Welcome to a Laptop Battery specialist
of the Toshiba Laptop Battery First post by: www.itsbattery.com
When you shop with Udtek.com, you'll choose from brand name computers-the industry's top names-at prices simply not possible anywhere else. But that's just the beginning. We also carry a vast inventory of components: laptop batteries, ac adapters, hard drives, lcd chargers, cases and more. You'll find emerging technologies as well, because at the end of the day, we love what we sell.
As we know in any battery such as Toshiba PA2487U Battery, Toshiba PA3107U-1BRS Battery, Toshiba PA3383U-1BRS Battery, Toshiba PA3384U-1BRS Battery, Toshiba PA3285U-1BRS Battery, Toshiba PA3191U-1BRS Battery, Toshiba PA3166U-1BRS Battery, Toshiba PA3331U-1BRS Battery, Toshiba PA3098U-1BRS Battery, an electrochemical reaction occurs like the ones described on the previous page. This reaction moves electrons from one pole to the other. The actual metals and electrolytes used control the voltage of the battery - each different reaction has a characteristic voltage. For example, here's what happens in one cell of a car's lead-acid battery:
* The cell has one plate made of lead and another plate made of lead dioxide, with a strong sulfuric acid electrolyte in which the plates are immersed.
* Lead combines with SO4 (sulfate) to create PbSO4 (lead sulfate), plus one electron.
* Lead dioxide, hydrogen ions and SO4 ions, plus electrons from the lead plate, create PbSO4 and water on the lead dioxide plate.
* As the battery discharges, both plates build up PbSO4 and water builds up in the acid. The characteristic voltage is about 2 volts per cell, so by combining six cells you get a 12-volt battery.
A lead-acid battery has a nice feature - the reaction is completely reversible. If you apply current to the battery at the right voltage, lead and lead dioxide form again on the plates so you can reuse the battery over and over. In a zinc-carbon battery, there is no easy way to reverse the reaction because there is no easy way to get hydrogen gas back into the electrolyte.
Modern Battery Chemistry
Modern batteries use a variety of chemicals to power their reactions. Typical battery chemistries include:
* Zinc-carbon battery - Also known as a standard carbon battery, zinc-carbon chemistry is used in all inexpensive AA, C and D dry-cell batteries. The electrodes are zinc and carbon, with an acidic paste between them that serves as the electrolyte.
* Alkaline battery - Alkaline chemistry is used in common Duracell and Energizer batteries, the electrodes are zinc and manganese-oxide, with an alkaline electrolyte.
* Lithium-iodide battery - Lithium-iodide chemistry is used in pacemakers and hearing aides because of their long life.
* Lead-acid battery - Lead-acid chemistry is used in automobiles, the electrodes are made of lead and lead-oxide with a strong acidic electrolyte (rechargeable).
* Nickel-cadmium battery - The electrodes are nickel-hydroxide and cadmium, with potassium-hydroxide as the electrolyte (rechargeable).
* Nickel-metal hydride battery - This battery is rapidly replacing nickel-cadmium because it does not suffer from the memory effect that nickel-cadmiums do (rechargeable).
* Lithium-ion battery - With a very good power-to-weight ratio, this is often found in high-end laptop computers and cell phones (rechargeable).
* Zinc-air battery - This battery is lightweight and rechargeable.
* Zinc-mercury oxide battery - This is often used in hearing-aids.
* Silver-zinc battery - This is used in aeronautical applications because the power-to-weight ratio is good.
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