to reduce the front to its fraction of the *total* load, rather than to its ratio with the *rear* load, that is perverse! What a world!
Agreed, but it sure seems to be common. Similarly, most people hammer in the maximum pressure printed on the sidewall -- if they remember to check their tires at all. A bike-shop friend actually recommends this to customers, since it at least means better rim protection and fewer "snakebite" flats from under-inflation. He says it beats the alternative, seeing customers' tires with as little as 15-20psi, cracked sidewalls, and complaints "something must be dragging". He has a point.
The drop is such a small number and a bit awkward to measure - I'm glad you've figured out a system for measurement with some precision!
The only way I could figure to do it was the similar to Berto's method:
1) Get two bathroom scales that read equally under the same weight (they're not as precise as I'd like, but at workably close).
2) Mark the center of each scale with an "x" across the top so the center of the axle/tire contact patch is on the center of the scale. Neglect this, and repeatability goes out the window. Block-up the bike's brakes so the wheel won't turn.
3) Mount the bike while on the scales and hang onto a wall. Get someone to note the scale readings while viewing vertically to discount parallax with the indicator needle/dial.
Once you know how much weight is going on each tire, remove the front wheel and mount it on the test rig (I used a spare fork with a modified stem clamped to the end, set on the ground so it supported the wheel vertically with the tire centered on one of the scales.
I then rigged one of my digital micrometers on the center of the rim top at the bottom (noting the reading in relation to the scale top), and pressed the forks till the scale readings for load at the axle matched what they were when the wheel/tire was mounted on the bike. At that point, I pushed the micrometer down on the rim and noted the reading. I then released the pressure on the tire and confirmed the "return" height equaled the initial height and subtracted the loaded height. Presto: tire drop at a given load, and repeatable for accuracy.
Fortunately, I use Rigida Andra rims and the same tires front and rear, so I was able to do my tests with just the front wheel/tire, changing pressure as needed to simulate F/R position on the bike.
Berto's method was a little different. He used a hydraulic jack and a dial caliper, but the basic methodology was similar. I'm not sure he allowed for the preload of the bare bike on the tires, however. I considered both, and finally went for a 15% drop overall with the bare wheel/tire loaded with the total weight relative to its position to see if I could duplicate drop using the weight registered on the scale with me atop the bike. I'm still pondering if this skews the figures compared to preloading the tire with the bike's weight, but figured this method was consistent with Berto's that measured overall load on the tire with bike *and* rider combined.
Careful as I was, there are still many potential sources of error in my measurements. For example, the center-top of the scales may be deforming under pressure, or the steerer of my test-rig fork may be bearing some small part of the vertical load, skewing the results a bit, though I took care to load the fork at the dropouts so as to load the axle in turn.
And, of course, all my carefully-gathered figures are for naught once I load the bike with bags and water!
I was curious as to where my body fit in relation to the Nomad's axles, so I grid-lined a profile photo and was surprised to find myself well within the wheelbase and pretty equally so (attached pic), though the bulk of my mass lies rearward of the center point between the lines.
Whew! Tire pressures are complexicated!
Best,
Dan.
