Liion-Battery-introduction锂离子电池介绍.pptx

1、Battrey Chemistry Fundamentals and CharacteristicsSinowealth BP wxlCONTENTSIntroductionLi-ion Battery Fundamentals and Electrical BehaviorMonitoring and SafetyGeneral Battery Characteristics Page 21.2 Li-ion Battery Fundamentals and Electrical Behaviorn1.2.1 Battery Structuren1.2.2 Fundamentalsn1.2.

2、3 Materials and their influencesn1.2.3 Electrical behaviorn1.2.4 Equivalent circuitPage 3Li-ion Battery StructurenCylindrical Li-ion Battery structureSeparator,cathode and anode are around the column.Page 418650Li-ion Battery StructurenPrismatic Li-ion Battery StructurePage 5Li-ion Battery Structure

3、nCoin Li-ion Battery structurePage 6Li-ion Battery StructurenThin Film Li-ion Battery Structure10-100um thinkness.for microminiature device Page 7Li-ion Battery StructurePage 8Li-ion Battery StructurenLi-ion Battery Structure:nAnode nCathodenSeparator nElectrolyte nEnclosure and packagecomponentmate

4、rialexampleAnodeLi-embedded Transition metal oxidesLiCoO4,LiMnO4,LiCoMnOx,LiFePO4CathodeLi-embeddable compound etc.(synthetic)graphiteElectrolyteLiPF6 alkyl acid estersEC,PC,EDCSeparatorpolyene porous membranePE,PP,PP/PE/PPEnclosure and packagemetalsteel,aluminumPage 9Li-ion Battery Performance requ

5、irements of anode materialsnhigh specific energynhigh specific powernlow self-discharge rationlow costnlong lifenhigh safety levelPage 10Capacity Calculation：1mol Li+,Q=96500C（F=NA*e=96500C/mol）1C=1AsTake LiFePO4 for example:The formula weight of LiFePO4 is 157.756 g/mol,(1g/157.756g/mol)*96500C/mol

6、/3600s=170 mAh/gThe formula weight of LiCoO2 is 97.88 g/mol,(1g/97.88g/mol)*96500C/mol/3600s=274 mAh/gLi-ion Battery Capacity Calculation for AnodePage 11LiFePO4LiMnOxLiCoO2LiNiO2LiNiCoMnO2main componentLiFePO4LiMn2O4LiMnO2LiCoO2LiNiO2LiNiCoMnO2ennergy density(mAh/g)170 ideal148286274274278130-140 a

7、ctual100-120200135-140190-210155-165voltage（V）3.2-3.73.8-3.93.4-4.33.62.5-4.13.0-4.5cycle life2000500inferior300inferior800transition metalvery richrichrichpoorrichpoorenvironmantalnon-poisonousnon-poisonousnon-poisonousradioactivity(Co)poisonous(Ni)poisonoussafetygreatgoodgoodbadbadnot badtemp()-20

8、7550low temp stable-20 55N/A-20 55Li-ion Battery anode materials and their peformancesPage 12LiCoO2LiMn2O4poor safety,high costSynthesis difficult serious attenuationLiNiO2Li-ion battery anode materialsPage 13Li-ion battery anode material developmentpower fieldcommunication fieldLiFePO4LiMn2O4Li-ter

9、nary compoundLiNiO2Ni-Hlead-acidLiCoO2power field:LiFePO4 and LiMn2O4 have the advantages of low cost,safety and heat minocation field:Li-ternary compound and LiNiO2 have higher specific energy.Li-ion battery anode materialPage 14Li-ion battery Performance requirements of cathode materialsnLi+can be

10、 embed and seperated rapidly.ngood reversibility of Li+reaction with seldom crystal structure change.nweak electric potential change in the reaction process.ngood surface texture(Solid Electrolyte Interface Film,SEI)stability and compactednlarge diffusion coefficient for Li+diffusion in cells,easy t

11、o charge quickly.Page 15cathode materialsungraphitisedungraphitisedcarboncarbongraphite graphite stratified structurestratified structureTransition metal oxidessilica-basedmaterialLi4Ti5O12spinel structuretin-basedmaterialmetal LiLi-ion battery Cathode materialsPage 16synthetic graphitesilicon carbo

12、n alloyLi-ion battery cathode materials performancecathode materialscapacityprocess-abilitytemperature stabilitydisadvantagesgraphite carbon360mAh/geasygoodlow capacitySi alloy2500mAh/geasygoodvolume change Sn alloy800-900mAh/ghardbadbad porformance for high rate discahrgemetal Li3860mAh/geasybadden

13、dritic crystalPage 17carbon materials potential risk Li4Ti5O12large mount of capacity,less expension,long cycle life and storage life,surpport quick charge.etc.Metal lithium is deposited on the carbon surface.It can explosively react with a variety of materials.Burning,explode and gas expansion are

14、all protential safety problems.carbon materialsLi4Ti5O12Fig.Li4Ti5O12 SEM photo and its chg/dsg performanceLi-ion battery cathode materialsPage 18二次锂电池正负极材料电压二次锂电池正负极材料电压-容量分布图容量分布图Voltage versus capacity for positive-and negative-electrode materials presently used or under serious considerations fo

15、r the next generation of rechargeable Li-based cells.Li-ion battery electrode Voltage-Capacity distributionPage 19Fig.2 electrolyte product manufacture processLi-ion battery electrolytenElectrolyte is one of four major part of the Li-ion battery,which plays an important role in Li+transfer and has a

16、n effect on Capacity,work temperature range cycle and safety of the battery.nElectrolyte is usually 15%of the total weight and 32%of total volume,and its purity is worth attention in the manufacturing process.raw-materialsolvent-preparepurificationfine purificationelectrolytesolution preparestirfini

17、shed productPage 20nkeep liquid state in large temperature range,high Li+conductivity(10-2S/cm).ngood chemical and heat stability,hard to evaporation and reaction with others.nhigh protential up to 4.5V(vs.Li/Li+)。nnon-toxicneasy to prepare,low costLi-ion battery Performance requirements of electrol

18、yte materialsPage 21nsafety,stability,compatibility with cathode,conductivity,high dielectric constant,low viscosity.ncomposed by solvent and additive中文名称short namedielectric constantviscosity(mPas)melting point()boiling point()decomposition voltage(V)乙烯碳酸酯EC901.9372385.8丙烯碳酸酯PC652.5-492425.8二甲基碳酸酯D

19、MC3.10.593905.7二乙基碳酸酯DEC2.80.75-431275.5乙基甲基碳酸酯EMC2.90.65-55108-二甲醚DME7.20.46-58844.9solventLi-ion battery electrolyte solventPage 22Li-ion battery electrolyte additiveAdditive NameApplicationComponent亚乙烯碳酸酯improve SEI film performanceSO2/Co2/VC磷酸三甲酯improve eletrolyte safetyTMP冠醚和穴状化合物improve electr

20、olyte conductivityether,etc.金属氧化物和盐balance acid concentrationAl2O3,MgO,BaO,Li/CaxCOyPage 23n1.liquid state,solution.high purity solvent,electrolyte(LiPF6),additive.n2.solid state,ploymer.polymer lithium ion battery,LIP.Li-ion battery electrolytePage 24electrolyte classifychemical formulafeatures高氯酸锂

21、LiClO4explosive四氟硼酸锂LiBF4stability,poor conductivity and cyclity六氟砷酸锂LiAsF6effeciency,stability,but cost high and poisonous六氟磷酸锂LiPF4good conductivity,poor thermal stability三氟甲基磺酰LiN(SO2CF3)good thermal stability and cyclity,but poor conductivity双草酸硼酸锂LiBOBgood thermal stability and chemical stabili

22、ty,but low solubility and poor conductivityplay an improtant role in:nkeep anode and cathode separatenallow ion to pass through itself and charge to transferLi-ion battery separatorPage 25Li-ion battery separator performanceabilitypurposeperformanceposition separator,insulationanode and cathode part

23、icles isolation aviod slef-discharging,internal short circuitporinessLi-ion transferhigh conductivity,low internal impendancechemical stabilityno reaction and consumptionlong storage lifeelectrolyte wettabilityfully contactedion conductivitylong cycle lifemechanical propertyin case of crack by force

24、 from dendritic crystal or the other.long storage lifeself-protectpores close when temperature risesafetyPage 26nporous ploymer thin film（PP,PE,PP/PE/PP）nmechanical property,wettablity,pore close temp point and fusing point conflictnnon-woven fabrics,Separion 无纺布型nhigh porosity nanofiber filmnSepari

25、on thin filmnploymer electrolytensolid,gelLi-ion Battery SeparatorPage 27Celgard2400 separator，PP，25m，37%porosity，0.117m*0.042m pore size Li-ion battery separator examplePage 28Li-ion Battery CharacteristicsnChemical Capacity and EnergynBattery ImpedancenUsable CapacitynPower CapabilitynCycle Life,D

26、urability,Shelf LifenSelf-Discharge PropertiesPage 29Li-ion Battery Chemical Capacity/EnergynQmax：Amount of charge can be extracted from the fully charged cell to the end of discharge voltage(EDV).Battery chemical capacity(no load)nIn Unit of:nAh/kg,Ah/l,Wh/kg,Wh/l n/l,/kg-protable equipments(phone,

27、pad,etc.),ploymer Li-ion Batteryn Ah,Wh-comparing different battery with same chemical materials in Ah,but Wh for different chemical battery.Fig.x Voltage profile during low-rate discharge of batteryPage 30Li-ion Battery Battery ImpedancenBattery Impedance：dV=I*R,after transient processnNyquist plot

28、Voltage responses on current of different frequencyA1:impedance,stretching real value of A2,3,5A5:0.51sA6:1000sRelaxation timePage 31Li-ion battery Battery ImpedancenBattery Impedance：dV=I*R,after transient processnNyquist plot:Voltage responses on current of different frequencyA1:1000s.real sesist

29、ance stop increasing，IR drop constant，DC resistance.Relaxation timePage 32nBattery Impedance：dV=I*R,after transient processnNyquist plot:Voltage responses on current of different frequency40m 6070m 100m A1 A2 A3 A4 A5 A6 1000sNOTE：Cell makers often report cell impendance at 1kHz,its not real cell re

30、sistance.real resistance(DC resistance)is 2.7 times larger than that at 1kHz.Relaxation time increasing，real resistance keep constant but imaginary increacing,as if serially connected capacitor and capatance is huge.note that cell impedance varies from SOC,resulting from active particals and ions ch

31、anges.Equivalent circuit refer to page 6 Fig.3.Li-ion battery Battery ImpedanceRelaxation timePage 33nQusable:battery voltages.fully charged voltage,end of discharge voltage。nCell voltage depending on SOC and discharge current(IR drop).nIR drop observed take about 500s.(Nyquist plot 1000s)nIR drop:c

32、urrent，temperature，cyclelife，different from diffferent SOC.nNote:Do not estimate IR drop by resistance from cell makers.1kHz vs DCnestimate usable capacity in real discharge process in thermal box,heat exchange,much more close to real usable capacitywhy not test cell temperature directly？self-heatin

33、g of cell and,more important,electronic devices result in enviroment temperature around the cells rising,abundant heat exchange(put in thermal box)is nessanary for monitoring.Li-ion battery Usable CapacityPage 34nRagone Plot:Power Density(W/kg)-Energy Density(Wh/kg)./kg,/l,/m2nEnergy Density(Wh/kg):

34、battery ennery for battery one cycle usenPower Density(W/kg):battery power for battery proviod ennery every unit timeLi-ion battery Power Capability and Ragone PlotPage 35ncell aged：chemical capacity loss and impedance increasenchemical capacity loss：nreason：crystal structure of active changeninflun

35、ce：high and low-rate discharge applicationsnimpedance increase：nprimary reason：passivating layer grow and electrolyte lossninflunce：high-rate discharge application.deeper IR drop，usable capacity decrease。Li-ion battery Cycle LifePage 36Li-ion Battery Cycle LifenAnalyze：nExperimental results-impedanc

36、e increase influnce is much larger than that of capacity loss.n100cycle later，capcity loss5%，impedance increase60%.(DC resistance increased but not 1kHz resistance(almost constant),DC resistance is worthy of our attention)ninternal resistance：R=(V-OCV)/IPage 37nShelf life depends on storage voltage(

37、storage SOC)and storage temperature.nExperimental result：lead-acid battery benefit from high SOC storage,and Li-ion battery prefer low SOC storagenAged analyzed is similar to that of cycle life,current exsitance accelarate the aged and parastic reactionncurrent cause cracking of passivating layer,an

38、d the layer regrow will use up some active Li,the extra reaction particles will jam up pores to decrease the conductivity.ncurrent appear and disappear make the passivating layer expansion and shrinkage,the machanical change cause the electrical disconnect.nduring same time，cycle aged 510 times larg

39、er than storage.Li-ion Battery Shelf Life(Storage Life)Page 38Li-ion Battery Shelf Life(Storage Life)nIn the same temperature,the lower voltage,the lower battery capacity loss,the longer storage life of the battery.nUnder the same voltage condition,the lower temperature,the lower battery capacity lo

40、ss,the longer storage life of the battery.nUnder the same charge current condition,the lower charge voltage,the longer cycle life of the battery.Page 39Li-ion battery Self-DischargenSelf-discharge Mechanism:nParasitic conductancenDendritic crystal grows in charge process,decreasing the suface of ano

41、de.nSaperator will be poked and cracked by more dendritic crystal,leading to electrode direct contect to each other.nPrecautions:nanoporous saparators have been used to reduce this effect.nshuttle moleculesnsome molecules can become oxidized on cathode,diffuse to anode,and become reduced there,and b

42、ack to cathode.Similar effect of electron transfer.nPrecautions:avoid bringing in impurities in cell manufacture process.nutilize:under the high voltage conditon,the redox reaction of shuttle molecules can prevent over charge.Page 40Li-ion battery Self-DischargenSelf-discharge Mechanism:nRecombinati

43、on of oxygen-hydrogennH2and O2generate by electrolysis of water,gasses then diffuse through the separator and react since saparators are not airtight.Another redox reaction generate which is similar to the effect of electron transfer.nRecombination of oxygen-hydrogen generates heat and becomes notic

44、eable close to the end of charge.nOther redox reactions by impurities in electrolyte.Page 41Li-ion battery Self-DischargenTemperature：the higher temperature,the higher self-discahrge ratenTemperature rise will accelerate all redox reactions.nAge：the more age,the higher self-discahrge ratenthe age,th

45、e more crack of active materials,the higher surface area,the more matters of redox reactions.nNote:ncell structure designnThe reactions between electrolyte and electrode always exsit in the process of self-discharge,which makes poor the material activity and changes its structure,leading to decrease

46、 the ennergy(voltage)of the cell under the constant capacity.Page 421.4 Monitoring and Safetyn1、safetynLi-ion battery safety problems need more anntention:nmore activity of Li,reaction with mounts of materialnhigh specific ennergy nConsequence:nThermal runaway(热逃逸，热失控热逃逸，热失控)：The temperature rise,th

47、e more additive heat.thermal positive feedbacknbattery explode(expansion by heat or much more gas)nSources:nManufacture process.internal short circuit,metal particlesnAge process.cell imbalance,electrode imbalancenunreasonable operation,over discharge/charge.crystal structure change,dendritic crysta

48、l,internal short circuit Page 431.4 Monitoring and Safetyn2、safety problem examplenexternal short circuit,external monitoring device and circuit prevention for safety.nInternal short circuit,Saperator may be poked and cracked by more dendritic crystal,leading to electrode direct contect to each othe

49、r.manufacturing sector and external monitoring circuit prevention for safety.ngas expansion.Under high current and high temperature condition,electrolysis producing amount of gas.manufacturing sector and external monitoring circuit prevention for safety.Gas Safety ValvenThermal dilation,high current

50、side effect.自收缩隔膜自收缩隔膜nLi is deposited on anode,react with a variety of materials including electrolyte and cathode.More dangerious if air seep into and react with lithium,burning and explode.Page 441.4 Monitoring and Safetyn3、PreventionnProper battery design and manifacture,Improve the monitoring