PIPES CONVEYING FLUID: LINEAR DYNAMICS I              187

                Making allowance for the shorter tube at the free end, the kinetic energy of the pipe is

                                               ~(" 4q ) +clp [2
                                          ~~
                      ,
                    T-L ,ml3    {I 3  ~  '2 +   4 2  ~  '  4  )  ~  4            (3.157)
                                  )
                                             1
                                       3
                      -
                                             '
                             p= 1                q=o            q=o
              where
                                                   2
                                                                          3
                  clp = 1 + (e - 1)6,~.   ~2~  = 1 + (e  - 1)6,~,   ~3~  = 1 + (e  - 1)6pN,
                                                                                 (3.158)
              and SP~ Kronecker's  delta, while the kinetic energy of the fluid is
                     is





                                                                                 (3.159)


              both correct up to the quadratic terms. The potential energy of  the system is






              The  equations  of  motion  are derived  via  Hamilton's  principle,  equation (3.10). In  this
              case, R = wLk  - cLi, t = @Nk + i, where
                                     N                         N
                                                                                 (3.161)
                                    p= 1                      p= 1

              The equations of  motion, in dimensionless form, are
                 2   "
                 ~C3r4r + Nyc2r4r + 2N2U2C1r(@~ - 4r)















                         r=  1,2,3 ..... N,                                      (3.162)