Nickel-iron battery

From Wikipedia, the free encyclopedia

Nickel-iron battery

Energy/weight	50 Wh/kg[1]
Power/weight	100 W/kg[1]
Charge/discharge efficiency	65%[2]
Energy/consumer-price	6-7 Wh/US$[1]
Self-discharge rate	20%-40%/month[1]
Time durability	30[2] - 50 years[3][4]
Cycle durability	Repeated deep discharge does not reduce life significantly.[2]
Nominal Cell Voltage	1.2 V[1]
Charge temperature interval	min.?-max.46°C[5]

The nickel-iron battery (NiFe battery) is a storage battery having a nickel(III) oxide-hydroxide cathode and an iron anode, with an electrolyte of potassium hydroxide. The active materials are held in nickel-plated steel tubes or perforated pockets. The nominal cell voltage is 1.2V. It is a very robust battery which is tolerant of abuse, (overcharge, overdischarge, short-circuiting and thermal shock) and can have very long life even if so treated. It is often used in backup situations where it can be continuously charged and can last for more than 20 years. Its use has declined since production was halted by the destruction by fire of Edison's factory/laboratory in 1914 (13 separate "fireproof" concrete buildings)^[6], due to low specific energy, poor charge retention (similar to nickel-metal hydride), and poor low-temperature performance, and its high cost of manufacture, comparable with the best sealed lead-acid batteries and under 1/2 the cost of nickel-metal hydride batteries. ^[7].

Contents 1 Durability 2 Electrochemistry 3 History 3.1 Waldemar Jungner 3.2 Thomas Edison 4 Manufacture 4.1 Past 4.2 Present 5 Environmental impact 6 Nickel-zinc battery 7 References 8 Further reading 9 External links

[edit] Durability

The ability of these batteries to survive frequent cycling is due to the low solubility of the reactants in the electrolyte. The formation of metallic iron during charge is slow because of the low solubility of the Fe₃O₄. While the slow formation of iron crystals preserves the electrodes, it also limits the high rate performance: these cells charge slowly, and are only able to discharge slowly.

Nickel-iron batteries have long been used in European mining operations because of their ability to withstand vibrations, high temperatures and other physical stress. They are being examined again for use in wind and solar power systems and for modern electric vehicle applications.

In many respects the nickel-iron battery was almost "too good." A battery that lasts for decades in many cases can outlast the equipment that it was originally designed to power. So from an economic standpoint lead acid, nickel-cadmium and other technologies have been deemed "good enough" and are the predominant technologies in use today even though they do not last as long as a nickel-iron counterpart.

[edit] Electrochemistry

The half-cell reaction at the cathode:

and at the anode:

(Discharging is read left to right, charging is from right to left.) [1]

[edit] History

[edit] Waldemar Jungner

Swedish inventor Waldemar Jungner had invented the nickel-cadmium battery in 1899. Jungner experimented with substituting iron for the cadmium in varying proportions, including 100% iron. Jungner had already discovered that the main advantage over the nickel-cadmium chemistry was cost, but due to the poorer efficiency of the charging reaction and more pronounced formation of hydrogen (gassing), the nickel-iron technology was wanting and was abandoned. Jungner never patented the iron version of his battery.

[edit] Thomas Edison

The battery was developed by Thomas Edison in 1901, and used as the energy source for electric vehicles, such as the Detroit Electric and Baker Electric. Edison claimed the nickel-iron design to be, "far superior to batteries using lead plates and acid" (lead-acid battery). Jungner's work was largely unknown in the US until the 1940's, when nickel-cadmium batteries went into production there. A 50 volt nickel-iron battery was the main power supply in the World War II German V2 rocket (together with two 16 volt accumulators which powered the four gyroscopes), with a smaller version used in the V1 flying bomb. (viz. 1946 Operation Backfire blueprints.)

[edit] Manufacture

[edit] Past

Edison's batteries were made from about 1903 to 1972 by the Edison Battery Storage Company located in East Orange, NJ. They were quite profitable for the company. In 1972 the battery company was sold to the Exide Battery Corporation, which discontinued making the battery in 1975. Edison was disappointed that his battery was not adopted for starting internal combustion engines and that electric vehicles went out of production only a few years after his battery was introduced. He actually developed the battery to be the battery of choice for electric vehicles which were the preferred transportation mode in the early 1900's (followed by gasoline and steam). Edison's batteries had a significantly higher energy density than the lead acid batteries in use at the time, and could be charged in half the time, however they performed poorly at low ambient temperatures and were more expensive. The battery enjoyed wide use for railroad signaling, fork lift, and standby power applications.

[edit] Present

No nickel-iron batteries are being manufactured in the Western world at this time (2007), but they are still manufactured in China and Hungary. They are currently sold in the USA through Be Utility Free.

[edit] Environmental impact

Nickel-iron batteries do not have the lead or cadmium of the lead-acid and nickel-cadmium batteries, which makes them a lesser burden on human and ecological health.

[edit] Nickel-zinc battery

Main article: Nickel-zinc battery

Thomas Edison was awarded a U.S. Patent for a rechargeable Nickel Zinc battery system in 1901 (U.S. Patent 684, 204).

[edit] References

1. ^ ^{a b c d e} mpoweruk.com: Accumulator and battery comparisons (pdf)
2. ^ ^{a b c} Mpower: Nickel Iron Batteries, Axeonpower: Nickel Iron Batteries
3. ^ "Nickel Iron Battery Frequently Asked Questions" BeUtilityFree
4. ^ a description of the Chinese nickel-iron battery from BeUtilityFree
5. ^ Web archive backup: Edison Battery Booklet original instruction book for the Edison battery
6. ^ "The Life of Thomas A. Edison" http://memory.loc.gov/ammem/edhtml/edbio.html
7. ^ http://www.google.com/search?q=cache:www.knovel.com/knovel/databook/pdf/627/59788_22.pdf+%22Nickel-iron+battery%22+%2B%22energy+density%22&hl=en

[edit] Further reading

• Black, Edwin (2006). Internal Combustion : How Corporations and Governments Addicted the World to Oil and Derailed the Alternatives. St Martin's Griffin. ISBN 978-0-312-35908-9. 

[edit] External links

• Modern nickel-iron battery data

v • d • e Galvanic cells Non-rechargeable: primary cells Alkaline battery · Aluminium battery · Bunsen cell · Chromic acid cell · Clark cell · Daniell cell · Dry cell · Grove cell · Leclanché cell · Lithium battery · Mercury battery · Nickel oxyhydroxide battery · Silver-oxide battery · Weston cell · Zamboni pile · Zinc-air battery · Zinc-carbon battery Rechargeable: secondary cells Air-fueled lithium-ion battery · Lead-acid battery · Lithium-ion battery · Lithium-ion polymer battery · Lithium iron phosphate battery · Lithium sulfur battery · Lithium-titanate battery · Nickel-cadmium battery · Nickel hydrogen battery · Nickel-iron battery · Nickel-metal hydride battery · Low self-discharge NiMH battery · Nickel-zinc battery · Rechargeable alkaline battery · Sodium-sulfur battery · Vanadium redox battery · Zinc-bromine battery Kinds of cells Battery · Concentration cell · Flow battery · Fuel cell · Trough battery · Voltaic pile Parts of cells Anode · Catalyst · Cathode · Electrolyte · Half cell · Ions · Salt bridge · Semipermeable membrane