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Rear derailleurs explained

This post explains important facts about bicycle rear derailleurs. From construction and parts, to important characteristics such as chain wrap capacity etc.

If you have any questions (or additions and corrections), please use the BikeGremlin forum:
www.bikegremlin.net

Table Of Contents (T.O.C.):

  1. How does the bicycle rear derailleur (RD) work?
  2. Rear derailleur bicycle frame mounting
    2.1. Hook type rear derailleur mount
    2.2. Standard mount rear derailleurs (RDs)
    2.3. Direct mount rear derailleurs
  3. Standard vs “rapid rise” rear derailleur
  4. Derailleur capacity – cage length
  5. Max sprocket size limit
  6. Number of speeds, compatibility


1. How does the bicycle rear derailleur (RD) work?

Rear derailleurs (often refferd to as RD) are used on bicycles with external gearing and multiple sprockets at the rear hub. They work on a simple, brute force principle: moving the chain sideways, until it slips off a sprocket onto the adjacent one.

This derailleur movement is usually operated via shifters (shifter levers), that are located on the bars (or somewhere at hand). Shifter cable is attached to shifters at one and and at the derailleur at the other end.

It consists of a metal cage and a spring. The spring moves derailleur to one side when the shifter cable is released, while the shifter cable, when pulled, moves it to the opposite side. It also has jockey wheels on a cage, with a spring, used to pull extra chain when changing to different sprocket sizes, so it doesn’t fall off.

1. The upper area on the derailleur is the b-knuckle. 2. On Shimano and SRAM derailleurs, the b-tension adjuster fine-tunes the height of the guide pulley. On Campagnolo derailleurs, the adjustment is done via a screw near the p-knuckle. 3. To adjust cable tension, use the barrel adjuster. 4. The guide pulley keeps the chain in line as it moves from cog to cog during shifts. 5. The idler pulley helps hold tension on the chain regardless of gear choice. 6. The mounting bolt connects the derailleur to the frame. 7. The parallelogram linkage lets the chain move left and right and up and down the cassette while remaining parallel to the cogs. 8. High and low limit stops are usually found near the b-knuckle but sometimes on the front of the parallelogram. The low limit (often marked L) prevents shifts into the spokes; the high limit (marked H) prevents the chain from dropping off the smallest cog. 9. The p-knuckle holds both the guide pulley and a spring that keeps tension on the cage to hold the chain taut. Shimano’s XTR Shadow Plus (for mountain bikes) has a switch that increases spring tension and activates a friction stabilizer to keep the chain from bouncing in rough terrain. 10. The cable bolt pinches the shift cable in place. On most derailleurs, when the shift lever pulls on the cable, the derailleur moves up the cassette to a lower gear. The exception: Shimano’s low-normal derailleurs, on which it does the opposite. 11. The cage keeps the chain in line between the pulleys.
1. The upper area on the derailleur is the b-knuckle.
2. On Shimano and SRAM derailleurs, the b-tension adjuster fine-tunes the height of the guide pulley. On Campagnolo derailleurs, the adjustment is done via a screw near the p-knuckle.
3. To adjust cable tension, use the barrel adjuster.
4. The guide pulley keeps the chain in line as it moves from cog to cog during shifts.
5. The idler pulley helps hold tension on the chain regardless of gear choice.
6. The mounting bolt connects the derailleur to the frame.
7. The parallelogram linkage lets the chain move left and right and up and down the cassette while remaining parallel to the cogs.
8. High and low limit stops are usually found near the b-knuckle but sometimes on the front of the parallelogram. The low limit (often marked L) prevents shifts into the spokes; the high limit (marked H) prevents the chain from dropping off the smallest cog.
9. The p-knuckle holds both the guide pulley and a spring that keeps tension on the cage to hold the chain taut. 
10. The cable bolt pinches the shift cable in place. .
11. The cage keeps the chain in line between the pulleys.


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– T.O.C. –


2. Rear derailleur bicycle frame mounting

There are three standards of rear derailleur attachment:

  1. Hook type (derailleur has a built in hook).
  2. Standard mount (frame must have a point for screwing the derailleur onto – derailleur hanger).
  3. Direct mount (a modern version of the standard mount, basically)

Which one of these derailleur mount types is used, depends on the frame rear dropout type:

Rear dropout without derailleur hanger - requires derailleur with a built in hanger.
Rear dropout without a derailleur hanger – requires a derailleur with a built-in hanger
Rear hanger with derailleur hanger built onto the frame.
Standard mount derailleur hanger built onto the frame
(Vertical) rear dropout, with mounted (replaceable) derailleur hanger.
(Vertical) rear dropout, with a mounted (replaceable) standard mount derailleur hanger

– T.O.C. –


2.1. Hook type rear derailleur mount

These RDs have a mounting hook built in, enabling them to be mounted on frames without any RD mounts.

Hook type mount rear derailleur.
Hook type mount rear derailleur
Back side of a hook type rear derailleur mount.
Back side of a hook type rear derailleur mount

In practice, they can often be mounted even on frames with a standard RD mount, if the frame’s standard mount doesn’t get in the way (either when mounting or during RD’s movement later on).

The way of mounting this derailleur type is shown in the pictures below:

Front side of a hook type rear derailleur frame attachment.
Front side of a hook type rear derailleur frame attachment. Bolt for fastening it once it is inserted is visible
Sliding a hook mounted rear derailleur inside a rear wheel dropout.
Sliding a hook mounted rear derailleur inside a rear wheel dropout
Hook type derailleur pushed all the way into the dropout. Ready for tightening the bolt to keep it firmly in place.
Hook type derailleur pushed all the way into the dropout. Ready for tightening the bolt to keep it firmly in place

– T.O.C. –


2.2. Standard mount rear derailleurs (RDs)

These RDs are screwed directly into a mount on the frame. But don’t mistake this type of RD for a direct-mount type.

Screweing a direct mount rear derailleur onto a frame (which has a hook with a threaded hole for screwing the derailleur onto).
Screwing a standard mount rear derailleur onto a frame (which has a hook with a threaded hole for screwing the derailleur into)
Direct mount rear derailleur.
Standard mount rear derailleur
Back side of direct mount rear derailleur. Threads of the screw for attachment are visible - it is screwed directly into the frame (which has a hook and cut threads for screwing derailleur in).
Back side of a standard mount rear derailleur. Threads of the screw for attachment are visible – it is screwed directly into the frame (which has a hook and cut threads for screwing derailleur in)

– T.O.C. –


2.3. Direct mount rear derailleurs

In 2012, Shimano decided to move the rear derailleur a bit further to the rear. 🙂 And so the “direct mount” RDs were born. Why?

  • This rearward movement allowed for easier rear wheel removal/installation. RD no longer needs to be pulled back, out of the way.
  • Also, this enabled the RD to be tucked a bit closer inwards, i.e. not sticking out so much, protected from impacts. Hence Shimano named this new type of RDs “Shadow” (kudos to their marketing team).

These derailleurs require a compatible direct-mount frame mount.

Direct mount rear derailleur mounted on a direct-mount frame mount
Direct mount rear derailleur mounted on a direct-mount frame mount

However, these RDs can also be mounted on a standard mount, if a “b-link” is used:

A direct-mount rear derailleur mounted on a standard hook, using a b-link
A direct-mount rear derailleur mounted on a standard hook, using a b-link

This drawing from the Shimano website nicely explains it:

A direct mount RD mounted on a standard mount using a b-link (left), and on a direct-mount (right)
A direct mount RD mounted on a standard mount using a b-link (left), and on a direct mount (right)
Source: shimano.com

To reiterate:

  • Standard mount RDs can’t be fitted on a direct mount hanger.
  • Direct mount RDs can be fitted on a standard mount hanger if a b-link is used.
  • Direct mount RDs are fitted to direct mount hangers without a b-link (i.e. directly).

– T.O.C. –


3. Standard vs “rapid rise” rear derailleur

Most rear derailleurs have a spring pushing them outwards. When shifter cable is released, the derailleur moves outwards, towards the smaller sprockets. When shifter cable is pulled, movement is reversed – towards the wheel, bigger sprockets. This way of functioning is called “high-normal“, or “top-normal“.

Shimano Rapid Rise“, also called “low-normal” derailleurs work the opposite way: spring pushes them towards the wheel, while pulling shifter cable moves them towards smaller sprockets. Same shifter levers can be used for both standards. If a shifter lever has gear indicator, if a rapid-rise is put instead of standard (or vice-versa, for rapid rise shifter levers), indicator will show “upside-down”. But shifting will work correctly.

– T.O.C. –


4. Derailleur capacity – cage length

Derailleur capacity is a number of tooth difference between front and rear sprockets that the derailleur can compensate. When chain is put on the largest chainring up front and the largest sprocket, the chain needs to be long enough to wrap. Then, when chain is placed on the smallest sprocket at the rear and smallest chainring, there will be a lot of “extra” chain length that rear derailleur pulleys must “gather”, to keep the chain tensioned. These are both extreme combinations, with worst cross chaining, so not recommended in practice.

So manufacturer chain capacity data can be taken with some liberty, if the user is experienced and careful, never using extreme combinations.

Derailleurs come in three sizes: short, medium and long cage. Derailleur capacity is proportional to cage length. For wide range MTB cassettes with three front chainrings, it is practical to have a long cage derailleur.  A typical narrow ranged road cassette and two front chainrings will make do with a short cage derailleur.

Shimano notes RDs as: SS (short cage), GS (medium cage) and SGS (long cage).

Example: if a bicycle has a crankset with 48-38-28 teeth, and a cassette that ranges from 11-32 teeth, then a needed RD capacity would be:

(48-28) + (32-11) = 20 + 21 = 41
This would take a long cage RD with over 40 teeth capacity

For a typical road bike setup with 53-39 crankset and a 11-25 cassette:

(53-39) + (25-11) = 14 + 14 = 28
A short cage RD with under 30 tooth capacity would suffice.

With 1x drivetrains, you only calculate the difference between the largest and smallest rear sprocket tooth count (since there’s only one chainring at the front, of course).

See here about: what if RD’s chain wrap capacity isn’t big enough?

– T.O.C. –


5. Max sprocket size limit

Apart from RD capacity, an important characteristic of a RD is the maximum number of teeth of the biggest rear sprocket that RD can handle. For short cage road bike RDs, this is usually about 25, or 28, while long cage MTB ones often enable use of 32, 34, or even more teeth at the cassette.

– T.O.C. –


6. Number of speeds, compatibility

A series of posts explaining what can be combined with what: Compatibility

MTB rear derailleurs from 6 to 9 speeds, and road RDs from 6 to 10 speeds are interchangeable and compatible. Slight difference in jockey wheel thickness is not a problem – a 6 speed RD will work on any number of speeds – up to 9 with a MTB and up to 10 with a road bike. It is the same ratio of derailleur cage movement per cable movement, so the shifter levers determine the movement and the number of “speeds”.

10 and 11 speed MTB derailleurs, as well as 11 speed road bike derailleur are not interchangeable. Different cable pull ratio and parallelogram movement for each. There are exceptions from these rules, so if some combining (mix-matchin) is planned, it is best to first read the post about bicycle rear derailleur compatibility.

If shifters used are indexed, shifter mechanism determines the amount of cable pulled for each gear, with each shifter click. So rear shifter compatibility needs to be accounted for. There is a difference in cable pull ratio for Campagnolo, SRAM and Shimano. That is why a SRAM rear derailleur will not work properly with indexed Shimano shifters (and vice-versa). With friction shifters (those that don’t have a click for each gear), this is not an issue.

So, one could say that if using indexed shifters, they will work as long as the RD is by the same manufacturer as the shifters. Though, apart from Campagnolo and SRAM, most other manufacturers are compatible with Shimano.

If you have any questions (or additions and corrections), please use the BikeGremlin forum:
www.bikegremlin.net

– T.O.C. –



The existing comments posted under this article (questions and answers) have been moved to this BikeGremlin forum thread:
https://www.bikegremlin.net/threads/rear-derailleurs-explained-article-comments.136/

20 thoughts on “Rear derailleurs explained”

  1. I am currently running with 3×9 setup. Planning to go 1×11 with shimano m5100. Is it okay if I use slx11 speed shifter? And also

    2) shimano m5120 description is that 1×10 or 2×11. Is it okay if If I run it 1×11?

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