关于等效直径和形状因子的文章
Beam elements can be a variety of shapes. For these elements to be represented in a simpler fashion for analysis, they can be converted to an equivalent circular beam. Heat transfer also needs to be considered. A Shape Factor is applied which adjusts for the additional surface area the converted beam should have.
Supported cross-sectional shapes for beam elements
The following table lists the available cross-sectional shapes and the required dimensions to define that cross-sectional shape. The figure that follows illustrates the required dimensions graphically.
Shape Required dimensions
Circular diameter (2r) see A below
Annular outer diameter (do), inner diameter (di) see B below
Half-circular diameter (2r), height (t) see C below
Rectangular width (a), height (b) see D and E below
Trapezoidal top width (b), bottom width (a), height (b) see F below
U-shape width (W), height (H), diameter (d) see G and H below
Ellipse long radii (a), short radii (b) see I below
Other Equivalent diameter, shape factor user-defined
Cross-sectional Geometry Equivalent Diameter, Based on Equivalent Cross-sectional Area Shape Factor
A
B
C
where
where
D
E
F
G
H
where
where
I
Worked example
A rectangular shaped runner has a width(a) of 5mm, and a depth(b) of 3mm.
Using the formula above, this runner could be modeled by a circular beam element with a diameter of or 5.64mm.
It would need a Shape Factor of or 1.16.
When modelling this beam element, select the Properties (Edit Properties). In the Cross-section is box select Other shape. Click Edit dimensions and enter the calculated values for Equivalent diameter(5.64) and Shape factor (1.16) in the Cross-Sectional Dimensions dialog that appears.
[ 本帖最后由 rde 于 2008-1-7 19:35 编辑 ] |
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发表于 2008-1-7 19:33:02
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