Why 0.2% of strain is considered while taking proof stress?

When a material does not show a distinct yield point then 0.2% of strain is considered and a line is drawn parallel to the elastic line and the corresponding stress is called proof stress. My question is why are they taking 0.2% of strain? Is that an assumption and does it differ with materials

It is not even an assumption but somewhat arbitrarily chosen and not universally adopted either. In some codes and for some materials 0.1% is chosen and in others 0.05% and sometimes x% total strain is used rather than the x% proof stress. Also proof stress is not x% of strain, it is 0.2% remaining strain after unloading. So the 0.2% proof stress is the stress where after unloading you end up with a permanent elongation of 0.2% of your specimen.

The choice of 0.2% is a compromise between being easily measurable with simple equipment while being exact enough for most engineering purposes.

• To briefly add to this, measuring equipment generally has some non-zero mechanical slack and always has some elasticity of its own, which depending on exactly how the sample is mounted may not contribute linearly to the measured stress-strain curve. Additionally all materials have some amount of non-linear mechanical energy loss mechanism when deformed and no materials are ever perfectly elastic, which is generally reflected by a gradual decrease in stress-strain slope in the elastic regime. Since the SS curve is non-linear, a line at 0.2% is often appropriate. May 22 '16 at 13:06

The stress strain diagram of many materials is actually a curve on which there is no definite proportional limit. In such cases stress-strain proportionality is assumed to exist upto a stress at which the strain increases at a rate 50% or more than that shown by intial tangent to stress-strain diagram. If a line is drawn parallel to the intial straight line portion of stress-strain curve from 0.2% strain, it cuts the stress-strain curve at the point where strain rate increases at a rate 50% more than that shown by intial straight line. This is the concept behind chosing 0.2% proof stress as the yield stress.

Although as mentioned by others this is not universally accepted, in my opinion the reason that the 0.2% strain was used for proof stress, is that it offers a more straight forward comparison with the yield stress of steel.

Steel has been (and probably still is) the most common material for structural engineering. However, it has distinct differences from other material e.g. aluminium

Steel has a distinct yield point, that you can use to set a good safety margin before failure. Most other materials don't have that distinct characteristic. Because most design happens up to yield stress, it was common to try and find similar values for other materials.

That is why the 0.002 strain value is used. To offer a better direct comparison of materials to steel. IMHO, it is not a very efficient metric but its one of two values you usually ask when considering a material (how stiff it is and what is its strength).

• Hot worked and annealed steel has a yield point . Cold rolled or heat treated does not. Sep 18 '20 at 15:08
• Fair point. Still hot worked and anneal steel predated cold rolled or advanced heat treatments like Decarburization. My point was that the 0.2% is mainly a remnant of older times, a soft type of "technical debt". Similar to measuring the speed of boats in knots. Sep 18 '20 at 17:26

Short answer : Because 0.2 % permanent strain ( offset) is what ASTM defined as the yield strength of steel. This is a good "rule of thumb" definition for most steels , generally corresponding to a 0.5 % total strain. It is NOT the yield point ( unless by coincidence). Yield point is unique characteristic of some steels. Over 100 years ago it was used because it was easy to measure with no stress/strain graph; Also known as "drop of the beam" . I bet money I am the only one here who has seen "drop of the beam" tests conducted for material qualification. The 0.5 % total strain ( 0.2 % permanent strain) is a good number for most metals and is widely defined as the yield strength. It is a problem for high strength steels so API defines the yield strength for high strength casing as up 0.8 % total strain depending on the grade of steel.