After the introduction section, UC and battery energy storage technologies for EV and their main developing trends are described in Section "The battery and UC energy storage technologies". Ultra-capacitor/battery hybrid energy storage solutions are presented in Section "Ultra-capacitor/battery hybrid energy storage solutions". Key
Based on a review of 20 relevant life cycle assessment studies for different flow battery systems, published between 1999 and 2021, this contribution explored relevant methodological choices
This paper proposes the use of existing LCA information for established energy storage technology (i.e. capacitors and lithium-ion batteries) to derive environmentally based performance goals for future technologies. In using this approach, goals become being at least as good as, if not better, for the environment than the contemporary
We investigate the environmental impacts of on-board (based on alternating current, AC) and off-board (based on direct current, DC) charging concepts for electric vehicles using Life Cycle
The goal of this study is to assess the environmental performances of two types of aluminum electrolytic capacitors, namely "Type 1" and "Type 2". The two capacitors differ for the
Nowadays, the energy storage systems based on lithium-ion batteries, fuel cells (FCs) and super capacitors (SCs) are playing a key role in several applications such as power generation, electric vehicles, computers, house-hold, wireless charging and industrial drives systems. Moreover, lithium-ion batteries and FCs are superior in terms of high energy density
A cradle-to-gate life cycle assessment (LCA) was performed to evaluate the environmental impact of 38 types of AECs in a product family from the manufacturer''s perspective. In the study, 100,000 AECs with specific rated working voltage (among 16 V, 25 V, and 35 V) and rated capacitance (among 4.7 to 6800 μF) produced by a
The Life Cycle Assessment (LCA) methodology which allows quantification of environmental performance of products and processes based on complete product life cycle was...
Battery storage environmental assessments are critical for evaluating how these systems affect the environment throughout their life cycle. This introductory section will examine the significance of comprehending the ecological consequences of energy cell retention, particularly through battery storage environmental assessments
Download Citation | An energy conservation and environmental improvement solution-ultra-capacitor/battery hybrid power source for vehicular applications | A single power source in battery-powered
The life cycle assessment (LCA) methodology which allows quantification of environmental performance of products and processes based on complete product life cycle was utilised to evaluate the environmental burdens associated with manufacturing a 48 V lithium-ion capacitor (LIC) module. The prospective LCA compared the environmental impact of manufacturing a
Methods A cradle-to-gate life cycle assessment (LCA) was performed to evaluate the environmental impact of 38 types of AECs in a product family from the manufacturer''s perspective. In the study, 100,000 AECs with specific rated working voltage (among 16 V, 25 V, and 35 V) and rated capacitance (among 4.7 to 6800 μF) produced by a
综合考虑了电池容量和循环次数,以1 kWh能量传递为功能单元,利用CML-IA baseline方法,在全球变暖、人体毒性、酸化等8种环境影响指标上进行环境影响计算。 结果表明: (1) 磷酸铁锂
The electricity used (798,545 kWh per 100,000 capacitors) and the raw material aluminum ingots (5130 kg per 100,000 capacitors) are the environmental hotspots for high-voltage AECs'' life...
The Life Cycle Assessment (LCA) methodology which allows quantification of environmental performance of products and processes based on complete product life cycle
The electricity used (798,545 kWh per 100,000 capacitors) and the raw material aluminum ingots (5130 kg per 100,000 capacitors) are the environmental hotspots for high-voltage AECs'' life...
Battery storage environmental assessments are critical for evaluating how these systems affect the environment throughout their life cycle. This introductory section will
The life cycle assessment (LCA) methodology which allows quantification of environmental performance of products and processes based on complete product life cycle was utilised to
The life cycle assessment (LCA) methodology which allows quantification of environmental performance of products and processes based on complete product life cycle was utilised to evaluate the environmental burdens associated with manufacturing a
This paper proposes the use of existing LCA information for established energy storage technology (i.e. capacitors and lithium-ion batteries) to derive environmentally based
An environmental Life Cycle Assessment (LCA) has been conducted to analyse the environmental impact of an innovative Thermal Battery (TB) and was compared with the impact of a Lithium Iron Phosphate Battery (LIPB) using a "cradle-to-gate" approach to establish the system boundaries. The study used the findings from existing
Among Carnot batteries technologies such as compressed air energy storage (CAES) [5], Rankine or Brayton heat engines [6] and pumped thermal energy storage (PTES) [7], the liquid air energy storage (LAES) technology is nowadays gaining significant momentum in literature [8].An important benefit of LAES technology is that it uses mostly mature, easy-to
Batteries for electric vehicles (EVs) have a capacity decay issue as they age. As a result, the use of lithium-ion is becoming more popular with super-capacitors (SCs), particularly in EVs. Over the decrease of carbon dioxide emissions, SC batteries offer a substantial benefit. In EVs, a dependable mechanism that guarantees the SC batteries'' capacity for charging and
综合考虑了电池容量和循环次数,以1 kWh能量传递为功能单元,利用CML-IA baseline方法,在全球变暖、人体毒性、酸化等8种环境影响指标上进行环境影响计算。 结果表明: (1) 磷酸铁锂电池在7种指标上最优,其中,全球变暖为2.70×10 −1 kg CO 2 eq、人体毒性为1.43×10 −1 kg 1,4-DB eq、酸化为1.24×10 −3 kg SO 2 eq;环境影响潜势从低到高分别为:磷酸铁锂、二次利用磷
An environmental Life Cycle Assessment (LCA) has been conducted to analyse the environmental impact of an innovative Thermal Battery (TB) and was compared with the
A decision support tool known as the Supply Chain Environmental Assessment Tool (SCEnAT) developed by Koh et al.[89] integrates both process-LCA and EIO LCA and is employed to compute the environmental profile of the capacitors under consideration. The framework of the tool is based on five steps namely: supply chain mapping, carbon calculation
The goal of this study is to assess the environmental performances of two types of aluminum electrolytic capacitors, namely "Type 1" and "Type 2". The two capacitors differ for the electrolyte source and composition: Type 2 electrolyte
Environmental life cycle assessment of supercapacitor electrode production using algae derived biochar aerogel Zhixiang Jiang 1 · Yihui Zou 1 · Yue Li 1 · Fanlong Kong 1 · Dongjiang Yang 1
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