The inventor is a mathematician. Why?

[Johan Bornman]

The inventor of this strange bike can only be a mathematician. Lets see who guesses why. I'll post links to the website once we have some suggestions as to my hypothesis.

 

http://images.china.cn/attachement/jpg/site1007/20090507/001109b42f980b6cb83515.jpg

[Bike Mob]

 

He's worked out that pairing a 3 sided "wheel" and a 5 sided one will keep the bike at the same level at all times, with offset heights?

 

Althought the front looks sprung? and the rear has no seatstays, so it's tough to tell if it's movable or not

Tarmac-GSTR2009-06-04 07:14:11

[Bos]

Hellknows...I would love to see it In motion.

[d-jas]

The front wheel should 'pull' the back wheel...

[Johan Bornman]

That was too quick.

 

I found the photo here - http://www.china.org.cn/china/photos/2009-05/07/content_17738257.htm

 

But there's no explanation of what's potting. Only once I went to the last photo did it notice the roller under the "carrier".

 

That gave me a clue. I'm no mathematician so I have no idea what the concept is called. But I do know why he didn't go for a spoked wheel.

 

 

[Racer X]

My engineering experience tells me that the bloke who put this together had to be a mathematician cause the whole concept revolves around convex planar bodies and shapes. I had to submit a thesis on this last semester.

[Bike Mob]

Intersting theory d-jas... it might once moving perpetuate it's own movement

[Old school]

From Wikipedia:

 

Reuleaux triangle

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http://upload.wikimedia.org/wikipedia/commons/thumb/d/d2/ReuleauxTriangle.svg/200px-ReuleauxTriangle.svg.png

The Reuleaux triangle is a constant width curve based on an equilateral triangle. The distances from any point on a side to the opposite vertex are all equal.

A Reuleaux polygon is a curve of constant width - that is, a curve such that, if two parallel lines are drawn tangent to the curve, the distance between them does not depend on their orientation. The best-known version is the Reuleaux triangle. Both are named after Franz Reuleaux, a 19th-century German engineer who did pioneering work on ways that machines translate one type of motion into another, although it was known before his time.

The Reuleaux triangle is the simplest non-trivial example of a curve of constant width. The trivial example is a circle.

To construct the Reuleaux triangle, start with an equilateral triangle. Center a compass at one vertex and sweep out the (minor) arc between the other two vertices. Do the same with the compass centered at each of the other vertices. Delete the original triangle. The result is a curve of constant width. Equivalently, given an equilateral triangle T of side length s, take the boundary of the intersection of the disks with radius s centered at the vertices of T.

By the Blaschke-Lebesgue theorem, the Reuleaux triangle has the least area of any curve of given constant width. This area is http://upload.wikimedia.org/math/9/d/b/9dbd79f0e81989aca3d032dff386d5e0.png, where s is the constant width.

The Reuleaux triangle can be generalized to regular polygons with an odd number of sides. See also the British twenty pence and fifty pence coins.

Other uses

http://upload.wikimedia.org/wikipedia/en/2/20/Rouleaux_triangle_Animation.gif

http://en.wikipedia.org/skins-1.5/common/images/magnify-clip.png

The Reuleaux triangle rotating inside a constant sized square

Because all of its diameters are the same length, the Reuleaux triangle, along with all other Reuleaux polygons, is an answer to the question "Other than a circle, what shape can you make a manhole cover so that it cannot fall down through the hole?" However, in practice manhole covers are not built in these shapes, due to difficulties in machining and lack of compelling reason.

The rotor of the Wankel engine is easily mistaken for a Reuleaux triangle. The curved sides of a Wankel rotor are somewhat flatter than that of a Reuleaux triangle; the Wankel rotor thus does not have a constant width.^[1]

A drill bit in the shape of a Reuleaux triangle can (if mounted in an apparatus that doesn't rotate it along its axis) drill a hole that is very nearly a perfect square.^[2]

A Reuleaux triangle rolls smoothly and easily, but does not make a good wheel because it does not roll about a fixed center of rotation. While an object on top of rollers with cross-sections that were Reuleaux triangles would roll smoothly and flatly, an axle attached to wheels shaped like Reuleaux triangles would bounce up and down three times per revolution. This concept was used in a science fiction short story by Poul Anderson titled "The Three-Cornered Wheel."

The existence of Reuleaux polygons is a good demonstration of why you cannot use diameter measurements alone to verify that an object has a circular cross-section.

Several pencils are manufactured in this shape, rather than the more traditional round or hexagonal barrels. They are usually promoted as being more comfortable or encouraging proper grip (if marketed for children), as well as having the advantage of not rolling off tables.

This shape is used for signing for the National Trails System administered by the United States National Park Service.^[3]

Three-dimensional version

The intersection of the balls of radius s centered at the vertices of a regular tetrahedron with side length s is called the Reuleaux tetrahedron, but is not a surface of constant width. It can, however, be made into a surface of constant width, called Meissner's tetrahedron, by replacing its edge arcs by curved surface patches; alternatively, the surface of revolution of a Reuleaux triangle through one of its symmetry axes forms a surface of constant width, with minimum volume among all surfaces of revolution of given constant width.

Mercx2009-06-04 07:22:10

[GoLefty!!]

a almost perpetual motion machine...?

[AndreZA]

Ha ha!, a drill bit that can drill an almost perfect square.

[straatvark]

 

 

But I do know why he didn't go for a spoked wheel. 

 

Compression required?

 

Put reality to "stay on TOP of your wheels"

 

[epoh]

What kind of guy would have invented this ?

 

 

[Jon0]

A clever one? haha jj

once u get it rolling surely it will keep on going cause once at the top of the triangle you get a down hill effectivly and then the up hill the front wheel pulls it because it is at a diffrent angle?

[_im_from_earth]

thats what they use in a wankel/ rotary engine right?

[TNT1]

 

thats what they use in a wankel/ rotary engine right?

 

Like so:

http://upload.wikimedia.org/wikipedia/commons/f/fc/Wankel_Cycle_anim_en.gif

 

[Fleming]

 

The inventor of this strange bike can only be a mathematician. Lets see who guesses why. I'll post links to the website once we have some suggestions as to my hypothesis.

 

http://images.china.cn/attachement/jpg/site1007/20090507/001109b42f980b6cb83515.jpg

 

I would love to see a video of that working. Anyone know of any youtube links