Nonlinear wave-wave interactions in turbulent jets were investigated based on the integrated energy of each scale of motion in a cross section of the jet. The analysis indicates that two frequency components in the axisymmetric mode can interact with other background frequencies in the axisymmetric mode, thereby amplifying an enormous number of other frequencies. Two frequency components in a single helical mode cannot, by themselves, amplify other frequency components. But combinations of frequency components of helical and axisymmetric modes can amplify other frequencies in other helical modes. The present computations produce several features consistent with experimental observations on two-frequency excitation such as (1) dependence of the interactions on the initial phase differences between the waves, (2) enhancement of the momentum thickness under multifrequency forcing, and (3) the increase in background turbulence under forcing. In a multifrequency-excited turbulent jet the mechanisms contributing to the development of the jet are identified. Mixing enhancement was found to result from the turbulence enhancement rather than simply from the amplification of forced wave components. The excitation waves pump energy from the mean flow to the turbulence, thus enhancing the latter. The high-frequency waves enhance the turbulence close to the jet exit, while the low-frequency waves are most effective farther downstream.

• 出版日期1991-4