CATALOG About delivery style, consult the sales representative. About the minimum order quantity, consult the sales representative. Product specification and appearance are subject to change for improvement. is a trademark of Sony Corporation. June <Japanese> <English> http://www.sony.co.jp/products/bat/ion/ http://www.sony.co.jp/en/products/bat/ion/
Polymer Lighter Weight Contributed by Higher Energy Density per Weight Non Liquid Electrolyte Construction Secures High Reliability and Safety Factor Fine Discharge Load Characteristics, Low Temperature and Cycle Performance Equivalent to Conventional Lithium Ion Consists of Liquid Electrolyte Graphite Higher Energy Density per Volume and Weight High-rate Version Available Fine Discharge Performance even at V cutoff Excellent Cycle Performance Hard Carbon Easy to Monitor Remaining Capacity Excellent Cycle Performance Superior Float Charge Performance
Charge / Discharge Mechanism Structure Battery charging and discharging occur through the migration of lithium ions between the cathodes and anodes and the exchange of electrons through doping and dedoping. More specifically, during charging lithium is dedoped from cathodes consisting of a lithiumcontaining compound, and the interlayers of carbon in anodes are doped with lithium. Conversely, during discharge lithium is dedoped from between the carbon layers in anodes, and the compound layers in cathodes are doped with lithium. Reactions occurring in lithium ion rechargeable batteries employing LiCoO (lithium cobalt oxide) in cathodes and carbon in anodes are shown in the figure below. Polymer tab Top insulator tab Load Charger Electrons Current Current Electrons Al laminate film Electrolyte (Polymer battery: gel polymer electrolyte) Electrolyte (Polymer battery: gel polymer electrolyte) Cylindrical Prismatic Discharge Charge + Top cover lead Terminal plate pin Charge and discharge mechanism of lithium ion rechargeable batteries Gasket Safety vent Insulator Cap plate Insulator (PTC) Safety vent Insulator case By means of the initial charging, which takes place during battery manufacturing, lithium ions migrate from the lithium compound of the cathode to the carbon material of the anode. Gasket initial charge LiCoO + C Li x CoO + Li x C lead can Subsequent discharge reactions occur through the migration of lithium ions from the anode to the cathode. can lead discharge Li x CoO +Li x C Li x+dx CoO +Li x dx C charge Insulator
Polymer Lithium Ion Polymer Rechargeable Battery Profile (UP86A) Sony Lithium Ion Polymer Rechargeable Battery Thickness Width Height Version Discharge Capacity Characteristics by Current Cycle Life Characteristics 7 7 6 Charge :.V max 7mA.h C Discharge :.V cutoff Discharge Current/mA 6 Charge :.V max 7mA.h C Discharge : 6mA.V cutoff Cycle Number/cycle UP8 UP86 UP6 Discharge Characteristics on Temperature Temperature Dependence on Discharge Capacity UP69 UP79 UP8 - C - C C C Charge :.V max 7mA.h C Discharge : 6mA 6 7 C 7 6 Charge :.V max 7mA.h C Discharge : 6mA.V cutoff - - - 6 Ambient Temperature during Discharge/ C Lineup & Specifications UP8AH UP86A UP86A UP6A UP69A UP69A UP79AH UP8AH * Nominal Voltage(V) Nominal Capacity(mAh)* Thickness Width Height Weight(Approx. g) 6 76 6 89 6 Cycle Life..8.8..... Dimensions(mm/max)...... 7.. 8. 6. 6. 6. 69. 69. 9. 8.. ±.V More than times C ~ + C C ~ + 6 C C ~ + C * Nominal Capacity :.C.V cutoff Average Discharge Capacity * Charge voltage, cycle life and temperature are applicable to all models. * About the tolerance of cell dimensions, delivery style and availability, consult the sales representative. 7.... 9. 9... Temperature Charge Discharge Storage Discharge Characteristics on Load ma Charge :.V max 7mA.h C 6 7 6mA 7mA ma Charge Current/mA 6 Charge Characteristics Charge Capacity 7 Charge Current Charge :.V max 7mA.h C... Charge Time/h Charge Capacity/% 6 7
Graphite Lithium Ion Rechargeable Battery Profile (US86G) Sony Lithium Ion Rechargeable Battery Diameter/Thickness Height/Width Height(:Cylindrical) Version Discharge Capacity Characteristics by Current Cycle Life Characteristics USGR USGR US6GR US767GR US8GR US86GR 6 Charge :.V max ma h C Discharge :.V cutoff 6 Discharge Current/mA 6 Charge :.V max ma h C Discharge : 7mA.V cutoff Cycle Number/cycle USG USGD US6G US767G US767GD US767GD US8G US86G US86GD US86G US86GD US68G US68G US667G US667G US6G US97G US97G US6G US68GR US667GR US6GR US97GR US6GR Lineup & Specifications * Nominal Voltage(V) Nominal Capacity(mAh) * Diameter Height Weight(Approx. g) 7 68 78 8 68 96 7 9 Cycle Life. *. *. * 7. * 7. * 7. * 8. * 8. * 8. * 8. * Dimensions(mm/max). 9.6 6. 67. 67. 67. 9. 6. 6. 6. 8. * 6. 6.x9.x8.(TxWxH) 6.x9.x8.(TxWxH) 6.x9.x67.(TxWxH) 6.x9.x67.(TxWxH) 6.7x.x9.9(TxWxH) 9.x.x7.(TxWxH) 9.x.x7.(TxWxH).x.x6.9(TxWxH) 6 9 8. 8. 9.... 9 6 Temperature Charge Discharge Storage. ±.V More than times C ~ + C C ~ + 6 C C ~ + C * Nominal Capacity :.C.V cutoff Average Discharge Capacity * Diameter : Including thickness of outer tube * Charge voltage, cycle life and temperature are applicable to all models. * About the tolerance of cell dimensions, delivery style and availability, consult the sales representative. Discharge Characteristics on Temperature 6 - C - C C C Charge :.V max ma h C Discharge : 7mA Discharge Characteristics on Load ma ma C 6 7mA Charge :.V max ma h C ma ma Charge Current/mA 6 Temperature Dependence on Discharge Capacity 6 Charge :.V max ma h C Discharge : 7mA.V cutoff - - - 6 Ambient Temperature during Discharge/ C Charge Characteristics Charge :.V max ma h C.... Charge Time/h Charge Capacity Charge Current 7 Charge Capacity/% 8 9
Hard Carbon Lithium Ion Rechargeable Battery Profile (US86) Sony Lithium Ion Rechargeable Battery Diameter/Thickness Height/Width Height(:Cylindrical) Discharge Capacity Characteristics by Current Cycle Life Characteristics 6 6 6 Charge :.V max ma h C Discharge :.V cutoff 6 Charge :.V max ma h C Discharge : 7mA.7V cutoff Discharge Current/mA Cycle Number/cycle Discharge Characteristics on Temperature Temperature Dependence on Discharge Capacity 6 US86 US66 US6 Charge :.V max ma h C Discharge : 7mA - C - C C C C 6 Charge :.V max ma h C Discharge : 7mA.V cutoff 6 6 - - - 6 Ambient Temperature during Discharge/ C Lineup & Specifications US86 US66 US6 * Dimensions(mm/max) Nominal Voltage(V) Nominal Capacity(mAh)* Diameter Height Weight(Approx. g).6.6.6 7 Cycle Life 8. * 6. 6.6 * 6.7. x. x 6.9(TxWxH) 8 8 Temperature Charge Discharge Storage. ±.V More than times C ~ + C C ~ + 6 C C ~ + C * Nominal Capacity :.C.V cutoff Average Discharge Capacity * Diameter : Including thickness of outer tube * Charge voltage, cycle life and temperature are applicable to all models. * About the tolerance of cell dimensions, delivery style and availability, consult the sales representative. Discharge Characteristics on Load Charge :.V max ma h C 6 6 8mA ma ma 7mA Charge Current/mA Charge Characteristics Charge Capacity 7 Charge Current Charge :.V max ma h C... Charge Time/h Charge Capacity/%
Handling Precautions Safety Instructions for Lithium Ion Rechargeable Battery Remarks for Appropriate Usage Lithium Ion Battery Transport Regulations WARNING PRECAUTIONS Keep away from infants. If infant happens to swallow the battery, consult a doctor immediately. In case of eye contact with the battery electrolyte, immediately flush eyes thoroughly with water, and consult a doctor. In case the battery electrolyte happen to come into mouth, gargle well enough and consult a doctor immediately. Do not heat or disposed in fire or water. Do not modify or disassemble the battery. It may damage the gasket, and may cause ignition, heating, leakage or explosion. Keep away from fire if battery has leakage or odor to prevent fire hazard. Assure the charge voltage is controlled within.±.v. Inappropriate charge voltage may cause permanent deterioration of the battery performance, or swelling, leakage, ignition or explosion. Do not overdischarge the battery lower than V. It may lead to reversed polarity and cause ignition, heating, leakage or explosion. Do not short-circuit positive (+) and negative (-) terminals. Keep away from metal or other conductive materials. Jumbling the batteries of direct contact with positive (+) and negative (-) terminals and metal or other conductive materials may cause short-circuit. Do not solder the battery directly. Excessive heating may cause deformation of the battery components such as the gasket, which may lead to the battery swelling, leakage, explosion or ignition. When the battery is stored or disposed, isolate positive (+) and negative (-) terminals of the battery to avoid those terminals touch each other. Insert the battery with positive (+) and negative (-) terminals correctly oriented. Do not put the battery into microwave oven or drying machine. Do not drop, apply excessive damage or deform the battery. Do not mix the used battery together with the new battery or different type of batteries. Consult the sales representative, when series or parallel connection of several batteries is required. For transportation, observe the package instruction to be specified by the manufacturer. Assure not to apply excessive vibration or not to drop the batteries packaged. Do not store the battery in high temperature and high humidity location and where the battery is exposed to sunlight to avoid performance deterioration, swelling or leakage of the battery. Temperature Charge C+ C *Battery performance may deteriorate when charged above C. Discharge - C ~ +6 C Storage - C ~ + C Current Charge C max. Discharge C max. *Reference only. For details, consult the representatives or ask information. Voltage Charge.+.V Discharge Polymar, Graphite :.V cutoff Hard Carbon :.V cutoff Battery Pack Design Battery terminals should be designed to prevent incorrect installation to the charger and/or end product. Charge Condition Constant Voltage and Constant Current Method Voltage.V/cell Current.C ~ C Protection Circuit Protection circuit should be installed either in battery pack, end product and/or charger. Protection circuit should have three functions specified below.. Over-charge Protection : Should be within a range of.v/cell ~.V/cell.. Over-discharge Protection : Should be within a range of.v/cell ~.V/cell. Leak current should be controlled less than µa.. Over-current Protection : Should operate at less than approx. C. *Reference only. For details, consult the representatives or ask information. Lithium ion batteries containing no more than.g/cell and 8g/battery pack of lithium can be treated as "non-dangerous goods" under the United Nations Recommendations on the Transport of Dangerous Goods, Special Provision 88, provided that the packaging is strong and prevents the products from short-circuiting. With regard to air transport, the International Civil Aviation Organization (ICAO) Special Provision A accepts the above UN Recommendation as is; further, the International Air Transport Association (IATA) adopts ICAO Provision A. In addition, the regulations of the US Department of Transportation (DOT) for land, sea and air transportation are based on the UN Recommendations. All of Sony's lithium ion cells and most* of its lithium ion battery packs fulfill the conditions of the UN Recommendations on the Transport of Dangerous Goods, Special Provision 88 (ICAO Special Provision A) and can be treated as "non-dangerous goods." The mass of lithium in a lithium ion battery is calculated as follows; (a) For the cell: (Ah of a cell) x (.g/ah) (b) For the battery pack: (Ah of a cell) x (number of cells used in the pack) x (.g/ah) (E.g., the amount of lithium in a pack using six 86 (Ah) cells = Ah x 6 x.g/ah =.6g.) *As for the details of specific models, consult the sales representative.