BTU/minute to Horsepower (Water)
BTU/min
hp
Conversion History
| Conversion | Reuse | Delete |
|---|---|---|
1 BTU/min (BTU/minute) → 0.02357004115089036423 hp (Horsepower (Water)) Just now |
Quick Reference Table (BTU/minute to Horsepower (Water))
| BTU/minute (BTU/min) | Horsepower (Water) (hp) |
|---|---|
| 1 | 0.02357004115089036423 |
| 10 | 0.23570041150890364228 |
| 100 | 2.35700411508903642283 |
| 500 | 11.78502057544518211417 |
| 1,000 | 23.57004115089036422834 |
| 5,000 | 117.85020575445182114168 |
| 10,000 | 235.70041150890364228335 |
About BTU/minute (BTU/min)
BTU per minute (BTU/min) equals approximately 17.58 watts and is used in moderate-scale thermal engineering and HVAC commissioning. Gas appliance heat outputs and furnace ratings are sometimes expressed in BTU/min in US engineering documents. One BTU/min is the power needed to raise one pound of water by one degree Fahrenheit every minute. It occupies the range between the very fine BTU/s and the coarser BTU/hour used for equipment nameplate ratings.
A 100,000 BTU/hour furnace (common US home size) delivers about 1,667 BTU/min or roughly 29.3 kW of heat output.
About Horsepower (Water) (hp)
Water horsepower (hp(W)) equals 746.043 watts and is used specifically in pump engineering to express the hydraulic power delivered to a fluid, as distinct from the shaft power input to the pump. It accounts for the fact that a pump's mechanical input power always exceeds the hydraulic power delivered due to efficiency losses. Pump efficiency is calculated as water hp divided by input shaft hp. The difference between water hp and electric/mechanical hp is negligible (0.05%) for most calculations.
A pump delivering 100 gallons per minute at 50 feet of head produces approximately 1.26 water hp of hydraulic power. A pump rated at 2 shaft hp may deliver 1.6 water hp at 80% efficiency.
BTU/minute – Frequently Asked Questions
When would an HVAC technician use BTU/min instead of BTU/hour?
During commissioning and troubleshooting, when measuring instantaneous heat output over a few minutes. If a furnace is cycling on/off and you're timing its burn cycle, you might measure 2,000 BTU/min during the 8-minute burn phase, then zero during the 4-minute off phase. This gives a clearer picture than the nameplate BTU/h rating, which assumes continuous operation and averages out the cycling.
How do you convert BTU/min to BTU/hour?
Multiply by 60. A burner producing 1,500 BTU/min delivers 90,000 BTU/h. Going the other way, divide by 60: a 120,000 BTU/h furnace runs at 2,000 BTU/min when firing. This conversion is so routine in US HVAC work that technicians do it reflexively. The minute rate is more intuitive during short measurements; the hourly rate matches equipment nameplate conventions.
What common appliances produce 100–1,000 BTU/min?
A gas stovetop burner on high: 150–250 BTU/min. A gas fireplace insert: 300–600 BTU/min. A residential water heater recovery: 500–700 BTU/min. A barbecue grill on full: 400–1,000 BTU/min. A clothes dryer: 350–600 BTU/min. These are all common US gas appliances where the original engineering was done in BTU-based units, and the nameplate may show BTU/h but the technician thinks in BTU/min during testing.
How many BTU/min does it take to heat a room?
A 15 m² (160 sq ft) room in a cold climate needs roughly 100–250 BTU/min (6,000–15,000 BTU/h) of heating depending on insulation quality and outdoor temperature. A portable space heater rated 5,000 BTU/h delivers about 83 BTU/min — adequate for a small well-insulated room but insufficient for a drafty old one. The rule of thumb in US HVAC: 20–30 BTU/h per square foot, or about 0.4 BTU/min per square foot.
Is BTU/min used outside the United States?
Almost never. The rest of the world uses watts or kilowatts for thermal power ratings. Even in countries that once used BTU (like the UK), equipment has long been rated in kW. Some Middle Eastern and Asian HVAC markets use BTU/h because they import US-manufactured equipment with American ratings, but BTU/min specifically is a niche US engineering convention. If you see it, you're almost certainly reading an American document.
Horsepower (Water) – Frequently Asked Questions
How do you calculate water horsepower for a pump?
Water HP = (Flow in GPM × Total Head in feet) / 3,960. The magic number 3,960 comes from the weight of water (8.33 lb/gal) × 33,000 ft·lbf/min per hp ÷ 8.33 × the appropriate conversions. For example: 200 GPM at 80 feet of head = 200 × 80 / 3,960 = 4.04 water hp. If the pump is 75% efficient, you need 4.04 / 0.75 = 5.39 shaft hp, so you'd select a 7.5 hp motor (next standard NEMA size up).
Why does water horsepower matter when sizing a pump motor?
Because the motor must provide shaft hp, not water hp. If your application needs 3 water hp but the pump is only 65% efficient, you need 3 / 0.65 = 4.6 shaft hp — meaning a 5 hp motor minimum. Underestimating this gap leads to overloaded motors, overheating, and premature failure. Pump efficiency varies from 30% (tiny pumps) to 90% (large, well-designed centrifugal pumps), so the water-hp-to-shaft-hp gap ranges from 10% to 70%.
How does water horsepower differ from brake horsepower in pumps?
Water hp is the useful hydraulic output — the power actually delivered to the fluid as pressure and flow. Brake hp (bhp) is the shaft input power measured at the coupling. The ratio is pump efficiency: η = WHP / BHP. A pump rated at 10 bhp with 80% efficiency delivers 8 water hp; the other 2 hp is lost to friction, turbulence, and heat in the pump. When specifying pumps, you calculate the required water hp first, then divide by efficiency to find the necessary brake hp.
Is water horsepower used outside the United States?
Rarely. International pump engineering uses kilowatts for both hydraulic power and shaft power. The formula becomes: Hydraulic Power (kW) = (Flow in m³/h × Head in meters × density × g) / 3,600,000. European pump catalogs list "hydraulic efficiency" as a percentage relating input kW to output kW. The concept is identical — water hp is just the US customary wrapper around it. If you see "water horsepower" in a specification, it's almost certainly an American or Canadian document.
What pump applications require the most water horsepower?
Municipal water supply: 50–500 water hp per pump station. Oil pipeline pumping: 1,000–10,000 water hp per station. Mining dewatering: 100–5,000 water hp. Hydroelectric dam penstocks deliver thousands of water hp to turbines (in reverse — the water does the work). The largest single pump installations, like the pumps protecting New Orleans from flooding, can exceed 10,000 water hp each — moving millions of gallons per minute against levee heights.