Physics Quiz 4

[Ether]

Figure1 is a top view of a block sitting on a table.

The block weighs 10 Newtons.

The coefficient of static friction between the block and the table is 0.8 (the same in all directions).

A force F1 = 6 Newtons is applied to the block (yellow arrow).

A force F2 (blue arrow) is then slowly applied in the direction shown. At what magnitude of F2 does the block begin to slide?

[BornaE]

2*SQRT(7) Newtons

[Ether]

Quote:

Originally Posted by BornaE

2*SQRT(7) Newtons

For the benefit of students reading this thread, would you please show your work?

Thank you.

[JesseK]

F2 >= 5N and some change.

Spoiler for Work:

sqrt(6^2 + F2^2) >= 10 * 0.8
or
6^2 + F2^2 >= 64
or
F2^2 >= 28
or

[Ether]

Make the following changes to the original problem:

- The static coefficient of friction in the "Y" direction (the direction of the yellow arrow) is mu_y = 0.8

- The static coefficient of friction in the "X" direction (the direction of the blue arrow) is mu_x = 0.2

- The static coefficient of friction varies linearly with theta from mu=0.2 in the "X" direction to mu=0.8 in the "Y" direction as theta goes from zero (X direction) to pi/2 (Y direction).

Now find the value of Fx at which the block begins to slide.

[PAR_WIG1350]

Spoiler for :

theta=arctan(6/f2)
-------------------
mu=n(theta)+.2
.8=n(pi/2)+.2
.6=n(pi/2)
1.2=n(pi)
1.2/pi=n
mu=(1.2/pi)theta+.2
mu=(1.2arctan(6/f2))/pi+.2
----------------------------
f2^2+36=(10(mu))^2
Sqrt[f2^2+36]=10(mu)
Sqrt[f2^2+36]/10=mu
-----------------------

Spoiler for :

Sqtr[f2^2+36]/10=(1.2arctan(6/f2))/pi+.2
Sqrt[f2^2+36]pi=12arctan(6/f2)+2pi
Sqrt[f2^2+36]-12arctan(6/f2)=2pi
that's ugly
Wolfram Alpha couldn't make it look any better, but it gives us an approximation for f2 of about

Spoiler for :

10.8N

[Ether]

Quote:

Originally Posted by PAR_WIG1350

You were doing great until you dropped the factor of "pi" on the left hand side in the very last equation. The numerical answer you got should have been a red flag that something was wrong.

Fix that, get a new numerical value for F₂, then ask yourself "what happens when F₂ = 2 Newtons?"

[theprgramerdude]

Quote:

Originally Posted by Ether

Figure1 is a top view of a block sitting on a table.

The block weighs 10 Newtons.

The coefficient of static friction between the block and the table is 0.8 (the same in all directions).

A force F1 = 6 Newtons is applied to the block (yellow arrow).

A force F2 (blue arrow) is then slowly applied in the direction shown. At what magnitude of F2 does the block begin to slide?

Can you list the plane on which the block rests, as well as the direction of the gravitational force?

[John]

F = sqrt(36 + F2^2)
F = 10*(.2 + .6 (theta/(pi/2)))
theta = arctan(6/F2)
F = 10*(.2 + .6 (2arctan(6/F2)/pi))
sqrt(36 + F2^2) = 2 + 6 (2arctan(6/F2)/pi)
F2 ~= 2.491 N

I'm confused; does this mean that it takes MORE sideways force to move the block than it would if there was no vertical force? For example, wouldn't the block move if F1 = 0N and F2 = 2N?

[Molten]

Quote:

Originally Posted by theprgramerdude

Can you list the plane on which the block rests, as well as the direction of the gravitational force?

Its not needed to be specified. It has already been given sort of. If the block is sitting on a table, we assume the plane is parallel to the ground and perpendicular to the gravitational force. Remember, it is a top view of the block.

Jason

[Ether]

Quote:

Originally Posted by John

F = sqrt(36 + F2^2)
F = 10*(.2 + .6 (theta/(pi/2)))
theta = arctan(6/F2)
F = 10*(.2 + .6 (2arctan(6/F2)/pi))
sqrt(36 + F2^2) = 2 + 6 (2arctan(6/F2)/pi)
F2 ~= 2.491 N

Excellent.

Quote:

I'm confused; does this mean that it takes MORE sideways force to move the block than it would if there was no vertical force? For example, wouldn't the block move if F1 = 0N and F2 = 2N?

Excellent. You have asked the $64K question.

If you assume that the coefficient in any given direction is not increased by force components not in that direction, then the answer is that the block will start to slip when F₂=2 Newtons. See attached "solution.pdf".

However, these 2 assumptions:

1: linear change in mu for angles between 0 and pi/2, and

2: mu is not increased by force components not in direction being considered

are I think open questions.

In FRC, there are wheels which are said to have different mu in the forward and sideways directions. I have looked but never seen any test data to show what happens when force is applied at a variety of angles between 0 and pi/2.

[theprgramerdude]

Quote:

Originally Posted by Molten

Its not needed to be specified. It has already been given sort of. If the block is sitting on a table, we assume the plane is parallel to the ground and perpendicular to the gravitational force. Remember, it is a top view of the block.

Jason

Top view with respect to what, though? The table, or the plane the forces are acting on? The ambiguity of the question leaves it perfectly open to interpretation that the table is flush with any of the six faces of the block. Assumptions are useful in solving situations like this, but they can also lead to highly erroneous answers if they are wrong.

[PAR_WIG1350]

Quote:

Originally Posted by Ether

You were doing great until you dropped the factor of "pi" on the left hand side in the very last equation. The numerical answer you got should have been a red flag that something was wrong.

Fix that, get a new numerical value for F₂, then ask yourself "what happens when F₂ = 2 Newtons?"

Its better that I make that mistake here than on the AP exam

Quote:

Originally Posted by theprgramerdude

Top view with respect to what, though? The table, or the plane the forces are acting on? The ambiguity of the question leaves it perfectly open to interpretation that the table is flush with any of the six faces of the block. Assumptions are useful in solving situations like this, but they can also lead to highly erroneous answers if they are wrong.

The plane on which the forces are acting and the table are the same plane, the normal force is perpendicular to that plane, the direction of gravity, irl, is down with respect to an observer in the same gravitational field as the object in question. since we are looking from the top, down can be assumed to be away from us.

[Molten]

Quote:

Originally Posted by theprgramerdude

Assumptions are useful in solving situations like this, but they can also lead to highly erroneous answers if they are wrong.

Agreed. Try solving such problems without making assumptions though. I've never had a professor explicitly spell out every detail of a problem. They always leave it up to the student to make a few assumptions. In a real world example, you never know all the details. Just learn what you can and do your best from there.

Jason

[JesseK]

Quote:

Originally Posted by Molten

Agreed. Try solving such problems without making assumptions though. I've never had a professor explicitly spell out every detail of a problem. They always leave it up to the student to make a few assumptions. In a real world example, you never know all the details. Just learn what you can and do your best from there.

Jason

Furthermore, in the 'real world', half the time we don't know what assumptions we're even making, yet somehow the work has to get done.