Example: Magnetic Field: Difference between revisions

Latest revision as of 20:33, 25 January 2010

Problem

A Metal Rod with length 1.2 m and mass 500 g is suspended in a magnetic field of 0.9 T. Determine the current needed suspend the rod without supports.

Solution

Ampere's Force Law

${\vec {F}}=\int \limits _{c}I~{\vec {d}}l\times {\vec {B}}$

For our problem we have ${\vec {B}}=0.9~T$

And we know the necessary Force to hold up the bar without the supports would be equal to the weight of the bar multiplied by the gravitational force.

We also know that the force vector will be in the ${\hat {k}}$ direction, and B is in the ${\hat {i}}$ direction.

So using the fact that ${\hat {k}}=-{\hat {j}}\times {\hat {i}}$ We can conclude that the current is in the $-{\hat {j}}$ direction, and therefore flows to the left.

${\vec {F}}_{\text{needed}}={\text{mass}}\times {\text{gravity}}$

${\vec {F}}=500*9.81~~(g*m/s^{2})$

${\vec {F}}=4.905~~(N)$

Substituting into Ampere's Law we are left with

$4.905=\int \limits _{c}I~{\vec {d}}l\times 0.9~~(T/N)$

Integrating from $~l=0~to~l=1.2~m~~$ gives us

$4.905=I*1.2*0.9~~(T*m/N)~~\Longrightarrow ~~~I=4.905/(1.2*0.9)=4.5417~~A$

In conclusion we would need 4.54 Amps of current flowing to the left to suspend the bar in the magnetic field.

$I~=~4.54~{\hat {i}}~~A$

Review Comments and Status

Andrew Sell- emailed 1.25.10

Kyle Lafferty- emailed 1.25.10

@@ Line 1: / Line 1: @@
+==Problem==
-==Problem==A Metal Rod with length 1.2m and mass 500 gm is suspended in a magnetic field of 0.9 T. Determine the current needed to be able to release the tension in the supports.
+A Metal Rod with length 1.2 m and mass 500 g is suspended in a magnetic field of 0.9 T. Determine the current needed suspend the rod without supports.
+[[Image:Emec_rod_magneticField.png|1000px]]
-Figure will be shown here
@@ Line 7: / Line 8: @@
 Ampere's Force Law
-<math>\vec F=\int\limits_{c} I \vec dl\times \vec B</math>
+<math>\vec F=\int\limits_{c} I ~\vec dl\times \vec B</math>
+For our problem we have <math>\vec B=0.9 ~T </math>
+And we know the necessary Force to hold up the bar without the supports would be equal to the weight of the bar multiplied by the gravitational force.
+We also know that the force vector will be in the <math>\hat k</math> direction, and B is in the <math>\hat i</math> direction.
+So using the fact that <math>\hat k=-\hat j\times \hat i</math>  We can conclude that the current is in the <math>-\hat j</math> direction, and therefore flows to the left.
+<math>\vec F_{\text{needed}}={\text{mass}}\times {\text{gravity}}</math>
+<math>\vec F=500*9.81  ~~(g*m/s^2)</math>
+<math>\vec F=4.905  ~~(N)</math>
+Substituting into Ampere's Law we are left with
+<math>4.905=\int\limits_{c} I ~\vec dl\times 0.9  ~~(T/N)</math>
+Integrating from <math> ~l=0 ~to~ l=1.2~m ~~</math>  gives us
+<math>4.905=I * 1.2* 0.9  ~~(T*m/N) ~~ \Longrightarrow~~~ I=4.905/(1.2*0.9)=4.5417 ~~A</math>
+In conclusion we would need 4.54 Amps of current flowing to the left to suspend the bar in the magnetic field.
+<math> I~=~4.54 ~\hat i~~A </math>
+==Review Comments and Status==
+Andrew Sell- emailed 1.25.10
+Kyle Lafferty- emailed 1.25.10

Example: Magnetic Field: Difference between revisions

Latest revision as of 20:33, 25 January 2010

Problem

Solution

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