How long will a 200Ah battery run an appliance that requires 1000W?

A 200Ah battery can power a 1000W appliance for approximately 2–2.4 hours under ideal conditions, assuming a 12V system. Actual runtime depends on battery voltage, discharge efficiency (~80% depth of discharge), and inverter losses (~10%). For example, a 12V 200Ah battery stores 2,400Wh (12V × 200Ah), delivering ~1,728Wh usable energy after efficiency losses—enough for 1000W loads for 1.7 hours.

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How does voltage affect runtime calculations?

Voltage determines total energy capacity. Batteries with identical Ah ratings but higher voltages store more watt-hours (Wh). A 24V 200Ah battery provides 4,800Wh—double the energy of a 12V system—extending 1000W runtime to ~3.5–4 hours after losses.

Battery voltage directly impacts energy storage through the formula Wh = V × Ah. Pro Tip: Always verify your battery bank’s nominal voltage before calculations—mismatched assumptions create large errors. For instance, industrial 48V systems maximize energy density: a 48V 200Ah battery holds 9,600Wh, theoretically powering 1000W devices for 9+ hours. However, few appliances operate at 48V DC, requiring inverters that introduce 5–15% losses. Transitionally, while Ah measures charge capacity, Wh reflects usable energy—the critical metric for runtime.

What efficiency factors reduce runtime?

Inverter losses (85–95% efficiency) and depth of discharge limits (typically 80%) reduce usable energy. A 12V 200Ah battery’s 2,400Wh becomes ~1,632Wh after 15% inverter loss and 80% discharge—cutting runtime from 2.4 to 1.6 hours.

Key factors include:

Practically speaking, a 3-year-old lead-acid battery might only deliver 1,200Wh instead of 2,400Wh due to aging. Transitionally, why do inverters matter? A 1000W microwave drawing 1,100W surges could trip low-quality inverters, interrupting power prematurely.

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