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4-cylinder Pogo Stick

Using the 4-stroke combustion cycle
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While there is a Product:Toy:Pogo Stick category, when talking about fuel-powered pogo sticks and transportation, the "toy" category is not really appropriate. A couple items in that category (linked) should probably be moved to this one.

The fundamental compression/explosion aspect of an internal combustion engine is ideally suited for pogo sticks, since there is no need to convert reciprocating motion into rotary motion. However, the 2-stroke combustion cycle used by most fueled pogo sticks is environmentally dodgy (skip next paragraph if you already know why).

In the conventional 2-stroke cycle, a fuel-air mixture is compressed. Then a spark ignites the mixture. At the end of the expansion/power stroke, openings in the side of the engine cylinder allow hot gas to escape, while simultaneously allowing fuel-air mix to enter. Pollution can occur because some of the fresh fuel can also exit the exhaust port.

A Diesel version of the 2-stroke cycle (one of the linked Ideas) could theoretically be cleaner, since fuel is added separately from the fresh air. But in practice the art of fuel-injection is imperfect, and not all the fuel burns cleanly, leading to the typical black smoke emitted by Diesel engines.

The 4-stroke combustion cycle can definitely be cleaner, so that is what I'll describe for this Idea.
O_O
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O_O
The above ASCII sketch (ignore the underscores) tries to show (overhead view) how the central column of a pogo stick should be associated with 4 engine cylinders. From underneath, the central column would have 4 piston rods attached to it; all the pistons would go up and down together in the cylinders. I'm specifying 4 cylinders solely for reasons of Dynamic Balance; 2 could work if you didn't care about such things.

I'll talk about 2 in this paragraph just to show how it works. One cylinder has fuel-air mix getting compressed, while the other cylinder is doing an "exhaust stroke" --a valve is open allowing the waste gas from the previous cycle to be pushed out. Then the exhaust valve closes and an intake valve opens for that cylinder, while the other cylinder gets the spark to ignite the compressed fuel-air mix. The power stroke in that cylinder allows the other cylinder's piston to suck fresh fuel-air mix. The intake valve closes, and now this description repeats, with one cylinder doing compression and the other doing exhaust.

In the 4-cylinder engine, 2 would be compressing and 2 would be exhausting, and so on. In the ASCII sketch, Dynamic Balance is achieved by pairing the cylinders on directly-opposite sides of the central column (such as lower-left with upper-right). The cylinders in each pair are always doing the same part of the combustion cycle together.

Next, the art of electric-powered engine valves has been developed to the point (linked) where that would be the most practical way to control the valves for this engine.

The engine can be air-cooled, since we all know a pogo stick won't be doing very many combustion cycles per minute (remember that air-cooling can work for, say, lawnmowers, which may have 1000 combustions per minute). The cylinders can also be smaller-diameter than the single cylinder of already-existing fuel-powered pogo sticks, simply because we get power from 2 at a time, and we don't really want the pistons to come all the way out of the bottoms of the cylinders, with the rider and the tops of the cylinders going unsafely high.

(The math says that if 2 smaller cylinders have the same interior total volume as 1 larger cylinder, and their lengths are the same, then the diameters of those 2 cylinders can be about 30% less than the diameter of the 1.)

Finally, we add something to the top of the pogo stick, known as a "tuned mass damper" (linked). Under electronic control and moved with electric power, this can ensure that the overall pogo stick remains generally upright (like a Segway), and doesn't tip over too far, as the rider bounces his or her way down the road.

Vernon, Dec 20 2011

An earlier IC pogo stick Idea Internal_20Combustion_20Pogo
As mentioned in the main text. [Vernon, Dec 20 2011]

Another transportation pogo stick Segway_20Pogo_20Stick
As mentioned in the main text. Gyros are actually not the right way to balance one like a Segway. [Vernon, Dec 20 2011]

A short history of fuel-powered pogo sticks http://io9.com/5790...powered-pogo-sticks
So far as I know, the notion of using the 4-stroke cycle is new with this Idea. [Vernon, Dec 20 2011]

Electric engine valves http://solenoidvalv...ves-in-engines.html
As mentioned in the main text. [Vernon, Dec 20 2011]

Tuned Mass Dampers http://en.wikipedia...i/Tuned_mass_damper
As mentioned in the main text. Normally they help skyscrapers resist earthquakes (keeps them from tipping over too far, perfect for this Idea!) [Vernon, Dec 20 2011]


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Annotation:







       Nice comeback, [Vernon]. [+]
Alterother, Dec 20 2011
  

       2 cylinders could also be balanced if they are stacked one above the other. The connecting rod will have to fork around them, instead of the cylinders forking around the central rod.
pocmloc, Dec 20 2011
  

       [pocmloc], if the two cylinders are one-above the other, then together they count as a single cylinder which would also need to be in-line with the main shaft of the pogo stick. Otherwise that double-cylinder would be off-center, of the main stick, and make the whole thing not dynamically balanced.
Vernon, Dec 27 2017
  

       Well yes that was assumed.
pocmloc, Dec 28 2017
  


 

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