Lead Acid to Lithium Battery Conversion Calculator

Convert flooded, AGM, gel, or SLA battery banks into a lithium replacement by usable energy, runtime, voltage class, module count, and weight.

⚙Conversion Presets

🔋Existing Lead Acid Bank

Lead acid system voltage

Lead acid bank capacity (Ah)

Use total bank Ah at the selected system voltage, not the sum of series battery labels.

Lead acid battery type

Usable lead acid depth of discharge (%)

Many deep-cycle lead banks are sized around 50% DoD for service life.

Current bank condition / derating (%)

Average connected load (watts)

Runtime uses average load; peak load is checked against lithium current capability.

🧪Lithium Replacement Settings

Lithium replacement chemistry

Usable lithium depth of discharge (%)

Extra reserve buffer (%)

Lithium module size (Ah)

Used to estimate how many same-voltage modules or parallel strings are needed.

Peak load or surge (watts)

Available lithium BMS current (amps)

📊Conversion Results

📝Selected Conversion Spec Grid

50%

Lead usable DoD

85%

Lithium usable DoD

12.8 V

12 V-class LFP nominal

Typical cycle advantage

📐Replacement Fit Notes

Usable Wh is the anchor

A 100 Ah lead acid bank and a 100 Ah lithium bank are not equivalent in usable energy because their recommended DoD and efficiency differ.

Voltage class must still match

Replace a 12 V lead bank with a 12 V-class lithium pack, such as 12.8 V LFP, unless the charge controller and loads support a different DC bus.

Current limits matter

Lithium packs often hold voltage better under load, but the BMS current rating must cover the peak watts and any inverter startup surge.

📘Reference Tables

Lead Acid Type	Nominal Usable DoD	Round-Trip Efficiency	Energy Density	Common Smart Home Use
Flooded deep cycle	45-50%	75-85%	12-18 Wh/lb	Legacy solar and standby banks
AGM deep cycle	50-60%	80-90%	15-22 Wh/lb	UPS, cabinets, camera backup
Gel deep cycle	50%	80-88%	14-20 Wh/lb	Low-current standby systems
Small sealed SLA	40-50%	75-85%	12-18 Wh/lb	Alarm panels and access control
Starter / standby	20-30%	75-85%	15-25 Wh/lb	Short outage backup only
Lead carbon	60-70%	85-90%	18-24 Wh/lb	Partial-state solar cycling

Lithium Type	Nominal Cell Voltage	Typical Usable DoD	Energy Density	Conversion Note
LiFePO4 (LFP)	3.2 V	80-90%	45-70 Wh/lb	Best stationary lead acid replacement
Lithium NMC	3.6 V	70-85%	70-110 Wh/lb	Compact high-energy packs
Lithium NCA	3.6 V	70-85%	75-115 Wh/lb	Energy dense, needs careful BMS
Lithium titanate (LTO)	2.4 V	90%+	25-45 Wh/lb	High cycle life, lower voltage per cell

Lead Acid Bank	Approx Lead Usable	Similar LFP Gross	Typical LFP Ah	Voltage Class
12 V 7 Ah SLA	34 Wh	45-55 Wh	4-5 Ah	12.8 V
12 V 35 Ah AGM	170-190 Wh	220-260 Wh	18-22 Ah	12.8 V
12 V 100 Ah AGM	480-540 Wh	620-750 Wh	50-60 Ah	12.8 V
24 V 100 Ah AGM	960-1,080 Wh	1.25-1.5 kWh	50-60 Ah	25.6 V
48 V 200 Ah AGM	3.8-4.3 kWh	5-6 kWh	100-120 Ah	51.2 V

Project Scenario	Lead Bank	Average Load	Estimated Runtime	Likely Lithium Start
Alarm panel	12 V 7 Ah SLA	8 W	4-5 h	12.8 V 5 Ah LFP
Router shelf	12 V 35 Ah AGM	22 W	7-9 h	12.8 V 20 Ah LFP
PoE camera corner	12 V 100 Ah AGM	45 W	10-12 h	12.8 V 60 Ah LFP
Network rack	24 V 200 Ah AGM	180 W	10-12 h	25.6 V 120 Ah LFP
Home battery cabinet	48 V 200 Ah AGM	350 W	11-13 h	51.2 V 120 Ah LFP

💡Conversion Tips

Check the charger before swapping. Lead acid float, absorption, and equalization settings can be wrong for lithium; match the charger profile to the lithium pack and BMS requirements.

Use the BMS rating as a hard limit. The Ah match may look correct, but inverter, PoE switch, motor, or lock-controller peaks still need enough continuous and surge current.

A 100 Ah lead acid battery and a 100 Ah lithium battery is not considered to be equivalent batteries because they provide different amounts of usable energy to the equipment that utilize them. Many individuals believes the Amp hour rating of a battery indicates the total amount of energy that the battery contain. The Amp hour rating, however, do not factor in the energy that can be drawn from that battery.

Furthermore, lead acid batteries is fragile and have limitations regarding how deep they can be discharged. If a lead acid battery is ever discharged to 50% of it capacity, the lead acid battery will degrade with time and have a shorter lifespan from which it can derive its energy. In contrast, lithium batteries, spesifically LiFePO4 batteries, can be deeply discharged to 80-90% of their energy before degrading and reducing the lifespan of those batteries.

How Lead Acid and Lithium Batteries Are Different

Because the lead acid batteries degrades with deep discharges, lithium batteries can be more smaller in comparison to lead acid batteries of the same capacity yet still provide the same amount of usable energy. Beyond the capacity of the batteries to provide energy, another factor to consider when comparing lead acid batteries to lithium batteries is the depth of discharge and the round trip efficiency of those batteries. The depth of discharge and round trip efficiency can factor into the amount of energy that can be drawn from the batteries.

Furthermore, another factor to consider is the current state of the lead acid batteries in use. After sitting in use for several years, the lead acid batteries will degrade in their ability to provide one hundred percent of the energy that they was manufactured to provide. Thus, if an individual were to use these specifications to determine the size of a new lithium battery, they may end up with a battery that is too large.

Instead, derating the lead acid batteries will provide an accurate measure of the energy output of those batteries. Another factor to consider in the comparison between lead acid and lithium batteries is that the lithium battery contain a Battery Management System while the lead acid battery do not contain a Battery Management System. The Battery Management System acts as a brain for the battery and protect the battery cells from overcharging and deep discharging of the battery.

The Battery Management System contains a current limit for the battery. If an amount of current is drawn from the battery that comes in excess of that limit, such as a power surge in the equipment using the battery, the Battery Management System will shut off the power to the batteries to protect them. Thus, the peak watts of the devices that the battery is to power must be checked against the current limit of the Battery Management System to ensure that the system will not crash due to an overdraw of the current by the equipment.

Another factor to consider is the weight of the batteries. The weight of the lead acid batteries will be very heavy due to the elements of the battery, lead. In contrast, the lithium batteries will be much lighter.

This factor is important to consider in locations such as high shelves or remote enclosures in which the batteries will be installed. Because the batteries will be much lighter with the use of lithium batteries, this will be a benefit to the installation location of the batteries. Finally, another factor to consider is the type of charger that will be used for the batteries.

The charger that is used with lead acid batteries isnt to be used for the charging of lithium batteries. The lead acid battery chargers contains a high voltage equalization stage. This voltage is likely to cause the Battery Management System of the lithium battery to shut off its power and damage its cells.

The charge profiles must be matched to the voltage of the battery. For instance, a twelve volt system can use a twelve point eight volt LFP battery pack. Another example is that a twelve volt lead acid battery will likely require a charger that outputs a voltage of twelve volts while the lithium battery will require a charger that outputs a voltage of twelve point eight volts.

Thus, if these factors is considered, the battery backup system will be ensured to work correctly.