NE 1396029G
Assessments
Alternative power supplies
Increasing reliance on batteries
Solar cells Batteries Inverter
Wind Turbine
Diesel Generator
Low Voltage
Why Study Cells & Why Study Cells & BatteriesBatteries
Alternative power supplies
Increasing reliance on batteries
Cordless Drills Hybrid cars Supply back-up
Why Study Cells & Why Study Cells & BatteriesBatteries
Can the batteries be fully discharged? Can the battery be left flat? Can you use a car battery for a solar power system?
Electrical current causing chemical change Electro-plating (electro-deposition)
Splitting water into Hydrogen & Oxygen
Lightning thought to have made the basic building blocks of life on earth.
Used to stop corrosion (Cathodic protection)
Refining of metals (Copper)
CHARGING OF BATTERIESCHARGING OF BATTERIES
Chemical Effect of Chemical Effect of CurrentCurrent
BACKGROUNDBACKGROUNDPeriodic Table Page
437Every element has a symbolLead=
Sulphur =Oxygen =
Hydrogen =
PbSOH
When “Compounds” are made the elements symbols are grouped together
Water=
H2O
Hydrogen Oxygenx2
BACKGROUNDBACKGROUNDWhen compounds are made the electrons
may be liberated creating:
Positive Ions Compounds lacking electrons
Free Electrons
Negative Ions Compounds with excessive electrons
BACKGROUNDBACKGROUNDProcesses that produce electric charge from a
chemical reaction are:
Fuel Cells
Developed to a usable form by NASA for Mercury, Apollo, and Skylab missions
Batteries
Fuel cell acts as a “combustion” chamber. Converting high energy fuel ( Hydrogen) with Oxygen to electric current.
Cells connected together
FUEL CELLSFUEL CELLS
HYDROGEN
OXYGEN ELECTRIC CURRENT
WATER
HEAT
Efficiency 45%
Can be any fuel(gas) provided the electrode and membrane are correctly chosen
Electrolyte
ELECTRIC CELLSELECTRIC CELLS
Anode
Cathode
An electric cell contains three parts, namely:Acid
Alkali (Base)Salt
Positive electrode or PlateNegative electrode or Plate
Discharging
Known as a Voltaic Cell
Electrolyte
ELECTRIC CELLSELECTRIC CELLS
Anode
Cathode
An electric cell contains three parts, namely:Acid
Alkali (Base)Salt
Positive electrode or PlateNegative electrode or Plate
Charging
Known as a Electrolytic Cell
ELECTRIC CELLSELECTRIC CELLS
-
--
++
+
Cathode
Electrolyte
Anode
ELECTRIC CELLSELECTRIC CELLSChemical reaction between two electrodes and the
electrolyte they are in contact with
Primary Cell
Secondary Cell
Chemical reaction is irreversible One electrode is “eaten” away When cell is constructed, all cell’s energy is
present
Chemical reaction is reversible Chemical change does not destroy electrode Once made, has to be charged
1737 - 1798
LUIGI GALVANILUIGI GALVANI
PRIMARY CELLSPRIMARY CELLS
Luigi Galvani discovered that when two different metals were connected together and then both touched to different parts of a nerve of a frog leg at the same time, they made the leg contract. He called this "animal electricity".
1780
ALESSANDRO GIUSEPPE ANTONIO ANASTASIO VOLTA
1745 - 1827
PRIMARY CELLSPRIMARY CELLS1800Voltaic Pile (Copper, Zinc, Sulphuric acid
PRIMARY CELLSPRIMARY CELLSCell
Voltage:Dependant on electrode typeSee Table 3.1 Page62
What voltage will the cell’s voltage be if Copper & Zinc is
used?Zinc = -0.76 V Copper = +0.34 V
1.1 V(-0.76)Voltage difference =
+0.34 - =
Copper electrode = Positive terminal
PRIMARY CELLSPRIMARY CELLSCell
Voltage:Dependant on electrode typeSee Table 3.1 Page62
What voltage will the cell’s voltage be if Gold & Aluminium is
used?Aluminium = -1.76 V Gold = +1.42 V
3.18 V(-1.76)Voltage difference =
+1.42 - =
Gold electrode = Positive terminal
PRIMARY CELLSPRIMARY CELLSCell
Voltage:Dependant on electrode typeSee Table 3.1 Page62
Cell Current:Dependant surface area of electrode
(Plate)
ZINC COPPER CELLZINC COPPER CELL
H+
Cl-
Hydrochloric Acid
HCl
HCl
ZnCl
Cl-
H+
HZn++
++ -
-
ZincCopper
ZINC COPPER CELLZINC COPPER CELLProblems with this type of cell
Hydrogen gas bubbles stick to the copper electrodeReduces surface area of electrodeEffect known as “Polarisation”Chemicals (Depolarisers) are added to reduce this effect
ZINC COPPER CELLZINC COPPER CELLProblems with this type of cellAny impurities in Zinc electrode will act as a small cell and eat the electrode away even if the cell is not connected
Effect known as “Local Action”Causes the cell to go flat or have a “shelf life”
1790 - 1845
JOHN FREDERIC JOHN FREDERIC DANIELDANIEL
THE DANIELL CELLTHE DANIELL CELL
Used second electrolyte to consume the hydrogen
First attempt to remove the problem of Polarisation
1836
1839 - 1882
GEORGES LECLANCHEGEORGES LECLANCHE
THE LECLANCHE CELLTHE LECLANCHE CELL
Positive electrode =
1866
Carbon
Negative electrode =
Zn(s) + 2 MnO2(s) + 2 NH4Cl(aq) → ZnCl2 + Mn2O3(s) + 2 NH3(aq) + H2O
Zinc
Electrolyte = Ammonium Chloride
Depolariser = Manganese Dioxide
THE ZINC CARBON THE ZINC CARBON CELLCELL1866
THE ZINC CARBON THE ZINC CARBON CELLCELL
Positive electrode =
1866
CarbonNegative electrode
=Zinc
Electrolyte = Ammonium ChlorideDepolariser =Manganese Oxide
Zn(s) + 2MnO2(s) + 2NH4+(aq) → Mn2O3(s) + Zn(NH3)2
2+(aq) + H2O(l)
THE ZINC CHLORIDE THE ZINC CHLORIDE CELLCELL
Zn(s) + 2 MnO2(s) + ZnCl2(aq) + 2 H2O(l) → 2 MnO(OH)(s) + 2 Zn(OH)Cl(aq)
Electrolyte = Zinc Chloride
Alkaline Cells Alkaline watch batteries are primarily used where cost is a factor. Construction is similar to Lithium cells. Voltage rated at 1.5 volts. Next time you find a free watch in your pack of breakfast cereal, chances are it will be powered by a Zinc Alkaline cell. Advantages
Cheap to make. Environmentally safe. Good for low and intermittent high drain applications. Will keep that el-cheapo quartz watch going for months!
Disadvantages
Only about half the capacity of a silver oxide cell. Voltage not very constant during its life. Relatively short shelf life, similar to carbon zinc cells in its characteristics, but with about double the stored energy capacity.
Uses
Suitable for applications where a cheap alternative is required. Wouldn't risk putting one in my Accutron even if I could find one to fit.
THE ALKALINE CELLTHE ALKALINE CELL
A) Cell top (-ve electrode)B) Anode of Zinc + Electrolyte gelC) Nylon sealD) Electrolyte in Separator, Anode and Cathode Material.E) Cathode of Manganese DioxideF) Absorbent separators containing electrolyteG) Cell Can (+ve electrode)
Cathode is a mixture of high purity electrolytic manganese dioxide and carbon conductor.Anode is a gelled mixture of zinc powder and electrolyte.Separators of specially selected materials prevent migration of any solid particles in thebattery.Steel can confines active materials and serves as the cathode collector.Brass collector serves as the anode collector.Positive and negative covers provide contact surfaces of nickel-plated steel.Non-conductive plastic film label electrically insulates the battery.Nylon seal provides a safety venting mechanism
Cylindrical alkaline batteries are produced with a high surface area zinc anode, a high densitymanganese dioxide cathode, and a potassium hydroxide electrolyte. A cutaway (fig. 4) of a typicalcylindrical alkaline battery is illustrated in the following diagram:
Mercury batteries have been the mainstay of watch batteries for almost 50 years. These cells are rated at 1.36 volts. Due to increasing concerns over waste mercury finding its way into our food, the manufacturing of these batteries has virtually stopped.Advantages
Extremely constant voltage over its useful life. Suitable for low drain and intermittent high drain applications. Long shelf life - up to 3 years.
Disadvantages
Contains mercury, which in certain forms is highly toxic to humans and animals.
Uses
Excellent for Accutrons, as they were designed originally to operate with these cells. Were used in nearly all applications requiring small constant voltage cells, ie, watches, hearing aids, portable scientific instruments etc.
THE MERCURY CELLTHE MERCURY CELL
A) Cell top (-ve electrode)B) Anode of powdered zinc + electrolyte gelC) Nylon sealD) ElectrolyteE) Cathode of Mercuric Oxide and GraphiteF) Absorbent separator of fabric and electrolyteG) Barrier separator membrane.H) Cell Can (+ve electrode)I) Metal sleeve to support the nylon case seal
The silver oxide/zinc alkaline primary battery is the predominate system of the miniature battery productline. It typically can be used in watches, calculators, photoelectric exposure devices, hearing aids, andelectronic instruments. Its general characteristics include:Higher voltage than comparable mercury batteriesFlatter discharge curve than alkaline manganese dioxide batteriesGood low temperature characteristicsGood resistance to shock, vibration, and accelerationLow and essentially constant internal resistanceExcellent service maintenance; in excess of 90% after storage at 21°C(70°F) for five yearsAvailable in voltages ranging from 1.5 to 6.0 volts and a variety of sizes.
Cathodes are a mixture of Ag2O and conductor.Anodes are a gelled mixture of amalgamated zinc powder and electrolyte.Separators of specially selected materials prevent migration of any solid particles in the battery.Insulating and sealing gaskets are moulded of nylon.Exterior battery surfaces of nickel are used to resist corrosion and to insure good electrical contact.
Silver oxide batteries contain a cathode of silver oxide with a low percentage of manganese dioxide andgraphite, an anode of high surface area zinc, and a highly alkaline electrolyte consisting of either sodiumhydroxide or potassium hydroxide. The open circuit voltage of silver oxide batteries is 1.6 volts. Theoperating voltage at typical current drains is 1.55 volts or more. Silver oxide batteries offer a higher flatoperating voltage characteristic than mercuric oxide batteries as illustrated in the following diagram:
The type of electrolyte used with silver oxide batteries determines their rate or current carrying capability.Under heavy drains, potassium hydroxide (KOH) electrolyte offers less resistance to the current flow andallows the battery to operate at higher efficiency than a sodium hydroxide (NaOH) electrolyte. At lowdrains both electrolytes operate with equal efficiency. This relationship is shown in the followingdiagram:
THE SILVER OXIDE THE SILVER OXIDE CELLCELL
A silver oxide battery (IEC code: S), also known as a silver–zinc battery, is a primary cell (although it may be used as a secondary cell with an open circuit potential of 1.86 volts). Silver oxide batteries have a long life and very high energy/weight ratio, but a prohibitive cost for most applications due to the high price of silver. They are available in either very small sizes as button cells where the amount of silver used is small and not a significant contributor to the overall product costs, or in large custom design batteries where the superior performance characteristics of the silver oxide chemistry outweigh cost considerations. The large cells found some applications with the military, for example in Mark 37 torpedoes or on Alfa class submarines
Silver oxide batteries containing a KOH electrolyte are more difficult to seal than those containing atNaOH electrolyte. As a result, NaOH batteries are typically more salt resistant than similar sized KOHbatteries. Both batteries however, exhibit excellent long term salt resistance.Temperature:Silver oxide batteries have good performance characteristics at temperature extremes. They can beused up to 55°C(131°F). Silver oxide batteries utilizing KOH as an electrolyte will operate with less lossof efficiency at lower temperatures than comparable NaOH batteries. Batteries with KOH electrolyte willoperate down to -28°C (-20°F) and NaOH batteries down to -10°C(14°F) with some service reduction inboth types.
Applications:Eveready silver oxide batteries are specially designed to meet the varying power requirements of a widevariety of applications.Watch and Calculator - Silver oxide watch batteries using a sodium hydroxide (NaOH) electrolytesystem are primarily designed for low drain continuous use over long periods of time, typically up to fiveyears. This is commonly found in analog watch applications.Silver oxide watch batteries using a potassium hydroxide (KOH) electrolyte system are principallydesigned for continuous low drains with periodic high drain pulse demands for periods of approximatelyone to two years. This is typical of applications such as LCD watches with backlight, analog watches withalarms and calculators.Hearing Aid and Electronic - Silver oxide hearing aid and electronic batteries are designed toproduce greater volumetric energy density at higher continuous discharge rates than silver oxide watch orphotographic batteries. Hearing aid and electronic batteries use potassium hydroxide electrolyte incombination with the separator system designed to match the required application.Photographic - Silver oxide photo batteries are designed to provide constant voltage or periodichigh drain pulses with or without a low drain background current.
It provides up to 40 percent more run time than lithium-ion batteries and also feature a water-based chemistry that is free from the thermal runaway and flammability problems that have plagued the lithium-ion alternatives
This once attractive technology had the highest energy density (prior to lithium technologies), and was primarily developed for aircraft use. The worldwide rise in silver prices seemed to spell its demise. It was the power source in all of the Apollo spacecraft: the command module re-entry batteries, the lunar module and the lunar rover. (The Apollo Service Module used fuel cells as a primary power source.)More recently, the company ZPower has introduced a new line of rechargeable silver-zinc batteries to compete with lithium-ion batteries. The claims include an energy density of 200Wh/kg, complete non-flammability, and no toxic chemicals. To offset the high price of silver, the company plans to offer a trade-in policy to recycle all of it.[2][3] Intel's venture arm, Intel Capital, has provided the company with financial backing.[4] ZPower claims that an undisclosed "major manufacturer" of laptop computers will introduce its silver-zinc battery in a new line of laptops in 2009.
Silver Oxide Cells The silver oxide cell is really the ideal successor to mercury batteries, and is superior in a number of ways. It has a higher capacity than mercury cells for a given size. These cells are rated at 1.62 volts. Their construction is very similar to mercury cells, the cathode material being the main difference.Advantages
Constant voltage over its useful life. Contains no chemicals harmful to the environment. Basically superior in all ways over mercury cells.
Disadvantages
About half the shelf life of mercury cells.
Uses
Main applications are in watches. Great for Accutrons, which will perform equally well with these cells as mercury cells.
A) Cell top (-ve electrode)B) Anode of powdered zinc + electrolyte gelC) Nylon sealD) ElectrolyteE) Cathode of Silver Oxide and GraphiteF) Absorbent separator of fabric and electrolyteG) Barrier separator membrane.H) Cell Can (+ve electrode)I) Metal sleeve to support the nylon case seal
THE LITHIUM CELLTHE LITHIUM CELLLithium Cells Lithium cells are often called "coin cells" due to their shape. The lithium cells used in watches are Lithium-Manganese Dioxide, and are rated at 3.0 volts. The other type of lithium cells commonly seen are Lithium-Thionyl Chloride, which are rated at 3.6 or 3.7 volts. These are not used in watches.Advantages
Fairly constant voltage over most of its useful life. Contains no chemicals harmful to the environment. Very long shelf life, up to 10 years.
Disadvantages
Suitable for low drain or only intermittent high drain applications.
Uses
Excellent for quartz watches that draw very low current, and only intermittent current when the stepper motor is driven. Can last 5 years or more in the correct application. Not suitable for Accutrons as the voltage is too high.
A) Cell top (-ve electrode)B) Anode of lithiumC) Nylon sealD) Electrolyte in Separator, Anode and Cathode Material.E) Cathode of Manganese DioxideF) Absorbent separators containing electrolyteG) Cell Can (+ve electrode)
Zinc-Air Cells
Note: Not to be used in watches!
Zinc-Air cells are not watch batteries, and are included in this list because they seem at first glance to be a good alternative to Mercury cells for our Accutrons. Read on and find out why not. Zinc-Air cells have the highest capacity of all button cells due to the fact that most of the cell volume can be taken up with anode material (zinc), because the cathode material used is oxygen obtained from the atmosphere. Their rated voltage is 1.4 volts. They are activated by peeling off an adhesive layer, allowing air to enter the cell through small vent holes.Advantages
Very high capacity for their size. Very constant voltage ouptut for most of their life. Able to be used in medium current applications. Slightly shorter shelf-life than Mercury cells when not activated, but longer than Alkaline and Silver Oxide. Environmentally safe.
Disadvantages
Must be used in applications where the battery compartment is vented to the atmosphere. The cells are hygroscopic, and therefore may store and release water to and from the atmosphere. Actual performance of the cell can depend on the relative humidity.
Uses
The main use for Zinc Air button cells is in hearing aids. They must not be used in watches, as they require atmospheric oxygen to function, and they may emit water which can be corrosive to metal parts. Under extremes of temperature, or if the cell is shorted out, the internal membranes may rupture, and vent liquids and gas to the atmosphere. Do not use in watches!!!
Chemical Reaction 2Zn + 3MnO2 KOH--> 2ZnO + MN3O4
Operating Temperature See each type.
Initial Voltage 1.5 volts or 9.0 volts.
CapacityAlkaline batteries do not have a standard capacity rating; see the Capacity heading for a full explanation.
Discharge RateSloping. Products with a high current drain are particularly hard on batteries; the higher the current drain is, the steeper the discharge slope will be.
Internal ResistanceVery low. It remains almost constant until the end of its life when it will increase rapidly.
ImpedanceVery low (much less than that of carbon zinc batteries).
Storage Life See below.
Storage Temperature See below.
Disposal Not recyclable; can be safely thrown away.
THE ALKALINE CELLTHE ALKALINE CELL
Type Primary
Chemical Reaction 2Zn + 3MnO2 KOH--> 2ZnO + MN3O4
Operating Temperature -20º F to 130º F ( -28º C to 54º C). Good range of operating temperatures.
Recommended for
High-discharge devices, which include (but are not limited to): Digital cameras, RC cars, portable power tools, heavy-use flashlights, CB walkie-talkies, FRS radios, portable televisions, handheld video games, portable audio systems (such as boomboxes), CD players, MP3 players, appliances, shavers, and toothbrushes.
Initial Voltage 1.5 volts or 9.0 volts.
Capacity
•When used in a device with a high discharge rate, the service life is up to 38% higher than standard alkalines. •At low to moderate discharge rates, performance is similar to standard alkalines. •Alkaline batteries do not have a standard capacity rating; see the Capacity heading for a full explanation.
Discharge RateSloping. Products with a high current drain are particularly hard on batteries; the higher the current drain is, the steeper the discharge slope will be.
Internal Resistance Very low. It remains almost constant until the end of its life when it will increase rapidly.
Impedance Very low (much less than that of carbon zinc batteries).
Storage LifeLoses 5% of performance after one year, and 2.5% each year after. We recommend that these be used within 5 years.
Storage Temperature -40º F to 120º F ( -40º C to 48º C).
Positive cap: Formed protrusion at one end of the battery can which identifies it as the positive terminal. Steel can: Nickel-plated steel which is formed into a container to hold chemicals and serves as the positive collector. Outer Jacket: A plastic sleeve which contains decorative printing identifying the cell type and size. Separator: Porous non-woven fibrous material which separates electrodes; holds electrolyte between electrodes. Electrolyte: A solution of potassium hydroxide in water which carries the ionic current inside the battery. Cathode: Manganese dioxide and graphite which take up electrons from the external circuits. Anode: Powdered zinc metal which serves as the source of electrons. Anode Collector: Tin-plated brass which serves as a path for the electrons from the anode to the external circuit. Seal/Vent: Molded plastic disc which holds internal components inside the cell and releases internal pressure when battery is abused.
THE LITHIUM IRON THE LITHIUM IRON DISULFIDE CELLDISULFIDE CELL
Lithium-Iron:A recent addition in the marketplace, the Lithium Anode, Iron Sulfide (or Iron Disulfide) Cathode battery stands out from the rest of the Lithium based Primary batteries in that its voltage output is typically 1.5 volts and comes in standard AA size. It also has for a Primary Lithium based battery uncommonly high capacity and high drain characteristics, typically higher than normal Zinc Manganese Dioxide Alkaline batteries. However their cost, when compared with normal Alkaline batteries has to be taken into consideration, especially when a lot of the simpler silent Super 8 cameras tend to have low to moderate drain characteristics.
BUTTONLithium-Manganese Dioxide:The most commonly available Lithium based button cell type battery, it consists of a Lithium Anode, Manganese Dioxide cathode and typically an organic electrolyte. It, however, cannot be used for replacing a Mercury Oxide battery because of its size, voltage (typically 3 volts) and its sloping output voltage characteristic under mid to
high drain applications.
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