Gear ratio calculation: speed, torque and tooth count

Design / Power Transmission June 28, 2026 10 min read 1,600 words

Gear ratio is the one number that links motor speed to output speed and input torque to output torque. Once you can count teeth and read it both ways, sizing a drive — gearbox, chain, or belt — stops being guesswork.

What gear ratio actually means

A gear ratio is simply the ratio of the driven (output) gear's tooth count to the driver (input) gear's tooth count. A ratio of 3:1 means the output shaft turns once for every three turns of the input — it runs a third of the speed and, ignoring losses, delivers three times the torque. That trade is the whole point of a gearbox: you buy torque with speed, or speed with torque.

The gear ratio formula

Gear ratio i = Ndriven / Ndriver = ωin / ωout N = number of teeth, ω = rotational speed. A pinion of 20 teeth driving a 60-tooth gear gives i = 60 / 20 = 3, a 3:1 reduction.

Because meshing gears share the same module, tooth count is proportional to pitch diameter — so you can equally write the ratio as the ratio of the two pitch diameters. For a multi-stage gearbox, the total ratio is the product of the individual stage ratios: a 4:1 stage feeding a 5:1 stage gives 20:1 overall.

Speed down, torque up

The two consequences of a reduction ratio follow directly:

ωout = ωin / i    Tout = Tin · i · η η is the gearbox efficiency (≈ 0.96–0.98 per spur stage, lower for worm drives). Torque is multiplied by the ratio, then trimmed by losses.

This is why a small, fast, cheap motor plus a reduction gearbox often beats a large, slow, direct-drive motor: you generate power where it is efficient and convert it to torque where you need it.

Module, pitch and centre distance

Two gears only mesh if they share the same module (m), the millimetres of pitch diameter per tooth. Pitch diameter d = m · N. From there the centre distance between two meshing gears is:

Centre distance a = m · (N1 + N2) / 2 With module 2 mm, a 20-tooth pinion and 60-tooth gear sit a = 2 × (20 + 60) / 2 = 80 mm apart.

Mismatch the module and the teeth simply will not engage — a surprisingly common error when mixing gears from two suppliers.

Worked example

A 1450 rpm motor delivering 10 N·m must drive a conveyor head shaft at about 290 rpm.

  1. Required ratio: i = 1450 / 290 = 5:1
  2. Tooth counts: a 20-tooth pinion needs a 20 × 5 = 100-tooth gear
  3. Output torque: Tout = 10 × 5 × 0.97 = 48.5 N·m
  4. Centre distance (module 2): a = 2 × (20 + 100) / 2 = 120 mm

So a single 5:1 spur stage turns a 10 N·m, 1450 rpm motor into a 48.5 N·m, 290 rpm output — exactly the conveyor duty, with the gearbox footprint set by the 120 mm centre distance.

Efficiency is not optional for worm drives Spur and helical stages are 96–98% efficient, so ignoring losses is a small error. A worm gearbox can be 50–90% efficient depending on lead angle — there, the η term dominates and skipping it will badly oversize the downstream torque estimate.

Quick reference: common ratios

Pinion teethGear teethRatioOutput speed (1450 rpm in)
20402:1725 rpm
20603:1483 rpm
201005:1290 rpm
1515010:1145 rpm
1224020:172.5 rpm

Run any combination — tooth count, module, centre distance and torque — through the gear ratio calculator to skip the arithmetic.

Common mistakes

  • Inverting the ratio. Driven over driver gives reduction; flipping it gives an overdrive you did not intend.
  • Mixing modules. Two gears of different module will not mesh, whatever their tooth counts.
  • Ignoring worm efficiency. A 70% worm drive delivers far less output torque than the ratio alone suggests.
  • Forgetting multi-stage multiplication. Total ratio is the product of stages, not the sum.
  • Too few pinion teeth. Below about 17 teeth, standard 20° involute gears undercut and weaken unless profile-shifted.
Sizing the motor behind the gearbox? Once you know the output torque and speed, the motor power calculation guide turns it into a kW rating. If your drive uses belts instead of gears, the sheet-metal guards around the drive still need accurate flat patterns.

If you are procuring cut gears against a drawing, balloon the tooth, bore and runout callouts before sending the print to a vendor so the FAI is unambiguous. CadNexa's auto-ballooning tool numbers every GD&T callout on a PDF gear drawing in the browser, and you can log the measured results on a ready inspection template.

Frequently asked questions

How do you calculate gear ratio?

Divide the number of teeth on the driven gear by the number of teeth on the driver gear. A 60-tooth gear driven by a 20-tooth pinion has a ratio of 60 / 20 = 3, written 3:1. The same value equals the ratio of input speed to output speed.

Does a higher gear ratio mean more torque?

Yes. A higher reduction ratio multiplies torque by that ratio (minus efficiency losses) while dividing output speed by the same ratio. A 5:1 reduction gives roughly five times the input torque at one-fifth the speed.

How do I find the centre distance between two gears?

Centre distance equals the module multiplied by the sum of the two tooth counts, divided by two: a = m · (N1 + N2) / 2. For module 2 with 20 and 60 teeth, that is 80 mm.

Why must meshing gears share the same module?

Module sets the tooth size — the pitch diameter per tooth. Two gears with different modules have differently sized teeth that cannot engage correctly, regardless of their tooth counts.

RR
Rajadurai R
Founder, MetricMech & CadNexa — 14 years plant-head experience