hi Please check this file.

Hi,

can you please check this.

Hi,

Attached in are the files and pictures required.

Yield strength: 330 MPa

Tensile Strength: 520 MPa

Force: 405340 N

Problem:

1. Inventor (even some other FEA softwares, not specifically inventor) results and actual results don't relate each other.

Using more finer mesh, more stress is developed, meaning it will fail but thats not the case in reality.

2. Adding ribs or supports must reduce stress and increase safety factor but the stress increases. For customer, high stress and low S.F means it will break faster or something in that part will crack faster at lower force.

3. Adding fillets and stress reducers increase the stress in software(very strange)

Inventor lacks in fillets and creating smooth surfaces. ecspecially in very complex curves.

If you have any solutions please help

This is for reference, our test modal.

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@Anonymous wrote:

 

2. Adding ribs or supports must reduce stress and increase safety factor but the stress increases. For customer, high stress and low S.F means it will break faster or something in that part will crack faster at lower force.

 

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Take a look again at your first example:

If you look only at the magnitude, it does appear that the model with the rib has the higher stress loading at 15.83MPa while the original has only a stress of 13.88MPa.

However, when you look _at the location_ too, the stress in the corners of the first model due to the loading is 13.88MPa (red) and has been reduced to somewhere near 9.56MPa (lime green) in the revised design with the rib.

I suspect that if you change the thickness of the rib, you can reduce the overall stress in the second design to be at or below that of the original; furthermore, you can probably reduce the stress in the corners even more by adding fillets.

As JDMather stated, FEA is a tool and, like any tool, you have to understand both how to utilize it and how to interpret the results that it provides.

HTH

May be you can use the files uploaded in meassage 25 and 26.

Lets wait for your analysis results.

And Please note I have applied 40 tons of force in the software.

In reality we ended up applying 320 tons of force still there was no breakage. We reached the maximum capacity of cylinders, but nothing could break that part.

Safety factor is measured with Yield strength/stress. No one is interested in what will happend after yield strength. No one designs or sells anything based on tensite strength. At least not in our branch (heavy structures/shipbuilding/mining)

From our hand calculations and from our extensive testing that we did over and over again we are getting much higher results than simulated by Inventor.

Also field test results prove the safety factor is much higher than expeted with Inventor.

Why do we have Inventor? or any other FEA analysis if SF of the simulation is much lower than tested and hand calculated.

HOW TO CALCULATE THE SAFETY FACTOR? (of course based on YIELD only)  

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@Anonymous wrote:

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@Anonymous wrote:

3. Adding fillets and stress reducers increase the stress in software(very strange)

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3. No.  Not strange if you have studied how digital analysis is done.
For a general discussion, I like the book Building Better Products with Finite Element Analysis by Vince Adams.

For Inventor specific FEA get the book by Wasim Younis.

But neither of these books really substitute for logic an practical experience.

 

The Younis book should show you how you can set up the analysis results such that unimportant (to the function of the part) areas can be handled such that the analysis results can be properly presented to the customer.  But again, you should have a clear understanding of exactly what you are doing with the digital model so that you are not simply creating pretty pictures that say what you want them to say.

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What are your simulation results?

Please interpret the results about the modal?

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@Anonymous wrote:

 

What are your simulation results?

  

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As I am not using Inventor 2014, I couldn't open your .ipt files; however, I did my best to recreate your part using the drawing/sketch you provided -- I must say that it left much to be desired as it was missing many dimensions.

Using the 880,000 N load and the fixed conical surfaces, my results were similar to yours; a resultant stress of approximately 317.7 MPa and a deflection of 0.446mm (for reference your values were 322.1 MPa stress and 0.411mm displacement).

However since the stress exceeds the yield of the steel material (~206.8 MPa), the FEA model does not reflect what would happen with the actual part under similar loading conditions.  I am curious how your FEA model indicates a Safety Factor of 0.97 Min when the material yield strength is 207MPa; did you accidentally use 307MPa in your original model as 207/322 = 0.64 not 0.97.

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As for the differences observed when using different mesh sizes for the FEA model, they are expected ... a coarse mesh allows for a faster computation of the stresses and deflections; however, it also means that the values aren't necessarily as accurate since each node in the FEA model influences the other nodes around it.  What the coarse mesh provides is a first order approximation of the magnitude of the stresses and deflections and approximately where the critical zones are.  With this information, the critical zones of the part could be redesigned to reduce the induced stress and deflection.

Once the design is finalized, finer meshes can be utilized in the FEA model to obtain a more accurate stress and deflection -- for your design, I used four different mesh sizes from 40mm (coarse) down to 5mm (fine) and while the stress value increased from 297MPa to 334MPa that only represents a 11% increase; the deflection on the other hand increased on 1.5%.  Note that with each reduction of mesh size the 'error' between it and the finest mesh model was significantly reduced.

Unless it is critical to have the highest accuracy for these stresses and deflections due to minimal design margins, a 10% difference in stress is generally acceptable as the material properties themselves will fluctuate.

HTH

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@Anonymous wrote:

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However since the stress exceeds the yield of the steel material (~206.8 MPa), the FEA model does not reflect what would happen with the actual part under similar loading conditions.  I am curious how your FEA model indicates a Safety Factor of 0.97 Min when the material yield strength is 207MPa; did you accidentally use 307MPa in your original model as 207/322 = 0.64 not 0.97.

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As already mentioned in message no. 25, I changed the yield strenth to 330 MPa

and tensile strength: 520 MPa. I didn't use Inventor steel.

I got safety factor around 1.04 as far as I remember at that time. 

And I totally agree with you for the mesh settings. But still it doesn't solve the issue.

manish wrote:

As already mentioned in message no. 25, I changed the yield strenth to 330 MPa and tensile strength: 520 MPa. I didn't use Inventor steel.

Was that change made before you did the pictures of your analysis that you provided in message 19 or did you use a different yield strength for that analysis for the Safety Factor image seems inconsistent with either a material with 207MPa or 330MPa yield strength.  Regardless of that inconsistency, my analysis using SolidWorks provides a similar stress and displacement to yours using Inventor; the minor differences between them can be attributed to both the different modeling method of the parts and mesh size used in the analysis.

As for translating the FEA model results into a prediction of real world performance, you have to first verify that all the assumptions and parameters are valid.

1. Stresses remain within the Elastic/Linear deformation zone (i.e. below the Yield Strength of the material)

2. Material properties (i.e. Elastic Modulus and Yield Strength) used in the FEA model match the actual material

3. Loading conditions and magnitudes`

4. Part geometry

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Remember that FEA is a design tool which can highlight critical regions of stress and/or deflection; this allows the engineer to optimize the part for the particular loading conditions.  However, it cannot predict how the part will perform outside of the elastic/linear stress region nor how much additional load is required for ultimate failure.  An excellent example of this would be subjecting a uniform shape under pure tension (i.e. a tensile test), we know that, in the real world, the part will critically fail once the loading exceeds the ultimate tensile strength of the material but an FEA model would only indicate that the stress exceeds the yield strength for the majority of the component’s length.

Trying to extrapolate results beyond the limitations of the analysis technique is meaningless.  If you require knowing exactly how much load can be applied before the part critically fails (i.e. breaks), then your only alternative may be to subject a series of parts to total destruction.

HTH