Post by: #1procrastinator on January 16, 2013, 10:23:45 am
e.g. If we have 2kg block on the bottom and a 10kg block on top of it and pushed the 2kg block with a force of 10N, would the acceleration be 5m/s^2?
Post by: Homer on January 16, 2013, 10:37:12 am
Post by: Quantum.Mechanic on January 16, 2013, 10:54:57 am
This is shown in mythbusters, if one can move something fast enough, you are able to only move the object on the bottom. I remember the episode Tabletop Chaos, where they try to move only the table cloth without shifting the tableware on top of the table. If one can provide sufficient force/speed/acceleration, then one can shift the tablecloth without shifting the tupperware and the like on the table.
Its not exactly the same thing, but the concept is pretty much the same. The acceleration would have to be 5m/s^2, assuming the force is provided on the bottom block ONLY
Post by: #1procrastinator on January 16, 2013, 01:51:11 pm
I guess even if the surfaces are completely smooth the force required would be greater, due to the gravity force acting downwards, however this is just a wild guess :p
That's what I thought made intuitive sense too but the added weight would just increase the total normal force which would increase the frictional foce making it harder to push. But in this imagined case, there's zilch friction!
It depends on whether you want to move the whole object as one or not. But if they are both smooth, you can't shift the top block if you provide a force only to the bottom block. Otherwise only the bottom block would move, the top block would fall off..
This is shown in mythbusters, if one can move something fast enough, you are able to only move the object on the bottom. I remember the episode Tabletop Chaos, where they try to move only the table cloth without shifting the tableware on top of the table. If one can provide sufficient force/speed/acceleration, then one can shift the tablecloth without shifting the tupperware and the like on the table.
Its not exactly the same thing, but the concept is pretty much the same. The acceleration would have to be 5m/s^2, assuming the force is provided on the bottom block ONLY
So in an ideal situation where all surfaces are completely frictionless, it wouldn't matter how much mass you stack on right, the force required to accelerate the bottom mass (for some a) would always be the same?
The reason I'm asking is because I'm working on this problem:
A 'pedagogical machine' is illustrated in the link below. All surfaces are frictionless. What force F must be applied to M1 to keep M3 from rising or falling.
http://hep.physics.wayne.edu/~harr/courses/5200/w99/problem6-4.gif
And I want to know if the acceleration of the system would include M2 (might be heading in the wrong direction here...)
Post by: Quantum.Mechanic on January 17, 2013, 09:33:03 am
You would have to include the mass of m2 in the equation. This would be because of gravity, and the tension between the two objects. If you have the tension between the 2 objects, you have to consider it as a whole mass, because moving m2, will also move m3.
Do you have the exact problem, or is this solving equations with just unnumbered variables.
Post by: #1procrastinator on January 17, 2013, 12:28:57 pm
when M1 accelerates, M3 would accelerate horizontally at the same rate right? so the force from M1 on M3 would be different than the external force on the system? and since M3 is attached to M2, then it pulls in M2 making it part of the system...
yeah, that's the actual question. very few numbers in this book which I much prefer :]
Post by: Quantum.Mechanic on January 18, 2013, 12:09:52 pm
If they are touching each other, the friction shouldn't affect the force provided, it should rather be the same. The only thing that is working on m3 is gravity. And since M2 and m3 are connected, it should be rather part of the whole system.
So by moving M1, M2 and M3 should move due to gravity downwards, rather than sliding off, due to the tension in the rope.
I think thats my interpretation of it. I should read more about Physics, rather than the simple IB and First Year Uni ones.
:P
Post by: #1procrastinator on January 19, 2013, 03:28:04 am
Have no idea if that is correct though cause there is no solutions in the book lol. Only an hint which says 'for equal masses, F=3Mg' which i just realised answered one my questions above :p
The book is called 'an introduction to mechanics' by kleppner and kolenkow if you're interested. It's meant for a first year course but i think it's hard to learn from without other resources (i'm mainly learning from one of those standard bigass first-year textbooks. Quite a few concepts are .the problems are great though, really makes you think about the physixs carefully rather than rely on mathematical trickery.
Anyway, i have no idea yet how to do this next question which applies to the same pedagogical machine in the previous one.
Consider the pedagogical machine of the last problem in the case where F=0. FInd the acceleration of M1
Post by: PlainElegy on March 09, 2014, 09:44:58 pm
Post by: saradom136 on April 13, 2014, 12:04:48 am
A horizontal 0.65 m rod, weighing 3.6 kg, has a pin protruding from the centre of one end and a string with a 0.66 kg box hanging from the other end. Calculate how much torque the pin must exert to keep the rod from rotating.
[Hint: Assume the string is massless. g = 9.80 m/s2]
Post by: Conic on April 13, 2014, 02:40:22 pm
Can anyone help with this? :)First find the downward torque due to gravity (Using pin as the pivot):
A horizontal 0.65 m rod, weighing 3.6 kg, has a pin protruding from the centre of one end and a string with a 0.66 kg box hanging from the other end. Calculate how much torque the pin must exert to keep the rod from rotating.
[Hint: Assume the string is massless. g = 9.80 m/s2]
This is equal to the upward torque, so the pin provides a torque of 16Nm.
I found this question annoying, because they never told you what point to use as the pivot, but this method seemed to get the right answer.
Post by: saradom136 on April 13, 2014, 10:22:06 pm
Post by: hobbitle on July 31, 2014, 05:54:28 pm
Say I want to know what units something will end up in, I know you can 'calculate' using just units (but without actual values assigned to the variables). Say I have a formula and one of the variables in it is squared - do I square the units of it, too?
Post by: nerdgasm on August 01, 2014, 12:26:09 am
Wasn't sure where to put this question but I just have a little Q about units.Just as a bit extra, what happens when we take derivatives? For standard derivatives, say
Say I want to know what units something will end up in, I know you can 'calculate' using just units (but without actual values assigned to the variables). Say I have a formula and one of the variables in it is squared - do I square the units of it, too?
If I wanted to describe
Now, when we take a higher derivative like
So yeah, hopefully this helps a bit.
Post by: hobbitle on August 01, 2014, 11:40:36 am
Post by: JuliaPascale123 on October 21, 2017, 05:13:54 pm
https://imgur.com/a/Z1oBO (Graph)
Could I please have some assistance with calculating the pressure, volume and temp of each of the four points. (question 2)
I already did Question 1 so the efficency of the diesel motor is:
https://imgur.com/a/uesqN
Notice: This is physics im just not sure how to find the values from what they have supplied
Post by: Wren on April 06, 2018, 11:20:43 am
A fuel pump sends gasoline from a car's fuel tank to the engine at a rate of 7.81x10-2 kg/s. The density of the gasoline is 732 kg/m3, and the radius of the fuel line is 2.99x10-3 m. What is the speed at which gasoline moves through the fuel line?