本实用新型结合了超级电容器和铅酸蓄电池两种电流载体。
This utility model combines the two kinds of current carriers: the super-capacitor and the plumbic acid battery group.
将来,超电容器将会更加强大并且能够取代越来越多的设备里的电池。
In the future, super capacitors will be more powerful and replace batteries in more and more devices.
超级电容器似乎能够兼备速度和耐久性这两个优势,这是因为和电池类似,在构造上它采的是用离子和电解液而不是简单依靠静电荷。
The reason ultracapacitors may be able to bridge the gap between speed and endurance is that, like batteries, they use ions and an electrolyte rather than simply relying on the static charges.
从广义上讲,存储电能的设备分为电池和电容器两大类。
Broadly speaking, devices for storing electricity come in two varieties: batteries and capacitors.
但是,相比电池,电容器储存的能量不足以维持任何比闪光时间长的时间,而闪光时间还不足一秒。
However, in contrast to batteries, a capacitor cannot store enough energy to power anything that lasts longer than a flash — some fraction of a second.
阿加延教授的设备之所以让人欣喜在于只要进行些许恰当的改动就能让它变成电池、电容器或两者的复合体。
The delightful thing about Dr Ajayan's device is that with suitable tweaking it can be used as a capacitor, a battery, or both.
和最耐反复充电的电池相比,超级电容器仍容易工作寿命更加长久。
And compared with most rechargeable batteries, supercapacitors tend to have a longer working life.
而且,和大部分可充电式电池相比,超级电容器有更长的工作寿命,长期来看更显优势。
And compared with most rechargeable batteries, supercapacitors tend to have a longer working life. In time that too would become a more obvious benefit.
电容器不依靠电-化学转化。相比电池,电容器能够更快的充电和放电,持续使用时间更长,并且更轻。
Without the chemical-electrical conversion, a capacitor can be charged and discharged much more rapidly than a battery, last longer and weigh less.
严格来说这种复合材料与电池并不相似,而更像是一个电容器,或者说是个超级电容器,格林浩尔博士说道。
Strictly speaking the composite behaves not like a battery but more like a capacitor, or rather a supercapacitor, says Dr Greenhalgh.
电池能够很好地储存大量电能,但传导很慢;电容器却正好相反。
Batteries are good at storing large amounts of charge but slow at delivering it; for capacitors the reverse is the case.
像电池一样,电容器能够储存能量,但是这也是电容器和电池相似的唯一地方。
Capacitors, like batteries, store energy, but that's where most of the similarities end.
这个概念是利用一个超级电容器和一个锂电池组成的复合装置来收集和储存能量。
The idea is to harvest the energy and store it using a combination of a super capacitor and a lithium battery.
由于石墨烯的这些优势,研究人员希望其可以为电池,燃料电池和电容器等许多电化学系统带来复合电极的重大进展。
With these advantages, the researchers expect the df-G to bring significant advances of composite electrodes for a variety of electrochemical system, including batteries, fuel cells, and capacitors.
这也有可能开发出5分钟就能充好电的手机电池,这种电池叫电容器。
It could also provide a cellphone battery that would charge in five minutes. That kind of battery is called a capacitor.
这个电容器可以通过被连接到电池上来充电。
This capacitor can be charged by being connected to a battery.
电池给电容器充电就像油库给油箱加油一样。
The charging of a condenser from a battery is not unlike the filling of tank from a reservoir.
事实上,XH- 150是一个三种动力装置的混合体。除了一部汽油发动机和一个普通的锂离子电池之外,它还有一个特殊的电容器。
In fact the XH-150 is a three-way hybrid, employing a petrol engine and conventional lithium-ion batteries as well as its special capacitors.
该类材料可以广泛地作为各种锂离子电池的负极材料,并可以作为电容器的电极材料。
This kind of material can be used as negative electrode material of diversified lithium ion battery widely, and as electrode material of capacitor.
利用电容器这一特性,把它和化学电池结合起来,组成了具有较高比功率的复合电源。
The composite power supply combined the capacitor with chemical battery, so it has high power density.
它具有比静电电容器大得多的能量密度,又有比二次电池大得多的功率密度。
They are also called battery capacitors, for their high energy density and high power density.
应用范围:主要应用于集成电路、继电器、接插件、锂电池、微波器件、传感器、钽电容器、压缩机接线柱等类产品中。
Application: mainly used in integrated circuit, relays, connectors, lithium batteries, microwave devices, sensors, tantalum capacitors, compressor terminals and other products.
但是,超级电容器和化学电池并不一定竞争。
But the supercapacitor and chemical battery are not necessarily in competition.
“相变储能”、“超导磁储能”、“超级电容器”、“锂离子电池”、“储能材料”等是储能技术领域的重要研究主题。
We found that phase change energy storage, superconducting magnetic energy storage, supercapacitor, lithium ion battery and energy storage materials are major research topics in this field.
这种超级电容器非常灵活,体型迷你,且能够处理1万个充电回数,比普通电池多了10倍。
The supercapacitor is flexible and tiny, and is able to handle 10,000 recharge cycles, more than normal batteries by a factor of 10.
双层电容器有希望成为新一代电池,本文介绍这种双层电容器的原理结构、性能及其应用。
It will become hopeful for a double -layer capacitor to be a new battery of the present age. This paper introduces its principle, structure and application.
讨论了凝胶电解质的特性、类型、关于其结构性能的研究方法,以及其在电双层电容器和锂离子二次电池方面的应用研究状况,并简要探讨了发展前景。
The specific properties, types, the methods in studying their structure and function and the prospect of their application in electronic double layer capacitors are discussed.
目前,人们提出的复合电源系统主要由“蓄电池+超级电容器”组成,但这种思路把两者比能量低的缺点叠加了,同时电容器的成本较高。
At present, the hybrid power generally composed by "battery + supercapacitor", but this idea overlaps the both shortcomings of low energy density, while the higher cost of the capacitor.
斯坦福大学的科学家利用在日常文件的形式纳米技术快速生产超轻量,可弯曲电池和超级电容器。
Stanford scientists are harnessing nanotechnology to quickly produce ultra-lightweight, bendable batteries and supercapacitors in the form of everyday paper.
斯坦福大学的科学家利用在日常文件的形式纳米技术快速生产超轻量,可弯曲电池和超级电容器。
Stanford scientists are harnessing nanotechnology to quickly produce ultra-lightweight, bendable batteries and supercapacitors in the form of everyday paper.
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