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James Park, PE, M.EngUpdated June 1, 2026Our Standards →

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Torque Calculator

Calculate torque from force and lever arm distance. Convert between Nm, ft-lbs, and in-lbs. Free mechanical engineering calculator with unit conversions.

Torque Calculator

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Calculate torque from force and lever arm, power and RPM, or moment of inertia and angular acceleration. Supports multiple calculation methods with unit conversions.

Details

Force & Lever Arm

N
m
90°

90° = perpendicular (maximum torque)

Enter values above to see results.

Want to learn more? Browse our calculation guides and tutorials →

Rotational Mechanics

Torque Calculator: Force, Power & Rotational Analysis Guide

Calculate torque from force and lever arm, power and RPM, or moment of inertia and angular acceleration for mechanical design.

Force-Arm

τ = F × r

Power-Speed

τ = P / ω

Inertia-Accel

τ = I × α

Unit

N·m (SI)

Reviewed by: CalculatorApp Mechanical Engineering Team

What Is Torque?

Torque is the rotational equivalent of linear force — it causes or resists angular acceleration. Every rotating machine involves torque: engines and motors produce it, gearboxes transmit and transform it, fasteners require it for proper clamping, and brakes oppose it. Understanding torque is essential for sizing motors, designing drive trains, specifying fasteners, and analyzing mechanical failures.

Force & Arm

τ = F × r

Power & Speed

τ = P / ω (ω = 2πn/60)

Inertia

τ = I × α

Power Link

P = τ × ω
ApplicationTypical Torque RangeDesign Focus
Threaded fasteners1 N·m – 2000 N·mClamp load, yield limit
Electric motors0.1 N·m – 10 kN·mStarting torque, efficiency
Automotive engines100 – 2000 N·mPeak torque vs RPM curve
Wind turbines10 kN·m – 10 MN·mGearbox ratio, shaft design

History Timeline

Antiquity: Archimedes formalizes the lever principle — the geometric foundation of torque.

1687: Newton's laws of motion establish the rotational analogs: τ = Iα follows from F = ma.

1800s: Steam engines make torque a central practical engineering quantity for power transmission.

1882: De Laval's steam turbine demonstrates high-speed rotational torque in continuous operation.

1900s: Automotive and aerospace industries drive precise torque standards for fasteners and driveshafts.

Modern era: Torque sensors, dynamometers, and smart wrenches enable real-time torque control in manufacturing.

ASME Mechanical Design

Standard mechanical design and power transmission codes.

NEMA Motor Standards

Torque rating standards for electric motors.

ISO Fastener Standards

Bolt tightening torque specifications from ISO.

OSHA Machine Safety

Rotating equipment guarding and safety standards.

Myth: Higher torque always means a more powerful machine.

Fact: Power = torque × speed. A high-torque, low-speed motor can have the same power as a low-torque, high-speed motor.

Myth: Tightening a bolt harder always improves joint strength.

Fact: Over-torquing yields the bolt shank, reducing or eliminating clamp load and causing premature failure.

Myth: Torque and moment are different quantities.

Fact: Torque and moment are both force × distance; torque specifically applies to a rotational axis.

Myth: Gear reduction reduces power.

Fact: Ideal gears preserve power; torque increases as speed decreases by the gear ratio (minus friction losses).

FAQ (12)

What is torque?

Torque (τ) is a rotational force: τ = F × r. It is measured in Newton-meters (N·m) in SI units.

How is torque related to power?

P = τ × ω, where ω is angular velocity in rad/s. For rpm: P = τ × 2πn/60.

What is the torque from rotational acceleration?

τ = I × α, where I is moment of inertia (kg·m²) and α is angular acceleration (rad/s²).

How do I convert Nm to ft-lb?

1 N·m = 0.7376 ft·lb. Multiply Newton-meters by 0.7376 to get foot-pounds.

What is a torque wrench used for?

Torque wrenches apply a specified tightening torque to fasteners, preventing over- or under-tightening that can cause joint failure.

How does gear ratio affect torque?

A gear reduction multiplies torque by the gear ratio while reducing speed proportionally, maintaining constant power (minus losses).

What is the relationship between torque and RPM for a motor?

At constant power, torque decreases as RPM increases: τ = P / ω. High-torque motors run at low RPM.

What is tightening torque for bolts?

Bolt tightening torque depends on bolt size, grade, and lubrication. Typical M10 8.8 bolt: ~45-50 N·m dry.

What is the difference between torque and moment?

Both describe rotational force × distance; torque specifically refers to a twisting force about a rotational axis.

What is angular momentum?

L = I × ω. Torque equals the rate of change of angular momentum: τ = dL/dt, analogous to force = dp/dt.

How do I calculate torque for a pump or fan?

τ = P/ω from the shaft power required; then select a motor with torque rating exceeding this with a service factor.

Why does over-torquing break fasteners?

Excess torque stresses the bolt beyond its yield strength, causing permanent stretch or fracture of the threaded section.

References

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Open Engineering Suite

Torque Calculator — Engineer's Complete Reference

Torque is the rotational equivalent of linear force. Whether you're designing a gearbox, sizing an electric motor, tightening a cylinder head, or selecting a servo for a robotic arm — accurate torque calculation is foundational to safe, efficient mechanical design.

∼450 N·m
F1 engine peak torque
660 N·m
Tesla Model S torque
25 N·m
M8 bolt spec torque
∼1.0×10²² N·m
Earth rotation torque*

*Approximate net torque acting on Earth from tidal braking forces.

What Is Torque?

Torque (symbol: τ, from Latin torquere — "to twist") is the rotational counterpart of linear force. While a linear force pushes or pulls an object along a straight line, torque causes an object to rotate about an axis. It is formally defined as the cross product of the position vector (lever arm) and the applied force: τ = r × F.

When the force is applied perpendicularly to the lever arm — which maximises rotational effect — the scalar form simplifies to τ = F × r, where F is force in Newtons and r is the perpendicular distance from the axis of rotation to the line of action of the force (the moment arm), measured in metres. The result is expressed in Newton-metres (N·m), the SI unit of torque.

Torque and work (energy) share the same dimensional analysis — both equal N·m — but they are fundamentally different quantities. Torque is a vector (direction matters); energy is a scalar. Torque is sometimes called the moment of force or simply moment in structural engineering contexts.

Torque Formulas

Force & Lever Arm

τ = F × r × sin(θ)

The fundamental definition. F = force (N), r = lever arm length (m), θ = angle between force vector and lever arm. When θ = 90° (perpendicular), sin(90°) = 1 and τ = F × r.

Power & Rotational Speed

τ = P / ω = (P × 60) / (2π × RPM)

P = power (Watts), ω = angular velocity (rad/s). Practical shortcut for motors: τ (N·m) = [P (kW) × 9,549] / RPM. Imperial: τ (lb·ft) = [HP × 5,252] / RPM.

Inertia & Acceleration

τ = I × α (Newton's 2nd Law for rotation)

I = moment of inertia (kg·m²), α = angular acceleration (rad/s²). Used for dynamic analysis: sizing a motor to accelerate a flywheel or robotic joint from rest to operating speed in a specified time.

Moment of Inertia Reference

ObjectAxisFormula
Solid cylinder / diskCentral (longitudinal)I = ½mr²
Thin cylindrical ringCentral (longitudinal)I = mr²
Solid sphereAny diameterI = ⅖mr²
Thin spherical shellAny diameterI = ⅔mr²
Thin rodPerpendicular through centreI = (1/12)mL²
Thin rodPerpendicular through endI = (1/3)mL²
Rectangular plateThrough centre (parallel to width)I = (1/12)mL²

Torque Unit Conversion Table

The Newton-metre (N·m) is the SI unit of torque. In the United States and the automotive industry, pound-foot (lb·ft) is standard. Note: "pound-foot" (force × distance) is the correct term for torque; "foot-pound" technically denotes energy, though the terms are used interchangeably in everyday mechanical work.

FromToMultiply byExample
N·mlb·ft0.73756100 N·m = 73.8 lb·ft
lb·ftN·m1.35582300 lb·ft = 406.7 N·m
N·mkgf·m0.10197100 N·m = 10.2 kgf·m
kgf·mN·m9.8066510 kgf·m = 98.1 N·m
lb·inN·m0.11298100 lb·in = 11.3 N·m
N·mlb·in8.8508100 N·m = 885 lb·in
oz·inN·m0.00706100 oz·in = 0.706 N·m

Real-World Torque Applications

🚗 Automotive Engineering

Engine torque (N·m or lb·ft) is rated at a specific RPM on a dynamometer. A diesel engine producing 400 N·m at 1,800 RPM delivers strong low-speed pulling force for towing. A sports engine producing 350 N·m at 7,000 RPM prioritises high-RPM power. Drivetrain gear ratios multiply torque: a 4:1 gear ratio transforms 400 N·m of engine torque into up to 1,600 N·m at the driven wheel (minus friction losses). Wheel-hub motors in EVs eliminate the drivetrain entirely, applying torque directly to each wheel.

⚡ Electric Motors & Servos

Electric motors are characterised by their stall torque (maximum torque at zero speed), continuous torque (sustainable without overheating), and peak torque (brief maximum). Industrial servo motors and stepper motors (used in CNC machines and robotics) are rated in N·m or oz·in. The torque constant Kt (N·m/A) lets engineers calculate torque from motor current: τ = Kt × I. This is critical for servo sizing: motor torque must overcome friction, load inertia, and gravity torque of the mechanical system.

🔩 Fastener Tightening

Correct torque is critical for fastener integrity. The torque-tension equation is T = K × D × F, where T is tightening torque, K is the nut factor (0.15–0.20 for dry steel; 0.10–0.15 lubricated), D is nominal diameter, and F is clamping force. Automotive wheel lug nuts typically require 100–150 N·m. Cylinder head bolts are often torque-angle tightened: first torqued to a specified value, then rotated an additional angle (e.g., 90°) to achieve a controlled bolt stretch beyond the yield point for consistent clamping.

🏗️ Structural & Civil Engineering

In structural engineering, torque (bending moment) analysis is essential for beam design. Torsional stress in circular shafts is calculated using τ = T·r/J, where T is applied torque, r is shaft radius, and J is the polar moment of inertia (J = πr⁴/2 for solid circular sections). Bridge designs must account for torsional loading from eccentric traffic loads. Wind turbine blades transfer aerodynamic torque to the main shaft — modern 15 MW offshore turbines generate shaft torques exceeding 20,000 kN·m.

🤖 Robotics & Mechatronics

Robot joint torque requirements are calculated from the link geometry, payload mass, and desired acceleration. For a planar robot arm: τ_joint = m × g × L × cos(θ) + I_link × α, where m is the combined mass of all links and payload distal to the joint, L is the distance to the centre of mass, θ is the joint angle relative to horizontal, and α is angular acceleration. Safety factors of 2–3× are applied because motors must handle dynamic loads, friction, and manufacturing tolerances.

🛠️ DIY & Workshop Applications

Torque wrenches are essential for home mechanics. A torque wrench measures applied torque and provides an audible click or visual indicator when the set value is reached. Common applications: spark plugs (15–30 N·m), oil drain plug (20–35 N·m), wheel lug nuts (100–150 N·m), and bicycle components (5–15 N·m for carbon fibre parts — over-tightening crushes carbon fibre layup). Digital torque adapters allow any standard ratchet to measure torque, making precise fastening accessible for all skill levels.

Torque vs. Power: Understanding the Difference

Torque and power are related but measure fundamentally different things. Torque is a static or instantaneous rotational force — how hard the engine twists. Power is the rate at which work is done — how fast torque is delivered. They are linked by the formula:

P (W) = τ (N·m) × ω (rad/s)

where ω = 2π × RPM / 60

For acceleration from a standstill, torque matters most — which is why electric vehicles (which produce maximum torque from zero RPM) accelerate explosively. For sustained high speed, power at high RPM determines performance. A 4-cylinder economy engine may match a V8's torque at 5,000 RPM but cannot sustain it because of lower displacement and thermal limits. In industrial machinery, motors are selected for their torque speed curve — the relationship between available torque and operating RPM across the full operating range.

Vehicle / MachinePeak TorquePeak PowerTorque RPM
Tesla Model S Plaid1,420 N·m (1,047 lb·ft)760 kW (1,020 hp)0 RPM (instant)
Formula 1 engine (2024)~450 N·m (332 lb·ft)1,000 kW+ (1,340 hp)~10,500 RPM
Diesel semi-truck engine2,800 N·m (2,064 lb·ft)450 kW (600 hp)1,100 RPM
Economy sedan (2.0L)200 N·m (148 lb·ft)110 kW (148 hp)4,000 RPM
15 MW offshore wind turbine20,000+ kN·m15,000 kW8–12 RPM

Bolt & Fastener Torque Reference

Proper fastener torque ensures correct clamping force and prevents joint failure from both under- and over-tightening. Always verify torque specifications with the manufacturer's service manual for safety-critical applications. Values below are typical for dry (unlubricated) conditions; reduce by 15–25% when lubricant or thread locker is applied.

ApplicationTorque (N·m)Torque (lb·ft)Notes
Wheel lug nut (passenger car)100–15074–111Always torque in a star pattern
Wheel lug nut (truck/SUV)150–200111–148Re-check after 50 km
Spark plug (aluminum head)20–3015–22Apply anti-seize to threads
Oil drain plug20–3515–26New crush washer each time
Cylinder head bolt (typical)80–12059–89Use torque-angle method for accuracy
Bicycle stem clamp5–74–5Critical for carbon fibre components
M8 Grade 8.8 bolt2518Standard structural fastener
M10 Grade 8.8 bolt4936Standard structural fastener
M12 Grade 8.8 bolt8663Standard structural fastener

History of Torque in Science & Engineering

~250 BC

Archimedes formulates the principle of the lever: "Give me a long enough lever and a fulcrum, and I will move the world." His treatise On the Equilibrium of Planes describes the moment of a force — the precursor to torque.

1687

Isaac Newton publishes Principia Mathematica, establishing F = ma. The rotational equivalent — τ = I × α — follows directly, though Newton worked primarily with linear motion.

1820

Augustin-Louis Cauchy and Siméon Denis Poisson develop the mathematical framework for stress tensors, linking internal material stresses to applied torque in shafts — foundational to mechanical engineering design.

1865

James Watt's unit of "horsepower" (550 ft·lbf/s) becomes the de facto standard for rating steam engine power. The relationship between horsepower, torque, and RPM (HP = τ × RPM / 5,252) originates from this era.

1960

The International System of Units (SI) establishes the Newton-metre (N·m) as the official unit of torque, replacing the multitude of regional units (kgf·m, lbf·ft, ozf·in) with a coherent global standard.

2012

Tesla Motors introduces the Model S with 440 lb·ft (597 N·m) of instant electric torque, redefining consumer expectations for vehicle acceleration. Modern EVs with dual motors produce over 1,000 N·m, surpassing most supercars.

Frequently Asked Questions

What is the difference between torque and moment?

In physics, "torque" and "moment of force" (or "moment") are synonymous — both describe a rotational force. In structural and civil engineering, "moment" is the preferred term, particularly for bending moments (forces causing beam bending). In mechanical and automotive engineering, "torque" is standard. The mathematics are identical: τ = F × r × sin(θ).

Why does angle matter in the torque formula?

Only the component of force perpendicular to the lever arm creates rotation. When force is applied at angle θ, the effective perpendicular component is F × sin(θ). At 90° (perpendicular), sin(90°) = 1 — maximum torque. At 0° or 180° (parallel to lever arm), sin(0°) = 0 — zero torque regardless of force magnitude. This is why door handles are designed for perpendicular pushing, and why wrenches are most efficient at 90° to the bolt axis.

Can I calculate horsepower from torque and RPM?

Yes. Use: HP = (τ_lb·ft × RPM) / 5,252, or equivalently: kW = (τ_N·m × RPM) / 9,549. Example: 300 lb·ft at 5,252 RPM = exactly 300 HP. Note that the 5,252 constant is derived from converting RPM to rad/s and watts to horsepower: 1 HP = 550 ft·lbf/s = 745.7 W. This relationship means torque and horsepower curves always cross at 5,252 RPM on a dyno chart.

What is stall torque for electric motors?

Stall torque is the maximum torque a motor produces at zero RPM (when the rotor is held stationary). It equals the motor's torque constant (Kt, in N·m/A) multiplied by the locked-rotor current. Operating at stall torque for extended periods causes thermal damage due to I²R losses. Most motor ratings specify continuous torque (safely maintainable indefinitely) and peak torque (brief bursts, typically 2–3× continuous).

References & Further Reading

  • • Meriam, J.L., & Kraige, L.G. (2012). Engineering Mechanics: Dynamics (7th ed.). Wiley.
  • • Beer, F.P., & Johnston, E.R. (2012). Vector Mechanics for Engineers: Statics and Dynamics (10th ed.). McGraw-Hill.
  • • Shigley, J.E., Mischke, C.R., & Budynas, R.G. (2014). Mechanical Engineering Design (10th ed.). McGraw-Hill.
  • • SAE International. (2019). Torque Tension Fastener Standards. Society of Automotive Engineers.
  • • ISO 286-1:2010. Geometrical product specifications — Limits and fits. International Organization for Standardization.
  • • NIST. (2023). The International System of Units (SI). National Institute of Standards and Technology.