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BTU per Hour to Watt Converter

Convert BTU/h to watts with our free online power converter.

Quick Answer

1 BTU per Hour = 0.293071 watts

Formula: BTU per Hour Γ— conversion factor = Watt

Use the calculator below for instant, accurate conversions.

Our Accuracy Guarantee

All conversion formulas on UnitsConverter.io have been verified against NIST (National Institute of Standards and Technology) guidelines and international SI standards. Our calculations are accurate to 10 decimal places for standard conversions and use arbitrary precision arithmetic for astronomical units.

Last verified: February 2026Reviewed by: Sam Mathew, Software Engineer

BTU per Hour to Watt Calculator

How to Use the BTU per Hour to Watt Calculator:

  1. Enter the value you want to convert in the 'From' field (BTU per Hour).
  2. The converted value in Watt will appear automatically in the 'To' field.
  3. Use the dropdown menus to select different units within the Power category.
  4. Click the swap button (β‡Œ) to reverse the conversion direction.
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How to Convert BTU per Hour to Watt: Step-by-Step Guide

Converting BTU per Hour to Watt involves multiplying the value by a specific conversion factor, as shown in the formula below.

Formula:

W = BTU/h Γ— 0.293071

Example Calculation:

1 BTU/h = 0.293071 W

Disclaimer: For Reference Only

These conversion results are provided for informational purposes only. While we strive for accuracy, we make no guarantees regarding the precision of these results, especially for conversions involving extremely large or small numbers which may be subject to the inherent limitations of standard computer floating-point arithmetic.

Not for professional use. Results should be verified before use in any critical application. View our Terms of Service for more information.

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What is a BTU per Hour and a Watt?

1 BTU/h = 0.293 W = 0.000293 kW

Key equivalents:

  • 3,412 BTU/h = 1 kW
  • 12,000 BTU/h = 1 ton of refrigeration = 3.52 kW
  • 1 BTU/h = 0.2931 W

The Physics of Power

Power is the rate at which work is done or energy is transferred.

Mathematical Definition: $$ P = \frac{E}{t} $$ Where:

  • $P$ = Power (Watts)
  • $E$ = Energy (Joules)
  • $t$ = Time (seconds)

Dimensional Analysis: $$ 1 \text{ W} = 1 \frac{\text{J}}{\text{s}} = 1 \frac{\text{kg} \cdot \text{m}^2}{\text{s}^3} $$

Electrical Definition: For electrical circuits, power is the product of voltage and current: $$ P = V \times I $$ Where:

  • $P$ = Power (Watts)
  • $V$ = Voltage (Volts)
  • $I$ = Current (Amperes)

Example:

  • A device drawing 5 Amps at 120 Volts consumes:
    • $P = 120 \text{ V} \times 5 \text{ A} = 600 \text{ W}$

Watt vs. Watt-Hour (The Confusion)

This is the #1 source of confusion about watts.

  • Watt (W): A unit of power (rate of energy use).
  • Watt-hour (Wh) or Kilowatt-hour (kWh): A unit of energy (total amount of energy used).

The Analogy:

  • Watts are like miles per hour (speed).
  • Watt-hours are like miles (distance).

Example:

  • A 100 W light bulb running for 10 hours uses:
    • $100 \text{ W} \times 10 \text{ h} = 1,000 \text{ Wh} = 1 \text{ kWh}$

Your electricity bill charges you for kWh (energy), not kW (power).

Note: The BTU per Hour is part of the imperial/US customary system, primarily used in the US, UK, and Canada for everyday measurements. The Watt belongs to the imperial/US customary system.

History of the BTU per Hour and Watt

: James Watt and the Steam Revolution

The Man Behind the Unit

James Watt (1736-1819) was a Scottish instrument maker and inventor. While he didn't invent the steam engine, he made it vastly more efficient, enabling the Industrial Revolution.

His Key Innovation (1769): Watt added a separate condenser to the Newcomen steam engine. This kept the main cylinder hot, reducing fuel consumption by 75%. Suddenly, steam engines became economical for factories, mines, and transportation.

The Irony: Watt also coined the term "horsepower" to market his engines (see our horsepower article). Yet the unit named after himβ€”the wattβ€”would eventually replace horsepower as the global standard for electrical power.

Official Adoption

  • 1882: The British Association for the Advancement of Science officially adopted the "watt" as the unit of electrical power, replacing the awkward "volt-ampere."
  • 1889: The International Electrical Congress endorsed the watt.
  • 1960: The watt was incorporated into the International System of Units (SI) as the standard unit of power.

The Original Definition

The watt was originally defined in relation to the absolute watt, based on mechanical power: $$ 1 \text{ W} = 10^7 \text{ erg/s} $$ (The erg is an obsolete CGS unit of energy.)

Today, the watt is defined in terms of fundamental SI units: $$ 1 \text{ W} = 1 \frac{\text{kg} \cdot \text{m}^2}{\text{s}^3} $$

Common Uses and Applications: BTU/h vs watts

Explore the typical applications for both BTU per Hour (imperial/US) and Watt (imperial/US) to understand their common contexts.

Common Uses for BTU/h

Air Conditioning: Window units (5,000-18,000 BTU/h), central systems (18,000-60,000 BTU/h). Furnaces: Home heating (40,000-150,000 BTU/h input). Water Heaters: Gas water heaters (30,000-50,000 BTU/h). HVAC Design: Load calculations, equipment sizing, ductwork design.

When to Use watts

1. Electrical Appliances

Every electrical device has a power rating in watts, indicating how much electricity it consumes when operating.

  • Low Power (1-100 W): LED bulbs, phone chargers, alarm clocks.
  • Medium Power (100-1,000 W): Laptops, TVs, fans, blenders.
  • High Power (1,000-5,000 W): Microwaves, hair dryers, space heaters, ovens.
  • Very High Power (5,000+ W): Electric water heaters, EV chargers, central AC.

2. Electricity Bills

Your utility company charges you for energy (kWh), not power (kW).

  • Formula: $\text{Cost} = \text{Power (kW)} \times \text{Time (hours)} \times \text{Rate ($/kWh)}$
  • Example: A 1,500 W space heater running 8 hours/day for 30 days:
    • Energy = $1.5 \text{ kW} \times 8 \text{ h/day} \times 30 \text{ days} = 360 \text{ kWh}$
    • Cost = $360 \text{ kWh} \times $0.10/\text{kWh} = $36$

3. Solar Panels & Renewable Energy

Solar panels are rated by their peak power output in watts under ideal conditions (full sun, 25Β°C).

  • Residential Panel: 300-400 W.
  • 10-Panel System: 3,000-4,000 W (3-4 kW).
  • Daily Energy (sunny location): ~15-20 kWh.

4. Electric Vehicles

EV charging power determines how fast the battery charges.

  • Level 1 (120V outlet): 1,400 W (1.4 kW) - adds ~4 miles/hour.
  • Level 2 (240V charger): 7,200 W (7.2 kW) - adds ~25 miles/hour.
  • DC Fast Charging: 50,000-350,000 W (50-350 kW) - adds 150-1,000 miles/hour.

5. Audio Equipment

Speaker and amplifier power ratings indicate maximum output.

  • Bluetooth Speaker: 5-20 W.
  • Home Theater Receiver: 100-200 W per channel.
  • Concert PA System: 10,000-50,000 W.

Additional Unit Information

About BTU per Hour (BTU/h)

How many BTU/h do I need for air conditioning?

Basic calculation: Room square footage Γ— 20-25 BTU/h

Adjustments:

  • Sunny room: Add 10%
  • Shaded room: Subtract 10%
  • Kitchen: Add 4,000 BTU/h
  • More than 2 people: Add 600 BTU/h per person
  • High ceilings (>8 ft): Add 10-20%

Examples:

  • 200 sq ft bedroom: 4,000-5,000 BTU/h (5,000 BTU window unit)
  • 400 sq ft living room: 8,000-10,000 BTU/h (10,000 BTU window unit)
  • 1,500 sq ft home: 30,000-36,000 BTU/h (2.5-3 ton central AC)

[BTU/h calculator for HVAC sizing]

How do I convert BTU/h to watts or kW?

Formula:

  • Watts = BTU/h Γ— 0.293
  • kW = BTU/h Γ· 3,412

Examples:

  • 12,000 BTU/h = 3,517 W = 3.52 kW (1 ton AC)
  • 24,000 BTU/h = 7,034 W = 7.03 kW (2 ton AC)
  • 10,000 BTU/h = 2,930 W = 2.93 kW (window unit)
  • 1,000 BTU/h = 293 W

BTU/h to Watts converter β†’ BTU/h to kW converter β†’

What is the difference between BTU and BTU/h?

BTU = Energy (total heat/cooling) BTU/h = Power (rate of heating/cooling)

Analogy:

  • BTU = distance traveled (miles)
  • BTU/h = speed (miles per hour)

Example:

  • A 10,000 BTU/h air conditioner removes 10,000 BTU of heat per hour
  • Running for 3 hours removes 30,000 BTU total

Always use BTU/h when rating HVAC equipment capacity!

How many BTU/h equals 1 ton of refrigeration?

1 ton = 12,000 BTU/h = 3.52 kW

Origin: Based on melting 1 ton (2,000 lbs) of ice in 24 hours

Common AC sizes:

  • 1 ton = 12,000 BTU/h (small rooms, ~400-600 sq ft)
  • 1.5 tons = 18,000 BTU/h (larger rooms, ~600-900 sq ft)
  • 2 tons = 24,000 BTU/h (small homes, ~900-1,200 sq ft)
  • 2.5 tons = 30,000 BTU/h (medium homes, ~1,200-1,500 sq ft)
  • 3 tons = 36,000 BTU/h (larger homes, ~1,500-1,800 sq ft)
  • 4 tons = 48,000 BTU/h (large homes, ~2,000-2,400 sq ft)
  • 5 tons = 60,000 BTU/h (very large homes, ~2,400-3,000 sq ft)

BTU/h to Tons converter β†’

How efficient is my furnace or AC?

Furnace efficiency (AFUE):

  • Old furnace: 60-70% AFUE
  • Standard: 80% AFUE (80,000 BTU/h input β†’ 64,000 BTU/h heat output)
  • High-efficiency: 90-98% AFUE

AC efficiency (SEER):

  • Old AC: SEER 8-10 (inefficient)
  • Standard: SEER 13-14 (minimum new units)
  • High-efficiency: SEER 16-20
  • Ultra-high: SEER 20-26

EER (Energy Efficiency Ratio) = BTU/h output Γ· watts input

  • Good window AC: EER 10-12
  • Excellent: EER 12+

About Watt (W)

How do I calculate my electricity bill from watts?

Step-by-Step:

  1. Find the power rating (in watts) on the device label.
  2. Estimate daily usage (in hours).
  3. Calculate daily energy: $\text{kWh/day} = \frac{\text{Watts} \times \text{Hours}}{1,000}$
  4. Calculate monthly energy: $\text{kWh/month} = \text{kWh/day} \times 30$
  5. Calculate cost: $\text{Cost} = \text{kWh/month} \times \text{Rate}$

Example: 1,500 W space heater, 6 hours/day, $0.12/kWh

  • Daily energy: $(1,500 \times 6) / 1,000 = 9 \text{ kWh}$
  • Monthly energy: $9 \times 30 = 270 \text{ kWh}$
  • Monthly cost: $270 \times $0.12 = $32.40$

What is the difference between watts and volts?

  • Volts (V): Electrical pressure (potential difference). Like water pressure in a pipe.
  • Amps (A): Electrical flow rate (current). Like gallons per minute.
  • Watts (W): Electrical power (rate of energy transfer). Like horsepower.

The Relationship: $$ \text{Watts} = \text{Volts} \times \text{Amps} $$

Example:

  • A device at 120 V drawing 10 A consumes:
    • $120 \times 10 = 1,200 \text{ W}$

Why do some devices say "VA" instead of "W"?

VA (Volt-Amperes) is apparent power, while W (Watts) is real power.

  • For resistive loads (heaters, incandescent bulbs), VA = W.
  • For reactive loads (motors, transformers), VA > W.

Example:

  • A motor rated at 1,000 VA with a power factor of 0.8 actually consumes:
    • $1,000 \times 0.8 = 800 \text{ W}$

How many watts does a house use?

Average US Home:

  • Peak Power: 5,000-10,000 W (5-10 kW) when AC, oven, and dryer run simultaneously.
  • Average Power: 1,000-1,500 W (1-1.5 kW) continuous.
  • Monthly Energy: 900-1,000 kWh.

Off-Grid Solar System Sizing:

  • To power a typical home, you'd need a 10-15 kW solar array with battery storage.

What is a megawatt?

1 Megawatt (MW) = 1,000,000 Watts = 1,000 kW

Used for large-scale power generation and consumption.

  • Wind Turbine: 2-3 MW.
  • Small Power Plant: 50-100 MW.
  • Large Coal Plant: 500-1,000 MW.
  • Nuclear Reactor: 1,000 MW (1 GW).

How many watts can a standard outlet provide?

US Standard (120V, 15A circuit): $$ 120 \text{ V} \times 15 \text{ A} = 1,800 \text{ W} $$ Safe continuous load: 1,440 W (80% of max).

US Heavy Duty (120V, 20A circuit): $$ 120 \text{ V} \times 20 \text{ A} = 2,400 \text{ W} $$ Safe continuous load: 1,920 W.

240V Outlet (Dryer, Oven, EV Charger): $$ 240 \text{ V} \times 30 \text{ A} = 7,200 \text{ W} $$

Can I run a 1,500 W heater on a 15A circuit?

Technically yes, but it's pushing the limit.

  • 1,500 W at 120 V draws 12.5 A.
  • Circuit Breaker: 15 A.
  • Safety Margin: You should stay under 80% (12 A).

Recommendation: Run the heater alone on that circuit. Don't plug in other devices.

What is "peak watts" vs "continuous watts"?

  • Continuous Watts: The power a device can sustain indefinitely.
  • Peak Watts (Surge Watts): The power a device draws briefly during startup.

Example: Refrigerator

  • Running: 150 W.
  • Startup (Compressor Kick): 600-800 W for 1-2 seconds.

Why It Matters: When sizing a generator or inverter, you need to account for peak watts, not just continuous watts.

Conversion Table: BTU per Hour to Watt

BTU per Hour (BTU/h)Watt (W)
0.50.147
10.293
1.50.44
20.586
51.465
102.931
257.327
5014.654
10029.307
25073.268
500146.536
1,000293.071

People Also Ask

How do I convert BTU per Hour to Watt?

To convert BTU per Hour to Watt, enter the value in BTU per Hour in the calculator above. The conversion will happen automatically. Use our free online converter for instant and accurate results. You can also visit our power converter page to convert between other units in this category.

Learn more β†’

What is the conversion factor from BTU per Hour to Watt?

The conversion factor depends on the specific relationship between BTU per Hour and Watt. You can find the exact conversion formula and factor on this page. Our calculator handles all calculations automatically. See the conversion table above for common values.

Can I convert Watt back to BTU per Hour?

Yes! You can easily convert Watt back to BTU per Hour by using the swap button (β‡Œ) in the calculator above, or by visiting our Watt to BTU per Hour converter page. You can also explore other power conversions on our category page.

Learn more β†’

What are common uses for BTU per Hour and Watt?

BTU per Hour and Watt are both standard units used in power measurements. They are commonly used in various applications including engineering, construction, cooking, and scientific research. Browse our power converter for more conversion options.

For more power conversion questions, visit our FAQ page or explore our conversion guides.

Helpful Conversion Guides

Learn more about unit conversion with our comprehensive guides:

πŸ“š How to Convert Units

Step-by-step guide to unit conversion with practical examples.

πŸ”’ Conversion Formulas

Essential formulas for power and other conversions.

βš–οΈ Metric vs Imperial

Understand the differences between measurement systems.

⚠️ Common Mistakes

Learn about frequent errors and how to avoid them.

View All Guides β†’

All Power Conversions

Watt to MilliwattWatt to KilowattWatt to MegawattWatt to GigawattWatt to HorsepowerWatt to Metric HorsepowerWatt to Electric HorsepowerWatt to BTU per HourWatt to BTU per MinuteWatt to BTU per SecondWatt to Foot-pound per SecondWatt to Foot-pound per MinuteWatt to Calorie per SecondWatt to Kilocalorie per HourWatt to Ton of RefrigerationWatt to Erg per SecondWatt to Joule per SecondMilliwatt to WattMilliwatt to KilowattMilliwatt to MegawattMilliwatt to GigawattMilliwatt to HorsepowerMilliwatt to Metric HorsepowerMilliwatt to Electric HorsepowerMilliwatt to BTU per HourMilliwatt to BTU per MinuteMilliwatt to BTU per SecondMilliwatt to Foot-pound per SecondMilliwatt to Foot-pound per MinuteMilliwatt to Calorie per SecondMilliwatt to Kilocalorie per HourMilliwatt to Ton of RefrigerationMilliwatt to Erg per SecondMilliwatt to Joule per SecondKilowatt to WattKilowatt to MilliwattKilowatt to MegawattKilowatt to GigawattKilowatt to HorsepowerKilowatt to Metric HorsepowerKilowatt to Electric HorsepowerKilowatt to BTU per HourKilowatt to BTU per MinuteKilowatt to BTU per SecondKilowatt to Foot-pound per SecondKilowatt to Foot-pound per MinuteKilowatt to Calorie per SecondKilowatt to Kilocalorie per HourKilowatt to Ton of RefrigerationKilowatt to Erg per SecondKilowatt to Joule per SecondMegawatt to WattMegawatt to MilliwattMegawatt to KilowattMegawatt to GigawattMegawatt to HorsepowerMegawatt to Metric HorsepowerMegawatt to Electric HorsepowerMegawatt to BTU per HourMegawatt to BTU per MinuteMegawatt to BTU per SecondMegawatt to Foot-pound per SecondMegawatt to Foot-pound per MinuteMegawatt to Calorie per SecondMegawatt to Kilocalorie per HourMegawatt to Ton of RefrigerationMegawatt to Erg per SecondMegawatt to Joule per SecondGigawatt to WattGigawatt to MilliwattGigawatt to KilowattGigawatt to MegawattGigawatt to HorsepowerGigawatt to Metric HorsepowerGigawatt to Electric HorsepowerGigawatt to BTU per HourGigawatt to BTU per MinuteGigawatt to BTU per SecondGigawatt to Foot-pound per SecondGigawatt to Foot-pound per MinuteGigawatt to Calorie per SecondGigawatt to Kilocalorie per HourGigawatt to Ton of RefrigerationGigawatt to Erg per SecondGigawatt to Joule per SecondHorsepower to WattHorsepower to MilliwattHorsepower to KilowattHorsepower to MegawattHorsepower to GigawattHorsepower to Metric HorsepowerHorsepower to Electric HorsepowerHorsepower to BTU per HourHorsepower to BTU per MinuteHorsepower to BTU per SecondHorsepower to Foot-pound per SecondHorsepower to Foot-pound per MinuteHorsepower to Calorie per SecondHorsepower to Kilocalorie per HourHorsepower to Ton of RefrigerationHorsepower to Erg per SecondHorsepower to Joule per SecondMetric Horsepower to WattMetric Horsepower to MilliwattMetric Horsepower to KilowattMetric Horsepower to MegawattMetric Horsepower to GigawattMetric Horsepower to HorsepowerMetric Horsepower to Electric HorsepowerMetric Horsepower to BTU per HourMetric Horsepower to BTU per MinuteMetric Horsepower to BTU per SecondMetric Horsepower to Foot-pound per SecondMetric Horsepower to Foot-pound per MinuteMetric Horsepower to Calorie per SecondMetric Horsepower to Kilocalorie per HourMetric Horsepower to Ton of RefrigerationMetric Horsepower to Erg per SecondMetric Horsepower to Joule per SecondElectric Horsepower to Watt

Other Power Units and Conversions

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Verified Against Authority Standards

All conversion formulas have been verified against international standards and authoritative sources to ensure maximum accuracy and reliability.

NIST Reference on Constants, Units and Uncertainty

National Institute of Standards and Technology β€” Fundamental physical constants and unit conversions

BIPM SI Units

Bureau International des Poids et Mesures β€” International System of Units (SI) definitions and standards

ISO 80000

International Organization for Standardization β€” Quantities and units international standards series

Last verified: February 19, 2026