(1+e)2+(E)
                               PIPES CONVEYING FLUID: LINEAR DYNAMICS I               71
                                                            =l.
                                                          2
                                                                                   (3.15)

               In both (3.14) and (3.13, xo may be replaced by  s.
                 If  the pipe cannot be considered to be  inextensible, e.g. in  Figure 3.l(a), 6x0 and 6s
               are no longer equal; they must be  related through (3.13) which, with the aid of  (3.12),
               leads to
                                                               -I  12
                                    ax,= [(l+-g)2+(e)2]  (3.16)
                                    as

                 The final preliminary point that needs be examined is related to the orders of  magni-
               tude of  the displacements, which define the degree of approximation and  simplification
               that is  admissible in the derivations to follow. First, it is  reasonable to  assume, partic-
               ularly  in  linear  analysis, that  the  lateral displacement w is  small compared to  the pipe
               length, i.e.
                                              w/L - f%E),                         (3.17a)

               where E  <<  1. By  expanding (3.15) and neglecting   as compared to  2(au/axo),
               and also replacing xo  by  s,  it is clear that

                                           I  aw
                                  u 2: - 1’ (%)  ds,      u/L - O(E*);            (3.17b)
                                           -
                                        02
               i.e.  longitudinal  displacements are  one  order  smaller  than  the  lateral  ones.  It  is  also
               well known  that, in  the  Newtonian approach, if  all  terms are correct to  order  E,  so  is
               the  equation  of  motion. In  the  Hamiltonian approach, however, since the  energies are
               generally quadratic expressions of displacements and velocities, the various terms should
              be  correct  to  order  c2. Hence,  in  the  Newtonian  derivation of  Section 3.3.2 one  may
              take x  = xo  = s and consider only the lateral deflection of  the pipe, w = w(x, t). In  the
               Hamiltonian derivation of  Section 3.3.3, however, one has to  take account of  u(x, t) as
              well,  and  to  take  care  to  differentiate xo  or  s  from x,  since  then  generally x $ s  for
              inextensible pipes and also xo  # s for extensible ones.



               3.3.2  Newtonian derivation

              Consider the system of Figure 3.1 (a-c),  a uniform pipe of length L, internal perimeter S,
               flow-area A, mass per unit length m, and flexural rigidity EZ, conveying fluid of mass per
              unit length M, with mean axial flow  velocity U. The flow in the pipe is fully developed
              turbulent. Consider the undisturbed axis of the pipe to be  vertical, along the x-axis, and
              the effect of  gravity to be generally non-negligible. The flow velocity may be subject to
              small perturbations, imposed externally, so that dU/dt # 0 generally.
                The pipe is considered to be slender, and  its lateral motions, w(x, t), to be  small and
              of  long  wavelength compared to  the diameter; thus,  in  accordance with  the discussion
              in  Section 3.3.1, the  curvilinear coordinate  s along the  centreline of  the  pipe  and  the
              coordinate x may be used interchangeably. Consider then elements 6s of the fluid and the
              pipe, as shown in Figure 3.6.