i = N₂/N₁
Core Formula
1:1 → 9:1
Single-Stage Range
T₂ = T₁ × i × η
Torque Formula
96–99%
Typical Efficiency η
Table of Contents
02 — The Basic Calculation Formula
03 — Worked Example 1: Simple Ratio
04 — Calculating Output Speed
05 — Calculating Output Torque
06 — Worked Example 2: Full Drive Design
07 — Pitch Line Velocity Calculation
08 — Compound Drive Systems
09 — Worked Example 3: Two-Stage Drive
10 — Differential Ratio Explained
11 — Choosing the Right Ratio
12 — Worked Example 4: Ratio Selection
13 — Common Calculation Mistakes
14 — Quick Reference Tables
15 — Customer Reviews
16 — FAQ
01
What Is a Bevel Gear Ratio and Why Does It Matter?
The bevel gear ratio — also referred to as the gear ratio, speed ratio, or transmission ratio — is a dimensionless number that expresses the relationship between the rotational speeds of the input shaft (the driving shaft, connected to the pinion) and the output shaft (the driven shaft, connected to the ring gear). It tells you, for every one revolution of the input shaft, how many revolutions the output shaft completes — and conversely, by how much the torque is multiplied or divided through the gear pair.
Understanding and correctly calculating the gear ratio is one of the most fundamental tasks in any bevel gear drive design. Getting the ratio right determines whether the output shaft runs at the required speed, whether the output torque is sufficient to drive the load, and whether the gear set is operating within its rated pitch line velocity envelope. An incorrectly calculated ratio can result in a machine that runs too fast (risking gear damage, noise, and bearing overload), too slow (failing to achieve the required production throughput), or with insufficient torque to overcome the load at all.
For bevel gear differentials — the application most familiar to automotive engineers — the ratio has an additional meaning: it defines the final drive ratio of the entire driveline and directly affects vehicle acceleration performance, top speed, and fuel economy. Changing the final drive ratio by swapping the ring-and-pinion gear set (a “regear”) is one of the most effective drivetrain modifications available for vehicles.
This guide works through every aspect of bevel gear ratio calculation, from the most basic single-stage formula to compound multi-stage drives, with fully worked numerical examples at each step. All formulas use SI units (Nm, rpm, kW, mm) unless noted.

02
The Basic Bevel Gear Ratio Formula
Core Formula
i = N₂ / N₁
i = gear ratio
N₂ = ring gear teeth
N₁ = pinion teeth
i = n₁ / n₂
Equivalent expression
n₁ = input speed (rpm)
n₂ = output speed (rpm)
The gear ratio i is defined as the number of teeth on the ring gear (driven gear, N₂) divided by the number of teeth on the pinion (driving gear, N₁). It is equivalently defined as the input shaft rotational speed (n₁) divided by the output shaft rotational speed (n₂). These two expressions are equal because gear tooth counts and shaft speeds are inversely related — if the ring gear has twice as many teeth as the pinion, it rotates at half the speed of the pinion.
Note the convention used here: a ratio of 4:1 (written as i = 4) means the input shaft (pinion) rotates 4 times for every single rotation of the output shaft (ring gear). The output shaft therefore rotates more slowly than the input shaft — this is a speed-reducing (torque-increasing) drive, which is the most common configuration in bevel gear applications. If the input were connected to the ring gear and the output to the pinion, the drive would be speed-increasing (torque-reducing), with i = 0.25 (1:4). The same physical gear set can function as either, depending on which shaft is connected to the power source.
Understanding the Gear Ratio Direction Convention
Engineering convention expresses bevel gear ratios with the larger number first when the drive is speed-reducing (e.g. 4:1, 3.73:1, 8:1). A ratio of 1:1 — the mitre gear configuration — indicates equal speeds on both shafts. A ratio above 1:1 is always speed-reducing. The ratio is always positive; gear direction reversal is indicated by tooth hand (left-hand or right-hand spiral) and assembly configuration, not by a negative ratio value. For automotive rear axle differentials, the ratio is always called the “final drive ratio” or “axle ratio” and is expressed as a single decimal number: 3.73, 4.10, 3.31 etc.
03
Worked Example 1 — Calculating the Gear Ratio from Tooth Counts
Example Problem 1
Given: A spiral bevel gear pair with a ring gear having 40 teeth and a pinion with 10 teeth. The input shaft (pinion) is connected to a motor running at 1,450 rpm. Find the gear ratio and output shaft speed.
Step 1 — Identify the inputs
N₁ (pinion teeth) = 10 N₂ (ring gear teeth) = 40 n₁ (input speed) = 1,450 rpm
Step 2 — Apply the gear ratio formula
i = N₂ / N₁ = 40 / 10 = 4.0 (expressed as 4:1)
Step 3 — Calculate output speed
n₂ = n₁ / i = 1,450 / 4.0 = 362.5 rpm
Result
Gear ratio i = 4:1 | Output shaft speed = 362.5 rpm
The calculation is straightforward: the ring gear has four times as many teeth as the pinion, so it rotates at one quarter the pinion speed. For every four revolutions of the motor and pinion shaft, the output shaft completes exactly one revolution.
04
Calculating Output Speed from Gear Ratio
Once the gear ratio is known, output speed is a direct algebraic rearrangement of the ratio formula. The three forms of the speed calculation you will use are:
n₂ = n₁ / i
Find output speed when
input speed and ratio known
n₁ = n₂ × i
Find required input speed when
output speed and ratio known
i = n₁ / n₂
Find required ratio when
both speeds known
The third form is used when working backwards from a known application requirement — you know the motor speed and the required output speed, and you need to calculate what ratio the bevel gear pair must provide. In practice, available gear ratios from standard catalogue bevel gear sets may not exactly match the calculated required ratio. In such cases, select the nearest available standard ratio and verify that the resulting small speed error (typically ±5% from nearest standard) is acceptable for the application. If the output speed must be exact — as in some synchronised multi-shaft machines — custom gear manufacture to precise tooth counts is required.
05
Calculating Output Torque — Including Efficiency Losses
Torque Formulas
T₂ = T₁ × i × η
Output torque (speed-reducing)
T in Nm, η = efficiency (0.96–0.99)
P = T × ω
Power = Torque × Angular velocity
ω = 2πn/60 (rad/s from rpm)
T = 9550 × P / n
Practical formula: T in Nm
P in kW, n in rpm
Torque is multiplied by the gear ratio in a speed-reducing drive — a 4:1 ratio bevel gear drive with 50 Nm input torque delivers 200 Nm at the output shaft (minus efficiency losses). However, the efficiency factor η must always be applied. Spiral bevel gears have η = 0.96–0.99; straight bevel gears typically η = 0.96–0.98; hypoid gears (with their additional sliding contact) typically η = 0.94–0.97. Using η = 1.0 (100% efficiency) overestimates output torque and can lead to an undersized gear set or motor.
The practical formula T = 9550 × P / n is the most commonly used in engineering practice to convert between power (kW), speed (rpm), and torque (Nm) without requiring separate angular velocity calculation. It is derived from P = T × 2πn/60 with the constant 9550 = 60,000/(2π) rolled in. This formula works for both input and output — simply use the appropriate power and speed for the shaft in question.
Quick example: A motor delivers 11 kW at 1,450 rpm. Input torque T₁ = 9550 × 11 / 1,450 = 72.4 Nm. Through a 4:1 spiral bevel gear with η = 0.97, output torque T₂ = 72.4 × 4 × 0.97 = 281 Nm at 362.5 rpm.
06
Worked Example 2 — Full Drive System Calculation
Example Problem 2 — Industrial Conveyor Drive
Given: A conveyor drive uses a 15 kW electric motor at 960 rpm connected to a spiral bevel right-angle gearbox (efficiency η = 0.97). The bevel gear set has a ring gear with 36 teeth and a pinion with 12 teeth. Find: (a) the gear ratio, (b) the output shaft speed, (c) the input torque, and (d) the output torque.
Step 1 — Gear Ratio
i = N₂ / N₁ = 36 / 12 = 3.0 (3:1)
Step 2 — Output Speed
n₂ = n₁ / i = 960 / 3.0 = 320 rpm
Step 3 — Input Torque at Motor Shaft
T₁ = 9550 × P / n₁ = 9550 × 15 / 960 = 149.2 Nm
Step 4 — Output Torque (with efficiency)
T₂ = T₁ × i × η = 149.2 × 3.0 × 0.97 = 434.5 Nm
Summary
Ratio: 3:1 | Output speed: 320 rpm | Input torque: 149.2 Nm | Output torque: 434.5 Nm
Note on power check: Output power = T₂ × 2π × n₂/60 = 434.5 × 2π × 320/60 = 14.55 kW. This is 97% of the 15 kW input — confirming the η = 0.97 efficiency was correctly applied. Lost power (0.45 kW) appears as heat in the gearbox.

07
Pitch Line Velocity (PLV) Calculation — The Speed Parameter That Determines Gear Type
PLV Formula
v = π × d_m × n / 60,000
v = pitch line velocity (m/s)
d_m = mean pitch circle diameter (mm)
n = rotational speed (rpm)
d_m = m × N × cos(δ)
Mean pitch diameter
m = module (mm)
δ = pitch cone angle
Pitch line velocity is one of the most important secondary parameters derived from the gear ratio calculation. It determines whether a straight bevel gear is appropriate for the application or whether a spiral bevel gear is required. The threshold is approximately 5 m/s: below this, straight bevel gears are acceptable for many applications; above this, spiral bevel gears are the standard recommendation to achieve acceptable noise, vibration, and fatigue life.
For a quick PLV estimate without the full cone angle calculation, use the outer pitch circle diameter of the ring gear (d_o = m × N₂ where m is the module in mm and N₂ is the ring gear tooth count) as a conservative upper bound for d_m. This gives a PLV that is slightly higher than the true mean pitch line velocity, providing a conservative (safe) check for the speed threshold. If the outer PLV is below 5 m/s, straight bevel gears are safe to specify. If it is above 5 m/s, proceed with the full mean diameter calculation before finalising the gear type selection.
PLV example: M5 spiral bevel ring gear, 40 teeth, running at 360 rpm. Outer pitch diameter d_o = 5 × 40 = 200 mm. PLV_max = π × 200 × 360 / 60,000 = 3.77 m/s. This is below 5 m/s — a straight bevel gear would be acceptable at this speed. However, the spiral bevel form would still be preferred if noise is a consideration.
08
Compound Drive Systems — Multiple Gear Stages in Series
When a single bevel gear stage cannot provide the required total gear ratio — either because the ratio exceeds the practical single-stage limit of approximately 8–9:1, or because the drive requires a combination of gear types (e.g. a bevel gear stage for direction change followed by a spur gear stage for final ratio reduction) — multiple gear stages are combined in series. The total drive ratio of a series-connected gear train is the product of the individual stage ratios.
Compound Drive Formulas
i_total = i₁ × i₂ × i₃ × …
Total ratio = product of all stage ratios
η_total = η₁ × η₂ × η₃ × …
Total efficiency = product of stage efficiencies
The efficiency penalty for compound drives is significant: if a bevel gear stage at η = 0.97 is combined with a spur helical stage at η = 0.98, the total efficiency is 0.97 × 0.98 = 0.95 (95%). Adding a third stage at η = 0.98 would reduce total efficiency to 0.93 (93%). This cumulative efficiency loss is an important consideration when designing multi-stage gear drives — each additional stage not only adds cost and complexity but reduces the power delivered to the load.
09
Worked Example 3 — Two-Stage Compound Drive
Example Problem 3 — Bevel Gear + Spur Gear Compound Drive
Given: A drive system uses a motor at 1,450 rpm, 22 kW. Stage 1 is a spiral bevel gear (N₁=10 teeth, N₂=30 teeth, η₁=0.97). Stage 2 is a helical spur gear (N₃=18 teeth, N₄=54 teeth, η₂=0.98). Find: total ratio, final output speed, and final output torque.
Step 1 — Stage ratios
i₁ = 30/10 = 3.0 i₂ = 54/18 = 3.0
Step 2 — Total ratio
i_total = 3.0 × 3.0 = 9:1
Step 3 — Final output speed
n_out = 1,450 / 9 = 161.1 rpm
Step 4 — Total efficiency
η_total = 0.97 × 0.98 = 0.9506 (95.1%)
Step 5 — Input and output torque
T_in = 9550 × 22 / 1,450 = 144.9 Nm
T_out = 144.9 × 9 × 0.9506 = 1,240 Nm
Summary
Total ratio: 9:1 | Output: 161.1 rpm | Output torque: 1,240 Nm | Total η: 95.1%

10
Bevel Gear Differential Ratio — The Automotive Final Drive
In automotive applications, the term “final drive ratio” or “axle ratio” refers to the gear ratio of the ring-and-pinion bevel gear set in the rear (or front, or both) differential. It is calculated using the same formula: ring gear teeth divided by pinion teeth. However, it is always expressed as a decimal rather than in n:1 format — for example, 3.73, 4.10, or 3.31 rather than “3.73:1”.
The final drive ratio, combined with the selected transmission gear ratio, determines the effective overall drive ratio from engine to wheels. For a vehicle in a given gear, the total drivetrain ratio is the product of the transmission gear ratio and the final drive ratio. A vehicle in third gear (transmission ratio 1.52:1) with a 3.73:1 final drive ratio has a total drive ratio of 1.52 × 3.73 = 5.67:1 — for every 5.67 revolutions of the engine crankshaft, the driven wheels rotate once.
Automotive Ratio Example
Given: A rear axle hypoid differential has a 41-tooth ring gear and an 11-tooth pinion. Find the final drive ratio.
i = N₂ / N₁ = 41 / 11 = 3.727 ≈ 3.73 (the nominal axle ratio stamped on the differential cover)
Note: The slight rounding from 3.727 to 3.73 is standard practice for axle ratio identification. Always use the actual tooth count ratio for engineering calculations, not the rounded nominal value.
Common passenger car final drive ratios range from approximately 2.8:1 (economy-oriented, low engine speed at highway cruise) to 4.5:1 (performance-oriented, better acceleration from lower speeds). Off-road vehicles and trucks may use ratios up to 6:1 or higher for maximum torque multiplication at low speeds. When “regearing” a vehicle by installing a different ring-and-pinion set, the speedometer calibration must be updated because the wheel-speed-to-propeller-shaft-speed relationship changes with the new ratio.
11
Choosing the Right Bevel Gear Ratio for Your Application
The required gear ratio for any drive application is determined by dividing the input shaft speed by the required output shaft speed. This calculated ratio then guides gear pair selection within the practical constraints of bevel gear geometry.
Practical Limits of Single-Stage Bevel Gear Ratios
As the ratio increases beyond 1:1, the pinion becomes progressively smaller relative to the ring gear. At ratios above approximately 6:1, the pinion has so few teeth that tooth undercutting at the root becomes a design challenge, and the bore available in the pinion for the input shaft becomes very small. At ratios above 8–9:1, a two-stage gear arrangement is almost always more practical than a single-stage bevel gear set.
12
Worked Example 4 — Selecting the Correct Ratio from Application Requirements
Example Problem 4 — Mixer Drive Design
Given: A food mixer requires an output shaft speed of 85 rpm from a motor running at 1,450 rpm. The output shaft must deliver a minimum of 220 Nm of torque. What is the required gear ratio, what motor power is needed, and what tooth combination achieves a standard close-ratio bevel gear pair?
Step 1 — Calculate required ratio
i = n₁ / n₂ = 1,450 / 85 = 17.06
17:1 is too high for a single-stage bevel gear. Two stages required.
Step 2 — Split ratio across two stages
Stage 1 (spiral bevel): i₁ = 4.0 (pinion 10T, gear 40T)
Stage 2 (helical spur): i₂ = 4.25 (pinion 16T, gear 68T)
i_total = 4.0 × 4.25 = 17.0
Resulting output speed: 1450/17 = 85.3 rpm ✓ (within 0.4% of target)
Step 3 — Required input torque (working back from output requirement)
η_total = 0.97 × 0.98 = 0.9506
T_in = T_out / (i_total × η_total) = 220 / (17.0 × 0.9506) = 13.6 Nm
Step 4 — Required motor power
P = T_in × n₁ / 9550 = 13.6 × 1,450 / 9550 = 2.07 kW
Select 2.2 kW motor (nearest standard size above calculated requirement).
Solution
Two-stage drive: 4:1 spiral bevel + 4.25:1 spur helical. Motor: 2.2 kW at 1,450 rpm. Output: 85 rpm, 220 Nm delivered.
13
Common Bevel Gear Ratio Calculation Mistakes
14
Quick Reference Tables — Standard Bevel Gear Ratios and Tooth Combinations
Standard catalogue bevel gear sets are produced in defined tooth count combinations. The table below lists common combinations available in standard production, showing the nominal ratio, exact ratio, and the nearest whole-number deviation for ratio selection purposes.

15
Customer Reviews
“Needed a 3.73 ratio replacement for a Hilux rear axle at a remote mine site. Ever-Power confirmed the exact 41/11 tooth combination, supplied with full material certs, and had it to us in 4 days. The ratio calculation support was genuinely useful — the guys actually checked our PLV before recommending the gear type.”
— Keith Thorburn
Fleet Maintenance Coordinator, Goldfields WA
“I designed a new conveyor drive and needed a 5.5:1 ratio spiral bevel stage. Sent Ever-Power the speed and torque requirements and they came back with the tooth combination, module, and face width recommendation within 24 hours. Custom manufactured to our drawing. Perfect first article.”
— Simon Partridge
Mechanical Design Engineer, Bulk Materials, SA
“Converted our vehicle to a 4.56 ratio for serious off-road work. Ever-Power found the 41/9 combination that gives 4.555 actual ratio — close enough. They also advised me on the speedometer recalibration. Very thorough service, not just a gear seller.”
— Jason Villanueva
Off-Road Enthusiast & Workshop Owner, QLD
“Our OEM gearbox had a 6.8:1 bevel stage and the original supplier was no longer trading. Most places said it was too high for a standard gear and wanted us to redesign. Ever-Power machined a matched set from scratch using our worn sample dimensions. Exactly 6.8:1, delivered in 3 weeks.”
— Priya Menon
Maintenance Manager, Pharmaceutical Packaging, VIC
16
FAQ — Bevel Gear Ratio Calculations
Common questions answered by Australia Ever-Power’s engineering team.
Australia Ever-Power · Condell Park NSW 2200
Need a Custom Bevel Gear at a Specific Ratio?
Provide your input/output speed requirements and we will specify the tooth combination, module, and material — and manufacture the matched pair.