Gear Ratio Climbing Calculator

Gear Ratio Climbing Calculator

Estimate gear inches, development, cadence-based climbing speed, target cadence, and crank torque demand from chainring teeth, cassette cog, wheel size, tire width, grade, rider weight, crank length, and target speed.

🚲Drivetrain climbing presets
Calculator inputs
Front chainring tooth count. Smaller rings lower the climbing gear.
Rear cog tooth count. Larger cogs reduce gear inches and torque at the crank.
The calculator adds tire height to bead seat diameter for effective rolling diameter.
A wider tire raises effective diameter slightly and changes development per pedal rev.
Pedaling cadence used to estimate climbing speed in the selected gear.
Road or trail slope. Torque demand rises almost linearly with grade on steep climbs.
Include rider, bike, water, racks, bags, tools, and cargo.
Longer cranks reduce pedal force for the same crank torque, but do not change gear inches.
Used to estimate required cadence, power, and torque demand on the selected grade.
Sets rolling resistance used in the torque demand estimate.

Gear ratio climbing estimate

Gear inches
0 in
effective wheel diameter x gear ratio
Development
0 m
distance per crank revolution
Climbing speed
0 mph
from selected cadence
Torque demand
0 Nm
crank torque at target speed
📋Gear and climb spec grid
18-22
Low gear inches for loaded climbs
24-28
Common gravel climbing range
60-85
Typical climbing cadence rpm
95%
Drivetrain efficiency used
📊Drivetrain preset reference
PresetGear comboWheel and tireBest use
Loaded bikepacking30 x 4229 x 50 mmModerate loaded dirt climbs
Gravel compact34 x 34700 x 40 mmAll-road climbing with light bags
Road endurance34 x 32700 x 28 mmPaved mountain roads
MTB trail32 x 5029 x 61 mmSteep singletrack and rough pitches
Cargo touring38 x 4627.5 x 56 mmHeavy loads and utility bikes
Sub-compact gravel30 x 36700 x 45 mmSteep gravel with lighter cargo
Rando triple low26 x 34650b x 42 mmClassic low touring gear
Mullet adventure38 x 5229 x 55 mmWide-range drop bar adventure
City hill gear42 x 36700 x 38 mmUrban climbs without big luggage
🛞Low gear inch guide
Gear inchesClimbing feelTypical setupPlanning note
Under 18 inVery lowMTB or expedition gearingUseful for heavy loads, rough grades, and very slow cadence control
18-22 inLowBikepacking or cargo touringGood target for steep dirt climbs with loaded bags
23-28 inModerate lowGravel compact or touring doubleWorks for fit riders on moderate paved or firm gravel climbs
29-34 inRoad lowCompact road drivetrainCommon on endurance road bikes, but hard with cargo on grades above 10%
35 in and upTall for climbingStandard road or city gearingBetter for rolling terrain than sustained loaded climbing
🔁Wheel size and tire diameter reference
Wheel sizeBSDExample tireApprox outside diameter
700c road622 mm28 mm26.7 in / 678 mm
700c gravel622 mm45 mm28.0 in / 712 mm
29er MTB622 mm61 mm29.3 in / 744 mm
650b gravel584 mm47 mm26.7 in / 678 mm
27.5 MTB584 mm56 mm27.4 in / 696 mm
26 in MTB559 mm50 mm25.9 in / 659 mm
Climb torque planning table
Grade bandWhat dominatesTorque cueGearing response
3-5%Aero and rolling still matterUsually cadence-limitedPick a gear that keeps normal spin
6-8%Gravity becomes primaryModerate seated torqueLow road or gravel gear helps
9-12%Gravity dominatesHigh torque for heavy ridersLoaded bikes benefit from 18-25 gear inches
13-18%Traction and balance matterVery high torque spikesUse MTB-range gearing and steady cadence
Over 18%Starts and wheel grip matterPeak torque can exceed sustainable rangePlan a bailout gear or walking pace
Cadence and development speed table
Development60 rpm75 rpm90 rpm
1.4 m/rev3.1 mph3.9 mph4.7 mph
1.8 m/rev4.0 mph5.0 mph6.0 mph
2.2 m/rev4.9 mph6.2 mph7.4 mph
2.6 m/rev5.8 mph7.3 mph8.7 mph
3.0 m/rev6.7 mph8.4 mph10.1 mph
💡Climbing gear calculation tips
Use the loaded system weight: torque demand depends on total climbing mass, so include racks, water, food, locks, tools, bags, and cargo instead of rider weight alone.
Compare target cadence: a gear may look low on paper but still force a very slow cadence at your target speed on steep grades.

When choosing climbing gear for a bicycle, the gear must be chosen based off the type of terrain and the strength of the riders leg. On a steep grade, a gear that allow for a steady pedaling rhythm is best for riders. A slow cadence for the pedals increases the torque that is placed into the crank of the bicycle.

Additionally, the high level of torque that the climb creates will determine whether or not the climb with the bicycle is difficult to ride. The calculator require the riders to enter several parameters of their bicycle for the calculator to determine the math for them. The parameters include the chainring size, the cassette cog size, the wheel size, the tire width, the total system weight of the bicycle and the rider, the crank length, the target speed, the target cadence, and the grade of the climb that is to be ridden.

How to Choose Bike Gears for Climbing

A bike and rider that is heavier than others will require more force to be pulled backwards on the terrain that is being ridden by the bicycle. A crank that is longer than others will require the rider to place more force into the pedals to produce the same amount of torque. A tire that is wider than others will change the diameter of the wheel, which will change the gear inches and the development of the bicycles current setup.

Gear inches allows for the comparison of different setups for the bicycles with different wheel sizes. The calculator calculates the gear inches by multiplying the diameter of the wheel by the gear ratio. A lower number of gear inches will require less force to be used to move the bicycle upwards on the terrain.

Development is another metric for measuring the distance that the bicycle travels in relation to the number of revolutions of the crank. This is used by roadies and those who ride long distances on there bicycles. Both gear inches and development is provided to the riders to allow for comparisons of their bicycles specifications.

The torque demand for a bicycle can be calculated to show how much effort the rider must produce in order to maintain the speed of the bicycle. A gear may look good on paper, but the torque demand may be extremely high for the rider at the specified target speed on the chosen grade. The effect of gravity on the bicycle is shown in the value of the torque demand.

The effect of the rolling resistance of the bicycle is also adjustable in the calculator. The rolling resistance factor will impact the number that is calculated for the required torque for the bicycle. The torque demand will provide a measurement of the mechanical work for the bicycle before the rider becomes fatigue.

Cadence, gear inches, and torque demand is directly related. A very low gear can create a slow cadence if the target speed is set to be low. A slightly taller gear will allow the riders crank to create a more natural spin at the target cadence.

The calculator will show the cadence that is required to achieve the target speed with the gear that is chosen for the bicycle. Additionally, the calculator can show the difference between the required cadence of the pedals and the cadence that is currently entered by the rider. This will allow the rider to understand whether or not the cadence will feel natural when ridden.

Terrain features have many different impacts on the bike and rider system. For example, a short steep climb may indicate that a bailout gear is needed for that particular ride. The loaded weight of the bike will require more strength from the rider to propel the bike upwards on the grade.

The total system weight includes any additional load on the bicycle, such as bags or water containers. The total system weight has to be used to ensure that the rider does not under estimate the total weight of the bicycle that is to be ridden. Wheel and tire sizes can have many effects on the performance of the bicycle.

For example, a wider tire can allow for increased comfort in longer rides, but may increase the rolling resistance of the bicycle. Additionally, a wheel diameter that is smaller than the standard wheel size will reduce the development of the bicycle with the same gear ratio. Some riders may want to use 650b wheels with a wider tire to distribute there body weight more evenly over the tires.

The calculator allows modifications to be made to the size of the wheel and tire width of the bicycle. However, other decisions include frames and the type of terrain to be ridden. Riders of bicycles can make many mistakes with their chosen gear ratios and settings.

For example, some may choose the lowest gear on the bicycle to maximize their pedaling speeds on flat terrain. Other individuals who may choose the gear ratios and specs for road cycling may not have enough strength in their legs to overcome the high torque demands of the climbs; they may have to walk most of the way uphill on their bicycles. A good gear allows a rider to maintain a cadence that is comfortable for that individual with their strength of their legs.

The tables provide information that can be immediately compared to the raw calculations of the bicycle. The tables show the gear inches ranges that are experienced with the bike loaded or unloaded. The tables also show the relationship between the size of the wheel and the outside diameter of the wheel.

Additionally, the tables show the effect that the terrain grade has on the terrain. The raw calculations will be more useful when compared to the data in these tables. The goal for the bicycle and rider is to understand the relationship between the numbers and the effort that will be required to ride the bicycle up the specified terrain.

The calculator cannot replace the feel of the terrain while on the bicycle, but it will eliminate the guesswork in creating gear specifications. Through using the bicycle gear specification calculator and the information provided within the calculator, the rider will have a complete understanding of the terrain that lies before them on there ride.

Gear Ratio Climbing Calculator

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