Stress/Strain Curve from a few values?

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To create a stress-strain curve for the weld deposit with UTS of 759 MPa and 0.2% proof strength of 598 MPa, three key points can be plotted: the elongation (EL), yield point (YP), and ultimate tensile stress (UTS). The elongation percentage can be used directly on the graph, while the yield point can be determined by plotting 598 MPa on the strain axis and drawing a line parallel to the proportional limit. The area under the curve represents strain energy density, which can be calculated using the relation u = energy/volume. The calculated energy must exceed 1.3 kJ to meet impact requirements but remain below 3.6 kJ to ensure the weld does not fail. This approach will help assess whether the weld joint is suitable for the intended application.
kieren12345
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Hi all,

I am trying to ensure that some supporting welds for a structure will meet the impact requirement of 1.3kJ.

I have the following information for the weld deposit:
UTS: 759 MPa
0.2% Proof: 598MPa
18.6% El
69.9% RofA

Is there any formulas that I can use to create a fairly accurate stress strain curve? I need the curve so that I can estimate the energy absorbtion of the material.

I cannot just over engineer this weld as with an impact of 3.6kJ the weld must break.

Any help on this matter will be greatly appreciated as this is the first time I have done anything like this.

Thanks

Kieren
 
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so u have a ductile material in ur hands. i can tell u how to find 3 points on the curve. i don't knw wat RofA means but i guess it'll help u get a more accurate shape or more points for the curve.

To draw the whole curve, u hav the EL i don't what the unit in %age means but i guess u can direcly plot it on the graph. if u can't then u can use the relation EL=stress/strain and just plot the point (1,EL).

u have 0.2% proof = 598Mpa. so u plot 0.2% point on the strain axis and draw a line parallel to the proportional line (the line from origin to the EL). u have the corresponding stress at 598Mpa and so now u have the yield point.

next u have the ultimate tensile stress, you divide it by the EL and you get the corresponding strain at that point. and then you plot the point.

so u have 3 points on the curve (EL, YP, UTS). u draw a straight line connecting the origin to the EL. i don't know how u would join the other points :(. mayb plot it in excel and see wat it shows. anyway, a straight line will give u an approximate value and can be easily calculated, area under a curve would be a pain to calculate. if u knw MATLAB then u can use tht.

now this area under the curve will be your strain energy density (u).we have the relation u= energy/volume. volume=area*length. you probably have this data from your structure. calculate the energy corresponding to the area under the graph.

now you have your impact requirement of 1.3kJ, so the energy that you had calculated earlier should be greater than this (take a suitable FOS), but less than or equal to 3.6KJ. if it isn't then u probably need a different weld joint.

correct me if m wrong, and i hope this helps. :)
 

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