Looks like those "layman's definitions" is what's confusing you.alkaspeltzar said:Can anyone give me a layman's definition of work?
How would you define it exactly?A.T. said:Looks like those "layman's definitions" is what's confusing you.
https://en.wikipedia.org/wiki/Work_(physics)#Mathematical_calculationalkaspeltzar said:How would you define it exactly?
And when you get two different answers from two different people, then you will be confused again?alkaspeltzar said:So I was looking for someone to explain how they think about it.
alkaspeltzar said:Clearly work is a form of energy.
alkaspeltzar said:I just want to know if work can therefore be thought of as "energy being exerted or expended" on a system. is that what work is? Seems confusion how work and energy have same units.
alkaspeltzar said:Okay but then why is work same as energy? Everything I read yes explains the conversion part, but isn't the force thru the distance like energy or an applied energy
It's not; work is a mechanical transfer of energy. You can also transfer energy via radiation/heat, electricity, chemical transport, etc.alkaspeltzar said:Okay but then why is work same as energy? Everything I read yes explains the conversion part, but isn't the force thru the distance like energy or an applied energy
DaveE said:Work is the amount of Energy that has been transferred or changed by a process. Energy is more static, work involves the amount of energy change.
Careful there. Looking at the units or dimensionality can provide insight but it can also lead you astray.alkaspeltzar said:clearly work is a form of energy. It has units of it. I just want to know if work can therefore be thought of as "energy being exerted or expended" on a system. is that what work is? Seems confusion how work and energy have same units.
Oh dear. Intuitions based on body physiology cause way more misunderstandings than they cure.phinds said:Think about this: you pick up a box weighing 100lbs. You carry the box 5 feet and place it on a shelf that is 3 feet higher than the level it was at when you picked it up. You have done a well defined amount of work.
Now pick up that same box and carry it half a mile out and then half a mile back and then place it on the same shelf. You have done exactly the same amount of work as in the first instance.
Do you seriously believe that you have expended the same amount of energy in both cases?
phinds said:Think about this: you pick up a box weighing 100lbs. You carry the box 5 feet and place it on a shelf that is 3 feet higher than the level it was at when you picked it up. You have done a well defined amount of work.
Now pick up that same box and carry it half a mile out and then half a mile back and then place it on the same shelf. You have done exactly the same amount of work as in the first instance.
Do you seriously believe that you have expended the same amount of energy in both cases?
I don't see why. You expend a lot of energy just using your muscles, but you aren't necessarily getting any work done.Drakkith said:I'm with gmax. This is more about biology than physics, and will be confusing out of context.
You're doing all that work on your muscles, not on the box. Which just brings the question back to what the difference between energy and work is.phinds said:I don't see why. You expend a lot of energy just using your muscles, but you aren't necessarily getting any work done.
I can't decide if this is completely irrelevant or just unnecessarily confusing. Best to consider closed systems if you are going to tally up work done vs. energy stored.phinds said:Think about this: you pick up a box weighing 100lbs. You carry the box 5 feet and place it on a shelf that is 3 feet higher than the level it was at when you picked it up. You have done a well defined amount of work.
Now pick up that same box and carry it half a mile out and then half a mile back and then place it on the same shelf. You have done exactly the same amount of work as in the first instance.
Do you seriously believe that you have expended the same amount of energy in both cases?
Hmm. I thought that was what I said. I actually think we all agree about this, we are just describing it differently.Drakkith said:Hmm. Wouldn't the amount of energy transferred just be the amount of energy itself? To me, this makes it seem like there are two names for the same thing, whereas thinking of work as a process in and of itself removes this conflict.
If you like this way of thinking, there is an analogy between work and impulse, in that both represent a transfer of a conserved quantity:alkaspeltzar said:So I do agree that are different as energy is stored but then work is still a "energy applied" or transferred in a sense.
That's where the analogy breaks down a bit, because there is only one form of momentum, so every impulse has some equal but opposite impulse in a closed system. But since energy can be converted into/from other forms, the negative work doesn't always equal some positive work done.alkaspeltzar said:If they weren't equal, then conservation of energy wouldn't work either, becuase work in has to equal something out
DaveE said:3) I know a lot of people will disagree with me, but I do actually think they are nearly the same thing. Energy is a property of things, and it can change when it is moved to other things. We call that change Work (perhaps to confuse 1st year physics students).
DaveE said:2) The amount of energy is also a property, of a thing or, perhaps a process. A flywheel can have energy (stored) when there is no work involved at a specific time. However, the energy of the flywheel can not be changed without work. There must be some process, with work, to change the energy of the object. The energy added by the process is not quantitatively the same as the (total) energy of the object.
I think "transfer of energy" is better than "change of energy" as description of work done by a force. An individual force can be doing work, while the energy doesn't change, because other forces do negative work.DaveE said:Energy is a property of things, and it can change when it is moved to other things. We call that change Work
"Doing work" is the processDrakkith said:If the work isn't the process, then the word 'work' is meaningless here.
Fair enoughDrakkith said:You're doing all that work on your muscles, not on the box. Which just brings the question back to what the difference between energy and work is.
This is the one time that I think Imperial Units are more helpful than SI and other metric systems. There is a clear distinction (marked on the sides of instruments actually) between Pound Feet (torque) and Foot Pounds (Work). Of course, the Joule is work done when a force of One Newton MOVES THROUGH one metre but it is never called a Newton metre. It would have helped if the unit for torque were chosen to be the metre Newton .gmax137 said:Wait until you get to torque -- that might "really bake your noodle" -- it too has units force x distance, Newton-meters. but nobody calls out torque in joules.
Plus one! this is really sound advicesophiecentaur said:@alkaspeltzar : Look at @A.T. 's post #8 again. Doing what he suggests will achieve much more for you than reading all the comments on this thread ten times.
A.T. said:"Doing work" is the process
"Work" is the amount of energy transferred in the process.
"Work" in a scientific context is a measure of the amount of energy transferred from one system to another. It is typically represented by the symbol W and is calculated by multiplying the force applied to an object by the distance it travels.
Work and energy are closely related concepts in science. Work is the transfer of energy from one system to another, and the amount of work done is equal to the change in energy of the system. In other words, work is a way of measuring the energy that is transferred or transformed.
The SI unit of work is the joule (J), which is defined as one newton-meter (N*m). Other common units of work include kilojoules (kJ) and calories (cal). In the imperial system, the unit of work is the foot-pound (ft-lb).
Work is calculated by multiplying the force applied to an object by the distance it travels in the direction of the force. Mathematically, this is represented by the equation W = F*d, where W is work, F is force, and d is distance. It is important to note that both force and distance must be in the same direction for work to be done.
Some common examples of work in everyday life include pushing a shopping cart, lifting a book, and pedaling a bicycle. In each of these scenarios, a force is applied to an object, causing it to move a certain distance. Other examples of work include using a hammer to drive a nail, carrying a backpack, and pushing a lawn mower.