
Request PDF | Comprehensive energy, economic, environmental assessment of a building integrated photovoltaic-thermoelectric system with battery storage for net zero energy building | To realize
Prospective life cycle environmental impact assessment of
The results indicate that the most environmentally friendly system is Case B2 which uses photovoltaic to produce hydrogen and electricity, with battery for energy storage and excess electricity sold back to grid. It shows apparently the best sustainability performance in global warming potential, which is 0.105 kg CO 2-eq per kg methanol. In
Life cycle assessment of lithium nickel cobalt
However, there are fewer basic assessment studies about the battery market, and the current study of the environmental impact of electric vehicle power batteries in China is still unclear. There is an urgent need to complete the establishment of a basic assessment system to cope with the upcoming wave of large-scale retirement of
Environmental impact assessment of battery boxes based on
This study provides environmental decision-making basis for the material selection of battery boxes and contributes to the development of lifecycle databases for
Environmental Benefit Assessment of Second-Life Use of Electric
Second-life use of electric vehicle lithium-ion batteries (LIBs) is an inevitable trend; however, battery performance degradation increases environmental loads. This study evaluated the life cycle environmental impacts of second-life use of LIBs in multiple scenarios, considering performance degradation and economic value. The results
From the Perspective of Battery Production:
Sustainability 2019, 11, 6941 2 of 12 production [6,7]. In China, great e orts are needed to reduce greenhouse gas (GHG) emissions and improve environmental impacts from battery manufacturing [8].
Study of energy storage systems and environmental challenges
Pb-A battery use is growing rapidly in China owing to different applications such as electric bicycles, automotive use, and local photovoltaic energy storage industries [161]. For the foreseeable future, China will continue to lead the world''s production, refining and use of both lead and Pb-A batteries, and contamination caused by lead and
Energy storage
Grid-scale battery storage investment has picked up in advanced economies and China, while pumped-storage hydropower investment is taking place mostly in China Global investment in battery energy storage exceeded USD 20 billion in 2022, predominantly in grid-scale deployment, which represented more than 65% of total spending in 2022.
Comparative environmental impacts of different
Life cycle assessment (LCA), a method for assessing the environmental burdens of products, processes, or activities throughout their life cycle [14], has attracted interest in the scientific community for quantitative research on the environmental impact of battery recycling. The environmental impacts of battery recycling are influenced by the
Comparative environmental life cycle assessment of conventional energy
However, the role of batteries has been widely noted in energy storage systems, with usage in multiple applications and integration within renewable technology systems [19, 20].A study conducted by Dhiman and Deb [21] shows the addition of a lithium ion based battery energy storage system to create a hybrid wind farm. The study
سابق:key support areas for energy storage
التالي:application fields of energy storage and heat storage technology
