Build accurate layups with angle‑ply support here. Enter ply data, thickness, and orientations in minutes. See matrices instantly, then download for reports anytime easily.
| Ply | θ (deg) | t (mm) | E1 (GPa) | E2 (GPa) | G12 (GPa) | v12 |
|---|---|---|---|---|---|---|
| 1 | 0 | 0.125 | 135 | 10 | 5 | 0.30 |
| 2 | 45 | 0.125 | 135 | 10 | 5 | 0.30 |
| 3 | -45 | 0.125 | 135 | 10 | 5 | 0.30 |
| 4 | 90 | 0.125 | 135 | 10 | 5 | 0.30 |
This tool uses Classical Lamination Theory for an orthotropic lamina in plane stress. Each ply builds a reduced stiffness matrix [Q], then rotates it by angle θ to obtain the transformed stiffness [Q̄]. Finally, the laminate extensional, coupling, and bending stiffness matrices are assembled as [A], [B], and [D].
The laminate response is split into extensional stiffness [A], bending–extension coupling [B], and bending stiffness [D]. In-plane loads mainly use A, moments mainly use D, and any nonzero B signals coupling that can create curvature under in-plane loading.
Common carbon/epoxy plies often use E1 ≈ 120–180 GPa, E2 ≈ 7–15 GPa, and G12 ≈ 4–7 GPa. E-glass/epoxy frequently falls near E1 ≈ 35–50 GPa and G12 ≈ 3–6 GPa. A reasonable v12 is commonly 0.25–0.35.
A ply thickness is usually 0.10–0.25 mm for many prepregs, while thicker fabrics can exceed 0.30 mm. The A matrix scales roughly with total thickness, but the D matrix scales with thickness cubed, so doubling thickness can raise bending stiffness by about eight times.
Changing θ rotates stiffness via [Q̄]. A 0° ply strongly boosts axial stiffness in the 1-direction, while 90° improves transverse stiffness. ±45° plies are efficient for in-plane shear and torsion because they change Q̄16 and Q̄26 coupling terms that appear in the laminate matrices.
If the laminate is symmetric about the midplane, the coupling matrix ideally becomes [B] = 0 because positive and negative z contributions cancel. A nonzero B may be intentional (for bend–twist tailoring) or may indicate an unintended stacking sequence imbalance.
A balanced layup typically includes +θ and −θ plies in equal amounts. This helps reduce in-plane shear–extension coupling terms and can drive A16 and A26 closer to zero. Quasi-isotropic stacks like [0/±45/90] often give more uniform stiffness in multiple directions.
Inputs are converted internally to SI units. The output uses A in N/m, B in N, and D in N·m. If you use GPa and mm, the tool converts automatically to keep results consistent.
Check that A11 and A22 are positive and that A is symmetric. If you expect quasi-isotropy, compare A11 and A22 and keep A12 within a reasonable fraction. For symmetric layups, B should be near zero. If values look extreme, verify thickness units, confirm v12 bounds, and recheck ply angles and ordering from bottom to top.
ABD is a combined 6×6 stiffness matrix built from A (extensional), B (bending–extension coupling), and D (bending) matrices. It links midplane strains and curvatures to forces and moments.
B becomes nonzero when the stack is not symmetric about the midplane, or when ply thicknesses differ above and below. Symmetric sequences like [0/45/−45/90]s typically drive B close to zero.
Yes. Use negative angles for −θ plies in balanced layups. The sign affects transformed stiffness terms, especially Q̄16 and Q̄26, and can reduce coupling when +θ and −θ plies are paired.
Choose the unit set that matches your material sheet. If your moduli are in GPa and thickness in mm, select that option. The tool converts internally to SI and reports A in N/m, B in N, and D in N·m.
The 3×3 form follows the common (11, 22, 12) plane-stress ordering with shear as the third component. The tables show indices 1–3, where 3 corresponds to the in-plane shear term.
You can model up to 50 plies using the ply-count builder. For large stacks, keep thickness units consistent, and consider grouping identical plies to reduce entry errors and speed up validation.
A scales roughly with thickness, but D scales with thickness cubed. Small thickness changes can strongly alter bending stiffness. Always confirm ply thickness, stacking order, and whether thickness is in mm or meters.
Important Note: All the Calculators listed in this site are for educational purpose only and we do not guarentee the accuracy of results. Please do consult with other sources as well.