Failed
tests / testsuite-gcc / simulation_modelica_algorithms_functions.ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar.mos (from (result.xml))
Stacktrace
Output mismatch (see stdout for details)
Standard Output
+ ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar.mos [BUG: #2403]... equation mismatch [time: 3] ==== Log /tmp/omc-rtest-unknown/simulation/modelica/algorithms_functions/ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar.mos_temp8074/log-ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar.mos true "" "model kc_evenGapLaminar extends Modelica.Icons.Example; parameter Integer n = size(cp, 1); parameter Modelica.SIunits.Diameter d_hyd = 2 * s; Real[n] abscissa = array((length / d_hyd / (max(Re[i], 0.001) * Pr[i])) ^ 0.5 for i in 1:n); Modelica.SIunits.Length length = L; Modelica.SIunits.Length dimlesslength(start = 0.01); Modelica.SIunits.PrandtlNumber[n] Pr = array(eta[i] * cp[i] / lambda[i] for i in 1:n); Modelica.SIunits.ReynoldsNumber[n] Re = array(rho[i] * velocity[i] * d_hyd / eta[i] for i in 1:n); Modelica.SIunits.Velocity[n] velocity = array(m_flow[i] / (rho[i] * h * s) for i in 1:n); parameter Modelica.SIunits.Length h = 0.1; parameter Modelica.SIunits.Length s = 0.05; parameter Modelica.SIunits.Length L = 1; parameter Modelica.SIunits.SpecificHeatCapacityAtConstantPressure[:] cp = {1007, 4189, 3384.55}; parameter Modelica.SIunits.DynamicViscosity[:] eta = {0.00001824, 0.0010016, 0.114}; parameter Modelica.SIunits.ThermalConductivity[:] lambda = {0.02569, 0.5985, 0.387}; parameter Modelica.SIunits.Density[:] rho = {1.188, 998.21, 1037.799}; Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con[n] m_flow_IN_con_1(each h = h, each s = s, each L = L, each final target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevOne); Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var[n] m_flow_IN_var_1(m_flow = m_flow, cp = cp, eta = eta, lambda = lambda, rho = rho); Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con[n] m_flow_IN_con_2(each h = h, each s = s, each L = L, each final target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevBoth); Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var[n] m_flow_IN_var_2(m_flow = m_flow, cp = cp, eta = eta, lambda = lambda, rho = rho); Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con[n] m_flow_IN_con_3(each h = h, each s = s, each L = L, each final target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevOne); Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var[n] m_flow_IN_var_3(m_flow = m_flow, cp = cp, eta = eta, lambda = lambda, rho = rho); Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con[n] m_flow_IN_con_4(each h = h, each s = s, each L = L, each final target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevBoth); Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var[n] m_flow_IN_var_4(m_flow = m_flow, cp = cp, eta = eta, lambda = lambda, rho = rho); Modelica.SIunits.NusseltNumber[n] Nu_1; Modelica.SIunits.NusseltNumber[n] Nu_2; Modelica.SIunits.NusseltNumber[n] Nu_3; Modelica.SIunits.NusseltNumber[n] Nu_4; protected Modelica.SIunits.MassFlowRate[n] m_flow = array(0.5 * h * lambda[i] * length / (cp[i] * d_hyd * dimlesslength ^ 2) for i in 1:n); equation der(dimlesslength) = 1 - 0.01; for i in 1:n loop (, , , Nu_1[i], ) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(m_flow_IN_con_1[i], m_flow_IN_var_1[i]); end for; for i in 1:n loop (, , , Nu_2[i], ) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(m_flow_IN_con_2[i], m_flow_IN_var_2[i]); end for; for i in 1:n loop (, , , Nu_3[i], ) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(m_flow_IN_con_3[i], m_flow_IN_var_3[i]); end for; for i in 1:n loop (, , , Nu_4[i], ) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(m_flow_IN_con_4[i], m_flow_IN_var_4[i]); end for; end kc_evenGapLaminar;" "" "function Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar input Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con IN_con; input Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var IN_var; output Real kc(quantity = \"CoefficientOfHeatTransfer\", unit = \"W/(m2.K)\"); output Real Pr(quantity = \"PrandtlNumber\", unit = \"1\"); output Real Re(quantity = \"ReynoldsNumber\", unit = \"1\"); output Real Nu(quantity = \"NusseltNumber\", unit = \"1\"); output Real failureStatus; protected Real MIN = 1e-15; protected Real laminar = 2200.0; protected Real[2] fstatus; protected Real A_cross(quantity = \"Area\", unit = \"m2\") = IN_con.s * IN_con.h; protected Real d_hyd(quantity = \"Length\", unit = \"m\", min = 0.0) = 2.0 * IN_con.s; protected Real prandtlMax = if IN_con.target == Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevOne then 10.0 else if IN_con.target == Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevBoth then 1000.0 else 0.0; protected Real prandtlMin = if IN_con.target == Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevOne or IN_con.target == Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevBoth then 0.1 else 0.0; protected Real velocity(quantity = \"Velocity\", unit = \"m/s\") = abs(IN_var.m_flow) / max(MIN, IN_var.rho * A_cross); algorithm Pr := abs(IN_var.eta * IN_var.cp / max(MIN, IN_var.lambda)); Re := max(1.0, abs(IN_var.rho * velocity * d_hyd / max(MIN, IN_var.eta))); kc := Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_KC(IN_con, IN_var); Nu := kc * d_hyd / max(MIN, IN_var.lambda); fstatus[1] := if Re > laminar then 1.0 else 0.0; fstatus[2] := if IN_con.target == Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevOne or IN_con.target == Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevBoth then if Pr > prandtlMax or Pr < prandtlMin then 1.0 else 0.0 else 0.0; failureStatus := 0.0; for i in 1:2 loop if fstatus[i] == 1.0 then failureStatus := 1.0; end if; end for; end Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar; function Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con \"Automatically generated record constructor for Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con\" input enumeration(DevOne, DevBoth, UndevOne, UndevBoth) target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevBoth; input Real h(quantity = \"Length\", unit = \"m\") = 0.1; input Real s(quantity = \"Length\", unit = \"m\") = 0.05; input Real L(quantity = \"Length\", unit = \"m\") = 1.0; output kc_evenGapLaminar_IN_con res; end Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con; function Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con$m_flow_IN_con_1 \"Automatically generated record constructor for Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con$m_flow_IN_con_1\" input enumeration(DevOne, DevBoth, UndevOne, UndevBoth) target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevBoth; input Real h(quantity = \"Length\", unit = \"m\") = 0.1; input Real s(quantity = \"Length\", unit = \"m\") = 0.05; input Real L(quantity = \"Length\", unit = \"m\") = 1.0; output kc_evenGapLaminar_IN_con$m_flow_IN_con_1 res; end Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con$m_flow_IN_con_1; function Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con$m_flow_IN_con_2 \"Automatically generated record constructor for Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con$m_flow_IN_con_2\" input enumeration(DevOne, DevBoth, UndevOne, UndevBoth) target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevBoth; input Real h(quantity = \"Length\", unit = \"m\") = 0.1; input Real s(quantity = \"Length\", unit = \"m\") = 0.05; input Real L(quantity = \"Length\", unit = \"m\") = 1.0; output kc_evenGapLaminar_IN_con$m_flow_IN_con_2 res; end Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con$m_flow_IN_con_2; function Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con$m_flow_IN_con_3 \"Automatically generated record constructor for Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con$m_flow_IN_con_3\" input enumeration(DevOne, DevBoth, UndevOne, UndevBoth) target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevBoth; input Real h(quantity = \"Length\", unit = \"m\") = 0.1; input Real s(quantity = \"Length\", unit = \"m\") = 0.05; input Real L(quantity = \"Length\", unit = \"m\") = 1.0; output kc_evenGapLaminar_IN_con$m_flow_IN_con_3 res; end Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con$m_flow_IN_con_3; function Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con$m_flow_IN_con_4 \"Automatically generated record constructor for Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con$m_flow_IN_con_4\" input enumeration(DevOne, DevBoth, UndevOne, UndevBoth) target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevBoth; input Real h(quantity = \"Length\", unit = \"m\") = 0.1; input Real s(quantity = \"Length\", unit = \"m\") = 0.05; input Real L(quantity = \"Length\", unit = \"m\") = 1.0; output kc_evenGapLaminar_IN_con$m_flow_IN_con_4 res; end Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con$m_flow_IN_con_4; function Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var \"Automatically generated record constructor for Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var\" input Real cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); input Real eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0); input Real lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\"); input Real rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0); input Real m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\"); output kc_evenGapLaminar_IN_var res; end Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var; function Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var$m_flow_IN_var_1 \"Automatically generated record constructor for Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var$m_flow_IN_var_1\" input Real cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); input Real eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0); input Real lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\"); input Real rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0); input Real m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\"); output kc_evenGapLaminar_IN_var$m_flow_IN_var_1 res; end Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var$m_flow_IN_var_1; function Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var$m_flow_IN_var_2 \"Automatically generated record constructor for Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var$m_flow_IN_var_2\" input Real cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); input Real eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0); input Real lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\"); input Real rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0); input Real m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\"); output kc_evenGapLaminar_IN_var$m_flow_IN_var_2 res; end Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var$m_flow_IN_var_2; function Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var$m_flow_IN_var_3 \"Automatically generated record constructor for Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var$m_flow_IN_var_3\" input Real cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); input Real eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0); input Real lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\"); input Real rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0); input Real m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\"); output kc_evenGapLaminar_IN_var$m_flow_IN_var_3 res; end Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var$m_flow_IN_var_3; function Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var$m_flow_IN_var_4 \"Automatically generated record constructor for Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var$m_flow_IN_var_4\" input Real cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\"); input Real eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0); input Real lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\"); input Real rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0); input Real m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\"); output kc_evenGapLaminar_IN_var$m_flow_IN_var_4 res; end Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var$m_flow_IN_var_4; function Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_KC input Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con IN_con; input Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var IN_var; output Real kc(quantity = \"CoefficientOfHeatTransfer\", unit = \"W/(m2.K)\"); protected Real MIN = 1e-15; protected Real d_hyd(quantity = \"Length\", unit = \"m\", min = 0.0) = 2.0 * IN_con.s; protected Real A_cross(quantity = \"Area\", unit = \"m2\") = max(MIN, IN_con.s * IN_con.h); protected Real Pr(quantity = \"PrandtlNumber\", unit = \"1\") = abs(IN_var.eta * IN_var.cp / max(MIN, IN_var.lambda)); protected Real Nu_1(quantity = \"NusseltNumber\", unit = \"1\") = if IN_con.target == Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevOne or IN_con.target == Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevOne then 4.861 else if IN_con.target == Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevBoth or IN_con.target == Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevBoth then 7.541 else 0.0; protected Real velocity(quantity = \"Velocity\", unit = \"m/s\") = abs(IN_var.m_flow) / max(MIN, IN_var.rho * A_cross); protected Real Re(quantity = \"ReynoldsNumber\", unit = \"1\") = max(1.0, IN_var.rho * velocity * d_hyd / max(MIN, IN_var.eta)); protected Real Nu_2(quantity = \"NusseltNumber\", unit = \"1\") = 1.841 * (Re * Pr * d_hyd / max(IN_con.L, MIN)) ^ 0.3333333333333333; protected Real Nu_3(quantity = \"NusseltNumber\", unit = \"1\") = if IN_con.target == Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevOne or IN_con.target == Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevBoth then (2.0 / (1.0 + 22.0 * Pr)) ^ 0.1666666666666667 * (Re * Pr * d_hyd / max(IN_con.L, MIN)) ^ 0.5 else 0.0; protected Real Nu(quantity = \"NusseltNumber\", unit = \"1\") = (Nu_1 ^ 3.0 + Nu_2 ^ 3.0 + Nu_3 ^ 3.0) ^ 0.3333333333333333; algorithm kc := Nu * IN_var.lambda / max(MIN, d_hyd); end Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_KC; class ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar parameter Integer n = 3; parameter Real d_hyd(quantity = \"Length\", unit = \"m\", min = 0.0) = 2.0 * s; Real abscissa[1]; Real abscissa[2]; Real abscissa[3]; Real length(quantity = \"Length\", unit = \"m\") = L; Real dimlesslength(quantity = \"Length\", unit = \"m\", start = 0.01); Real Pr[1](quantity = \"PrandtlNumber\", unit = \"1\"); Real Pr[2](quantity = \"PrandtlNumber\", unit = \"1\"); Real Pr[3](quantity = \"PrandtlNumber\", unit = \"1\"); Real Re[1](quantity = \"ReynoldsNumber\", unit = \"1\"); Real Re[2](quantity = \"ReynoldsNumber\", unit = \"1\"); Real Re[3](quantity = \"ReynoldsNumber\", unit = \"1\"); Real velocity[1](quantity = \"Velocity\", unit = \"m/s\"); Real velocity[2](quantity = \"Velocity\", unit = \"m/s\"); Real velocity[3](quantity = \"Velocity\", unit = \"m/s\"); parameter Real h(quantity = \"Length\", unit = \"m\") = 0.1; parameter Real s(quantity = \"Length\", unit = \"m\") = 0.05; parameter Real L(quantity = \"Length\", unit = \"m\") = 1.0; parameter Real cp[1](quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = 1007.0; parameter Real cp[2](quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = 4189.0; parameter Real cp[3](quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = 3384.55; parameter Real eta[1](quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = 1.824e-05; parameter Real eta[2](quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = 0.0010016; parameter Real eta[3](quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = 0.114; parameter Real lambda[1](quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = 0.02569; parameter Real lambda[2](quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = 0.5985; parameter Real lambda[3](quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = 0.387; parameter Real rho[1](quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = 1.188; parameter Real rho[2](quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = 998.21; parameter Real rho[3](quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = 1037.799; enumeration(DevOne, DevBoth, UndevOne, UndevBoth) m_flow_IN_con_1[1].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevOne; Real m_flow_IN_con_1[1].h(quantity = \"Length\", unit = \"m\") = h; Real m_flow_IN_con_1[1].s(quantity = \"Length\", unit = \"m\") = s; Real m_flow_IN_con_1[1].L(quantity = \"Length\", unit = \"m\") = L; enumeration(DevOne, DevBoth, UndevOne, UndevBoth) m_flow_IN_con_1[2].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevOne; Real m_flow_IN_con_1[2].h(quantity = \"Length\", unit = \"m\") = h; Real m_flow_IN_con_1[2].s(quantity = \"Length\", unit = \"m\") = s; Real m_flow_IN_con_1[2].L(quantity = \"Length\", unit = \"m\") = L; enumeration(DevOne, DevBoth, UndevOne, UndevBoth) m_flow_IN_con_1[3].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevOne; Real m_flow_IN_con_1[3].h(quantity = \"Length\", unit = \"m\") = h; Real m_flow_IN_con_1[3].s(quantity = \"Length\", unit = \"m\") = s; Real m_flow_IN_con_1[3].L(quantity = \"Length\", unit = \"m\") = L; Real m_flow_IN_var_1[1].cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = cp[1]; Real m_flow_IN_var_1[1].eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = eta[1]; Real m_flow_IN_var_1[1].lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = lambda[1]; Real m_flow_IN_var_1[1].rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = rho[1]; Real m_flow_IN_var_1[1].m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\") = m_flow[1]; Real m_flow_IN_var_1[2].cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = cp[2]; Real m_flow_IN_var_1[2].eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = eta[2]; Real m_flow_IN_var_1[2].lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = lambda[2]; Real m_flow_IN_var_1[2].rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = rho[2]; Real m_flow_IN_var_1[2].m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\") = m_flow[2]; Real m_flow_IN_var_1[3].cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = cp[3]; Real m_flow_IN_var_1[3].eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = eta[3]; Real m_flow_IN_var_1[3].lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = lambda[3]; Real m_flow_IN_var_1[3].rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = rho[3]; Real m_flow_IN_var_1[3].m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\") = m_flow[3]; enumeration(DevOne, DevBoth, UndevOne, UndevBoth) m_flow_IN_con_2[1].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevBoth; Real m_flow_IN_con_2[1].h(quantity = \"Length\", unit = \"m\") = h; Real m_flow_IN_con_2[1].s(quantity = \"Length\", unit = \"m\") = s; Real m_flow_IN_con_2[1].L(quantity = \"Length\", unit = \"m\") = L; enumeration(DevOne, DevBoth, UndevOne, UndevBoth) m_flow_IN_con_2[2].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevBoth; Real m_flow_IN_con_2[2].h(quantity = \"Length\", unit = \"m\") = h; Real m_flow_IN_con_2[2].s(quantity = \"Length\", unit = \"m\") = s; Real m_flow_IN_con_2[2].L(quantity = \"Length\", unit = \"m\") = L; enumeration(DevOne, DevBoth, UndevOne, UndevBoth) m_flow_IN_con_2[3].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.DevBoth; Real m_flow_IN_con_2[3].h(quantity = \"Length\", unit = \"m\") = h; Real m_flow_IN_con_2[3].s(quantity = \"Length\", unit = \"m\") = s; Real m_flow_IN_con_2[3].L(quantity = \"Length\", unit = \"m\") = L; Real m_flow_IN_var_2[1].cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = cp[1]; Real m_flow_IN_var_2[1].eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = eta[1]; Real m_flow_IN_var_2[1].lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = lambda[1]; Real m_flow_IN_var_2[1].rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = rho[1]; Real m_flow_IN_var_2[1].m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\") = m_flow[1]; Real m_flow_IN_var_2[2].cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = cp[2]; Real m_flow_IN_var_2[2].eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = eta[2]; Real m_flow_IN_var_2[2].lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = lambda[2]; Real m_flow_IN_var_2[2].rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = rho[2]; Real m_flow_IN_var_2[2].m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\") = m_flow[2]; Real m_flow_IN_var_2[3].cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = cp[3]; Real m_flow_IN_var_2[3].eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = eta[3]; Real m_flow_IN_var_2[3].lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = lambda[3]; Real m_flow_IN_var_2[3].rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = rho[3]; Real m_flow_IN_var_2[3].m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\") = m_flow[3]; enumeration(DevOne, DevBoth, UndevOne, UndevBoth) m_flow_IN_con_3[1].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevOne; Real m_flow_IN_con_3[1].h(quantity = \"Length\", unit = \"m\") = h; Real m_flow_IN_con_3[1].s(quantity = \"Length\", unit = \"m\") = s; Real m_flow_IN_con_3[1].L(quantity = \"Length\", unit = \"m\") = L; enumeration(DevOne, DevBoth, UndevOne, UndevBoth) m_flow_IN_con_3[2].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevOne; Real m_flow_IN_con_3[2].h(quantity = \"Length\", unit = \"m\") = h; Real m_flow_IN_con_3[2].s(quantity = \"Length\", unit = \"m\") = s; Real m_flow_IN_con_3[2].L(quantity = \"Length\", unit = \"m\") = L; enumeration(DevOne, DevBoth, UndevOne, UndevBoth) m_flow_IN_con_3[3].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevOne; Real m_flow_IN_con_3[3].h(quantity = \"Length\", unit = \"m\") = h; Real m_flow_IN_con_3[3].s(quantity = \"Length\", unit = \"m\") = s; Real m_flow_IN_con_3[3].L(quantity = \"Length\", unit = \"m\") = L; Real m_flow_IN_var_3[1].cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = cp[1]; Real m_flow_IN_var_3[1].eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = eta[1]; Real m_flow_IN_var_3[1].lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = lambda[1]; Real m_flow_IN_var_3[1].rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = rho[1]; Real m_flow_IN_var_3[1].m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\") = m_flow[1]; Real m_flow_IN_var_3[2].cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = cp[2]; Real m_flow_IN_var_3[2].eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = eta[2]; Real m_flow_IN_var_3[2].lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = lambda[2]; Real m_flow_IN_var_3[2].rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = rho[2]; Real m_flow_IN_var_3[2].m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\") = m_flow[2]; Real m_flow_IN_var_3[3].cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = cp[3]; Real m_flow_IN_var_3[3].eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = eta[3]; Real m_flow_IN_var_3[3].lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = lambda[3]; Real m_flow_IN_var_3[3].rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = rho[3]; Real m_flow_IN_var_3[3].m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\") = m_flow[3]; enumeration(DevOne, DevBoth, UndevOne, UndevBoth) m_flow_IN_con_4[1].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevBoth; Real m_flow_IN_con_4[1].h(quantity = \"Length\", unit = \"m\") = h; Real m_flow_IN_con_4[1].s(quantity = \"Length\", unit = \"m\") = s; Real m_flow_IN_con_4[1].L(quantity = \"Length\", unit = \"m\") = L; enumeration(DevOne, DevBoth, UndevOne, UndevBoth) m_flow_IN_con_4[2].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevBoth; Real m_flow_IN_con_4[2].h(quantity = \"Length\", unit = \"m\") = h; Real m_flow_IN_con_4[2].s(quantity = \"Length\", unit = \"m\") = s; Real m_flow_IN_con_4[2].L(quantity = \"Length\", unit = \"m\") = L; enumeration(DevOne, DevBoth, UndevOne, UndevBoth) m_flow_IN_con_4[3].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_evenGap.UndevBoth; Real m_flow_IN_con_4[3].h(quantity = \"Length\", unit = \"m\") = h; Real m_flow_IN_con_4[3].s(quantity = \"Length\", unit = \"m\") = s; Real m_flow_IN_con_4[3].L(quantity = \"Length\", unit = \"m\") = L; Real m_flow_IN_var_4[1].cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = cp[1]; Real m_flow_IN_var_4[1].eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = eta[1]; Real m_flow_IN_var_4[1].lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = lambda[1]; Real m_flow_IN_var_4[1].rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = rho[1]; Real m_flow_IN_var_4[1].m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\") = m_flow[1]; Real m_flow_IN_var_4[2].cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = cp[2]; Real m_flow_IN_var_4[2].eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = eta[2]; Real m_flow_IN_var_4[2].lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = lambda[2]; Real m_flow_IN_var_4[2].rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = rho[2]; Real m_flow_IN_var_4[2].m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\") = m_flow[2]; Real m_flow_IN_var_4[3].cp(quantity = \"SpecificHeatCapacity\", unit = \"J/(kg.K)\") = cp[3]; Real m_flow_IN_var_4[3].eta(quantity = \"DynamicViscosity\", unit = \"Pa.s\", min = 0.0) = eta[3]; Real m_flow_IN_var_4[3].lambda(quantity = \"ThermalConductivity\", unit = \"W/(m.K)\") = lambda[3]; Real m_flow_IN_var_4[3].rho(quantity = \"Density\", unit = \"kg/m3\", displayUnit = \"g/cm3\", min = 0.0) = rho[3]; Real m_flow_IN_var_4[3].m_flow(quantity = \"MassFlowRate\", unit = \"kg/s\") = m_flow[3]; Real Nu_1[1](quantity = \"NusseltNumber\", unit = \"1\"); Real Nu_1[2](quantity = \"NusseltNumber\", unit = \"1\"); Real Nu_1[3](quantity = \"NusseltNumber\", unit = \"1\"); Real Nu_2[1](quantity = \"NusseltNumber\", unit = \"1\"); Real Nu_2[2](quantity = \"NusseltNumber\", unit = \"1\"); Real Nu_2[3](quantity = \"NusseltNumber\", unit = \"1\"); Real Nu_3[1](quantity = \"NusseltNumber\", unit = \"1\"); Real Nu_3[2](quantity = \"NusseltNumber\", unit = \"1\"); Real Nu_3[3](quantity = \"NusseltNumber\", unit = \"1\"); Real Nu_4[1](quantity = \"NusseltNumber\", unit = \"1\"); Real Nu_4[2](quantity = \"NusseltNumber\", unit = \"1\"); Real Nu_4[3](quantity = \"NusseltNumber\", unit = \"1\"); protected Real m_flow[1](quantity = \"MassFlowRate\", unit = \"kg/s\"); protected Real m_flow[2](quantity = \"MassFlowRate\", unit = \"kg/s\"); protected Real m_flow[3](quantity = \"MassFlowRate\", unit = \"kg/s\"); equation abscissa = {(length / (d_hyd * max(Re[1], 0.001) * Pr[1])) ^ 0.5, (length / (d_hyd * max(Re[2], 0.001) * Pr[2])) ^ 0.5, (length / (d_hyd * max(Re[3], 0.001) * Pr[3])) ^ 0.5}; Pr = {eta[1] * cp[1] / lambda[1], eta[2] * cp[2] / lambda[2], eta[3] * cp[3] / lambda[3]}; Re = {rho[1] * velocity[1] * d_hyd / eta[1], rho[2] * velocity[2] * d_hyd / eta[2], rho[3] * velocity[3] * d_hyd / eta[3]}; velocity = {m_flow[1] / (s * h * rho[1]), m_flow[2] / (s * h * rho[2]), m_flow[3] / (s * h * rho[3])}; m_flow = {0.5 * h * lambda[1] * length / (dimlesslength ^ 2.0 * d_hyd * cp[1]), 0.5 * h * lambda[2] * length / (dimlesslength ^ 2.0 * d_hyd * cp[2]), 0.5 * h * lambda[3] * length / (dimlesslength ^ 2.0 * d_hyd * cp[3])}; der(dimlesslength) = 0.99; (_, _, _, Nu_1[1], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_1[1]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_1[1])); (_, _, _, Nu_1[2], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_1[2]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_1[2])); (_, _, _, Nu_1[3], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_1[3]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_1[3])); (_, _, _, Nu_2[1], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_2[1]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_2[1])); (_, _, _, Nu_2[2], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_2[2]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_2[2])); (_, _, _, Nu_2[3], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_2[3]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_2[3])); (_, _, _, Nu_3[1], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_3[1]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_3[1])); (_, _, _, Nu_3[2], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_3[2]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_3[2])); (_, _, _, Nu_3[3], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_3[3]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_3[3])); (_, _, _, Nu_4[1], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_4[1]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_4[1])); (_, _, _, Nu_4[2], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_4[2]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_4[2])); (_, _, _, Nu_4[3], _) = Modelica.Fluid.DissipUnexpected end of /proc/mounts line `overlay / overlay rw,relatime,lowerdir=/var/lib/docker/overlay2/l/CM3C2UP6O2ZBUJT7NNGQ3RA4O2:/var/lib/docker/overlay2/l/OFBQHWN5VWB3ZDIVLSEHB4ZZO7:/var/lib/docker/overlay2/l/XKNAMZMLHIGLUIWZN6NHS4LQOB:/var/lib/docker/overlay2/l/XDXTSPLZ4IFADJTBU5VPCFEWAO:/var/lib/docker/overlay2/l/TLE42ND4WLQ5HMCG4FABWZYYBM:/var/lib/docker/overlay2/l/N2ZO5AQSQ6RGU55LFPZO3NSFIG:/var/lib/docker/overlay2/l/AFXOGW55ZNK4NUDS4WEZ6VE76H:/var/lib/docker/overlay2/l/KJ36F2MJVNS5N45ELI4N3CNXLN:/var/lib/docker/overlay2/l/SFDLWMOUVQFPH' Unexpected end of /proc/mounts line `overlay / overlay rw,relatime,lowerdir=/var/lib/docker/overlay2/l/CM3C2UP6O2ZBUJT7NNGQ3RA4O2:/var/lib/docker/overlay2/l/OFBQHWN5VWB3ZDIVLSEHB4ZZO7:/var/lib/docker/overlay2/l/XKNAMZMLHIGLUIWZN6NHS4LQOB:/var/lib/docker/overlay2/l/XDXTSPLZ4IFADJTBU5VPCFEWAO:/var/lib/docker/overlay2/l/TLE42ND4WLQ5HMCG4FABWZYYBM:/var/lib/docker/overlay2/l/N2ZO5AQSQ6RGU55LFPZO3NSFIG:/var/lib/docker/overlay2/l/AFXOGW55ZNK4NUDS4WEZ6VE76H:/var/lib/docker/overlay2/l/KJ36F2MJVNS5N45ELI4N3CNXLN:/var/lib/docker/overlay2/l/SFDLWMOUVQFPH' Unexpected end of /proc/mounts line `overlay / overlay rw,relatime,lowerdir=/var/lib/docker/overlay2/l/CM3C2UP6O2ZBUJT7NNGQ3RA4O2:/var/lib/docker/overlay2/l/OFBQHWN5VWB3ZDIVLSEHB4ZZO7:/var/lib/docker/overlay2/l/XKNAMZMLHIGLUIWZN6NHS4LQOB:/var/lib/docker/overlay2/l/XDXTSPLZ4IFADJTBU5VPCFEWAO:/var/lib/docker/overlay2/l/TLE42ND4WLQ5HMCG4FABWZYYBM:/var/lib/docker/overlay2/l/N2ZO5AQSQ6RGU55LFPZO3NSFIG:/var/lib/docker/overlay2/l/AFXOGW55ZNK4NUDS4WEZ6VE76H:/var/lib/docker/overlay2/l/KJ36F2MJVNS5N45ELI4N3CNXLN:/var/lib/docker/overlay2/l/SFDLWMOUVQFPH' ation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_4[3]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_4[3])); end ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar; " "" "Check of ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar completed successfully. Class ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar has 137 equation(s) and 137 variable(s). 110 of these are trivial equation(s)." "" record SimulationResult resultFile = "ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar_res.mat", simulationOptions = "startTime = 0.0, stopTime = 1.0, numberOfIntervals = 500, tolerance = 1e-06, method = 'dassl', fileNamePrefix = 'ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar', options = '', outputFormat = 'mat', variableFilter = '.*', cflags = '', simflags = ''", messages = "LOG_SUCCESS | info | The initialization finished successfully without homotopy method. LOG_SUCCESS | info | The simulation finished successfully. " end SimulationResult; "Warning: The initial conditions are not fully specified. For more information set -d=initialization. In OMEdit Tools->Options->Simulation->OMCFlags, in OMNotebook call setCommandLineOptions("-d=initialization"). " Equation mismatch: diff says: --- /tmp/omc-rtest-unknown/simulation/modelica/algorithms_functions/ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar.mos_temp8074/equations-expected2019-01-25 00:40:33.682118257 +0000 +++ /tmp/omc-rtest-unknown/simulation/modelica/algorithms_functions/ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar.mos_temp8074/equations-got2019-01-25 00:40:36.322088958 +0000 @@ -352,11 +352,12 @@ (_, _, _, Nu_3[1], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_3[1]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_3[1])); (_, _, _, Nu_3[2], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_3[2]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_3[2])); (_, _, _, Nu_3[3], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_3[3]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_3[3])); (_, _, _, Nu_4[1], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_4[1]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_4[1])); (_, _, _, Nu_4[2], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_4[2]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_4[2])); -(_, _, _, Nu_4[3], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_4[3]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_4[3])); +(_, _, _, Nu_4[3], _) = Modelica.Fluid.DissipUnexpected end of /proc/mounts line `overlay / overlay rw,relatime,lowerdir=/var/lib/docker/overlay2/l/CM3C2UP6O2ZBUJT7NNGQ3RA4O2:/var/lib/docker/overlay2/l/OFBQHWN5VWB3ZDIVLSEHB4ZZO7:/var/lib/docker/overlay2/l/XKNAMZMLHIGLUIWZN6NHS4LQOB:/var/lib/docker/overlay2/l/XDXTSPLZ4IFADJTBU5VPCFEWAO:/var/lib/docker/overlay2/l/TLE42ND4WLQ5HMCG4FABWZYYBM:/var/lib/docker/overlay2/l/N2ZO5AQSQ6RGU55LFPZO3NSFIG:/var/lib/docker/overlay2/l/AFXOGW55ZNK4NUDS4WEZ6VE76H:/var/lib/docker/overlay2/l/KJ36F2MJVNS5N45ELI4N3CNXLN:/var/lib/docker/overlay2/l/SFDLWMOUVQFPH' +ation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_4[3]), /*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_var*/(m_flow_IN_var_4[3])); end ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar; " "" "Check of ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar completed successfully. Class ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar has 137 equation(s) and 137 variable(s). Equation mismatch: omc-diff says: Failed 'a' 'U' Line 357: Text differs: expected: ], _) = Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar(/*.Modelica.Fluid.Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_IN_con*/(m_flow_IN_con_ got: ], _) = Modelica.Fluid.DissipUnexpected end of /proc/mounts line `overlay / overlay rw,relatime,lowerdir=/var/lib/docker/overlay == 1 out of 1 tests failed [simulation/modelica/algorithms_functions/ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.Channel.kc_evenGapLaminar.mos_temp8074, time: 3]