Calculating the force on a Crankshaft in a Steam Engine

AI Thread Summary
To calculate the force on a crankshaft in a steam engine, it's essential to understand the relationship between the piston force and the crankshaft dynamics. The force exerted by the piston can be determined using the formula for pressure times the piston area, and this force translates to the crankshaft through the connecting rod. The torque on the crankshaft, which varies with the crank's rotation angle, is crucial and is calculated as the force multiplied by the lever arm distance. The discussion highlights the importance of considering both x and y components of forces at the crankshaft's connection to the flywheel. Understanding the velocity of the piston and the geometry of the system, including the angle of the flywheel, is also necessary for accurate calculations.
Mellorillo
Messages
3
Reaction score
0
Given that I have a steam engine, and now its size, the size of the piston, the length of its stroke and the force acting on the piston at certain points, I need to calculate the force on the crankshaft.

Now, I now that Fx should be the same where the piston meets the crank, and we can ignore Fy at this point I think, since there is no friction. But how do I calculate the force at the other end of my crank? Where the crank pushes the flywheel?

Since i don't really want people doing all the work for me I figured I needn't include variables, just some theory work from you guys would be much appreciated.

Finally, am I right in thinking i need to know the velocity of my piston, and thus my crank(Or at least the velocity of one point) I also now the RPM of the flywheel when the piston is a t top dead centre (I.e fully closed)

Hope that covers everything thanks in advance!
 
Physics news on Phys.org
Now, I now that Fx should be the same where the piston meets the crank, and we can ignore Fy at this point I think, since there is no friction. But how do I calculate the force at the other end of my crank? Where the crank pushes the flywheel?

I guess you have a pistom, connecting rod, and crankshft ( attached flywheel).
Perhaps you should do a fbd of the connecting rod to determine your forces at your pins, knowing that with a pin connection the force will be along the centrerline of the member ( or from centre of one pin to the other ), Is there really no y-force?
 
Done a free body.
I can't think of what the y force would be? there should be none on the piston (other than gravity and some force N pushing up on the piston but since there is no friction i ignore these right?)
Though there will be an x and y component of the forces on the pin at the other end of the crankshaft where it meets the fly wheel.
Finding these forces is proving to be a problem.

I know the force on the piston at a point B as the steam expands. (Pressure*pistonArea - ambientPressure*piston diameter) so that should also be my Fx where the piston meets the rod, but how then do I go about finding the force at the other end of the rod? Does finding the velocity help?

I think a friend mentioned finding an equation X in theta (where theta is the angle of the flywheel out of the 360 degrees in a revolution) but I am unsure how to do that, Trigonometry using the flywheel radius and the rod maybe?

Thanks for your time
 
I would think the germane question is what is the torque, not the force, on the crankshaft.

The force is just the force of the piston. The torque is that force times the lever-arm imparting torque to the crankshaft. That torque is of course time-varying with the rotation angle of the crankshaft.
 
The torque you reckon? Which is the force translated to the fly wheel?
By lever arm do you mean the rod length? or the distance from the pin on the fly wheel to the fly wheel centre?
 
Thread 'Have I solved this structural engineering equation correctly?'

Thread 'Have I solved this structural engineering equation correctly?'

Hi all, I have a structural engineering book from 1979. I am trying to follow it as best as I can. I have come to a formula that calculates the rotations in radians at the rigid joint that requires an iterative procedure. This equation comes in the form of: $$ x_i = \frac {Q_ih_i + Q_{i+1}h_{i+1}}{4K} + \frac {C}{K}x_{i-1} + \frac {C}{K}x_{i+1} $$ Where: ## Q ## is the horizontal storey shear ## h ## is the storey height ## K = (6G_i + C_i + C_{i+1}) ## ## G = \frac {I_g}{h} ## ## C...
View full post »

Similar threads

Questions to do with crankshaft of an engine
Replies
32
Views
7K
Internal combustion engine calculation questions
Replies
9
Views
3K
B How to calculate the efficiency of a steam engine?
Replies
10
Views
1K
Engineering Can I assume that any steam turbine is isentropic?
Replies
1
Views
2K
Advanced Hydrodynamic Problem - University level
Replies
49
Views
4K
On-demand steam engine idea
Replies
14
Views
2K
Steam boiler efficiency calculations
Replies
10
Views
2K
Automotive The reason for the low efficiency of the ICE - zero shoulder crankshaft
Replies
13
Views
2K
Gas - cylinder - piston problem
Replies
1
Views
2K
Calculating Centripetal Acceleration of a Locomotive's Crank Pin
Replies
1
Views
2K

Hot Threads

Recent Insights

Back
Top