Talk:Simple machine

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Give me strength. — Preceding unsigned comment added by 79.79.153.6 (talk) 14:16, 24 July 2022 (UTC)[reply]

Does anyone know exactly what a simple machine is?

Should it say "In mechanical engineering" instead of "In physics"? Also, can anyone explain how it is known that there are just these six and no others? Is it just engineering experience, or is a something like a mathematical theorem? Michael Hardy 18:45, 24 Mar 2005 (UTC)

A simple machine is the most basic possible machine that operates on a specific mechanical principle. The pulley, for example, is the simplest way to change the direction of a pulling force without wasting it all (as occurs when you simply pull a rope around a corner). Adaptations of a simple machine are not different machines in themselves, even if they can do things that the basic mechanism does not inherehtly do. A block and tacke, for instance, is an application of the pulley that produces a mechanical advantage although the basic pulley does not. The number of simple machines is defined by the number of known unique mechanical principles.

Despite what so many "experts" say, there are not six principles, which would allow six simple machines. There are four or, if you count Rolamite, five. The four are the inclined plane, lever, pulley, and wheel and axle. Both the screw and the wedge are applications of the inclined plane; and, in fact, the Wikipedia articles on them both so state. Because an application of a simple machine is not a different simple machine, the number is really four. Rolamite, which I include as a fifth simple machine, operates on a principle unlike those of the other four simple machines, and some experts consider it to be a fifth simple machine.

Richard Binder • Pens That Write Right! 23:54, 7 January 2007 (UTC)

Well, you're partly right. The concept of simple machines is intended to identify the lowest common denominators for the transformation of forces. ("Wasting" has nothing to do with it - pulling the rope around a corner is actually an example of an inefficient class 1 pulley.) Inclined planes, levers and pulleys tranform the direction and magnitude of a force. The wheel-and-axle transforms a rotational force into a lateral force and vice versa. The screw also transforms a rotational force but this time into a longitudinal force. Is that sufficient to earn its own "class" as a simple machine? That's an interesting question but neither of our opinions are relevant to the article. Historically, there have been 6 classes of simple machines. The article already notes that some scholars have tried to revise the count but six is still the most commonly accepted list.

Your example of the rolamite is new to me, but on first glance it appears to be in implementation of the wheel-and-axle. The potential applications look fascinating but, Popular Science notwithstanding, I think the jury's still out on whether this will be seen as another simple machine. Rossami (talk) 03:47, 8 January 2007 (UTC)[reply]

I think arguing about the number of simple machines is somewhat of a moot point. As was stated above, the designation simple machines arises from engineering, not physics. There is not any "law" in physics that defines a simple machine, but through experience we have developed tools that can easily be utilized to change forces, direction of motion, etc. From reading several articles on wikipedia I've begin to notice how the line between what is science and what is engineering is often blurred, I assume because it in general it encourages education in both areas. Still, I think it is very important to distinguish whether something is a scientific concept or an application of science. I don't know if we need to change physics to mechanical engineering in the article, but I hope people can see the difference. Arsawyer84 16:33, 21 July 2007 (UTC)[reply]

Can I suggest that if the 6 examples are indeed a 'classic' list, then we find some references for this, eg physics text books etc. And then the second part of the article can elaborate on how some of them use the same principles. I can't help thinking that the list of the simple machines must rooted quite deep in history, as this would explain why '2pistons+hydraulic coupling' is not included in the list. Jimbowley 13:14, 22 August 2007 (UTC)[reply]

Tried to address the issue of the arbitrariness of any list of simple machines by a rewrite in May. Hope it helps --Chetvorno^TALK 12:04, 26 June 2008 (UTC)[reply]

The line between science and engineering is only 'blurred' by ignorant people who don't understand these terms. For example, there is no such thing as 'rocket science'. It's pure engineering. That is why 'physics' in this article is nonsense - it should be 'mech. engineering'. There are also people who don't understand the difference between invention and discovery, e.g. the author of the Rolamite article and the ignorant clowns who award patents for genes (as distinct from patents for methods of isolating them). Finally, the Rolamite is an obvious application of the wheel, just as the block and tackle is an application of the pulley. — Preceding unsigned comment added by 79.79.153.6 (talk) 14:24, 24 July 2022 (UTC)[reply]

Is a hydraulic system a simple machine, independent of the others?

reversed statement on hydraulics because link supplied [1] did not support the statement. My statement may be a bit strong, but I suspect it is a better representation than the previous statement. Hmmmmm. Even if they were included in a few lists somewhere, the inclusion would be 'wrong' so I'm not even sure whether the hydraulics thing should be mentioned at all? Jimbowley (talk) 13:56, 12 December 2007 (UTC)[reply]

Hydraulics is the science and the hydraulic press is the simplest possible application of the science in a machine.

The hydraulic press was invented by Blaise Pascal around 1645, and is the latest invention to be potentially included in the list of simple machines. All the other members on the list are thousands of years old.

For a hydraulic press to be a Simple Machine the following must be proved to be true :

a) requires a single force to work

b) performs force transformation (change direction, multiply/reduce force/speed)

c) is not a compound machine (cannot be broken down into simpler Simple Machines)

d) is not a variation on an existing Simple Machine

e) no overzealous application of d) is used (similar to making the Six Simple Machines into only 2 - see main article).

a) and b) are easily true according to most articles on the subject.
c) while a hydraulic Jack is broken into a lever for the handle and a hydraulic press, the hydraulic press itself is typically not broken further down into simple machines.
d) and e) are the tricky requirements.

References for hydraulic press being a kind of Pulley [2]

References for hydraulic press being a kind of lever [3], [4]

References for hydraulic press being a unique Simple Machine [5], [6], [7], [8], [9], [10], [11]

Ambivalent references that mention hydraulic press along with simple machines, but at the same time claim it is not one of the six classical machines. [12], [13], [14]

If the list of 6 classical machines is collapsed into only 2 simple machines [15] then the hydraulic press would belong in the group: lever together with pulley and wheel.

But if we consider the mental leap necessary for jumping from pulley or wheel to lever, then the jump from hydraulic press is of of equal proportion. This would make the hydraulic press a Simple Machine, on the same level as Wheel and Pulley.

Conclusion : The current six Simple Machines are the classical list of Simple Machines, with the hydraulic press being a Simple Machine but not a classical Simple Machine, it being a added in modern time.

Please point out flaws in my (non-original) research, assumptions and conclusions. Jesper Jurcenoks (talk) 04:05, 2 April 2008 (UTC)[reply]

100% correct!

I suppose that a spring could be regarded as another simple machine, if attachments were made at different points along the spring. Such a spring would convert a small force applied at the end through a large distance, to a larger force applied through a smaller distance at one of the attachments. Some conveyor belts use such a transformation of force of a spring, to avoid shocks in loading.

--Joseph D. Rudmin 18:27, 11 January 2007

What you have described does not actually transform the forces. Springs store and release energy. During release, they apply force identically-opposite to the force applied during storage. The distance over which the force is applied is unchanged. Rossami (talk)

A machine ought to be able to multiply force - "mechanical advantage". A spring is able to multiple Power, that is the energy is released much faster than it is accumulated. A little out of the scope of Basic mechanics, though. Good observation.Pete318 (talk) 23:08, 9 April 2008 (UTC)[reply]

Err, no. A simple pulley does not multiply the force. Nor does the inclined plane.

There really are only four simple machines. Look at the articles for the wedge, screw, and the incline plane. Essentially, the goals of these three machines are the same and thus they are the same machine. Please note that the screw in itself to be an incline plane but rather the threading around the screw that lets it enter an object. Read the articles on each of these three machines. —Preceding unsigned comment added by 71.53.70.145 (talk) 03:08, 9 September 2007 (UTC)[reply]

Many have argued that (and the article already says so). The classic list, however, is of six based on differences in the interpretation of how forces are transformed. For example, you could interpret a screw as a helical inclined plane or you could say that the inclined plane transforms a horizontal force into a vertical force while the screw transforms a rotational force into a longitudinal force. Rossami (talk) 04:44, 9 September 2007 (UTC)[reply]

I suppose that this is true. I guess my main quarrel with this article was how it seemed to state that very few people believed there to be only four simple machines. I had believed that the idea should be given a bit more thought. Yet I admit that this annoyance I have is not really all that big. —Preceding unsigned comment added by 71.53.70.145 (talk) 9 September 2007

There is no such thing as a 'rotational force'. When turning a screw, at each moment you are applying a straight tangential force. The screw IS an inclined plane (which does NOT 'transform a horizontal force into a vertical force' in any shape or form). — Preceding unsigned comment added by 79.79.153.6 (talk) 14:34, 24 July 2022 (UTC)[reply]

As has already been discussed extensively above, there is no magic answer for the definitive number of simple machines. However, the classic texts generally list the six shown in the current version of the article. Here are a few quick citations of publications with notes on their counts. Most of these are teacher-support sites aimed at elementary or middle school students and their teachers. I don't consider any of the ones I found to be ideal cites. Better references are requested from anyone who can find them. Rossami (talk) 05:14, 24 October 2007 (UTC)[reply]

• The Franklin Institute - 6
• The Science Learning Network - 6
• Scholastic books - 6
• Utah State Office of Education - 6
• Henry County Public Schools, GA - 6
• NASA Glenn Research Center -6
• GSU Physics/Astronomy Dept - 6
• MiKids.com - 6
• Teacher resource cite hosted from Univ of Houston - 6
• EdHeads.org - 7 (includes the gear)
• Boston Museum of Science - 5 (omits the inclined plane)

Note: None of these cites verify the mnemonics that were added to the article back in July 2005. If the mnemonics can't be independently sourced, we should probably pull them out. Rossami (talk)

Thanks for your efforts Rossami, I think we have the same view. We still need a good citation for the 'classic list of six' to prove that there is such a thing. Within the above citations there is plenty of misunderstanding especially on wheel and axle (a wheel on a wagon is not a 'wheel and axle' in the simple machine sense) this is someting I am making my mission to bring clarity to. And the use of a woodscrew as an example of the screw is pretty much 99% missing the point, a car jack (of the vertical screw type)would be a perfect example. Jimbowley 12:43, 24 October 2007 (UTC)[reply]

While there is certainly plenty of misunderstanding on this topic, I don't think your two examples are quite it. A wheel on a wagon is still an example of a wheel-and-axle because it is converting the magnitude of force needed to overcome friction at the point of attachment. Consider that without the wheel, the bed of the wagon must be pushed along the floor and will require a certain force (exerted over a given distance) to overcome the friction. With the wheel, the point of friction is moved to the connection between the axle and the wagon (or the axle and wheel hub in the more conventional design). The force you use to push the wagon is increased by the ratio of the radii of the wheel and axle (and the distance moved at the point of connection correspondingly reduced).
On your second point, a bolt would be a better example than a woodscrew because a "normal" woodscrew is simultaneously a simple screw and a wedge. The woodscrew (like the car jack screw) converts a rotational force into a longitudinal force while it is being inserted. That longitudinal force powers the wedge which causes the wood fibers to separate and then to provide friction against the screw. But the difference between a woodscrew and a bolt is not that great to a third grader - and that was the apparent target audience of most of these sites. Rossami (talk) 23:15, 24 October 2007 (UTC)[reply]

There is no such thing as a 'rotational force'. When turning a screw, at each moment you are applying a straight tangential force. It is an inclined plane (+ conceivably a wedge). — Preceding unsigned comment added by 79.79.153.6 (talk) 14:37, 24 July 2022 (UTC)[reply]

In reverse order. My example 2, Yes a bolt is better than a screw as an example, but the car jack is much better because lifting a car is understandable to a layman as 'work' where as after doing up a bolt the 'work achieved' is harder to understand (mainly because you can't normally see it).
On whether a wheel on wagon is an example of a simple machine, I can see that I should first persuade you before I tackle the world. This is a little difficult because the wiki pages for simple machine and wheel-and-axle share some of the wrong ideas. anyway, here goes:

Why a wheel is not a machine.[edit]

I like to consider lifting objects when thinking about simple machines, in fact I think a useful definition of a simple machine would be that it can help you lift something heavy. However for the purpose of this argument I will use the task of getting a heavy rock from A to B (separated horizontally).
A) We could drag the rock from A to B. This would require considrable effort to be expended.
B) We could attach pulleys to the rock and to a handy tree. The mechanical advantage of this machine means you need to pull the rope less hard (but further) to drag the rock. The same effort is expended.
C) We could spread super slick grease (mu=0.0) along the floor. This would reduce the effort required to a negligible amount.
D) We could attach wheels to rock. This would reduce the effort required to a negligible amount.

The point of these illustrations is that the wheel is like the grease, not like the pulley. The wheel removes the friction that is causing the effort to be expended, it does not give you a mechanical advantage over it.

An important concept is that no 'useful work' has been done in the example above. If we return to the subject of lifting things, we can see that the pulley can help us, but the grease and the wheel are not helpful.
I await comments. I'm sure I can improve my argument if this does not convince. regards. Jimbowley 15:42, 31 October 2007 (UTC)[reply]

Your A-D are a great way to explain this. But the wheel is more like a pulley than like grease because, contrary to intuition, the wheel does not remove any friction - it just moves it to a different point and trades distance for force. Friction is a function only of μ, the coefficient of friction (which is an empirical property of the contacting materials) and Fn, the normal force exerted between the surfaces. If you put the rock in a wooden wagon bed, make your wheel, axle and floor all from the same wood with exactly equal smoothness, etc, the coefficient of friction is the same whether between the wagon bed and the floor or between the wagon bed and the axle. And the mass of the rock is unchanged, so the normal force between the wagon and the floor is the same as the normal force between the wagon and the axle. Thus, the force of friction is equal in either scenario. (Now, you can grease the axle and thereby affect μ but for the purposes of this discussion, that would be cheating. Let's continue to assume identical materials. Let's also assume for simplicity that this is a very rudimentary wagon with the wheels fixed to the axle and the axle free to spin within some sort of bracket attached to the underside of the wagon bed.)

To drag the rock from A to B, you must do work equal the force necessary to overcome the friction times the distance travelled - μ Fn (B-A) - because the entire wagonbed travels from A to B, scaping along the floor the whole way.

When you add wheels, the force you apply on the wagon is balanced by the force of the floor on the bottom of the wheel. The force at the bottom of the wheel is transferred into a force applied between the bed of the wagon and the exterior surface of the axle. In doing so, the force is increased in magnitude by the ratio of the radii of the wheel and the axle but is applied over a shorter distance in the same ratio. Since we only have to overcome μ Fn of frictional force at the point of connection, we can use much less input force on the back of the wagon to do so.

Another way to think about it is to consider what would change if you attached a log to the bottom of the wagon instead of a wheel and axle - that is, what if the radii of the wheel and axle were the same? If you nail the log to the bed, you've got wood-to-wood friction (because you're still on the wood floor). If you allow the log to spin within the bracket, you've got wood-to-wood friction of exactly the same magnitude.

Having said all that to defend the "wagon wheel" example, I think that winching the bucket up from the waterwell is a more intuitive example and is much better suited for most classes. Rossami (talk) 20:38, 31 October 2007 (UTC)[reply]

On Wheel-and-axle, I added a picture of a waterwell some weeks ago, but used the wrong licence declaration so it got pulled. It may not be the best example anyway because on a waterwell the 'wheel' is usually just a handle and hence does not look like a wheel. I've tried to find an illustration of the wheel and axle that I suspect were used to raise the drawbridge, or raise the portcullis, in a castle. Or maybe I can find an example on a trebuchet.

I see that I need to apply some further argument to persuade you that a wheel is not a machine. I do this not for the sake of winning the argument or to save you from your misconception but to clear the way for me to correct the articles.

Your argument above is based on saying that the wheel does not remove friction but just moves it to a different place. But that is wrong for any example other than your specific wheel/axle/road made of the same material. How does your argument stand up if the wheel has frictionless bearings? Is that a machine still? You said yourself right at the top of this page that 'wasting effort' has nothing to do with it, yet your argument now relies on frictional waste to argue that the wheel is a machine.

Perhaps this confusion is all arising becasue we don't have an agreed definition of 'simple machine' rather we have a historical list but don't know the concept behind the list. For me, a simple machine gives you a mechanical advantage so you can lift stuff, but I'm not sure what makes it 'simple'. Jimbowley 13:46, 1 November 2007 (UTC)[reply]

If the wheel, axle or road are made of different materials or if you add bearings, then you are correct that the wheel has the additional effect of changing μ. That does not invalidate the observation that the wheel and axle also transforms forces as a simple machine (though you could argue that if you are simultaneously changing μ that it is now a slightly complex machine).

I think you're right that we disagree over the definition of a simple machine. You are framing it solely in terms of lift. Enabling lifting is a pretty good example but not complete. In classical mechanics, a "machine" is anything which can transform a force in either magnitude or direction. A lever can change the magnitude and/or the direction of a force, whether that force is used to lift a rock up or press a bullet down into a casing or simply to crack a walnut shell (neither up nor down). Likewise, the pulley changes magnitude and direction of a force whether it is vertical (lifting a rock) or horizontal (pulling a ship out to sea). The inclined plane and wedge transform horizontal forces into a vertical forces and vice versa. A screw transforms rotational force into a longitudinal force and vice versa. A wheel and axle transforms a rotational force into a lateral force and back.

The "simple" part is what has always been problematic. In theory, these are the six "simple" machines because they were thought to represent the lowest common denominators - that all other machines could be composed of combinations and variations on these. As the article already says, many people believe that some of the six are not in fact the lowest common denominator - that, for example, the wedge is a variation on the inclined plane. Nevertheless, these are the classic six. Rossami (talk) 05:45, 2 November 2007 (UTC)[reply]

I am not saying all machines are lifting devices, just that thinking about lifting is useful when determining whether something is a machine. All the 'simple machines' can be used to help you lift something. Similarly, all the simple machines could be used to help get your bullet into its casing. But a wheel will not help you get a bullet into its casing.

You did not answer my challenge to your argument. What if the wheel has a frictionless bearing? Where is the transformation of forces, that your defintion of machine relies on? (note that this does not imply that I accept your definition of machine, I am simply taking your argumant apart).Jimbowley 14:05, 2 November 2007 (UTC)[reply]

As I said above, a wheel with any kind of bearing (frictionless or not) is more than a simple machine. Changing μ is outside the scope of a classic simple machine. It reduces the need for a force, it does not change any force.

A wheel and axle can be used to lift something (or press the bullet into the casing). If you attach a cam to the axle, you can convert a small (rotational) force applied over a longish distance to a much larger force applied over a shorter distance to press the bullet into the casing. And if you attach a rope to the axle, you can winch up the water bucket.

I think that the way you are defining the problem, you are prelimiting yourself to scenarios which require a longitudinal force. That's not how the wheel and axle works. It transforms rotational forces. By the way, this is not "my" definition of a simple machine. That's the standard definition used in classical mechanics texts. Rossami (talk) 15:02, 2 November 2007 (UTC)[reply]

All the above info about 'wheel and axle' is irrelevant. We are discussing a wheel, and the example we are using is a wheel on a wagon which. You stated it was a machine because it transforms forces.

When I say 'your definition' that means the definition that you are using in your argument, it does not mean you invented it, and it does not imply that I either agree or disagreee with it.

So please, give me a definition of a simple machine and show how a wheel with a frictionless bearing meets that definition. Or better still, having had plenty of time now to think it through, agree that a wheel is not a machine.Jimbowley 17:25, 3 November 2007 (UTC)[reply]

I am curious about why the vector mechanics devices are often ignored. True, the topic of simple machines is usually restricted to undergraduate and even elementary science courses, however the bowstring (in an archer's bow) is both ancient and basic.

Further, an number of (web)sites and articles confuse mechanical efficiency (work out/work in [which should be 1.00 for an ideal machine]) with mechanical advantage, i.e. force out/force in.

142.163.53.194 (talk) 18:25, 11 December 2007 (UTC)(peter)[reply]

See the discussion on springs above. A bowstring stores and then releases energy but does not convert the force applied. Rossami (talk) 21:37, 11 December 2007 (UTC)[reply]

I should be more specific. The BOW itself (a cantilever spring)stores the energy, the bowstring [a taut cord] bends the bow and stores very little energy itself. When the deflection is minimal a small horzontal force requires large vertical forces in the string to maintain equilibrium.

The crankshaft mechanism at TDC (and BDC) of a crank and slider(piston) assembly exhibits a similar nonlinear mechanical advantage.

With respect to the section on springs:
The helical spring is primarily an energy storage device..... however each coil displays a lever mechanism. A spring with a few coils with a large spring constant is difficult to deflect, however increasing the number of identical coils lowers the spring constant allowing a a greater deflection for the same force. True, it maybe a "stretch"(sorry!) but in that sense it displays the attributes of multple simple machines.

One additional note on simple machines that is also often overlooked is that of the block and tackle. Pulleys are not necessary for mechanical advantage to be achieved - only rings or bars with a low coefficient of friction between the rings and rope. The mechanical advantage is achieved by the number of passes of a constant tension cable.

142.163.53.194 (talk) 22:48, 11 December 2007 (UTC)Peter[reply]

You are right. But in the bow application it is just part of a process which may explain why it was not considered worthy. I am currently trying to think of an example where the principle is used to lift something or do some other work as an end result! Jimbowley (talk) 14:05, 12 December 2007 (UTC)[reply]

You make a good point - the bowstring mechanical advantage is only part of the mechanism.

If still curious, though, there is a technique used to tighten rigging on ships - mostly tall ships now. The rope in a block and tackle assembly is wrapped around a pin or rail to maintain tension. Then one crew member pulls on one of the pulley ropes as one would with an archer's bow. The blocks are pulled together easier than pulling directly (axially) on the rope. As the rigger releases the bowed cable the other riggers pull in the slack.

Modern riggers now use a gear winch with a rachet mechanism to trim large sails.

A rare application now, but if one scans tall ship videos one is bound to see the technique.

Still, the bow string better displays ( I think) the vector technique than does the variations of the inclined plane.

The application of this technique in compression(as opposed to tension in the bow string) is common in crank and slider designs in manufacting processes such as stamping and pressing.142.163.53.194 (talk) 20:04, 12 December 2007 (UTC)Peter[reply]

What you describe I would call a general rigging technique, but there isn't a machine there. For some reason this got me wondering how many people go through life without ever using ropes and knots. Jimbowley (talk) 11:03, 13 December 2007 (UTC)[reply]

This tall ship video almost shows this technique: Youtube Video on Barque James Craig added Feb3/07 by "betobatres" 6:56min see frames between 1:40 and 2:00 minutes. [16]Pete318 (talk) 18:30, 10 April 2008 (UTC)[reply]

There current discussions about salvaging of the Costa Cocordia often mentions the concept of "parbuckling". The mechanical advantage of traditional parbuckling is discussed in the Wiki article "Parbuckle Salvage" [17].

However in the more generic sense of the term there is a technique used by sailors to pull a vessel into dock against a strong wind. From this source[18] it appears that the mechanical advantage of the Bow String (vector mechanics) that I have noted - is used. ("Bow" as in "bow and arrow" not to be confused with "bow" as the front of a boat.)

“…..If ever you find yourself with a heavy boat tied to a dock or wall, blowing off so that no amount of heaving will bring her in, you can always use the simple principle of parbuckling on your docklines. Dig out a stout rope of reasonable length. Make one end fast to the dock, somewhere between your two docklines. Now pass it around a bight in your bow line, bringing the working part back to where the bitter end is secured, and haul away. The bow line will take on a V-shape, and your boat will march in toward the dock in defiance of all the natural forces acting upon her. Once she’s alongside, you can either rig another bow line to replace the one you’ve parbuckled, or you can smartly release your parbuckling line and have the crew snatch in the slack on the existing bow line. …”

Pete318 (talk) 19:16, 17 September 2013 (UTC)[reply]

Yes Simratk. (talk) 09:41, 6 January 2024 (UTC)[reply]

Could we consider adding the Gear as an item under the variations list? I have found several sources (including wikipeida's own article on gear) that define it aas a simple machine.--Cpkondas (talk) 19:44, 29 January 2008 (UTC)[reply]

Wikipedia's article is, ironically, not a reliable source for the verification of other Wikipedia content. You could add it to the variations list if you have other reliable sources. I only found a single reference (in the list above that mentioned the gear as a simple machine. That one reference didn't seem strong enough to me. Rossami (talk) 23:59, 30 January 2008 (UTC)[reply]

Here is one external source: http://www.mos.org/sln/Leonardo/InventorsToolbox.html Do you need a definite number to add to the variations list? --Cpkondas (talk) 18:07, 31 January 2008 (UTC)[reply]

There's no magic number. It's a qualitative assessment made by the consensus of editors who choose to discuss it here.
Your source is the same Boston Museum of Science reference we found above. It doesn't really call a gear a simple machine. It lists gears in the section titled "Other Elements of Machines", a heading at the same level as the section titled "Simple Machines". (I must also admit that my confidence in that reference is reduced by their unexplained omission of the inclined plane from the list of simple machines.) Rossami (talk) 23:20, 31 January 2008 (UTC)[reply]

I agree. A gear is a special application of a simple machine such as a wheel. In fact, it's simply a wheel that needs a lot of "friction", the way a tire on your car needs some friction against the road. Look at a Gear#Rack_and_pinion, which is clearly a gear. Now squint and pretend the pinion is smooth instead of toothed, like the rubber roller that feeds paper through a printer. Pretend the rack is also smooth (like the paper). Is there any difference in the mechanical action of a rack-and-pinion vs a rubber roller and paper? Each is converting rotational force into lateral force. Depending on the magnitude of the torque and the material you need to move, you simply vary the surface of the pinion, perhaps smooth like rubber, or as rough as sandpaper, or even so rough that it's toothed to match a toothed rack. A worm gear is a special application of the inclined plane. Seems like it's a helically shaped inclined plane that transfers rotational movement to longitudinal (not lateral) movement. Petershank (talk) 23:45, 4 January 2011 (UTC)[reply]

I think that any machine that is simple could be called a "simple machine" but that only the 6 (or 4,5,7 ect) "simple machines" discussed on this page falls under the category of "Simple Machine" (notice caps). This way we indicate that we a talking about the result of classical mechanical reductionism and not just of any machine that is simple. Jesper Jurcenoks (talk) 23:42, 1 April 2008 (UTC)[reply]

summary of previous discussion: Rolamite is a bearing, not a machine.

Does anyone know exactly what a simple machine is [?] Richard Binder • Pens That Write Right! 23:54, 7 January 2007 (UTC)

This article needs a good simple non-ambiguous definition of a Simple Machine. So that anybody can take a given machine and see if it falls under the definition of a Simple Machine. Definitions like : a Simple Machine is one of the following X machines - Lever, Pulley, ...." will not do, as the definition needs to shows why these X machines are Simple Machines, not just be an arbitrary selection.

I propose the following definition of a Simple Machine :

For a given machine to be a Simple Machine the following must be proved to be true :

a) requires a single force to work (no stored energy see discussion on springs)

b) performs force transformation (change direction, multiply/reduce force/speed)

c) is not a compound machine (cannot be broken down into simpler Simple Machines)

d) is not a variation on an existing Simple Machine

e) no overzealous application of d) is used (similar to making the 6 Simple Machines into only 2 - see main article).

Jesper Jurcenoks (talk) 04:06, 2 April 2008 (UTC)[reply]

While certainly a reasonable definition, it is not one that I have ever seen written down anywhere else. It would therefore seem to fall afoul of WP:NOR. Can you cite that definition in some other reliable source? Rossami (talk) 04:24, 2 April 2008 (UTC)[reply]

The Proposed definition is a sumary of the most common definitions of Simple Machines found on the web. Definitions of the type : "a Simple Machine is one of the following X machines - Lever, Wedge ..." are excluded from participating in this definition discussion as they only lists Classical Simple Machines from a certain standpoint but does not define why they are on the list.

A proposed definition of a Simple Machine must be able to pass the following test :
Can it be applied to the current list of Simple Machines and correctly identify them according to the new definition.

Requires a single force to work
Some definitions include the "Require a single force to work" in one form or another including this article and the following links : [19], [20] [21] [22] [23] [24]

Performs force transformation
You will see the force transformation in one of many variations in most definitions of a Simple Machine :
Including : It is to move an object from one position to another position. [25]
Makes work Easier [26] [27],[28], [29],
A Simple Machine is a device for increasing forces or changing the direction of a force [30] [31] [32] [33]

Is not a Compound Machine
Since the definition of a Compound Machine is that it is made from 2 or more Simple Machines [34], [35], [36], [37] It goes that any Machine that can be broken down into simpler machines is therefore not a Simple Machine but a Compound Machine. Typical wordings for this require includes : "any of various elementary devices considered as the elements of which all machines are composed" [38] "All Machines are build from one or more simple machines" [39]

It is not a variation of an existing simple machine

The list of Simple Machines are not all the simple machines in the world, but the base form of the simple machines that surround us. Example the "baseball bat" is a 3rd class lever, it is therefore a simple machine in itself, but it is not listed among the classical list of Simple Machines as it is listed under its base form: the lever. The knife is a wedge and the bolt is a screw, a Crowbar is a lever etc.

no overzealous application of d) is used

Simple machines fall into families : currently there are two known families : the Inclined plane family (inclined plane, screw and wedge) and the lever family (lever, pulley, wheel & axle). Most Scholars refers to the families but keep the six machines distinct. Some people place gears as a separate simple machine [40], [41] while other claim that gears are just wheels with teeth.[42]

The last requirement is the hardest to quantify, until somebody can describe a method to measure the distance from knife to wedge, from gear to wheel from wedge to inclined plane and from wheel to lever, we will have to make it a judgment call. Current consensus seems to favor :
That the distance from knife to wedge, from seasaw to lever from bolt to screw is "small" and that they therefore are variations of a base Simple Machine.
That the distance from from wedge to inclined plane, and from gear to wheel is "medium" and therefore could fall into either "Variance of base simple machine" or "distinct simple machine"
That the distance from pulley to lever, from wheel to lever, and from screw to the inclined plane is "large" and therefore these are distinct Simple Machines.
That the distance from pulley to lever is shorter than the distance from pulley to inclined plane, and therefore the pulley belongs to the lever family.
That the distance from inclined plane to lever is "Great" and therefore these are separate families.

Other definitions
It is made of 1 or 2 pieces [[43]] [44]

On 25 April 2008, Beland added the {{reqdiagram}} tag at the top of this Talk page. First, I despise those templates. They permanently "tag" a talk page and confuse future editors long after the problem has been addressed. Second, I'm not sure that diagrams are appropriate on this page. This article discusses the aggregate concept of a "simple machine" and prominently links each of the simple machines. Those drill-down pages are very well diagramed. I don't know what picture you could put here that would benefit readers without merely cloning in content that's already better discussed elsewhere. Rossami (talk) 16:15, 27 April 2008 (UTC)[reply]

I agree with Rossami, no need for pictures here Jesper Jurcenoks (talk) 13:11, 11 May 2008 (UTC)[reply]

I generally agreed that there should be no pictures, but then I found a chart of simple machines from a 16th century encyclopedia. It seemed to illustrate the topic so well that I put it in the article. Hope nobody minds too much. --Chetvorno^TALK 12:17, 26 June 2008 (UTC)[reply]

In my opinion, the wedge has two distinct purposes, one as an inclined plane and one as a hydraulic. A wedge stuck into a door acts as an inclined plane, turning a horizontal force into a vertical force. An ax, however, is also considered a wedge. When it first strikes a perpendicular surface, it does not rotate any force to other directions. What it does is, like a hydraulic, trade distance for pressure. Consider a piece of wood with a wedge on top of it pointed down, and a cubic weight on top of the wedge. Without the wedge, the weight resting on the wood would apply a pressure equal to its weight divided by the area of one side. With the wedge in place, the weight provides a pressure equal to its weight divided by the very small area of the pointed edge of the wedge. This "concentration of force," if you will, is the entire principle behind blades, which one could consider a form of wedge. But the simple machine most associated with such a concentration is the hydraulic, not the wedge.24.90.235.104 (talk) 14:23, 9 July 2008 (UTC)[reply]

Not to be impolite, but your opinion is wanting of erudition. Although an ax may be shaped like a wedge, in proper use it does not behave like a wedge, which "operates by converting a force applied to the wide end into forces perpendicular to the inclined surfaces". (Wikipedia, Wedge.)

Furthermore, "concentration of force" is not the "entire principle behind blades". The ability of axes, knives and other blades to "cut" lies in the heat generated by friction at the interface of the blade's edge and the surface being cut. The narrower (sharper) the blade's edge the more that heat is concentrated, resulting in a higher local temperature at the interface. Sufficient heat can be generated by applying a relatively large force to the blade, or by applying a relatively small force while moving the blade longitudinally. An ax blade is used in former manner.

Cheers!, Rico402 (talk) 14:06, 9 November 2008 (UTC)[reply]

what's the etiquette? certain things on here are unlikely to rear their ugly heads again eg the mnemonic. Human fulcrum needs to go. Rolamite disussions should all go. I will start to delete, you can always put it back if you feel it adds anything. I'd also like to edit my 'wheel is not a machine' section back to the basic argument and remove most of the debate with Rossami. PS. Glad to see the article in much better shape than last time I visited. —Preceding unsigned comment added by Jimbowley (talk • contribs) 22:07, 2 January 2009 (UTC)[reply]

This article says that there are six simple machines, but there really are only three. A pulley is just a wheel with a rope through it, a wedge is just two inclined planes placed back-to-back, and a screw is just an inclined plane wrapped around a nail. —Preceding unsigned comment added by 71.167.228.99 (talk) 02:30, 4 March 2009 (UTC)[reply]

The blade focuses energy on a smaller point, thus manipulating and allowing it to conform to the definition of simple machine. Some would argue that the blade is a variant on the wedge. This is not true as one could remove the point of the wedge and have it remain just as potent as before while removing the edge of a blade would dramatically reduce it's ability to convert energy. The edge is inherent to the blade, not to the wedge. Demagoguery (talk) 23:02, 25 March 2009 (UTC)[reply]

Some would argue... - who? WP:RS please. Vsmith (talk) 02:39, 26 March 2009 (UTC)[reply]

This debate is interesting, but the topic is already being discussed under the heading 'About the Wedge' above. Maybe we should move these entries up to that heading. --Chetvorno^TALK 05:09, 26 March 2009 (UTC)[reply]

24.90.235.104 "argues" it above under "About the Wedge". Rico402 (talk) 09:43, 27 March 2009 (UTC)[reply]

There are some good observations made in this section as well as the referred item "About The Wedge". If the concentration of stress by a sharpened wedge point plays a role in the failure of the "cut" materials one would have to include the Awl (tapered point as opposed to tapered edge) as a similar mechanism.

In fact the "blade" concept is a little ambigious since the mechanics of the failure of the target material are varied. For example does a fibrous material break by concentrated shear stress or is there a wedging action (inclined plane) forcing the fibres to break in tension or is the fibre actually crushed (by a blunter "blade") or a combination of all three?

High speed blades, cutting grass or other natural fibres, actually may involve crude collisions with the fibre, in effect smashing the target, although the taper of the blade increases the efficiency.

Further the blade metaphor is also clouded by the fact that the motion is not always solely vertical but there is tranverse or horozontal motion as well. "Sharp" blades are not always defined by a smooth fine point but rather by many fine serrations where the cutting motion is important.

Perhaps somewhere in primitive cultures, hunters and craftsmen quickly realized that sharpening the edges and points of their tools and projectiles greatly improved the performance. They probably appreciated this concept long before rolling a wheel around(?). In that context, perhaps this topic warrants a little more consideration.

Pete318 (talk) 19:05, 27 March 2009 (UTC)[reply]

A postscript to the last comment: The sharpened edge of a wedge or a blade or the sharpened point of an awl multiplies pressure not force. If a machine is defined a device that multiplies force then the blade is a different mechanism. The same way a spring can multiply power - it is a mechanism but is it a simple machine?

The analogy with an hydraulic mechanism is misleading. An hydraulic device uses the same pressure to multiply force, but the blade uses the same force to multiply pressure. Thus the question is if an hydraulic system is a "simple" machine, that is, is it basic enough?

Pete318 (talk) 18:41, 30 March 2009 (UTC)[reply]

Basic enough? I think that is not an 'enough' rigorous point. The real question In My Humble Opinion should be, "can it be represented by other simple machines"? That is, if it (hydraulics) transforms one mechanical energy mode into another and no (other) simple machine can replace it, add it to the list. Perhaps it wasn't known at the time of the original list. Though if one includes machines made in the digital age, like the transistor, the list may grow unwieldy. But then you've nearly reduced it to two machines!24.146.226.25 (talk) 21:46, 29 June 2011 (UTC)LeucineZipper[reply]

Elementary school teachers like the concept of simple machines because it appears to move their students toward knowledge of technology and even engineering. There are many web-pages that illustrate simple machines and analyze their operation as applications of physics and mathematics. Unfortunately, the engineering is wrong and sometimes the physics as well. In the 1800's the classification of machines along the lines of Aristotle became increasingly complex as more machines were designed. The individual who most diligently pursued this effort was Franz Reuleaux. His collection of 800 machine elements can be found at Cornell's KMODDL site. It is, perhaps, no surprise that it was Franz Reuleaux, who identified a more fundamental approach to describing machines that informs designers to this day. This approach, which is over one hundred years old, has nothing to do with the statement: "A simple machine is a device that transforms the direction or magnitude of a force." Prof McCarthy (talk) 05:04, 29 November 2011 (UTC)[reply]

Pillars that support a highway overpass transform the magnitude and direction of bridge and highway loads. Similarly, a dam that holds back water transforms the magnitude and direction of hydraulic forces. I do not believe anyone would classify these devices as simple machines. The concept of set of simple machines from which other machines are constructed is a Renaissance interpretation of Greek texts on technology. This viewpoint lasted until the late 1800's, at which time the number of simple machines was found to be many hundreds, including the various devices in the figure that is part of this article. This article on simple machines should be written as a historical piece that provides insight to an elementary mechanical movement. But it should be recognized that this approach has been abandoned for a long time as a useful tool for machine analysis and design. Prof McCarthy (talk) 05:37, 29 November 2011 (UTC)[reply]

I respect your expertise in this field. As a professor of mechanical engineering at a major university, If you say the concept of "simple machine" is outdated, I am inclined to believe you. However, your changes to the article require the citation of reliable sources. Secondly, as you mention above, the concept of "simple machines" is still widely taught. And not just in elementary school; the references in this article show it appears in secondary school and college texts, and is knowlege required on standardized tests. Thirdly, even if this approach has been abandoned in machine design, in everyday usage the term "simple machine" has a specific meaning, which is the traditional concept of a force scaler or amplifier linkage. I think this is the primary definition and must appear in the article's lead paragraph.

If the engineering or physics in this article is wrong, it should certainly be corrected, with sources. If machines are no longer analyzed as combinations of simple machines, I would support a properly sourced section saying so. However, I feel the major changes you made to the article misrepresent the term, so I am reverting them. --Chetvorno^TALK 21:21, 29 November 2011 (UTC)[reply]

I did my best to preserve the basic ideas of simple machines and present the fundamentals correctly. If you disagree then fine, I will leave it alone. Prof McCarthy (talk) 21:29, 29 November 2011 (UTC)[reply]

Well, our colleague Chetvorno in a desire to keep the unusual definition that "simple machine is a device that transforms the direction or magnitude of a force," has reverted all of my edits with little attention to their individual value. I have to say that his statement that a " 'simple machine' has a specific meaning, which is the traditional concept of a force scaler or amplifier linkage" captures the essence of mechanical advantage, but does not represent a transformation of the direction and magnitude of a force. All things change the direction and magnitude of a force in some way. I am willing to let him have his way with this topic, I have had this experience before. However, I do have one regret, that the listing of simple machines stops with those identified in the Renaissance and does not include those recited in the later years of the Industrial Revolution, for example the listing of 60 or more simple machines shown in the figure attached to this article or the more than 800 simple machines identified by Franz Reuleaux. Prof McCarthy (talk) 22:34, 29 November 2011 (UTC)[reply]

The list of simple machines discussed in this article is known to have been identified by the time of the Renaissance. During the Industrial Revolution that followed many additional simple machines were identified. I assume gears may be considered examples of the wheel and axle, however their engagement to provide power transmission is not among the simple machines of the Renaissance. More importantly, the discovery of the involute tooth which makes standardization and commercialization practical is of fundamental importance. I would propose that cam mechanisms, the geneva wheel, escapements, the universal joint, and the flyball governor are all examples of simple machines that were discovered after the Renaissance and deserve consideration as fundamental components used to make more complex machines. Some would consider Watt's linkage to be of such importance that it qualifies it as having the significance of a wheel and axle, because it is considered to have made the steam engine practical. Why is it off-limits in this article to simply mention that after the Renaissance other simple machines were identified? Prof McCarthy (talk) 06:22, 1 December 2011 (UTC)[reply]

I am trying to get Chevorno to address whether it is enough to leave the sentence "a simple machine transforms the magnitude and direction of a force" in the lead. This would allow my to reinstate the other 24 or so edits. His mass elimination of these edits seemed an ill-considered action to maintain this one sentence, which I had simply moved to a later section. I have asked on his talk page if I may interpret his silence as approval. Prof McCarthy (talk) 01:37, 2 December 2011 (UTC)[reply]

I have not heard from anyone, so I assume that if I leave the sentence "a simple machine transforms the magnitude or direction of a force" alone, though most everything does this, and work on the remaining parts of this article, I will not have my edits completely reverted. At least I hope this is the case. Prof McCarthy (talk) 18:20, 3 December 2011 (UTC)[reply]

This article describes a compound machine as a series of simple machines and computes the mechanical advantage of a compound machine as the product of the mechanical advantage of simple machines. This was obtained from the reference: ^[1]

It is important to recognize that this is a special case that is useful for introducing elementary school students to the idea of mechanical advantage, and not a description of machines in general. Prof McCarthy (talk) 19:22, 3 December 2011 (UTC)[reply]

The section Simple machine#Alternate definitions exposes the error in a focus on "the transformation of the magnitude or direction of a force." This is a useful simplification if the only concern is the six classical simple machines. But there are many other machine components that transform the magnitude and direction of forces. In fact a close look at most devices shows that they transform forces in some way---please see my examples of pillars and a dam above. The critical concept in understanding classical simple machines that has an important modern form is mechanical advantage. From this point of view, hydraulic systems are clearly simple machines, though not one of the classical cases. The expansion of the list of simple machines in the late 1800's is what lead to a revision of the basic view of the analysis of machines that has now been in place for over one hundred years. Prof McCarthy (talk) 19:36, 3 December 2011 (UTC)[reply]

I have looked into the references in this section and found that they are not very substantial. I would like to replace them with a very old physics text that addresses these issues nicely. It is Robert Hunt, (1851), Elementary Physics: and introduction to the study of natural philosophy, Reeve and Benham, London. Prof McCarthy (talk) 07:16, 6 December 2011 (UTC)[reply]

I am trying to figure out how to fix the section on alternate definitions. I have checked the references and found them to be elementary school notes or summaries that are equivalent to these notes. So the alternate definitions seems to be what various writers have proposed to help their students understand simple machines. It is correct that a wedge, screw and inclined plane have the same basic physics. A lever, wheel and axle, and pulley also have the same basic physics. This does not change the fact that the Renaissance scientists identified these devices as simple machines. I do not think this section is very helpful to the reader. There is no controversy about what was considered to be a simple machine in the 1500's. Prof McCarthy (talk) 07:30, 6 December 2011 (UTC)[reply]

I renamed the section "Frictionless analysis" to be "Mechanical advantage," because this is what is discussed in this section. The derivation of mechanical advantage based on work is the standard approach used in the various notes for elementary schools. However, this is better done using power, because mechanical advantage depends on the configuration of the machine, and is actually an instantaneous property like velocity. In contrast, work is path dependent and is best used for simple cases, such as falling weights, unless the displacement is held to be very small, in which case it becomes a velocity analysis. Prof McCarthy (talk) 16:24, 6 December 2011 (UTC)[reply]

The section on "Self-locking machines" is based on the reference Gujral, I.S. (2005). Engineering Mechanics. Firewall Media. pp. 382. ISBN 8170086361. It seems to say that if the efficiency is poor enough, the machine will be self-locking. I guess this is a way of saying there is good in a poorly performing machine. Prof McCarthy (talk) 05:07, 7 December 2011 (UTC)[reply]

The analysis of self-locking due to friction does not seem to be appropriate for this article on simple machines for a number of reasons. Perhaps the most important is that it is overly simplified to the point of being incorrect in the cases where it matters the most, the inclined plane. Self-locking due to friction is a characteristic of the analysis of an inclined plane and includes the wedge and power screw. The mechanical advantage of a frictionless inclined plane is 1/tanφ where φ is the angle of the inclined plane. In the presence of friction, let the angle of the plane where friction forces balance be α, then the mechanical advantage is 1/tan(α+φ), when raising a load. The system is self-locking if α≥φ. Clearly the inclined plane with friction has the efficiency η=tanφ/tan(α+φ). If the friction angle is exactly α≡φ, and φ<10degrees, then η≈φ/2φ = 1/2. This analysis changes in the case of lowering the load. This is a much more subtle analysis than simply adding work due to the load and work due to friction, and probably should be reserved for the articles on inclined planes. Prof McCarthy (talk) 18:00, 7 December 2011 (UTC)[reply]

I propose deleting the section on self-locking from this article and introducing the appropriate derivations in the articles on the inclined plane, wedge (mechanical device), and screw (simple machine). Prof McCarthy (talk) 17:54, 7 December 2011 (UTC)[reply]

The application of friction is essential in mechanical devices such as fastners - helical bolts and screws - by preventing the helix turning and releasing the axial preload on the machine part. It is a stretch (no pun) but if a rod was clamped with a wedge to prevent the rod from moving it would be useless without friction. However this application of friction is not an ACTIVE machine element. It does not multiply force, but rather increases the PASSIVE resistance to force on a bona fide simple machine.

That is the best defense that I can think of just now.

Pete318 (talk) 18:57, 24 January 2012 (UTC)[reply]

Pete318, you are correct fasteners use internal forces and even mechanical advantage to maintain a structure. Other examples are toggle clamps and door stops. I believe you are right because the Renaissance notion of a simple machine is a device that moves loads, not one that makes a structure rigid. Thank you. Prof McCarthy (talk) 00:48, 25 January 2012 (UTC)[reply]

Apparently, there is not enough about the Pyramids and the Great Wall in other articles in Wikipedia, they must be discussed in this article as well. It is true that Usher attributes a misreading of a Greek text on moving heavy loads as the source of the concept of Simple machines. However, is it necessary to list all ancient monuments that have benefited from this construction technology? I suppose we could include Stonehenge, the Mayan Temples, as well as the temples of the Acropolis. Then there are mythical structures like the Tower of Babel, the Colossus of Rhodes and maybe the lost city of Atlantis. Prof McCarthy (talk) 07:37, 17 February 2012 (UTC)[reply]

I really also wasn't done with the section. I just decided to add the section because it really is important to the history of the simple machine. Algamicagrat (talk) 15:02, 17 February 2012 (UTC)[reply]

It would help me to know what part of the following description of the history of the Great Wall is important to the history of the simple machine:

The Great Wall of China is the longest man made structure ever built in the history of mankind, with its present length of 8,851.8 km or 5,500.3 miles stretching into several provinces of China such as Liaoning, Hebei, Tianjin, Beijing, Shanxi, Inner Mongolia, Shaanxi, Gansu, and Qinghai. However, the Great Wall of China is a noncontinuous series of walls in different places, especially during the period of its initial construction. It was primarily built by several states during the Warring State Period in China to prevent attacks from other neighboring states. Later on, when the states vanished, leaving the Qin State in a unified China, Emperor Qin Shi Huang ordered the connection of the series of walls and termed it as “10,000 li Long Wall.” It was connected to prevent further attacks, that time from the northern nomadic tribes. Later on, the last reconstruction of the Great Wall undertook during the Ming Dynasty after change of several dynasties. The Ming Dynasty purposely reconstructed the wall to strengthen its defense further from the Mongol in the northern part of the country.

Prof McCarthy (talk) 15:39, 17 February 2012 (UTC)[reply]

Good Point...Algamicagrat (talk) 23:55, 17 February 2012 (UTC)[reply]

Recent edits by our colleague 3/4-10 appear to assert an equivalence between machine elements and simple machines. At least this is the way I interpret the following taken from the lede to this article:

Various authors have compiled lists of simple machines and machine elements, sometimes lumping them together under a single term such as "simple machines",^[1] "basic machines",^[2] "compound machines",^[3] or "machine elements"; the use of the term "simple machines" in this broader sense is a departure from the neoclassical sense of the six essential simple machines, which is why many authors prefer to avoid its use, preferring the other terms (such as "machine element")

I believe is it appropriate to consider the phrase simple machine as referring either to a machine that is simple or to one of the set of six simple machines identified by Renaissance scientists. However, machine element is a modern concept that should be separated from what is actually an odd concept that machines are constructed from combinations of six devices identified by Renaissance scientists. As Usher notes this was a misunderstanding of a text on devices used to move heavy loads. It was not the result of a scientific study of the decomposition of mechanical movement. In contrast, Reuleaux did perform such a study of mechanical movement and constructed models of 800 different devices that can be considered machines that are simple. As a result, Reuleaux identified the rotary, linear and direct contact joints, which he described a lower pairs and higher pairs, as the elemental components of mechanical movement. These are the predecessors to what are now known as machine elements, and the list has expanded to other important mechanical components. However, blending the terms simple machines and machine elements is to blur the important distinction between a failed tradition and its modern successful approach. Prof McCarthy (talk) 06:58, 13 March 2012 (UTC)[reply]

The concept I was trying to cover is that one word sense of the term "simple machines" is only the 6 fundamental classical/neoclassical ones, whereas another word sense of the term treats it more like "machine elements" (for example, at least 2 of the cited refs use it in that sense). I personally would rather see people confine the term to the first sense mentioned, because it better allows for precise-while-brief (that is, succinct) communication. What I saw in the earlier version was the remnants of various editors coming here and disputing the definition of the term—the answer to that is to have the article explain that both word senses exist, even if one is not preferred. If anyone wants to work on refining the coverage so it's clearer, that's fine. — ¾-10 00:58, 15 March 2012 (UTC)[reply]

I appreciate your thoughts on this. I have had many run-ins with editors who insist this article must limit the notion of simple machines to the Renaissance view because of the many elementary school web-sites that use this as an introduction to technology. I believe it makes sense to broaden the term to at least include the many simple machines that are represented by Reuleaux's models as well as other listings such as the figure in the lede. While I do think there is a technical concern with blending this definition with machine elements, I could be persuaded that if elementary school teachers viewed axles, bearings, screws, gears and other machine elements as simple machines this could actually be a good thing for elementary school engineering, in particular, and machine theory in general.Prof McCarthy (talk) 01:18, 15 March 2012 (UTC)[reply]

I agree with the Prof that this article should discuss the Renaissance list as a historical item (which has been the previous consensus) and also that adding eg Reuleaux's work is appropriate. I also agree that we don't want to mix machine elements with simple machines Jimbowley (talk) 16:37, 10 July 2012 (UTC)[reply]

I think to improve this page we should include a comparision between simple machines and compound machines. I do not know how to explain it right so if you know how could you please edit it because I would just like to help this wikipedia page better. Thanks for your time.

~Lily Clarissa Smithers~ — Preceding unsigned comment added by 184.56.82.19 (talk) 17:54, 25 March 2012 (UTC)[reply]

The article contains a section on compound machines that explains that a compound machine is made up of several simple machines connected in series. What would you like to see added? --Chetvorno^TALK 01:31, 26 March 2012 (UTC)[reply]

I think the question that arises in the consideration of simple machines is how do we get from simple machines to more complex machines. While it would seem that a start might be attaching simple machines in series, this turns out not to be correct. The correct strategy was identified by Franz Reuleaux, and by many elementary school teachers, who realize that a lever, pulley and wheel and axle are basically the same device, a body rotating about a hinge, and that an inclined plane, wedge and screw are similarly a block sliding on a flat surface.

With this realization it becomes clear that there are fundamental joints, or connections between moving bodies, and that machines are constructed from these joints in standardized ways. Starting with four types of joints, the rotary joint, sliding joint, cam joint and gear joint, and related connections such as cables and belts, it is possible to understand a machine as an assembly of solid parts that connect these joints.

From this point of view we build machines as follows, a power source drives a rotational or linear movement, which is then transformed into another movement by a mechanism. Mechanisms start out as a frame, a hinge and one bar or crank to form a lever, door, wheel, door knob, and on and on. They become increasingly complicated by combining a frame and two cranks connected by one floating bar to form a four-bar linkage which is the input-output mechanism in door-openers, trashcan lids, door and hood lift mechanisms and many more. A variation of this uses a lever or crank connected by a floating bar to a slider which is the heart of an internal combustion engine, and devices such as clamps, slicers and more. And the process continues with the addition of gear trains, and cam and follower mechanisms.

The key insight is that there are, in fact, primitive mechanisms that form all machines. Its just that these primitive mechanisms, unfortunately, are not the six simple machines identified by Renaissance scientists. Prof McCarthy (talk) 04:04, 26 March 2012 (UTC)[reply]

Very good food for thought. I for one would like to see this article contain a section called "alternative classification schemes" (or something along those lines) that basically says what Prof McCarthy said above. — ¾-10 00:38, 27 March 2012 (UTC)[reply]

The section as written is not incorrect. If you define a compound machine as a series of simple machines, then the equations etc are correct. The section does not state that all complex machines are compound machines. I have not come to an opinion on whether the section is useful for the article yet. Jimbowley (talk) 17:03, 10 July 2012 (UTC)[reply]

I'd like to see a clearer separation between the classical Renaissance theory of simple machines and the different modern concept based on kinematic chains added by Prof McCarthy. In the classical theory, still taught in physics classes, there are only 6 simple machines and "compound machines" consist of series of simple machines. In the modern theory by Franz Reuleaux and others, there are hundreds of "simple machines". Both theories are important, but in its present condition the article doesn't cleanly distinguish between them. This will confuse nontechnical readers. I think the two theories should have separate sections. Perhaps the main body of the article can be devoted to the classical theory, which is what most readers want when they look up "simple machine", and a separate section at the end can explain "kinematic chains". --Chetvorno^TALK 19:54, 10 July 2012 (UTC)[reply]

Chetvorno, this is the spirit in which the section on kinematic chains was added. Prof McCarthy (talk) 02:21, 11 July 2012 (UTC)[reply]

It looks good as far as it goes, but the last paragraph of the introduction doesn't emphasize enough that it refers to a modern departure from the classical concepts. Also, it needs to be clearer that the last two sections, "Kinematic chains" and "Classification of machines" are separate from the preceding sections which refer to classical machines. Couldn't they be grouped under a section titled "Modern machine theory" or something like that? --Chetvorno^TALK 21:00, 11 July 2012 (UTC)[reply]

My initial reaction is that this gives the modern theory more prominence than perhaps is necessary in this article on simple machines, but it may be a good idea. Prof McCarthy (talk) 22:15, 11 July 2012 (UTC)[reply]

I've only just noticed that the '2 classes' paragraph is wrong.

A pulley is not characterized by the equilibrium of torques and movement around a pivot. Pulleys are about vector resolution of forces, there are no torques involved. And the movement is linear not around a pivot.

The screw is not characterized by the vector resolution of forces and movement along a line. The input is a torque.

This all goes back to 2008 when there was a lot of discussion about what this page was about. I seem to remember that the agreement was that the 'list of 6' was at least a recognised historic list. Somehow the unreferenced '2 classes' seems to have slipped through and gone unchallenged since (unless I missed the challenge, if so, sorry).

Jimbowley (talk) 12:08, 4 May 2012 (UTC)[reply]

I beleive that there should only be two Simple Machines: an Inclined Plane and a Lever, in actual fact an inclined plane could be contrued to be a Lever. — Preceding unsigned comment added by 184.71.58.110 (talk) 20:56, 4 March 2014 (UTC)[reply]

Modern machine theory would describe these simple machines in terms of the joints that allow movement of their component parts. The wedge and inclined plane are defined by linear sliding joints and the wheel, pulley and lever are defined by rotary joints. The screw is a combination of the two. Generally, an inclined plane is not construed as a lever. However, theoreticians do consider the linear sliding joint to be equivalent to the rotation of a long lever about a fulcrum at infinity. Prof McCarthy (talk) 13:02, 5 March 2014 (UTC)[reply]

He's not talking about the kinematic chain concept, but the traditional Renaissance model. Some sources regard some of the six classic machines as special cases of others. There used to be a paragraph on that in this article. --Chetvorno^TALK 15:16, 5 March 2014 (UTC)[reply]

Maybe consider mentioning that the mechanical advantage of (force) vector addition has often been ignored. In the context of this section it would provide, not new material, but rather an observation on current encylopedic knowledge of the subject. The most common example might be the compression of a gas or pumping of a liquid by a Crank and Connecting Rod/Piston assembly. Less common would be parbuckling of mooring lines.

Would some text in that context be eligible for an entery on the Article Page?

Pete318 (talk) 22:21, 20 May 2014 (UTC)[reply]

I'm not exactly sure what you mean. The two examples you give are not simple machines. However the hydraulic press, which amplifies force with two different sized pistons, has mechanical advantage, and has often been suggested as an addition to the 6 classical simple machines. Is that what you were referring to? Again, the article mentioned that before someone eviscerated it. --Chetvorno^TALK 23:18, 20 May 2014 (UTC)[reply]

hmmmm... I suppose the crank/connecting rod/piston is a complex machine - I see your point(?). However a single piece of rope or string can generate a significant mechanical advantage. The simplest example is probably how a bow string bends the bow (as in bow and arrow). The Bow itself may be a complex device, but the bowstring is about as simple as it gets.

...the problem is, if the bow string is classified as new material, then under generic encylopedic rules - wiki included - it cannot (ought not) be entered into the main article, thus the discussion is moot(?)! "....Primary research. If you have discovered something or found something out, put your ideas in a book for a learning school, not on Wikipedia. Wikipedia will talk about your ideas once it is known to a lot of people...."[45]

Even as an observation of the current understanding of the subject by the entry author/editor, there ought to be at least one more source - established in the particular field - making a similar observation. Non?

Pete318 (talk) 15:06, 21 May 2014 (UTC)[reply]

I don't know what it is about this page that so consistently attracts vandalism from anonymous users. Looking at several years of history, the vandalism is not correlated with the school year (which had been my hypothesis in early lock-downs). I fear that there is no choice but to restrict the editing of this article to confirmed users only. Rossami (talk) 18:27, 28 May 2015 (UTC)[reply]

THIS WEBSITE IS TRASH DONT TRUST IT — Preceding unsigned comment added by 64.56.10.139 (talk) 14:45, 7 February 2017 (UTC)[reply]

A spring is not a simple machine because it does not make work easier.If it simplified work then it would be considered a simple machine. a simple machine can be associated with springs like a rube goldberg machine.

                                                                                                                                     -Anna  — Preceding unsigned comment added by 2604:6000:B7CE:1800:649E:C921:91BF:8E9F (talk) 00:56, 4 April 2017 (UTC)[reply] 

Right. A spring stores energy (work). A simple machine doesn't store energy, it just transforms it, increasing the force while decreasing the velocity or distance moved (or sometimes vice versa). In a frictionless simple machine the same amount of energy or power comes out of it moving the load as goes into it from the applied force. In a spring, applying a force to it, flexing the spring, stores work or energy in it, which stays there until the spring is released. --Chetvorno^TALK 01:18, 4 April 2017 (UTC)[reply]

@Prof McCarthy: Re your recent edits to the "Ideal simple machine" section. I don't see that the equality of velocity ratio and distance ratio is limited to certain machines, it seems to me it is a property of all 6 of the classical simple machines (this section is about the 6 Renaissance simple machines; not cam followers)

For any simple machine, let ${\displaystyle \mathbf {x} _{\text{in}}(t)=[x_{\text{in}}(t),y_{\text{in}}(t),z_{\text{in}}(t)]}$ be the point at which input force is applied to the machine, and ${\displaystyle \mathbf {x} _{\text{out}}(t)=[x_{\text{out}}(t),y_{\text{out}}(t),z_{\text{out}}(t)]}$ be the point at which the machine applies force to the load at time ${\displaystyle t}$. ${\displaystyle \|\cdot \|}$ is the Euclidean norm. From the Ideal simple machine section, the mechanical advantage is equal to the velocity ratio at any time

${\displaystyle \mathrm {MA} ={v_{\text{in}}(t) \over v_{\text{out}}(t)}}$

${\displaystyle v_{\text{in}}(t)=\mathrm {MA} \cdot v_{\text{out}}(t)}$

${\displaystyle {\Big \|}{d\mathbf {x} _{\text{in}}(t) \over dt}{\Big \|}=\mathrm {MA} {\Big \|}{d\mathbf {x} _{\text{out}}(t) \over dt}{\Big \|}}$

${\displaystyle \|d\mathbf {x} _{\text{in}}(t)\|=\mathrm {MA} \|d\mathbf {x} _{\text{out}}(t)\|}$

Let ${\displaystyle S_{\text{in}}}$ be the path the input point follows, and ${\displaystyle S_{\text{out}}}$ be the path the output point follows between any time ${\displaystyle t_{1}}$ and ${\displaystyle t_{2}}$. Let ${\displaystyle D_{\text{in}}}$ be the length of ${\displaystyle S_{\text{in}}}$, and ${\displaystyle D_{\text{out}}}$ be the length of ${\displaystyle S_{\text{out}}}$.

${\displaystyle \int _{S_{\text{in}}}\|d\mathbf {x} _{\text{in}}\|=\int _{S_{\text{out}}}\mathrm {MA} \|d\mathbf {x} _{\text{out}}\|}$

${\displaystyle \int _{S_{\text{in}}}\|d\mathbf {x} _{\text{in}}\|=\mathrm {MA} \int _{S_{\text{out}}}\|d\mathbf {x} _{\text{out}}\|}$

${\displaystyle D_{\text{in}}=\mathrm {MA} \cdot D_{\text{out}}}$

${\displaystyle \mathrm {MA} ={D_{\text{in}} \over D_{\text{out}}}}$

${\displaystyle {v_{\text{in}} \over v_{\text{out}}}={D_{\text{in}} \over D_{\text{out}}}}$

--Chetvorno^TALK 21:30, 25 November 2017 (UTC)[reply]

Reverted edits, added supporting citations. --Chetvorno^TALK 02:00, 4 December 2017 (UTC)[reply]

You start by showing that MA is a function of time, and then you integrate assuming that MA is not a function of time. In general the velocity ratio is not constant. The integration to obtain a distance ratio requires that the velocity ratio remain constant. It was exactly this statement that you reverted and have now replaced with an error. Prof McCarthy (talk) 06:18, 4 December 2017 (UTC)[reply]

I accept your point that in other linkages generally the MA changes with time as the linkage moves, and perhaps that should be mentioned in the article. But in the 6 Renaissance simple machines, which is what are being discussed in the "Ideal simple machine" section, the MA is constant with time. That's what I assumed in my proof above, that v_in(t) and v_out(t) change with time but MA = v_in/v_out is constant. In the lever the MA is the ratio of the lever arms; in the wedge and inclined plane it is the slope of the flat bearing surfaces, in the screw it is the lead, in the pulley it is the number of cables supporting the load, and in the wheel and axle it is the ratio of the wheel to axle radius. In textbooks on classical simple machines "velocity ratio" and "distance ratio" are used synonymously: [46], [47], [48]. --Chetvorno^TALK 15:20, 4 December 2017 (UTC)[reply]

In the History section, we have the sentence "He was the first to understand that simple machines do not create energy, only transform it.[16]" The referenced source does not state this, nor is it a defensible statement. Galileo was apparently the first to describe this fact, but it is unlikely he was the first to conceive of the idea that simple machines do not create energy, and it is impossible to know this for certain unless we can look into the minds of everyone who ever thought about the subject.

Here is the relevant quote from the source: ″He was the first to explain that simple machines do not create work, but rather alter the way in which work is applied.″ That is not the same sentence, both in that it only claims he was the first to explain, not the first to understand, but also that it refers to work, not energy.

I suggest either re-wording or perhaps removing the statement. I'm not sure if it adds much, and I'm not sure if Krebs' assertion is reliable anyway. Leperflesh (talk) 21:31, 19 December 2017 (UTC)[reply]

I think explain in this sentence means assert or state. If no previous scientist "explained" that simple machines do not create work, then Galileo should be credited with this important breakthrough insight. And of course "work" is a form of "energy", so in modern terminology what Galileo realized was that simple machines do not create energy. ----Chetvorno^TALK 04:51, 21 December 2017 (UTC)[reply]