Inverter Battery Calculator

Backup Runtime and Bank Planner

Estimate the battery bank, inverter class, DC current, and recharge target needed to keep critical loads running through outages without draining the bank too deeply.

9 outage presets Lead-acid and lithium models Battery, surge, and recharge checks

📌Preset Backup Scenarios

Model note: The calculator starts with AC load and outage runtime, then adjusts for inverter efficiency, usable depth of discharge, reserve buffer, and cold-weather battery derating before it recommends a nominal bank.

⚙Battery and Inverter Inputs

Use duty cycle below 100% for loads that cycle on and off, such as refrigerators and sump pumps. Surge watts should reflect the highest startup burst on the protected circuit.

Unit System

Critical AC Load (W) Total steady running watts the inverter must feed during the outage.

Startup Surge (W) Use the highest motor or compressor startup surge on the protected circuit.

Required Runtime (hours) Planned outage window before grid or generator power returns.

Average Duty Cycle Apply lower duty cycle to intermittent loads so runtime is not overstated.

Installed Inverter Class Efficiency and surge headroom change the battery draw and inverter pass/fail check.

Battery Chemistry Different chemistries use different safe depth-of-discharge and cold weather factors.

Battery Bank Voltage Higher DC voltage lowers current and usually reduces cable and fuse stress.

Battery Module Format Module count uses series strings and parallel strings from this selected battery size.

Battery Temperature (°F) Cold batteries deliver less capacity, especially lead-acid below 50°F.

Reserve Buffer Reserve prevents the bank from being sized exactly on the edge.

Recharge Window (hours) Time available for solar, charger, or generator to restore the used energy.

One-Way DC Cable Run (ft) This does not replace cable ampacity tables, but it flags high current plus long run combinations.

Backup Sizing Snapshot

Enter a load profile to compare usable outage energy, the nominal battery bank required, inverter fit, and the recharge power needed to reset the bank.

Enter a scenario

Required AC Energy

Usable outage energy after duty cycle is applied.

Recommended Battery Bank

Nominal battery size before depth-of-discharge and temperature derating.

Inverter Margin

Continuous and surge headroom against the selected inverter class.

Recharge Target

Average charger or solar power to refill the energy used.

📈Selected System Spec Grid

Battery Chemistry

LiFePO4

90% DoD

High usable capacity and strong cycle life for frequent outages or daily cycling.

Inverter Class

2000W Pure Sine

92% eff

Clean waveform for compressors, CPAP units, routers, and electronics with moderate surge loads.

Battery Module Plan

24V 100Ah Pack

2.4 kWh

Series and parallel strings update after each calculation to show a practical module count.

DC Bank Stress

24 V bank

10 A

Continuous current, surge current, and cable advisory help catch high-current layouts early.

🔋Battery Chemistry Reference

Chemistry	Usable DoD	Round-Trip	Cycle Life	Best Fit
AGM Lead-Acid	50%	88%	500-800	Occasional backup circuits
Flooded Deep-Cycle	50%	85%	400-700	Ventilated shed or cabin banks
Gel Deep-Cycle	55%	87%	500-1,000	Quiet standby use
Carbon Lead	60%	90%	1,200-1,800	Frequent outage use
LiFePO4	90%	96%	3,000-6,000	Daily cycling and deep backup
NMC Lithium	85%	95%	2,000-3,500	Compact high-density packs

Usable depth-of-discharge values above reflect conservative whole-bank sizing targets rather than emergency one-time depletion limits.

⚡Inverter Class Reference

Inverter Class	Continuous	Surge	Best Bank	Typical Loads
1000W Modified Sine	1,000 W	1,600 W	12 V	Routers, chargers, resistive loads
1500W Pure Sine	1,500 W	3,000 W	12 or 24 V	CPAP, laptops, networking
2000W Pure Sine	2,000 W	4,000 W	24 V	Fridge, freezer, office circuits
3000W Hybrid	3,000 W	6,000 W	24 or 48 V	Apartment essentials, sump pumps
5000W Hybrid	5,000 W	10,000 W	48 V	Multi-circuit home backup
6000W Split-Phase	6,000 W	12,000 W	48 V	Well pumps, light whole-home service

Pure sine output is the safer default for electronics and inductive motors. Modified sine should stay with simple power supplies or resistive loads.

📋Preset Scenario Reference

Scenario	Effective Load	Runtime	Battery Bank	Inverter Fit

These rows use the same formulas as the calculator so you can compare realistic outage profiles before fine-tuning your own numbers.

📏DC Current by Bank Voltage

AC Load	12 V Bank	24 V Bank	48 V Bank

Current values assume roughly 90% inverter efficiency. Large loads on 12 V banks rise quickly into heavy cable, fuse, and busbar territory.

Tip: If your continuous load is above about 1,200 watts, move quickly toward a 24 V or 48 V bank. Lower current usually means cleaner starts and easier conductor sizing.

Tip: For lead-acid banks in cold spaces, keep a wider reserve than usual. A battery that looks large on paper can lose meaningful usable capacity before sunrise.

To calculate the correct battery size, you must determine both the energy needs of the appliances you wish to power and the number of hour that you need power outages to last. Many people make the mistake of purchasing the largest battery available instead of calculating the wattage and number of hours of outages needed by the appliance that they have. If you purchase a battery without performing such a calculation, however, you run the risk of buying a battery that is too small to supply the needs of those appliances.

To calculate the energy needs of the appliances, you must calculate the number of watts that each appliance use and the number of hours that each appliance will need to be on. The capacity of the battery, however, will not need to be equal to the energy needs of the appliances due to the fact that inverter electronics will lose 10-15% of the batterys energy transforming that energy into usable electricity for the appliances. Beyond the energy output of the battery, the chemistry of the batteries will affect there capacity.

How to Calculate the Right Battery Size

Lead-acid batteries can only be safely discharge to 50% of their capacity, for example, while lithium batteries can be safely discharged to 90% of their capacity. The temperatures at which the batteries are store can also affect the chemistry of the battery; batteries stored in a cold garage will have less energy than batteries stored at more typical storage temperatures. Beyond the chemistry and capacity of the batteries, there are other consideration of the appliances themselves.

Appliances often have a surge wattage; the amount of power that the appliance draws when it start to run. Such a wattage is often much higher than the wattage that the appliance continuously uses. For instance, a refrigerator may use 150 watts while it is running, but may use 1200 watts to start moving.

If the inverter does not have enough surge wattage to supply that surge, the inverter will fail to start that appliance. Thus, the surge wattage of the inverter should be higher than the maximum wattage of all of the appliances. Similarly, appliances like sump pump may have a low duty cycle; the number of hours that an appliance is on versus off during a specific period.

If the duty cycle of those appliances is low, they will not need to use as much energy as a device that is on all of the time. In addition to considering the appliances themselves, you must consider the voltage of the battery bank; the higher the voltage, the less current that will be require to run the appliances. If the battery bank is 12 volts and the appliances require 2000 watts of power, for instance, the battery bank will have to supply 200 amps of current to those appliances.

200 amps of current, however, will require relatively thick wires to move that amount of electricity. Using a 24 volt or 48 volt battery bank will reduce the current that the appliances require, reducing the amount of thick wiring that is required for installation. Higher voltage battery bank can also be used with inverter batteries; inverters that can handle the power from the electrical grid, solar panel arrays, and battery banks.

The chemistry of the batteries also determines how many time that battery can be used. AGM lead-acid batteries are relatively inexpensive, but often only provide around 500 charging cycles before they wear out and die. In contrast, LiFePO4 batteries are more expensive, but provide thousands of charge cycles before wearing out.

In addition to the chemistry of the batteries, you should provide a reserve buffer; a battery bank that can provide an additional 10-20% of power beyond that which is calculated for the appliances to be run during power outages. Additionally, the battery bank should be able to be recharged. The battery bank and charger should have enough wattage to provide enough power to recharge the batteries within the timeframe that you would like the batteries to last.

Additionally, long electrical cable can reduce the voltage that is provided to the appliances. If the cables between the battery bank and the appliances are too long, the voltage drop that results from the long cable could result in malfunctioning of the appliances. Thus, calculating each of these factors will allow you to create a battery bank and power system that perform in the way that you intend for it to function.