Axial hydraulic static force exerted on valve

Valve Forces

The Valve Hydraulic Force block simulates axial hydraulic static force exerted on a valve by fluid flowing through the orifice. The relationship between the valve opening, the pressure drop, and the force is provided as a two-dimensional table, which is processed by the PS Lookup Table (2D) block. The table can be obtained experimentally or analytically and can represent both the hydraulic static axial force and pressure forces. The force matrix must be rectangular and contain as many rows as there are pressure differential measurements and as many columns as there are valve openings. The pressure differential and opening vectors must be arranged in strictly ascending order and cover the whole range of valve operation. Connect the block in parallel with the orifice whose flow induces the force.

Connections A and B are hydraulic conserving ports that should
be connected to the valve block ports in such a way as to monitor
the pressure differential across the valve. Connection S is a physical
signal port that provides the valve control member displacement. Connection
F is a physical signal port that outputs the hydraulic axial force
value. This port should be connected to the control port of an Ideal
Force Source block. The pressure differential inside the block
is determined as $$p={p}_{A}-{p}_{B}$$. The force orientation
is specified by the table values and can be positive or negative with
respect to the globally assigned positive direction, depending on
the value of the **Orifice orientation** parameter.

No transient effects can be simulated.

**Initial opening**Orifice initial opening. The parameter can be positive (underlapped orifice), negative (overlapped orifice), or equal to zero for zero lap configuration. The default value is

`0`

.**Orifice orientation**The parameter is introduced to specify the effect of the valve opening on the valve force. The parameter can be set to one of two options:

`Opens in positive direction`

or`Opens in negative direction`

. The value`Opens in positive direction`

specifies an orifice that opens when the valve is shifted in the globally assigned positive direction. The default value is`Opens in positive direction`

.**Tabulated valve openings**Specify the vector of input values for valve openings as a one-dimensional array. The input values vector must be strictly increasing. The values can be nonuniformly spaced. The minimum number of values depends on the interpolation method: you must provide at least two values for linear interpolation, at least three values for cubic or spline interpolation. The default values, in meters, are

`[0,1e-3,2e-3,3e-3,4e-3]`

. The**Tabulated valve openings**values will be used together with**Tabulated pressure differentials**for two-dimensional table lookup in the**Hydraulic axial force table**.**Tabulated pressure differentials**Specify the vector of input values for pressure differentials as a one-dimensional array. The vector must be strictly increasing. The values can be nonuniformly spaced. The minimum number of values depends on the interpolation method: you must provide at least two values for linear interpolation, at least three values for cubic or spline interpolation. The default values, in Pa, are

`[-100e5,-75e5,-50e5,-25e5,0,25e5,50e5,75e5,100e5]`

.**Hydraulic axial force table**Specify the hydraulic axial force as an

`m`

-by-`n`

matrix, where`m`

is the number of valve openings and`n`

is the number of pressure differentials. Each value in the matrix specifies an axial force corresponding to a specific combination of valve opening and pressure differential. The matrix size must match the dimensions defined by the input vectors. The default values, in N, are:[0, -127.3576, -27.8944, 227.2513, 575.3104; ... 0, -95.5182, -20.9208, 170.4385, 431.4828; ... 0, -63.6788, -13.9472, 113.6256, 287.6552; ... 0, -31.8394, -6.9736, 56.8128, 143.8276; ... 0, 0, 0, 0, 0; ... 196.3495, 120.7506, 97.5709, 111.9898, 150.9306; ... 392.6991, 241.5013, 195.1418, 223.9797, 301.8613; ... 589.0486, 362.2519, 292.7126, 335.9695, 452.7919; ... 785.3982, 483.0025, 390.2835, 447.9594, 603.7225]

**Interpolation method**Select one of the following interpolation methods for approximating the output value when the input value is between two consecutive grid points:

`Linear`

— Uses a bilinear interpolation algorithm, which is an extension of linear interpolation for functions in two variables.`Cubic`

— Uses the bicubic interpolation algorithm.`Spline`

— Uses the bicubic spline interpolation algorithm.

**Extrapolation method**Select one of the following extrapolation methods for determining the output value when the input value is outside the range specified in the argument list:

`Linear`

— Extrapolates using the linear method (regardless of the interpolation method specified), based on the last two output values at the appropriate end of the range. That is, the block uses the first and second specified output values if the input value is below the specified range, and the two last specified output values if the input value is above the specified range.`Nearest`

— Uses the last specified output value at the appropriate end of the range. That is, the block uses the last specified output value for all input values greater than the last specified input argument, and the first specified output value for all input values less than the first specified input argument.

The block has the following ports:

`A`

Hydraulic conserving port associated with a valve port.

`B`

Hydraulic conserving port associated with another valve port to monitor the pressure differential.

`S`

Physical signal port that provides the valve control member displacement.

`F`

Physical signal port that outputs hydraulic axial force.

The following example shows a model of a poppet valve built of a Poppet Valve block and a Valve Hydraulic Force block. The Valve Hydraulic Force block is connected in parallel and provides tabulated data to compute hydraulic force acting on the valve. The force value is exported through the F port.

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