PIPES CONVEYING FLUID: LINEAR DYNAMICS I1              26 1

             contention that parametric resonance regions calculated with   = 0 are representative of
             cases with effectively any value of B.



             4.5.6  Two-phase and stochastically perturbed flows
             As  already mentioned, practical interest in  this  work has been associated with possible
             excitation of  piping by  pump-generated pulsations. A different and interesting applica-
             tion was  studied by  Hara (1977,  1980) in connection with two-phase flow  in piping, in
             the  'slug-flow'  regime, where the flow is essentially composed of  alternating liquid and
             gaseous slugs.
               Clearly, in this case it is not the velocity that is varying with time but the mass per unit
             length; moreover, the time variation is more like a square wave than a harmonic function.
             This is the phenomenon accidentally discovered in the experiments with piping aspirating
             flow, as shown in Figure 4.1 l(b). Hara's experiments, involving a 2.2 m long horizontal
             simply-supported pipe were in fact conducted with air-water  mixtures simulating true two-
             phase  flow. Parametric resonances were found for  w/w,  E 0.65, 0.95 and  1.94, where
             w is the frequency associated with  'slug arrival times';  these ratios are remarkably close
             to  the  theoretically expected $,  1  and  2.  The  strongest excitation in  this  case  was  for
             w/w,  = 1 rather than  2;  this  is  explained as being due to  additional two-phase forced
             excitation when w = wn .
               Finally,  the  case  of  a  pipe  conveying  stochastically  perturbed  flow  was  studied
             by  Narayanan  (1983),  Ariaratnam  &  Namachchivaya  (1986b)  and  Namachchivaya  &
             Ariaratnam  (1987).  By  assuming  the  intensity  and  correlation  time  of  the  stochastic
             perturbations to be small (broad-band spectrum), the problem is transformed into a Markov
             process, and solutions are obtained by  stochastic averaging. It is found that the amount
             of  damping necessary to ensure stability depends only on  those values of  the excitation
             PSD near twice the eigenfrequencies and near their sums and differences.


             4.6  FORCED VIBRATION

             There are two aspects of forced vibration of pipes conveying fluid worthy of discussion.
             The first is the physical aspect, which sheds further light onto the dynamics of the system,
              and  the  second is related to the  analytical techniques which  can be  used  to obtain the
             forced response of  such systems. These will be dealt with separately in what follows.


             4.6.1  The dynamics of forced vibration

             Let  us  consider  a  pipe  subjected  to  an  arbitrary  harmonic  force  field,  such  that  it  is
             governed by  an equation of the form

                                                                                  (4.76)

             in which %(v) is given by  equation (3.70). By means of Galerkin's  method, this may be
             discretized into
                                     Mq + C(u)q + K(u) q = F eior,                (4.77)