© 2006 Texas Instruments Inc, Slide 1 Battery Charging and Chemistry Detection with the MSP430 Neal Brenner MSP430 FAE North America Texas Instruments.

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Presentation transcript:

© 2006 Texas Instruments Inc, Slide 1 Battery Charging and Chemistry Detection with the MSP430 Neal Brenner MSP430 FAE North America Texas Instruments

© 2006 Texas Instruments Inc, Slide 2 Battery Charging Basics Li-Ion Charging NiMH Charging Chemistry Detection Hardware and Software Overview Demo Agenda

© 2006 Texas Instruments Inc, Slide 3 Battery Chemistries ChemistryAlkalineNi-CadNiMHLi-Ion RechargeableNoYes Memory EffectN/ALargeSmallNone Self DischargeMediumHigh Low Current OutputMediumHigh Low CapacityLow MediumHigh CostLow MediumHigh Li-Ion is potentially dangerous to charge Ni-Cad is very environmentally unfriendly

© 2006 Texas Instruments Inc, Slide 4 Battery Charging Basics Battery Capacity is expressed in mAh Charge rate is expressed in terms of C C = Battery Capacity / 1 hour Example: 2500mAh battery  C = 2.5A  2C = 5A  C/2 = 1.25A  C/10 = 250mA  Etc. A battery charged at 1C should charge in ~1 hour, at C/2 in ~2 hours

© 2006 Texas Instruments Inc, Slide 5 Battery Charging Basics Li-Ion Charging NiMH Charging Chemistry Detection Hardware and Software Overview Demo Agenda

© 2006 Texas Instruments Inc, Slide 6 Li-Ion Charging Stages Pre-Charge (Conditioning)  If battery voltage < 2.5V  Constant current of C/10 Fast Charge  Constant current of 1C  While battery voltage in between 2.5V and 4.1V Constant Voltage Charge  Constant voltage at 4.1V Termination  When current drops below C/10

© 2006 Texas Instruments Inc, Slide 7 Li-Ion Charging

© 2006 Texas Instruments Inc, Slide 8 Battery Charging Basics Li-Ion Charging NiMH Charging Chemistry Detection Hardware and Software Overview Demo Agenda

© 2006 Texas Instruments Inc, Slide 9 NiMH Charging Stages Pre-Charge (Conditioning)  If battery voltage < 0.9V  Constant Current of C/10 Charge  Constant current of C/2 - 1C  When battery voltage > 0.9V Termination  3 different methods Trickle Charge  After termination constant current of C/20 to maintain charge

© 2006 Texas Instruments Inc, Slide 10 NiMH Charging

© 2006 Texas Instruments Inc, Slide 11 NiMH Charge Termination 3 Methods  -ΔV/Δt (primary)  ΔT/Δt (secondary)  Timer (secondary) Use all 3 for robust charge termination ΔT/Δt  Look for sharp increase in battery temperature over ambient or absolute safety temperature Timer  Set timer for appropriate charge time + 10% to 20% (to account for inefficiencies)  Example: if charging at C/2, set timer for 2 hours + 12 to 24 minutes

© 2006 Texas Instruments Inc, Slide 12 -ΔV/Δt Termination Look for battery voltage dip

© 2006 Texas Instruments Inc, Slide 13 Battery Charging Basics Li-Ion Charging NiMH Charging Chemistry Detection Hardware and Software Overview Demo Agenda

© 2006 Texas Instruments Inc, Slide 14 About Chemistries Detection Different battery chemistries have different internal impedances These impedances change over temperature, charge state, and life of the battery Goal: only charge the battery if it is definitely a NiMH (or NiCad) Never attempt to charge different chemistries (Alkaline, Lithium, etc.) NiMH has lowest impedance of all AA battery chemistries Impedance = R Bat = V Bat(Closed) - V Bat(Open) I Bat(Closed)

© 2006 Texas Instruments Inc, Slide 15 Open Loop Voltage I Bat = 0mA V sense = 0V V Bat = V In

© 2006 Texas Instruments Inc, Slide 16 Closed Loop Voltage I Bat < 150mA V sense = G ∙ I Bat ∙ R Sense V Bat = V In - (I Bat ∙ R Sense )

© 2006 Texas Instruments Inc, Slide 17 Impedance Calculation V Bat(Closed) = V In - (V sense / G) I Bat(Closed) = V sense / (G ∙ R Sense ) R Bat = V Bat(Closed) - V Bat(Open) I Bat(Closed)

© 2006 Texas Instruments Inc, Slide 18 How to Identify a NiMH AA Battery We use the battery’s impedance calculation along with its open circuit voltage (estimate of its charge state) to determine whether it is a NiMH battery This method will sometimes fail to identify very old NIMH batteries correctly  Impedance increases over the life of a battery Conditioning charge of 150mA for some time often allows NiMH to recover to low impedance Example Impedance cutoffs for AA batteries Voltage1.5V1.2V0.9V Cutoff Impedance 100mOhm150mOhm200mOhm

© 2006 Texas Instruments Inc, Slide 19 Battery Charging Basics Li-Ion Charging NiMH Charging Chemistry Detection Hardware and Software Overview Demo Agenda

© 2006 Texas Instruments Inc, Slide 20

© 2006 Texas Instruments Inc, Slide 21 Battery Charge Circuitry

© 2006 Texas Instruments Inc, Slide 22 Software Overview

© 2006 Texas Instruments Inc, Slide 23 Battery Charging Basics Li-Ion Charging NiMH Charging Chemistry Detection Hardware and Software Overview Demo Agenda

© 2006 Texas Instruments Inc, Slide 24 Demo Impedance Demo NiMH Charging Demo

© 2006 Texas Instruments Inc, Slide 25 Summary Li-Ion and NiMH batteries can be charged using the analog and digital control capabilities of the MSP430 Non-Rechargeable batteries can be detected by measuring their open circuit voltage and impedance