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{{distinguish|Torricelli's equation|Torricelli point}}
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'''Torricelli's law''', also known as '''Torricelli's theorem''', is a theorem in [[fluid dynamics]] relating the speed of fluid flowing out of an opening to the height of fluid above the opening.
 
[[Image:Spouting_can_jets.svg|right|256px]]
Torricelli's law states that the speed of efflux, ''v'', of a fluid through a sharp-edged hole at  the bottom of a tank  filled to a depth ''h'' is the same as the speed that a body (in this case a drop of water) would acquire in falling freely from a height ''h'', i.e. <math>v = \sqrt{2gh}</math>, where ''g'' is the acceleration due to gravity (9.81 N/kg).  This last expression comes from equating the kinetic energy gained, <math>\frac{1}{2}mv^2</math>, with the potential energy lost, ''mgh'' , and solving for ''v''.
 
The law was discovered (though not in this form) by the Italian scientist [[Evangelista Torricelli]], in 1643.  It was later shown to be a particular case of [[Bernoulli's principle]].
 
==Derivation==
 
[[Bernoulli's principle]] states that:
 
:<math>{v^2 \over 2}+gz+{p\over\rho}=\text{constant}</math>
 
where ''v'' is fluid speed, ''g'' is the [[gravitational acceleration]] (9.81&nbsp;m/s^2), ''z'' is the fluid's height above a reference point, ''p'' is pressure, and ''ρ'' is density.  Define the opening to be at ''z''=Ø.  At the top of the tank, ''p'' is equal to the atmospheric pressure. ''v'' can be considered 0 because the fluid surface drops in height extremely slowly compared to the speed at which fluid exits the tank. At the opening, ''z''=Ø and ''p'' is again atmospheric pressure.  Eliminating the constant and solving gives:
 
:<math>gz+{p_{atm}\over\rho}={v^2 \over 2}+{p_{atm}\over\rho}</math>
:<math>\Rightarrow v^2=2gz\,</math>
:<math>\Rightarrow v=\sqrt{2gz}</math>
 
''z'' is equivalent to the ''h'' in the first paragraph of this article, so:
 
:<math>v=\sqrt{2gh}</math>
 
==Experimental evidence==
Torricelli's law can be demonstrated in the spouting can experiment, which is designed to show that in a [[liquid]] with an open surface, [[pressure]] increases with depth. It consists of a tube with three separate holes and an open surface. The three holes are blocked, then the tube is filled with water. When it is full, the holes are unblocked. The jets become more powerful, the fluid exit's velocity is greater the further down the tube they are.<ref>[http://www.4physics.com/phy_demo/SpoutingCylinder/SpoutingCylinder.html Spouting cylinder fluid flow<!-- Bot generated title -->]</ref>
 
Ignoring viscosity and other losses, if the nozzles point vertically upward then each jet will reach the height of the surface of the liquid in the container.
 
==References==
{{reflist}}
 
==Further reading==
* {{cite book | last =  T. E. Faber | year = 1995 | title = Fluid Dynamics for Physicists  | publisher = Cambridge University Press  | isbn = 0-521-42969-2}}
* Stanley Middleman, ''An Introduction to Fluid Dynamics: Principles of Analysis and Design'' ([[John Wiley & Sons]], 1997) ISBN 978-0-471-18209-2
* Dennis G. Zill, ''A First Course in Differential Equations'' (2005)
 
==See also==
* [[Pascal's law]]
 
{{commons category|Torricelli's Law}}
 
<!--[[in:lohit]]-->
 
{{DEFAULTSORT:Torricelli's Law}}
[[Category:Fluid dynamics]]
[[Category:Physics experiments]]

Latest revision as of 11:58, 4 January 2015

The author's name is Christy Brookins. My day occupation is a travel agent. It's not a typical thing but what she likes performing is to play domino but she doesn't have the time lately. My wife and I reside in Kentucky.

My web site; psychic readers