Watt to BTU/hour
W
BTU/h
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Quick Reference Table (Watt to BTU/hour)
| Watt (W) | BTU/hour (BTU/h) |
|---|---|
| 1 | 3.41214163312787465105 |
| 10 | 34.12141633127874651052 |
| 60 | 204.72849798767247906311 |
| 100 | 341.21416331278746510519 |
| 800 | 2,729.71330650229972084151 |
| 1,200 | 4,094.56995975344958126226 |
| 2,000 | 6,824.28326625574930210377 |
About Watt (W)
The watt (W) is the SI unit of power, defined as one joule of energy transferred per second. It is the universal unit for electrical power, covering everything from a 1 W LED indicator light to a 3,000 W electric shower. Power consumption of appliances, power station output, and solar panel ratings are all expressed in watts or its multiples. One watt equals one volt multiplied by one ampere in a DC circuit, linking power directly to the foundational electrical quantities.
A modern LED bulb uses 8–10 W to produce the same light as a 60 W incandescent. A laptop draws 30–65 W; a microwave oven 800–1,200 W.
Etymology: Named after Scottish engineer James Watt (1736–1819), whose improvements to the steam engine drove the Industrial Revolution. The unit was adopted by the Second Congress of the British Association for the Advancement of Science in 1889.
About BTU/hour (BTU/h)
BTU per hour (BTU/h) is the standard power unit for heating and cooling equipment in the United States — air conditioners, furnaces, heat pumps, and water heaters are all rated in BTU/hour. One BTU/h equals approximately 0.293 watts. A typical window air conditioner is rated at 5,000–24,000 BTU/h; a central HVAC system for a mid-sized home at 36,000–60,000 BTU/h (called "3 to 5 tons"). The unit appears exclusively in US thermal and HVAC engineering.
A 12,000 BTU/h (1-ton) air conditioner uses roughly 1,200 W of electricity while removing 3,517 W of heat from the room. A typical US gas furnace is rated 60,000–100,000 BTU/h.
Watt – Frequently Asked Questions
How many watts does a phone charger actually use?
A standard USB charger draws 5–10 W, while fast chargers pull 18–65 W and some proprietary ones hit 120–240 W. The charger itself consumes about 0.1–0.3 W even when nothing is plugged in — so-called "vampire power." Over a year, a plugged-in-but-idle charger wastes roughly 2 kWh, costing pennies but multiplied across billions of chargers worldwide it adds up to gigawatt-hours of waste.
Why is a watt called a watt and not a joule per second?
Both are identical — 1 W = 1 J/s — but the watt was named in 1889 to honor James Watt, who quantified engine power decades before the joule was formalised. Giving power its own name made practical engineering simpler: saying "a 60-watt bulb" is far catchier than "a 60-joules-per-second bulb." The naming also followed a 19th-century tradition of honoring scientists with SI units — volt, ampere, ohm, and watt all came from this era.
What wattage does a human body produce?
A resting adult generates about 80–100 W of thermal power, roughly equivalent to an old incandescent light bulb. During intense exercise this spikes to 300–500 W total metabolic output, though only 20–25% becomes mechanical work — the rest is waste heat. This is why a packed lecture hall gets stuffy fast: 200 students produce about 20 kW of heat, equivalent to running 20 space heaters.
How many watts is a lightning bolt?
A single lightning stroke delivers about 1–5 billion watts (1–5 GW) of instantaneous power, but only for 1–2 milliseconds. The total energy per bolt is surprisingly modest — roughly 1–5 billion joules compressed into microseconds, equivalent to about 250 kWh or one month of a US household. You could theoretically power a town for a second, but capturing it is impractical because the pulse is too brief and unpredictable.
What is the difference between watts and watt-hours?
Watts measure the rate of energy flow (like the speed of water through a pipe), while watt-hours measure total energy consumed over time (like the total volume of water). A 100 W bulb running for 10 hours uses 1,000 Wh (1 kWh). Your electricity bill charges per kWh, not per watt — so a 2,000 W heater running one hour costs the same as a 100 W lamp running 20 hours.
BTU/hour – Frequently Asked Questions
How many BTU/h air conditioner do I need for my room?
The classic rule: 20 BTU/h per square foot. A 300 sq ft bedroom needs about 6,000 BTU/h; a 500 sq ft living room about 10,000 BTU/h. But this varies wildly with sun exposure (+10% for south-facing), ceiling height, insulation quality, number of occupants (+600 BTU per person), and climate zone. A room above a pizza oven in Phoenix needs more than a basement in Seattle. When in doubt, oversize slightly — an undersized unit runs constantly and never reaches setpoint.
What happens if you oversize or undersize your home AC unit by a ton?
Undersizing is obvious — the unit runs constantly and never reaches the thermostat setpoint on hot days. But oversizing is worse in subtle ways. An oversized AC cools the air quickly then shuts off before removing enough humidity, leaving you with a clammy 72°F house. The short cycles also wear the compressor faster (startup is the hardest moment) and waste energy. A 1-ton oversize in a humid climate like Florida can raise indoor humidity from a comfortable 45% to a muggy 60%. Proper Manual J load calculations matter more than most homeowners realize.
What does "1 ton" of air conditioning mean in BTU/h?
Exactly 12,000 BTU/h. One ton of AC is the cooling effect of melting one short ton (2,000 lbs) of ice over 24 hours. The ice absorbs 288,000 BTU of heat as it melts (2,000 lbs × 144 BTU/lb latent heat), divided by 24 hours = 12,000 BTU/h. Residential systems run 1.5–5 tons; commercial buildings 10–500 tons. The "ton" unit persists because HVAC contractors think in tons — "that house needs a 3-ton unit" is faster than "that house needs 10.5 kW of cooling."
How efficient is a modern air conditioner in BTU/h per watt?
Modern units achieve 12–25 BTU/h per watt of electricity (SEER 12–25). A SEER 20 unit removes 20 BTU/h of heat for every watt consumed — effectively a 3:1 heat pump ratio. That 12,000 BTU/h window unit draws 500–1,000 W of electricity depending on efficiency. The best mini-splits achieve SEER 30+, removing 30 BTU/h per watt, making them cheaper to run than resistive electric heaters even in heating mode.
How do BTU/h ratings differ between gas furnaces and heat pumps?
A gas furnace's BTU/h rating is its thermal output after combustion efficiency losses (typically 80–96% of fuel input). A heat pump's BTU/h rating is the heat delivered including energy moved from outside — at COP 3, a heat pump delivering 36,000 BTU/h uses only 12,000 BTU/h worth of electricity. This makes direct BTU/h comparisons misleading: a 60,000 BTU/h furnace and a 60,000 BTU/h heat pump deliver the same heat, but the heat pump uses one-third the energy.