Robots With Square Wheels?

Roland Piquepaille writes "About eighteen months ago, I told you about a tricycle with square wheels which needed a specially designed road. But now, Distributed Robotics, a company from Troy, N.Y., is developing robots with square wheels which don't need specific roads. These new 'cars' propel themselves on flat surfaces by taking advantage of gravity. This might sound crazy, but the inventors think it could lead to new robots and toys, and more generally to new micro-machines or MEMS applications."

question

[baldass_newbie]

So, instead of a donut for a flat, do you get a danish?

Coral cache link to video

[ThomasKregaard]

http://www.globalcomposites.net.nyud.net:8090/Rein venting%20the%20Wheel%201.mpg [nyud.net]

Triangular wheels are optimal.

[Rufus88]

I prefer apple turnovers.

Re:Triangular wheels are optimal.

[HermanAB]

Triangular wheels are indeed better - they eliminate one bump.

ROTATING TURRET OF DOOM!

[LiquidCoooled]

OMG

"The shifting weight sequentially drives each wheel that is under the weight to sit flat on the ground, thus moving the other wheels in a rotational manner, and the car in a linear direction; reversing the direction of the rotating weight, reverses the direction of the car. There are also several methods for steering the car that are under development" says Steven Winckler, President of Global Composites.

This thing has a rotating hammer around its roof and just moves around based on the shifting weight.

Thats should be fun on the motorway in a morning

Why are folks so obsessed with literally reinventing the wheel?

Re:ROTATING TURRET OF DOOM!

[mwvdlee]

Why are folks so obsessed with literally reinventing the wheel?
Because if, against all odds, you managed to do it, you'd be rich and famous beyond your wildest dreams.
Besides, what's the challenge of trying to invent something when people believe it _can_ be done?

Re:ROTATING TURRET OF DOOM!

[saskboy]

"Because if, against all odds, you managed to do it, you'd be rich and famous beyond your wildest dreams."
Firestone invented new wheels for Ford Exploders, and it didn't make them rich.

Re:ROTATING TURRET OF DOOM!

[geminidomino]

Besides, what's the challenge of trying to invent something when people believe it _can_ be done?

"It's the simplest machine in the bloody universe!" -Ford Prefect

Why comprehending TFA is important too

[Legion303]

"Thats should be fun on the motorway in a morning"

True. Running over "robots, micro machines, novelty toys, and others" on your way to work might give you a flat.

Re:Why comprehending TFA is important too

[TERdON]

Because less parts = cheaper...

Re:Why comprehending TFA is important too

[orasio]

If your question is: WHY you cant find the motivation behind this?
Then the answer is: because you are not an engineer, or an engineering-oriented person. Don't worry about that. It's just not for you.

Re:Why comprehending TFA is important too

[orasio]

Of course.
But that's another deal.
One thing is understanding the motivation behind the devlopment of an idea, and another is finding practical uses. The OP asked WHY, and said that the wheel was the simplest approach.
What I say is that maybe the wheel is not the simplest approach in every case. IF this did work, it might have applications in places with different physics involved than your average road. The motivation of resaerching is that if you don't challenge the simplest designs you know, you will neve

Re:ROTATING TURRET OF DOOM!

[chris_eineke]

Why are folks so obsessed with literally reinventing the wheel?

Because it makes you go in circles?

Re:ROTATING TURRET OF DOOM!

[big_a]

Why are folks so obsessed with literally reinventing the wheel?

Because they've already invented a better mousetrap?

Re:ROTATING TURRET OF DOOM!

[kinnell]

Why are folks so obsessed with literally reinventing the wheel?

Because when you're making machines at microscopic scales, you get a whole new set of problems. Lubricating bearings is difficult, because conventional lubricants are too viscous. Assembling complex devices is difficult, because you need complex devices to do it. And reliably creating smooth round surfaces is difficult because irregularities in the material cause rough surfaces. Flat surfaces are easy to make - just shear a crystaline material.

Re:ROTATING TURRET OF DOOM!

[LiquidCoooled]

How exactly can you make a motorized rotating turret without doing all of the things you just suggested were difficult.
Read my other posts on this subject to see that I am already aware of these kinds of problems.

Re:ROTATING TURRET OF DOOM!

[MindStalker]

As article and other poster suggested you can get rid of the turrent and use electro magnets on the ground that shift position, but then again I can use electromagnets that shirt position to pull the dang thing around anyways :)

I think the really hard part on a microscopic scale would be linking the wheels together.

Re:ROTATING TURRET OF DOOM!

[SnowZero]

What about the belt or chain that is currently needed to connect the two axles? That doesn't sound easier to make than a more circular wheel.

Re:ROTATING TURRET OF DOOM!

[Carnildo]

Because you can replace the belt with three co-planar gears, and gears are very easy to make - one of the first micro-scale inventions was a set of three co-planar gears.

Re:ROTATING TURRET OF DOOM!

[RPI Geek]

Why are folks so obsessed with literally reinventing the wheel?

The contact information at the bottom of the page gives it away if you know the guy, which I do: Steve Derby was my advisor and one of my professors at RPI just this past spring. He's the type of person who loves to tinker with new ideas and who will probably come up with a revolutionary solution to some problem. Our projects for that class involved coming up with an idea that interested us and running with it for a few weeks (using the met

Re:ROTATING TURRET OF DOOM!

[vertinox]

Why are folks so obsessed with literally reinventing the wheel?

So they can patent it.

Re:ROTATING TURRET OF DOOM!

[colmore]

From the article it seems like an interesting solution to a specific problem. Imagine the way running works in bipeds, you create imbalance so you're always falling forward and catching yourself. It's a good way of maintaining momentum over rough terrain.

Do you have stairs in your house?

[Big Nothing]

With square wheels, these new and improved robots are especially well adapted to climbing stairs. Do you have stairs in your house?

Re:Do you have stairs in your house?

[Anonymous Coward]

Of course! How else would I keep the daleks out?

Credit goes to somebody for this:

[SamSim]

True Daleks don't climb stairs: they level the building. (More pedantically, Daleks can fly.)

Tip it's center of gravity and all bets are off

[Anonymous Coward]

With a drive system that relies on gravity and a horizontal swinging weight, these Rube Golberg contraptions would be especially ill-adapted to climbing any inclined surface.

Put it at a stair-climbing angle and when the hammer swings to the back it'll just tumble backwards.

Re:Tip it's center of gravity and all bets are off

[corngrower]

If the attraction between the surface and the wheels and rotating mass were to be magnetic, or due to static charges, I could see this thing travelling upside-down, directly up walls, or any direction whatsoever.

Square wheels wouldn't help anyway

[Anonymous Coward]

A few moments playing it out in your head will make it obvious that square wheels are actually worse at climbing stairs than round ones. Sitting on them, sure. Climbing them, not so much. A star-shaped wheel might be better, but it'd have to be big (each flat side as long as the step itself) which means a big vehicle, which means a big, heavy swinging hammer jerking the vehicle in every direction on it's way up.

And that still wouldn't work, even if you shifted the hammer forward to keep it from throwing

Re:Do you have stairs in your house?

[stienman]

Do you have stairs in your house?

noo, you cannot come here go away robot, you are scaring me

-Adam

Re:Do you have stairs in your house?

[Hognoxious]

Why the hell anyone would think square wheels is a good ideas is just beyond me.

You can park on a hill and the car won't roll away.

Next up

[NorwBlue]

Rev.2 will have triangelshaped wheels. The benefit You might ask? Well, 1 less hump pr. rotation.

Re:Next up

[jurt1235]

Pentagonal shaped wheels will perform better since the humps and bumps will be smaller, also the energy needed to get over the dead point will be smaller.

Next version: Hexagonal shaped wheels?

Maybe the invention of the round wheel was a step back in the technical evolution. Maybe this explains how the "fill in a race which moved unbelievable large objects without wheels" build their "object".

Re:Next up

[cjanota]

With more sides though, the difference in radial distance is reduced and the moving of the weight would do less. The limiting case would be the circle where shifting the weight does nothing.

Re:Next up

[Fordiman]

Actually, if you think about it, it's all based on angular acceleration versus potential energy.

Essentially, you'd need to generate geometric identity per-rotation. On a triangle, that would mean a 30 deg turn per-wheel for triangular (rotate an equilateral triangle 120 deg and you have its identity. Divide that by four wheels and you have your needed angle). That means the weight would need to move the assembly by a larger angular interval per 1/4 rotation. Possible efficiency problems with smaller an

see, that's the problem with most geeks...

[circusboy]

the rest of us would look for ways to increase the humping...

Re:Next up

[Ced_Ex]

And then, some genious will invent ROUND wheels that have NO humps when rotating!

I guess you can certainly count yourself out then, huh?

Reinventing the Wheel

[AthenianGadfly]

I think this is a really good idea for moving any sort of vehicle forward. However, I have an idea that might make it even more efficient... perhaps they could cut off the corners of the wheels to create an octagonal wheel, which would mean less force would be required to turn the wheel. Maybe, somewhere down the line, it could be expanded even further to have more sides and even fewer sharp angles. Now that I think of it, perhaps the edge of the wheel could be configured in some sort of smooth "curve" to eliminate corners altogether... hmmm... imagine what it could evolve into someday.

It looks like these improvements of mine could really take off and go somewhere. I'd better patent it.

Re:Reinventing the Wheel

[ArsenneLupin]

I'd better patent it.

Too late. It's already been done! [bbc.co.uk]

Re:Reinventing the Wheel

[ArsenneLupin]

Along with all the colors of the rainbow.

No, not all of them. They only patented the various shades of blue.

Pattented the shades of blue

[QMO]

Even the Hooloovoo?

Then we may be in trouble.

Lasers?

[Anonymous Coward]

This might sound crazy, but the inventors think it could lead to new robots

Will these be killer robots with lasers? If so, put me down for about 50 of them, and deliver them to Roland's place.

An intriguing challenge for mathematicians.

[Strolls]

The tricycle article says:

So far, no one has found a road-and wheel combination in which the road has the same shape as the wheel. That's an intriguing challenge for mathematicians.

but this seems to me to be most obviously untrue. A conventional road has the same cross-section as the planet it's built on... so a hypothetical flat road encircling the globe is as near as damnit circular. Now what shape are wheels? An intriguing challenge for mathematicians and bloggers, perhaps.

Re:An intriguing challenge for mathematicians.

[whopis]

A conventional road has the same cross-section as the planet it's built on... so a hypothetical flat road encircling the globe is as near as damnit circular. Now what shape are wheels?

You are correct that a conventional road is circular (or at least much closer to being circular than the straight line that we perceive it to be). However, the constraints of the problem (from the article) included "keeping the axle moving in a straight line and at a constant velocity". Clearly a conventional road fails

Re:An intriguing challenge for mathematicians.

[Eivind]

But equally clear, the challenge as stated, is unsolvable. Any reasonable definition of "wheel" requires it to be able to turn multiple rounds, in effect a wheel must be a closed loop.

If the road is the same shape, then the road must also be a closed loop.

There's no way a vehicle can move straigth along a road that is a closed loop. At best it could move straigth for a short while, but eventually the road has to curve to be able to close back on itself.

Re:An intriguing challenge for mathematicians.

[TERdON]

Isn't there even a possibility for a solution in a non-euclidian geometry?

Re:An intriguing challenge for mathematicians.

[SomeoneGotMyNick]

Isn't there even a possibility for a solution in a non-euclidian geometry?

Only in LSDian geometry. Wait, that's showing my age... It's in Extacian geometry. But then again, you forget about it by morning.

Re:An intriguing challenge for mathematicians.

[Kadin2048]

Yes, but IMO the non-Euclidian solution is rather trivial: you have a wheel rotating around and following a straight cirumferential (great or small circle [wolfram.com]) path on a sphere. Being on a sphere, the wheel's path can be "straight" and also a closed loop. You could also have a solution on the curved surface of a cylinder

Whether or not that's an acceptable solution to you depends on how you define "straight" in the problem originally. If you take it to be something like 'a path whose coordinates remain constant

Re:An intriguing challenge for mathematicians.

[Hognoxious]

you have a wheel rotating around and following a straight cirumferential (great or small circle) path on a sphere.

Already proposed, already shot down: moving in a circle involves a change in velocity.

My solution is to make the wheel any darn shape you like, and have the road fit exactly to it, all around. Then the velocity will be constant - constantly zero.

Infinite Loop

[SteveM]

There's no way a vehicle can move straigth along a road that is a closed loop. At best it could move straigth for a short while, but eventually the road has to curve to be able to close back on itself.

It could if the loop was infinite.

SteveM

Re:Infinite Loop

[Eivind]

Not really. A infinite circle is still only *locally* straigth, not globally straigth.

Re:Infinite Loop

[SteveM]

But the loop will always appear local to the vehicle.

At best it could move straigth for a short while, but eventually the road has to curve to be able to close back on itself.

In the case of an infinite loop, the "short while" also becomes infinite.

SteveM

Re:An intriguing challenge for mathematicians.

[slashname3]

Didn't you just define a tank tread? Seriously, ;) isn't a tank tread a closed loop road way that the wheels of the tank drive on?

Re:Well duh

[Eivind]

Like mostly in such cases, the real problem is in the problem-definition. I was fully aware that it was unlikely that mathemathicians had spent significant time on a problem without discovering something as obvious as this. Still -- the problem as stated has this problem. I can't help it that what they're actually asking is not what they mean to ask.

The problem, as restated by you (the wheel must consist of segments, and the road of identical segments) also inituitively seems unsolvable to me. Essentially

Re:Well duh

[Eivind]

Yeah I know what they're asking. I just think the answer is: There's no solution to this puzzle. I even consider it pretty likely that serious mathemathicians know this, and only somehow that knowledge failed to influence this article.

As to the point of Slashdot, that's a good question :-))

Obligatory

[connah0047]

I think they are trying to reinvent the wheel here...

Why?

[Big Nothing]

I have to ask: why? What is the advantage of this means of propulsion? What are the special applications for this system?

It's not a perpetum mobile; it needs energy to work, just like any other propulsion system. It seems to me that this type of propulsion would have a significantly lower efficiency than an ordinary, circular wheel system.

Neither the article, nor the homepage [globalcomposites.net] (which just went on it's knees, so don't bother clicking the link anytime today. They have a counter that will only go as high as 999

Re:Why?

[Sarmis]

Sometimes reading the article reads to fascinating statements, which answer the question you apparently pose after reading only the blurb. Such as this tidbit: ""For use in micro-machines or MEMS applications, one of the key benefits is that the motor and gearing moving the shifting weight is all in a plane parallel to the motion surface. No right angle gearboxes are required. The connection between the two axels can be accomplished by simple linkages""

Re:Why?

[KlaymenDK]

I RTA, and I I think this is very neat (if not elsewhere, this could at least be very useful in wheel-and-circle-deficient Lego builds! ;o) ).

Still, I don't see it. Surely, if you keep the axle linkages, sand the wheels down, and merely rotate the motor 90 degrees so its drive shaft is parallel to the axles, that would also yield propulsion without right-angle gearing, no? Granted, you would need a chain drive or a (non-angled) set of gears to connect motor and axle, unless the axle IS the drive shaft.

Re:Why?

[Suidae]

Rotating the motor might make it harder to build the motor. If you are producing the motor and weight assembly using lithography it would probably be easier to build the motor so that the output shaft is vertical with a weight that it can swing around in a circle.

I wish the article had gone into some more detail about the construction techniques so we could more easily see the problems that this solves.

I think its a clever bit of technology, although I'm curious about the linkage between the front and rear

Re:Why?

[Grimster]

Because it's a new way to do an old task. Is it practical? I don't know, how many "impractical" or "silly" things later were found to be extremely useful?

Looking at the article I was just struck with a sense of "whoa neat" at the simplicity of the idea yet the fact (as far as I know) it's never been done before (using a "helicopter" of shifting weight to propel a car forward by it's properly aligned square wheels). Sometimes it's not so much "why?" but "why hasn't anyone ever thought of this before?".

Re:Why?

[Yartrebo]

I belief is that the problem is getting enough normal force to make the thing work. Micromachines (machines in the 1 to 1000 micrometer range - not the trademark) tend to be very light and at such size scales, gravity becomes less and less significant.

Anoher probable problem (unless you happen to be the patent holder) is that this is apparently patented, which means it's unlikely to be seriously researched until said patents expire.

Re:Why?

[Cyn]

because you have to have a large enough counter-weight above to remove enough of the vehicle weight from the opposing wheels to allow them to rotate. At car sizes, you're basically talking about swinging another car above you - trying not to tip over - and all the while slowly stumbling along with a rough ride - and twice the weight you need to be pulling along.

As far as I can see, this would only be practical at smaller sizes, because of the simplicity of the design. Think small robots/vehicles.

I'd love

Re:Why?

[Potor]

The beauty of a university (even in this age of patents, industrial parks, and spin-offs) is that in theory any problem can be investigated without having to be justified. Who knows if this experiment will go anywhere (pun really not intended), but the ultimate (perhaps, commercial) form of any pure research is quite hard to imagine ab inititio.

I know that you are just asking a question, and indeed a good question. I am simply trying to forestall the opinion that because the advantages are not immediately to be seen, this must be a waste.

Re:Why?

[GileadGreene]

The beauty of a university (even in this age of patents, industrial parks, and spin-offs) is that in theory any problem can be investigated without having to be justified.

That may well be the theory. The practice is very different. Research (even "basic" research) requires funding to pay for time, equipment, and grad students. That means you need to be able to sell a funding agency on what you are doing. Which in turn means that you need to be able to justify your research somehow. Now, granted, you don't

Re:Why?

[Potor]

I am well aware of the hijacking of the university, and the supression of free research. Curiously, this has gone hand in hand with the increasing ownership of knowledge (don't tell me patents are only for designs and implementations), and the rampant commercialisation of our faculties. Actually, it is not the curious at all. It's called greed, or at least short-sightedness.

And this 'theory' you talk about - well, that's the very basis of the university, and it also contributes to the idea of tenure. Theor

Help for the retarded

[GodSpiral]

There's 2 reasons this is useful.

1. At small scales rolling resistance is much higher. -- because surface smoothness is relatively much choppier. -- benefit of round wheels and gliding potenitial is much less.

It moves by wobbling from side to side with a weight moving like a helicopter rotor to sequentially push down on each wheel. so,

2. This simplifies small scale motion, because you dont need gears, axels or chains to transfer motor rotation into differen axes.

Explanation for the mechanically challenged.

[Sparr0]

The vehicle described here, and built as a prototype, has 4 square wheels each with different orientations (evenly spaced). When the front left wheel sits flat the rear left wheel is 1/16th of a turn from being flat. Shifting the center of gravity of the car towards that rear left wheel causes it to 'fall' forward to sit flat, which rotates all 4 wheels 1/16th of a turn. The front left wheel is now 1/16th past flat (and 3/16ths from the lying flat on its next side) and the rear right wheel is 1/16th from being flat. Shift the weight to the rear right and it rolls forward another 1/16th of a turn. This produces moderately wobbly and slightly jerky motion, but could prove to be a simpler method of locomotion at very small scales, especially if magnetism instead of gravity is used to pull the wheels down/forward.

Toys? Seriously?

[Sockatume]

I don't know how parents will take to a toy with four spinning pointy wheels and a rotating hammer on top.

Where's Rudolph when you need him?

[Woldry]

::sings:: Weeee're on the islannnd of miiiisfit tooooyyyys....

Okay, I'll go sit in my [square] corner now.

Subscribers

[$RANDOMLUSER]

The next blog entry on a page hit whore's site is ready now, but subscribers can see it early.

Misfit train..

[Vellmont]

Looks like Rudolph's [imdb.com] misfit train [groundspeak.com] will finally have a purpose.

Link mirror

[a_nonamiss]

I'd like to see this square-wheel-robot in action, but the link to the video on the site has obviously been slashdotted, or else they're running the whole site off a dial-up modem. Anyway, according to Firefox, it's going to be another 12 hours before I can see the video. Any chance anybody saved it before it got slashdotted and can post a mirror somewhere? Here was the original link: http://www.globalcomposites.net/Reinventing%20the % 20Wheel%201.mpg [globalcomposites.net]

Re:Link mirror

[keeboo]

You may download the video from

[cefetpr.br]ftp://mirror.cefetpr.br/pub/misc/Reinventing%20the %20Wheel%201.mpg [cefetpr.br]

'Tis the season!

[Equis]

I just saw this great report on television the other day. It turns out no one wants a Charlie in the Box, a squirtgun that squirts jelly, or a robot with square wheels. They're all just Misfits.

Oh, and Bumbles bounce.

Perfect for the Scion Xb or the Honda Element

[digitaldc]

Now you can have square wheels to go with your box car

Re:Perfect for the Scion Xb or the Honda Element

[Wiseazz]

How about ugly wheels to go with my Mom's Aztec?

In other news...

[Quixadhal]

Scientists make use of extensive surplus budget to create the new threadless screw.

"We think this new screw will help the industry by providing a less complex fastening device for the end users, and it should be more economical for manufacturers as well."

The new threadless screw serves the same function as a traditional screw, but doesn't require a complex torque-riddled installaton process. Simple repeated impacts will drive the new screw home with far less effort.

"The average consumer is often frustrated with traditional screw technology. Do you need flat heads, phillips, star-point? Will sheet metal screw threads work, or do you need the heftier wood threads? Self-threading points, or rounded? It's mind-boggling! These new screws are great. They only have one head type, and you just pick the length and heft you need. That's all!"

Scientists expect the threadless screw to be a big hit in 2006, and look forward to tackling the next problem at hand.

"We're thinking of developing a shorter lever next year... One that doesn't require so much space to operate. It will have less leverage, but most people don't really use the leverage their current levers provide."

Woooooooooosh......

[Overzeetop]

Not only did you miss the joke, you didn't even ge the right fastener.

Re:In other news...

[everphilski]

You hit the nail on the head. Not really.

-everphilski-

Reversing is Simple

[giafly]

Just replace the offset weight by a helium balloon.

square wheel to circle to square again

[Anonymous Coward]

It seems that we have come full square...

Mindstorms

[Siener]

Looking at the photo in the article, this seems like a perfect project to implement in Lego Mindstorms. Anyone up for it?

Re:Mindstorms

[RPI Geek]

You wouldn't even need Mindstorms, you could do it with regular Technix parts :)

Next up: Bread

[Nerdposeur]

In other news, baking researchers have found a new way to create bread segments that requires fewer steps than traditional slicing.

How does it turn?

[CheeseTroll]

Turning would mean that the outside wheels would cover more distance, which would throw off the synchronized movement of the 4 wheels.

Getting the corners sharpened?

[dpbsmith]

"Honey, I need to take the car to the tire shop and get the corners sharpened."

Even on a small scale, concentrating the weight on even a rounded edge like that would seem an invitation to excessive wear, both on the wheels and on the surface it runs on.

About as practical as high heels.

how do you turn?

[Cyn]

extremely slowly and carefully?

From what I see, this whole design is only practical at small scale, where the simplicity is needed. I've been wrong before though.

I did it!!!! do i get a prize?????

[Artfldgr]

no one has made a road and a wheel in which the two are the same? obviously this person has never used a gear and rail... duh...

How does it decide which direction to move?

[Paul Crowley]

It looks like it could set off in the wrong direction, or just rock back and forth. What decides which direction it moves in?

Re:How does it decide which direction to move?

[Paul Crowley]

Sweet - thanks!

To be driven by an elf who wants to be a dentist

[karlandtanya]

Cat got your tongue? (something important seems to be missing from your comment ... like the body or the subject!)

Cool!

[Fantastic Lad]

What a neat idea!

Heck, walking is a kind of controlled falling using weight management and multiple levers; Lean forward and flip out your leg thingies to stop yourself from crashing. Repeat.

Rah rah for useless research! Science for the heck of it!

-FL

Micro-machines!

[Necromancyr]

They're bringing back Micro-machines now too? Great! I loved those things...will the fast talking guy be back also?

My favorite part ...

[jc42]

... was the paragraph:

The main driving force for the table top prototype is produced by gravity pulling downward. Other forces that could hold the car against a surface, and provide the moving force necessary to increment the car along, include aerodynamic, hydrodynamic, magnetic, electromagnetic, and electrostatic. Such forces could be independent of the car mass, and could thus propel the vehicle with much greater force and velocity. In some instances, these forces could provide their own means to move fr

Re:it takes work to spin the weight

[jc42]

Yeah; I understand all that. But I was talking about a paragraph of the article, where the author stated that "these forces could provide their own means to move from wheel to wheel".

This sure sounds like they think that the gadget could be pulled by gravity (for example) in such a way that when one wheel is pulled down, gravity itself will also move the rotating mass to the next wheel. This sort of thing is historically the basic of most designs of perpetual-motion machines. Somehow the designers are ne

driven by...

[Hognoxious]

The main driving force for the table top prototype is produced by gravity pulling downward.

So as long as the earth continues to exist, we have a perpetual motion machine?

Roll me up!

[argent]

All the cars on the earth(which is round) has round wheels!!!!

Yes, but only Katamari Darmacii can build a car big enough to take advantage of that.

Ten steps ahead

[bradleyland]

Ten steps ahead would mean tetradecagon wheels, not hexagons ;)

Re:Why we need this invention

[theLOUDroom]

Any day now someone is going to figure out that the current rules let you patent the circle.

Actually, somebody already did. [cnn.com]

Re:MEMs and gravity don't mix

[Breakfast Pants]

Then charge the thing and use an opposing charge on the surface to simulate gravity.