D H said:For a given diameter, a solid tube is stronger than a hollow one. For a given mass, its the other way around. The extra mass in the middle doesn't add a whole lot of integrity, but it does add a whole lot of mass.
Where did you get the idea that hexagonal tubing is stronger? Failures typically happen at edges; a circle doesn't have any.
handsomecat said:At the corners of the hexagon, you will have stress concentration. Hence the remark above that "Failures typically happen at edges".
What kind of problem are you doing with FEA? Beam-bending?
If it is beam-bending then usually the explanation is that one cross-section has higher moment of inertia (I), since the denominator for the deflection is always EI.
OutCell said:The problem is a roll cage roll over simulation.. I have a cage (2- in circular and hexagonal tube structure), then i applied equal force on them (Basically same boundary conditions).
TVP45 said:OK, that's a common way people do it. So, looking at that, can you make comparisons of: mass/unit length, moment of inertia, etc and draw any conclusion? When you say the hexagonal is stronger, what do you mean by stronger? What is your design intent?
I am sorry, you are right. it was between edgestmoan said:a hexagonal equivalent to the circular should have a diameter of 10 between edges not sides if that's the diameter of the cylinder
tmoan said:so you have to apply the forces on the edges you should find that circular is stronger.the hexagon could be stronger if it is on the sides, but when you are testing for strength then you are accessing failure measurements to do that you must obtain minimum force to collapse.(on the edges)
that is why circular is stronger because it has no edges and therefore no weak points
I'm F***ed, this is my final year project ..tmoan said:that is why i mentioned failure because in the roll over test the tubing is hit on all sides.and all the edges.
OutCell said:I'm F***ed, this is my final year project ..
rocketboy said:not at all, this gives you something new to write about... your prof will be impressed, more so than if you hadn't asked the question in the first place! Showing an analysis with both edges and corners and talking about the stress concentrations that arise in corners will likely strengthen the report.
OutCell said:I'm F***ed, this is my final year project ..
TVP45 said:I don't know your time limit, but you should be able to salvage something from this. There is value in incorrect solutions if you know what is incorrect. In the case of a roll bar, you might look at actual requirements (NHRA, for example). You would see that weight is critical for race cars. You might also run into the design requirement that force directions in crashes can never be predicted. You might look at the nodes (which are absolutely critical) and ask how difficult it is to weld them for various shapes. Finally, consider the ease of cold drawing round tubing (with the attendant increase in strength). Do a comparison between round and hex. You're not nearly the first engineering student to do this sort of thing; you may get a bad grade but you're not going to get traded to the Performing Arts Department. Show that you've learned from it!
Finally, how did the FEA not show stress in the corners? Look at your restraints. Be critical of your test report. Your prof knows all this stuff, but remember this is education - show him you've been able to learn from your mistakes.
OutCell said:So what can you say about this picture? In relation to strength
http://i169.photobucket.com/albums/u233/OutCell/ERW-3viewtubing.jpg
First thanks for your continuous replies, i really appreciate it.TVP45 said:It's a little hard to see. What are the weights of the hex and square relative to the round? Is your mesh small enough to show edges? It looks like you fixed the ends and loaded the middle downward? If so, the square shows some obvious weld problems (assuming the model is realistic).
OutCell said:First thanks for your continuous replies, i really appreciate it.
I used the same material for all. I tried to make the circular, hexagonal and square the same size and length. Restrained the ends and applied same load to all.
If i wanted to compare strength using this picture (Just assuming), which would be the strongest?
My presumption was that the bigger the von mises stress figure, means the stronger the shape is..
TVP45 said:This thing has bounced my answer twice already. Hope this goes through.
It's hard to see all the detail I'd like, but it looks like the hexagonal has the highest stress. Stress is bad. Stress leads to failure. The square tubing looks like it has the lowest stress, but what it does have is right there where your welds are going to have to be. That's a problem. I'm also betting the square tubing is the heaviest of the 3.
if I were doing the FEA, I would have set the three Von Mises scales up to be the same. That way, I'd get a quick color confirmation (love to see blue! hate to see red!). I would also set up a factor of safety calculation for calculated stress divided into maximum design stress. I would also, if I had CPU time, have run a parametric optimization for number of sides from 4 to say 12, looking for just that barely acceptable factor of safety and looking for minimum weight. I'd bet I'd get 12 which is just a round tube. Again, depending on time, I might have put a more realistic node in there and run that to see what kind of weld problems I might have; my gut tells me I'll need gussets.
OutCell said:Thanks again, really..
I wish i knew all of this in the beginning of the year when i was starting the report. I already did everything and I am on the discussion part of the report which has to be handed in by next week, and find out all what i did so far was wrong! I am dead and stupid of course..
I had 5 designs. I analyzed the 1st design with circular, hexagonal and square tubing with different material. I choose the structure with highest von mises thinking it would be the strongest, then i continued with that choosen structure (Hexagonal) with the rest of the 4 designs..
And now i am in the discussion and find out that all that was wrong.. I don't think there is time to fix anything now :(:(
TVP45 said:Nah, you're not dead. Part of engineering is learning to think on your feet, so put the best spin on this you can and take your lumps. I've found the best way to deal with mistakes in engineering is: 1) never apologize; 2) always fix them if you can; 3) don't repeat them. Crikey, I worked with the engineer who designed the "Fremont Flyer" and he survived (that's the infamous subway train that was supposed to come to a smooth stop in front of a gaggle of government officials standing at the end of the line. Instead it came smartly past them about 30 mph and on into the parking lot. Truly an "Oh Crap!" moment)
Hollow tubes have a void space in their center, while solid tubes do not. This difference in structure can affect the overall strength and weight of the tube.
The hexagonal shape allows for a more efficient distribution of weight and stress throughout the tube, making it stronger than traditional round or square shapes.
Yes, studies have shown that hexagonal tubes have a higher strength-to-weight ratio compared to traditional round or square tubes. This means they can withstand more stress and weight while still being lightweight themselves.
In addition to their strength advantage, hexagonal tubes also have better torsional resistance and are less likely to buckle under pressure. They also have a more aesthetically pleasing appearance compared to traditional tube shapes.
The findings can be used to inform the design and construction of various structures, such as bridges, buildings, and aircraft, to make them stronger and more efficient. They can also be applied in the manufacturing of various products, such as sports equipment and automotive parts.