Battery – Laptop Charger, Cell Phone, Rechargeable
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From Wikipedia, the free encyclopedia
Symbols representing a single Cell (top) and Battery (bottom), used in circuit diagrams.
A Pair of AA Energizer Alkaline Cells energy Portal
A galvanic cell is a electrochemical cell that stores chemical energy and makes it available in an electrical form, and a battery is a string of two or more cells in series. Other types of electrochemical cell include electrolytic cells, fuel cells, flow cells, or voltaic cells.
Though an early form of battery may have been used in antiquity (the Baghdad Battery), the development of modern batteries started with the Voltaic pile, invented by the Italian physicist Alessandro Volta in 1800. According to a 2005 estimate, the worldwide battery industry generates US$48 billion in sales annually.
Formally, an electrical "battery" is a series-connected array of similar voltaic cells ("cells"). However, in many contexts it is common to call a single cell a battery. There is possiblity of deviation from this array, however, by use of nanograss that makes use of the hydrophobic effect of the nanograss to allow 20 year shelf lives and instant power on. The nanograss (See Bell Labs, mPhase, DARPA and U.S. Army Picatinny Test Facility reports) allows for separation of chemicals nearly indefinitly, shrinks battery size and provides near instant recharge. Added capability is the shock resistance and, with the reduced size, the certainty of a paradign shift in the design of laptop computers greatly extending battery life by virtue of multibattery designs providing multivoltages to laptops eliminating the need for power consuming voltage regulation.
The two types of batteries, primary and secondary, both convert chemical energy to electrical energy. However, primary batteries can only be used once, as they use up their chemicals in an irreversible reaction. Secondary batteries can be recharged because the chemical reactions they use are reversible; they are recharged by running a current parallel to the battery, with an orientation opposite to the original discharge.
2 How batteries work
3 Classification of batteries
4 Types of batteries
4.3 Flow batteries
4.4 Homemade cells
4.5 Battery packs
4.5.1 Traction batteries
5 Battery capacity and discharging
6 Conversion to energy
7 Effect of a battery's internal resistance
8 Battery lifetime
8.1 Life of primary batteries
8.2 Life of rechargeable batteries
8.3 Extending battery life
9 Environmental considerations
10 Battery explosion
12 See also
13 External links
Main article: History of the battery
A Voltaic Pile, the first modern battery.The earliest known artifacts that may have served as batteries are the Baghdad Batteries, which existed some time between 250 BC and 640 AD. However, it is not known what electrical function they may have served, and if they were in fact batteries at all. Scientists have developed several theories about its use, including medicine (as a painkiller) and electroplating jewelry.
The story of the modern battery begins in the 1780s with the discovery of "animal electricity" by Luigi Galvani, which he published in 1791. He created an electric circuit consisting of two different metals, with one touching a frog's leg and the other touching both the leg and the first metal, thus closing the circuit. In modern terms, the frog's leg served as both electrolyte and detector, and the metals served as electrodes. He noticed that even though the frog was dead, its legs would twitch when he touched them with the metals.
By 1791, Alessandro Volta realized that the frog could be replaced by cardboard soaked in salt water, employing another form of detection. Having already studied the electrostatic phenomenon of capacitance, Volta was able to quantitatively measure the electromotive force (emf) associated with each electrode-electrolyte interface (voltage) in volts, which were named after him. Such a device is called a voltaic cell, or cell for short. In 1799, Volta invented the modern battery by placing many galvanic cells in series, literally piling them one above the other. This Voltaic Pile gave a greatly enhanced net emf for the combination, with a voltage of about 50 volts for a 32-cell pile. In many parts of Europe batteries continue to be called piles. Unfortunately, Volta did not appreciate that the voltage was due to chemical reactions. He thought that his cells were an inexhaustible source of energy, and that the associated chemical effects (e.g., corrosion) were a mere nuisance -- rather than, as Michael Faraday showed around 1830, an unavoidable by-product of their operation.
Later, researchers placed galvanic cells in series. Such banks of cells are called batteries, presumably after the earlier use by Benjamin Franklin to describe Leyden jars (capacitors) in series and in parallel.
Although early batteries were of great value for experimental purposes, their limitations made them impractical for large current drain. Later, batteries, starting with the Daniell cell in 1836, provided more reliable currents and were adopted by industry for use in stationary devices, particularly in telegraph networks where they were the only practical source of electricity, since electrical distribution networks did not exist then. These wet cells used liquid electrolytes, which were prone to leaks and spillage if not handled correctly. Many used glass jars to hold their components, which made them fragile. These characteristics made wet cells unsuitable for portable appliances. Near the end of the 19th century, the invention of dry cell batteries, which replaced liquid electrolyte with a paste made portable electrical devices practical.
How batteries work
Main article: Electrochemical cell
One example of a galvanic cell, element of a batteryA battery is a device that converts chemical energy directly to electrical energy. It consists of one or more voltaic cells. Each voltaic cell consists of two half cells connected in series by a conductive electrolyte. Each cell has a positive electrode (cathode), and a negative electrode (anode). These do not touch each other but are immersed in a solid or liquid electrolyte. In a practical cell the materials are enclosed in a container, and a separator between the electrodes prevents the electrodes from coming into contact.
Each half cell has a net electromotive force (or emf), with the net emf of the battery being the difference between the emfs of the half-cells, a fact first recognized by Volta. Thus, if the electrodes have emfs , then the net emf is . (Hence, two identical electrodes and a common electrolyte give zero net emf.) Each half cell emf is due to a charge-transferring (or faradaic) chemical reaction at the electrode-electrolyte interface, which transfers charge across the interface. The reaction stops when the charge transfer is enough to cancel out the tendency of the reaction to occur. Non-charge-transferring, or nonfaradaic, reactions (also called parasitic or "side-reactions") can also occur at the interface. These are undesirable, using up the chemicals without producing current (which is the rate of charge transfer).
The electrical potential difference across the terminals of a battery is known as its terminal voltage, measured in volts. The terminal voltage of a battery that is neither charging nor discharging is called the open-circuit voltage, and gives the emf of the battery. The terminal voltage of a battery that is discharging is smaller in magnitude than the open-circuit voltage, and the terminal voltage of a battery being charged is greater than the open-circuit voltage. 
The voltage developed across a cell's terminals depends on the chemicals used in it and their concentrations. For example, alkaline and carbon-zinc cells both measure about 1.5 volts, due to the energy release of the associated chemical reactions. Because of the high electrochemical potential changes in the reactions of lithium compounds, lithium cells can provide as much as 3 volts or more.
Classification of batteries
Batteries are usually divided into two broad classes:
Primary batteries irreversibly transform chemical energy to electrical energy. When the initial supply of reactants is exhausted, energy cannot be readily restored to the battery by electrical means.
Secondary batteries can be recharged, that is, have their chemical reactions reversed by supplying electrical energy to the cell, restoring their original composition.
Historically, some types of primary batteries used, for example, for telegraph circuits, were restored to operation by replacing the components of the battery consumed by the chemical reaction. Secondary batteries are not indefinitely rechargeable due to dissipation of the active materials, loss of electrolyte, and internal corrosion.
Further information: List of battery sizes
Types of batteries
Various batteries (clockwise from bottom left): two 9-volt, two "AA", one "D", a handheld ham radio battery, a cordless phone battery, a camcorder battery, one "C" and two "AAA"
From top to bottom: Two button cells, a 9 volt PP3 battery, a AAA battery, a AA battery, a C battery, a D battery, a large 3R12From a user's viewpoint, at least, batteries can be generally divided into two main types: non-rechargeable (disposable) and rechargeable. Each is in wide usage.
Disposable batteries, also called primary cells, are intended to be used once and discarded. These are most commonly used in portable devices with either low current drain, only used intermittently, or used well away from an alternative power source. Primary cells were also commonly used for alarm and communication circuits where other electric power was only intermittently available. Primary cells cannot be reliably recharged, since the chemical reactions are not easily reversible and active materials may not return to their original forms. Battery manufacturers recommend against attempting to recharge primary cells, although some electronics enthusiasts claim it is possible to do so using a special type of charger.
By contrast, rechargeable batteries or secondary cells can be re-charged by applying electrical current, which reverses the chemical reactions that occur in use. Devices to supply the appropriate current are called chargers or rechargers.
The oldest form of rechargeable battery still in modern usage is the "wet cell" lead-acid battery. This battery is notable in that it contains a liquid in an unsealed container, requiring that the battery be kept upright and the area be well ventilated to ensure safe dispersal of the hydrogen gas produced by these batteries during overcharging. The lead-acid battery is also very heavy for the amount of electrical energy it can supply. Despite this, its low manufacturing cost and its high surge current levels make its use common where a large capacity (over approximately 10Ah) is required or where the weight and ease of handling are not concerns.
A common form of lead-acid battery is the modern wet-cell car battery. This can deliver about 10,000 watts of power for a short period, and has a peak current output that varies from 450 to 1100 amperes. An improved type of lead-acid battery called a gel battery (or "gel cell") has become popular in automotive industry as a replacement for the lead-acid wet cell. The gel battery contains a semi-solid electrolyte to prevent spillage, electrolyte evaporation, and out-gassing, as well as greatly improving its resistance to damage from vibration and heat. Another type of battery, the Absorbed Glass Mat (AGM) suspends the electrolyte in a special fiberglass matting to achieve similar results. More portable rechargeable batteries include several "dry cell" types, which are sealed units and are therefore useful in appliances like mobile phones and laptops. Cells of this type (in order of increasing power density and cost) include nickel-cadmium (NiCd), nickel metal hydride (NiMH), and lithium-ion (Li-Ion) cells.
Further information: List of battery sizes
Not designed to be rechargeable - sometimes called "primary cells". "Disposable" may also imply that special disposal procedures must take place for proper disposal according to regulation, depending on battery type.
Zinc-carbon battery - mid cost - used in light drain applications
Zinc-chloride battery - similar to zinc carbon but slightly longer life
Alkaline battery - alkaline/manganese "long life" batteries widely used in both light drain and heavy drain applications
Silver-oxide battery - commonly used in hearing aids, watches and calculators
Lithium Iron Disulphide battery - commonly used in digital cameras. Sometimes used in watches and computer clocks. Very long life (up to ten years in wristwatches) and capable of delivering high currents but expensive. Will operate in sub-zero temperatures.
Lithium-Thionyl Chloride battery - is used in industrial applications, including computers, electric meters and other devices which contain volatile memory circuits and act as a "carryover" voltage to maintain the memory in the event of a main power failure. Other applications include providing power for wireless gas and water meters. The cells are rated at 3.6 Volts and come in 1/2AA, AA, 2/3A, A, C, D & DD sizes. They are relatively expensive, but have a proven ten year shelf life.
Mercury battery - formerly used in digital watches, radio communications, and portable electronic instruments, manufactured only for specialist applications due to toxicity
Zinc-air battery - commonly used in hearing aids
Thermal battery - high temperature reserve. Almost exclusively military applications.
Water-activated battery - used for radiosondes and emergency applications
Nickel Oxyhydroxide battery - Ideal for applications that use bursts of high current. Better performance and cheaper in this application than Lithium Iron Disulphide.
Paper battery - In August 2007, a research team at Rensselaer (led by Drs. Robert Linhardt, Pulickel M. Ajayan, and Omkaram Nalamasu) developed a paper battery with aligned carbon nanotubes, designed to function as both a lithium-ion battery and a supercapacitor, using ionic liquid, essentially a liquid salt, as electrolyte. The sheets can be rolled, twisted, folded, or cut into numerous shapes with no loss of integrity or efficiency, or stacked, like printer paper (or a Voltaic pile), to boost total output. As well, they can be made in a variety of sizes, from postage stamp to broadsheet. Their light weight and low cost make them attractive for portable electronics, aircraft, and automobiles, while their ability to use electrolytes in blood make them potentially useful for medical devices such as pacemakers. In addition, they are biodegradable, a major drawback of chemical cells.
A rechargeable lithium polymer Nokia mobile phone battery.Main article: Rechargeable battery
Also known as secondary batteries or accumulators. The National Electrical Manufacturers Association has estimated that U.S. demand for rechargeables is growing twice as fast as demand for non-rechargeables.  There are a few main types:
Nickel-cadmium battery: Best used for motorized equipment and other high-discharge, short-term devices. NiCd batteries can withstand even more drain than NiMH; however, the mAh rating is not high enough to keep a device running for very long, and the memory effect is far more severe.
Nickel-metal hydride battery: Best used for high-tech devices. NiMH batteries can last up to four times longer than alkaline batteries because NiMH can withstand high current for a long period of time.
Flow batteries are a special class of battery where additional quantities of electrolyte are stored outside the main power cell of the battery, and circulated through it by pumps or by movement. Flow batteries can have extremely large capacities and are used in marine applications and are gaining popularity in grid energy storage applications.
Zinc-bromine and vanadium redox batteries are typical examples of commercially-available flow batteries.
Almost any liquid or moist object that has enough ions to be electrically conductive can serve as the electrolyte for a cell. As a novelty or science demonstration, it is possible to insert two electrodes made of different metals into a lemon, potato, et cetera and generate small amounts of electricity. "Two-potato clocks" are also widely available in hobby and toy stores; they consist of a pair of cells, each consisting of a potato (lemon, et cetera) with two electrodes inserted into it, wired in series to form a battery with enough voltage to power a digital clock. Homemade cells of this kind are of no real practical use, because they produce far less current—and cost far more per unit of energy generated—than commercial cells, due to the need for frequent replacement of the fruit or vegetable. In addition, one can make a voltaic pile from two coins (such as a nickel and a penny) and a piece of paper towel dipped in salt water. Such a pile would make very little voltage itself, but when many of them are stacked together in series, they can replace normal batteries for a short amount of time.
Sony has developed a biologically friendly battery that generates electricity from sugar in a way that's similar to what's found in living organisms. The battery generates electricity through the use of enzymes that break down carbohydrates, which is essentially sugar.
Lead acid cells can easily be manufactured at home, but a tedious charge/discharge cycle is needed to 'form' the plates. This is a process whereby lead sulfate forms on the plates, and during charge is converted to lead dioxide (positive plate) and pure lead (negative plate). Repeating this process results in a microscopically rough surface, with far greater surface area being exposed. This increases the current the cell can deliver. For an example, see .
Main article: Battery pack
The cells in a battery can be connected in parallel, series, or in both. A parallel combination of cells has the same voltage as a single cell, but can supply a higher current (the sum of the currents from all the cells). A series combination has the same current rating as a single cell but its voltage is the sum of the voltages of all the cells. Most practical electrochemical batteries, such as 9 volt flashlight (torch) batteries and 12 V automobile (car) batteries, have several cells connected in series inside the casing. Parallel arrangements suffer from the problem that, if one cell discharges faster than its neighbour, current will flow from the full cell to the empty cell, wasting power and possibly causing overheating. Even worse, if one cell becomes short-circuited due to an internal fault, its neighbour will be forced to discharge its maximum current into the faulty cell, leading to overheating and possibly explosion. Cells in parallel are therefore usually fitted with an electronic circuit to protect them against these problems. In both series and parallel types, the energy stored in the battery is equal to the sum of the energies stored in all the cells.
Main article: Traction battery
Traction batteries are high-power batteries designed to provide propulsion to move a vehicle, such as an electric car or tow motor. A major design consideration is power to weight ratio since the vehicle must carry the battery. While conventional lead acid batteries with liquid electrolyte have been used, gelled electrolyte and AGM-type can also be used, especially in smaller sizes.
The largest installations of batteries for propulsion of vehicles are found in submarines, although the toxic gas produced by seawater contact with acid electrolyte is a considerable hazard.
Battery types commercially used in electric vehicles include:
flooded type with liquid electrolyte.
AGM-type (Absorbed Glass Mat)
Zebra Na/NiCl2 battery operating at 270 °C requiring cooling in case of temperature excursions
NiZn battery (higher cell voltage 1.6 V and thus 25% increased specific energy, very short lifespan)
See also: battery electric vehicles and hydrogen vehicle.
Battery capacity and discharging
The more electrolyte and electrode material there is in the cell, the greater the capacity of the cell. Thus a small cell has less capacity than a larger cell, given the same chemistry (e.g. alkaline cells), though they develop the same open-circuit voltage.
Because of the chemical reactions within the cells, the capacity of a battery depends on the discharge conditions such as the magnitude of the current, the duration of the current, the allowable terminal voltage of the battery, temperature, and other factors.
The available capacity of a battery depends upon the rate at which it is discharged. If a battery is discharged at a relatively high rate, the available capacity will be lower than expected. Therefore, a battery rated at 100 A·h will deliver 5 A over a 20 hour period, but if it is instead discharged at 50 A, it will run out of charge before the theoretically expected 2 hours. For this reason, a battery capacity rating is always related to an expected discharge duration, such as 15 minutes, 8 hours, 20 hours or others.
The relationship between current, discharge time, and capacity for a lead acid battery is expressed by Peukert's law. The efficiency of a battery is different at different discharge rates. When discharging at low rate, the battery's energy is delivered more efficiently than at higher discharge rates.
Battery manufacturers use a standard method to rate their batteries. The battery is discharged at a constant rate of current over a fixed period of time, such as 10 hours or 20 hours, down to a predetermined terminal voltage per cell. So a 100 ampere-hour battery is rated to provide 5 A for 20 hours at room temperature. Ampere-hours are commonly called amp-hours.
In general, the higher the ampere-hour rating, the longer the battery will last for a certain load. Installing batteries with different A·h ratings will not affect the operation of a device rated for a specific voltage.
Typical alkaline battery sizes and capacities (at lowest discharge rates) Diagram Size Capacity (mAh) Voltage ANSI/NEDA IEC Diam. (mm) Weight (g) Height (mm) Length (mm) Width (mm)
AAAA 625 1.5 25A LR8D425 8.3 6.5 42.5 cylindrical cylindrical
N 1000 1.5 910A LR1 12 9 30.2 cylindrical cylindrical
AAA 1250 1.5 24A LR03 10.5 11.5 44.5 cylindrical cylindrical
AA 2850 1.5 15A LR6 14.5 23 50.5 cylindrical cylindrical
J 625 6 1412A 4LR61 prismatic 30 48.5 35.6 9.18
9V 625 9 1604A 6LR61 prismatic 45.6 48.5 26.5 17.5
C 8350 1.5 14A LR14 26.2 66.2 50 cylindrical cylindrical
D 20500 1.5 13A LR20 34.2 148 61.5 cylindrical cylindrical
Lantern 26000 6 915A 4R25Y prismatic 885 112 68.2 68.2
Lantern 26000 6 908A 4LR25X prismatic 885 115 68.2 68.2
Lantern 52000 6 918A 4LR25-2 prismatic 1900 127 136.5 73
Conversion to energy
The ampere-hour (A·h) rating of a battery is related to the amount of energy it stores when fully charged. If two batteries have the same nominal voltage, then the one with the higher A·h rating stores more energy. It also typically takes longer to recharge. Accurate calculation of the energy stored in the battery is complex due to the varying terminal voltage during discharge (and so the need to specify an end terminal voltage for discharge), and due to the dependency of total capacity on the discharge rate and discharge duty.
Secondary batteries always yield less energy than was used to charge them, since (among other reasons) the terminal voltage during charging is higher than during discharging. The nickel cadmium and nickel metal-hydride designs have efficiencies of around 66%. However, modern lithium designs have almost negated this wastage as they can have efficiencies of around 99%.
Effect of a battery's internal resistance
A battery can be simply modeled as a perfect voltage source (i.e. one with zero internal resistance) in series with a resistor. The voltage source depends mainly on the chemistry of the battery, not on whether it is empty or full. When a battery runs down, its internal resistance increases. When the battery is connected to a load (e.g. a light bulb), which has its own resistance, the resulting voltage across the load depends on the ratio of the battery's internal resistance to the resistance of the load. When the battery is fresh, its internal resistance is low, so the voltage across the load is almost equal to that of the battery's internal voltage source. As the battery runs down and its internal resistance increases, the voltage drop across its internal resistance increases, so the voltage at its terminals decreases, and the battery's ability to deliver power to the load decreases.
The formula for calculating the voltage Vt at the terminals of a battery is:
Voc is the open-circuit voltage of the battery
Ri is the battery's internal resistance
I is the current flowing through the battery
This can be rearranged to calculate the internal resistance given the other quantities:
Life of primary batteries
Even if never taken out of the original package, disposable (or "primary") batteries can lose two to twenty-five percent of their original charge every year. This is known as the "self discharge" rate and is due to non-current-producing "side" chemical reactions, which occur within the cell even if no load is applied to it. The rate of the side reactions is reduced if the batteries are stored at low temperature, although some batteries can be damaged by freezing. High or low temperatures may reduce battery performance. This will affect the initial voltage of the battery. For a AA alkaline battery this initial voltage is approximately normally distributed around 1.6 volts.
Life of rechargeable batteries
Rechargeable batteries traditionally self-discharge more rapidly than disposable alkaline batteries; up to three percent a day (depending on temperature). However, modern Lithium designs have reduced the self discharge to a relatively low level (but still poorer than for primary batteries). Due to their poor shelf life, rechargeable batteries should not be stored and then relied upon to power flashlights or radios in an emergency. For this reason, it is a good idea to keep alkaline batteries on hand. NiCd Batteries are almost always "dead" when purchased, and must be charged before first use.
Although rechargeable batteries may be refreshed by charging, they still suffer degradation through usage. Low-capacity Nickel Metal Hydride (NiMH) batteries (1700-2000 mAh) can be charged for about 1000 cycles, whereas high capacity NiMH batteries (above 2500 mAh) can be charged for about 500 cycles. Nickel Cadmium (NiCd) batteries tend to be rated for 1,000 cycles before their internal resistance increases beyond usable values. Normally a fast charge, rather than a slow overnight charge, will result in a shorter battery lifespan. However, if the overnight charger is not "smart" (i.e. it cannot detect when the battery is fully charged), then overcharging is likely, which will damage the battery. Degradation usually occurs because electrolyte migrates away from the electrodes or because active material falls off the electrodes. NiCd batteries suffer the drawback that they should be fully discharged before recharge. Without full discharge, crystals may build up on the electrodes, thus decreasing the active surface area and increasing internal resistance. This decreases battery capacity and causes the dreaded "memory effect". These electrode crystals can also penetrate the electrolyte separator, thereby causing shorts. NiMH, although similar in chemistry, does not suffer from ‘memory effect’ to quite this extent.
Automotive lead-acid rechargeable batteries have a much harder life. Because of vibration, shock, heat, cold, and sulfation of their lead plates, few automotive batteries last beyond six years of regular use. Automotive starting batteries have many thin plates to provide as much current as possible in a reasonably small package. Typically they are only drained a small amount before recharge. Care should be taken to avoid deep discharging a starting battery, since each charge and discharge cycle causes active material to be shed from the plates. Hole formation in the plates leads to less surface area for the current-producing chemical reactions, resulting in less available current when under load. Leaving a lead-acid battery in a deeply discharged state for any significant length of time allows the lead sulfate to crystallize, making it difficult or impossible to remove during the charging process. This can result in a permanent reduction in the available plate surface, and therefore reduced current output and energy capacity.
"Deep-Cycle" lead-acid batteries such as those used in electric golf carts have much thicker plates to aid their longevity. The main benefit of the lead-acid battery is its low cost; the main drawbacks are its large size and weight for a given capacity and voltage. Lead-acid batteries should never be discharged to below 20% of their full capacity, because internal resistance will cause heat and damage when they are recharged. Deep-cycle lead-acid systems often use a low-charge warning light or a low-charge power cut-off switch to prevent the type of damage that will shorten the battery's life.
Special "reserve" batteries intended for long storage in emergency equipment or munitions keep the electrolyte of the battery separate from the plates until the battery is activated, allowing the cells to be filled with the electrolyte. Shelf times for such batteries can be years or decades. However, their construction is more expensive than more common forms.
Extending battery life
Battery life can be extended by storing the batteries at a low temperature, as in a refrigerator or freezer, because the chemical reactions in the batteries are slower. Such storage can extend the life of alkaline batteries by ~5%; while the charge of rechargeable batteries can be extended from a few days up to several months. In order to reach their full power, batteries must be returned to room temperature; therefore, alkaline battery manufacturers like Duracell do not recommend refrigerating or freezing batteries.
Since their development over 250 years ago, batteries have remained among the most expensive energy sources, and their manufacturing consumes many valuable resources and often involves hazardous chemicals. For this reason many areas now have battery recycling services available to recover some of the more toxic (and sometimes valuable) materials from used batteries. Batteries may be harmful or fatal if swallowed. It is also important to prevent dangerous elements found in some batteries, such as lead, mercury, cadmium, from entering the environment.
A battery explosion is caused by the misuse or malfunction of a battery, such as attempting to recharge a primary (non-rechargeable) battery, or short circuiting a battery. With car batteries, explosions are most likely to occur when a short circuit generates very large currents. In addition, car batteries liberate hydrogen when they are overcharged (because of electrolysis of the water in the electrolyte). Normally the amount of overcharging is very small, as is the amount of explosive gas developed, and the gas dissipates quickly. However, when "jumping" a car battery, the high current can cause the rapid release of large volumes of hydrogen, which can be ignited by a nearby spark (for example, when removing the jumper cables).
When a battery is recharged at an excessive rate, an explosive gas mixture of hydrogen and oxygen may be produced faster than it can escape from within the walls of the battery, leading to pressure build-up and the possibility of the battery case bursting. In extreme cases, the battery acid may spray violently from the casing of the battery and cause injury.
Battery explosions can also occur in maintenance free lead-acid batteries if the valves fail by being blocked, for example. The pressure rises within the cells until a short-circuit ignites the hydrogen-oxygen mixture. Such explosions can cause severe personal injury. The problem can be detected in Car batteries if the sides appear at all swollen.
Additionally, disposing of a battery in fire may cause an explosion as steam builds up within the sealed case of the battery.
Overcharging — that is, attempting to charge a battery beyond its electrical capacity — can also lead to a battery explosion, leakage, or irreversible damage to the battery. It may also cause damage to the charger or device in which the overcharged battery is later used.
Some common battery-related terms:
C: nominal capacity, in Ah (or submultiplier mAh) for a given voltage.
W: watt, unit of power. One watt equals one joule per second.
W/kg: watts per kilogram, unit of power per mass.
W/l: watts per liter, unit of power density.
W•h: watt-hour, unit of energy, or work. 1 watt expended continuously for 1 hour equals 1 watt-hour.
W•h/kg: watt-hours per kilogram, unit of energy per mass.
W•h/l: watt-hours per litre, unit of energy density.
W•h/lb: watt-hours per pound, unit of energy per mass.
List of battery types
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