Many fleets, both public sector and commercial, have been moving aggressively towards acquiring more hybrids. Limo operators are no exception to this trend.

One issue not fully addressed in the lifecycle analysis of electric and particularly hybrid-electric vehicles is what happens at the end of their service life.

Most vehicle batteries, in fact most batteries in general, contain highly poisonous substances that should never enter our drinking water or food chain.

So, what should be done with the batteries, and does disposal vary for different kinds of batteries?

Since the first onboard electric systems became available in the early years of the 20th century, the system's battery in automobiles were still lead-acid units. Lead and hydrochloric acid are not noted for being environmentally friendly. Nickel-cadmium batteries are even worse. New battery technology is much "greener."

Nickel-metal hydride (NiMH) is the technology of choice for the emerging hybrid-electric vehicle market. The technology is gaining acceptance for mission-critical backup power needs due to its excellent performance, high energy, reliability, low cost of ownership, and long life.

Cobasys LLC, headquartered in Orion, Mich., with manufacturing facilities in Springboro, Ohio, has been a leader in the development of NiMH batteries for automotive and other applications.

Cobasys was formed as a joint venture between Chevron and Energy Conversion Devices (ECD Ovonics) to further the development of emerging technologies and alternative-energy processes and products. The company has been working closely with major automakers to incorporate advanced energy storage systems to meet hybrid-electric vehicle requirements.

According to Cobasys, battery packs in hybrid vehicle applications must survive extremes in temperature and road vibrations and last the life of a vehicle.

NiMH batteries consist of two electrodes: the positive uses nickel-hydroxide for the cathode and the negative uses metal hydride for the anode. The electrodes are sandwiched together with a polymer separator to eliminate shorting. A small amount of water plus a potassium hydroxide mixture forms the electrolyte, which is added to the cell. The cell is sealed and charged electrically to form a 1.2v electrochemical couple. Individual cells can be connected in series to make batteries in various voltage ranges. A typical module is 12v.

Battery technologies are evaluated in terms of complete discharge cycles. A standard electric-vehicle battery can be charged and discharged 1,000 times to 80 percent depth-of-discharge (DOD), equivalent to more than 100,000 miles.

Hybrid vehicle applications use batteries differently. Generally, the battery is never fully charged or discharged in hybrid applications. NiMH batteries used in hybrid-electric vehicle applications can be cycled in shallow discharges hundreds of thousands of times and last more than 200,000 miles under a partial charge/discharge regime.

NiMH batteries are 100-percent recyclable and use no toxic materials (lead, cadmium, or lithium), making them the only rechargeable battery that can be legally disposed of in a landfill. But simply dumping them into a landfill is not economically nor environmentally sound.

So the answer is recycling. Hybrid vehicle manufacturers said they would accept the old battery and recycle it when it needed replacing.

Battery technology is advancing day by day. If you put a hybrid vehicle into service today, you probably will never have to worry about replacing the battery.

Note: This article is reprinted courtesy of Government Fleet, a Bobit Business Media publication.

Originally posted on Charged Fleet

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