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Excerpt
hiddentrue

Analyzing a continuous momentum flux (water from a hose).

Image Added

Photo from Wikimedia Commons
Original by Doclector

When you spray water from a garden hose you feel a backward force as you hold the nozzle. Similarly, anything you spray the water at feels a force in the direction away from the spray. What is the origin of this force, and what determines its magnitude?

Composition Setup

Solution

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idsysa
System:
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idsysa

Element of water stream as a acting on an article, also treated as a .

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idinta
Interactions:
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We will ignore the vertical direction, so that the only interaction is the force due to the changes in momentum of the water and the item hit..

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idmoda
Model:
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.

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idappa
Approach:

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iddiaga
Diagrammatic Representation

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Image Added


Imagine a stream of water as a cylinder of uniform cross-sectional area A and density ρ. We consider an elemental unit of this that is Δx long. It travels, as does the rest of the stream, horizontally at velocity v (We will ignore the downward force of gravity here).

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idmatha
Mathematical Representation

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Consider the element of length Δx and area A and density ρ. Its mass m must therefore be

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{excerpt:hidden=true}Analyzing a continuous momentum flux (water from a hose).{excerpt}

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|!Hose Spraying Water.jpg!|
|Photo from Wikimedia Commons
Original by Doclector|


When you spray water from a garden hose you feel a backward force as you hold the nozzle. Similarly, anything you spray the water at feels a force in the direction away from the spray. What is the origin of this force, and what determines its magnitude?

{composition-setup}{composition-setup}

  

h4. Solution

{toggle-cloak:id=sysa} *System:*  {cloak:id=sysa}Element of water stream as a [point particle] acting on an article, also treated as a [point particle]. {cloak}

{toggle-cloak:id=inta} *Interactions:* {cloak:id=inta}We will *ignore the vertical direction*, so that the only interaction is the force due to the changes in momentum of the water and the item hit..

 {cloak}

{toggle-cloak:id=moda} *Model:*  {cloak:id=moda}[Momentum and External Force].{cloak}

{toggle-cloak:id=appa} *Approach:*  

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{toggle-cloak:id=diaga} {color:red} *Diagrammatic Representation* {color}

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|!Momentum Transport 01.PNG!|
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Imagine a stream of water as a cylinder of uniform cross-sectional area *A* and density {*}ρ{*}. We consider an elemental unit of this that is {*}Δx{*} long. It travels, as does the rest of the stream, horizontally at velocity *v* (We will ignore the downward force of gravity here).


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{toggle-cloak:id=matha} {color:red} *Mathematical Representation* {color}

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Consider the element of length {*}Δx{*} and area *A* and density {*}ρ{*}. Its mass *m* must therefore be
\\
{latex}\begin{large}\[ m = \rho A \Delta x \] \end{large}{latex}
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Since it travels with velocity *v*, its momentum is thus 
\\
{latex}


Since it travels with velocity v, its momentum is thus

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\begin{large} \[ \vec{p} = \rho A \Delta x \vec{v} \] \end{large}{latex}
\\


Let's

...

assume

...

that

...

this

...

element

...

of

...

the

...

stream

...

strikes

...

an

...

object

...

(a

...

wall,

...

say),

...

and

...

breaks

...

up,

...

dissipating

...

in

...

all

...

directions.

...

the

...

stream

...

element

...

loses

...

all

...

of

...

its

...

momentum

...

in

...

the

...

process.

...

The

...

change

...

in

...

momentum

...

of

...

the

...

stream

...

element

...

is

...

thus

Latex

\\
{latex}\begin{large} \[ \Delta \vec{p} = \rho A \Delta x \vec{v} \] \end{large}{latex}
\\
If this happens in a time {*}Δt{*}, then the change in momentum with 


If this happens in a time Δt, then the change in momentum with time (which is just the Average Force) is

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time (which is just the *Average Force*) is
\\
{latex}\begin{large} \[ \vec{F_{avg}} = \frac{\Delta \vec{p}}{\Delta t} = \rho A \vec{v} \frac{\Delta x}{\Delta t} \] \end{large}{latex}
\\
But {*}Δx/Δt{*} = *v* , so the [magnitude]


But Δx/Δt = v , so the magnitude of the Average Force is thus

Latex
 of the Average Force is thus
\\
{latex}\begin{large} \[ F_{avg} = \rho A v^{2} \]\end{large}{latex}
\\



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