AFT Arrow allows the user to enter valve coefficient data in terms of K_v or C_v. Conversions are handled seamlessly in the background. K_v is the metric equivalent to C_v.

The valve C_v loss model type is unique in that this loss model can be used as part of both the subsonic and sonic loss calculations across the valve.

Subsonic Loss

The relationship between valve C_v, X_t, and flow is provided by ANSI/ISA-75.01.01-2012ANSI/ISA Standard 75.01.01-2012, Industrial-Process Control Valves - Part 2-1: Flow Capacity - Sizing equations for fluid flow under installed conditions, 2012, published by International Society of Automation, Research Triangle Park, North Carolina, USA standard as follows:

Where C is the flow coefficient (C_v or K_v) and N is a numerical constant found in Table 1 of the ANSI standard referenced above. The units for the flow, pressure and density will be based off of the numerical constant chosen.

F_p is a correction factor for piping geometry. This correction will be treated as 1 unless the Valve ID has been entered by the user.

X_sizing is the ratio of the pressure drop across the valve to the inlet pressure of the valve for subsonic flow:

Y is the expansion factor, which accounts for the change in density as the gas passes through the vena contracta, and is calculated as follows:

Where X_t is the pressure ratio, X, when the valve has just begun to choke.

Sonic Loss

If choked flow occurs across the valve, then the mass flow equation above is still used. However, the X_sizing is now equivalent to X_t, which is the pressure ratio when the valve first begins to choke.

Estimated Cv/Kv in Output

In the Output window the estimated Cv /Kv can be displayed if the Cv /Kv was not defined by the user. The estimated Cv /Kv value is calculated using the mass flow rate equation shown above, with Xsizing estimated as follows

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Making Sense of xT - Valve Loss in Compressible Flow