Example: Magnetic Field: Difference between revisions

Revision as of 01:16, 21 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.

Figure will be shown here

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.

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

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

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

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

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

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

@@ 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.
 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. -->
+<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 l=0 to l=1.2 m gives us
+<math>4.905=I * 1.2* 0.9  ~~(T*m/N) ~~ \to I=4.905/(1.2*0.9)=4.5417 ~~A</math>
+In conclusion we would need 4.54 Amps of current to suspend the bar in the magnetic field.

Example: Magnetic Field: Difference between revisions

Revision as of 01:16, 21 January 2010

Problem

Solution

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