modulus of elasticity = 15 Msi; poisson ratio = 0.3
modulus of rigidity = E/ ((2(1 + poisson)) = 5.8 Msi
Go to this web site: http://www.engineeringtoolbox.com/modulus-rigidity-d_946.html
It is around 40 GPa.
mujhe b nae pata
IN MACHINE design modulus of elasticity place an important role. from the value of modolus of elasticity we come to know about maximum value of load that can be to the given material upto which the material is assume to follow the hook's law.
They are classified according to their strength, rigidity, plasticity, and boiling/melting temperatures. They are classified according to their strength, rigidity, plasticity, and boiling/melting temperatures.
7,4*1010 N/m2
The Weibull Modulus is related to the distribution of flaws in a brittle specimen. It is important to note that it isn't relate to the size of the flaws. To find the Weibull Modulus, many samples of the same material are tested, in tension, to failure. If the flaws are evenly distributed throughout the specimen, the data from the the tests will show little statistical scatter and result in a high value of the Weibull Modulus. Conversely, if the flaws are unevenly distributed causing the test data to differ greatly from sample to sample (greater flaws means more opportunities for stress concentrations at those flaws, causing a lower failure stresses) then there will be large statistical scatter in the test data, and the Weibull Modulus will be measured as a lower number.
about 70 to 80 GPa
it is 14.67n/m3
there are different types of modulus it depends on what types of stress is acting on the material if its direct stress then then there is modulus of elasticity,if tis shear stress then its modulus of rigidity and when its volumetric stress it is bulk modulus and so on
Flexural Rigidity/strength and sectional modulus
G = E/2(1+u) where G = mod of rigidity and u =poisson ration and E = young modulus
http://www.engineeringtoolbox.com/modulus-rigidity-d_946.html
It is around 40 GPa.
modulus of elasticity, E, relates tension stress, s, to strain,e (s = Ee) modulus of rigidity, G, relates shear stress, t, to angular strain, g (t = Gg) modulus of rigidity G is related to E as G = E/2(1+u) whree u = poisson ratio
shearing stress to shearing strain
It is defined as ratio of the product of modulus of rigidity and polar moment of inertia to the length of the shaft. Torsional Rigidity is caluclated as: Torsional Rigidity= C J/l
It is defined as ratio of the product of modulus of rigidity and polar moment of inertia to the length of the shaft. Torsional Rigidity is caluclated as: Torsional Rigidity= C J/l
It is the ratio of shear stress to shear strain.