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**rickoff** · 07-18-2010, 06:21 AM

Here's an original advertisement for a mobile swinging gym setup of the type that is most commonly found at traveling carnivals that go from town to town during the summer.

These are of a somewhat smaller scale than some stationary units found at amusement parks, since they must be built to clear bridge underpasses on highways. The first time I tried one, at age 13, was at an amusement park in New Jersey some 52 years ago. We estimated that the top of the cage was 30 feet above ground at its highest point in the rotation, and the ride operator said our estimate was just about right. The units in the above photo are constructed a bit differently than the ones shown in the video of my previous post, but the triangular support framework and triangular pattern of the pivot points is closely related. The main difference in this suspension is that the upper pivot arm is connected to the top center of the cage side, rather than at shoulder height as shown in the video, and I believe that makes rotation more difficult, although it adds more stability to the suspension. This photo does show more clearly, however, the actual connections of the pivot arms to the cage. It also shows two important human weight shifting attributes.
1. In the cage closest to the viewer there are two boys. Both should be in the position maintained by the boy on the right side of the cage. The cage is moving downward, and will soon be at the bottom of the arc. The boy at the right side is bending his knees to shift his weight lower in the cage while "pulling" on the bar at the right side as the cage moves down, and is just beginning to reach for the handle bar at the other side of the cage. Ideally, he should have his body weight lowest at bottom dead center (BDC), and be holding both bars at that point, but also leaning more to the left and moving quickly in that direction, and should begin to extend his body as the cage passes BDC and moves upwards, very much like the boy who is already at the left side. These boys are actually working aginst each other. Now look at the fellow in the highest cage. He is centered in the cage, at a full standing height, and with both bars being held. If he is already rotating, then he appears to be rotating counter-clockwise, and is about to make his move to the left side of the cage. This move should begin somewhere around 30 degrees from the top, and the final lurch to the left should occur at about 10 degrees. While going down, it is most advantageous to keep the body as close to the cage side as possible, but to also begin turning the body so that you will be able to step towards the other side near the bottom.

Now if we reasonably estimate the cage height at 7 feet from top to bottom, then the cage scales to about 7ft x 3.5ft x 2ft, approximately. The pivot arms are each about 8 ft in overall length, including the counterweights, and are about 5 ft between their pivot points. The supporting triangular framework is about 11 ft high from its base to the uppermost pivot point, and perhaps 5 to 6 ft wide at the base. The base is slightly obscured in the photo, but the width of the trailer is stated as 7ft 10 inches, and this would be measured at the widest part, where the wheels and fenders protrude. The cage would be suspended so that the bottom of the cage would be close to the ground or base level, perhaps just 6 inches above. So, if the distance between pivot points on the pivot arms is about 5 ft, then the lower pivot points on the triangular frame are about 5 ft + 6 inches, above the base. These are just rough guesstimates, of course, but not very far from actual measurements, so gives a reference to draw up some construction diagrams of the parts, which can then be scaled down to a manageable experimental build. A frame height of perhaps 2 to 3 ft from base to upper pivot point would be quite adequate for experimental purposes, and at 2.2 ft would represent a 1/5 scale model.

**rickoff** · 07-18-2010, 07:12 AM

Here's another still photo that shows a different, but more stable setup. Notice the bars extending from the framework to the ground, where they are likely anchored well. You could rightly say that this is an improved version. Stability is important where you have an out of balance condition. As you can see, three cages are reaching the top nearly in unison. If all four were doing this then the combined thrust could lift the base off the ground if not anchored down sufficiently. The pivot arms appear to be longer on these units than in the previous post's photo, perhaps around 9.5 ft overall length, which would place the counterweights where they would relieve more of the human burden, and that's why these people seem to be doing so well. The designer probably assumed that by making the ride easier, more people would choose to go on it, and to also go on repeat rides, and that makes sense. The green and blue cages are rotating counter-clockwise. The person in the blue cage has just cleared top dead center (TDC), while the woman in the green cage is about 15 degrees or so past TDC, starting to bend knees, and preparing to turn her body so that she will be facing towards the opposite direction near the bottom of the rotation. The fellow in the yellow cage is standing in the wrong place unless he is rotating clockwise and is in the process of making his move from the left side of the cage to the right side as he goes over the top.

**Matos de Matos** · 07-18-2010, 01:52 PM

Originally posted by rickoff View Post

I can tell you that the trick is to always maintain a position within the cage that is closely adjacent to to the outer perimeter of the rotating arc, as this develops the greatest inertial thrust both going down and going up. The operator's position within the cage must begin to shift from one side to the other close to the top, and again near the bottom, of the rotation, in order to keep weight distribution close to the arc perimeter. Also, the operator needs to bend their knees to keep their weight low as they near the bottom, and then extend the body mass to a full height while going up. You can see that either side of the cage has bars that the operator can hold onto. If going down, you are holding the bar at one side, and if going up you are holding the bar on the opposite side. When shifting weight from one side to the other, you hold onto the side you are on with one hand as you step to the middle and reach out to grasp the opposite handlebar. At this point, which should be within 10 degrees or so of the top or bottom of a cycle, you should be holding both bars, and should then continue deliberately leaning and moving quickly to the side you are aiming for. In your arms and hands, it feels like you are actually "pulling" the cage lower as you approach the bottom, and then "lifting" it higher, as you begin to move upward. This cannot be so, of course, but it does give you the feeling that this is what you are doing when you move correctly.

Best to all, Rick

Hi Rick:
Your experience is for sure, more trustful than my mental exercise of riding a machine that I never saw.
I see the swinging gym pumping mechanism similar to pumping a swing.
In the swinging gym, ideally, would be that the counter weights where the same mass of the cage and with same arm length.
That would give equilibrium at 90�, with fulcrum in the midpoint between the cage and counter weight, horizontally.
We have to pull the cage to the vertical position, to get in, but the system will be more efficient, and with little effort you can pump your own weight up, like pumping a swing.
It is like a lever, that when you move closer to the fulcrum, you go up, if you had a balancing counter weight on the other extreme.
The clips at this page, Pumping of a Swing - Physics | Grinnell Collegeshows that, as you shorten the path on the way up, reducing the time where kinetic changes to potential energy, and reducing the work of gravity, some kinetic energy is left over to pump the swing.
Did you see my last thread where I am using rotating Halbach permanent cylinders as weights and as pumping mechanisms?
http://www.energeticforum.com/renewa...scillator.html
It may be a perpetual machine of the third kind.

David

**rickoff** · 07-18-2010, 05:33 PM

Originally posted by Matos de Matos View Post

Hi Rick:
Your experience is for sure, more trustful than my mental exercise of riding a machine that I never saw. I see the swinging gym pumping mechanism similar to pumping a swing. In the swinging gym, ideally, would be that the counter weights where the same mass of the cage and with same arm length. That would give equilibrium at 90�, with fulcrum in the midpoint between the cage and counter weight, horizontally. We have to pull the cage to the vertical position, to get in, but the system will be more efficient, and with little effort you can pump your own weight up, like pumping a swing.

True, it would require less exertion if you start out with a fully balanced system, where the counterweights balance out the weight of the cage and its occupant, when the occupant is positioned at the center of the cage. This may well be the situation where we would like to begin testing at, since it will allow for the least exertive forces possible. On the other hand, closely balancing the system will greatly reduce the inertial momentum, which is a very important factor in attaining and maintaining rotation with this device. Remember that, in your swing example, there is no counterweight. You have the full weight of the suspended swing and rider providing inertial thrust. Now suppose that instead of hanging that swing from rope or chain, that it was suspended from rigid bar stock. You would still have the same swinging pendulum effect. But what if you extended the bars an equal distance above the pivot point and placed a weight there equal to the swing rider's weight? The system would then be balanced, and should be ideal according to your reasoning. In actuality, though, this removes all inertial thrust except the slight amount that can be gained by the rider through body positioning, and it is quite unlikely that the rider could gain a high arc position, let alone go over the top and rotate.

As shown in my previous post, extending the counterweights of the Swinging Gym does make it easier in that it requires less exertion from the rider. So there definitely is a positioning of the counterweights that would prove ideal for the load of the cage and its contents. That ideal will not be a balanced load, though. Instead, it will be an unbalanced situation that provides for strong inertial thrust, but which does not require exhaustive exertion by the rider. For the Swinging Gym, this imbalance is designed to be always greater than the rider's weight, but it certainly could be optimized for whatever the rider's weight might be. An optimized imbalance, with rider aboard, might be somewhere in the neighborhood of, let's say, 100 pounds. If set up this way, the rider would find operation relatively easy, but it would still allow for good inertial thrust. I'm certain that, set up this way, I could rotate the machine with relative ease for an extended period of time, and that mimicking the required weight shifting movements by other than human means would be quite possible.

I hope you can find one of these Swinging Gyms this summer and try it out for yourself, and then this will all be much clearer. What state are you located in? In the northeast US there are numerous town and county fairs where traveling carnivals make the rounds, and where you would most likely find one of these machines.

Best 2 U David,

Rick

**Matos de Matos** · 07-18-2010, 07:25 PM

Originally posted by rickoff View Post

Remember that, in your swing example, there is no counterweight. You have the full weight of the suspended swing and rider providing inertial thrust. Now suppose that instead of hanging that swing from rope or chain, that it was suspended from rigid bar stock. You would still have the same swinging pendulum effect. But what if you extended the bars an equal distance above the pivot point and placed a weight there equal to the swing rider's weight? The system would then be balanced, and should be ideal according to your reasoning. In actuality, though, this removes all inertial thrust except the slight amount that can be gained by the rider through body positioning, and it is quite unlikely that the rider could gain a high arc position, let alone go over the top and rotate.

I hope you can find one of these Swinging Gyms this summer and try it out for yourself, and then this will all be much clearer. What state are you located in? In the northeast US there are numerous town and county fairs where traveling carnivals make the rounds, and where you would most likely find one of these machines.

Best 2 U David,

Rick

Hi Rick:
My apologies but I have to disagree with you.
A robot battery powered child in a fixed rod will rotate 360� and accelerate at each swing with amplitude less than 360� and after each revolution if exactly mimic as showed on the picture.
The sketch below shows that any unbalanced gain will be used on the other side going up.
I am not aware of other mechanical pumping of oscillators other than direct push or the change of center of mass shortening the up trajectory of the bob.
The design of the unbalanced swinging gym, with such a heavy cage, in my opinion is to difficult the rider and make him work.
Remember how easy is pumping a swing?
I live in Luanda, Angola, the most expensive city in world. Typical African capital of an oil reach country.
We import bottled water and vegetables.
I couldn�t find anywhere in the Country simple permanent magnets. I order and import them.
That is the reason of not presenting physical prototypes, I just can�t make them.
Well, everybody is invited to prototype them

David

**rickoff** · 07-19-2010, 06:26 AM

Originally posted by Matos de Matos View Post

Hi Rick:
My apologies but I have to disagree with you.
A robot battery powered child in a fixed rod will rotate 360� and accelerate at each swing with amplitude less than 360� and after each revolution if exactly mimic as showed on the picture.
The sketch below shows that any unbalanced gain will be used on the other side going up.
I am not aware of other mechanical pumping of oscillators other than direct push or the change of center of mass shortening the up trajectory of the bob.
The design of the unbalanced swinging gym, with such a heavy cage, in my opinion is to difficult the rider and make him work.
Remember how easy is pumping a swing?

Okay, you can disagree with me, but about what, exactly, are you disagreeing with? And what is this "robot battery powered child in a fixed rod?" I have absolutely no idea what you are talking about, David, as I simply can't visualize that.

So are you saying that a swinging gym would be optimized for performance if the total of the counterweights equaled the weight of the cage plus the rider? If so, then it looks like we will simply have to agree to disagree and leave it at that. Yes, I have pumped many a swing in my younger years, and remember that quite well. And yes, it is relatively easy to pump a swing, but that's because you have inertia working for you both when swinging downward and swinging upward through the arc. Remember, a swing is unbalanced - there is no counterweight above the pivot point. As I said in my last post, if you suspended the swing from rigid metal rods that were extended an equal distance past the pivot point, and fastened counterweights there to equal the total weight at the bottom of the swing (including the rider), then you would have an almost impossible time trying to pump the swing. Don't believe that? Well then, try it and let's see.

Exactly balancing out the Swinging Gym would prove just as futile. You really do need a good amount of inertial thrust to swing, and rotate the device. Yes, the standard Swinging Gym is purposely engineered so that it is not that easy to get over the top, Some are easier than others, as my last post with photo shows. The counterweights are extended further out on that build, which relieves some of the operator burden, and they could certainly be extended even further out. At some point of extension you would find the ideal setting to allow for operator ease while also leaving enough imbalance to provide good inertial thrust. In my last post, I suggested that perhaps a 100 pound imbalance might be ideal. That would be much less imbalance than a standard Swinging Gym setup, but should still allow for adequate inertia. The extension would have to be made adjustable, of course, to provide the same 100 pound imbalance for varying cage loads (riders of different weights, and multiple riders).

Too bad you don't live where you could try out a Swinging Gym, but you could certainly build a full scale one almost entirely from junked parts. And a small one, with a 2 to 3 foot high frame could also be quite useful for experiments, even though it won't allow you the experience of riding it over the top.

Best regards to all,

Rick

**Matos de Matos** · 07-19-2010, 10:43 AM

Originally posted by rickoff View Post

So are you saying that a swinging gym would be optimized for performance if the total of the counterweights equaled the weight of the cage plus the rider?

Best regards to all,

Rick

Hi Rick

I didn�t say �plus the rider�.
What I am trying to say is that doesn�t matter how many counter weights you add to a pendulum, gravity will always look for the equilibrium, and that any gain on the descend will be used on ascending.
To pump a pendulum, with amplitudes less than 180� or over (full rotation) you have to change the center of mass. (or give it a push)
The energy gain when pumping is proportional to the mass moved around.
Anywhere you add mass to unbalance the system, it will only change the equilibrium position and increase the mass to be pumped, with your little mass moving up and down.
The picture shows the battery operated robot that bends the knees on the bottom and rises then on the top.
I would like to see one of those. And will accelerate for sure.
David

**Matos de Matos** · 07-19-2010, 10:47 AM

[QUOTE=Matos de Matos;104476]The picture shows the battery operated robot that bends the knees on the bottom and rises then on the top.
[QUOTE]

It is the other way around:
The picture shows the battery operated robot that raises the legs on the bottom and bends the knees on the top.

**rickoff** · 07-20-2010, 07:26 AM

Originally posted by Matos de Matos View Post

The picture shows the battery operated robot that bends the knees on the bottom and rises then on the top.

Hi David,

I'm well aware of the attributes and functional parameters of a pendulum, so no need to cover that again. I'm glad to hear that you would not suggest counterbalancing the full weight of the cage plus the rider, and so it seems you would agree that a useful Swinging Gym type of device does need at least some amount of imbalance. By useful, of course, I mean a device capable of doing work, such as pumping water or generating electricity. A fully balanced sytem would not be a useful device. True, just one gram of imbalance added to the top of a balanced system could theoretically cause the unit to rotate downwards, but the developed torque would be insufficient to accomplish any useful work. To do that we need an appropriate weight of imbalance working for us, and that's why I suggested perhaps allowing for a 100 pound imbalance after taking into account the weight of the cage plus the weight of the rider. This would make operation of the device quite easy, but would allow for plenty of useful torque development as well. Would you not agree?

Rick

p.s. - What is it that the large circle at the bottom of your last post is supposed to represent? Also, why does the the robot have knees bent at the top and the right side, as well as the bottom of the circle? Then too, why is the circle skewed on the left side to show a solid and a dotted curve?

This isn't meant to represent a robot mimicking the human movements used with a Swinging Gym, is it? If it is then it is way off.

**Matos de Matos** · 07-20-2010, 09:24 AM

Originally posted by rickoff View Post

Hi David,

p.s. - What is it that the large circle at the bottom of your last post is supposed to represent? Also, why does the the robot have knees bent at the top and the right side, as well as the bottom of the circle? Then too, why is the circle skewed on the left side to show a solid and a dotted curve?

This isn't meant to represent a robot mimicking the human movements used with a Swinging Gym, is it? If it is then it is way off.

Hi Rick:

Did you look at the clips on this page?
It is very elucidative, specially the first, where he shows how to pump a pendulum pulling the weight inwards on ascending.

Pumping of a Swing - Physics | Grinnell College

On the picture posted earlier, the swing before the circle shows the mechanism to pump a swing, where the child, when it reaches the bottom, stands up and when reaches the end of the amplitude (stop) he lays down bending the knees. This is done both ways.

If you hang the child from a solid rod, and you drop him from the top, with the knees bend, and if he does stand up at bottom, he will pump the swing on ascending, accelerating.
On top he will have a higher velocity than when he was dropped, a full rotation can be accomplished, and on the next rotation, if he pumps again he will have higher velocity.
At each revolution he will accelerate, accelerate to a maximum allowed by his physical forces.
This is what I am trying to show with the circle picture.
The left dotted line is the trajectory of a normal pendulum, and the solid trajectory, is when the child pumps it, changing his center of mass, closer to the center (fulcrum).

This is the only way I know to pump a pendulum, or an unbalanced wheel that is a pendulum with amplitudes of 180�, (reaching the top), or over 180�, with a full revolution.

David

**rickoff** · 07-21-2010, 05:49 AM

Originally posted by Matos de Matos View Post

Hi Rick:

Did you look at the clips on this page?
It is very elucidative, specially the first, where he shows how to pump a pendulum pulling the weight inwards on ascending.

Pumping of a Swing - Physics | Grinnell College

Sorry, I am at my cottage in a remote area of Maine for several days, and only have slow dial-up service here, so cannot view any clips. I can most assuredly tell you, however, that if you keep to the inward side of the Swinging Gym cage as it is ascending from the bottom, you will not make it over the top. The outward side of the cage, as it comes down, becomes the inward side going up, so it would be very easy to just stay on that side if it would work, but it doesn't. I have fully explained the body movements and timing that is necessary for successful operation, and suggest that you review those. You can show me diagrams and video clips until the cows come home, but it doesn't matter. When it comes to the Swinging Gym, which is the subject of this thread, I have the experience to know what works and what doesn't. I suggest that you draw a diagram of a Swinging Gym apparatus, and then show (inside the cage) where you think a human operator should be positioned every 30 degrees for best performance. This thread is about mimicking the successful operator of a Swinging Gym, not a swing, so let's start with the correct apparatus. You could use the attached simple image, or make your own. The attachment simply and roughly depicts twelve 30 degree positions, and does not mean to suggest that 12 cages should be suspended within one device. Let's assume that the operator is rotating the device clockwise.

Rick

Attached Files

Swinging Gym at 30 degree increments.jpg (22.3 KB, 14 views)

**Harvey** · 07-21-2010, 06:25 AM

If we were to treat the swinging gym as a parametric oscillator, could the operator simple stand up at the bottom and squat 45� later to add energy to the system?

And if we treat a pendulum as at driven oscillator, could we not simply attach a cross bar to the end and rotate it horizontal at one end of the swing action and then vertical at the other? That is, perpendicular and then parallel to the pendulum arm?

What if we used some magnets to flip that cross bar between horizontal and vertical? Could this be the secret to splitting the conservative field into non-conservative parts?

**Matos de Matos** · 07-21-2010, 09:29 AM

Originally posted by rickoff View Post

When it comes to the Swinging Gym, which is the subject of this thread, I have the experience to know what works and what doesn't. I suggest that you draw a diagram of a Swinging Gym apparatus, and then show (inside the cage) where you think a human operator should be positioned every 30 degrees for best performance. This thread is about mimicking the successful operator of a Swinging Gym, not a swing, so let's start with the correct apparatus. You could use the attached simple image, or make your own. The attachment simply and roughly depicts twelve 30 degree positions, and does not mean to suggest that 12 cages should be suspended within one device. Let's assume that the operator is rotating the device clockwise.

Rick

Hi Rick:

Sorry to come up with the swing, I thought that was the same mechanism, where the applied forces where done at same points, but in fact the change of center of mass is different, and very interesting and shall be analyzed with more time.
This is how I see it.
On the right side the body has to move down faster than the cage being in the outer (biggest radius) and when reaches the bottom has to raise the body and keep it as close to the center as possible.
It will be easier to push down the weight on the right side faster than the cage, than in the swing where you have to pull it up at the highest point.
The driven mechanism is the next issue, and if you do not mind I can post some opinions. Unfortunately, Africa my home, doesn�t let me do prototypes.

Sorry Rick, but I have to answer the off topic subject bring by Harvey.
I am trying to open a discussion on the parametric oscillator and did open a few threads with different ideas, but unfortunately, people are not responding, and what they see is if works or not and the �thinker� mathematical and academic status.
I am not seem any �Ifs�
I know that some proposals are �physically� impossible, but they are only ideas that when talked and though about will lead to better ones.
Please check the treads that I have where instead of a bar I have a sliding magnet.
Thank you
David
http://www.energeticforum.com/renewa...ics-quest.html
http://www.energeticforum.com/renewa...scillator.html
http://www.energeticforum.com/renewa...ted-wheel.html
http://www.energeticforum.com/renewa...um-hammer.html
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**rickoff** · 07-22-2010, 05:08 AM

Originally posted by Matos de Matos View Post

Hi Rick:

Sorry to come up with the swing, I thought that was the same mechanism, where the applied forces where done at same points, but in fact the change of center of mass is different, and very interesting and shall be analyzed with more time.
This is how I see it.
On the right side the body has to move down faster than the cage being in the outer (biggest radius) and when reaches the bottom has to raise the body and keep it as close to the center as possible.
It will be easier to push down the weight on the right side faster than the cage, than in the swing where you have to pull it up at the highest point.
The driven mechanism is the next issue, and if you do not mind I can post some opinions. Unfortunately, Africa my home, doesn�t let me do prototypes.

[ATTACH]6085[/ATTACH]

Hi David,

I saw where you filled in some circles inside the "cages" of the drawing. I was hoping for some stick figure bodies, but the circles are a good start. I am assuming that each circle represents a weight, rather than a body, and that the placement of each circle is where you expect that the weight will have the optimum effect on rotation of the Swinging Gym. You partially have it correct on the right half of the rotation, but the left side is way off. What you show would actually provide rotation if this were a Bessler type wheel built with multiple cages. Those who attempt Bessler wheel builds always wrestle with the problem of somehow having the weights outward on the way down, and moving them inward on the way up. The idea being, of course, that the outward weights will have enough leverage to lift the inward weights. The Swinging Gym cage suspension solves that problem by automatically shifting the outward weight to the inside on the way up. With wide enough cages, the weights could be kept very close to center on the way up. So there you have it - the solution to the Bessler wheel dilemma. As to the single cage Swinging Gym, though, it's an altogether different story. In the Swinging Gym, you want to be standing at full height against the right side of the cage for the 3 o'clock position. Why? Because this distributes your weight as close as possible to the outer arc perimeter, where it will have the most leverage. Only after you pass 3 o'clock should the knees begin to bend, and this is because you want to maintain your body weight as close to the arc perimeter as is possible. At 4 o'clock and 5 o'clock, the right side of the cage is moving further and further away from the arc perimeter, while the bottom of the cage is moving closer, so the knees continue bending to bring the rider's weight closer to the cage bottom and the arc perimeter. At 6 o'clock, the bottom of the cage is closely aligned with the arc perimeter, and the rider should be positioned at the center of the cage with knees bent the maximum amount. As the rotation continues, to 7 and 8 o'clock, the rider is progressively straightening the knees and moving to the left side of the cage in order to maintain a position as close to the arc perimeter as is possible. At 9 o'clock, the rider is standing at full height and pressed against the left side of the cage, where body weight is most evenly distributed as close as possible to the arc perimeter, just as in the 3 o'clock position. The reason for staying close to the arc perimeter on the way up, as well as on the way down, is to provide leverage and inertial thrust. Now there is a point in the upward half of the rotation where maintaining weight at the left side of the cage becomes a liability. As the cage moves on to the 10 and 11 o'clock positions, the left side of the cage is moving further and further away from the perimeter, and the rider is already standing at full height, so cannot get any closer to the arc perimeter unless he jumps up and grabs the top of the cage and lifts his knees up toward his chest. That would be too difficult, and too dangerous, for a Swinging Gym rider, so at about 10 o'clock the rider instead begins moving quickly towards the right side of the cage, making it to the middle by 11 o'clock, and fully to the right by 12 o'clock. This is the precise method used by any experienced rider to rotate the Swinging Gym. And, being an experienced rider myself, I assure you that this works quite well. Therefore, any proposals for mimicking the necessary human movements should provide not only for up and down weight shifting, but also shifting along a horizontal plane from cage side to side at the correct timing points.

Rick

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The Swinging Gym - model for an effective gravity wheel?

The Swinging Gym - model for an effective gravity wheel?

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