Lithium Manganese Dioxide CR2 I RE G ST FI RM BSI E RED BRIEF SPECIFICATION Model: CR2 Nominal Voltage: 3.0V Nominal Capacity: 750mAh Standard Discharge Current: 10mA Weight: 11g Stainless steel container ISO9002 Certified Non dangerous for transportation CONTENTS 1. General Information 1.1 1.2 1.3 Advantages for EEMB Lithium Manganese Dioxide cells Construction of Lithium Cells Characteristics and Applications 2. CR Primary Lithium Cells 2.1 2.2 Technical Data CR Primary Lithium Cylindrical Cell Performance Data 3. General Design Characteristics 3. 1 3.1.1 3.1.2 3.1.3 3.1.4 3.1.5 3.2 3.3 Safety Tests Compression Test 1120 kg in short circuit condition 24 H, 0.1¦¸ Test at 150¡ãC for 2 hours. Puncture Test total penetration of the cell by a nail §æ3mm Vibration Test Safety Guidelines Transportation of EEMB Lithium Cells 1. General Information The EEMB Lithium Manganese Dioxide cell chemistry was one of the first solid cathode cells commercially developed and is still the most widely used system today. These cells offer an excellent shelf life, good high-rate and low-rate capability, a wide operation temperature range and availability in cell designs. Potential design-in applications for these products are electronic, telecommunication, metering, instrumentation, office and other portable equipment use. Based on the outstanding cell performance and reliability of these produces, they have been able to meet and exceed the requirements of our customer base worldwide. 1.1 Advantages for EEMB Lithium Manganese Dioxide cells: High open circuit and load voltage: 2.8-3.2 volts per cell. High energy density: 270Wh/kg and 510Wh/l. Outstanding operational temperature range: -40¡ãC to +70¡ãC Flat discharge profile under low to medium rate applications. Low self-discharge: less than 1% per year at RT. Superior shelf life and operational life: up to 10 years. Ability to provide a variety of laser welded termination tabs for all cells. Safe and environmentally friendly. Http://eemb.com E-mail:[email protected] 1.2 Constructions of Lithium Cells EEMB offers a complete range of primary lithium manganese dioxide cylindrical cells for memory backup and portable applications worldwide. The cylindrical cell configurations, offer the high-capacity bobbin construction and high-power spirally wound product. The bobbin construction is targeted at low to moderate power requirements, dedicated for applications requiring up to a 10 year operational life at 20¡ãC. Our spirally wound constructional product offers high-rate discharge capability, with an operational life in excess of 5 years. Lithium Cylindrical Batteries Insulation Disk Neg.collector Sealing Lid Laser Welding Electrolyt Neg.Contact Fig.2 Bobbin construction Schematic construction of a Li/MnO2 cylindrical cell (CR 1/2AA) Lithium M nO 2 R i ng Separator Pos.Contact Positive Cap PTC Device Lid Positive Tab Anode (Lithium) Electrolyte +Separator Fig.3 Spiral construction Schematic construction of a Li/MnO2cylindrical cell (CR 123A) Cathode (Mn02 ) Negative Tab Negative Can Insulator Plate Http://eemb.com E-mail:[email protected] 1.3 Characteristics and Applications Main Applications Both mechanical and electrical properties, together with reliability, ensure that EEMB lithium batteries meet the requirements of modern electronics. They are therefore ideally suited as power sources for the long term supply of microelectronic circuitry. Main Characteristics Long life expectancy and long operational life. Low self discharge rate High energy density High cell voltage: 3 V Wide temperature range High operating Safety High reliability Resistance to corrosion No leakage problems 2. CR Primary Lithium Cells 2.1 Technical Data Model Nominal Voltage(v) Nominal capacity (mAh) CR 2 3.0 750 Pulse Standard Continuous discharge discharge discharge current (mA) current (mA) current (mA) 10 1000 Http://eemb.com E-mail:[email protected] 2500 2.2 CR Primary Lithium Cylindrical Cell Performance Data CR 2 5.9mm CR 2 1mm 27.0mm 15.6mm NOMINAL VOLTAGE (V) NOMINAL CAPACITY (mAh) STANDARD DISCHARGE CURRENT (mA) MAX. DISCHARGE CURRENT (mA) CONTINUOUS PULSE DIAMETER (mm) HEIGHT (mm) WEIGHT (g) 3.0 750.0 10 1000 2500 15.6 27.0 11.0 CR2 Temperature Characteristics 3.5 Voltage(v) Load:560 3.0 2.5 O -20 C 2.0 0 50 60 C 20 C O O 100 150 Time(h) CR2 Discharge Load vs.CellCapaity Capacity 600 400 200 2.0 0 40 80 100 Time(h) Http://eemb.com E-mail:[email protected] 3. General Design Characteristics In order to ensure optimum battery performance for the primary CR cylindrical cells, we suggest consideration of the following design-in requirements. They are the nominal and operating voltage, load current and profile, the duty cycle, temperature requirements and shelf life for the application. These characteristics for each battery type must be evaluated against the design requirements to select the most appropriate product that fulfills these requirements. 3. 1 Safety Tests 3.1.1 Compression Test 1120 kg No significant electrolyte loss No rupturing 3.1.2 In short circuit condition 24 H, 0.1¦¸ After 24 hours the bottom of the cell is curved by only 0.1mm; diameter unchanged. No electrolyte creepage or loss. No rupturing. 3.1.3 Test at 150¡ãC for 2 hours. No electrolyte creepage or loss No rupture No fire No explosion 3.1.4 Puncture Test total penetration of the cell by a nail §æ3mm No splashing or pressurized electrolyte loss. No rupturing. 3.1.5 Vibration Test Amplitude at frequency range: 5 to 55 Hz: ¡À0.75mm Frequency Range: 5Hz 55Hz 500Hz 55Hz 5Hz Acceleration at frequency range: 55 Hz to 500 Hz: 100m/s Cycle duration:15min Oscillation time of each main axis:3 h. Without changing of the electrical values of CR 1/2 AA, CR2/3 AA, CRAA. Http://eemb.com E-mail:[email protected] 3.2 Safety Guidelines Safety and Handling Issues We recommend that attention begins to the design and implementation of our lithium-Manganese Dioxide cells to ensure superior operating performance. With our Lithium-Manganese Dioxide Batteries, the appropriate precautions must be taken to avoid physical and electrical abuse otherwise, the batteries can be hazardous if not used properly. To avoid such incidents, we would suggest you review the following safety and handling precautions for your potential applications: 1.Do not heat. Nor dispose of in fire. If heated the plastic materials in the cell such as the gasket and separator may be damaged, causing leakage. The heat generated by a short circuit inside the batteries may lead to bursting or combustion. If disposed of in fire, batteries my violently rupture. 2.Do not charge (Lithium Primary Battery CR Series). When a Lithium Primary Battery is charged, gas is generated inside the battery and can result in swelling, heat generation, leakage, violent rupture or potential fire. 3.Avoid forced discharge. When batteries are force-over discharged with an external power source, the voltage drops to under 0.0 V (reverse electrode), and inner gas is generated. This can lead to swelling, heating, leakage violent rupture and / or potential fire. 4.Do not short circuit. If the positive and negative terminals come into contact with each other or with a metal object, this can cause a short circuit, generating heat. If the batteries are stacked on top of each other or mixed, the resulting short-circuit can lead to heat generation, leakage, violent rupture or fire. 5.Do not disassemble, apply excessive pressure or deform. If a battery is forcefully disassembled, gas may be generated which may cause throat irritation, or the lithium metal may generate heat, causing fire. If deformed under pressure or under impact, distortion of the seal may lead to leakage, or a short circuit inside the battery may lead to potential safety hazards. 6.Do not use with other battery types or old batteries with fresh cells. If different types of batteries are used together, or fresh are used with old ones, the difference in characteristics of voltage, capacity, etc., may cause over discharge of the battery which is exhausted first, leading to swelling, bursting or fire. Http://eemb.com E-mail:[email protected] 7.Observer the (+) and (-) polarity. If the batteries cell polarity is reversed by inserting the battery backwards, depending on the equipment, a short circuit or over discharging may result a potential safety hazard. 8.Do not swallow store batteries in a safe location, out of the reach of babies and small children. Also, make sure that batteries can not be easily removed from equipment in which they are used. If swallowed by mistake, consult a doctor immediately. 9.Do not throw into the water. This can result in corrosion and the generation of combustible gas. 10.Do not store in direct sunlight or rain. Store batteries in a place not subject to direct sunlight. Make sure the area is dry and is approximately 20¡ãC. Storage in areas with higher temperature, humidity or exposure to rain may cause deterioration in battery quality and durability. 11.Soldering. Do not solder or weld directly to the cells surface. Use preassembled cells with tabs or leads. 3.3 Transportation of EEMB Lithium Cells Lithium cells are considered non-dangerous if each battery with a solid cathode contains 1 gram or less of lithium and are therefore not subject to national or international dangerous goods regulations for transport by road, rail, sea, or air, provided that 1.Batteries are separated so as to prevent short circuits. 2.Batteries are packed in strong packaging, except when installed in electronic devices. 3.Details of specific transport regulations are available on special request. All EEMB Lithium Cells listed above contain less than 1.0 gram of Lithium and, as long as they are packed as above, are therefore not subject to the dangerous goods regulations. Http://eemb.com E-mail:[email protected] 4.Tabs EEMB Company Limited can provide following tabs and leads with the battery, Custom design welcomed. Figure 1 L H1 D Black Red D 6 Figure 2 H1 Figure 3 L H1 D Black Red H1 5 4 5 4 D Figure 4 0.3 H2 0.75 0.75 H1 D 5 5 Figure 5 0.2 0.2 0.75 7.45 H2 0.75 Http://eemb.com E-mail:[email protected]