Give boundary conditions of the Navier solution?
Simply supported edges —> No deflection and moment at the edge
(Assumption: Moment only with D11 & D22 because we assume that under uniaxial load, no twisting arises)
How is the buckling differential equation for a Navier solution derrived?
In the condensed plate equilibrium, load p is dropped, but additional loads due to Normal force flows in 2nd order are introduced.
Substituting Moments with deflections via the constitutive law, the buckling differential equation is created
What Ansatz is choosen to solve the buckling differential equation?
A similar approach to the Navier solution in plate analysis is used, however not as a series expansion —> Case studies must be conducted:
How is the buckling differential equation solved with the given Ansatz?
The Ansatz
is inserted into the buckling differential equation, yielding:
—> To avoid the trivial solution, the Bracket term is set to 0 yielding:
The buckling load is Nxx0 is dependent on the choosen number of halfwaves n & m, how is the lowest buckling load found?
n: appears only in the nominator —> lowest n (1) technically relevant
m: appears in the nominator and denominator —> different approaches can be utilized to finde lowest Nxx:
Extremum problem: Differentiate w.r.t. m, set to zero
Case study: Investigate until lowest load found
Graphical representation: Draw the Gierlandenkurve, utilize lower boundary (or just use first low minimum vor all plate sizes —> on the conservative side)
Give an idea, how an additional load Nyy influences the Girlandenkurve
psi (-) tensile psi (+) compressive
Give an idea, how rigid supports influence the Girlandenkurve
Give an idea, how free edges influence the Girlandenkurve
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