define kinetic energy and potential energy, along with the appropriate units in each system. ...
TRANSCRIPT
Define kinetic energy and potential energy, along with the appropriate units in each system.
Describe the relationship between work and kinetic energy, and apply the WORK-ENERGY THEOREM.
Define and apply the concept of POWER, along with the appropriate units.
EnergyEnergyEnergyEnergy is anything that can be is anything that can be converted into work; i.e., anything converted into work; i.e., anything that can exert a force through a that can exert a force through a distancedistance.
Energy is the capability for doing Energy is the capability for doing work.work.
Potential Energy:Potential Energy: Ability to do work Ability to do work by virtue of position or conditionby virtue of position or condition.
A stretched bowA stretched bowA suspended weightA suspended weight
Gravitational Potential Gravitational Potential EnergyEnergy
What is the P.E. of a 50-kg person at a height of 480 m?
U = mgh = (50 kg)(9.8 m/s2)(480 m)
U = 235 kJU = 235 kJ
Kinetic Energy:Kinetic Energy: Ability to do work Ability to do work by virtue of motion. (Mass with by virtue of motion. (Mass with velocity)velocity)A speeding car A speeding car
or a space or a space rocketrocket
2 21 12 2 (1000 kg)(14.1 m/s)K mv
What is the kinetic energy of a 5-g What is the kinetic energy of a 5-g bullet traveling at 200 m/s?bullet traveling at 200 m/s?
What is the kinetic energy of a What is the kinetic energy of a 1000-kg car traveling at 14.1 m/s? 1000-kg car traveling at 14.1 m/s?
5 g5 g
200 200 m/sm/s
K = 100 JK = 100 J
K = 99.4 JK = 99.4 J
2 21 12 2 (0.005 kg)(200 m/s)K mv
A resultant force changes the velocity A resultant force changes the velocity of an object and does work on that of an object and does work on that
object.object.
m
vo
m
vfx
F F
( ) ;Work Fx ma x 2 2
0
2fv v
ax
2 21 102 2fWork mv mv
Work is Work is equal to the equal to the change inchange in ½mv½mv22
If we define If we define kinetic energykinetic energy as as ½mv½mv22 then we can state a very important then we can state a very important
physical principle:physical principle:
The Work-Energy Theorem:The Work-Energy Theorem: The work The work done by a resultant force is equal to done by a resultant force is equal to the change in kinetic energy that it the change in kinetic energy that it produces.produces.
2 21 102 2fWork mv mv
x
F = ?F = ?
80 80 m/sm/s
6 cm6 cmWork = ½Work = ½ mvmvff
2 2 - ½- ½ mvmvoo
22
0
F x = - F x = - ½½ mvmvoo22
FF (0.06 m) cos 180 (0.06 m) cos 18000 = - = - ½½ (0.02 kg)(80 (0.02 kg)(80 m/s)m/s)22
FF (0.06 m)(-1) = -64 J (0.06 m)(-1) = -64 J F = 1067 NF = 1067 N
Work to stop bullet = change in K.E. for Work to stop bullet = change in K.E. for bulletbullet
2525 mm fff = f = k.k.n = n = k k mgmg
Work =Work = F(F(cos cos ) ) xx
Work = - Work = - k k mg mg xx
0K =K = ½½ mvmvff
2 2 - ½- ½ mvmvoo22
-½-½ mvmvoo22 = - = -k k mgmg xx vvoo = = 22kkgxgx
vo = 2(0.7)(9.8 m/s2)(25 m) vo = 18.5 m/s
vo = 18.5 m/s
Work = K
K = Work
hh3030
00
nnff
mgmg
xx
Plan: Plan: We must calculate We must calculate both the resultant work both the resultant work and the net displacement and the net displacement xx. Then the velocity can . Then the velocity can be found from the fact be found from the fact that that Work = Work = K.K.
Resultant work = (Resultant force down Resultant work = (Resultant force down the plane) the plane) xx (the (the displacement down the displacement down the plane)plane)
h
300
nf
mg
x
From trig, we know that the Sin From trig, we know that the Sin 303000 = = h/x h/x and:and:
0
20 m40 m
sin 30x 0sin 30
h
x
hx
303000
WWyy = = (4 kg)(9.8 m/s(4 kg)(9.8 m/s22)(cos 30)(cos 3000) = 33.9 N
hh
303000
nnff
mgmg
x = x = 4040
mm
Draw free-body diagram to find the resultant Draw free-body diagram to find the resultant force:force:
nnff
mgmg303000
x
y
mgmg cos 30 cos 3000 mgmg sin 30 sin 3000
WWxx = = (4 kg)(9.8 m/s(4 kg)(9.8 m/s22)(sin 30)(sin 3000) = 19.6 N
nnff
mgmg303000
x
y
33.9 N33.9 N19.6 N19.6 N
Resultant force down Resultant force down plane: plane: 19.6 N - 19.6 N - ffRecall that Recall that ffkk = = k k
nnFFyy = 0 or = 0 or nn = 33.9 = 33.9 NN
Resultant Force = 19.6 N – kn ; and k = 0.2Resultant Force = 19.6 N – (0.2)(33.9 N) = 12.8 N
Resultant Force Down Plane = 12.8 N
(Work)(Work)RR = = FFRRxx
FFRR
303000
xxNet Work = (12.8 N)(40 m)Net Work = 512 J
Finally, we are able to apply the work-energy theorem to find the final velocity:
2 21 102 2fWork mv mv
0
hh3030
00
nnff
mgmg
xx Resultant Work = Resultant Work = 512 J512 JWork done on block Work done on block
equals the change in K. equals the change in K. E. of block.E. of block.
½½ mvmvff2 2 - ½- ½ mvmvoo
22 = = WorkWork
0 ½½ mvmvff
22 = = 512 J512 J
½½(4 kg)(4 kg)vvff22 = 512 = 512
JJ vf = 16 m/svf = 16 m/s
Power is defined as the rate at which work is done: (P = dW/dt )
10 kg
20 mh
m
mg
t
4 s
F
Power of 1 W is work done at rate of 1 J/s
Power of 1 W is work done at rate of 1 J/s
Work F rPower
time t
Work F rPower
time t
2(10kg)(9.8m/s )(20m)
4 s
mgrP
t
490J/s or 490 watts (W)P 490J/s or 490 watts (W)P
1 W = 1 J/s and 1 kW = 1000 W
One watt (W) is work done at the rate of one joule per second.
One ft lb/s is an older (USCS) unit of power.One horsepower is work done at the rate of 550 ft lb/s. ( 1 hp = 550 ft lb/s )
Power Consumed: P = 2220 W
Power Consumed: P = 2220 W
What power is consumed in lifting a 70-kg robber 1.6 m in
0.50 s?Fh mghP
t t
2(70 kg)(9.8 m/s )(1.6 m)
0.50 sP
Recognize that work is equal Recognize that work is equal to the change in kinetic to the change in kinetic energy:energy: Work
Pt
2 21 102 2fWork mv mv
2 21 12 2 (100 kg)(30 m/s)
4 sfmv
Pt
m = 100 kg
Power Consumed: P = 1.22 kW
Power Consumed: P = 1.22 kW
Recall that average or constant velocity is distance covered per unit
of time v = x/t.
P = = Fx
t
F x
tIf power varies with time, then calculus is needed to integrate over time. (Optional)
Since P = dW/dt: ( )Work P t dt ( )Work P t dt
P FvP Fv
v = 4 m/s
P = (900 kg)(9.8 m/s2)(4 m/s)
P = F v = mg v
P = 35.3 kW
P = 35.3 kW
Work = 132,000 ft lb
Work = 132,000 ft lb
550ft lb/s4hp 2200ft lb/s
1hp
(2200ft lb/s)(60s)Work
; Work
P Work Ptt
The Work-Energy Theorem:The Work-Energy Theorem: The work The work done by a resultant force is equal to the done by a resultant force is equal to the change in kinetic energy that it produces.change in kinetic energy that it produces.
The Work-Energy Theorem:The Work-Energy Theorem: The work The work done by a resultant force is equal to the done by a resultant force is equal to the change in kinetic energy that it produces.change in kinetic energy that it produces.
Potential Energy:Potential Energy: Ability to do Ability to do work by virtue of position or work by virtue of position or conditioncondition.
U mgh
Kinetic Energy:Kinetic Energy: Ability to do work Ability to do work by virtue of motion. (Mass with by virtue of motion. (Mass with velocity)velocity)
212K mv
Work = ½ mvf2 - ½
mvo2
Work = ½ mvf2 - ½
mvo2
Power is defined as the rate at which work is done: (P = dW/dt )
WorkP
t
Work F rPower
time t
Work F rPower
time t
Power of 1 W is work done at rate of 1 J/s
Power of 1 W is work done at rate of 1 J/s
P= F v
