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A nickel metal hydride battery, abbreviated NiMH, is a type of rechargeable battery similar to a nickel-cadmium (NiCd) battery but has a hydride absorbing alloy for the anode instead of cadmium, which is an environmental hazard; therefore, it is less detrimental to the environment. Like in NiCd batteries, nickel is the cathode. 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. Applications of NiMH type batteries includes hybrid vehicles such as the Toyota Prius and consumer electronics. The NiMH technology will also be used on the Alstom Citadis low floor tram ordered for Nice, France; as well as the humanoid prototype robot ASIMO designed by Honda. Standard NiMH batteries perform better with moderate drain devices such as digital cameras, flashlights, and other consumer electronics, but, because NiCd batteries have lower internal resistance, they still have the edge in very high current drain applications such as cordless power tools and RC cars.
Charging When fast-charging, it is advisable to charge the NiMH batteries with a smart battery charger to avoid overcharging, which can damage batteries and cause dangerous conditions. Modern NiMH batteries contain catalysts to immediately deal with gases developed as a result of over-charging without being harmed (2 H2 + O2 ---catalyst--> 2 H2O). However, this only works with over-charging currents of up to C/10 h (nominal capacity divided by 10 hours). As a result of this reaction, the batteries will heat up considerably, marking the end of the charging process. Some quick chargers have a fan to keep the batteries cool. Some equipment manufacturers consider that NiMH can be safely charged in simple fixed (low) current chargers with or without timers, and that permanent over-charging is permissible with currents up to C/10 h. In fact, this is what happens in cheap cordless phone base stations and the cheapest battery chargers. Although this may be safe, it may not be good for the health of the battery. According to the Panasonic NiMH charging manual (link below), permanent trickle charging (small current overcharging) can cause battery deterioration and the trickle charge rate should be limited to between 0.033×C per hour and 0.05×C per hour for a maximum of 20 hours to avoid damaging the batteries. Long-term maintenance charge of NiMH batteries needs to be by low duty cycle pulses of high current rather than continuous low current in order to preserve battery health. Brand new batteries, or batteries which have been unused for some time, need "reforming" to reach their full capacity. For this reason new batteries may need several charge/discharge cycles before they operate to their advertised capacity. Discharging Care must also be taken during discharge to ensure that one or more cells in a series-connected battery pack, like the common arrangement of four AA cells in series in a digital camera, do not become completely discharged and go into polarity reversal. Cells are never absolutely identical, and inevitably one will be completely discharged before the others. When this happens, the "good" cells will start to "drive" the discharged cell in reverse, which can cause permanent damage to that cell. Some cameras, GPS receivers and PDAs detect the safe end-of-discharge voltage of the series cells and shut themselves down, but devices like flashlights and some toys do not. Once noticeable dimming or slowing of the device is noticed, it should be turned off immediately to avoid polarity reversal. A single cell driving a load won't suffer from polarity reversal, because there are no other cells to reverse-charge it when it becomes discharged. NiMH chemistry has a somewhat higher self-discharge rate than the NiCd chemistry. The self-discharge is 5-10% on the first day, and stabilizes around 0.5-1% per day at room temperature. The rate is strongly affected by the temperature at which the batteries are stored. A new nickel metal hydride battery on the consumer market made by Sanyo, called eneloop, limits the self-discharge problem and retains energy by means of "superlattice alloy". Eneloop batteries retain 90% of their charge after six months, 85% after a year and 70% after two years. * They are estimated to last 1,000 cycles and have four times as much energy capacity as alkaline batteries. * History and other information NiMH battery technology was developed by Michigan-based Ovonic Battery, a division of ECD Ovonics (www.ovonic.com), the company co-founded in the 1950s by physicist Stanford R. Ovshinsky and his wife Iris Ovshinsky. NiMH batteries were made available to the public in 1983. Common penlight-size (AA) batteries have nominal capacities C ranging from 1100 mA·h to 2700 mA·h at 1.2 V, usually rated at 0.2×C rate. Useful discharge capacity is an inverse function of the discharge rate, but up to around 1×C rate, there is no significant difference. NiMH batteries have an alkaline electrolyte, usually potassium hydroxide. The specific energy density for NiMH material is approximately 60 W·h/kg (220 kJ/kg), with a volumetric energy density of about 100 W·h/L (360 MJ/m³). Sometimes, voltage-sensitive devices won't perform as well as the voltage is lower than disposable batteries at equivalent sizes. Even though the voltage is lower, it can be beneficial for the length of the discharge cycle. Chemistry The anode reaction occurring in a NiMH battery is as follows: H2O + Mm + 2e- ↔ OH- + 0.5H2 (stored as Mm-Hx) The battery is charged in the right direction of this equation and discharged in the left direction. Mm stands for mischmetal. One should note that the hydrogen evolved during charging is stored as Mm-Hx, the metal hydride of the battery. It is not evolved as a gas. Nickel(II) hydroxide forms the cathode. The "metal" in a NiMH battery is actually an intermetallic compound. Many different compounds have been developed for this application, but those in current use fall into two classes. The most common is AB5, where A is a rare earth mixture and/or titanium and B is nickel, cobalt, manganese, and/or aluminum. Higher-capacity "multi-component" electrodes are based on AB2 compounds, where A is titanium and/or vanadium and B is zirconium or nickel, modified with chromium, cobalt, iron, and/or manganese *. Any of these compounds serves the same role, reversibly forming a mixture of metal hydride compounds. When hydrogen ions are forced out of the potassium hydroxide electrolyte solution by the voltage applied during charging, this process prevents them from forming a gas, allowing a low pressure and volume to be maintained. As the battery is discharged, these same ions are released to participate in the reverse reaction. NiMH batteries are less prone to corrosion; therefore if you had them in a flashlight for over a year, there would be less corroded content than if you used alkaline batteries. See also | ||||||||
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