Horsepower (Electric) to Foot pounds-force second

It's a deliberate rounding for simplicity. The mechanical horsepower is 745.69987... watts — an ugly number for electrical calculations. The electric motor industry rounded to 746 W for clean nameplate ratings and straightforward calculations. The 0.04% difference is far below any motor's manufacturing tolerance. Some standards even use 750 W as an approximation. In practice, the distinction between 745.7 and 746 matters only to standards lawyers and unit conversion pedants.

Divide the hp rating by the motor efficiency and power factor. A 5 hp motor at 90% efficiency draws: 5 × 746 / 0.90 = 4,144 W of electrical power to deliver 3,730 W of shaft power. For three-phase motors, also divide by (√3 × voltage × power factor) to get amperage. Real-world efficiency ranges from 75% for small motors to 96% for large premium-efficiency ones. The nameplate always shows shaft output, not electrical input — a common source of confusion.

Because American homeowners and pool contractors have decades of experience sizing pumps in hp: "a 20,000-gallon pool needs a 1.5 hp pump" is ingrained knowledge. The Department of Energy actually mandated variable-speed pool pumps in 2021 and encouraged watt-based efficiency ratings, but manufacturers still prominently display hp because it drives purchasing decisions. A customer choosing between a 1 hp and 1.5 hp pump understands the difference intuitively; 746 W vs 1,119 W means nothing to them.

NEMA (National Electrical Manufacturers Association) defines standard motor sizes using electric hp: 1/4, 1/3, 1/2, 3/4, 1, 1.5, 2, 3, 5, 7.5, 10, 15, 20, 25, 30, 40, 50, 60, 75, 100 hp and up. These are standardized frame sizes — a 5 hp motor from any manufacturer fits the same mounting bolts. The hp(E) rating is the shaft output; NEMA also specifies efficiency classes (IE1 through IE4) that determine how much electrical power the motor actually consumes.

Not usually. EV manufacturers rate motors in kilowatts because the electrical connection is obvious and kW is internationally understood. A Tesla Model 3 motor is listed as 211 kW, not "283 hp(E)." However, marketing materials often convert to hp for American consumers: "283 horsepower" sounds sportier. Interestingly, EV motors are far more efficient (90–97%) than combustion engines (25–40%), so a 200 hp EV motor consumes far less total energy than a 200 hp gasoline engine.

James Watt calculated that a mill horse could turn a mill wheel 144 times per hour, doing 32,572 ft·lbf of work per minute — he rounded up to 33,000 ft·lbf/min (550 ft·lbf/s) for marketing purposes. He wanted to sell steam engines by comparing them to horses, so he likely overestimated the horse to make his engines look like better value. A real horse sustains closer to 350–500 ft·lbf/s, so Watt's "1 HP" is actually more than one horse.

Power (ft·lbf/s) = Torque (ft·lbf) × RPM × 2π / 60. This is the workhorse formula (pun intended) of US mechanical engineering. For example, an engine producing 200 ft·lbf of torque at 3,000 RPM delivers 200 × 3,000 × 6.2832 / 60 = 62,832 ft·lbf/s ≈ 114 hp. The formula works because angular velocity in rad/s times torque in ft·lbf gives power directly in ft·lbf/s.

Pushing with 1 pound of force at 1 foot per second — roughly the effort of slowly sliding a light book across a table against friction. Lifting a 1-pound weight 1 foot in 1 second. Turning a doorknob with a very light touch. It's about 1.36 watts — enough to dimly light an LED. In human terms, it's almost effortless: casual walking produces about 50–80 ft·lbf/s of mechanical power, and you don't even notice.

Yes, particularly in ballistics (muzzle energy rates), mechanical testing (dynamometer output), agricultural machinery specs, and industrial equipment designed for the US market. However, even in the US, many engineering firms are switching to SI units for international compatibility. The automotive industry increasingly quotes power in both hp and kW. Aerospace has been mostly metric since the 1990s. Ft·lbf/s survives mainly in traditional mechanical and manufacturing industries.

Bullets are rated in ft·lbf of muzzle energy (not per second), but the power of a firearm is the muzzle energy divided by barrel time. A .308 rifle bullet exits with about 2,600 ft·lbf of energy over a barrel transit time of ~0.001 seconds, meaning the instantaneous power is roughly 2,600,000 ft·lbf/s (about 3,500 hp). That's why rifle recoil feels punchy — for a millisecond, you're absorbing the reaction force of a truck engine.