Mechanics of solids by crandall,dahl,lardner, 2nd chapter
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Transcript of Mechanics of solids by crandall,dahl,lardner, 2nd chapter
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Chapter 2
Introduction to Mechanics of deformable bodies
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Analysis of deformable bodies
1. Identification of a system2. Simplification of this system3. To develop model which can be analyzed
Steps to analysis System
1. Study of forces and equilibrium requirements2. Study of deformation and conditions of
geometric fit3. Application of force- deformation relations
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Example:A machine part carrying a load F terminates in a piston which fits into a cavity, as shown in Fig. Within the cavity are two springs arranged coaxial with each other. Each spring has the characteristic that the force required to deflect it is proportional to the amount of deflection. Such a spring is said to have a linear force-deflection relation, and the amount of force required to produce a unit deflection is called the spring constant ofthe spring. We use the symbols kA and kB to denote the spring constants of the two springs in the cavity. When the springs are unloaded, each has the same length L. We wish to know how much of the load F is carried by the spring with constant kA
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SolutionSteps to analyze the system
1. Selection of model of the actual system
2. Assumptions
3. Study of forces and equilibrium requirements
4. Study of deformation and conditions of geometric fit
5. Application of force- deformation relations to predict behavior of the system
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1. Selection of model
a)Identify the elements of proposed model of the system.
In given problem the system has two elements one Piston and two springs
2. Assumptions
a)Assumed that the springs have been made with flat ends such that the compressing force which is distributed around the periphery of the spring, can be considered to act along the spring axis
b)Assumed that gravity effects can be ignored
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3. Study of forces and equilibrium requirements
a)Isolate the elements from its surrounding i.e. Draw free body diagram
b)Apply equations of equilibrium
i. e.
∑∑
=
=
0
0
M
F
c) Springs fit in the cavity perfectly without bending
d) Linear springs
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Free body Diagram
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Piston
0
00
=∑
=−+=∑=∑
M
FFFFF
BAy
i.e.
, as all forces FA, FB, Fare acting along the same line of action
00=∑=∑
MF
SpringsEqual and opposite forces act at the ends of each spring along the line of action
&
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4. Study of deformation and conditions of geometric fit
Find what are the requirements for geometric compatibility
δδδ == BA
5. Application of force- deformation relations
Force deflection relation in given ProblemThe force in each spring is linearly proportional to the deflection of the spring, and the constant of proportionality is the spring constant
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BBB
AAA
kFkFδδ
==
By combining above equations we obtain desire result
;BA
AA
KKK
FF
==
Total deflection of the piston
BAA
A
KKF
KF
+==δ
B
B
kF
kK
==
BA
BB
kkk
FF
+=
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Example:Let us consider a very light and stiff wood plank of length 2L. Two similar springs (spring constant k) are attached to it. The springs are of length h when the plank is resting on them.
Let a man stands on middle of plank and begins to walk slowly towards one end. Find how far the man can walk before one end of the plank touches the ground
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Solution1. Force equilibrium : Free body diagram
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0)(20
00
=+−=∑
=−+=∑
WbaaFM
WFFF
D
DCi. e.
i. e.
&
------ 1
--- 2
Reaction at point E will be zero since the plank is just touching the ground
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2. Study of Geometry of deformation and requirements of geometric compatibility
Both springs can be considered two force members as shown in fig (d)
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From fig (d) following relations can be deduced
aLaL
hh
D
C
−+
=
DD
CC
hhhh
−=−=
δδ
--------- 3
} ---------- 4
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3. Relation between forces and deflectionsAssuming same spring constant and linear spring
DD
CC
kFkFδδ
==
} ---------- 5
Equation 1 to 5 will give seven independent relations for seven unknowns
bhhFF DCDCDC &,,,,, δδ
Known: a, L, h, k, W
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]12[2
−=WKh
Lab
)1(2
)1(2
ab
kW
ab
kW
D
C
+=
−=
δ
δ
--------- 6
Spring deflections
} ---------- 7
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It can be seen that is always positive in the sense defined in Fig. d. is positive as long as b < a. When b = a, the man is directly over the spring D, and, as would be expected, all the load is taken by the spring D, and the deflection and force in the spring C are zero. When b > a, then is negative (i.e., the spring extends). In Fig. C we assumed that b > a and that the spring C is compressed.
DδCδ
Cδ
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If after making these assumptions in a particular case the result from equation 6 was b > a, then we would find from algebra that both and FC were negative. These negative results would be interpreted to mean that the actual and FC were in directions opposite to those defined as positive in Fig. D
Cδ
Cδ
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Equation 6 could be written in following nondimensional form
)12
()( 2 −=k
Wh
La
Lb
------- 8
Let’s see the basic nondimensional ratios of the problem. It is always good practice in any engineering problem to consider the physical meaning of the nondimensional quantities which appear in the problem.
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The ratio (W/2k) / h is the ratio of the deflection of the springs to the original length of the springs when b = 0, that is, when the man is standing midway between the springs.If this ratio is small, then b/ L might exceed unity and our analysis does not apply. If this ratio is near 1, i.e., if the springs are soft, then b/ L is near zero.
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Another question of interest is the effect of different spring constants on the value of b. We expect that the result for b/ L will depend on the ratios a/ L, W/ 2kC h, and on the ratio of the spring constants, for example,
γ = kC / kD
The result for b/ L is
--- 9)1)(1(211
2[
)/1)(1(211
)( 2
aL
Whk
LaL
a
Lb C +−+−
+−−= γ
γ
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Equation 9 is a surprisingly complicated function of the ratio of the spring constants. Note that equation 9 reduces to equation 8 when
γ =1
i.e. kC = kD = k
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ExampleA light rigid bar ABC is supported by three springs, as shown in fig a. Before the load P is applied, the bar is horizontal. The distance from the centre spring to the point of application of P is , where is a dimensionless parameter which can vary between
and . The problem is to determine the deflections in the three springs as functions of the load position parameter . We shall obtain general solution for arbitrary values of the spring constants and display the results for the particular set kA= (1/2) k, kB= k, kC= (3/2) k.
aλ λ
1−=λ 1=λ
λ
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Solution1. Study of forces and equilibrium requirements
a. First draw the free body diagram for springs and bar
b. Total unknown parameters are three and equilibrium equations are two. This is statically indeterminate situation
c. Express two of these parameters in term of remaining one parameter
}-- 1
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2. Study of geometric compatibility requirementsa. After application of load the spring should be
remain connected to the bar. The bar is rigid one so points A, B, and C remain collinear after application of load which will yield
3. Relations between forces and deformations
)(21
CA δδδ +−B ------ 2
-3--- } , , C
CC
B
BB
A
AA k
FkF
kF
=== δδδ
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Equation 1, 2, and 3 are three equations for six unknown deflections at point A, B and C and three
unknown forces FA, FB and FC can be obtained. In general
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Remarks1. Each deflection is linear to 2. For each position of the load the middle
deflection at B is always midway between the end deflections A and C
3. When the load is near one end, the deflection at other end is negative
4. When the load is at the position indicated by in fig. (d) all three spring deflections are equal
λ
0λ
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5. The line marked A in fig. (d) represents the deflection . It also represents the actual position of the bar when the load is applied at point A.
6. When load is at point A the deflection at three spring locations are given by the ordinate of three lines at
7. If ordinate is transferred to the location of point B i. e. and is transferred to the location of point C i. e. , the transferred ordinates lie precisely on the line marked at A
1−=λ
)(λδ A
)1(−Bδ0=λ )1(−Cδ
1=λ
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8. The line marked B and C in fig. (d) also have this same reciprocal property.
9. The position marked is the one point on the bar whose deflection is independent of the load location. It acts as a pivot point for the bar
Pivot location is given by
And the invariant deflection at this location is
0λ
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UNIAXIAL LOADING & DEFORMATION
The basic type of deformation which will be considered in most of the problem situations in this chapter is shown in Fig. (a). A bar is loaded by two forces, and we are interested in the relative motion of the points of application of the two forces. Consider the deformation of three rods of identical material, but having different lengths and cross-sectional areas as shown. Assume that for each bar the load is gradually increased from zero, and at several values of the load a measurement is made of the elongation .
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If the maximum elongation is very small (say, not greater than 0.1 percent of the original length), then for most materials the results of the three tests will be represented by a plot like Fig. (b) or like Fig. (c). The relative positions of the three curves in each plot are what we would expect from the experience we have had with easily deformable bodies such as rubber bands.
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If the experimental data are replotted with load over area as ordinate and elongation over original length as abscissa, the test results for the three bars can be represented by a single curve, as shown in Fig. d or e. The fact that this replotting brings all the data from different test specimens into common agreement greatly simplifies the problem of determining the load-deformation behavior of' materials. Thus, to obtain the uniaxial load-elongation characteristics of a particular material, we can test a single specimen and present the results as a plot of P/A against /L, as illustrated in Fig. (d) & (e)
δ
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If the uniaxial load-elongation relation of the material is linear, then this relation can be expressed by giving the slope of the straight line in Fig. (d). This slope is called the modulus of elasticity and usually is denoted by the symbol E.
Typical values of E for a few materials are given in Table 2.1 ; for example, for steel, E is approximately 205 GN/m2.
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Deflection can be given in terms of E
The above equation is simple form of Hook’s law, so named after Robert Hooke who was the first to record that many materials have ,a linear relation between load and deformation. When the load-deflection curve is linear, a solid bar subjected to end loads acts in same manner as the linear spring. If spring made of steel 10000 sq. meter in area and 1m long, the spring constant would be
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If the material is nonlinear, then it will not be possible to represent the uniaxial load- elongation relation by a single constant; in fact, it will be necessary to specify this relation by an actual curve.
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Statically determinate situations
These are the situations in which the forces can be obtained without reference to the geometry of deformation
Example
Fig. shows a triangular frame supporting a load of 20 kN. Our aim is to estimate the displacement at the point D due to the 20 kN load carried by the chain hoist.
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Solution
1. Select the model:
Draw free body diagram
2. Assumptions:
Joint C is treated as a frictionless pinned joint3. Force equilibrium:
The forces in the members were determined in Example 1.3. These are shown in the free-body sketch of Fig. 2.7b.
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4. FORCE.DEFORMATION RELATIONSEquation (2.2) gives the deformations of the members OD and CD due to the forces acting on the ends of the members. These deformations are
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5. GEOMETRIC COMPATIBILITYGeometric compatibility of the deformations requires that the bars BD and CD move in such a way that, while the bars change lengths by the amounts calculated above, they remain straight and also remain fastened together at D.The mechanism by which this can be accomplished is illustrated in Fig. 2.7c. Assume, for the moment that the bars are uncoupled at D and allowed to change lengths by and so that the bars now are of lengths BD1 and CD2, respectively. We see from the sketch that we can bring the ends D1 and D2 into coincidence without further change in the lengths of the bars by rotating the bars BD1 and CD2 about B and C as centers. Thus, due to the action of the 20-kN load, the point D moves to D3, and the deformed shape of the structure is as shown in the dotted position in Fig. 2.7c.
BDδCDδ
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Locating the point D3 at the intersection of the two arcs in Fig. 2.7c is a rather lengthy calculation. Fortunately, since the deformations of the bars are only very small fractions of the lengths (these deformations are exaggerated greatly in Fig. 2.7), we can, with great accuracy, replace the arcs by the tangents to the arcs at D1 and D2 and obtain the intersection D4 as an approximation to the location of D3. Because of its simplicity and accuracy, this approximation is used in practically all engineering calculations of deflections of structures.Employing this approximation of replacing the arcs with tangents, we illustrate in Fig. 2.7d the calculation of the horizontal and vertical displacements by which the point D moves to D4. We begin by laying off and to locate the points D1 and D2.
BDδ CDδ
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At D1 and D2 we erect the perpendiculars (tangents) D1G and D2F; these perpendiculars intersect in the desired point D4. From the geometry of Fig. 2.7d we then can write
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We thus have accomplished our objective of making an estimate of the displacement of the point D of the frame in Fig. 2.6.
In analyzing a deformable structure according to the steps (2.1), the equilibrium requirements of the first step should be satisfied in the deformed equilibrium configuration. In most engineering applications the deformations are so small that it is sufficiently accurate to apply the equilibrium requirements to the undeformed configuration. As an example of this approximation the forces in Fig. 2.7b were obtained by applying the equilibrium requirements to the undeformed frame. If the equilibrium requirements are applied to the deformed shape of Fig. 2.7d, the forces in the bars are not significantly different (the tension in BD is decreased by 12 N, and the compression in CD is decreased by 0.6 N).
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Example Figure shows the truss The truss material is aluminum; all the outer members of the truss have a cross-sectional area of 4 in.2, and each of the three inner members has an area of 2 in.2. We wish to determine how much the length of each member changes due to the loads shown in Fig.
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FORCE EQUILIBRIUMThe symbols T and C are used to indicate whether the force is tensile or compressive.
GEOMETRIC COMPATIBILITY OF DEFORMATIONThe members of the truss make up a series of triangles, and the truss is the sum of these triangles. If the pins are frictionless and allow free rotation, then the three members which form anyone triangle also will form a triangle if the three members change their lengths..
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Furthermore, adjacent triangles can distort independently of each other in the present example, since the roller support at B is free to move horizontally to accommodate the distortion of the triangles which make up the truss. From this we conclude that each member of the truss is free to lengthen or shorten without any restraint being imposed by the other members of the truss. The overall behavior of the truss is indicated in Fig.cwhere the deflections have been exaggerated greatly for purposes of illustration
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RELATIONS BETWEEN FORCES AND DEFORMATIONSThe deformations of the three members which make up the triangle ACD are
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The changes in length of the other members of the truss can be obtained from similar calculations.
The determination of the displacement of any point, say D, in the truss of Fig. c is a fairly cumbersome calculation. However, the principles involved in such a calculation are quite simple, as was illustrated in Example 2.4. Computer programs have been devised to facilitate the calculation of displacements. This will be illustrated in Sec. 2.5. In Sec. 2.6 we shall develop an energy method which provides a convenient means of calculating deflections of linearly elastic structures.
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Example The stiff horizontal beam AD in Fig. a is supported by two soft copper rods AC and DD of the same cross-sectional area but of different lengths. The load-deformation diagram for the copper is shown In Fig. 2.9b. A vertical load of 150 kN is to be suspended from a roller which rides on the horizontal beam. We do not want the roller to move after the load is put on, so we wish to find out where to locate the roller so that the beam wiII stilI be horizontal in the deflected position. Also, we should like to know if the location would be the same if the load is increased from 150kN to 300 kN.
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FORCE EQUILIBRIUMFrom free body of the beam in Fig. 2.9c
GEOMETRIC COMPATIBILITYSince the beam moves down without rotating, we must have
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Using this equality, we see from the lengths of the bars in Fig. 2.9a that
RELATION BETWEEN FORCE AND DEFORMATIONThe diagram in Fig. 2.9b gives the relation between force and elongation. For example, if we enter the diagram with FB/ AB= 100MN/ sq.m, we find
= 0.0015B
B
Lδ
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The relations (a), (c), and (d) represent the formulation of the three steps of (2.1); that is, they represent our analysis of the physics of the problem. We now must combine (a), (c), and (d) mathematically to find the correct location of the roller. Dividing the first of Eqs. (a) by AA, we have
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Substituting AA = AB = 1300 sq.mm, we obtain the following relation.
We now select an arbitrary value of . Then, using (c) to obtain we enter the diagram in Fig. 2.9b and obtain FB/AB and FA/AA. We then check to see if these values satisfy (e). If (e) is not satisfied, we make a new guess for and obtain new values for FA/AA and FB/AB. Proceeding in this way, we find the points a and b in Fig. 2.9b. From these points,
BB L/δ
BB L/δ
AA L/δ
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Substituting this value for FB in the second of Eqs. (a), we obtain the required location of the roller.
c = 0.355m
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If we repeated the analysis for a load of 300 kN, the solution would be represented by the points a' and b' in Fig. 2.9b, with the results
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It is not surprising that this value of c differs from the previous result, since a nonlinear material does not produce equal increments of elongation for equal increments of load. For example, in Fig. 2.9b a value of PIA of 50 MN/m2 produces a /L of 0.0006, whereas the next increment of 50 MN/m2
produces an increment in IL of 0.0009.
δ
δ
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Analysis of thin ring and thin cylinders
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Force equilibriumFollowing relations will be deduced
(a) --- )]([ θΔ=Δ rbpFp
(b)----- sin)]([sin θθθ Δ=Δ=Δ rbpFF py
(c) ---- 02)sin(0
=−=∑ ∫∏=
=Ty FdpbrF θθ
θ
θ
(d) ---- prbFT =
(e) ---- 02)2( =−=∑ Ty FrbpF
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Geometric compatibility
Force deformation relation
(f) ----- )2
1(2)(
)]2(2[ 2
rt
tEpr
Ebt
trFTT +
Π=
+Π=δ
(g) --- 2Π
= TR
δδ
(h) ---- )2
1(2
rt
tEpr
R +=δ
(i) ----- 2
tEpr
R =δ
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Analysis of flexible drives
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02
cos2
cos)(
02
sin)(2
sin
=Δ−Δ
−Δ
Δ+=∑
=Δ
Δ+−Δ
−Δ=∑
NfTTTF
TTTNFr
θθ
θθ
θ
} -- (a)
Force equilibrium
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0)(
02
)(2
=Δ−−Δ+
=Δ
Δ+−Δ
−Δ
NfTTT
TTTN θθ
} -- (b)
(c) --- fTT=
ΔΔθ
(d) ---- fTddT
=θ
(e) ---- θfADeTT =
(f) ---- 38.11 4.0 kNeT θ=
4.0 ,40 =Π=== fandatkNTTngSubstituti
BC θ
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Relation between force and deformation
(g) ---- AE
TR θδ Δ=Δ
Geometric Compatibility
(h) ------
00 ∫∫
Π=
=
Π=
===
θ
θ
θ
θ
θδδAE
dTRdAB
(i) ------ )1(0∫Π Π −== fADfAD
AB eAEf
RTde
AERT
θδ θ
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Statically Indeterminate Situations
Example2.9Figure 2.12a shows the pendulum of a clock which has a12-N weight suspended by three rods of 760-mm length. Two of the rods are made of brass and the third of steel. We wish to know how much of the 12-N suspended weight is carried by each rod.
We shall now consider two examples in which we must examine the deformation of the system in order to determine the manner in which the forces are distributed within the system.
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Force equilibrium
(a) ---- 0212 =−−=∑ BSy FFF
Geometric compatibility
(b) ------ BS δδ =
Relation between forces and deformations
(c) ---- BB
BBB
SS
SSS EA
LFEALF
== δδ
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Combining (b) and (c),
BBS
BSBB
BSSS
FFF
FLEALEA
F
541.0760)100()5.2(760)200()3.1(
(d) -----
2
2
==
=
Combining (a) and (d), we find
NFNF
B
S
72.4 55.2
==
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Example 2.10
Figure 2.130 shows an instrument suspension consisting of two aluminum bars and one steel rod mounted in a stiff frame, together with a spring EA which is inclined at 45° to BA. In assembly the nut on the steel rod at D is tightened so there is no slack in the line BAD, and then the spring EA is installed with sufficient extension to produce a force of 10lb. We wish to find the deflection of the joint A (relative to the frame) caused by the spring loading.
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Force equilibrium
02
10
02
10
=−=∑
=−−=∑
ACy
ABADx
FF
FFF
} ---- (a)
Geometric compatibility
ncompressioextension
extension
xAB
xAD
yAC
(b) ----- }
δδδδ
δδ
==
=
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Relation between forces and deformations
)1010(005.02.1)(
-(c)--- } )1030(00071.0
6.1)(
. 00020.0)1010(005.0
)4.1(07.7)(
6
6
6
×==
×==
=×
==
ABABAB
ADADAD
ACAC
FAEFL
FAEFL
inAEFL
δ
δ
δ
Solving (a), (b), and (c) simultaneously, we obtain
. 00013.0
(d) --- } . 00020.0 35.5 72.1
in
inncompressiolbF
tensionlbF
x
y
AB
AD
=
===
δ
δ
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ELASTIC ENERGY; CASTIGLIANO'S THEOREM
In this section we give a brief introduction to the concept of energy and develop a powerful tool for calculating deflections of elastic systems.The work done by a force vector F when its point of application moves through a displacement vector ds is the scalar, or dot, product
ds cos ds . θFF =where is the angle between F and ds.θ
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In general, F will vary as the point of application follows a certain path so that the total work done by F is given by an integral
∫ dsF .
Conservative systems:When work is done by an external force on certain systems, their internal geometric states are altered in such a way that they have the potential to give backequal amounts of work whenever they are returned to their original configurations.
e.g. Elastic spring
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Consider the elastic, but not necessarily linear, spring in Fig. 2.17. Let the spring undergo a gradual elongation process during which the external force F remains in equilibrium with the internal tension. The potential energy U associated with an elongation b is defined to be the work done by F in this process
(2.3) ------ .0
∫ ∫ ==δ
δ UFddsF
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Fig.2.17 Nonlinear spring (a) has deflection due to force F. Potential energy U is area under force-deflection curve (b). Complementary energy U * is area above curve (c).
δ
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In Fig. 2.17b, this energy appears as the shaded area under the force-deflection curve. Note that U is a function of the elongation
. If this spring should happen to be part of a larger elastic system, it will always contribute the energy (2.3) to the total stored energy of the system whenever its individual elongationis
δ
δNext, consider the general elastic system of Fig. 2.18a, which can be loaded by an arbitrary number of loads. At a typical loading point Ai the load is Pi, and the equilibrium displacement due to all the loads is sj. If, during the loading process, the displacements si are permitted to grow slowly through a sequence of equilibrium configurations, the total work done by all the external loads will equal to the total potential energy U stored by all the internal elastic members
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(2.4) ----- Uds i
s
0i
i
∑∫ =•iP
Flg.2.18 General elastic structure
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When the point of application of a variable force F undergoes a displacement s, the complementary work is
∫ • dFs
When complementary work is done on certain systems, their internal force states are altered in such a way that they are capable of giving up equal amounts of complementary work when they are returned to their original force states. Under these circumstances the complementary work done on such a system is said to be stored as complementary energy.
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Let us reconsider the gradual loading process for the nonlinear spring of Fig.2.17a. The complementary energy U* associated with a force F is defined to be the complementary work done by F
(2.5) --- 0
*∫ ∫ ==⋅F
UdFdFs δ
Total complementary energy U* stored by all the internal elastic members discussed in fig.2.18 is
∑∫ ∑ ∫ ==⋅i
p
i
p
iiii
i i
Udpdps0 0
* (2.6) ------ δ
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Suppose that the system in Fig. 2.18a is in its equilibrium position with the complementary energy (2.6). We now consider a small increment to the load Pi while all the other loads remain fixed. The internal forces will change slightly to maintain force equilibrium, and the increment in complementary work will equal the increment in complementary energy .For small we have, approximately
iPΔ
iPΔ*UΔ
ii
ii PUUP δδ =ΔΔ
Δ=Δ*
* or
In the limit as this approaches a derivative which we indicate as a partial derivative since all the other loads were held fixed
0→Δ iP
(2.7) ----- *
iiP
U δ=∂∂
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This result is a form of Castigliano's theorem (extended to nonlinear systems). It states that if the total complementary energy U* of a loaded elastic system is expressed in terms of the loads, the in-line deflection at any particular loading point is obtained by differentiating U* with respect to the load at that point. The theorem can be extended to include moment loads Mi as well as force loads Pi. In the case of a moment load, the in-line displacement is the angle of rotation about the axis of the moment vector Mi, and in place of (2.7) we have
iφ
(2.8) -------- *
iiM
U φ=∂∂
For the linear spring the elastic energy is
(2.10) ------- 22
121 2
2
kFFkU === δδ
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Similarly, for the linear uniaxial member the elastic energy is
(2.11) ------- 22
12
22
EALPP
LEAU === δδ
Finally, the in-line deflection at any loading point A i is obtained by differentiation with respect to the load Pi
iδ
(2.12) ------ i
i PU∂∂
=δ
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Example 2.11Consider the system of two springs shown in Fig. 2.19. We shall use Castigliano's theorem to obtain the deflections and which are due to the external loads P1 and P2
1δ 2δ
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To satisfy the equilibrium requirements the internal spring forces must be
F1 = P1 + P2 & F2 = P2
The total elastic energy using (2.10), is
2
22
1
221
21 22)(
kP
kPP
UUU ++
=+=
The deflections then follow from (2.12)
2
2
1
21
22
121
11
kP
kPP
PU
kPP
PU
++
=∂∂
=
+=
∂∂
=
δ
δ
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Example 2.12Let us consider again Example 2.4 (also Example 1.3), and determine the deflections using Castigliano's theorem. In Fig. 2.20 the isolated system from Example 2.4 is shown together with the applied loads.
Solution:
Total energy is
(a) ------ 22
222 2
2
1
2
2
22
1
21
21 kP
kP
kP
kP
UUU +=+=+=
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Deflection of point D in the direction of P
mm
kkP
kP
kP
PPU
P
P
77.110 ]0023.00421.0[ 202
(b) -------- 2112
26
212
2
1
2
=×+×=
⎟⎟⎠
⎞⎜⎜⎝
⎛+=⎟⎟
⎠
⎞⎜⎜⎝
⎛+
∂∂
=∂∂
=
−δ
δ
Total energy in terms of loads P and Q is
(c) ------- )(21
22 2
21
2
QPkk
PU −+=
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mmkP
thereforebutQk
QPQU
and
Q
Q
0915.0
,0
(d) ---------- 0
2
2
−=−
=
=
−−=
∂∂
=
δ
δ
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Fig. 2.21Structure of Fig. 2.20 with fictitious load Q at D.
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Example 2.13As a final example in this chapter, let us use Castigliano's
theorem to determine deflections in the truss' problem that we considered in Example 2.5 and in the computer-solution example of Sec.2.5.
The method of solution here is exactly the same as in the previous example; i.e., we calculate the total energy in terms of the real and fictitious loads, and determine deflections by taking appropriate derivatives. However, because a larger number of members is involved, it is worthwhile to set up a system that permits the necessary manipulations with the least effort.
Solution:If a truss is made of n axially loaded members, the
energy stored in the ith member, according to (2.11), is
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(b) ------
is membersn of system in theenergy total theand
(a) ------ 2
1
2
∑−
=
=
n
ii
ii
iii
UU
EALF
U
Deflection in the direction of P is
(d) -------
asitten further wr becan Which
(c) ----- 2
1
11
2
∑
∑∑
=
==
∂∂
=
∂∂
=∂∂
=∂∂
=
n
i
i
ii
iiP
in
i ii
iin
i ii
iiP
PF
EAL
F
PF
EALF
EALF
PPU
δ
δ
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From equation d and table 2.6
lbQor
QQQF
EAL
F i
ii
ii
1067.16
]104.2][10201033.13[0
3
633
×−=
×+×++×==∂∂
∑ −
If now we wish to solve for the deflection at P, we must reevaluate the products in rows 1 and 2 of Table 2.6 with Q at its actual value as determined above. These new values are
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The values for members 3 through 9 do not change since they carry no Q. Therefore '
in. 0.11170.05340.1651δThus
1016.67Qbut
102.31651.0PUδ
P
3
6P
=−=
×−=
×+=∂∂
= −Q