Difference between revisions of "Forest UCM NLM BlockOnInclineWfriction"
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=Step 5: Use Newton's second law= | =Step 5: Use Newton's second law= | ||
− | + | ==Motion in the <math>\hat j</math> direction described by Newton's second law is:== | |
:<math>\sum F_{ext} = N - mg \cos \theta = ma_y = 0</math> | :<math>\sum F_{ext} = N - mg \cos \theta = ma_y = 0</math> | ||
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What is the condition to satisfy for the object to move down the inclined plane? | What is the condition to satisfy for the object to move down the inclined plane? | ||
− | + | ==Motion in the <math>\hat i</math> direction described by Newton's second law is:== | |
:<math>\sum F_{ext} = mg \sin \theta - F_f= ma_x = m \frac{dv_x}{dt}</math> | :<math>\sum F_{ext} = mg \sin \theta - F_f= ma_x = m \frac{dv_x}{dt}</math> | ||
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The condition that must occur in order for an object with no initial velocity to begin moving with a non-zero accelleration is | The condition that must occur in order for an object with no initial velocity to begin moving with a non-zero accelleration is | ||
− | :<math>F_f = \mu_s N = \mu_s mg \cos \theta | + | :<math>F_f = \mu_s N = \mu_s mg \cos \theta < mg \sin \theta</math> |
+ | |||
+ | The critical angle of incline for the object to start moving becomes | ||
+ | ::<math>\theta_c = \tan^{-1}\left( {\mu_s mg}\right )</math> | ||
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− | Newton's second law under the condition that the object has a velocity becomes | + | ==Newton's second law under the condition that the object has a velocity becomes== |
:<math>\sum F_{ext} = mg \sin \theta - F_f= ma_x = m \frac{dv_x}{dt}</math> | :<math>\sum F_{ext} = mg \sin \theta - F_f= ma_x = m \frac{dv_x}{dt}</math> | ||
:<math>\sum F_{ext} = mg \sin \theta -\mu_k mg \cos \theta= ma_x = m \frac{dv_x}{dt}</math> | :<math>\sum F_{ext} = mg \sin \theta -\mu_k mg \cos \theta= ma_x = m \frac{dv_x}{dt}</math> | ||
− | : <math>\int_0^t g \left ( \sin \theta - \mu_k | + | : <math>\int_0^t g \left ( \sin \theta - \mu_k\cos \theta \right ) dt = \int_{v_i}^{v} dv </math> |
− | : <math>v= v_i - g \left ( \ | + | : <math>v= v_i - g \left ( \mu_k\cos \theta -\sin \theta \right ) t </math> |
The amount of time that lapses until the blocks final velocity is zero | The amount of time that lapses until the blocks final velocity is zero | ||
− | <math>t= \frac{v_i}{\left ( \ | + | <math>t= \frac{v_i}{\left ( \mu_k\cos \theta - \sin \theta \right ) }</math> |
After the above time the blocks speed is zero. The friction will change from being kinetic to static after the above time interval. | After the above time the blocks speed is zero. The friction will change from being kinetic to static after the above time interval. | ||
− | :<math>v(t) =\left \{ {v_i - g \left ( \ | + | :<math>v(t) =\left \{ {v_i - g \left (\mu_k\cos \theta -\sin \theta \right ) t \;\;\;\;\;\;\;\; t< \frac{v_i}{\left ( \mu_k\cos \theta - \sin \theta \right ) } \atop 0\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\;\; t>= \frac{v_i}{\left ( \mu_k\cos \theta - \sin \theta \right ) }} \right .</math> |
[[Forest_UCM_NLM#Block_on_incline_with_friction]] | [[Forest_UCM_NLM#Block_on_incline_with_friction]] |
Latest revision as of 13:31, 21 August 2014
The problem
Consider a block of mass m sliding down an infinitely long inclined plane shown below with a frictional force that is given by
Find the blocks speed as a function of time.
Step 1: Identify the system
- The block is the system with the following external forces, A normal force, a gravitational force, and the force of friction.
Step 2: Choose a suitable coordinate system
- A coordinate system with one axis along the direction of motion may make solving the problem easier
Step 3: Draw the Free Body Diagram
Step 4: Define the Force vectors using the above coordinate system
Step 5: Use Newton's second law
Motion in the direction described by Newton's second law is:
- where is the coefficent of STATIC friction
The
indicates that STATIC friction will be a force that is suficient to keep the block from moving. STATIC friction has a maximum value. If the sum of the other forces exceeds the static friction force, then the object will move, and the coeffiicent of kinetic friction will be used to describe the motion.What is the condition to satisfy for the object to move down the inclined plane?
Motion in the direction described by Newton's second law is:
if there is no acceleration then
If the object is not moving then
The largest value for the frictional force of an object with no velocity is
The condition that must occur in order for an object with no initial velocity to begin moving with a non-zero accelleration is
The critical angle of incline for the object to start moving becomes
After the object exceeds the above condition is will have a non-zero velocity AND the coefficient of friction will decrease from to
Newton's second law under the condition that the object has a velocity becomes
The amount of time that lapses until the blocks final velocity is zero
After the above time the blocks speed is zero. The friction will change from being kinetic to static after the above time interval.