Chapter 6: Conservation of Energy
Introduction z Energy z
– ability to perform work.
Unit of energy (and of work) – Joules (J) 1 J = 1 kg- m2 / s2 Forms of energy: ¾Light, chemical, nuclear, mechanical, electrical, sound, heat, kinetic, elastic, magnetic etc. ¾Each type of energy is calculated differently
Page
Law of Conservation of Energy z
In any natural process, total energy is always “conserved”, i.e. energy can not be created nor destroyed. ¾Can be transformed from one form to another. ¾Can be transferred from one system to another. In science, any law of conservation is a very powerful tool in understanding the physical universe.
Work by Constant Force z Work
– transfer of energy as a result of
force. z
Constant force – its magnitude and direction unchanged.
z
The force acts on the object throughout the process.
z Only
component of force parallel to direction of motion performs work!
Page
Work by Constant Force Work done by force F in moving the object at constant speed through displacement ∆x : W = (F cos θ) ∆x F cos θ = component of F parallel to ∆x. Work is a scalar quantity. Unit = Joule (J).
f
1 J = 1 N-m
F
N
θ
∆x
W
Work by Constant Force W = (F cos θ) ∆x 1. If ∆x = 0, then W = 0 ¾If you held a 50 kg bag on your head without moving for 3 hours, would you have done work?
Page
W = (F cos θ) ∆x 2. If θ = 0, cos 0 = 1 ie F and ∆x are parallel and W = F ∆x F ∆x
W = (F cos θ) ∆x 3. If θ = 90o, cos 90ο = 0, ie F and ∆x are perpendicular to each other and W = 0 f
F
N
θ
∆x
W
Work done by the normal force N is zero
Page
W = (F cos θ) ∆x 4. If θ = 180o, cos 180ο = −1, ie F and ∆x are antiperpendicular to each other and W = negative.
f
F
N
∆x
θ W
Work done by the frictional force f is - F ∆x
Example: A 30 N chest was pulled 5 m across the floor at a constant speed by applying a force of 50 N at an angle of 30o. How much work was done by tension T? W = F ∆x cos θ = (50 Ν) (5 m) cos (30) = 217 Joules 50 N 30o
N f mg
Page
T
Example: A 30 N chest was pulled 5 m across the floor at a constant speed by applying a force of 50 N at an angle of 30o. How much work was done by gravity? T N 50 N
f
30o
f
mg
mg
∆x
W = F ∆x cos θ = 50 x 5 cos(90) = 0
mg
90o
Example: A 30 N chest was pulled 5 m across the floor at a constant speed by applying a force of 50 N at an angle of 30o. How much work was done by 50 N friction f? f mg To find the magnitude of f: Consider x-component of forces acting. Since constant velocity: Fnet = 0 So Tcos30o – f = 0 Thus f = 43.3 N. W = 43.3 x (cos180o) x 5 = -217 J
Page
T
N f mg
f
∆x 180o
Work by Variable Force
W = Fx ∆x
Work = area under F vs x plot
Force F ∆x
x
Force k F=
Spring F = k x Area = ½ k (x)2 = Wspring
Example A dart gun with a spring constant k = 400.0 N/m is compressed 8.0 cm. How much energy will it transfer to a dart when the spring is released? W = ½ k(∆x)2
Page
x
x
Kinetic Energy Suppose a constant force F is applied horizontally on a small rigid object of mass m. Its velocity will change, say from vo to v as it moves through a distance ∆x (without rotation). Work done on the object W = Fx ∆x [F parallel to ∆x] = m ax ∆x [Recall: v2 = vo2 + 2a(x-xo)] = ½ m (v2 – v02) = ½ mv2 - ½ mv02 The quantity ½ . mass . (velocity)2 is called kinetic energy of the object.
An object of mass m, moving with velocity v, has kinetic energy K = ½ mv2 ¾K ∝ m: If m is doubled, K will double. ¾K ∝ v2 If v is doubled, K will quadrupled. ¾Can K ever be zero? ¾Can K ever be negative? ¾W = ∆K
Can W ever be negative?
Page
Kinetic Energy F
vo
v ∆x
If more than one force acts on the object, the change in kinetic energy is the total work done by all the forces acting on the object. Total work Wtotal = ∆K This is called the Work- Energy Principle
Total Work Total work Wtotal = ∆K Wtotal = First find work done by each force , then add them. = first add all the forces and then then calculate work done by the net force Q: What is the total work done on an object moving with constant velocity? (A) Positive (B) Negative (C) Zero
Page
Example 1: A 30 N chest was pulled 5 m across the floor at a constant speed by applying a force of 50 N at an angle of 30o. How much work was done by all the forces acting on it? WT = F ∆x cos θ = (50 Ν)(5 m) cos (30) = 217 J WN = 0, Wmg = 0 Wf = -217J Wtotal = 217 + 0 +0 +(-217) = 0 T = 50 N 30o
N
T
f mg
Example 2: A 30 N chest was pulled 5 m across the floor by applying a force of 50 N at an angle of 30o. How much work was done by all the forces acting on it if its speed changed from 2 m/s to 5 m/s in the process?
Page
Example You are towing a car up a hill with constant velocity. The work done on the car by the normal force is: 1. positive 2. negative correct 3. zero
• Work done by gravity? • Work done by tension?
FN
V
T
W
Since the direction of the force is positive the value of work will be positive. it's negative because it's trying to slow down the car. The normal force does no work because it acts in a direction perpendicular to the displacement of the car.
Example: Block w/ friction z
A block is sliding on a surface with an initial speed of 5 m/s. If the coefficient of kinetic friction between the block and table is 0.4, how far does the block travel before y stopping? N
Y direction: F=ma N-mg = 0 N = mg Work WN = 0 Wmg = 0 Wf = f ∆x cos(180) = -µmg ∆x 5 m/s
f
x mg
W=∆K -µmg ∆x = ½ m (vf2 – v02) -µg ∆x = ½ (0 – v02) µg ∆x = ½ v02 ∆x = ½ v02 / µg = 3.1 meters
Page
POTENTIAL ENERGY Potential Energy (U) = stored energy. It is the energy an object possess due to its position or its configuration. There are different types of potential energy: Gravitational potential energy. Elastic potential energy. Electrical potential energy.
Gravitational Potential Energy To move mass m from initial point to final point at constant velocity, an external force FEXT, equal but opposite to the force of gravity must be applied. WEXT = F cosθ ∆y = mgh
Yf = h
= (mg)(cos0)h = mgh Wg =
FEXT
mgcos(180o)(h)
= -mgh
mg
Page
Yo = 0
Gravitational Potential Energy z The
quantity mgh is called gravitational potential energy near the earth’s surface: U = mgh
where U = 0 wherever we have chosen h = 0 • More general way of writing gravitational potential energy is
U = mg h
Gm1m2 r
FEXT
U = 0 at r = ∞
mg
U (r ) = −
U=0
Work done by force of gravity = Wg = - mgh The quantity mgh is called gravitational potential energy. The gravitational potential energy of an object of mass m at a height h is Ug = mgh Ug = mgh and Wg = -mgh ie Ug = - Wg. 2. Ug ∝ m 3. Ug ∝ h 4. A reference level where h = 0 can be chosen to be at any convenient location. 5. Only change in Ug is important. ∆Ug = mg∆h = mg(hf – hi) 1.
Page
Gravitational Potential Energy Example 3: A block slid down a plane If a block is slid down a plane. Distance moved down the plane = ∆s Vertical height moved = h How much work will the force of gravity do? W = F cosθ ∆x Wg = mg . cosθ . ∆S
h
But ∆S = ∆y /cosθ
θ mg
Wg = (mg)(cosθ)(h/cosθ) = mgh
Elastic Potential Energy Elastic (Spring) force F = -kx Work done by spring force W = ½ kx2 Energy stored in the spring when compressed or stretched by distance x
Elastic Potential Energy U = ½ kx2
Page
S
Example Emil throws an orange straight up and catches it at the same point it was thrown. (a) How much work is done during the orange’s free fall? (b) If the orange was thrown upward from a 1.2 m height above the ground and falls to the ground, how much work is done by gravity?
Conservative and Non Conservative Forces Sliding down a plane
h
Dropped θ mg Thrown
Work done by force of gravity, Wg = - mgh Independent of path
Page
Conservative Forces Forces which perform same amount of work independent of the path taken are called conservative forces. Eg: gravity, elastic force, electric force. 1. Work done by a conservative force depends only on the initial and final position and not on the path taken to get there. 2. Potential energy only goes with conservative forces. There is potential energy associated with gravity, elastic force, electric force. 3. WC = - ∆U
[ Ug = mgh and Uspring = ½ kx2]
Non Conservative Forces 1. Amount of work done by them depend on the path taken. Eg: friction, tension, push/pull. 2. There is no potential energy associated with non conservative forces.
Page
Work - Energy w/ Conservative Forces Total work = Work done by all types of forces. = Work by conservative forces + work by non-conservative forces WTotal = WC + WNC But WTotal = ∆K and WC = - ∆U So, ∆K = - ∆U + WNC ie, WNC = ∆K + ∆U
WNC = ∆K + ∆U
Work - Energy w/ Conservative Forces WNC = ∆K + ∆U When only conservative forces are acting; WNC = 0 0 = ∆K + ∆U OR
OR
0 = (Kf – Ki) + (Uf – Ui)
Kf + Uf = Ki + Ui
The quantity K + U is called mechanical energy E Thus Ef = Ei (Conservation of mechanical energy)
Page
Skiing Example (no friction) A skier goes down a 78 meter high hill with a variety of slopes. What is the maximum speed she can obtain if she starts from rest at the top? [Assume friction is negligible]
Conservation of energy: Ki + Ui = Kf + Uf ½ m vi2 + m g yi = ½ m vf2 + m g yf 0 + g yi = ½ vf2 + g yf vf2 = 2 g (yf-yi) vf = sqrt( 2 g (yf-yi)) vf = sqrt( 2 x 9.8 x 78) = 39 m/s
Example Suppose the initial kinetic and potential energies of a system are 75J and 250J respectively, and that the final kinetic and potential energies of the same system are 300J and -25J respectively. How much work was done on the system by non-conservative forces? 1. 0J 2. 50J Initially = 75 J + 250 J = 325 J. 3. -50J Finally = 300 J - 25 J = 275 J. 4. 225J Final -Initial = 275 - 325 = -50 J. No 5. -225J energy goes into or comes out of the system overall, so some nonconservative force has to be accounted for.
Page
Example A dart gun with a spring constant k = 400.0 N/m is compressed 8.0 cm. (a) How much energy will it transfer to a dart of mass 100 g when the spring is released? (b) What would be the escape speed of the dart? (c) If the dart was aimed upward, how high would it travel? Uspring = ½ k(∆x)2 K = ½ mv2, Ug = mgh
Power Average Power P = rate at which work is being done. = rate at which energy is being transformed. P = ∆W / ∆t Units: J/s = Watt ∆W/ ∆t = [F ∆x cos(θ)]/ ∆t = F (v ∆t) cos(θ) i.e., P = F v cos(θ)
Page
