Lesson 12 Chapter 4

Force and motion
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In deze les zitten 22 slides, met tekstslides.

time-iconLesduur is: 45 min

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Force and motion

Slide 1 - Tekstslide

Work

Slide 2 - Tekstslide

Work
a measure of how much energy a force transferred to an object.

Slide 3 - Tekstslide

Work
W=Fs
a measure of how much energy a force transferred to an object.

Slide 4 - Tekstslide

Work
W=Fs
a measure of how much energy a force transferred to an object.
Quantity
Unit
work (W)
Newton-meter (Nm)
Force (F)
Newton (N)
distance covered (S)
meters (m)

Slide 5 - Tekstslide

Work
W=Fs
a measure of how much energy a force transferred to an object.
Quantity
Unit
work (W)
Newton-meter (Nm)
Force (F)
Newton (N)
distance covered (S)
meters (m)
A force that causes an object to move is called a motive force

Slide 6 - Tekstslide

Work & Energy

Slide 7 - Tekstslide

Work & Energy
a measure of how much energy a force transferred to an object.
1 Unit of work = 1 unit of energy 
1 Newton-meter (Nm) = 1 Joule (J)

Slide 8 - Tekstslide

Work and energy
η=EtotEused100
Eused=work

Slide 9 - Tekstslide

Work and energy
η=EtotEused100
Eused=work
Example
The work done by the force generated by a car engine is equal to the useful energy generated by that car enginge.

Slide 10 - Tekstslide


Do exercise 7 and 8 

From section 4.3

To apply this new material

Slide 11 - Tekstslide

Do exercise 7 and 8 From section 4.3

To apply this new material
Work a measure of how much energy a force transferred to an object.
W=Fs
η=EtotEused100
Eused=work
Unit of work: Newton-meter (Nm)

1 Newton-meter (Nm) = 1 Joule (J)

Slide 12 - Tekstslide

                    Practice problem
1) In which segment does the greatest acceleration take place?

2) Calculate is the acceleration in segment B?

3) Calculate the distance covered.
A
B
C
D

Slide 13 - Tekstslide

Acceleration
a=ΔtΔv

Slide 14 - Tekstslide

Acceleration
a=ΔtΔv
a=Δtvfvi

Slide 15 - Tekstslide

imagine a rollercoaster ride with the following start.
  •  You sit down

  • 35 seconds later the ride starts to move. Which starts with being pulled up a slope at a steady speed of 2.2 m/s.

  • now 55 seconds after sitting down you reach the top of the slope and get dropped down causing the speed to increase tremendously.

  • a moment later 61 seconds after sitting down you reach the bottom of the drop with a tremendous speed of 31 m/s. 

Calculate the the acceleration during the drop.



Slide 16 - Tekstslide

a=Δtvfvi
Δt=avfvi
vi=vf(at)
vf=(at)vi

Slide 17 - Tekstslide

a=Δtvfvi
Δt=avfvi
vi=vf(at)
vf=(at)vi

Slide 18 - Tekstslide

a=Δtvfvi
Δt=avfvi
vi=vf(at)
vf=(at)vi

Slide 19 - Tekstslide

a=Δtvfvi
Δt=avfvi
vi=vf(at)
vf=(at)vi

Slide 20 - Tekstslide

  • Study the concept of inertia

  • Get savvy with the Newtons second law
Fres=ma

Slide 21 - Tekstslide

  • Study the concept of inertia

  • Get savvy with the Newtons second law
Fres=ma
  • know the meaning of its components
  • Be able to rearrange it
  • Understand what it means
  • Tip 1: look up some youtube videos
  • Tip 2: Do exercise from the book (answers will be provided)

Slide 22 - Tekstslide