Piston size and proportionate forces

In summary, the smaller piston would have a greater propensity to overcome the radial friciton of the piston rings.
  • #1
gloo
261
2
Given the same radial force and combustion pressure, would it be correct to say that the larger diameter piston would have a greater propensity to overcome the radial friciton of the piston rings? That is would a 50cm piston diameter overcome the friction than say a 25cm diameter piston easier (with the same combustion pressure).
 
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  • #2
Yes. That is one reason why 4-piston engines are generally more efficient than 8-piston engines. Another reason is that the volume to surface ratio of the combustion chamber is higher, which relates to convection heat loss after ignition, while the burned gas is pushing the piston down. This might be one reason Cadillac dropped its V-16 engine, and the Lincoln Zephyr its V-12.
Bob S
 
  • #3
the bigger piston is going to have more drag than the smaller one. regarding cc volume and pressure..if you have two IC with same comp ratio this means same force..right?
so F x D /T = Power..would not the 4 cyl make less power simply by the number of cylinders?
 
  • #4
With the same CR you'd have the same pressure in the cylinder. You'd have more force with a larger piston.

F= P*A

If you had a 4 cylinder and 8 cylinder engine, both 2 litres.

The 4 cylinder would make more torque, but big hefty pistons give huge stresses ad it wouldn't rev as high. The V8 could rev higher and make more top end power, but less overall torque.
Back in the 90's F1 teams had a free reign over the number of cylinders they could use, but capped at 3.5L.
Ferrari always made the most top end power from their V12, as it was also the highest revving engine on the grid at about 15000-17000 rpm.
The Ford V8 was down on power to the ferrari as it couldn't rev nearly as high, but it was the most drivable engine on the grid due to a better torque curve. Revs ususally topped at 13000-14000rpm.
 
  • #5
exactly...Chris .. good one!

this is why i love this forum...the less cylinders will make more bottom end torque but rattle your teeth when revving.. firing a piston every 90 degrees the smoother V8 firing every 45 degrees will make more high end hp way smoother .. but will be less on torque...
 
  • #6
Ranger Mike said:
exactly...Chris .. good one!

this is why i love this forum...the less cylinders will make more bottom end torque but rattle your teeth when revving.. firing a piston every 90 degrees the smoother V8 firing every 45 degrees will make more high end hp way smoother .. but will be less on torque...
I have never understood for the uneven firing order of V8's. It is not left right left right etc. The exhaust manifold breathing sounds like xxxx. My old '41 Buick with a straight eight sounded much better. See table for V8's in
http://en.wikipedia.org/wiki/Firing_order
Bob S
 
  • #7
I know you can slightly alter power output characteristics with odd firing patters (not entirely sure how though). Also odd firing patterns only really occur in crossplane V8's. With flatplane cranks you can have an even firing order, with 1 bank firing like a straight 4 and the other bank firing like the mirror image of that straight 4.

Beyond that I'm with you wondering why they have an odd firing pattern.
 
  • #8
good info..my two cents is that in the old days..( here we go again) volume automotive manufacturers had to compromise regarding carbureation, smooth operation, power , longevity and production cost. the intake manifold layout has to consider single intake runner or siamese port design. The same goes for the exhaust ports. The central located carb means there will be a lean couple of runners and a rich couple of runners and half that are " optimum". Thing two was to develop a firing order with minimum stress induced on the crank and engine case (block). Note the weakest and highest stressed points on the crank are at either end. The middle throws are nested in the center of the case and have pretty good lateral support. These are the cylinders that light off ( cyl. 4) followed by the opposite bank piston (cyl3.) that is connected to that same crank pin. the end slugs like No. 1 fire followed by the opposite end No.8 slug. Manufacturing costs of single runner intake and exhaust ( like the Hemi) get real expensive compared to economy of scale mass production cost of siamese port design. Also crank balance shaft cost, assembly time, maintenance ..etc...figure in too.

Opps..i just looked at the firing order on a small block Ford and this theory just got shot down..
what do you think Chris?
 
  • #9
I really have no idea what I am talking about regarding this it's all just an educated guess, but each of the points you made makes sense. As to how relevant the engine manufacturers think they are in deciding a firing order I don't know.

I'd guess the uneven charge distribution in a plenum/single carb based intake would prbably be the most like course for them having odd firing orders. With reliabity of the crank coming in a close second.
You never know though, all this talk of power, stress and engineering reasons maybe tosh. It may be the sound the designer finds sexy.

The thundering rumble of a crossplane V8 vs the howl of a flat crank V8... it's a toss up as to which a prefer.
 

1. What is the relationship between piston size and proportionate forces?

The size of a piston directly affects the proportionate forces it can exert. A larger piston will be able to generate more force than a smaller piston, assuming the same pressure is applied to both.

2. How does piston size affect the efficiency of a system?

In general, a larger piston will result in a more efficient system. This is because a larger piston can exert more force, allowing it to do the same amount of work with less effort. However, other factors such as friction also play a role in system efficiency.

3. How do I determine the appropriate piston size for my application?

The appropriate piston size for an application depends on various factors such as the desired force output, available pressure, and size of the system. It is best to consult with a professional engineer or use mathematical calculations to determine the optimal piston size for your specific needs.

4. Can a piston be too large or too small for a system?

Yes, a piston can be too large or too small for a system. If a piston is too small, it may not be able to generate enough force to meet the system's requirements. On the other hand, a piston that is too large may be too heavy and require more pressure to operate, resulting in inefficiency.

5. How does piston size affect the speed of a system?

Piston size does not directly affect the speed of a system. However, a larger piston may require more time to reach its maximum force due to its larger surface area. This can result in a slower overall system speed.

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