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1.Rotational displacement ‘θ’ describes how far an object has rotated (radians, or revolutions). 2.Rotational velocity ‘ω’ describes how fast it rotates.

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Presentation on theme: "1.Rotational displacement ‘θ’ describes how far an object has rotated (radians, or revolutions). 2.Rotational velocity ‘ω’ describes how fast it rotates."— Presentation transcript:

1 1.Rotational displacement ‘θ’ describes how far an object has rotated (radians, or revolutions). 2.Rotational velocity ‘ω’ describes how fast it rotates (ω = θ /t) measured in radians/sec. 3.Rotational acceleration ‘α’ describes any rate of change in its velocity (α = Δθ /t) measured in radians /sec 2. (All analogous to linear motion equations.) Recap: Rotational Motion of Solid Objects (Chapter 8)

2 Question: Which force ‘F’ will produce largest effect? Effect depends on the force and the distance from the fulcrum /pivot point.  Torque ‘τ’ about a given axis of rotation is the product of the applied force times the lever arm length ‘l’. τ = F. l (units: N.m) The lever arm ‘l’ is the perpendicular distance from axis of rotation to the line of action of the force. Result: Torques (not forces alone) cause objects to rotate. Why Do Objects Rotate? F F F F No effect as F acting through the pivot point. Pivot Need a force. Direction of force and point of application are critical…

3 Long lever arms can produce more torque (turning motion) than shorter ones for same applied force. rock pivot point F l Larger ‘l’ more torque… If ‘F’ not perpendicular, the effective ‘l’ is reduced. Example: Easier to change wheel on a car.. sticky nut F l pivot point rock pivot point F l For maximum effect the force should be perpendicular to the lever arm.

4 Direction of rotation of applied torque is very important (i.e. clockwise or anticlockwise). Torques can add or oppose each other. If two opposing torques are of equal magnitude they will cancel one another to create a balanced system. Balanced Torques W 1 = m 1.g W 2 = m 2.g l2l2 l1l1 (Torque = F.l ) W 1.l 1 = W 2.l 2 Thus at balance: m 1.l 1 = m 2.l 2 or m 1.g.l 1 = m 2. g.l 2 (This is the principle of weighing scales.)

5 Example: Find balance point for a lead mass of 10 kg at 0.2 m using 1 kg bananas. W 1 = m 1.g W 2 = m 2.g l2l2 l1l1 Torque At balance: Torques are of equal size and opposite in rotation. m 1.l 1 10 x 0.2 m 2 1 Balances use a known (standard) weight (or mass) to determine another, simply by measuring the lengths of the lever arms at balance. Important note: There is NO torque when force goes through a pivot point. W 1.l 1 = W 2.l 2 or m 1.l 1 = m 2.l 2 l 2 = = = 2.0 m

6 Center of Gravity The shape and distribution of mass in an object determines whether it is stable (i.e. balanced) or whether it will rotate. Any ordinary object can be thought of as composed of a large number of point-masses each of which experiences a downward force due to gravity. These individual forces are parallel and combine together to produce a single resultant force (W = m.g) weight of body.  The center of gravity of an object is the point of balance through which the total weight acts. As weight is a force and acts through the center of gravity (CG), no torque exists and the object is in equilibrium. W=m.g τ1τ1 τ2τ2 τ3τ3 τ4τ4 l1l1 CG

7 To find CG (balance point) of any object simply suspend it from any 2 different points and determine point of intersection of the two “lines of action”. line of action center of gravity How to Find the CG of an Object The center of gravity does not necessarily lie within the object…e.g. a ring. Objects that can change shape (mass distribution) can alter their center of gravity, e.g. rockets, cranes…very dangerous. Demo: touching toes!

8 If CG falls outside the line of action through pivot point (your feet) then a torque will exist and you will rotate! Objects with center of gravity below the pivot point are inherently stable e.g. a pendulum… If displaced the object becomes unstable and a torque will exist that acts to return it to a stable condition (after a while). pivot point CG torque stable Summary: Center of gravity is a point through which the weight of an object acts. It is a balance point with NO net torque. Stability

9 Rotational equivalent of Newton’s 1st law: A body at rest tends to stay at rest; a body in uniform rotational motion tends to stay in motion, unless acted upon by a torque. Question: How to adapt Newton’s 2 nd law (F = m.a) to cover rotational motion? We know that if a torque ‘τ’ is applied to an object it will cause it to rotationally accelerate ‘α’. Thus torque is proportional to rotational acceleration just as force ‘F’ is proportional to linear acceleration ‘a’. Define a new quantity: the rotational inertia (I) to replace mass ‘m’ in Newton’s 2 nd law: ‘I’ is a measure of the resistance of an object to change in its rotational motion. (Just as mass is measure of inertial resistance to changes in linear motion) Dynamics of Rotation τ = I. α (analogous to F = m.a)

10 Unlike mass ‘m’, ‘I’ depends not only on constituent matter but also the object’s shape and size. So What Is ‘I’? F r axis of rotation m Consider a point mass ‘m’ on end of a light rod of length ‘r’ rotating. The applied force ‘F’ will produce a tangential acceleration ‘a t ’ By Newton’s 2 nd law: F = m.a t But tangential acceleration = r times angular acceleration (i.e. a t = r.α) by analogy with v = r.ω. So: F = m.r.α (but we know that τ = F.r) So: τ = m.r 2.α (but τ = I.α) Thus: I = m.r 2 (units: kg. m 2 ) This is moment of inertia of a point mass ‘m’ at a distance ‘r’ from the axis of rotation. In general, an object consists of many such point masses and I = m 1 r 1 2 + m 2 r 2 2 + m 3 r 3 2 …equals the sum of all the point masses.

11 Now we can restate Newton’s 2 nd law for a rotating body:  The net torque acting on an object about a given axis of rotation is equal to the moment of inertia about that axis times the rotational acceleration. Or the rotational acceleration produced is equal to the torque divided by the moment of inertia of object. (α = ). Larger rotational inertia ‘I’ will result in lower acceleration. ‘I’ dictates how hard it is to change rotational velocity. Example: Twirling a baton: The longer the baton, the larger the moment of inertia ‘I’ and the harder it is to rotate (i.e. need bigger torque). Eg. As ‘I’ depends on r 2, a doubling of ‘r’ will quadruple ‘I’!!! (Note: If spin baton on axis, it’s much easier as ‘I’ is small.) τ = I. α τIτI

12 Example: What is the moment of inertia ‘I’ of the Earth? For a solid sphere: I = m.r 2 I = (6 x 10 24 ) x (6.4 x 10 6 ) 2 I = 9.8 x 10 37 kg.m 2 The rotational inertia of the Earth is therefore enormous and a tremendous torque would be needed to slow its rotation down (around 10 29 N.m) Question: Would it be more difficult to slow the Earth if it were flat? For a flat disk: I = ½ m.r 2 I = 12.3 x 10 37 kg.m 2 So it would take even more torque to slow a flat Earth down! In general the larger the mass and its length or radius from axis of rotation the larger the moment of inertia of an object. 2525 2525 Earth: r = 6400 km m = 6 x 10 24 kg

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