Why It's Impossible For Steel Frames To Be More Comfortable Than Aluminium

It's annoying I know, but the reason I'm hoping to build a Patreon audience is that UA-cam pays about $10 per 10,000 views! When I put 100+ hours into a video like this my hourly rate is, no joke... 20 cents. 😂 If you think this bike knowledge is worth more than 20c per hour, consider supporting the channel here: www.patreon.com/cyclingabout

Great video. I love steel bikes, not just for their supposed comfort, but I agree with everything he said. Tire width and pressure matters far more than anything else for bump absorption.
After a lifetime of futzing with bikes, including working as a mechanic, I think that most of what bike nerds obsess about just doesn't matter (unless you race bicycles to earn a living). The older I get, the less fussy I am about parts, and the more I enjoy just riding.

But.... steel is the only frame material rhyming with “real”. 🙂🙂

I clicked on the video with an attitude: “Oh yeah? Change my mind!” Well, thanks for changing my mind! You have a great way of stripping away the hubris and spookiness and bringing science to the forefront. 👏

Something not explored in this video is the frequency range of vibrations; they cover a spectrum depending on road surface and what obstacles you encounter. With similar setup when riding on the roald, I've always had the unmistakable impression that steel damps the higher frequency vibrations better than carbon resulting in a more velveting road feel that I simply haven't experienced on a carbon bike.

I'm glad you went and put some numbers and tests to this. The conclusion also feels pretty correct. I changed from a 700 28C to a 29er MTB and the comfort I get from these BIG tyres make much more of the difference, also the seat post and saddle, play in that equation.

Thanks for the informative video. You inspired me to buy a Brooks B 67 saddle for my Cube travel bike. I remember how comfortable my English 3 speeds were with their sprung Brooks saddles. After so many years on 23c tires, I am also loving the 2.2's tires. I can run the pressure down to 30 psi and they still roll great and give a soft ride. I have also started running 25c's on my Giant TCR. I guess as I get fatter, so do my tires

Great video, but forgot to introduce the advantage heavier frames have in terms of comfort simply due to higher inertia. It's the same when you attach bottles and bags to your bike--it becomes more comfortable to ride because the bike simply can't rattle you as much as lighter bikes can. This is probably one reason for why people believe steel bikes are more comfortable. They may be, but not if you compensate for the weight difference, for example by attaching weights to a carbon frame.

I love that you present actual data!! And this analysis also corroborates what I’ve been spouting for years: if you want comfort, ride a fat bike 🤣🤣

pure worthy content without any bloat! What a simple cure for today's overabundance of drivel and hot air just to be heard. Keep it up because the point is sharp.

Thank you so much for using the correct terminology!!!!! It's a pleasure watching your videos and analysis. Very thorough and concise. A+

I actually started road riding on that EXACT same steel trek (my dad's old bike), then 20ish years ago when I finally bought a modern GURU road bike with aluminum lugs and carbon tubes the difference in stiffness was MASSIVE (the carbon bike had what felt like absolutely zero flex or peddle bob and my feet would go numb from road vibrations...it made the steel trek bike feel like a full suspension bike!). So I'm not sure how much I really agree with the results here, at least my interpretation of them...

I've known for a long time that changing your seat post to say carbon, can make a stiff uncomfortable bike less taxing to ride. Thanks to you now I know why.... great video.

I am currently resurrecting my 1998 Surly Karate Monkey. Owning 12 bikes, and gone through Alum, to Titanium, to Carbon, now making my way back to the Safety of Steel. Only a couple pounds more weight, but a TON more reliability.

Great video. Keep it up. Educational videos like this make the world smarter. That in turn makes the world a better place. Cheers!

You're looking at a short lever inserted into a long truss (seat-post into seat tube), the point you're missing here is on the other side of the frame. The long lever inserted into the short truss member (the fork into the head tube). The majority of deflection and bump attenuation is going to occur at the front of the bike. The fork reacts to a bump (regardless of the fork material) and transfers this up to the head tube. There's much more force at this location because of the long lever (the fork), the way the head-tube takes this deflection and transfers it through the frame is going to play a big part in ride feel and quality. Its a simple matter of material science that aluminum has a more tightly packed structure (google images of aluminum structure and steel). Steel has a much looser packed structure and will in fact allow vibrations to smooth out through the material. These micro vibrations make all the difference.

I think most of it comes from when aluminium bikes were fairly new. I am old enough to remember. I had a Bridgstone RB1 (a now legendary frame) and I could feel a little bit of flex in the bottom bracket when I'd sprint or stand to climb. In 1991, I bought a new Cannondale and the ride was very different. It was much more harsh, but there was no detectable flex in the bottom bracket. I loved that bike even though the stiff frame combined with the high pressure 18c and 20c tires brought a very jarring ride. Aluminum design has greatly improved since then but the image has not for a lot of people

Food for thought. I have steel frame Surly fatbikes, and love them for a number of reasons. I agree that tire size and pressure will always be a dominant factor in comfort and performance. Tires are your (or part of) your suspension, even in a car. I’d say this data is most focused at road bikes, where the tires are small and high pressure.

I'm new to cycling and thinking about building a bike...found your vid really informative

Awesome to see someone approach this sort of question with some real research and data instead of marketing buzzwords and biased impressions. Subbed.

Very informative regarding frame comfort! I'd be interested to see a comparison in fork materials as that relates to comfort (aluminum vs. carbon vs. titanium vs. hi-tensile steel vs. chromo steel). My guess is that a chromo steel or carbon fork will be more comfortable than an aluminum fork, assuming constant handlebars and thin tires.

I've tried steel, carbon, aluminum, titanium, and looked at trying magnesium alloy. Honestly, I haven't felt a difference outside of the stance, ride position, and tire width. I ride steel now on both my hardtail and my gravel bike. The only reason I do this is price. Steel frames are so much cheaper to find and build, giving me more money to spend where it really counts. I'm not a weight weenie, I would rather have a comfortable ride over a particularly fast one. Great video! glad I was not the crazy one who couldn't feel a difference in frame material.

Good info. I find that I change body position significantly if on rougher terrain. It is easier for me to absorb rough terrain on my gravel bike than my "cruiser", but also tires me out (pun intended) faster on my gravel bike.

Thanks a lot. This was very useful information. Kind of supports the approach I have taken with my latest bike addition. A relatively inexpensive aluminium gravel bike where I swapped out the stock tires for wider ones and also installed a suspension seat post. Resulted in a quite comfortable ride feel.

Totally agree, I always laughed a 'Frame Ride' reviews, when what the 'Princes & the Pea" reviewers were actually telling you about were the stock speced tires.

I have ridden several mid 90's steel mountain bikes that were very stiff feeling (as much as an Alu bike feels to me). And I've also ridden an early 2000's On-One Inbred (a cult british, taywan made steel hardtail with thin tubes, a long top tube geometry and Dekerf style fork rear stays).
The Inbred has always felt noticeably less harsh on the trail when compared with the thicker tubed, shorter "triangled" bikes of the 90s.
I've always felt that the zingy feel of the On-One comes from the frame twisting "sideways" relative to the vertical plane as opposed to the vertical movement you are focusing on in the video.
My intuition attributes this extra flex to: thinner walled tubes (they bend more easily), smaller diameter tubes (also bend more easily) and a significantly longer top tube (triangles with longer sides, twist more).
As concluded in the video It is not surprising that a structure that has its maximum strength in the vertical direction does not deform a lot in that direction.
BUT, when riding a bike in the real world, the purely vertical loads are far from being the only forces that define how a bike feels, especially when the bike is tilted/leaned on by the rider and goes around corners and the wheels hit obstacles and bumps that impart lateral forces on the wheels.
These more "lateral twisting" forces are probably way more important to ride feel and comfort than the vertical ones. (precisely because most frames are designed precisely to guarantee they are very strong in this direction. For the counter point consider something like the Slingshot mountain bikes of the 90s, the ones where the down-tube was a tensioned cable. Look at the lateral flex on those bikes!)
Don't forget that all key components that are in between the force "origins" and the frame are nowadays typically very stiff. Namely: the rims, hubs and spokes, the fork, the pedals, cranks and bottom bracket.
Also don't forget that most frames nowadays (even steel ones) are built to be very laterally stiff, because this is a sort of assumption by manufacturers that stiffness is a desirable property in general. This is a symptom of the influence of road bike racing (the stiffer the less energy is wasted) and of mountain bike design where in the last few decades everything from handlebar diameter, to fork stanchions, to head tubes to axle diameters became oversized in the quest for more stiffness.
I'd love to see new tests done by applying a twisting force via a lateral load to the front view axis of the steered tube for example (with the rear dropouts affixed to a solid stand).
I do reckon such tests would show that this torsional frame stiffness is more dependent on the actual tube specs and frame design, than the materials per se.
These are just the ramblings of a non-engineer that has been riding bikes for 40 years. So take that as you will :P

That was genuinely very interesting. Thank you.

Very cool! I think something to take into account that isn’t talked about in the video is that often times aluminum or carbon frames have oversized (diameter) seat post where is steel frames often have 27.2 or smaller diameter posts. Obviously the narrower seat post will deflect more and while this doesn’t necessarily make steel more compliant then aluminum, our perception of it while riding is that it is more compliant.

I am not scientist but I personally feel steel more comfortable-specifically because I have 2 bikes one a steel and one Alu-frame. It depends on the style on frame.Alu frame can only “flex” one time😂

Thanks for the effort making this video.I have both steel and aluminium frames hardtail and I cannot tell the different, but have always thought I am not good enough to feel the different. The video pretty much explains well for vertical compliance. I bet there will be huge arguments over whether this is true or not in the comment section. Though, it's good that we keep thinking, making more connection in your brains.

Thank you, great detail. Nothing like your video's on the internet. Fantastic work, thank you again very much.

With this video we went waaay deep into the rabbit hole of geeky, in-depth analysis... I love it! Well done! It's been a long time, after many years of following bike tech, that I've actually learned something new! Interesting subject and approach!

There was a study a few years back on fatigue to feet and legs, which included micro-injuries caused by vibrations and shock. The cumulative damage and fatigue can be very substantial in some situations (long off-road touring, for example).
I have bikes made of different materials and designed for different purposes. I've noticed a lot of compliance - but not VERTICAL compliance - in some of the steel frames. It is more like torsional compliance. I can feel a major difference going over sharp bumps and rough surfaces at times.
It's the sort of flex you can experience when you're off the bike, and putting one foot on a pedal at the six o'clock position, and then repeatedly applying a lot of your weight to that pedal, especially when the bike is held at an angle away from you. Other things are flexing also, but the frame flex is very substantial in some bikes when doing this.
I haven't thought much about how this plays out while riding, but I have noticed a "spring" in some steel frames that is other than vertical, and yet very attractive. It makes for a lively, desirable, and more comfortable ride.

Very strong position using sound principles in mechanics. Would be interesting to hear how the opposing view would refute this strong data. Thanks for the video!

Nice to see some actual data and science being compiled. Even if you would be wrong, you got a well deserved like and a subscribe for going with a more rational approach. Thanks and keep it up!

I guess this could be the reason I settled on Brooks Cambium saddles for my bikes, more vertical compliance in those than tyres or seatposts.

My most favorite mountain bikes I've owned were cro-mo and they both rode smooth and beautiful but after watching this video now i believe it was more to do with the geometry than anything else. Both of the Steel bikes fit me perfectly but all the alloy frames I've had a shorter top tube for a similar seat tube. I have a carbon seat post in my steel bike now and when i checked bugger its got a fair bit of flex. So now I think a carbon post and good geometry are more important that light weight materials.

I'm 57 and rode as a cycling messenger in NYC for 15 years. From my own experience steel really is real.

Very informative. I hope to see more videos like this from you.

Excellent video that brought me back to my mechanical engineering studies (I was waiting for 1/k1 +1/k2=1/k). I will invest in a flexible seat post for my new steel gravel bike with large tires 😊

Is the fork considered not part of the frame? On many vintage bikes you can see the fork flex if you pull the front brake and try push the bike forward. How about vibration dampening? Sorry but the seatpost flex test seems too simplistic to paint the whole picture. Youre correct that tyres and saddle etc play a huge role though, not arguing that.

The problem with the theory of vertical springs in a perfectly vertical plane is that when you ride a bicycle, your bike is not - probably rarely completely vertically aligned to the ground. That being said, the bicycle is absorbing bumps not as they are in a lab (perfectly vertical), but when the bike is ever so slightly tilted. Also, if you are claiming that because the lab could not show measurable differences, that would fly in the face of your preference for the resonance damping characteristics of carbon frames since it isn't measurable.
In fact, the minuscule differences between the resonance damping effects of certain tube designs are added up among millions of vibrations that occur over long timeframes when you are on the bike. Those can be felt by the rider. Those millions of vibrations while the bike is slightly off a vertical plane. Bikes are pedaled, not run by a motor, so you have the motions of balance at play, throwing the bike at an angle while transferring road jarring which I am not so sure the science has tested for.

Thanks for the video. For years I have been unable to tell the difference, but felt that I should have, given opinions out there in the cycling universe. Thanks for letting me know that I am not (completely) insane.

I like your videos! Keep up the GREAT work. I've been wanting to do my first thousand mile ride around lake Michigan.

Thanks for this.
Always wondered at what point frame material made no difference. 40mm tyres seems that point for yourself, interesting to know.
(I'm riding aluminium frame, 35mm tyres, redshift suspension stem, redshift suspension seat post (recent addition))

I’ve gone from steel to aluminium to carbon to aluminium and recently back to steel I will never go back to anything else again

Love your practical and real world usable content!
If you have affiliate links let me know!

This was great information, thank you!

In terms of comfort, I would suggest saddle choice can make a large difference as well. The more your saddle conforms to your shape and distributes the load out to your contact points, the more comfort you will have. I've ridden Selle SMP saddles for years, even though they are ugly as sin, because they fit me better than other saddles and have made a huge difference in comfort.

I bought a very expensive Ti frame and it’s amazing how smooth it is. I think you forgot to consider how much it helps if you riding on a cloud of hundreds. 😉

I'm an xc rider since from the start, but since following this channel, I'm so inspired to build touring bike. 🚲🚲

Very interesting stuff. Thank you.

I think when they're comparing steel, titanium, aluminum and carbon in terms of comfort, they refer mostly to vibrations that are transmitted through the frame material and not visible or measurable flex. The way the frame resonates does give a slightly different 'feel' to the bike, but you have to know how to distinguish it.

I've owned/ridden steel, aluminum and carbon, and I can't tell the difference. I have never experimented with seat stems. In my experience it's tires that make the most difference.

This came up on my feed, and based on recent experience, I concur. I'll explain.
For many years (38 to be exact), I've had a Marukin M420 road bike. I recently had it overhauled by my LBS, which put on 27x1 1/4" Panaracer Pacela ProTite tires on it. ProTite is Panaracer's puncture protection system; it's implemented by an extra band of material between the tire tread and the carcass. Because of the ProTite protection, the tire has a rougher ride. I feel almost all road imperfections, including the individual stones in the pavement.
OTOH, same LBS had a vintage Cannondale ST500, which I purchased and had overhauled. However, because it has an Al frame, the LBS put on regular Panaracer Pacelas; they're the same 27x1 1/4" size as well. The regular Pacela doesn't have the ProTite puncture protection, so it offers a much more supple ride. The Cannondale, in spite of having an aluminum frame, rides MUCH BETTER than my Marukin does! The main difference is one of the spring force variables cited in this video, mainly the tires.
Years Ago, I rode a bike with an aluminum frame, and it was stiff and jarring. The bike had a suspended seatpost. However, I don't know what tires the aluminum bike had. I can't explain why the aluminum bike I tried out had a harsh ride. OTOH, based on my recent experience with my two road bikes, both of similar vintage (mid-late 1980s) and their different frame materials, my Cannondale rides much better; the only major difference between the two (besides frame materials) is the tires that each uses. The aluminum Cannondale, with better riding tires, rides better. Thanks to this video, I now know why. THANK YOU!

Hey there, really interesting video. I have some thoughts…
when I ride over rough stuff I usually stand up which in turn means we have to consider a couple of factors not considers it your video that ant that might or might not put a bigger emphasis on the differences on materials.
when I stand Seat post and saddle have no influence putting more emphasis on frames and add Cranks to the picture.
Definitely handle bars are a massive factor in the feel of a bike as well as grips. Usually peoples hands are more sensitive than their butts.
more and more carbon frames are not built in classic double diamond design but other shapes that are not possible in metal that allow extra compliance.
Geo, the shorter a bike, the more upright you sit the more the discs in your spine get tortured...
so much more factors that could be considered...
also when on the seat and pedaling, pressing down a pedal means taking weight of the seat. hence totally changing your stack of springs. the more power I put in the less weight on the seat.
in this case only tire and frame compliance can give you added traction climbing up a steep gravel road.
Well, the reality is really there is nothing else in this world that people ride around on that people would consider better without suspension or that even still exists without suspension but still some cyclists insist.... only reason we have super uncomfortable road bikes today is UCI rules and bike companies complying to them. How many people really rides in UCI races?
Not only does this give us really uncomfortable road bikes, UCI also makes sizing really inappropriate for taller riders as there is max measurement...
well, Ok sure Forklifts also dont have suspension, so all of the fork lift drivers out there, your are good to continue on your hardtails

I have owned both steel and aluminum road race bikes for years. My personal experience has always been on the same tire size, same routes, same rides. And steel never beats up my body as much as aluminum does. The fatigue from riding on aluminum has always been more noticeable, fatigue from riding steel is non existent.

Interesting. I switched from a steel HT rigid MTB to an Alu HT rigid Mtb, and I actually got bruises on my love handles. Everything was exactly the same except for the frame and the seat post. The seatpost on the Alu frame was actually not as biffy and straight as on the steel frame.

Wow. That was so nice. Thank you for your scientific approach and for the structural explanation.

Impressive amount of details. As a bike nerd who also dabbled in physics in college this video was right up my alley. I literally just sold my Aluminum 40mm gravel bike (with 20mm stem suspension) for a Steel 60mm montercross bike. I definitely have way more vertical compliance from the wheels. I still love some other qualities of the steel like the aesthetics and durability.

I find that a long seatpost, a quality steel frame, carbon bars, high volume tires tubeless, and carbon fork helps

From my experience it is mostly about the fork, it the front is a steel fork it is very likely to have a bit more flexibility than a aluminium one or a carbon one, especially if it has more rake. That puts less harsh impacts on the shoulders and makes rides more comfy. The variations of stiffness of the rear is not significantly different. Everyone who changed from a undamped mountainbike to a front shock absorbed bike in the 1990's can understand that.

Informative, and thank You for saving my money in near future!

Brilliantly analytical! I'm just getting into biking but am a numbers guy, economics and stats, this was so much clearer for me. Guess what I ride a 4.5" fatty hard tail and feel way more comfortable than my brothers 29 hard tail.

Steel forks with low trail curves flex pretty well. I think you focused too much on frame and seatpost and neglected fork flex

Nice. Seems like shock absorption is all about tires and suspension. However the frame contributes to dampness. I can definitely feel the differences in materials. Steel has a characteristic feel compared to Aluminum. A carbon Bianchi with countervail is super smooth!

YOU GET A FUKKEN SUBSCRIPTION FOR THIS DUDE. SO GOOD. Love the use of data. Honestly, I came for the clickbait title, but stayed for the data.

excellent research and data to support the facts . one area that would be good to research is how different fork materials / design shape curve of the fork, head tube angle ect , can effect the ride comfort of a bicycle .

Thanks for the vid and the all work you clearly put into it. Bike designer Mike Burroughs (r&d for Giant for many years) mentions in his excellent book 'Bicycle Design' that there is no inherent difference in terms of rigidity between the two materials, but because steel is stronger you are able to use narrower tubing allowing a less torsionally rigid frame. Aluminium is weaker so thicker tubing is required leading to a stiffer frame. You also don't need much of an increase in tube thickness to acheive an exponential increase in strength. One would have to build two identical frames with identical geometry, tube diameters, wall thicknesses and subsequent spec to be able to perform a valid comparison. As many have mentioned there are many factors contributing to the flex of a bicycle so presumably you'd need to eliminate all variables save for the frame material. So really you may be right in your title but you'd need to risk building and riding a thin tubed aluminium frame..! Of course, we have carbon now so no need to try :-) Just some thoughts! Cheers

That was a great Mythbusters Video! Good to see that most marketing slogans in the bike industry were just urban legends... 😉
I figured out that with a good carbon flex-seatpost I can simply ignore the frame, be it carbon, steel or aluminum.

great video - thanks for the content!

awesome video man! i will help u with patreon for sure!

I bet when it comes to frames the key factor is harmonics and what hertz rate of vibrations different materials usually carry over the best.

7:40 look at the wheel set up on that tractor in the background. Now that's something you don't see everyday.

Really interesting, if not super bike geeky stuff. Thanks!

I believe most of that sounds reasonable . , I believe a frames horizontal flex was missed. though the most comfortable bikes are those that have been fitted properly. After all the smallest adjustments to a seats angle and or height can have significant changes to the comfort of the ride. Dig the video's, keep them coming!

I'm always surprised by all these fancy looking plots the industry shows. Wouldn't you need a bode diagram that shows the amplification of movement of a frame at different frequencies? Also, carbon might sound dull as it dampens in opposing directions. However, the young's modulus of carbon fibre is a lot bigger that steel's and therefore it won't flex at all, stressed in its direction.
Quite difficult to reduce this to a "dull sound"

This is horse dung. Diameter of tubes, length of tubes, wall thickness of tubes, shape of tubes, butting of tubes, elastic properties of the material, and construction design of the frame all contribute to the ride quality of the frame. High strength butted steel tubes are highly fatigue resistant are much smaller diameter as so flex more, butting of tubes stops vibrations.

Thanks for putting this research together. I've always been mystified by the alledged differences between steel and aluminium frames given that they are both metal triangles. The trend of more and more seat post real estate makes a lot of sense now!

Excellent analysis on vertical compliance. Though I'm curious why you didn't consider fork, stem, and handlebars? IME, the bumps coming up through my hands have a much bigger impact on my discomfort than anything coming through the back end.
(I have a sprung Brooks saddle and a Softride suspension stem on my primary bike, and when I ride a different bike, it's the stem I miss the most.)

Expensive heat-treated steel is stronger and can be made thinner to flex more without breaking. Cheap steel bikes cannot do this and feel terrible. It's all to do with young's modulus. Aluminium frames cannot tolerate as much flex. I can littery feel a steel frame flex when I put on the power, so it is very noticeable to us humans. Never got the same flex as put on power from carbon or Ali, so something is making a difference, even if your measurements do not pick it up? I have ridden high-quality low weight Ali frames and they are not the same. They deliver the power more efficiently but also lack feel and spring (both in power delivery and comfort compared to an expensive steel frame). I would suggest it's the way a steel frame flexes, or how much it is able to flex. Perhaps the tests need to look more into real-world conditions - not just flex for a given once only load. Of course, tyres and post make a difference too.

A few comments:
• It isn't just the width of the tyre that makes a difference. Some brands of tyre aren't as compliant as others. Simply changing to a more compliant brand in the same size can make a huge difference. I bought a set of slightly used hand built road wheels from a friend who didn't like them, tried them out and I also hated them for the road buzz, then swapped the Contis they had fitted to some Michelins, and they were perfect.
• The choice of tubes can also make a big difference: latex tubes are more compliant than butyl rubber.
• Your video ignored the front end of the bike. The road buzz transmitted via the front wheel, forks, and bars into the hands can be a major factor in the perceived (lack of) comfort of a bike. Aluminium and carbon forks go straight from the crown to the dropouts, and the geometry doesn't allow for any give. Steel forks are generally designed with a curve in the blades, which allows the fork blade to flex ever so slightly. On a road bike, with skinny tyres, that fork flex can make a difference.

Very good content, as always!
I have to say, i always wondered why all carbon wheels (on road bikes) i rode definitelty ride nicer than aluminium rims. even with the same tires at the same pressure on my own bike that i know very well. if there is basically no vertical compliance in either wheel, where does the difference come from?
a thing i also noticed is, that with a wider heavier tire, there are situations where the same bike begins to feel less "floaty" over a certain type of bumps than with a narrower lighter one, even with vastly less pressure.
so i recon the rotational mass does make a difference. and less mass is sometimes better.it feels more "zingy", less "crashy" when you ride lighter wheels on a roadbike.

very comprehensive, this helped me a lot

Great information!

High quality steel frames are a much smoother ride. Double butted thin walled steel frames have muluiple reasons for better comfort. High end steel tubing is highly resistant to fatigue, meaning flex can and is built into the tubing. The tubing in steel frames is much smaller diameter due to higher strength and fatigue resistance so flexes with less force. Most mocdern bikes are built on a compact design, short tubes and short wheelbase. This does two things, short tubes are much less flexible than long tubes, the wheels are directly under the rider transfering road shock and vibration. Any such frame is much more harsh to ride.
Comparing a large size Giant defey advanced 2013 with my current steel framed bike. Steel frame is 16 cm longer wheelbase, no foot front wheel overlap, very smooth ride and only 1 kg heavier. Frame design and frame material both matter for ride quality as do wheels, spoke lacing, rim width, and tyre size

I totally agree about everything you said 👍👍. Frame size, reach etc are most important then frame material . I had issues with numb hands always assumed it was from the aluminum frame but downsizing all of my bikes to extra small cured the problem on my mountain, road and urban bike . The hybrid should have been the perfect bike but it was just a compromise as the saying goes a jack of all trades the master of none .

As an experiment, if you can zip tie one or two 5 lb. hand weights to a bottle cage, the ride comfort improves favorably. BTW, this video is the most accurate ride analysis ever made on YT.

To me, vertical deflection is a small and only one component of comfort and road feel. When you pedal hard, the energy goes into twisting the frame and your body is working against it. If the road vibrations are transmitted to your body in the process (at contact points) your will fatigue faster and not enjoy the activity as much. If you are climbing out of the saddle and the frame flexes back a little it is more comfortable and fun even though it may not be as efficient. Same goes for tires:many other considerations such as how well it grips under high speed cornering or how supple the sidewall is under angular forces, determine how comfortable and fun it is to ride.

I had low spec steel framed Specialized MTB with no suspension fork back in the early 90's which gave a lovely, quite flexy, smooth ride compared to something similar in aluminium. I don't think it was my imagination..........

Good video. Seems like double wrapping or getting thick, vibration-reducing bar tape would also go a long way for cheap.

Thank you very much from confirming what I thought to be true for a very long time! My anecdotal evidence has suggested to be true, I use to ride what was probably the stiffest frame of all time a Banshee Mophine and never found it harsh due to 2.5" tires, and I have ridden some classically "flexy" bikes and never found them softer vertically, even though I found them terribly "flexy" laterally.

I understand the video is about frames but I think the idea of steel=comfort always came from curved steel forks that were designed to flex. Also there are some steel bikes (don't know off the top of my head) which have specially shaped rear triangles in an attempt to allow the tubes to bend, which would allow an action similar to mountain bike rear shocks. Not common, but worth looking into as they are a definite exception. overall a nice video.

I feel like you're reading my mind because I've come to the exact same conclusions over the last couple of years, and have been meaning to write an article for a while. I always try to explain this to people, but they don't understand because they've tried x aluminum bike and thought it was stiff and y steel bike and thought it was comfortable, yet they haven't controlled for tires, tire pressure, seatpost length, saddle, fork, handlebar, etc etc. Or too stuck in the "steel is real" thing, thinking that steel has some magical quality that allows vertical compliance, when in reality it is the stiffest material used for frames (and also damps vibrations the least, iirc?). Not that steel doesn't have other benefits.
You might look into framebuilder Rob English (English Cycles). He has a masters in mechanical engineering. Despite using the thinnest seatstays in the business, he also says that frame vertical compliance is a myth and thus designs to maximize seatpost length.
The single exception to all this are vintage rim-brake steel forks with thin walls (this does NOT include most unicrown forks e.g. Surly-type bikes, and it doesn't even include many lugged crown forks). Aluminum can't be made to flex enough in a fork due to fatigue.

Superb video! Thanks for digging up all those numbers.
What about the fork? It's probably the longest lever on a bike with a diamond shaped frame and therefore deflecting more than the seatpost. I never rode a carbon fork, but all steel ones I rode felt much more comfy/flexible than aluminium ones. Keep it up!

Now look at datas for:
fore/aft movement of the front wheel
lateral movement of the bottom bracket.
"feeling" explained.

Thank you for this video. Excellent analysis.
I see some BTL comments are trotting out the mythical difference in feel between common seamed high tensile steel tubing, and thin-wall steel alloys such as chromoly and mangaloy (Reynolds 531, etc). This misses the point you clearly make. Much work has been done by some of cycling's most respected engineers and scientists (as opposed to marketing departments and other sellers of magic pixie dust) to debunk this hokum.
Here's the late Prof. D.G. Wilson on the subject:
"The goal of increased strength or stiffness is somewhat in conflict
with elastic compliance for comfort over bumps. Actually the main arena
for this competition is the handlebars, and to a lesser extent the seat,
cranks, and fork; the rest of the frame plays no role in softening bumps.
There is probably value in trying to increase the handlebars’ torsional stiffness while maintaining or decreasing vertical stiffness." (David Gordon Wilson, Bicycling Science, 3rd ed. MIT, 2004, p. 367).
Further :
"In Papadopoulos’s limited experience of blind testing (varied tire
pressure +/- 1 bar, varied bicycle mass +/- 2 kg) or double-blind testing (varied
frame stiffness and material) of bicycle characteristics, riders could not
demonstrate anywhere near the powers of discrimination among alternatives that they claim to possess. We speculate that many ‘performance’ sensations are imagined; demonstrating otherwise is a promising field for determining what really matters." (p. 302).
Finally:
"David Malicky (1987) performed a double-blind test of stiffness perception, using bicycles with frame tubing of relatively high and relatively
low wall thickness (with mass added so the bicycles would weigh the same). The test population of racers could not perceive any difference in stiffness among the bicycles. (p. 367-8).
Sorry for the long comment, but as a cycle industry veteran, this is a subject close to my heart.

Time to order in a springy seat post, gr8 vid al

I bought an alloy gravel bike last year, mainly as I wasn't sure whether I'd really ride it much so spent the least I could (Planet X Full Monty c/w Apex 1), I've been surprised how it's not been the boneshaker I was expecting.
If you follow me though on my old On One 456Ti you can literally see the 'give' in the QR rear end and hear the tyre touching the chain stays either side. Boy is this bike comfy, preCEN testing...

Interesting indeed, thank you ! On MTB hardtail though, the story is a little different : most of the roughness perceived would be in a different posture which is of course standing on the pedals. The chain of stiffness would be : tire/rear triangle/crankset for the feet feeling. Let's forget about the hands' feeling who are heavily protected by a 1XXmm travel fork.
The other fact you can add to your video would be that all of your measurements are static ones (i.e. very very slow), whereas our body is much more fatigued by certain frequencies, and that if the stifness is comparable when going from static to dynamic, the amplitude can vary a lot. Riding on trails or pavement can induce a lot of vibrations, so that this consideration is not pointless I think. Unfortunately I'm not aware of any litterature about it.
Keep up the good videos !