Effects of environmental temperature on the thermal runaway of lithium-ion batteries during charging process

Lithium-ion batteries with relatively narrow operating temperature range have provoked concerns regarding the safety of LIBs. In this work, a series of experiments were conducted to explore the thermal runaway (TR) behaviors of charging batteries in a high/low temperature test chamber. The effects of charging rates (0.5 C, 1 C, 2 C, and 3 C), and ambient temperature (2 °C, 32 °C and 56 °C) are comprehensively investigated.The results indicate that the cell exhibited greater thermal hazard at the high charging rate and ambient temperature conditions. As the charging rate increased from 0.5 C to 3 C, more lithium intercalated in the anode prompt the TR triggered in advance, the TR onset temperature decreased from 297.5 °C to 264.7 °C. In addition, the charging time decreased with the elevated ambient temperature, resulting in a relatively higher TR onset temperature and lower maximum temperature, and the average TR critical time declined by 115–143 s. Finally, the TR required less heat accumulation with increasing of charging rate and ambient temperature, and the heat generation of side reaction played a substantial role that accounted for approximately 54%∼63%. These results provide an insight into the charging cell thermal runaway behaviors in complex operation environments and deliver valuable guidance for improving the safety of cell operation.     

Management of used lead acid battery in China: Secondary lead industry progress,policies and problems

The amount of used lead acid batteries rises along with the rapid development of battery manufacture in China. The battery manufacture and recycling industry has developed sharply in these recent 5 years. The annual production of secondary lead from used lead acid batteries in China increased rapidly to 1.5 million tonnes (MT) in 2013, making china the world's largest secondary lead producer. Secondary lead enterprises are mainly located in the middle and eastern regions of China, with a legal production capacity of 3 MT/year. Environmental pollution problems began to happen frequently from 2009. After 2011, the government began to put in efforts to promote pollution control, eliminate outdated production capacity, support advanced production and technology innovation research, and has achieved remarkable results. However, the main existing problems are that the proportion of secondary lead production is only 30% of the total lead production, no formal recycling network has been established and the overall level of industrial technology and equipment is outdated. Compared with developed countries, this paper predicts that, secondary proportion will reach 44% in 2015 and 60% in 2028. Finally some countermeasures are given to the recycling mode and technology promotion.     

江苏省铅蓄电池行业环保现状及对策

近年来铅蓄电池行业血铅污染事件引发了社会各界群众的高度关注,国家和地方也陆续颁布和实施了一系列控制重金属污染的法规政策,将铅蓄电池行业推向了改革的风口浪尖。经过几年的初步改革,虽然相关企业的环保行为有所提升,但与国家和地方的要求仍存在不小差距。以江苏省现有规模以上铅蓄电池生产企业为研究对象,深入剖析各企业在环境保护方面存在的突出问题,有针对性的提出环保发展对策,为全省乃至全国铅蓄电池行业的综合整治和产业升级指明方向,具有重要的现实意义。     

受限空间环境压力对三元锂离子电池热失控影响*

为研究三元锂离子电池在空运低压环境中的安全性,通过自主设计搭建的封闭式变压实验舱开展相关实验,对不同荷电状态（SOC）下的三元锂离子电池在不同压力环境（101,80,60,40 kPa）下的热失控特性进行研究,采集电池热失控过程中的温度以及实验舱内的压力变化,并对热失控后实验舱内的气体成分进行分析。结果表明:三元锂离子电池热稳定性随着SOC的升高而下降,常压下100%SOC的电池热失控温度可达650.8 ℃,初始环境压力越低,相同SOC的电池热失控最高温度越低。随着环境压力的降低,相同SOC的电池在热失控后会生成更多CO,且电解液占比升高。研究结果可为锂离子电池空运安全性研究提供理论依据。     

真空冶金法回收废旧锌锰电池中金属汞和镉的工艺研究

本文通过试验采用真空冶金方法处理锌锰电池,分离回收其中的金属汞(Hg)和镉(Cd),考察真空度、温度、加热时间对两种金属回收率的影响,结果表明:Hg和Cd的回收率随着真空度、加热时间及温度的升高而增加,但在加热时间和温度达到一定值时,两种金属的回收率接近饱和值,最大值接近95%;真空冶金法回收废旧锌锰电池中金属Hg和C...     

磷酸铁锂电池不同应用场景的生命周期评价

为评估磷酸铁锂(LFP)电池梯次应用的生命周期环境影响,设定直接应用和梯次应用2个应用场景,采用生命周期评价(LCA)方法,对应用场景生命周期各阶段的环境影响及其贡献进行分析.功能单位设定为应用总容量1GWh的LFP电池作为通讯基站(CBS)储能电池,循环寿命为800次.结果表明,2个应用场景的环境影响热点均为储能应用...     

国内外废旧铅酸蓄电池回收模式探讨

铅酸蓄电池由于含有大量的重金属成分,属于危险废物,如果不进行妥善处理,将对环境和人体健康产生严重威胁,但铅酸蓄电池又具有较高的回收利用价值,因此对废旧铅酸蓄电池的合理有效回收利用有着极大的必要性。比较了国内外铅酸蓄电池回收利用体制,提出我国废旧铅酸蓄电池回收行业的发展建议,为此类二次资源的合理有效利用提供借鉴。     

废旧锂离子电池资源化技术研究

通过介绍废旧锂离子电池的组成成分及近年来废旧锂离子电池资源化处理技术的研究进展,提出目前主要回收方法有溶解分离法和直接回收正极材料的新型方法等,并对现有研究中存在的二次污染、安全性问题进行了初步探讨。     

An integrated approach to the toxicity assessment of Irish marine sediments: validation of established marine bioassays for the monitoring of Irish marine sediments

This paper describes the ecotoxicological evaluation of marine sediments from three sites around Ireland representative of a range of contaminant burdens. A comprehensive assessment of potential sediment toxicity requires the consideration of multiple exposure phases. In addition to the evaluation of multi-exposure phases the use of a battery of multi-trophic test species has been advocated by a number of researchers as testing of single or few organisms may not detect toxicants with a specific mode of action. The Microtox(R) solid phase test (SPT) and the 10-d acute amphipod test with Corophium volutator were used to assess whole sediment toxicity. Porewater and elutriates were assessed with the Microtox(R) acute test, the marine prasinophyte Tetraselmis suecica, and the marine copepod Tisbe battagliai. Solvent extracts were assayed with the Microtox(R) and T. battagliai acute tests. Alexandra Basin was identified as the most toxic site according to all tests, except the Microtox(R) SPT which identified the Dunmore East site as being more toxic. However, it was not possible to correlate the observed ecotoxicological effects with a specific and/or class of contaminants based on sediment chemistry alone. Therefore porewaters found to elicit significant toxicity (Dunmore East and Alexandra Basin) with the test battery were selected for further TIE assessment with T. battalgiai and the Microtox(R) system. The results of this study have important implications for risk assessment in estuarine and coastal waters in Ireland, where, at present the monitoring of sediment and water quality is predominantly reliant on chemical analysis alone.     

Pre-feasibility study of stand-alone hybrid energy systems for applications in eco-houses

In light of rising cost of fossil fuels and fears of its depletion, coupled with the increase in energy demand and the rise in pollution levels, governments worldwide have had to look at alternative energy resources. Combining renewable energy generation like solar power with superior storage and conversion technology such as hydrogen storage, fuel cells and batteries offers a potential solution for a stand-alone power system. The aim of this paper was to assess the techno-economic feasibility of using a hybrid energy system with hydrogen fuel cell for application in an eco-house that will be built in Sultan Qaboos University, Muscat, Oman. Actual load data for a typical Omani house of a similar size as the eco-house was considered as the stand-alone load with an average energy consumption of 40 kW/day and 5 kW peak power demand. The National Renewable Energy Laboratory's Hybrid Optimisation Model for Electric Renewable software was used as a sizing and optimisation tool for the system. It was found that the total annual electrical energy production is 42,255 kW and the cost of energy for this hybrid system is 0.582 $/kW. During daylight time, when the solar radiation is high, the photovoltaics (PV) panels supplied most of the load requirements. Moreover, during the evening time the fuel cell mainly serves the house with the help of the batteries. The proposed system is capable of providing the required energy to the eco-house during the whole year using only the solar irradiance as the primary source.