Gaines 研究表明如果锂离子电池能够有效回收利用,用于生产锂离子电池的锂需求将会减少一半。
尽管现在锂金属在自由市场很难售出,但是锂离子电池里其他金属元素,例如镍,钴,都非常珍贵,如果把锂离子电池直接送到垃圾场,就太可惜了。
Though lithium currently fetches very little on the open market, other components in lithium-ion batteries, such as nickel and cobalt, will make the batteries far too valuable to send to the landfill.
目前大多数实验性电动汽车都采用某种形式的锂离子电池,许多专家都认同,锂离子电池技术已经可以应用于第一代电动汽车上了。
Most experimental electric vehicles today use some form of Li-ion batteries and many experts agree the technology is ready for the first generation of electric vehicles.
Gaines研究表明如果锂离子电池能够有效回收利用,用于生产锂离子电池的锂需求将会减少一半。
Gaines' research found that the amount of lithium needed for some types of lithium-ion batteries could be cut in half if those batteries are effectively recycled.
说明:锂离子电池介绍,详细介绍锂离子电池应用。
Lithium-ion battery, the details on the application of lithium-ion battery.
锂离子电池能保持电量。同锂氢电池每个月损失20%的电量相比,锂离子电池组每个月仅损失5%的电量。
Theyhold their charge. A lithium-ion battery pack loses only about 5 percent of itscharge per month, compared to a 20 percent loss per month for NiMH batteries.
问题出在锂离子电池身上,它已成为便携式电子产品的标配,包括手机、平板电脑和手提电脑,因为一块小小的锂离子电池能存储大量电能。
Thee problem is lithium-ion batteries, which have become the standard for portable consumerelectronics, including phones, tablets and laptops, because of the power they can pack into asmall package.
随着锂离子电池应用范围拓宽和人们对锂离子电池高电压、高比能等性能的要求,锂离子电池的高容量和高安全受到关注。
More and more attentions are being paid on the capacity and safety of Li-ion battery for its wider use and higher performance demands.
随着锂离子电池消费量的增加,废旧锂离子电池已成为环境污染源之一,其回收利用工作逐渐引起人们的重视。
With the increase consumption in lithium ion battery, waste lithium ion battery has become one of the environmental pollution sources. People gradually attach importance to its recycle.
正极材料作为锂离子电池的重要组成部分已经成为制约其大规模推广应用的瓶颈,是进一步提高锂离子电池性能、降低成本的关键。
The anode material which is one of the important components of the lithium ion battery system is the biggest bottlenecks that restrict the popular application of lithium ion battery.
此外,还介绍了锂离子电池的工作原理,以及常见的锂离子电池电极材料的特性。
In addition, the principles of lithium ion batteries and the characteristics of cathode and anode materials were also introduced.
本课题的立意在于寻求锂离子电池电解液的低温共溶剂,并考察其对锂离子电池低温电化学性能的影响。
Searching electrolyte low temperature co-solvent and investigating the effect of it on low temperature electrochemical performance of lithium ion batteries are the intentions of this research.
依据锂离子电池的工作原理,阐述了非正常使用对锂离子电池的影响,解读了人们在使用锂离子电池时所产生的一些误区。
This paper expounds on its working principles the effects of non-normal USES of lithium batteries, and explains the areas of errors that people misuse them.
正极材料在锂离子电池成本中约占40%以上,锰酸锂被认为是目前最具发展前景的锂离子电池的正极材料。
It is a common knowledge that the anode material accounts for over 40% of the total cost of lithium battery and lithium manganate is the most promising anode material.
基于此,本文应用ANSYS分析计算了密闭电池舱段内锂离子电池组的温度场,研究了锂离子电池的发热问题。
In this paper Li-ion batteries' thermal field in confined battery module is analyzed using ANSYS, its exothermic question is researched.
从BS对锂离子电池电化学性能影响的研究表明,加入少量的BS能够显著提高锂离子电池的室温放电容量、低温及高温储存放电性能。
It was found that the discharge capacities at room temperature, low temperature and after high temperature storage were significantly improved due to the presence of BS.
华为宣布了其在锂离子电池研究方面的一个重大突破——透露全球首个能够耐高温长寿命的石墨烯锂离子电池。
Huawei announced a major breakthrough in its research into Li-ion batteries, unveiling the world's first long-lifespan graphene-assisted Li-ion battery able to withstand high temperatures.
该锂离子电池中,所述的负极为采用上述方法制备的锂离子电池负极。
In the lithium ion battery, the cathode is the lithium ion battery cathode prepared by the method.
凝胶型聚合物锂离子电池的现场聚合工艺已经成为聚合物锂离子电池领域的一个研究热点。
In-situ polymerization technology is a current research focus for gel polymer Li-ion batteries.
在锂离子电池电解液中添加4-溴苯甲醚(简称4BA)可提高锂离子电池的过充保护能力。
In order to improve the ability of overcharge protection, 4BA was added as a novel electropolymerizable additive to the electrolyte of lithium-ion batteries.
锂离子电池用高性能电极材料一直是锂离子电池开发研究的关键技术之一。
The high-performance electrode material of lithium ion battery has become one of the key technologies in the study and development of high performance lithium ion battery.
介绍了锂离子电池的结构。分析了锂离子电池中各种材料的物理化学性质。
The structure of Li-ion battery and the physical and chemical properties of every all kinds of materials in Li-ion battery are introduced.
本发明涉及一种锂离子电池负极及其制备方法以及应用该锂离子电池 负极的锂离子电池。
The invention relates to a lithium ion battery cathode, a preparation method thereof and a lithium ion battery using the lithium ion battery cathode.
本文从锂离子电池热安全性特点着手,分析了锂离子电池的着火、爆炸和电解液泄漏等安全事故特点。
From the point of lithium-ion batteries' thermal safety characteristics, its performances of fire, explosion, and electrolyte leakage are analyzed in this paper.
本发明一种快速充电方法属于电池领域,特别是涉及一种锂离子电池、聚合 物锂离子电池快速充电的方法。
The invention relates to a quick charge method, which belongs to the field of batteries, in particular to a quick charge method of lithium ion batteries and polymer lithium ion batteries.
本发明涉及锂离子电池电解液。可再充电的锂离子电池包括阳极、阴极和包含一种或多种分散的锂盐的电解液。
A rechargeable lithium-ion battery includes an anode, a cathode and an electrolyte containing one or more dispersed lithium salts.
本文主要介绍了采用UCC3975的3/4节锂离子电池充电电路和有关保护电路的工作原理和锂离子电池充电的主要特性。
This paper has mainly introduced the UCC3975s application in 3/4 cell lithium-ion batteries in charging and its protection. Also has introduced the lithium-ion cells charge property.
(与设备包装在一起的锂离子电池)。 如果包装件既含有锂金属电池,也含有锂离子电池,则包装件必须根据要求标明这两种电池类型。
Questions have been asked regarding whether to classify equipment with lithium batteries as battery-powered equipment, or only lithium batteries contained in equipment.
(与设备包装在一起的锂离子电池)。 如果包装件既含有锂金属电池,也含有锂离子电池,则包装件必须根据要求标明这两种电池类型。
Questions have been asked regarding whether to classify equipment with lithium batteries as battery-powered equipment, or only lithium batteries contained in equipment.
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