All 28 Chapters Covered
SOLUTIONS
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Table of contents
Part A: Fundamentals of Structural Analysis
1. Basic elasticity
2. Two-dimensional problems in elasticity
3. Torsion of solid sections
4. Virtual work and energy methods
5. Energy methods
6. Matrix methods
7. Bending of thin plates
8. Columns
9. Thin plates
10. Structural vibration
Part B: Analysis of Aircraft Structures
11. Materials
12. Structural components of aircraft
13. Airworthiness
14. Airframe loads
15. Fatigue
16. Bending of open and closed, thin-walled beams
,17. Shear of beams
18. Torsion of beams
19. Combined open and closed section beams
20. Structural idealization
21. Wing spars and box beams
22. Fuselages
23. Wings
24. Fuselage frames and wing ribs
25. Laminated composite structures
26. Closed section beams
27. Open section beams
28. Wing problems
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Solutions Manual
Solutions to Chapter 1 Problems
S.1.1
The principal stresses are given directly by Eqs (1.11) and (1.12) in which σx = 80 N/mm2, σy = 0
(or vice versa), and τxy = 45 N/mm .2 Thus, from Eq. (1.11),
80 1 pffiffiffiffiffi2ffiffiffiffiffiffiffiffiffiffiffiffiffiffi ffiffiffiffiffi2ffi
σ I = 2 + 2 80 + 4 × 45
i.e.,
σI = 100.2 N/mm2
From Eq. (1.12),
80 1 pffi ffiffi ffiffi2ffiffiffi ffiffiffiffiffiffiffiffiffiffiffi ffiffi ffiffiffi2ffi
σ II = — 80 + 4 × 4 5
2 2
i.e.,
σII = —20.2 N/mm2
The directions of the principal stresses are defined by the angle θ in Fig. 1.8(b) in which θ is given by
Eq. (1.10). Hence,
2 × 45
tan 2θ 1.125
= =
80 — 0
which gives
θ = 24°11' and θ = 114°11'
It is clear from the derivation of Eqs (1.11) and (1.12) that the first value of θ corresponds to σI while the
second value corresponds to σII.
Finally, the maximum shear stress is obtained from either of Eqs (1.14) or (1.15). Hence from
Eq. (1.15),
100.2 — (—20.2) 2
τmax = 2 = 60.2 N/mm
and will act on planes at 45° to the principal planes.
S.1.2
The principal stresses are given directly by Eqs (1.11) and (1.12) in which σx = 50 N/mm2,
σy =–35 N/mm2, and τxy = 40 N/mm2. Thus, from Eq. (1.11),
3
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qffi ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi ffiffiffiffiffi ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
50 — 35 1
σ I= + (5 0 + 3 5) 2 + 4 × 4 0 2
2 2
i.e.,
σI = 65.9 N/mm2
and from Eq. (1.12),
qffi ffiffiffiffi ffiffiffiffiffiffiffi ffiffiffiffi ffiffiffiffiffi ffiffiffiffiffiffiffiffiffiffiffiffiffi ffiffiffi ffi
50 — 35 1
σ II= — (5 0 + 3 5) 2 + 4 × 40 2
2 2
i.e.,
σII = —50.9 N/mm2
From Fig. 1.8(b) and Eq. (1.10),
2 × 40
tan 2θ 0.941
= 50 + 35 =
which gives
θ = 21°38'(σI) and θ = 111°38'(σII)
The planes on which there is no direct stress may be found by considering the triangular element of unit
thickness shown in Fig. S.1.2 where the plane AC represents the plane on which there is no direct stress.
For equilibrium of the element in a direction perpendicular to AC,
0 = 50ABcos α — 35BCsin α + 40ABsin α + 40BCcos α (i)
Dividing through Eq. (i) by AB,
0 = 50 cos α — 35 tan α sin α + 40 sin α + 40 tan α cos α
which, dividing through by cos α, simplifies to
0 = 50 — 35 tan 2α + 80 tan α
FIG. S.1.2
, Solutions to Chapter 1 Problems 5
from which
tan α = 2.797 or — 0.511
Hence,
α = 70°21' or — 27°5'
S.1.3
The construction of Mohr’s circle for each stress combination follows the procedure described in
Section 1.8 and is shown in Figs S.1.3(a)–(d).
FIG. S.1.3(a)
FIG. S.1.3(b)
FIG. S.1.3(c)
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FIG. S.1.3(d)
S.1.4
The principal stresses at the point are determined, as indicated in the question, by transforming each
state of stress into a σx, σy, τxy stress system. Clearly, in the first case, σ=x 0, σ=
y 10 N/mm , τxy= 0
2
(Fig. S.1.4(a)). The two remaining cases are transformed by considering the equilibrium of the trian-
gular element ABC in Figs S.1.4(b), (c), (e), and (f). Thus, using the method described in Section 1.6
and the principle of superposition (see Section 5.9), the second stress system of Figs S.1.4(b) and (c)
becomes the σx, σy, τxy system shown in Fig. S.1.4(d) while the third stress system of Figs S.1.4(e) and
(f) transforms into the σx, σy, τxy system of Fig. S.1.4(g).
Finally, the states of stress shown in Figs S.1.4(a), (d), and (g) are superimposed to give the state of
stress shown in Fig. S.1.4(h) from which it can be seen that σI =σII =15 N/mm2 and that the x and
y planes are principal planes.
FIG. S.1.4(a)
, Solutions to Chapter 1 Problems 7
FIG. S.1.4(b)
FIG. S.1.4(c)
FIG. S.1.4(d)
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FIG. S.1.4(e)
FIG. S.1.4(f)
FIG. S.1.4(g)
, Solutions to Chapter 1 Problems 9
FIG. S.1.4(h)
FIG. S.1.5
S.1.5
The geometry of Mohr’s circle of stress is shown in Fig. S.1.5 in which the circle is constructed using
the method described in Section 1.8.
From Fig. S.1.5,
σx = OP1 = OB —BC + CP1 (i)
In Eq. (i) OB =σ I, BC is the radius of the circle that is equal to τ max
and CP1 =
qffi ffiffiffi ffiffiffi ffiffiffiffiffiffiffi ffiffiffiffiffiffiffiffi ffi qffi ffiffi ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
C Q 12 — Q 1 P12 = max τ2 — τxy2 . Hence,
qffi ffi ffi ffi ffi ffi ffi ffi ffi ffi ffiffiffiffi ffiffi ffiffiffi
σx = σ1 — τmax + τ 2 max
— τxy 2
Similarly,
σy = OP2 = OB — BC — CP2 in which CP2 = CP1
Thus, qffi ffiffi ffiffi ffiffi ffi ffiffi ffiffiffiffi ffiffi ffiffiffi
σy = σI — τmax — τ 2 — τ xy2
max
SOLUTIONS
, @LECTSOLUTIONSSTUVIA
Table of contents
Part A: Fundamentals of Structural Analysis
1. Basic elasticity
2. Two-dimensional problems in elasticity
3. Torsion of solid sections
4. Virtual work and energy methods
5. Energy methods
6. Matrix methods
7. Bending of thin plates
8. Columns
9. Thin plates
10. Structural vibration
Part B: Analysis of Aircraft Structures
11. Materials
12. Structural components of aircraft
13. Airworthiness
14. Airframe loads
15. Fatigue
16. Bending of open and closed, thin-walled beams
,17. Shear of beams
18. Torsion of beams
19. Combined open and closed section beams
20. Structural idealization
21. Wing spars and box beams
22. Fuselages
23. Wings
24. Fuselage frames and wing ribs
25. Laminated composite structures
26. Closed section beams
27. Open section beams
28. Wing problems
, @LECTSOLUTIONSSTUVIA
Solutions Manual
Solutions to Chapter 1 Problems
S.1.1
The principal stresses are given directly by Eqs (1.11) and (1.12) in which σx = 80 N/mm2, σy = 0
(or vice versa), and τxy = 45 N/mm .2 Thus, from Eq. (1.11),
80 1 pffiffiffiffiffi2ffiffiffiffiffiffiffiffiffiffiffiffiffiffi ffiffiffiffiffi2ffi
σ I = 2 + 2 80 + 4 × 45
i.e.,
σI = 100.2 N/mm2
From Eq. (1.12),
80 1 pffi ffiffi ffiffi2ffiffiffi ffiffiffiffiffiffiffiffiffiffiffi ffiffi ffiffiffi2ffi
σ II = — 80 + 4 × 4 5
2 2
i.e.,
σII = —20.2 N/mm2
The directions of the principal stresses are defined by the angle θ in Fig. 1.8(b) in which θ is given by
Eq. (1.10). Hence,
2 × 45
tan 2θ 1.125
= =
80 — 0
which gives
θ = 24°11' and θ = 114°11'
It is clear from the derivation of Eqs (1.11) and (1.12) that the first value of θ corresponds to σI while the
second value corresponds to σII.
Finally, the maximum shear stress is obtained from either of Eqs (1.14) or (1.15). Hence from
Eq. (1.15),
100.2 — (—20.2) 2
τmax = 2 = 60.2 N/mm
and will act on planes at 45° to the principal planes.
S.1.2
The principal stresses are given directly by Eqs (1.11) and (1.12) in which σx = 50 N/mm2,
σy =–35 N/mm2, and τxy = 40 N/mm2. Thus, from Eq. (1.11),
3
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qffi ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi ffiffiffiffiffi ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
50 — 35 1
σ I= + (5 0 + 3 5) 2 + 4 × 4 0 2
2 2
i.e.,
σI = 65.9 N/mm2
and from Eq. (1.12),
qffi ffiffiffiffi ffiffiffiffiffiffiffi ffiffiffiffi ffiffiffiffiffi ffiffiffiffiffiffiffiffiffiffiffiffiffi ffiffiffi ffi
50 — 35 1
σ II= — (5 0 + 3 5) 2 + 4 × 40 2
2 2
i.e.,
σII = —50.9 N/mm2
From Fig. 1.8(b) and Eq. (1.10),
2 × 40
tan 2θ 0.941
= 50 + 35 =
which gives
θ = 21°38'(σI) and θ = 111°38'(σII)
The planes on which there is no direct stress may be found by considering the triangular element of unit
thickness shown in Fig. S.1.2 where the plane AC represents the plane on which there is no direct stress.
For equilibrium of the element in a direction perpendicular to AC,
0 = 50ABcos α — 35BCsin α + 40ABsin α + 40BCcos α (i)
Dividing through Eq. (i) by AB,
0 = 50 cos α — 35 tan α sin α + 40 sin α + 40 tan α cos α
which, dividing through by cos α, simplifies to
0 = 50 — 35 tan 2α + 80 tan α
FIG. S.1.2
, Solutions to Chapter 1 Problems 5
from which
tan α = 2.797 or — 0.511
Hence,
α = 70°21' or — 27°5'
S.1.3
The construction of Mohr’s circle for each stress combination follows the procedure described in
Section 1.8 and is shown in Figs S.1.3(a)–(d).
FIG. S.1.3(a)
FIG. S.1.3(b)
FIG. S.1.3(c)
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FIG. S.1.3(d)
S.1.4
The principal stresses at the point are determined, as indicated in the question, by transforming each
state of stress into a σx, σy, τxy stress system. Clearly, in the first case, σ=x 0, σ=
y 10 N/mm , τxy= 0
2
(Fig. S.1.4(a)). The two remaining cases are transformed by considering the equilibrium of the trian-
gular element ABC in Figs S.1.4(b), (c), (e), and (f). Thus, using the method described in Section 1.6
and the principle of superposition (see Section 5.9), the second stress system of Figs S.1.4(b) and (c)
becomes the σx, σy, τxy system shown in Fig. S.1.4(d) while the third stress system of Figs S.1.4(e) and
(f) transforms into the σx, σy, τxy system of Fig. S.1.4(g).
Finally, the states of stress shown in Figs S.1.4(a), (d), and (g) are superimposed to give the state of
stress shown in Fig. S.1.4(h) from which it can be seen that σI =σII =15 N/mm2 and that the x and
y planes are principal planes.
FIG. S.1.4(a)
, Solutions to Chapter 1 Problems 7
FIG. S.1.4(b)
FIG. S.1.4(c)
FIG. S.1.4(d)
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FIG. S.1.4(e)
FIG. S.1.4(f)
FIG. S.1.4(g)
, Solutions to Chapter 1 Problems 9
FIG. S.1.4(h)
FIG. S.1.5
S.1.5
The geometry of Mohr’s circle of stress is shown in Fig. S.1.5 in which the circle is constructed using
the method described in Section 1.8.
From Fig. S.1.5,
σx = OP1 = OB —BC + CP1 (i)
In Eq. (i) OB =σ I, BC is the radius of the circle that is equal to τ max
and CP1 =
qffi ffiffiffi ffiffiffi ffiffiffiffiffiffiffi ffiffiffiffiffiffiffiffi ffi qffi ffiffi ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
C Q 12 — Q 1 P12 = max τ2 — τxy2 . Hence,
qffi ffi ffi ffi ffi ffi ffi ffi ffi ffi ffiffiffiffi ffiffi ffiffiffi
σx = σ1 — τmax + τ 2 max
— τxy 2
Similarly,
σy = OP2 = OB — BC — CP2 in which CP2 = CP1
Thus, qffi ffiffi ffiffi ffiffi ffi ffiffi ffiffiffiffi ffiffi ffiffiffi
σy = σI — τmax — τ 2 — τ xy2
max
