Operating Lead-Acid or LiFePO₄ Batteries in Winter Under Overcast Conditions

By Rusty Latenser

Introduction

Multi-day overcast conditions in winter present one of the toughest operating environments for portable changeable message signs (PCMS) and other solar-powered field systems. Reduced irradiance, low ambient temperatures, and limited recharge opportunities combine to stress both lead-acid and LiFePO₄ (lithium iron phosphate) batteries. Extending usable days requires chemistry-specific strategies that balance depth of discharge (DoD), temperature thresholds, and thermal management.

Key Performance Attributes

Attribute	Lead-Acid	LiFePO₄
Cold-weather discharge	Reliable down to ~–20 °C, but capacity drops sharply (like half)	Stable to –20 °C, retains higher usable capacity
Cold-weather charging	Can accept charge at low temps, but risk of sulfation	Charging below 0 °C risks lithium plating (must be avoided)
Warm-weather tolerance	Heat accelerates water loss and grid corrosion	Heat reduces cycle life but less catastrophic
Depth of Discharge (DoD)	Practical limit ~50% for longevity	Usable up to 80–90% without major degradation
Solar recovery under overcast	Lower efficiency, higher acceptance of partial charge	Requires higher voltage accuracy, sensitive to charge controller settings
Cycle life under stress	500–800 cycles typical	2000–4000 cycles typical

Cold Weather Scenarios

Lead-Acid

• Strengths: Can be charged at sub-freezing temperatures, though efficiency drops.
• Risks: Sulfation accelerates if left partially charged for multiple days.
• Strategies:
  • Limit DoD to ~40–50% during overcast stretches.
  • Insulate enclosures to slow temperature swings.
  • Use temperature-compensated charge controllers to prevent under/overcharging.

LiFePO₄

• Strengths: Maintains higher usable capacity at low temps.
• Risks: Charging below 0 °C can permanently damage cells.
• Strategies:
  • Employ battery heaters or insulated enclosures to keep cells above 5 °C.
  • If heaters are unavailable, suspend charging until ambient rises.
  • Operate at 70–80% DoD to maximize usable days without risking deep discharge.

Warm Weather Scenarios

Lead-Acid

• Strengths: No charging restrictions in warm conditions.
• Risks: Accelerated water loss and plate corrosion above 35 °C.
• Strategies:
  • Increase ventilation in enclosures.
  • Use AGM or gel variants to reduce maintenance.
  • Limit DoD to ~50% to slow degradation.

LiFePO₄

• Strengths: Handles warm weather better than lead-acid.
• Risks: Elevated temps shorten cycle life.
• Strategies:
  • Shade or ventilate enclosures to reduce thermal load.
  • Operate at higher DoD (up to 80–90%) to extend usable days.
  • Monitor charge controller accuracy to avoid overvoltage stress.

Extending Usable Days Under Overcast

Universal Practices

• Panel Tilt & Cleaning: Maximize winter irradiance by tilt angles and keeping panels clear of snow/dust.
• Load Management: Reduce unnecessary draws (e.g., dimming displays, cycling auxiliary systems).
• Enclosure Design: Insulation for cold, ventilation for heat.

Chemistry-Specific

• Lead-Acid:
  • Accept partial charging during overcast but avoid prolonged undercharge.
  • Rotate batteries if possible to prevent sulfation buildup.
• LiFePO₄:
  • Prioritize thermal management to keep cells above freezing.
  • Exploit deeper DoD capability to stretch autonomy during multi-day overcast.

Scenario-Based Recommendations

Cold + Overcast (3–5 days):

• Lead-Acid: Limit DoD to 40%, insulate enclosure, accept partial recharge.
• LiFePO₄: Suspend charging below 0 °C, rely on deeper DoD, use heaters if available.

Warm + Overcast (3–5 days):

• Lead-Acid: Ventilate enclosure, limit DoD to 50%, monitor water levels.
• LiFePO₄: Allow 80–90% DoD, ensure charge controller accuracy, shade enclosure.

Conclusion

Lead-acid batteries remain more forgiving in cold charging scenarios but suffer from lower usable capacity and shorter cycle life. LiFePO₄ batteries deliver superior autonomy and longevity but demand strict thermal management to avoid cold-charge damage.