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7.4 SHEAR FLOW IN BUILT-UP MEMBERS

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Title: 7.4 SHEAR FLOW IN BUILT-UP MEMBERS


1
7.4 SHEAR FLOW IN BUILT-UP MEMBERS
  • Occasionally, in engineering practice, members
    are built-up from several composite parts in
    order to achieve a greater resistance to loads,
    some examples are shown.
  • If loads cause members to bend, fasteners may be
    needed to keep component parts from sliding
    relative to one another.
  • To design the fasteners, we need to know the
    shear force resisted by fastener along members
    length

2
7.4 SHEAR FLOW IN BUILT-UP MEMBERS
  • This loading, measured as a force per unit
    length, is referred to as the shear flow q.
  • Magnitude of shear flow along any longitudinal
    section of a beam can be obtained using similar
    development method for finding the shear stress
    in the beam

3
7.4 SHEAR FLOW IN BUILT-UP MEMBERS
  • Thus shear flow is

Equation 7-6
q shear flow, measured as a force per unit
length along the beam V internal resultant
shear force, determined from method of sections
and equations of equilibrium I moment of
inertia of entire x-sectional area computed about
the neutral axis Q ?A y dA yA, where A
is the x-sectional area of segment connected to
beam at juncture where shear flow is to be
calculated, and y is distance from neutral axis
to centroid of A
4
7.4 SHEAR FLOW IN BUILT-UP MEMBERS
  • Note that the fasteners in (a) and (b) supports
    the calculated value of q
  • And in (c) each fastener supports q/2
  • In (d) each fastener supports q/3

5
7.4 SHEAR FLOW IN BUILT-UP MEMBERS
  • IMPORTANT
  • Shear flow is a measure of force per unit length
    along a longitudinal axis of a beam.
  • This value is found from the shear formula and is
    used to determine the shear force developed in
    fasteners and glue that holds the various
    segments of a beam together

6
EXAMPLE 7.4
Beam below is constructed from 4 boards glued
together. It is subjected to a shear of V 850
kN. Determine the shear flow at B and C that must
be resisted by the glue.
7
EXAMPLE 7.4 (SOLN)
Section properties Neutral axis (centroid) is
located from bottom of the beam. Working in units
of meters, we have
Moment of inertia about neutral axis is
I ... 87.52(10-6) m4
8
EXAMPLE 7.4 (SOLN)
Section properties Since the glue at B and B
holds the top board to the beam, we have
QB yB AB 0.305 m ? 0.1968 m(0.250 m)(0.01
m) QB 0.270(10-3) m3
Likewise, glue at C and C holds inner board to
beam, so
9
EXAMPLE 7.4 (SOLN)
Shear flow For B and B, we have
qB VQB /I 850 kN(0.270(10-3)
m3/87.52(10-6) m4 qB 2.62 MN/m
Similarly, for C and C,
qC VQC /I 850 kN(0.0125(10-3)
m3/87.52(10-6) m4 qC 0.0995 MN/m
10
EXAMPLE 7.4 (SOLN)
Shear flow Since two seams are used to secure
each board, the glue per meter length of beam at
each seam must be strong enough to resist
one-half of each calculated value of q. Thus
qB 1.31 MN/m qC 0.0498 MN/m
11
7.5 SHEAR FLOW IN THIN-WALLED MEMBERS
  • We can use shear-flow equation q VQ/I to find
    the shear-flow distribution throughout a members
    x-sectional area.
  • We assume that the member has thin walls, i.e.,
    wall thickness is small compared with height or
    width of member

12
7.5 SHEAR FLOW IN THIN-WALLED MEMBERS
  • Because flange wall is thin, shear stress will
    not vary much over the thickness of section, and
    we assume it to be constant. Hence,

q ? ? t
Equation 7-7
  • We will neglect the vertical transverse component
    of shear flow because it is approx. zero
    throughout thickness of element

13
7.5 SHEAR FLOW IN THIN-WALLED MEMBERS
  • To determine distribution of shear flow along top
    right flange of beam, shear flow is

Equation 7-8
14
7.5 SHEAR FLOW IN THIN-WALLED MEMBERS
  • Similarly, for the web of the beam, shear flow is

Equation 7-9
15
7.5 SHEAR FLOW IN THIN-WALLED MEMBERS
  • Value of q changes over the x-section, since Q
    will be different for each area segment A
  • q will vary linearly along segments (flanges)
    that are perpendicular to direction of V, and
    parabolically along segments (web) that are
    inclined or parallel to V
  • q will always act parallel to the walls of the
    member, since section on which q is calculated is
    taken perpendicular to the walls

16
7.5 SHEAR FLOW IN THIN-WALLED MEMBERS
  • Directional sense of q is such that shear appears
    to flow through the x-section, inward at beams
    top flange, combining and then flowing
    downward through the web, and then separating and
    flowing outward at the bottom flange

17
7.5 SHEAR FLOW IN THIN-WALLED MEMBERS
  • IMPORTANT
  • If a member is made from segments having thin
    walls, only the shear flow parallel to the walls
    of member is important
  • Shear flow varies linearly along segments that
    are perpendicular to direction of shear V
  • Shear flow varies parabolically along segments
    that are inclined or parallel to direction of
    shear V
  • On x-section, shear flows along segments so
    that it contributes to shear V yet satisfies
    horizontal and vertical force equilibrium

18
EXAMPLE 7.7
  • Thin-walled box beam shown is subjected to shear
    of 10 kN. Determine the variation of shear flow
    throughout the x-section.

19
EXAMPLE 7.7 (SOLN)
  • By symmetry, neutral axis passes through center
    of x-section. Thus moment of inertia is

I 1/12(6 cm)(8 cm)3 ? 1/12(4 cm)(6 cm)3 184
cm4
Only shear flows at pts B, C and D needs to be
determined. For pt B, area A 0 since it can be
thought of located entirely at pt B.
Alternatively, A can also represent the entire
x-sectional area, in which case QB yA 0
since y 0.
20
EXAMPLE 7.7 (SOLN)
Because QB 0, then qB 0
For pt C, area A is shown dark-shaded. Here mean
dimensions are used since pt C is on centerline
of each segment. We have
QC yA (3.5 cm)(5 cm)(1 cm) 17.5 cm3
qC VQC/I ... 95.1 N/mm
21
EXAMPLE 7.7 (SOLN)
Shear flow at D is computed using the three
dark-shaded rectangles shown. We have
QD yA ... 30 cm3
qC VQD/I ... 163 N/mm
22
EXAMPLE 7.7 (SOLN)
Using these results, and symmetry of x-section,
shear-flow distribution is plotted as shown.
Distribution is linear along horizontal segments
(perpendicular to V) and parabolic along vertical
segments (parallel to V)
23
7.6 SHEAR CENTER
  • Previously, we assumed that internal shear V was
    applied along a principal centroidal axis of
    inertia that also represents the axis of symmetry
    for the x-section
  • Here, we investigate the effect of applying the
    shear along a principal centroidal axis that is
    not an axis of symmetry
  • When a force P is applied to a channel section
    along the once vertical unsymmetrical axis that
    passes through the centroid C of the x-sectional
    area, the channel bends downwards and also twist
    clockwise

24
7.6 SHEAR CENTER
25
7.6 SHEAR CENTER
  • When the shear-flow distribution is integrated
    over the flange and web areas, a resultant force
    of Ff in each flange and a force of VP in the
    web is created
  • If we sum the moments of these forces about pt A,
    the couple (or torque) created by the flange
    forces causes the member to twist
  • To prevent the twisting, we need to apply P at a
    pt O located a distance e from the web of the
    channel, thus

? MA Ff d Pe
26
7.6 SHEAR CENTER
  • Express Ff is expressed in terms of P ( V) and
    dimensions of flanges and web to reduce e as a
    function of its x-sectional geometry
  • We name the pt O as the shear center or flexural
    center
  • When P is applied at the shear center, beam will
    bend without twisting
  • Note that shear center will always lie on an axis
    of symmetry of a members x-sectional area

27
7.6 SHEAR CENTER
  • IMPORTANT
  • Shear center is the pt through which a force can
    be applied which will cause a beam to bend and
    yet not twist
  • Shear center will always lie on an axis of
    symmetry of the x-section
  • Location of the shear center is only a function
    of the geometry of the x-section and does not
    depend upon the applied loading

28
7.6 SHEAR CENTER
  • Procedure for analysis
  • Shear-flow resultants
  • Magnitudes of force resultants that create a
    moment about pt A must be calculated
  • For each segment, determine the shear flow q at
    an arbitrary pt on segment and then integrate q
    along the segments length
  • Note that V will create a linear variation of
    shear flow in segments that are perpendicular to
    V and a parabolic variation of shear flow in
    segments that are parallel or inclined to V

29
7.6 SHEAR CENTER
  • Procedure for analysis
  • Shear-flow resultants
  • Determine the direction of shear flow through the
    various segments of the x-section
  • Sketch the force resultants on each segment of
    the x-section
  • Since shear center determined by taking the
    moments of these force resultants about a pt (A),
    choose this pt at a location that eliminates the
    moments of as many as force resultants as possible

30
7.6 SHEAR CENTER
  • Procedure for analysis
  • Shear center
  • Sum the moments of the shear-flow resultants
    about pt A and set this moment equal to moment of
    V about pt A
  • Solve this equation and determine the moment-arm
    distance e, which locates the line of action of V
    from pt A
  • If axis of symmetry for x-section exists, shear
    center lies at the pt where this axis intersects
    line of action of V

31
7.6 SHEAR CENTER
  • Procedure for analysis
  • Shear center
  • If no axes of symmetry exists, rotate the
    x-section by 90o and repeat the process to obtain
    another line of action for V
  • Shear center then lies at the pt of intersection
    of the two 90o lines

32
EXAMPLE 7.8
  • Determine the location of the shear center for
    the thin-walled channel section having the
    dimensions as shown.

33
EXAMPLE 7.8 (SOLN)
  • Shear-flow resultants
  • Vertical downward shear V applied to section
    causes shear to flow through the flanges and web
    as shown. This causes force resultants Ff and V
    in the flanges and web.

34
EXAMPLE 7.8 (SOLN)
  • Shear-flow resultants
  • X-sectional area than divided into 3 component
    rectangles a web and 2 flanges. Assume each
    component to be thin, then moment of inertia
    about the neutral axis is

I (1/12)th3 2bt(0.5h)2 (0.5th2)(h/6) b
Thus, q at the arbitrary position x is
35
EXAMPLE 7.8 (SOLN)
  • Shear-flow resultants
  • Hence,

The same result can be determined by first
finding (qmax)f, then determining triangular area
0.5b(qmax)f Ff
36
EXAMPLE 7.8 (SOLN)
  • Shear center
  • Summing moments about pt A, we require

Ve Ff h

As stated previously, e depends only on the
geometry of the x-section.
37
CHAPTER REVIEW
  • Transverse shear stress in beams is determined
    indirectly by using the flexure formula and the
    relationship between moment and shear (V
    dM/dx). This result in the shear formula?
    VQ/It.
  • In particular, the value for Q is the moment of
    the area A about the neutral axis. This area is
    the portion of the x-sectional area that is held
    on to the beam above the thickness t where ? is
    to be determined

38
CHAPTER REVIEW
  • If the beam has a rectangular x-section, then the
    shear-stress distribution will be parabolic,
    obtaining a maximum value at the neutral axis
  • Fasteners, glues, or welds are used to connect
    the composite parts of a built-up section. The
    strength of these fasteners is determined from
    the shear flow, or force per unit length, that
    must be carried by the beam q VQ/I
  • If the beam has a thin-walled x-section then the
    shear flow throughout the x-section can be
    determined by using q VQ/I

39
CHAPTER REVIEW
  • The shear flow varies linearly along horizontal
    segments and parabolically along inclined or
    vertical segments
  • Provided the shear stress distribution in each
    element of a thin-walled section is known, then,
    using a balance of moments, the location of the
    shear center for the x-section can be determined.
  • When a load is applied to the member through this
    pt, the member will bend, and not twist
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