The head velocity of the density current in the convergent and divergent channel is a key parameter for evaluating the extent to which suspended material travels,and for determining the type and distribution of sediment in the water body.This study experimentally evaluated the effects of the reach degree of convergence and divergence on the head velocity of the density current.Experiments were conducted in the flume with 6.0 m long,0.72 m width and 0.6 m height.The head velocity was measured at three convergent degrees(-8°;-12°;-26°),at three divergent degrees(8°;12°;26°) and two slopes(0.009,0.016) for various discharges.The measured head velocity of the density current is compared with the head velocity of the density current in the constant cross section channel. Based on non-dimensional and statistical analysis,relations as linear multiple regression offered for prediction head velocity of the density current in the convergent,divergent and constant cross section channel.Also the results of this research show that for the same slope and discharge,the head velocity of the density current in the convergent and divergent channel are greater and less than the head velocity of the constant cross section, respectively. The head velocity of the density current in the convergent and divergent channel is a key parameter for evaluating the extent to which suspended material travels, and for determining the type and distribution of sediment in the water body. This study experimentally evaluated the effects of the reach degree of convergence and divergence on the head velocity of the density current. Experiments conducted in the flume with 6.0 m long, 0.72 m width and 0.6 m height. head velocity was measured at three convergent degrees (-8 °; -12 ° ; -26 °) at three divergent degrees (8 °; 12 °; 26 °) and two slopes (0.009, 0.016) for various discharges. The measured head velocity of the density current is compared with the head velocity of the density current Based on non-dimensional and statistical analysis, relations as linear multiple regression offered for prediction head velocity of the density current in the convergent, divergent and constant cross section channel. Also the results of this research show that for the same slope and discharge, the head velocity of the density current in the convergent and divergent channels are greater and less than the head velocity of the constant cross section, respectively.