Thursday, April 24, 2014

DON'T PANIC

While enjoying some suspension fork troubleshooting at work today I got to thinking back to when I was still terrified of things in general.  Like hydraulic brakes and suspension components. Like commitment, failure, self-assertion, dancing; there's plenty of things to be afraid of if you're prone to anxiety and self-deprecation. But hydraulic brakes and suspension components really aren't complicated.  My hang up was what I think many mechanics have--simple fear of the unknown.

In a brake, the lever pushes some fluid and it displaces the pistons toward the rotor.  That's really it.  There's a couple different ways you can push the fluid, and that accounts for the only differences between various brake systems.  In suspension, it's slightly more complicated, but only slightly-  you've got a spring, you've got some oil moving through various types of holes, and you've got a bunch of o-rings.  All the forks and shocks out there are pretty much the same with some minor differences that do change performance drastically.  Once you get over the voodoo and take a few apart (and i mean actually take them apart, not just pop new dust seals in and follow the directions) it's laughably simple.  I'm embarrassed by how long it took me to get over the fear.

I always had the attitude of not wanting to make things worse, and assuming it was probably too complicated for me, or not having enough time to take it slow and really learn while doing it.  Which is the worst attitude because it only prolonged the fear.

Then I got out of the bike industry, learned what it's like to work under power tripping assholes, saw some gory, Tarantino-style human death up close, had my (fourth or fifth) existential crisis, and decided to stop giving two fucks about it all.  Forks are cool; let's take them apart.  

Once in possession of the correct attitude, I could learn much faster.  It didn't take long to see how you can make a lot of it work better. I just took apart all the old junk laying around.  That's important- and it held me back earlier- go out of your way to find junk to take apart.  Old blown fox vanillas have the exact same things going on inside as the newest stuff.  When it's junk there's really nothing to be afraid of (except spraying oil at 200psi all over yourself/wear eye protection).

The bike industry spews out a lot of shit.  Both in marketing and manufacturing.  But by studying it you can go through the shit and pick out the undigested corn kernels that are still worth something.  And maybe even make them into tortillas!

Like my beloved Manitou Minute fork.  It's got this wonderful digressive damper (both compression and rebound), and a linear to progressive hybrid air-coil spring.  Really about all you could ask for except the bushings have a ton of play and the classic manitou top-out bummper gives a clunk everytime the front wheel comes off the ground.  Bushings I'm kind of at a loss with, I even warrantied the thing and got one in return with equal play.

The reason for the lack of negative spring is that the MARS air spring has a coil and air spring in series.  I'm not exactly sure how much the coil moves before the air spring piston lifts off its seat, but it's more than on a normal air sprung fork of course.  Coil springs have no energy at full extension, so technically speaking the low speed rebound circuit should control the rebound until the coil loses all its energy at the top of the stroke, so a little bumper is all you need.  It really makes the fork "stand-up" in it's travel, which is nice at times.  But unless you run the LSR really slow, there's some left over energy (air piston still moving?  preload on coil?) and it tops-out harsh.

But I was relatively easily able to replace the top-out bumper with a coil spring from ace hardware.  The top out bumper was something like 20mm long and I figured it compressed a little bit at top out, so I found a spring the correct diameter that is about 2" long extended but can't compress to shorter than 15mm or so, when all the coils hit each other.  I felt like that gave me good margin for error in terms of maintaining adequate bushing overlap, though I didn't do any measuring of the stanchions etc. It has smoothed the initial travel and top out massively.  Since it's a linear (coil) negative spring you can feel the transition when it releases if you're pushing on the fork, but it's invisible while riding.   I squeezed a few springs and got one that felt stiff enough to to compress almost completely at top-out.  I got lucky and it was right the first time.  I'm sure these Ace springs are quite cheap and I keep waiting for it to break, but so far so good.

An update from last year:

The Fox Float RP2 rebuild was extremely unsatisfying.  I changed the propedal needle valve spring (found some weird tiny spring at work that fit and was stiffer and longer) to increase platform, and then fucked with the shim stack a little.  IIRC, I pulled all the Belleville stacks off and put a regular stack in their place.  But I also called FOX twice and begged and pleaded for damper seals to no avail.  I also called some factory authorized service centers with the same result.  Then I spent hours at the O-ring store but replacing the main Viton damper body seal with BUNA-N just didn't work.   Too soft I guess, blew out after riding twice around the block.  I had a few bounces of enlightenment when I started feeling what the mods had achieved (Much more low speed compression with propedal on but not enough damping in OPEN mode), and then it blew up so I gave up and bought a Monarch.   Which is a great shock and completely user serviceable and I haven't had a reason to take it apart yet.  Much more heavily damped than the Fox with a nice crisp shim-stacky feel.

Saturday, August 17, 2013

Patents and Prior Art

Some of the brightest and most influential minds in our world cut their teeth as patent clerks.  Clara Barton, Thomas Jefferson, and of course Albert Einstein.  As they would tell you, patent eligibility hinges on the invention's separation from "Prior Art" and it's non-obviousness.  In other words, patentable ideas should not be an evolution of an existing idea, but something new- an intellectual leap.  It is conceded that practically all inventions arise from existing knowledge.  Kepler could not have deduced the solar system without Euclidean geometry.  One idea builds on the last.  But within the bike industry I see market greed and protectionism driving patent applications- and surprisingly, they are approved again and again.  In both bicycle suspension and saddles, the areas of my interest lately, there are plentiful examples. Pages and pages of obtuse language fill these patents and intimidate potential trespassers (and probably the patent clerks themselves).  But where is the content?  With Specialized's "FSR" (bought from Horst which is actually a Macpherson strut) patent expiring soon and Dave Weagle's ongoing lawsuits with Giant and Trek over alleged patent infringements, it's a relevant topic.

Let's look at two patents, both filed and approved at the end of the 1990's by two of the largest American bicycle companies- Specialized, with their saddle with cut-out, and Trek/Bontrager with a normal, padded saddle.

In patent EP1024992 A1 Specialized covers their version of the "prior art": "Bicycle seats, or saddles, have traditionally been designed with a convex profile such that they fit between the body's ischial tuberosities ("sit bones") with a small protrusion tucked up in the crotch."

Except, of course, every saddle on a cruiser bike ever, and, as far as I can tell, the vast majority of saddles ever made, racing saddles being only a small minority thereof.

The meat of their patent application (the rest is legal jargon necessary to describe the general shape and construction of any bicycle saddle) lies in the explanation of the groove: "Yet another aspect of the present invention includes a groove with dimensions approximately equal to the dimensions of a human body ischial tuberosities such that pressure is reduced on the internal pudendal arteries."

Let's look back to a patent by Frank A. Hollenbeck in 1897, almost exactly 100 years prior,  regarding designing for these differential pressures on a bicycle saddle:  "The horn, and particularly the laterally flaring enlargements thereof,  afford considerable support to the rider, and the bifurcation of said horn and the aperture a' prevent injury to his overlying parts." 



Maybe it's not as explicitly presented in the Grey's Anatomy kind of way but to me that is saying exactly the same thing.
 
It's thanks to that other aforementioned patent that I easily found Hollenbeck's original idea.  Legendary Keith Bontrager, already quoted in this blog, included it as reference to his patent US6149230 A. His claims for the new Trek saddle are:
1. A bicycle saddle that includes a novel contoured upper seating surface which primarily supports the rider's ischeal tuberosities and thereby reduces the pressure placed on the perineum is disclosed.

Bontrager:


OK, now, see...umm, almost every other performance saddle ever made? Like, you know what I'm saying?





2. In particular, the seating surface of the saddle includes laterally spaced apart right and left posterior support surfaces for supporting primarily the ... ischeal tuberosities of the bicycle rider. The ...posterior support surfaces are formed by a ... V-shaped open space extending forwardly from a rear edge...of the saddle and terminating at an apex, and also formed by a central, longitudinally extending depression extending from the apex forwardly to the anterior portion of the saddle.

So, what Specialized said.

3. The invention disclosed herein includes a variation wherein the foam padding is comprised of a first pad and a second pad designed especially for female riders. The first pad, which is comparatively quite soft, covers a central portion of the anterior portion of the shell. The second pad, which provides cushioning but is relatively firmer than the first pad, covers the posterior portion of the shell and also surrounds the first pad thereby covering the extreme side portions and extreme forward portion of the anterior portion of the shell.  

Wait, let me guess: "The horn, and particularly the laterally flaring enlargements thereof,  afford considerable support to the rider, and the bifurcation of said horn and the aperture a' prevent injury to (her) overlying parts."

Fortunately I don't think there's been much aggressive defense of these particular patents; Trek has even allowed theirs to lapse (they came out with a new model I guess).  I could go on and on, but frankly these pretend inventions that are somehow awarded patents are so numerous in the bike industry that it gets quite boring. In fact, if you browse through Bontrager's thorough listing of references, you'll find 2 more saddles with perineal cutouts patented in 1897 and 1899.  Bicycle Retailer summed up my feelings very concisely in what I hope was a subtly ironic jab: "Cane Creek's Aheadset patent is due to expire in the fall of 2010. Additional patents, which are refinements of the original patent, like Tange Seiki's Zero Stack patent, will remain active after 2010."

It's also interesting that the US patent office, as of this spring, switched its "First-to-invent" policy to "first-to-apply."  The obvious intent is to eliminate the long and costly legal battles between contradicting parties.  However, if prior art is already so loosely interpreted, would not a "first-to-apply" policy make it even easier to patent previously un-patented prior art as new?

For all the dogfighting between DW and Trek over the "Active Braking Pivot" and "Split Pivot" systems, couldn't a patent clerk back in 2006 or whenever just have said, "Look, what you both have designed is a nice way of integrating a floating brake into a bicycle suspension design.  Sure, "he said, she said", one of you probably stole this idea, but let's take a step back here.  There were previously both bicycle suspensions and floating brakes.  They weren't intrinsically or even superficially hardly any different than this.  But hey, it's a little lighter and cleaner than a real floater, and at least you made it partially better than a single pivot, thank god, so kudos for that.  We have a word for incremental improvement here at the Patent Office:  Engineering.  Call us back when you come up with something new.  And would you stop fighting about it?" 


Here's an actual innovation.


Friday, May 31, 2013

Tuning Fox Float RP2

Let me get this out of the way- I service forks and shocks at work and for fun, but am just learning about custom tuning dampers.


This, be warned, is what happens when my girlfriend goes out of town for a few days:

My Float RP2 feels the same as what every one on mtbr.com says: wallowy through the mid-stroke, blows through travel.  I've ran it almost entirely with the Propedal engaged. But then it's just not that plush or responsive.  Especially compared to my new Minute Pro 120 fork.  Now that the shock finally took a shit on my last descent down Crooked Trail, it's time to figure out how to rebuild this thing and maybe tune it a little better.  The damper hasn't been maintained in 5 years of hard use, and finally the seals let air into the damper.  The damping became very inconsistent very quickly with lots of slurping noises.  It's not worth the money to send it to Fox or PUSH for a rebuild because it's almost the same price (for me) as much nicer replacement shock.

Goals:
1. Firmer Propedal for road climbs (Propedal on RP2 was more of a "trail" setting)
2. "Trail" tuned damper in full open- more low and especially mid speed damping, digressive curve at the high end to counteract low-volume progressive air can.
3. Replace critical damper seals: IFP seal, shaft seal, damper body seal.

I'm not going to go step-by-step through the rebuild.  Floats are very similar in design to RS Monarch/Ario and RS provides great instructions with photos.  Practicing on something that's actually meant for end-user service would be a good start.  I also had the privilege of tearing apart a few old, broken Floats at the shop. Filling the IFP chamber is the trickiest part, I cut 5/16x24 threads onto a truck tire tubeless valve and used the rubber gasket from inside a high quality schraeder cap to seal it. I'll have to remove the valve to get the air can on and off.



For the sake of simplicity, unless I can scrap something obvious from one of the old shocks, I'm going stick with the basic (but not very simple) piston and shaft setup of the RP2.





 
Here is the obligatory shim-stack photo: (note, I'm not that grungy- those rags are washed and clean, just stained)

FAQLoad has a good explanation of the RP2(3) damper.

The belleville washers push on the outside of the thick aluminum shim between the glide ring/piston and my thumb (left).  That thick washer is separate from the washer axial to it.  The large washer slides on the inner washer; I have them offset slightly so the the difference is visible.  The large washer completely seals the ports through the main piston, so it also acts as a check valve under rebound to create a separate rebound circuit. Compared to a normal shim stack, once the belleville washers are compressed to vertical, the thick aluminum shim can't flex any further.  However, since the whole shim moves rather than just the upper edge, it's hard to say how it affects the damping curve.  My guess is that it allows a lot of fluid to move at high speed. 

There's also a secondary compression piston (right) after the main/belleville piston.  Fluid enters the shaft if enough force exists to open the Propedal needle valve (or if the adjuster is set to Open), and can exit the shaft either at the secondary compression piston or at the rebound orifice.  The secondary piston is closed completely by shims and so only opens at a certain force.  It would be hard to guess whether the main piston with it's highly preloaded belleville washers or the secondary piston's shim stack opens first, though given that the propedal system is designed to control low speed damping, and given the high preload on the belleville washers, my guess is that the LSC shim stack on the secondary piston opens first.

So in Propedal mode the low speed damping is controlled by the very peripheral parts of the main piston's ports.  With the Propedal open, the LSC is controlled by the same part of the main piston as well as the upper-shaft rebound orifice.  Mid and high speed damping are controlled by the belleville shims on the main piston and the shim stack on the secondary piston (depending on the propedal needle preload force).  I'm have no idea why there are two pistons working in tandem like this.  It seems to me that the belleville shim set-up increases friction because of the extra moving parts and might make the damper less reactive because of it's on-off nature.  I also might be full of shit.

Without changing the whole layout I think I have three options:
1.  Increase preload on the Propedal needle valve.  This is two birds with one stone- firmer propedal setting, also more LSC in full open.  I need to make sure the propedal adjuster doesn't travel too far- adding too much preload could bottom out the propedal coil spring when the platform is engaged. The propedal lever was getting a little loose anyways so I'll at least add a small amount of preload (1 or 2 of the tiny shims if i can find some)
2.  Add a shim to the secondary piston.  The belleville washers on the main system seem to me like kind of an on/off sort of setup because as soon as that thick washer lifts off the piston the oil flow is massively increased.  I want it digressive as I mentioned earlier to counteract the progressivity of my small volume air shock, but I think it might be digressive too soon, need more velocity-dependency through the mid-speed range.  If I add shims to the secondary piston it might increase mid-speed damping, or it might just put more pressure on the main piston, and cause it to open earlier, so I don't think this is a good option.
3.  Add more preload to the Belleville washers so the mid-speed impacts are damped through the more traditional shim stack on the secondary piston.  I'm assuming that since they bothered to design the secondary piston and shim stack in the first place, the shaft orifice at the propedal valve is big enough that it can pass more fluid than what can escape the rebound orifice. As the FAQLoad page mentions, 3 belleville shims are used on the High tune RP2's.  I have two, for the medium tune, so maybe some extra preload on the two will be a middle ground.  The problem here is that adding a washer without subtracting one of the two preload shims that already sit behind the secondary piston will restrict how far the main piston's valve can open, which could lead to high speed spiking.  I really need a half-diameter belleville shim to replace one of the preload shims.  Some shocks are going to be torn apart tomorrow!

Am I totally wrong on this?  Please enlighten me if that's the case. 


Thursday, May 30, 2013

Science of Flow (non-Newtonian)

I love to complain about trail flow.

In fact, it's one of my favorite things to talk about, especially while riding.  If you ever went riding with me, by the third time I yelled" Ughhh decreasing radius blind corner what the fuck!", you'd have already turned around to ride it uphill instead, figuring that would be much more pleasant.

As an amateur trail builder and enthusiast, I feel like I have a small right to complain.  I've built a small bit of good trail, a fair amount of mediocre trail, and some trail so bad that we had to fix it before anyone else saw what we had done.  I guess I've never been able to learn any other way, but it sure works quickly.  So in other words, I'm an expert in what bad trail looks like.

All mountain bikers can feel the difference between good and bad trail.  But is a slightly awkward corner really worth complaining about?  You're still out in the fresh air, on your bike, and no one's telling you what to do.  You have to appreciate the time someone took to build it.  The weeks that someone took to build it.  It's because we stand on the shoulders of inventive, motivated giants, that we can see the finer points of trail building so well now- both in the negative examples, and the plethora of beautiful, so subtly-executed trails.  The real problem with bad trails is not a rider's enjoyment but the durability of the tread.  Anytime you have hard braking, cornering, and descending at the same time, the tread will blow out quickly.  That's my motto: It sucks to brake hard, corner, and descend at the same time.  Now Keith Bontrager will be quoted on the Internet for the 7-billionth time: "Pick two." (Since less than half of the world has Internet access this is probably at least the second time I've done so)

But the magic of a great trail is worth striving for.  And for the record, I'm not talking about the pump-track type of trail in which no corner goes un-burmed.  There's a place for that kind of trail, and I'm always impressed by the ambition and engineering cred of the builders and the skill of the riders.  But for most mountain bikers, where shared use is a reality and maintaining a wilderness feel and a safer appearance keeps the trails open, this isn't realistic.  A simpler trail doesn't have to come at the expense of flow and challenge.  It's those very trails that use nothing more than a ribbon of singletrack, with just enough grade reversal before the corners, crossing over roots and rocks that are just barely rideable, corners just tight enough that it's very hard to ride fast but doesn't suck to ride slow that are truly great trails.  These are the trails that I'm in love with.

Like everything else, I learned the hard way about tread width- at first it feels right to dig that nice deep backslope, make absolutely sure there's no false toe, and to inslope all the corners.  But wide trails are fast trails and managing speed is the hardest thing about trail building. They're also ugly trails-not only is there a lot of dirt showing, but twice as much (or more) left over dirt to be dispersed.  A high-use trail that crosses or turns on a very steep hillside needs some width.  But for every other situation, let's have narrow. Turns out it takes half the time to build them, too.

------------------------------

Lately I find myself much less critical of trails.  In fact it's been at least 4 rides since the last time I cursed a corner halfway through.  I would like to believe that it's an indication that I'm much more at peace with the world (I mean, this world, Earth), or my existence in it, or even that the anti-anxiety herbs are working and sleep makes me that much more pleasant of a person.  But I've looked over the evidence again and again and there's only one answer:

I put real tires and a well-damped 120mm fork on my bike.

When I started mountain biking I realized immediately that a five inch fork and some knobby-ass 2.3's turned awkward or sketchy into just fun.  I used to tease my dad (who to my knowledge never has used an index shifter) that not only did my bike have index shifting but also indexed-rolling tires.  I proudly rocked (as opposed to ran) a 200 dollar fork on a bike I paid $380 for, new. Later I developed this road racing problem and all my mtb tires got lighter and faster, and my forks got shorter, even to the point of riding a '99 SID (which that they never should have put disc tabs on, that was just scary). I went tubeless and kept dropping my pressure to try to squeeze a little actual traction out of the fast rolling tires (Michelin Dry2 was the rockbottom equivalent of the SID).

Anyways, a few weeks ago I put 2.4 Conti Mountain King black chili Protections on front and rear.  They fit great on my 26" Anthem.  They actually hook up better at 30-35 psi because the knobs bite so much they need support.  I ride in loose country--Missoula, MT--and an open tread pattern with real knobs is the only thing that hooks up.  Sure, better riders can milk a lot of speed out of some startlingly bald tires, and I'm probably not night-and-day faster than I used to be, but there is a massive difference in the level of control at high speed and the ability to use your brakes.  Magnum rubber = more fun, more control, less trail damage.  Plus, it's a great excuse to be the last up the hill! 

Soon: can you guess what this means?


Thursday, January 10, 2013

Hello World

Getting old school with the title there.  When we used to name the school computer lab passwords after our guinea pigs and hamsters, "Hello World" was kind of a thing on the internet.  Also, remember, Garage rhymes with Carriage.

I'm just now realizing that in general the harder I think about things the worse my decisions are, so I'm trying to be a little more impulsive and much less deliberating.  I thought about starting one of these like three times, which is way too much.  And now somehow I'm framing starting a blag (thank you xkcd, big fan) as a good decision! 

Regarding the over-thinking thing, I was shoveling the driveway and sidewalk this morning and thought that I might shovel the sidewalk in front of my neighbor's place as well.  When you grow up in the pacific NW in the 90's, you learn that that might actually be a bad idea, because my neighbor would naturally assume that I was shoveling it in disgust with their reluctance to do so (of course the snow had been falling for just a few hours and it's the middle of a weekday).  I don't want to offend them!   If I shovel for them, they would clearly feel obliged to reciprocate, creating more work for them.  That would defeat the point.  At what age do people transition from reciprocating snow shoveling, to just appreciating it?  They don't look that old.  Do people even reciprocate shoveling? They have never shoveled our sidewalk.  Am I going to offend the next house down, whose sidewalk I don't shovel?  I have to draw a line in the snow somewhere!  And then what about the loaf of bread she baked us when we moved in?  Does shoveling equal bread?  Did I already pay-back that favor?  Does this require her to double-favor reply?  What if I double-shovel them before they can reciprocate?  God knows I'm unemployed, I can shovel any time of day.  What if it's my turn to reciprocate when we eventually move out, and it's summertime?  Am I going to have to come back with brownies or weed their garden or something?  I still haven't even had a real conversation with them.  This might never stop.  I definitely shouldn't shovel their sidewalk.  Ok, you concluded that, so it's probably wrong. I better just do it quickly; I won't be caught.    "Ha," I said to an old friend in my head, as I shuffled icily around their sidewalk, who used to argue with me about altruism, claiming that everyone was always in it for something, if only the praise or ego boost.  Here I am, trying not to get found out.  My first steps were skittish, nervously glancing.  With each pass I was more confident that I would get away with.  But O, how the snow just sloughs-off this shovel blade, clearly the radius is too tight!  Who designs these things?  I need another pass; I'm losing all the snow.  Finally finished, and relieved to have escaped unseen, I moved to my other neighbor's sidewalk.  Just as I got there, I heard a noise behind me. Drat, now I'm done for!  What if I pushed the snow somewhere they didn't like it?  I hope she doesn't bring out a loaf of bread!

As I turned, she poked her head out from behind the front door, waved, and said, "Thank you!".