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An introduction to determining the size of the static friction force.

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{excerpt:hidden=true}An introduction to determining the size of the static friction force.{excerpt} {composition-setup}{composition-setup} {table:border=1|cellpadding=8|cellspacing=0|frame=void|rules=cols} {tr:valign=top} {td:width=350|bgcolor=#F2F2F2} {live-template:Left Column} {td} {td} {deck:id=bigdeck} {card:label=Part A} h2. Part A Suppose a 10 kg cubic box is at rest on a horizontal surface. There is friction between the box and the surface characterized by a coefficient of static friction equal to 0.50. If one person pushes on the box with a force _F_~1~ of 25 N directed due north and a second person pushes on the box with a force _F_~2~ = 25 N directed due south, what is the magnitude and direction of the force of static friction acting on the box? h4. Solution {toggle-cloak:id=sysa} *System:* {cloak:id=sysa}Box as [point particle].{cloak} {toggle-cloak:id=inta} *Interactions:* {cloak:id=inta}External influences from the earth (gravity) the surface (normal force and friction) and the two people (applied forces).{cloak} {toggle-cloak:id=moda} *Model:* {cloak:id=moda}[Point Particle Dynamics].{cloak} {toggle-cloak:id=appa} *Approach:* {cloak:id=appa} {toggle-cloak:id=diaga} {color:red} *Diagrammatic Representation* {color} {cloak:id=diaga} To determine the force of static friction, we first find the net force _in the absence of friction_. We first draw the situation. A top view (physical representation) and a side view (free body diagram) of the box _ignoring any contribution from friction_ are shown here. !basicstatic1.jpg! {cloak:diaga} {toggle-cloak:id=matha} {color:red} *Mathematical Representation* {color} {cloak:id=matha} The net force parallel to the surface in the absence of friction is then: {latex}

Card

label	Part A

Part A

Suppose a 10 kg cubic box is at rest on a horizontal surface. There is friction between the box and the surface characterized by a coefficient of static friction equal to 0.50. If one person pushes on the box with a force F₁ of 25 N directed due north and a second person pushes on the box with a force F₂ = 25 N directed due south, what is the magnitude and direction of the force of static friction acting on the box?

Solution

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System:

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Box as .

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Interactions:

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External influences from the earth (gravity) the surface (normal force and friction) and the two people (applied forces).

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id	moda

Model:

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.

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Approach:

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id	appa

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Diagrammatic Representation

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To determine the force of static friction, we first find the net force in the absence of friction. We first draw the situation. A top view (physical representation) and a side view (free body diagram) of the box ignoring any contribution from friction are shown here.

Image Added

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	diaga
	diaga

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Mathematical Representation

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The net force parallel to the surface in the absence of friction is then:

Latex

\begin{large}\[ \sum_{F \ne F_{f}} F_{x} = 0 \]
\[\sum_{F \ne F_{f}} F_{y} = F_{1} - F_{2} = 0 \]\end{large}

{latex}

Thus,

the

net

force

along

the

surface

is

zero

_

without

_

the

influence

of

static

friction,

and

so

the

static

friction

force

will

also

be

0.

{cloak:matha} {cloak:appa} {card} {card:label=Part B} h2. Part B Suppose a 10 kg cubic box is at rest on a horizontal surface. There is friction between the box and the surface characterized by a coefficient of static friction equal to 0.50. If one person pushes on the box with a force _F_~1~ of 25 N directed due north and a second person pushes on the box with a force _F_~2~ = 25 N directed due east, what is the magnitude and direction of the force of static friction acting on the box? h4. Solution {toggle-cloak:id=sysb} *System:* {cloak:id=sysb}Box as [point particle].{cloak} {toggle-cloak:id=intb} *Interactions:* {cloak:id=intb}External influences from the earth (gravity) the surface (normal force and friction) and the two people (applied forces).{cloak} {toggle-cloak:id=modb} *Model:* {cloak:id=modb}[Point Particle Dynamics].{cloak} {toggle-cloak:id=appb} *Approach:* {cloak:id=appb} {toggle-cloak:id=diagb} {color:red} *Diagrammatic Representation* {color} {cloak:id=diagb} To determine the force of static friction, we first find the net force _in the absence of friction_. We first draw the situation. A top view (physical representation) and a side view (partial free body diagram) of the box _ignoring any contribution from friction_ are shown here. !basicstatic2.jpg! {cloak:diagb} {toggle-cloak:id=mathb} {color:red} *Mathematical Representation* {color} {cloak:id=mathb} The net force parallel to the surface in the absence of friction is then: {latex}

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Card

label	Part B

Part B

Suppose a 10 kg cubic box is at rest on a horizontal surface. There is friction between the box and the surface characterized by a coefficient of static friction equal to 0.50. If one person pushes on the box with a force F₁ of 25 N directed due north and a second person pushes on the box with a force F₂ = 25 N directed due east, what is the magnitude and direction of the force of static friction acting on the box?

Solution

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id	sysb

System:

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id	sysb

Box as .

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id	intb

Interactions:

Cloak

id	intb

External influences from the earth (gravity) the surface (normal force and friction) and the two people (applied forces).

Toggle Cloak

id	modb

Model:

Cloak

id	modb

.

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Approach:

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Diagrammatic Representation

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To determine the force of static friction, we first find the net force in the absence of friction. We first draw the situation. A top view (physical representation) and a side view (partial free body diagram) of the box ignoring any contribution from friction are shown here.

Image Added

Cloak

	diagb
	diagb

Toggle Cloak

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Mathematical Representation

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The net force parallel to the surface in the absence of friction is then:

Latex
\begin{large}\[ \sum_{F \ne F_{f}} F_{x} = F_{2} = \mbox{25 N} \] \[\sum_{F \ne F_{f}} F_{y} = F_{1} = \mbox{25 N} \]\end{large}

{latex}

In

order

to

prevent

the

box

from

moving,

then,

static

friction

would

have

to

satisfy:

{

Latex

}


\begin{large}\[ F_{s} = - \mbox{25 N }\hat{x} - \mbox{25 N }\hat{y} = \mbox{35.4 N at 45}^{\circ}\mbox{ S of W}.\]\end{large}

{latex} {warning}

Warning
We're

not

finished

yet!

{warning}

We

must

now

check

that

this

needed

friction

force

is

compatible

with

the

static

friction

limit.

Newton's

2nd

Law

for

the

_

z

_

direction

tells

us:

{

Latex

}


\begin{large}\[ \sum F_{z} = N - mg = ma_{z}\]\end{large}

{latex} {note}Note that friction from an _xy_ surface cannot act in the _z_ direction.{note} We know that the box will remain on the surface, so _a_~z~ = 0. Thus, {latex}

Note
Note that friction from an xy surface cannot act in the z direction.

We know that the box will remain on the surface, so a_z = 0. Thus,

Latex
\begin{large}\[ N = mg = \mbox{98 N}\]\end{large}

{latex}

With

this

information,

we

can

evaluate

the

limit:

{

Latex

}


\begin{large}\[ F_{s} \le \mu_{s} N = \mbox{49 N} \]\end{large}

{latex}

Since

35.4

N

<

49

N,

we

conclude

that

the

friction

force

is

indeed

35.4

N

at 45° S of W. {cloak:mathb} {cloak:appb} {card} {card:label=Part C} h2. Part C Suppose a 10 kg cubic box is at rest on a horizontal surface. There is friction between the box and the surface characterized by a coefficient of static friction equal to 0.50. If one person pushes on the box with a force _F_~1~ of 25 N directed due north and a second person pushes on the box with a force _F_~2~ = 25 N also directed due north, what is the magnitude and direction of the force of static friction acting on the box? h4. Solution {toggle-cloak:id=sysc} *System:* {cloak:id=sysc}Box as [point particle].{cloak} {toggle-cloak:id=intc} *Interactions:* {cloak:id=intc} External influences from the earth (gravity) the surface (normal force and friction) and the two people (applied forces).{cloak} {toggle-cloak:id=modc} *Model:* {cloak:id=modc}[Point Particle Dynamics].{cloak} {toggle-cloak:id=appc} *Approach:* {cloak:id=appc} {toggle-cloak:id=diagc} {color:red} *Diagrammatic Representation* {color} {cloak:id=diagc} To determine the force of static friction, we first find the net force _in the absence of friction_. We first draw the situation. A top view (physical representation) and a side view (free body diagram) of the box _ignoring any contribution from friction_ are shown here. !basicstatic3.jpg! {cloak:diagc} {toggle-cloak:id=mathc} {color:red} *Mathematical Represenatation* {color} {cloak:id=mathc} The net force parallel to the surface in the absence of friction is then: {latex}

at 45° S of W.

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Card

label	Part C

Part C

Suppose a 10 kg cubic box is at rest on a horizontal surface. There is friction between the box and the surface characterized by a coefficient of static friction equal to 0.50. If one person pushes on the box with a force F₁ of 25 N directed due north and a second person pushes on the box with a force F₂ = 25 N also directed due north, what is the magnitude and direction of the force of static friction acting on the box?

Solution

Toggle Cloak

id	sysc

System:

Cloak

id	sysc

Box as .

Toggle Cloak

id	intc

Interactions:

Cloak

id	intc

External influences from the earth (gravity) the surface (normal force and friction) and the two people (applied forces).

Toggle Cloak

id	modc

Model:

Cloak

id	modc

.

Toggle Cloak

id	appc

Approach:

Cloak

id	appc

Toggle Cloak

id	diagc

Diagrammatic Representation

Cloak

id	diagc

To determine the force of static friction, we first find the net force in the absence of friction. We first draw the situation. A top view (physical representation) and a side view (free body diagram) of the box ignoring any contribution from friction are shown here.

Image Added

Cloak

	diagc
	diagc

Toggle Cloak

id	mathc

Mathematical Represenatation

Cloak

id	mathc

The net force parallel to the surface in the absence of friction is then:

Latex
\begin{large}\[ \sum_{F \ne F_{f}} F_{x} = 0 \] \[\sum_{F \ne F_{f}} F_{y} = F_{1}+F_{2} = \mbox{50 N} \]\end{large}

{latex}

In

order

to

prevent

the

box

from

moving,

then,

static

friction

would

have

to

satisfy:

{

Latex

}


\begin{large}\[ F_{s} = \mbox{0 N }\hat{x} - \mbox{50 N }\hat{y} = \mbox{50 N due south}.\]\end{large}

{latex}

Again,

we

must

check

that

this

needed

friction

force

is

compatible

with

the

static

friction

limit.

Again,

Newton's

2nd

Law

for

the

_

z

_

direction

tells

us:

{

Latex

}


\begin{large}\[ \sum F_{z} = N - mg = ma_{z}\]\end{large}

{latex}

and

know

that

the

box

will

remain

on

the

surface,

so

_

a

_~z~

_z =

0.

Thus,

{

Latex

}


\begin{large}\[ N = mg = \mbox{98 N}\]\end{large}

{latex}

With

this

information,

we

can

evaluate

the

limit:

{

Latex

}


\begin{large}\[ F_{s} \le \mu_{s} N = \mbox{49 N} \]\end{large}

{latex}

Since

50

N

>

49

N,

we

conclude

that

the

static

friction

limit

is

violated.

The

box

will

move

and

kinetic

friction

will

apply

instead!

{cloak:mathc} {cloak:appc} {card} {deck} {td} {tr} {table} {live-template:RELATE license}

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Key

Part A

Solution

Part B

Solution

Part C

Solution