轴压圆柱壳的屈曲特性英文文献和中文翻译(2)

2。Background: buckling of axially compressed cylinders

2。1。Theoretical background

The failure/buckling behavior of cylindrical shell is mainly characterized by the radius-to-thickness ratio of the shell。 Thin- shell cylinder usually buckles elastically, so failure by buckling

controls the design criterion。 Whilst, thick cylinder fails in the elastic–plastic range, so failure is govern by collapse。 If a cylinder is subjected to uniform axial compression, the following buckling

Table 1Set of material data obtained from uni-axial tensile tests on mild steel plate (E ¼ young's modulus, UTS¼ ultimate tensile strength)。 Note: The upper yield for

0。5 mm thickness specimen was taken from 0。2% proof stress。

modes can be experienced: (i) axisymmetric mode, where the

cylinder develops a corrugated appearance, with waves only in the axial direction, (ii) asymmetric mode, where the cylinder develops inward and outward displacement of the shell wall with several full waves around the circumference, and usually several waves up the height (note that the number of waves falls progressively as the shell becomes thicker), and (iii) symmetric mode, where the cylinder forms a single bulge around the circumference。

The classical buckling analysis of cylinder is based on the hy- pothesis of membrane pre-buckling state, i。e。, bending stresses are neglected, and of Donnell shallow shell theory。 From the above hypothesis, the classical elastic critical buckling load for axially

compressed cylinder with axisymmetric mode is given by:

and at the other end, the cylinder is only allowed to move in the

axial direction。 Fig。 1b shows the photograph of the experimental set up of the cylinder, taking a close look at the top edge after spring-back/unloading。 The cylinder is assumed to be made from

However, for relatively thick cylinder that fails within the plastic region, the reference buckling load, Fref, is taken as the load required to cause the cylinder to yield and it is designed according to Ref。 [15] as Eq。 (2):

mild steel with the material properties shown in Table 1。

The specimens were modeled using four-node three-dimen- sional doubly curved shell elements with six degree of freedom (S4R)。 The material is modeled as elastic perfectly-plastic。 Non-

ﬁed Riks

Fref = πDtσyp

whereFcyl is the cylinder classical elastic critical buckling load

linear static analysis was carried out using the modi

method algorithm which is implemented in ABAQUS。

Fref is the cylinder reference buckling load required to cause

yieldE is the Young's Modulus of the material

syp is the yield stress of the material

ѵ is the Poisson's ratio of the material

D is the diameter of the cylinder

t is the wall thickness of the cylinder

2。2。Modeling details

Consider a circular cylinder with diameter, D, radius, R and uniform wall thickness, t, having an axial length, L, as sketched in Fig。 1a。 It is assumed that the cylinder is subjected to axial com- pression。 The cylinder is assumed to be fully clamped at one end,

3。

Experimentation

3。1。Cylinder geometry and material properties

For this experiment, ﬁve mild steel cylinders with three dif- ferent thickness (t ¼ 0。5, 1。0, 2。0 mm) as shown in Fig。 2, were tested。 All cylinders were assumed to have nominal diameter, D ¼ 100 mm。 The axial lengths for all cylinders were kept at 轴压圆柱壳的屈曲特性英文文献和中文翻译(2):http://www.youerw.com/fanyi/lunwen_97826.html