is there a certain chemical in there that makes it rechargeable
2007-01-23 11:38:22 · 4 answers · asked by macgyver 1 in Science & Mathematics ➔ Engineering
Nickel-iron battery is a very robust battery which is tolerant of mistreatment, (overcharge, overdischarge, short-circuiting and thermal shock) and can have very long life. It is often used in backup situations where it can be continuously charged and can last for 20 years [citation needed]. Its limitations are a low specific energy, poor charge retention, and poor low-temperature performance, and its high cost of manufacture. Its chemical composition is nickel(III) oxide-hydroxide for the cathode, iron for the anode, and potassium hydroxide for the electrolyte. This battery chemistry has been produced since 1903.
The different kinds of lead batteries:
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o Wet lead acid battery: The major advantage of this chemistry is its low cost[1] - a large battery (e.g. 70 Ah) is relatively cheap when compared to other chemistries. However, this battery chemistry has lower energy density than other battery chemistries available today. Its applications include vehicles, alarm systems, and uninterruptible power supplies. This battery chemistry was invented in 1859.
o Gel battery: A type of VRLA battery that uses gelified electrolyte. Unlike a traditional wet-cell lead-acid battery, the cells of a gel battery are valve-regulated. Its applications include automobiles, motorcycle, boats, aircraft, and other motorized vehicles.
o Absorbed glass mat: A type of VRLA battery. The plates in an AGM battery may be flat like wetcell lead-acid batteries, or they may be wound in tight spirals. In cylindrical AGM's, the plates are thin and wound, like most consumer disposable and rechargeable cells, into spirals so they are also sometimes referred to as spiral wound. Its chemical composition are electrolytes absorbed into a fiberglass mat.
Nickel cadmium battery: This chemistry gives the longest cycle life (over 1500 cycles), but has low energy density compared to some of the other chemistries. Batteries using older technology suffer from memory effect, but this has been reduced drastically in modern batteries. Cadmium is toxic to most life forms, so it poses environmental concerns. Its chemical composition is nickel for the cathode and cadmium for the anode. It is used in many domestic applications, but is being superseded by Li-ion and Ni-MH types. It has been mass produced since 1946.
Nickel metal hydride battery: Similar to a nickel-cadmium (NiCd) battery but it uses a hydride absorbing alloy for the anode; therefore, it is less detrimental to the environment. A NiMH battery can have two to three times the capacity of an equivalent size NiCd and the memory effect is not as significant. However, compared to the lithium ion chemistry, the volumetric energy density is lower and self-discharge is higher. Its chemical compostition is nickel for the cathode and a hydride absorbing alloy for the anode. Applications include hybrid vehicles such as the Toyota Prius and consumer electronics. It was made available in 1983.
Lithium ion battery: A relatively modern battery chemistry that offers a very high charge density (i.e. a light battery will store a lot of energy) and which does not suffer from any memory effect whatsoever. Its chemical composition is LiCoO2, LiMn2O4, LiNiO2 or Li-Ph for the cathode and carbon for the anode. Applications include laptops, modern camera phones, some rechargeable MP3 players, and most other portable rechargeable digital equipment. It was released c1990.
Lithium ion polymer battery: Similar characteristics to lithium-ion, but with slightly less charge density and a greater life cycle degradation rate. An advantage over regular lithium-ion is ultra-slim design (as little as 1mm thin). Applications include ultra-slim cells for PDAs. Released in 1996.
Sodium-sulfur battery: Exhibits a high energy density, high efficiency of charge/discharge (89—92%), long cycle life, and is made from inexpensive, non-toxic materials. However, the operating temperature of 300 to 350 °C and the highly corrosive nature of sodium make it suitable only for large-scale non-mobile applications. A suggested application is grid energy storage in the electric grid.
Nickel-zinc battery: A type of rechargeable battery commonly used in the light electric vehicle sector. The battery is still not commonly found in the mass market, but they are considered as the next generation batteries used for high drain applications, and is expected to replace lead-acid batteries because of their higher energy to mass ratio and higher power to mass ratio (up to 75% lighter for the same power), and are relatively cheap compared to nickel-cadmium batteries (expected to be priced somewhere in between NiCd and lead-acids, but have twice the energy storing capacity).
Molten salt battery: High temperature electric battery that offers both a higher energy density through the proper selection of reactant pairs as well as a higher power density by means of a high conductivity molten salt electrolyte. They are used in services where high energy density and high power density are required. These features make rechargeable molten salt batteries the most promising batteries for powering electric vehicles. However, operating temperatures of 400 to 700°C bring problems with thermal management and safety, and places more stringent requirements on the rest of the battery components. Its composition includes a molten salt electrolyte.
Super iron battery: A new class of rechargeable electric battery. "Super-iron" is a moniker for a special kind of ferrate salt (iron(VI)): potassium ferrate or barium ferrate, as used in this new class of batteries.[2] As of 2004, chemist Stuart Licht of the University of Massachusetts in Boston was leading research into a Super-iron battery.
Zinc bromide battery: A type of hybrid flow battery. A solution of zinc bromide is stored in two tanks. When the battery is charged or discharged the solutions (electrolytes) are pumped through a reactor and back into the tanks. One tank is used to store the electrolyte for the positive electrode reactions and the other for the negative. Its composition includes a zinc bromide electrolyte.
Rechargeable alkaline battery: A variety of alkaline battery that can be recharged. It was first released in 1993, but is now out of production in most parts of the world. It is still being sold in Canada under the brand Pure Energy.
2007-01-23 11:43:23 · answer #1 · answered by Antonio R 3 · 0⤊ 1⤋
Rechargeable batteries are rechargeable because the chemical reactions that produce electricity are reversible. Putting a load on the battery makes the chemicals generate electricity. Putting electricity in makes the chemicals change back to the way they were.
2007-01-23 17:21:11 · answer #2 · answered by Ed 6 · 0⤊ 0⤋
No matter how you rationalize it, 1.2v batteries don't work as well in the practical applications that one would normally use. The reason may be more close to the fact that battery manufacturers would prefer to sell millions of replacements rather than a battery that can be recharged 100 times on a device that may last a lifetime. james
2016-05-24 02:20:15 · answer #3 · answered by ? 4 · 0⤊ 0⤋
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2017-03-05 05:02:52 · answer #4 · answered by ? 3 · 0⤊ 0⤋