(14) were all set to zero. This reduced the gas to an ideal gas with constant specific heats. The program was then run at the same p u T x and P2/p\ values as those given in In conclusion, a program has been developed to determine the expansion factor of a nonideal gas through a venturi meter. The program accounts for nonideal gas behavior as described by the Redlich-Kwong equation of state. For gas flows that are nonideal, the use of the ideal expansion factor in determining m, underestimates the true value. For the example given in this paper, a relative error as much as 6.58 percent was obtained when p 2 /p\ = 0.6 and d 2 /di = 0.8. The program also provides the means for determining the critical pressure ratio as well as the maximum flow rate per unit throat area. For the example given in this paper the maximum percent difference in the critical pressure ratio between the nonideal and ideal gases was 5.81 percent while the maximum percent difference in the maximum flow rate per unit throat area was 7.62 percent. An important aspect of the venturi flow problem that has not been treated in this paper is the nonideal gas effects on the discharge coefficient, C D . If these effects are minimal, then the procedure outlined in this paper would provide an accurate method for determining the mass flow rate of a nonideal gas through a venturi meter
