How Is Force Calculated to Maintain Position on an Inclined Wedge?

AI Thread Summary
To maintain a block's position on an inclined wedge, the force (F) required is derived from the equation F = (M+m)((sinα-μscosα)/(cosα-μssinα))g. The discussion emphasizes the importance of drawing a free-body diagram (FBD) to accurately represent the forces acting on both blocks. Participants noted that resolving the forces into components parallel and perpendicular to the wedge surface is crucial for equilibrium analysis. Newton's first and second laws are applied to establish the relationship between gravitational force, friction, and acceleration. A clear understanding of these principles is essential for solving the problem effectively.
amajorflaw
Messages
2
Reaction score
0

Homework Statement


a block of mass (m) is placed on a bigger triangular shaped block with a mass (M). The wedge is of angle (α) . The coefficient of static friction between the two blocks is μs . What must the force (F) be in order to keep the smaller block at the same height on the wedge-shaped block? The answer is an equation in terms of the coefficient of friction, M, m, the angle and the gravitational acceleration. A FBD is also required. All laws must be documented and used properly.
clip_image002.jpg



Homework Equations


Newton's 1st Condition
Gravitational Acceleration
Definition of Friction


The Attempt at a Solution



I have the answer, but I'm having trouble getting to it.
The answer to the problem:
F = (M+m)((sinα-μscosα/cosα-μssinα))g
 
Last edited:
Physics news on Phys.org
You are missing another important theory, Newton's 2nd. Also, you should draw a free-body diagram to clearly communicate all of the forces being exerted on this body.

Casey
 
The acceleration of the system = a = F/(M + m )
the forces acting on the mass m are mg and ma. Resolve them into the components parallel and perpendicular to the surface of the wedge and find the condition for the equilibrium.
 
Yeah that's where I'm stuck. I'm not sure where all of the forces apply on the two blocks, so my free body diagram is wrong. It's not the equations that are troubling me. It's getting all of the parts to the FBD that is troubling me.
 
I'm not sure where all of the forces apply on the two blocks Both the blocks experience equal force in thr horizontal direction. You have to draw FBD for the body of mass m. As I have already mensioned, resolve them into the components parallel and perpendicular to the surface of the wedge and find the expression for a.
 
mgSin(alpha)-μsmgCos(alpha)=maCos(alpha)-μsmaSin(alpha)

forces acting on m in equilibrium.
forces due to gravity = forces due to F.
 
mgSin(alpha)-μsmgCos(alpha)=maCos(alpha)-μsmaSin(alpha)
That is correct. You can simplify this as g[Sin(alpha)-μsCos(alpha)]=a[Cos(alpha)-μsSin(alpha)]. Now substitute the value af a
 

Similar threads

Block tied to a fixed string on an accelerating wedge
Replies
37
Views
2K
Curvilinear Dynamics and forces
Replies
9
Views
2K
Acceleration of a block on a moving wedge
Replies
6
Views
3K
Calculating acceleration of a prism and block connected to a wall through a rope and pulley
Replies
4
Views
333
What is the acceleration of a wedge with an inclined mass resting on it?
Replies
20
Views
3K
Maximizing Friction Coefficient for Block on a Wedge: A Calculus Approach
Replies
3
Views
2K
Find min/max accel. for block to stay on wedge (static fric)
Replies
1
Views
2K
Find acceleration of Moving incline with a block on it
Replies
11
Views
3K
Finding the acceleration of a block of ice on a ramp
Replies
25
Views
3K
Block and acceleration of wedge
Replies
11
Views
6K

Hot Threads

Recent Insights

Back
Top