model PropValve43PT2TableAx
parameter Real inputMax = 10 "Input value for 100 % open"
annotation (Dialog(group = "Control Parameters"));
parameter Modelica.SIunits.AngularFrequency angFreq = 2 * Modelica.Constants.pi * 50 "Angular frequency"
annotation (Dialog(group = "Control Parameters"));
parameter Modelica.SIunits.DampingCoefficient damping = 0.7 "Damping"
annotation (Dialog(group = "Control Parameters"));
parameter Modelica.SIunits.TimeAging vMax = 100 "max. Velocity"
annotation (Dialog(group = "Control Parameters"));
parameter Modelica.SIunits.TimeAging vMin = -100 "min. Velocity"
annotation (Dialog(group = "Control Parameters"));
extends HydraulicsByFluidon.Components.Valves.Base.PartialValve43TableAx;
extends HydraulicsByFluidon.Components.Valves.Base.PartialValveControlSignal_x3;
extends HydraulicsByFluidon.Components.Valves.Base.PartialValveProp_x3;
Modelica.SIunits.DimensionlessRatio Stroke(start = 0) "rel. Position of valve spool";
Modelica.SIunits.TimeAging Velocity(start = 0) "rel. Velocity of valve spool";
Modelica.Blocks.Nonlinear.Limiter limiter(limitsAtInit = true, strict = true, uMax = 1, uMin = -1);
equation
if enableStrokeOut then
valveStrokeOut = Stroke;
end if;
if noEvent(vMax < Velocity) then
der(Stroke) = vMax;
elseif noEvent(Velocity < vMin) then
der(Stroke) = vMin;
else
der(Stroke) = Velocity;
end if;
gain1.u = Stroke;
limiter.u = Input / inputMax;
valveEdgeBT.Input = Stroke;
valveEdgePA.Input = Stroke;
der(Velocity) = angFreq * (angFreq * (limiter.y - Stroke) - 2 * damping * Velocity);
annotation (Documentation(info = "<html>\n <p>\n The component PropValve43PT2TableAx is a model of a 3-way proportional valve where the stroke follows the input signal with a 2nd order delay.\n </p>\n <p>\n <center><img src=\"modelica://HydraulicsByFluidon/Resources/Images/Components/Valves/DirectionalValves/PropValve43PT2.png\"></center>\n </p>\n <p>\n The parameterization of the valve is done by providing the <var>Flow coefficient alphaD</var> and a look-up \n table of the <var>Cross-sectional area</var> as a function of the input signal. Each of the four meetering \n edges is parameterised with a separate look-up table and a <var>Flow coefficient alphaD</var> given by the \n user. Further information regarding the formatting of the look-up table can be found in the documentation of \n the component <a href=\"modelica://HydraulicsByFluidon.Components.Resistors.ResistorTableAx\">ResistorTableAx</a>. \n Unlike the Resistor component, the look-up table for valve edges is declared for the input range from -1 to 1.\n </p>\n <p>\n For a positive and negative stroke, the cross-sectional area of the valve's meetering edge is given as a function \n of the input signal through a look-up table starting from 0 to maximum area (the cross-sectional area of the valve \n edge when it is completely open). The cross-sectional area must be given in m^2. The flow is then calculated based \n on <var>Flow coefficient alphaD</var>, <var>Cross-sectional area</var>, density of the fluid and pressure difference \n between the two edges of the valve, according to the formula given below:\n </p>\n <p>\n <center><img align=\"middle\" src= \"modelica://HydraulicsByFluidon/Resources/Images/Components/Resistors/TurbulentFlow.png\"></center>\n </p>\n <p>\n The valve stroke can be shifted by <var>Relative overlap general</var>. In accordance with common valve parameters \n a negative overlap will open the valve edge. <var>Relative overlap general</var> is applied to all valve edges \n simultaneously. If at least one of the edge-specific values, e. g. <var>Relative overlap PA</var> or <var>-AT</var> \n is set to a value different from 0, then the <var>Relative overlap general</var> is ignored and the individual overlaps are used.\n </p>\n </html>"));
end PropValve43PT2TableAx;