SLUAAR1 july   2023 BQ24630 , BQ25170 , BQ25180 , BQ25300 , BQ25620 , BQ25730 , BQ25798

 

  1.   1
  2.   Abstract
  3.   Trademarks
  4. 1Introduction
  5. 2Charge Profile and SOC vs OCV
  6. 3Thermal Runaway and Temperature Characteristics
  7. 4Applications
  8. 5Summary
  9. 6References

1 Introduction

When choosing between batteries there are many tradeoffs to consider: cost, size, weight, energy density, cycle life, stability, etc. In general, Lithium Iron Phosphate (LiFePO4) batteries are preferred over more traditional Lithium Ion (Li-ion) batteries because of their good thermal stability, low risk of thermal runaway, long cycle life, and high discharge current.

However, LiFePO4 batteries have a lower energy density and lower charge voltage, so they typically have to take up more area compared to a Li-ion battery. Furthermore, due to the lower charge voltage, a LiFePO4 battery may need a boost converter when a Li-ion may not. Table 1-1 shows a general comparison between typical low power multi-chemistry charging designs.

Later sections will focus on the differences between LiFePO4 and Li-ion’s charge profiles and thermal performance and the design implications these differences cause. We will then provide potential charger designs that are suitable for LiFePO4 batteries.

Table 1-1 Tradeoffs Between Typical Low Power Multi-Chemistry Batteries (1)
Li-Ion LiFePO4 Ni-MH SuperCap
Energy Density High 150-180 Wh/kg Medium 90-120 Wh/kg Low 60-120 Wh/kg Low 4.5Wh/kg
V(nom)/cell 3.6 V 3.2 V 1.2 V 2.7 V
V(charging) 3.9 V-4.2 V 3.5 V-3.65 V 1.4 V-1.6 V 2.7 V
Area Low Medium High High
Price High Medium Low Medium
Benefits
  • High Energy density
  • High voltage/cell at 3.6 V can lead to single cell use and space savings
  • Long cycle life 500 cycles
  • High current rating 3°C
  • Long cycle life 2000 cycles
  • Good thermal stability
  • Safer Li-Ions: enhanced
  • safety/tolerance if abused
  • Tolerant to full charge conditions
  • Reliable and Durable
  • Safe: Overcharge and discharge do not create high temperatures
  • More cost effective
  • Safe: No volatile chemicals, Overcharge and discharge do not create high temperatures
  • Long life, no wear out mechanism 500k cycles
Limitations
  • Fragile: requires protection circuit for safe operation
  • Peak voltage limited during charge
  • Temperature needs to be monitored
  • Lower voltage of 3.2 V/cell
  • Higher self-discharge which can cause balancing issues with aging
  • Quick self-discharge, needs to be charged more frequently
  • Lower voltage 1.2V/cell require multi-cell packs and larger designs
  • Voltage can have large change with discharge, SOC.
  • Low cell voltage can require series cell and possible balancing circuit.
Charge Temp 0°C to 45°C 0°C to 45°C 0°C to 40°C -40°C to 65°C
Discharge Temp -20°C to 60°C -20°C to 60°C

0°C to 50°C

-20°C to +85°C Possible

 -40°C to 65°C