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Point-Mass at it's Orbit: Newton's Equations searched

vlehner
14-Alexandrite

Point-Mass at it's Orbit: Newton's Equations searched

Hello!

I have calculated the complete dynamics for a mass-point moving along a parabola curvation without any resistance like air-resistance, friction, etc.

 

05-07-2017 21-34-02.jpg

 

The solution is correctly solved with the Lagrangesche-methos, the movement happens in that way i suggested.

But sometimes it's very complex to create ODEs in that way and therefore it's better to use Newton's Laws.

 

I tryed to solve the problem with the dynamic balance of forces acting on the mass, but i couldn’t get the same solution in that way so i’m asking what’s wrong. (please see attachement including MP4 and Pdf-file)

 

Can somebody tell me what’s wrong there?

 

Thank you very much.

Volker
11 REPLIES 11

The attached file may help

vlehner
14-Alexandrite
(To:Fred_Kohlhepp)

Hi Fred,

In principal i understand what you calculated.

But what i do not understand is: The sign of the force Fhx.

 

Initial situation:

The body is on the right side and we release it at xo, then it moves along downwards the curvature to the left.

 

I calculated Fhx as negative and added Ftx, this should be zero.(see sketch)

Fhx (yellow) is acting from right to the left side and will accelerate the body, the force Ftx acts from left to the right because the body has the intension to stay at the position he is (=Trägheitskraft).

 

If i built the sum, then i have: -Fhx+Ftx=0 what gives a wrong graph, but the dynamic statik says: the sum of all forces have to be zero. In many textbooks i saw this same procedure.

 

When changing the sign of Fhx to positive, i get a correct graph like you have.

Now i'm confused because i know that the sum of all acting forces have to be zero taking into account their direction they act.

I had the same problem in the thread: https://community.ptc.com/t5/PTC-Mathcad-Questions/Hello-World-See-my-1-st-Prime-Animation/td-p/196317/page/7

 

neither something in my interpretation is basically wrong, nor something other don't work correctly.

Please explain me.

 

Thanks for your help.

Volker
vlehner
14-Alexandrite
(To:vlehner)

Another example for the sum of all forces:

We have an inclined plane without friction and any resistance, then it is (like in many textbooks):

 Scan.jpg

This princip is the same with the parabola.

Volker

The disconnect is the "sum of forces equals zero."  If the forces sum to zero there will be no acceleration  (F = ma).

 

So there must be a force unbalance. 

 

I tried to solve for acceleration along the curve, using the tangential component of weight; but I'm not good enough to sort x and y out of the acceleration along the curve.

vlehner
14-Alexandrite
(To:Fred_Kohlhepp)

Hi Fred,

 

it's easy for the acceleration along the curve.

You can use the solved x(t) to compute this acceleration and make a new balance of forces with m*a=-Fh:

Anyway: I'm not familiar with the Signs of the forces in the balances. We have a dynamic statik.

See attachement please.

06-07-2017 18-42-58.jpg

 

Volker
vlehner
14-Alexandrite
(To:Fred_Kohlhepp)

"

The disconnect is the "sum of forces equals zero."  If the forces sum to zero there will be no acceleration  (F = ma).

 

So there must be a force unbalance. "

 

An what is now about this:

Scan.jpg

There is a contradiction!

Volker
vlehner
14-Alexandrite
(To:vlehner)

Something else has occurred to me:

comparing the ODE from the Lagrangesche Method with the ODE from the Newtons method shows following:

Lagrangesche ODE:

 

07-07-2017 11-51-32.jpg

 

Newton's ODE:

 

07-07-2017 11-54-41.jpg

 

Note, that the sin and cos functions can be written here as:

 

07-07-2017 11-58-03.jpg

Volker
vlehner
14-Alexandrite
(To:vlehner)

All this is from my textbook kinetics, technical mechanik 3:

The origin task see example 4.5 in this textbook.Scan1.jpg

 

Scan.jpg

 

Volker
-MFra-
21-Topaz II
(To:vlehner)

Hi Volker,

Could you be interested in the following Lagrange multiplier technique? 

Material poin on a surface.jpg

Greetings

Francesco

vlehner
14-Alexandrite
(To:-MFra-)

Hi Francesco,

 

Absolutely!

It's impressive.

could you attach this file please- then i can study it much better.

Thank you.

Volker
-MFra-
21-Topaz II
(To:vlehner)

Hi Volker,

I've attached the requested file.

I hope I've zipped the file correctly.

Greetings

Francesco

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