You know which factors have an impact on airfriction
You can explain the concept of terminal velocity
You can explain how the forces at work on a parachutist and the corresponding v-t graph are related with each other
Slide 3 - Diapositive
Slide 4 - Diapositive
Slide 5 - Diapositive
Free fall
Definition:
In Newtonian physics, free fall is any motion of a body where gravity is the only force acting upon it.
The gravitational force is the only force at work, so there is no air friction at all.
The term Free fall is often not used correctly of which the article of the NOS is an example. The free fall of the lift was not really a free fall since only the hoisting cable snapped. The other cable were still attached. Besides that the lift shaft is filled with air, so there was both air friction and friction from the other cables.
The people inside did survive their fall.
.
NOS,
19-11-2019
Slide 6 - Diapositive
Slide 7 - Diapositive
Upload your v-t graph
Slide 8 - Question ouverte
Slide 9 - Diapositive
Explanation
You can use this text to get a better understanding on how the v-t graph is interrelated with the forces at work.
Slide 10 - Diapositive
Airfriction (drag)
Can you explain why the v-t graph of a falling object will look like the graph below?
When there would be no airfriction the graph would follow the black line (see the graph on the right)
Slide 11 - Diapositive
Airfriction
The amount of air friction is influenced by:
the velocity of the object
the frontal area of the object
the density of the air
the aerodynamic shape of an object
Slide 12 - Diapositive
Drag Formula
- velocity
- frontal area (cross section)
- density
- aerodynamic value (drag coefficient)
FD=21⋅CD⋅A⋅ρ⋅v2
CD
(m2)
A
ρ
v
(m3kg)
(sm)
Slide 13 - Diapositive
Slide 14 - Vidéo
Slide 15 - Diapositive
Slide 16 - Diapositive
Slide 17 - Diapositive
Assignments
Question 1
Draw a x-t (distance against time) and a v-t (speed against time) graph of a falling rock without any air friction.
Question 2
Draw a x-t (distance against time) and a v-t (speed against time) graph of a falling rock with air friction.
Question 3
Look at both graphs. These graphs describe the motion of a falling object.
How can you make up out of both graphs that the air friction cannot be neglected?