Why do tensile testing graphs show a negative slope at these regions?

In summary: However, for the most part, materials will go through a range of deformation (elastic-plastic-elastic) before reaching the ultimate limit.
  • #1
gikiian
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Do tensile testing machines reduce the value of load in these regions? If yes, why? If no, what's happening in the graph?
 

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  • #2
Most of the time, the plots show engineering stress. You input the cross sectional area, A, of the specimen, and the machine will give you a plot of Force/(A)const for every incremental displacement. In reality, "A" is changing (decreasing, in a tensile test), rather than remaining constant. If you were to plot the "true stress" - Force/(A)actual, the stress should always increase.
 
  • #3
These are regions of dynamic elongation in which the transferred force level is falling even as the specimen continues to elongate. If this continues very far (as is the case at the right end), rupture occurs.

These are really scaled force plotted against scaled elongation curves. With convenient scaling, we can think of them as stress - strain curves, but in the dynamic regions, this is not strictly true.
 
  • #4
It's an issue of lateral contraction and whether or not it is being considered.

As OldEngr63 states, engineering stress vs. strain is just a scaled version of force vs. deformation. Either way, you'd get a plot that looks like the one the TS posted.

As I said before, however, true stress vs. strain would NOT look like the plot that the TS posted.
 
  • #5
gikiian said:
Do tensile testing machines reduce the value of load in these regions? If yes, why? If no, what's happening in the graph?

If you are asking what is happening to the sample, the graph shows the elastic and plastic deformatiom. As the stress is increased the material deforms elastically, which is the straight line region. At a value of stress the material begins to deform plastically and the material begins to neck down at the same or less level of stress. While this material is deforming plastically it is also work hardening, until the point in the graph where the curve swings upwards again ( workhardening has made the material stronger ). As you progress along the curve, more stress results in more plastic deformation, and more work hardening, until the ultimate tesile stress is reached, after which the specimen necks down and rupture occurs.

The curve appears to be that for some sort of soft metal, possibly a mild steel. Not all materials exhibit the same pattern in their stress strain curve - a brittle material shows a curve decisively different from that of a ductile materail.
 
Last edited:

1. Why do tensile testing graphs show a negative slope at the yield point?

The negative slope at the yield point on a tensile testing graph is due to the material undergoing plastic deformation. This means that the material has reached its maximum stress and is starting to permanently deform, causing the graph to show a decrease in stress while strain continues to increase.

2. What causes the negative slope at the necking region on a tensile testing graph?

The negative slope at the necking region is caused by the material undergoing significant deformation and becoming thinner at that point. This results in a decrease in cross-sectional area and an increase in strain, leading to a negative slope on the graph.

3. Why is the negative slope at the fracture point steeper than the rest of the graph?

The steeper negative slope at the fracture point is due to the material rapidly losing strength and undergoing significant deformation before ultimately breaking. This results in a more drastic decrease in stress and a steeper slope on the graph.

4. How does the type of material affect the negative slope on a tensile testing graph?

The type of material can greatly affect the negative slope on a tensile testing graph. Materials with higher ductility, such as metals, will have a more gradual decrease in stress and a shallower negative slope, while materials with lower ductility, such as ceramics, will have a more drastic decrease in stress and a steeper negative slope.

5. What other factors can influence the negative slope on a tensile testing graph?

Aside from the type of material, other factors that can influence the negative slope on a tensile testing graph include the temperature, rate of loading, and presence of impurities or defects in the material. These factors can affect the behavior of the material and alter the shape of the graph, including the negative slope regions.

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