davidm1732 said:
Was that the complete question? If so, I'd agree with your answer, and respectfully disagree with the two previous posts...
PeterO...if you put a backpack on the man... he (well the combination of him + backpack) does weigh more... which is why the reaction force increases... If he didn't, and the reaction force increased, you'd have a force imbalance and he'd accelerate upwards...
Tiny-tim... by definition, a reaction force is equal and opposite to the applied force (his weight in this example)...so both forces are not acting in the same direction. Draw a free body diagram of it...again, they have to be opposing, or else you wouldn't have static equilibrium.
PeterO...if you put him on an incline, yes the normal force is now not equal and opposite to the weight, but you have an additional vector component (the frictional force) that when added to the normal reaction force, is equal to the weight...again, if it were not, he'd be accelerating in one direction (down the slope in this case)
PeterO...you also give the exact example as the original question, but argue the opposite answer?...cheers
dsm
dsm: In order of comments:
1.
Putting a back pack on the man does not increase the weight of the man himself. My example was to show that the weight of the man and the reaction force from the floor are not even equal when the man is loaded up with something - like a back pack.
We could never put a limit on Newtons Third law which said "unless he is wearing a back pack", so we should never have thought this was an example of Newtons 3rd law in the first place.
2.
The weight of a man is the force of the Earth attracting a the man, it is NOT the force of the man on the ground. Take the ground away and the man still has weight - and as a result will accelerate down at a rapid rate until he meets a new ground - painfully probably
Newtons 3rd law couples can never give equilibrium - they act on different bodies.
Now a whole bunch of 3rd law couples might collectively hold one or more bodies in equilibrium
3.
OK so on the incline you have an extra force [same when you put the back pack on - the man was subjected to 2 downward forces; his weight and the backpack pushing down]
The fact that there are now need 2 forces to balance his weight means firstly, nether one of those extra 2 forces can constitute a 3rd law couple with his weight, and also that neither one of them is even in the opposite direction to the weight force.
4.
You need you read more carefully
The original question posed a question about the weight of the man [a force acting on the man] and the Normal Reaction force of the floor on the man [another force acting on the man.
My examples were 3rd Law couples
The Earth pulls the man down - the man pulls the Earth up
The first force act on the man, the second force acts on the Earth
The man pushes on the floor - the floor pushes on the man
The first force acts on the floor, the second force acts on the man.
Note that the Earth and the floor are not even the same body. One is possibly made of wood and the other is mostly molten rock with a crisp outer crust.
2 of those 4 forces act on the man - one from the first couple and one from the second couple.
The question asked was do these two constitute a 3rd law couple [were they an example of Newtons Third Law]. The answer is NO.
EDIT: David let's agree that at 12:00 Grenwich Mean time on Septemebr 6th - you will push South on a tree in a park with a Force of exactly 100N. I will be pushing with a force of 100N North on a tree in a Park near me at that time. Both those forces will be acting on the Earth [due to the trees growing in/on the Earth]. They will be equal in magnitude and opposite in direction. Will they constitute an action-reaction pair? I don't really think either of us actually have to got to the Park on the 6th.
