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Flexural stiffness design using Miki’s diagram

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1 Flexural stiffness design using Miki’s diagram
Flexural lamination parameters Boundaries of the domain What laminates have the same position on the Miki in-plane diagram as on the Miki flexural diagram?

2 Examples (0/90)s : 𝑧 0 =βˆ’2𝑑, 𝑧 1 =βˆ’π‘‘, 𝑧 2 =0,h=4t 0 2 Β± 45 :
𝑠 0 = 𝑑 3 βˆ’ 𝑑 3 +8 𝑑 3 =0.875, 𝑠 90 = 𝑑 𝑑 3 =0.125 π‘Š 1 βˆ— =0.875cos 0 π‘œ cos 180 π‘œ =0.75 π‘Š 3 βˆ— =0.875cos 0 π‘œ cos 360 π‘œ =1 0 2 Β± 45 :    π‘Š 1 βˆ— =0.875cos 0 π‘œ cos 90 π‘œ =0.875,    π‘Š 3 βˆ— =0.875cos 0 π‘œ cos 180 π‘œ =0.75

3 Stiffest laminate under lateral loads
Recall displacement under sine load To find stiffest laminate we need to maximize S= 𝐷 𝐷 𝐷 π‘Ž 𝑏 𝐷 π‘Ž 𝑏 4 From Table 2.1 This implies that S is a linear function of the lamination parameters, and the stiffest laminate is an angle ply. Why?

4 Example 8.2.1a Design a 16-layer 20x15” laminated graphite epoxy plate to maximize its fundamental frequency. Material properties are: 𝐸 1 =18.5,  𝐸 2 =1.89,  𝐺 12 =0.93𝑀𝑠𝑖,  𝜈 12 =0.3, 𝑑=0.005",β€‰πœŒ=0.057𝑙 𝑏 𝑖 𝑛 3 Tsai-Pagano material properties (in Msi) are π‘ˆ 1 =8.3252,  π‘ˆ 2 =8.3821,  π‘ˆ 3 =1.9643,  π‘ˆ 4 =2.5366,  π‘ˆ 5 =2.8943

5 Normalized fundamental frequency
Normalized frequency For our data For maximum frequency we want negative π‘Š 1 βˆ— and negative π‘Š 3 βˆ— , so angles near 60-deg. Why?

6 Maximization of frequency
Iso-frequency contours on Diagram. Maximum where iso-frequency line is tangent to diagram Get Text suggests Β± 𝑠 Can we do better? Should be omega21 in figure

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