Modelica_3_2_1_Build_4 with alias name: Version 1 | Modelica_3_2_1_Build_2 with alias name: Version 2 | Version: 3.2.1 Build 4 | Version: 3.2.1 Build 2 |
Version date: 2015-09-30 | Version date: 2013-08-14 |
Equations in Version 1 | Equations in Version 2 |
initial equation pre(u) = fill(false, nu); |
Component |
Version 1 |
Version 2 |
mean | final x0=x0 | |
x0 | Present |
Component |
Version 1 |
Version 2 |
mean | final x0=x0 | |
x0 | Present |
Component |
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Version 2 |
mean1 | final x0=x0Cos | |
mean2 | final x0=x0Sin | |
x0Cos | Present | |
x0Sin | Present |
Component |
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Version 2 |
Falling | max=-small | |
| min=-small |
Component |
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Vknee | =0 | |
| start=0 |
Component |
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Version 2 |
Vknee | =0 | |
| start=0 |
Component |
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Version 2 |
Vknee | =0 | |
| start=0 |
Component |
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Version 2 |
Ron | | graphical |
Goff | | graphical |
Component |
Version 1 |
Version 2 |
Ron | | graphical |
Goff | | graphical |
Component |
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Version 2 |
level | | graphical |
Ron | | graphical |
Goff | | graphical |
Component |
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Version 2 |
level | | graphical |
Ron | | graphical |
Goff | | graphical |
Component |
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Version 2 |
tSwitch | fixed=true | |
Component |
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Version 2 |
tSwitch | fixed=true | |
Component |
Version 1 |
Version 2 |
level | | graphical |
Ron | | graphical |
Goff | | graphical |
tSwitch | fixed=true | |
Component |
Version 1 |
Version 2 |
level | | graphical |
Ron | | graphical |
Goff | | graphical |
tSwitch | fixed=true | |
Component |
Version 1 |
Version 2 |
z | start=0 | |
fixed=true | |
Component |
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Version 2 |
vout | start=0 | |
fixed=true | | |
y | fixed=true | |
Component |
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Version 2 |
T0 | fixed=true | |
Component |
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Version 2 |
t_i | fixed=true | |
Component |
Version 1 |
Version 2 |
w_meas | SIunits.AngularVelocity | SIunits.Current |
pf_meas | Real | SIunits.Current |
eff_meas | Real | SIunits.Current |
Component |
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Version 2 |
smr | ir(each fixed=true) | |
| ir(fixed=true) |
Component |
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Version 2 |
smpm | ir(each fixed=true) | |
| ir(fixed=true) |
Component |
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Version 2 |
smee | ir(each fixed=true) | |
| ir(fixed=true) |
Component |
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Version 2 |
smee | | ir(fixed=true) |
Component |
Version 1 |
Version 2 |
smee | ir(each fixed=true) | |
| ir(fixed=true) |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_n2, core.plug_p3); |
|
connect(core.plug_p2, l2sigma.plug_n); | connect(core.plug_p2, l2sigma.plug_p); |
connect(core.plug_n3, star2.plug_p); |
Equations in Version 1 | Equations in Version 2 |
... connect(star2.pin_n, starpoint2); |
|
connect(l2sigma.plug_n, Rot2.plug_p); | connect(l2sigma.plug_p, Rot2.plug_p); |
connect(l1sigma.plug_n, core.plug_p1); ... |
Equations in Version 1 | Equations in Version 2 |
... connect(star2.pin_n, starpoint2); |
|
connect(Rot2.plug_n, l2sigma.plug_n); | connect(Rot2.plug_n, l2sigma.plug_p); |
connect(l1sigma.plug_n, core.plug_p1); ... |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_n2, core.plug_p3); |
|
connect(l2sigma.plug_n, core.plug_n3); | connect(l2sigma.plug_p, core.plug_n3); |
connect(core.plug_p2, star2.plug_p); |
Equations in Version 1 | Equations in Version 2 |
... connect(star2.pin_n, starpoint2); |
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connect(Rot2.plug_p, l2sigma.plug_n); | connect(Rot2.plug_p, l2sigma.plug_p); |
connect(l1sigma.plug_n, core.plug_p1); ... |
Equations in Version 1 | Equations in Version 2 |
... connect(star2.pin_n, starpoint2); |
|
connect(l2sigma.plug_n, Rot2.plug_n); | connect(l2sigma.plug_p, Rot2.plug_n); |
connect(l1sigma.plug_n, core.plug_p1); ... |
Equations in Version 1 | Equations in Version 2 |
connect(star1.pin_n, starpoint1); | |
connect(Delta2.plug_p, r2.plug_p); | connect(Delta2.plug_p, r2.plug_n); |
connect(l1sigma.plug_n, core.plug_p1); ... connect(core.plug_n3, Delta2.plug_n); |
|
connect(core.plug_p2, l2sigma.plug_n); | connect(core.plug_p2, l2sigma.plug_p); |
Equations in Version 1 | Equations in Version 2 |
connect(star1.pin_n, starpoint1); | |
connect(Delta2.plug_n, r2.plug_p); | connect(Delta2.plug_n, r2.plug_n); |
connect(l2sigma.plug_n, Rot2.plug_p); | connect(l2sigma.plug_p, Rot2.plug_p); |
connect(l1sigma.plug_n, core.plug_p1); ... |
Equations in Version 1 | Equations in Version 2 |
connect(star1.pin_n, starpoint1); | |
connect(Delta2.plug_n, r2.plug_p); | connect(Delta2.plug_n, r2.plug_n); |
connect(l1sigma.plug_n, core.plug_p1); ... connect(core.plug_n2, core.plug_p3); |
|
connect(core.plug_n3, l2sigma.plug_n); | connect(core.plug_n3, l2sigma.plug_p); |
connect(core.plug_p2, Delta2.plug_p); |
Equations in Version 1 | Equations in Version 2 |
connect(star1.pin_n, starpoint1); | |
connect(Delta2.plug_p, r2.plug_p); | connect(Delta2.plug_p, r2.plug_n); |
connect(l1sigma.plug_n, core.plug_p1); ... connect(core.plug_p2, Delta2.plug_n); |
|
connect(l2sigma.plug_n, core.plug_n3); | connect(l2sigma.plug_p, core.plug_n3); |
Equations in Version 1 | Equations in Version 2 |
connect(star1.pin_n, starpoint1); | |
connect(Rot2.plug_p, l2sigma.plug_n); | connect(Rot2.plug_p, l2sigma.plug_p); |
connect(Delta2.plug_n, r2.plug_p); | connect(Delta2.plug_n, r2.plug_n); |
connect(l1sigma.plug_n, core.plug_p1); ... |
Equations in Version 1 | Equations in Version 2 |
connect(star1.pin_n, starpoint1); | |
connect(Delta2.plug_n, r2.plug_p); | connect(Delta2.plug_n, r2.plug_n); |
connect(l1sigma.plug_n, core.plug_p1); ... connect(core.plug_n3, Delta2.plug_p); |
|
connect(core.plug_p2, l2sigma.plug_n); | connect(core.plug_p2, l2sigma.plug_p); |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_p3, Rot21.plug_p); |
|
connect(l2sigma.plug_n, Rot22.plug_p); | connect(l2sigma.plug_p, Rot22.plug_p); |
connect(Rot22.plug_n, core.plug_n2); ... |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_p3, Rot21.plug_n); |
|
connect(l2sigma.plug_n, Rot22.plug_p); | connect(l2sigma.plug_p, Rot22.plug_p); |
connect(Rot22.plug_n, core.plug_n2); ... |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_n3, star2.plug_p); |
|
connect(l2sigma.plug_n, core.plug_n2); | connect(l2sigma.plug_p, core.plug_n2); |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_p3, Rot21.plug_n); |
|
connect(l2sigma.plug_n, core.plug_n2); | connect(l2sigma.plug_p, core.plug_n2); |
connect(core.plug_n3, star2.plug_p); |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_n3, star2.plug_p); |
|
connect(l2sigma.plug_n, Rot22.plug_n); | connect(l2sigma.plug_p, Rot22.plug_n); |
connect(Rot22.plug_p, core.plug_n2); |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_p3, Rot21.plug_n); |
|
connect(l2sigma.plug_n, Rot22.plug_n); | connect(l2sigma.plug_p, Rot22.plug_n); |
connect(Rot22.plug_p, core.plug_n2); ... |
Equations in Version 1 | Equations in Version 2 |
connect(star2.pin_n, starpoint2); | |
connect(l2sigma.plug_n, Rot2.plug_p); | connect(l2sigma.plug_p, Rot2.plug_p); |
connect(Delta1.plug_p, r1.plug_p); ... |
Equations in Version 1 | Equations in Version 2 |
connect(star2.pin_n, starpoint2); | |
connect(Rot2.plug_n, l2sigma.plug_n); | connect(Rot2.plug_n, l2sigma.plug_p); |
connect(Delta1.plug_p, r1.plug_p); ... |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_n2, core.plug_p3); |
|
connect(l2sigma.plug_n, core.plug_n3); | connect(l2sigma.plug_p, core.plug_n3); |
connect(core.plug_p2, star2.plug_p); |
Equations in Version 1 | Equations in Version 2 |
... connect(r1.plug_p, Delta1.plug_p); |
|
connect(Rot2.plug_p, l2sigma.plug_n); | connect(Rot2.plug_p, l2sigma.plug_p); |
connect(l1sigma.plug_n, core.plug_p1); ... |
Equations in Version 1 | Equations in Version 2 |
... connect(r1.plug_p, Delta1.plug_p); |
|
connect(l2sigma.plug_n, Rot2.plug_n); | connect(l2sigma.plug_p, Rot2.plug_n); |
connect(l1sigma.plug_n, core.plug_p1); ... |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_n3, star2.plug_p); |
|
connect(core.plug_p2, l2sigma.plug_n); | connect(core.plug_p2, l2sigma.plug_p); |
Equations in Version 1 | Equations in Version 2 |
connect(r1.plug_p, Delta1.plug_p); | |
connect(Delta2.plug_p, r2.plug_p); | connect(Delta2.plug_p, r2.plug_n); |
connect(l1sigma.plug_n, core.plug_p1); ... connect(core.plug_n2, core.plug_p3); |
|
connect(core.plug_p2, l2sigma.plug_n); | connect(core.plug_p2, l2sigma.plug_p); |
connect(core.plug_n3, Delta2.plug_n); |
Equations in Version 1 | Equations in Version 2 |
connect(r1.plug_p, Delta1.plug_p); | |
connect(Delta2.plug_n, r2.plug_p); | connect(Delta2.plug_n, r2.plug_n); |
connect(l2sigma.plug_n, Rot2.plug_p); | connect(l2sigma.plug_p, Rot2.plug_p); |
connect(l1sigma.plug_n, core.plug_p1); ... |
Equations in Version 1 | Equations in Version 2 |
connect(r1.plug_p, Delta1.plug_p); | |
connect(Delta2.plug_n, r2.plug_p); | connect(Delta2.plug_n, r2.plug_n); |
connect(l1sigma.plug_n, core.plug_p1); ... connect(core.plug_p2, Delta2.plug_p); |
|
connect(core.plug_n3, l2sigma.plug_n); | connect(core.plug_n3, l2sigma.plug_p); |
Equations in Version 1 | Equations in Version 2 |
connect(Delta2.plug_p, r2.plug_p); | connect(Delta2.plug_p, r2.plug_n); |
connect(Delta1.plug_p, r1.plug_p); ... connect(Delta2.plug_n, core.plug_p2); |
|
connect(core.plug_n3, l2sigma.plug_n); | connect(core.plug_n3, l2sigma.plug_p); |
Equations in Version 1 | Equations in Version 2 |
connect(r1.plug_p, Delta1.plug_p); | |
connect(Delta2.plug_n, r2.plug_p); | connect(Delta2.plug_n, r2.plug_n); |
connect(Rot2.plug_p, l2sigma.plug_n); | connect(Rot2.plug_p, l2sigma.plug_p); |
connect(l1sigma.plug_n, core.plug_p1); ... |
Equations in Version 1 | Equations in Version 2 |
connect(r1.plug_p, Delta1.plug_p); | |
connect(Delta2.plug_n, r2.plug_p); | connect(Delta2.plug_n, r2.plug_n); |
connect(l1sigma.plug_n, core.plug_p1); ... connect(core.plug_n2, core.plug_p3); |
|
connect(core.plug_p2, l2sigma.plug_n); | connect(core.plug_p2, l2sigma.plug_p); |
connect(core.plug_n3, Delta2.plug_p); |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_p3, Rot21.plug_p); |
|
connect(l2sigma.plug_n, Rot22.plug_p); | connect(l2sigma.plug_p, Rot22.plug_p); |
connect(Rot22.plug_n, core.plug_n2); ... |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_p3, Rot21.plug_n); |
|
connect(l2sigma.plug_n, Rot22.plug_p); | connect(l2sigma.plug_p, Rot22.plug_p); |
connect(Rot22.plug_n, core.plug_n2); ... |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_p3, Rot21.plug_p); |
|
connect(l2sigma.plug_n, core.plug_n2); | connect(l2sigma.plug_p, core.plug_n2); |
connect(core.plug_n3, star2.plug_p); |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_n3, star2.plug_p); |
|
connect(l2sigma.plug_n, core.plug_n2); | connect(l2sigma.plug_p, core.plug_n2); |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_n3, star2.plug_p); |
|
connect(l2sigma.plug_n, Rot22.plug_n); | connect(l2sigma.plug_p, Rot22.plug_n); |
connect(Rot22.plug_p, core.plug_n2); |
Equations in Version 1 | Equations in Version 2 |
... connect(core.plug_n3, star2.plug_p); |
|
connect(l2sigma.plug_n, Rot22.plug_n); | connect(l2sigma.plug_p, Rot22.plug_n); |
connect(Rot22.plug_p, core.plug_n2); |
Component |
Version 1 |
Version 2 |
coreParameters | | final m=m |
m | =coreParameters.m | =3 |
Component |
Version 1 |
Version 2 |
coreParameters | | final m=1 |
Component |
Version 1 |
Version 2 |
constT2 | final k=T2 | final k=T1 |
Component |
Version 1 |
Version 2 |
powerBalance | final power1=Machines.SpacePhasors.Functions.activePower(v1, i1) | final power1=Machines.SpacePhasors.Functions.activePower(v1, +i1) |
final power2=Machines.SpacePhasors.Functions.activePower(v2, i2) | final power2=Machines.SpacePhasors.Functions.activePower(v2, -i2) |
Equations in Version 1 | Equations in Version 2 |
connect(r1.plug_n, l1sigma.plug_p); | |
connect(l2sigma.plug_n,r2.plug_p); |
|
connect(plug1, r1.plug_p); | |
connect(r2.plug_n, plug2); |
|
connect(thermalPort, internalThermalPort); ... connect(r2.heatPort, internalThermalPort.heatPort2); |
|
connect(r2.plug_p, plug2); connect(l2sigma.plug_p, r2.plug_n); |
Equations in Version 1 | Equations in Version 2 |
... connect(idealDiode.n, plug_n.pin); |
|
connect(idealDiode.heatPort, heatPort); |
Component |
Version 1 |
Version 2 |
off | Present |
Equations in Version 1 | Equations in Version 2 |
off = idealThyristor.off; |
|
connect(plug_p.pin, idealThyristor.p); ... |
Equations in Version 1 | Equations in Version 2 |
... if j < m then |
|
connect(plugToPins_n.pin_n[j], plugToPins_p.pin_p[j + 1]); | connect(plugToPins_p.pin_p[j], plugToPins_n.pin_n[j+1]); |
else | |
connect(plugToPins_n.pin_n[j], plugToPins_p.pin_p[1]); | connect(plugToPins_p.pin_p[j], plugToPins_n.pin_n[1]); |
end if; ... |
Component |
Version 1 |
Version 2 |
currentP | final m=m | |
currentN | final m=m | |
voltageP | final m=m | |
voltageN | final m=m | |
Component |
Version 1 |
Version 2 |
X1 | X1(X1(X1(Q1(vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbc(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0))), X2(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true))), X3(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbe(start=0, fixed=true))), X4(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbe(start=0, fixed=true))), X5(Q1(vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbc(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbe(start=0, fixed=true))), X6(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0))), X7(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbe(start=0, fixed=true), vbc(start=0, fixed=true)), RC(v(start=0))), X8(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true))), X9(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), RC(v(start=0)))), X2(X1(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=false)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbc(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true))), X2(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), RC(v(start=0))), X3(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbe(start=0, fixed=true)), RC(v(start=0))), X4(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true))), X5(Q1(vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbe(start=0, fixed=true))), X6(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbe(start=0, fixed=true))), X7(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), RC(v(start=0))), X8(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true))), X9(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), RC(v(start=0))))) | X1(X1(X1(Q1(vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbc(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0))), X2(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true))), X3(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbe(start=0, fixed=true))), X4(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbe(start=0, fixed=true))), X5(Q1(vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbc(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbe(start=0, fixed=true))), X6(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0))), X7(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbe(start=0, fixed=true), vbc(start=0, fixed=true)), RC(v(start=0))), X8(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true))), X9(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), RC(v(start=0)))), X2(X1(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbc(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true))), X2(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), RC(v(start=0))), X3(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbe(start=0, fixed=true)), RC(v(start=0))), X4(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true))), X5(Q1(vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbe(start=0, fixed=true))), X6(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbe(start=0, fixed=true))), X7(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), RC(v(start=0))), X8(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true))), X9(Q1(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q2(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q3(Binternal(start=0), icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q4(icapbe(start=0), vbc(start=0, fixed=true), vbe(start=0, fixed=true)), Q5(vbc(start=0, fixed=true), vbe(start=0, fixed=true)), RC(v(start=0))))) |
Component |
Version 1 |
Version 2 |
T0 | fixed=true | |
Component |
Version 1 |
Version 2 |
T0 | fixed=true | |
Component |
Version 1 |
Version 2 |
in_vp | Electrical.Spice3.Internal.Mos2.Mos2ModelLineVariables | Electrical.Spice3.Internal.Mos.MosModelLineVariables |
Component |
Version 1 |
Version 2 |
in_vp | Electrical.Spice3.Internal.Mos2.Mos2ModelLineVariables | Electrical.Spice3.Internal.Mos.MosModelLineVariables |
Component |
Version 1 |
Version 2 |
in_qm | qm_capgb=0 | |
qm_capgs=0 | | |
qm_capgd=0 | | |
qm_qgs=0 | | |
qm_qgb=0 | | |
qm_qgd=0 | | |
qm_vgs=0 | | |
qm_vgb=0 | | |
qm_vgd=0 | | |
int_m | m_len=1e-4 | |
m_width=1e-4 | | |
m_drainArea=Spice3.Internal.SpiceConstants.CKTdefaultMosAD | | |
m_sourceArea=Spice3.Internal.SpiceConstants.CKTdefaultMosAS | | |
m_drainSquares=1.0 | | |
m_sourceSquares=1.0 | | |
m_drainPerimeter=0.0 | | |
m_sourcePerimeter=0.0 | | |
m_dICVDS=0.0 | | |
m_dICVDSIsGiven=0.0 | | |
m_dICVGS=0.0 | | |
m_dICVGSIsGiven=0.0 | | |
m_dICVBS=0.0 | | |
m_dICVBSIsGiven=0.0 | | |
m_off=0 | | |
m_bPMOS=0 | | |
m_nLevel=1 | | |
m_drainPerimiter=0.0 | | |
m_sourcePerimiter=0.0 | | |
m_uic=false | |
Component |
Version 1 |
Version 2 |
temp | Real | SIunits.Temp_K |
Equations in Version 1 | Equations in Version 2 |
algorithm |
|
temp := 0; | vce := in_p.m_type * (in_m_pVoltageValues[4] - in_m_pVoltageValues[6]); |
vce = in_p.m_type * (in_m_pVoltageValues[4] - in_m_pVoltageValues[6]); |
|
vbe = in_p.m_type * (in_m_pVoltageValues[5] - in_m_pVoltageValues[6]); ... if (in_p.m_transitTimeHighCurrentF <> 0) then |
|
temp = cbe / (cbe + in_p.m_transitTimeHighCurrentF); | cbe = cbe / (cbe + in_p.m_transitTimeHighCurrentF); |
argtf = argtf * temp * temp; ... |
Component |
Version 1 |
Version 2 |
smpmM | ir(each fixed=true) | |
| ir(fixed=true) | |
smpmE | ir(each fixed=true) | |
| ir(fixed=true) |
Component |
Version 1 |
Version 2 |
smpmM | ir(each fixed=true) | |
| ir(fixed=true) | |
smpm3 | ir(each fixed=true) | |
| ir(fixed=true) |
Component |
Version 1 |
Version 2 |
smeeM | ir(each fixed=true) | |
| ir(fixed=true) | |
smeeE | ir(each fixed=true) | |
| ir(fixed=true) |
Component |
Version 1 |
Version 2 |
smeeM | ir(each fixed=true) | |
| ir(fixed=true) | |
smee3 | ir(each fixed=true) | |
| ir(fixed=true) |
Component |
Version 1 |
Version 2 |
smrM | ir(each fixed=true) | |
| ir(fixed=true) | |
smrE | ir(each fixed=true) | |
| ir(fixed=true) |
Component |
Version 1 |
Version 2 |
smrM | ir(each fixed=true) | |
| ir(fixed=true) | |
smr3 | ir(each fixed=true) | |
| ir(fixed=true) |
Component |
Version 1 |
Version 2 |
world | gravitySphereDiameter=0.1 | |
Component |
Version 1 |
Version 2 |
world | redeclare function gravityAcceleration = Modelica.Mechanics.MultiBody.Examples.Elementary.Utilities.theoreticalNormalGravityWGS84 (phi=geodeticLatitude) | redeclare function gravityAcceleration = Modelica.Mechanics.MultiBody.Examples.Elementary.Utilities.theoreticalNormalGravityWGS84 (mue=1, phi=geodeticLatitude) |
Equations in Version 1 | Equations in Version 2 |
... frame_b.r_0 = frame_a.r_0; |
|
if Connections.rooted(frame_a.R) then | if rooted(frame_a.R) then |
R_rel = Frames.planarRotation(e, phi_offset + phi, w); ... |
Equations in Version 1 | Equations in Version 2 |
... frame_b.r_0 = frame_a.r_0; |
|
if Connections.rooted(frame_a.R) then | if rooted(frame_a.R) then |
R_rel_inv = Frames.nullRotation(); ... |
Equations in Version 1 | Equations in Version 2 |
... Connections.branch(frame_a.R, frame_b.R); |
|
if Connections.rooted(frame_a.R) then | if rooted(frame_a.R) then |
R_rel_inv = Frames.nullRotation(); ... |
Equations in Version 1 | Equations in Version 2 |
... R_rel = Frames.axesRotations(sequence_start,                                {angle[1], angle[2], angle[3]},                                {der(angle[1]), der(angle[2]), der(angle[3])}); |
|
if Connections.rooted(frame_a.R) then | if rooted(frame_a.R) then |
R_rel_inv = Frames.nullRotation(); ... |
Equations in Version 1 | Equations in Version 2 |
... frame_b.r_0 = frame_a.r_0 + Frames.resolve1(frame_a.R, r); |
|
if Connections.rooted(frame_a.R) then | if rooted(frame_a.R) then |
frame_b.R = Frames.absoluteRotation(frame_a.R, R_rel); ... |
Component |
Version 1 |
Version 2 |
J | min=0 | |
=1 | |
Component |
Version 1 |
Version 2 |
J | min=0 | |
=1 | |
Component |
Version 1 |
Version 2 |
c | =1e4 | |
d | =1 | |
springDamper | Mechanics.Rotational.Examples.Utilities.SpringDamperNoRelativeStates | Mechanics.Rotational.Components.SpringDamper |
Component |
Version 1 |
Version 2 |
c | =1e4 | |
Component |
Version 1 |
Version 2 |
interpolation_result | sizes=, 14 | sizes=, 1-1 |
eta_mf1 | unit="1" | |
eta_mf2 | unit="1" | |
tau_bf_a | SIunits.Torque | Real |
tau_eta | SIunits.Torque | Real |
tau_bf1 | SIunits.Torque | Real |
tau_bf2 | SIunits.Torque | Real |
quadrant1 | SIunits.Torque | Real |
quadrant2 | SIunits.Torque | Real |
quadrant3 | SIunits.Torque | Real |
quadrant4 | SIunits.Torque | Real |
quadrant1_p | SIunits.Torque | Real |
quadrant2_p | SIunits.Torque | Real |
quadrant3_m | SIunits.Torque | Real |
quadrant4_m | SIunits.Torque | Real |
eta_mf1_0 | =Modelica_3_2_1_Build_4.Math.Vectors.interpolate(lossTable[:, 1], lossTable[:, 2], 0, 1) | =interpolation_result_0[1, 1] |
unit="1" | | |
eta_mf2_0 | =Modelica_3_2_1_Build_4.Math.Vectors.interpolate(lossTable[:, 1], lossTable[:, 3], 0, 1) | =interpolation_result_0[1, 2] |
unit="1" | | |
tau_bf1_0 | SIunits.Torque | Real |
tau_bf2_0 | SIunits.Torque | Real |
tau_bf_a_0 | SIunits.Torque | Real |
interpolation_result_0 | Present |
Equations in Version 1 | Equations in Version 2 |
... ideal = Modelica_3_2_1_Build_4.Math.Matrices.isEqual(   lossTable,   [0,1,1,0,0],   Modelica_3_2_1_Build_4.Constants.eps); |
|
if ideal then | interpolation_result = if ideal then [1,1,0,0] else Modelica_3_2_1_Build_2.Math.tempInterpol2( noEvent(abs(w_a)), lossTable, {2,3,4,5}); |
interpolation_result = [1, 1, 0, 0]; eta_mf1 = 1; eta_mf2 = 1; tau_bf1 = 0; tau_bf2 = 0; else interpolation_result = [Modelica_3_2_1_Build_4.Math.Vectors.interpolate(     lossTable[:, 1],     lossTable[:, 2],     noEvent(abs(w_a)),     1),Modelica_3_2_1_Build_4.Math.Vectors.interpolate(     lossTable[:, 1],     lossTable[:, 3],     noEvent(abs(w_a)),     1),Modelica_3_2_1_Build_4.Math.Vectors.interpolate(     lossTable[:, 1],     lossTable[:, 4],     noEvent(abs(w_a)),     1),Modelica_3_2_1_Build_4.Math.Vectors.interpolate(     lossTable[:, 1],     lossTable[:, 5],     noEvent(abs(w_a)),     1)]; |
|
eta_mf1 = interpolation_result[1, 1]; ... tau_bf2 = noEvent(abs(interpolation_result[1, 4])); |
|
end if; |
|
if Modelica_3_2_1_Build_4.Math.isEqual(   eta_mf1,   1.0,   Modelica_3_2_1_Build_4.Constants.eps) and Modelica_3_2_1_Build_4.Math.isEqual(   eta_mf2,   1.0,   Modelica_3_2_1_Build_4.Constants.eps) then ... |
Component |
Version 1 |
Version 2 |
s1 | s_rel(start=0.5, fixed=true) | s_rel(start=1, fixed=true) |
Component |
Version 1 |
Version 2 |
m | | quantity=Medium.mediumName |
mXi | | quantity=Medium.substanceNames |
Component |
Version 1 |
Version 2 |
level | SIunits.Length | SIunits.Height |
Component |
Version 1 |
Version 2 |
tank | level_start=0.8 | level_start=0 |
stiffCharacteristicForEmptyPort=false | | |
hysteresisFactor=0.01 | |
Component |
Version 1 |
Version 2 |
system | energyDynamics=Modelica_3_2_1_Build_4.Fluid.Types.Dynamics.FixedInitial | |
massDynamics=Modelica_3_2_1_Build_4.Fluid.Types.Dynamics.FixedInitial | |
Component |
Version 1 |
Version 2 |
system | energyDynamics=Modelica_3_2_1_Build_4.Fluid.Types.Dynamics.FixedInitial | |
massDynamics=Modelica_3_2_1_Build_4.Fluid.Types.Dynamics.FixedInitial | |
Component |
Version 1 |
Version 2 |
system | energyDynamics=Modelica_3_2_1_Build_4.Fluid.Types.Dynamics.FixedInitial | |
massDynamics=Modelica_3_2_1_Build_4.Fluid.Types.Dynamics.FixedInitial | |
Component |
Version 1 |
Version 2 |
system | energyDynamics=Modelica_3_2_1_Build_4.Fluid.Types.Dynamics.FixedInitial | |
massDynamics=Modelica_3_2_1_Build_4.Fluid.Types.Dynamics.FixedInitial | |
Component |
Version 1 |
Version 2 |
system | energyDynamics=Modelica_3_2_1_Build_4.Fluid.Types.Dynamics.FixedInitial | |
massDynamics=Modelica_3_2_1_Build_4.Fluid.Types.Dynamics.FixedInitial | |
Component |
Version 1 |
Version 2 |
HEX | length=20 | length=2 |
area_h_1=0.075*20 | area_h_1=0.075*2*20 | |
area_h_2=0.075*20 | area_h_2=0.075*2*20 | |
redeclare model HeatTransfer_2 = Modelica.Fluid.Pipes.BaseClasses.HeatTransfer.ConstantFlowHeatTransfer (alpha0=2000) | redeclare model HeatTransfer_2 = Modelica.Fluid.Pipes.BaseClasses.HeatTransfer.ConstantFlowHeatTransfer (alpha0=200) | |
massFlowRate1 | m_flow=0.2 | m_flow=0.5 |
Ramp1 | height=0.4 | height=-1 |
offset=-0.2 | offset=0.5 |
Component |
Version 1 |
Version 2 |
wall | area_h=area_h | area_h=(crossArea_1 + crossArea_2)/2 |
pipe_1 | final p_a_start=p_a_start1 | |
final p_b_start=p_b_start1 | | |
pipe_2 | final p_a_start=p_a_start2 | final p_a_start=p_a_start1 |
Equations in Version 1 | Equations in Version 2 |
... end if; |
|
heatPort_a[i].Q_flow=2*k_wall/s*(Ta[i]-T[i])*area_h/n; | heatPort_a[i].Q_flow=k_wall/s*(Ta[i]-T[i])*area_h/n; |
heatPort_b[i].Q_flow=2*k_wall/s*(Tb[i]-T[i])*area_h/n; | heatPort_b[i].Q_flow=k_wall/s*(Tb[i]-T[i])*area_h/n; |
end for; ... |
Component |
Version 1 |
Version 2 |
heatTransfer | redeclare final package Medium = Medium | |
| redeclare each final package Medium = Medium |
Component |
Version 1 |
Version 2 |
m_flows_turbulent | ={nParallel*(crossAreas[i] + crossAreas[i + 1])/(dimensions[i] + dimensions[i + 1])*mus_act[i]*Re_turbulent for i in 1:n - 1} | ={nParallel*(Modelica_3_2_1_Build_2.Constants.pi/4)*0.5*(dimensions[i] + dimensions[i + 1])*mus_act[i]*Re_turbulent for i in 1:n - 1} |
Component |
Version 1 |
Version 2 |
dp_fric_nominal | =sum(WallFriction.pressureLoss_m_flow(m_flow_nominal/nParallel, rho_nominal, rho_nominal, mu_nominal, mu_nominal, pathLengths_internal, diameters, (crossAreas[1:n - 1] + crossAreas[2:n])/2, (roughnesses[1:n - 1] + roughnesses[2:n])/2, m_flow_small/nParallel, Res_turbulent_internal)) | =sum(WallFriction.pressureLoss_m_flow(m_flow_nominal/nParallel, rho_nominal, rho_nominal, mu_nominal, mu_nominal, pathLengths_internal, diameters, (roughnesses[1:n - 1] + roughnesses[2:n])/2, m_flow_small/nParallel, Res_turbulent_internal)) |
Equations in Version 1 | Equations in Version 2 |
... if from_dp and not WallFriction.dp_is_zero then |
|
m_flows = homotopy( actual = WallFriction.massFlowRate_dp( dps_fg - {g*dheights[i]*rhos_act[i] for i in 1:n-1}, rhos_act, rhos_act, mus_act, mus_act, pathLengths_internal, diameters, (crossAreas[1:n-1]+crossAreas[2:n])/2, (roughnesses[1:n-1]+roughnesses[2:n])/2, dp_small/(n-1), Res_turbulent_internal)*nParallel, simplified = m_flow_nominal/dp_nominal*(dps_fg - g*dheights*rho_nominal)); |
m_flows = homotopy( actual = WallFriction.massFlowRate_dp( dps_fg - {g*dheights[i]*rhos_act[i] for i in 1:n-1}, rhos_act, rhos_act, mus_act, mus_act, pathLengths_internal, diameters, (roughnesses[1:n-1]+roughnesses[2:n])/2, dp_small/(n-1), Res_turbulent_internal)*nParallel, simplified = m_flow_nominal/dp_nominal*(dps_fg - g*dheights*rho_nominal)); |
else | |
dps_fg = homotopy( actual = WallFriction.pressureLoss_m_flow( m_flows/nParallel, rhos_act, rhos_act, mus_act, mus_act, pathLengths_internal, diameters, (crossAreas[1:n-1]+crossAreas[2:n])/2, (roughnesses[1:n-1]+roughnesses[2:n])/2, m_flow_small/nParallel, Res_turbulent_internal) + {g*dheights[i]*rhos_act[i] for i in 1:n-1}, simplified = dp_nominal/m_flow_nominal*m_flows + g*dheights*rho_nominal); |
dps_fg = homotopy( actual = WallFriction.pressureLoss_m_flow( m_flows/nParallel, rhos_act, rhos_act, mus_act, mus_act, pathLengths_internal, diameters, (roughnesses[1:n-1]+roughnesses[2:n])/2, m_flow_small/nParallel, Res_turbulent_internal) + {g*dheights[i]*rhos_act[i] for i in 1:n-1}, simplified = dp_nominal/m_flow_nominal*m_flows + g*dheights*rho_nominal); |
end if; ... if from_dp and not WallFriction.dp_is_zero then |
|
m_flows = homotopy( actual = WallFriction.massFlowRate_dp_staticHead( dps_fg, rhos[1:n-1], rhos[2:n], mus[1:n-1], mus[2:n], pathLengths_internal, diameters, g*dheights, (crossAreas[1:n-1]+crossAreas[2:n])/2, (roughnesses[1:n-1]+roughnesses[2:n])/2, dp_small/(n-1), Res_turbulent_internal)*nParallel, simplified = m_flow_nominal/dp_nominal*(dps_fg - g*dheights*rho_nominal)); |
m_flows = homotopy( actual = WallFriction.massFlowRate_dp_staticHead( dps_fg, rhos[1:n-1], rhos[2:n], mus[1:n-1], mus[2:n], pathLengths_internal, diameters, g*dheights, (roughnesses[1:n-1]+roughnesses[2:n])/2, dp_small/(n-1), Res_turbulent_internal)*nParallel, simplified = m_flow_nominal/dp_nominal*(dps_fg - g*dheights*rho_nominal)); |
else | |
dps_fg = homotopy( actual = WallFriction.pressureLoss_m_flow_staticHead( m_flows/nParallel, rhos[1:n-1], rhos[2:n], mus[1:n-1], mus[2:n], pathLengths_internal, diameters, g*dheights, (crossAreas[1:n-1]+crossAreas[2:n])/2, (roughnesses[1:n-1]+roughnesses[2:n])/2, m_flow_small/nParallel, Res_turbulent_internal), simplified = dp_nominal/m_flow_nominal*m_flows + g*dheights*rho_nominal); |
dps_fg = homotopy( actual = WallFriction.pressureLoss_m_flow_staticHead( m_flows/nParallel, rhos[1:n-1], rhos[2:n], mus[1:n-1], mus[2:n], pathLengths_internal, diameters, g*dheights, (roughnesses[1:n-1]+roughnesses[2:n])/2, m_flow_small/nParallel, Res_turbulent_internal), simplified = dp_nominal/m_flow_nominal*m_flows + g*dheights*rho_nominal); |
end if; ... |
Component |
Version 1 |
Version 2 |
dps_fg_turbulent | each min=0 | |
Equations in Version 1 | Equations in Version 2 |
initial equation |
for i in 1:n-1 loop |
for i in 1:n loop assert(abs(crossAreas[i] - pi/4*dimensions[i]^2) < 1e-10*crossAreas[i],              "NominalTurbulentPipeFlow model requires circular tubes"); end for; equation   for i in 1:n-1 loop |
|
ks_inv[i] = (m_flow_nominal/nParallel)^2/((dp_nominal/(n-1)-g*dheights[i]*rhos_act[i]))/rhos_act[i]; ... |
Equations in Version 1 | Equations in Version 2 |
initial equation |
|
for i in 1:n loop assert(abs(crossAreas[i] - pi/4*dimensions[i]^2) < 1e-10*crossAreas[i],              "NominalTurbulentPipeFlow model requires circular tubes"); end for; |
|
if system.use_eps_Re then ... |
Component |
Version 1 |
Version 2 |
crossArea | Present |
Component |
Version 1 |
Version 2 |
crossArea | Present |
Component |
Version 1 |
Version 2 |
crossArea | Present |
Component |
Version 1 |
Version 2 |
crossArea | Present |
Equations in Version 1 | Equations in Version 2 |
... if dp>=dp_a then |
|
m_flow = Internal.m_flow_of_dp_fric(dp - dp_grav_a, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta); | m_flow = Internal.m_flow_of_dp_fric(dp - dp_grav_a, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta); |
elseif dp<=dp_b then | |
m_flow = Internal.m_flow_of_dp_fric(dp-dp_grav_b, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta); | m_flow = Internal.m_flow_of_dp_fric(dp-dp_grav_b, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta); |
else | |
(m_flow_a, dm_flow_ddp_fric_a) = Internal.m_flow_of_dp_fric(dp_a-dp_grav_a, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta); | (m_flow_a, dm_flow_ddp_fric_a) = Internal.m_flow_of_dp_fric(dp_a-dp_grav_a, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta); |
(m_flow_b, dm_flow_ddp_fric_b) = Internal.m_flow_of_dp_fric(dp_b-dp_grav_b, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta); | (m_flow_b, dm_flow_ddp_fric_b) = Internal.m_flow_of_dp_fric(dp_b-dp_grav_b, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta); |
(m_flow, dm_flow_ddp_fric_zero) = Utilities.regFun3(dp_zero, dp_b, dp_a, m_flow_b, m_flow_a, dm_flow_ddp_fric_b, dm_flow_ddp_fric_a); ... |
Equations in Version 1 | Equations in Version 2 |
... assert(roughness > 1e-10,     "roughness > 0 required for quadratic turbulent wall friction characteristic"); |
|
m_flow_a = if dp_grav_a<dp_grav_b then Internal.m_flow_of_dp_fric(dp_grav_b - dp_grav_a, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta)+m_flow_small else m_flow_small; |
m_flow_a = if dp_grav_a<dp_grav_b then Internal.m_flow_of_dp_fric(dp_grav_b - dp_grav_a, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta)+m_flow_small else m_flow_small; |
m_flow_b = if dp_grav_a<dp_grav_b then Internal.m_flow_of_dp_fric(dp_grav_a - dp_grav_b, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta)-m_flow_small else -m_flow_small; |
m_flow_b = if dp_grav_a<dp_grav_b then Internal.m_flow_of_dp_fric(dp_grav_a - dp_grav_b, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta)-m_flow_small else -m_flow_small; |
if m_flow>=m_flow_a then | |
dp = Internal.dp_fric_of_m_flow(m_flow, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta) + dp_grav_a; | dp = Internal.dp_fric_of_m_flow(m_flow, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta) + dp_grav_a; |
elseif m_flow<=m_flow_b then | |
dp = Internal.dp_fric_of_m_flow(m_flow, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta) + dp_grav_b; | dp = Internal.dp_fric_of_m_flow(m_flow, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta) + dp_grav_b; |
else | |
(dp_a, ddp_dm_flow_a) = Internal.dp_fric_of_m_flow(m_flow_a, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta); | (dp_a, ddp_dm_flow_a) = Internal.dp_fric_of_m_flow(m_flow_a, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta); |
dp_a = dp_a + dp_grav_a "Adding dp_grav to dp_fric to get dp"; | |
(dp_b, ddp_dm_flow_b) = Internal.dp_fric_of_m_flow(m_flow_b, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta); | (dp_b, ddp_dm_flow_b) = Internal.dp_fric_of_m_flow(m_flow_b, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta); |
dp_b = dp_b + dp_grav_b "Adding dp_grav to dp_fric to get dp"; ... |
Component |
Version 1 |
Version 2 |
crossArea | Present |
Component |
Version 1 |
Version 2 |
crossArea | Present |
Component |
Version 1 |
Version 2 |
pi | Present |
Equations in Version 1 | Equations in Version 2 |
... end if; |
|
m_flow = crossArea/diameter*mu*(if dp >= 0 then Re else -Re); | m_flow = (pi*diameter/4)*mu*(if dp >= 0 then Re else -Re); |
Equations in Version 1 | Equations in Version 2 |
... mu = if m_flow >= 0 then mu_a else mu_b; |
|
Re = diameter*abs(m_flow)/(crossArea*mu); | Re = (4/pi)*abs(m_flow)/(diameter*mu); |
lambda2 = if Re <= Re1 then 64*Re else             (if Re >= Re2 then 0.25*(Re/Math.log10(Delta/3.7 + 5.74/Re^0.9))^2 else              interpolateInRegion2(Re, Re1, Re2, Delta)); ... |
Equations in Version 1 | Equations in Version 2 |
... if dp>=dp_a then |
|
m_flow = Internal.m_flow_of_dp_fric(dp-dp_grav_a, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta); | m_flow = Internal.m_flow_of_dp_fric(dp-dp_grav_a, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta); |
elseif dp<=dp_b then | |
m_flow = Internal.m_flow_of_dp_fric(dp-dp_grav_b, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta); | m_flow = Internal.m_flow_of_dp_fric(dp-dp_grav_b, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta); |
else | |
(m_flow_a, dm_flow_ddp_fric_a) = Internal.m_flow_of_dp_fric(dp_a-dp_grav_a, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta); | (m_flow_a, dm_flow_ddp_fric_a) = Internal.m_flow_of_dp_fric(dp_a-dp_grav_a, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta); |
(m_flow_b, dm_flow_ddp_fric_b) = Internal.m_flow_of_dp_fric(dp_b-dp_grav_b, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta); | (m_flow_b, dm_flow_ddp_fric_b) = Internal.m_flow_of_dp_fric(dp_b-dp_grav_b, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta); |
(m_flow, dm_flow_ddp_fric_zero) = Utilities.regFun3(dp_zero, dp_b, dp_a, m_flow_b, m_flow_a, dm_flow_ddp_fric_b, dm_flow_ddp_fric_a); ... |
Equations in Version 1 | Equations in Version 2 |
algorithm |
|
m_flow_a := if dp_grav_a<dp_grav_b then Internal.m_flow_of_dp_fric(dp_grav_b - dp_grav_a, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta)+m_flow_small else m_flow_small; |
m_flow_a := if dp_grav_a<dp_grav_b then Internal.m_flow_of_dp_fric(dp_grav_b - dp_grav_a, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta)+m_flow_small else m_flow_small; |
m_flow_b = if dp_grav_a<dp_grav_b then Internal.m_flow_of_dp_fric(dp_grav_a - dp_grav_b, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta)-m_flow_small else -m_flow_small; |
m_flow_b = if dp_grav_a<dp_grav_b then Internal.m_flow_of_dp_fric(dp_grav_a - dp_grav_b, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta)-m_flow_small else -m_flow_small; |
if m_flow>=m_flow_a then | |
dp = Internal.dp_fric_of_m_flow(m_flow, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta) + dp_grav_a; | dp = Internal.dp_fric_of_m_flow(m_flow, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta) + dp_grav_a; |
elseif m_flow<=m_flow_b then | |
dp = Internal.dp_fric_of_m_flow(m_flow, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta) + dp_grav_b; | dp = Internal.dp_fric_of_m_flow(m_flow, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta) + dp_grav_b; |
else | |
(dp_a, ddp_dm_flow_a) = Internal.dp_fric_of_m_flow(m_flow_a, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta); | (dp_a, ddp_dm_flow_a) = Internal.dp_fric_of_m_flow(m_flow_a, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta); |
dp_a = dp_a + dp_grav_a "Adding dp_grav to dp_fric to get dp"; | |
(dp_b, ddp_dm_flow_b) = Internal.dp_fric_of_m_flow(m_flow_b, rho_a, rho_b, mu_a, mu_b, length, diameter, crossArea, Re1, Re2, Delta); | (dp_b, ddp_dm_flow_b) = Internal.dp_fric_of_m_flow(m_flow_b, rho_a, rho_b, mu_a, mu_b, length, diameter, Re1, Re2, Delta); |
dp_b = dp_b + dp_grav_b "Adding dp_grav to dp_fric to get dp"; ... |
Component |
Version 1 |
Version 2 |
crossArea | Present |
Equations in Version 1 | Equations in Version 2 |
... end if; |
|
m_flow = crossArea/diameter*mu*(if dp_fric >= 0 then Re else -Re); | m_flow = (pi*diameter/4)*mu*(if dp_fric >= 0 then Re else -Re); |
dm_flow_ddp_fric = crossArea/diameter*mu*dRe_ddp; | dm_flow_ddp_fric = (pi*diameter*mu)/4*dRe_ddp; |
Component |
Version 1 |
Version 2 |
crossArea | Present |
Equations in Version 1 | Equations in Version 2 |
... end if; |
|
Re = abs(m_flow)*diameter/(crossArea*mu); | Re = (4/pi)*abs(m_flow)/(diameter*mu); |
aux1 = diameter/(crossArea*mu); | aux1 = 4/(pi*diameter*mu); |
if Re <= Re1 then ... |
Component |
Version 1 |
Version 2 |
dp_fric_nominal | =WallFriction.pressureLoss_m_flow(m_flow_nominal, rho_nominal, rho_nominal, mu_nominal, mu_nominal, length, diameter, crossArea, roughness, m_flow_small) | =WallFriction.pressureLoss_m_flow(m_flow_nominal, rho_nominal, rho_nominal, mu_nominal, mu_nominal, length, diameter, roughness, m_flow_small) |
min=0 | | |
dp_small | min=0 | |
crossArea | Present |
Equations in Version 1 | Equations in Version 2 |
if from_dp and not WallFriction.dp_is_zero then | |
m_flow = WallFriction.massFlowRate_dp_staticHead(dp, rho_a, rho_b, mu_a, mu_b, length, diameter, g_times_height_ab, crossArea, roughness, if use_x_small_staticHead then dp_small_staticHead else dp_small); |
m_flow = WallFriction.massFlowRate_dp_staticHead(dp, rho_a, rho_b, mu_a, mu_b, length, diameter, g_times_height_ab, roughness, if use_x_small_staticHead then dp_small_staticHead else dp_small); |
else | |
dp = WallFriction.pressureLoss_m_flow_staticHead(m_flow, rho_a, rho_b, mu_a, mu_b, length, diameter, g_times_height_ab, crossArea, roughness, if use_x_small_staticHead then m_flow_small_staticHead else m_flow_small); |
dp = WallFriction.pressureLoss_m_flow_staticHead(m_flow, rho_a, rho_b, mu_a, mu_b, length, diameter, g_times_height_ab, roughness, if use_x_small_staticHead then m_flow_small_staticHead else m_flow_small); |
end if; ... |
Component |
Version 1 |
Version 2 |
show_NPSHa | Present |
Component |
Version 1 |
Version 2 |
dp_small | min=0 | |
Component |
Version 1 |
Version 2 |
dp_small | min=0 | |
Component |
Version 1 |
Version 2 |
dp_small | min=0 | |
Component |
Version 1 |
Version 2 |
dp_small | min=0 | |
Component |
Version 1 |
Version 2 |
dp_small | min=0 | |
zeta_nominal | | start=zeta |
Equations in Version 1 | Equations in Version 2 |
... else |
|
zeta_nominal = 2*A_mean^2*d*dp_nominal/m_flow_nominal^2; | dp_nominal = BaseClasses.lossConstant_D_zeta(diameter, zeta_nominal)/d*m_flow_nominal^2; |
end if; ... |
Component |
Version 1 |
Version 2 |
dp_small | min=0 | |
Component |
Version 1 |
Version 2 |
dp_small | min=0 | |
Component |
Version 1 |
Version 2 |
dp_start | min=-Modelica_3_2_1_Build_4.Constants.inf | |
Component |
Version 1 |
Version 2 |
IN_con_turb | Present |
Equations in Version 1 | Equations in Version 2 |
algorithm |
|
kc := SMOOTH( laminar, turbulent, Re)*Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_KC( IN_con, IN_var) + SMOOTH( turbulent, laminar, Re)*Dissipation.HeatTransfer.Channel.kc_evenGapTurbulent_KC( IN_con_turb, IN_var); |
kc := SMOOTH( laminar, turbulent, Re)*Dissipation.HeatTransfer.Channel.kc_evenGapLaminar_KC( IN_con, IN_var) + SMOOTH( turbulent, laminar, Re)*Dissipation.HeatTransfer.Channel.kc_evenGapTurbulent_KC( IN_con, IN_var); |
Component |
Version 1 |
Version 2 |
Nu3 | =if IN_con.target == TYP.UWTuUFF then (2/(1 + 22*Pr))^(1/6)*(Re*Pr*IN_con.d_hyd/IN_con.L)^0.5 else if IN_con.target == TYP.UHFuUFF then 0.924*(Pr^(1/3))*(Re*IN_con.d_hyd/IN_con.L)^(1/2) else 0 | =if IN_con.target == TYP.UWTuUFF then (2/(1 + 22*Pr))^(1/6)*(Re*Pr*IN_con.d_hyd/IN_con.L)^0.5 else if IN_con.target == TYP.UHFuUFF then 1.953*(Re*Pr*IN_con.d_hyd/IN_con.L)^(1/3) else 0 |
Component |
Version 1 |
Version 2 |
IN_con_turb | Present | |
IN_con_lam | Present |
Equations in Version 1 | Equations in Version 2 |
algorithm |
|
kc := SMOOTH( laminar, turbulent, Re)*Dissipation.HeatTransfer.StraightPipe.kc_laminar_KC(IN_con_lam, IN_var) + SMOOTH( turbulent, laminar, Re)*Dissipation.HeatTransfer.StraightPipe.kc_turbulent_KC( IN_con_turb, IN_var); |
kc := SMOOTH( laminar, turbulent, Re)*Dissipation.HeatTransfer.StraightPipe.kc_laminar_KC(IN_con, IN_var) + SMOOTH( turbulent, laminar, Re)*Dissipation.HeatTransfer.StraightPipe.kc_turbulent_KC( IN_con, IN_var); |
Component |
Version 1 |
Version 2 |
A2 | =if frac_RD > 2.0 then 6e2 else if frac_RD <= 2.0 and frac_RD > 0.55 then (if frac_RD > 1.0 then 1e3 else if frac_RD <= 1.0 and frac_RD > 0.7 then 3e3 else 6e3) else 4e3 | =if frac_RD > 2.0 then 6e2 else if frac_RD <= 2.0 and frac_RD >= 0.7 then (if frac_RD > 1.0 then 1e3 else if frac_RD <= 1.0 and frac_RD > 0.7 then 3e3 else 6e3) else 4e3 |
Component |
Version 1 |
Version 2 |
A2 | =if frac_RD > 2.0 then 6e2 else if frac_RD <= 2.0 and frac_RD > 0.55 then (if frac_RD > 1.0 then 1e3 else if frac_RD <= 1.0 and frac_RD > 0.7 then 3e3 else 6e3) else 4e3 | =if frac_RD > 2.0 then 6e2 else if frac_RD <= 2.0 and frac_RD >= 0.7 then (if frac_RD > 1.0 then 1e3 else if frac_RD <= 1.0 and frac_RD > 0.7 then 3e3 else 6e3) else 4e3 |
v_lam | =if 1e7*sqrt(abs(zeta_LOC_sharp_turb*abs(dp)*IN_var.rho*d_hyd^2)) < abs(A2*IN_var.eta) then 2*abs(dp)*d_hyd/A2/IN_var.eta else (-A2/2*IN_var.eta + 0.5*sqrt(max(MIN, (A2*IN_var.eta)^2 + 8*zeta_LOC_sharp_turb*abs(dp)*IN_var.rho*d_hyd^2)))/zeta_LOC_sharp_turb/IN_var.rho/d_hyd | =(-A2/2*IN_var.eta + 0.5*sqrt(max(MIN, (A2*IN_var.eta)^2 + 8*zeta_LOC_sharp_turb*abs(dp)*IN_var.rho*d_hyd^2)))/zeta_LOC_sharp_turb/IN_var.rho/d_hyd |
v_tra | =if 1e7*sqrt(abs(zeta_LOC_sharp_turb*abs(dp_lam_max)*IN_var.rho*d_hyd^2)) < abs(A2*IN_var.eta) then 2*abs(dp_lam_max)*d_hyd/A2/IN_var.eta else (-A2/2*IN_var.eta + 0.5*sqrt(max(MIN, (A2*IN_var.eta)^2 + 8*zeta_LOC_sharp_turb*abs(dp_lam_max)*IN_var.rho*d_hyd^2)))/zeta_LOC_sharp_turb/IN_var.rho/d_hyd | =(-A2/2*IN_var.eta + 0.5*sqrt(max(MIN, (A2*IN_var.eta)^2 + 8*zeta_LOC_sharp_turb*abs(dp_lam_max)*IN_var.rho*d_hyd^2)))/zeta_LOC_sharp_turb/IN_var.rho/d_hyd |
Component |
Version 1 |
Version 2 |
Re_lam_min | =5e2 | =1e3 |
Re_lam_max | =1e4 | =4e4 |
Re_turb_max | =2e5 | =3e5 |
B | =24.8 | =0.0292*(delta)^2 + 1.1995*delta |
exp | =0.263 | =1 |
lambda_FRI_rough | =0.25/(Modelica_3_2_1_Build_4.Math.log10(k/(3.7*IN_con.d_hyd) + 5.74/max(Re_lam_min, Re)^0.9))^2 | =0.25/(Modelica_3_2_1_Build_2.Math.log10(k/(3.7*IN_con.d_hyd) + 5.74/min(Re_turb_const, max(Re_lam_leave, Re))^0.9))^2 |
lambda_FRI_smooth | =0.25/(Modelica_3_2_1_Build_4.Math.log10(5.74/max(Re_lam_min, Re)^0.9))^2 | =0.25/(Modelica_3_2_1_Build_2.Math.log10(5.74/min(Re_turb_const, max(Re_lam_leave, Re))^0.9))^2 |
CF_fri | =SMOOTH(Re_lam_leave, Re_lam_min, Re)*max(1, min(1.4, (lambda_FRI_rough/lambda_FRI_smooth))) + SMOOTH(Re_lam_min, Re_lam_leave, Re) | =if delta <= 45 then max(1, min(1.4, (lambda_FRI_rough/lambda_FRI_smooth))) else 1 |
CF_Re | =SMOOTH(Re_turb_min, Re_turb_max, Re)*B/Re^exp + SMOOTH(Re_turb_max, Re_turb_min, Re) | =SMOOTH(Re_min, Re_lam_leave, Re)*B/Re^exp + SMOOTH(Re_lam_leave, Re_min, Re) |
zeta_TOT | =A*C1*zeta_LOC*CF_Re*CF_fri | =A*C1*zeta_LOC*CF_fri*CF_Re |
Component |
Version 1 |
Version 2 |
Re_lam_min | =500 | =1e3 |
Re_lam_max | =1e4 | =4e4 |
Re_turb_max | =2e5 | =3e5 |
B | =24.8 | =0.0292*(delta)^2 + 1.1995*delta |
exp | =0.263 | =1 |
dp_min | =A*C1*zeta_LOC*(B/2)*(d_hyd/IN_var.eta)^(-exp)*IN_var.rho^(1 - exp)*v_min^(pow) | =1 |
v_turb | =(A*C1*zeta_LOC*IN_var.rho/2)^(-0.5)*Modelica_3_2_1_Build_4.Fluid.Dissipation.Utilities.Functions.General.SmoothPower(abs(dp), dp_min, 0.5) | =(2*abs(dp))^0.5*(A*C1*zeta_LOC*IN_var.rho)^(-0.5) |
v_lam | =(2*(d_hyd/IN_var.eta)^exp/(A*C1*zeta_LOC*B*(IN_var.rho)^(1 - exp)))^(1/pow)*Modelica_3_2_1_Build_4.Fluid.Dissipation.Utilities.Functions.General.SmoothPower(abs(dp), dp_min, 1/pow) | =(2*(d_hyd/IN_var.eta)^exp/(A*C1*zeta_LOC*B*(IN_var.rho)^(1 - exp)))^(1/pow)*Fluid.Dissipation.Utilities.Functions.General.SmoothPower(abs(dp), dp_min, 1/pow) |
v_smooth | =if abs(dp) > dp_turb_max then v_turb else if abs(dp) < dp_turb_min then v_lam else SMOOTH(dp_turb_max, dp_turb_min, abs(dp))*v_turb + SMOOTH(dp_turb_min, dp_turb_max, abs(dp))*v_lam | =if abs(dp) > dp_lam_max then v_turb else if abs(dp) < dp_lam_trans then v_lam else SMOOTH(dp_lam_max, dp_lam_trans, abs(dp))*v_turb + SMOOTH(dp_lam_trans, dp_lam_max, abs(dp))*v_lam |
lambda_FRI_rough | =0.25/(Modelica_3_2_1_Build_4.Math.log10(k/(3.7*IN_con.d_hyd) + 5.74/max(Re_lam_min, Re_smooth)^0.9))^2 | =0.25/(Modelica_3_2_1_Build_2.Math.log10(k/(3.7*IN_con.d_hyd) + 5.74/min(Re_turb_const, max(Re_lam_leave, Re_smooth))^0.9))^2 |
lambda_FRI_smooth | =0.25/(Modelica_3_2_1_Build_4.Math.log10(5.74/max(Re_lam_min, Re_smooth)^0.9))^2 | =0.25/(Modelica_3_2_1_Build_2.Math.log10(5.74/min(Re_turb_const, max(Re_lam_leave, Re_smooth))^0.9))^2 |
CF_fri | =SMOOTH(dp_lam_leave, dp_lam_min, abs(dp))*max(1, min(1.4, (lambda_FRI_rough/lambda_FRI_smooth))) + SMOOTH(dp_lam_min, dp_lam_leave, abs(dp)) | =if delta <= 45 then max(1, min(1.4, (lambda_FRI_rough/lambda_FRI_smooth))) else 1 |
v_min | Present | |
v_lam_min | Present | |
v_lam_leave | Present | |
dp_lam_min | Present | |
lambda_lam_leave_rough | Present | |
lambda_lam_leave_smooth | Present | |
dp_lam_leave | Present | |
lambda_turb_min_rough | Present | |
lambda_turb_min_smooth | Present | |
lambda_turb_max_rough | Present | |
lambda_turb_max_smooth | Present | |
v_turb_min | Present | |
v_turb_max | Present | |
dp_turb_min | Present | |
dp_turb_max | Present | |
v_lam_trans | Present | |
v_lam_max | Present | |
dp_lam_trans | Present | |
dp_lam_max | Present |
Component |
Version 1 |
Version 2 |
IN_con_lam | Present |
Equations in Version 1 | Equations in Version 2 |
algorithm |
|
DP := SMOOTH( Re_lam_min, Re_lam_max, Re)*Dissipation.PressureLoss.StraightPipe.dp_laminar_DP( IN_con_lam, IN_var, m_flow) + SMOOTH( Re_lam_max, Re_lam_min, Re)*Dissipation.PressureLoss.StraightPipe.dp_turbulent_DP( IN_con, IN_var, m_flow); |
DP := SMOOTH( Re_lam_min, Re_lam_max, Re)*Dissipation.PressureLoss.StraightPipe.dp_laminar_DP( IN_con, IN_var, m_flow) + SMOOTH( Re_lam_max, Re_lam_min, Re)*Dissipation.PressureLoss.StraightPipe.dp_turbulent_DP( IN_con, IN_var, m_flow); |
Component |
Version 1 |
Version 2 |
IN_con_lam | Present |
Equations in Version 1 | Equations in Version 2 |
algorithm |
|
M_FLOW := SMOOTH( Re_lam_min, Re_turb, Re)*Dissipation.PressureLoss.StraightPipe.dp_laminar_MFLOW( IN_con_lam, IN_var, dp) + SMOOTH( Re_turb, Re_lam_min, Re)*Dissipation.PressureLoss.StraightPipe.dp_turbulent_MFLOW( IN_con, IN_var, dp); |
M_FLOW := SMOOTH( Re_lam_min, Re_turb, Re)*Dissipation.PressureLoss.StraightPipe.dp_laminar_MFLOW( IN_con, IN_var, dp) + SMOOTH( Re_turb, Re_lam_min, Re)*Dissipation.PressureLoss.StraightPipe.dp_turbulent_MFLOW( IN_con, IN_var, dp); |
Component |
Version 1 |
Version 2 |
ddeltax | Present | |
dpow | Present |
Equations in Version 1 | Equations in Version 2 |
... elseif noEvent(x <= -adeltax) then |
|
dy = dx*pow*(-x)^(pow - 1); | dy = -dx*pow*(-x)^(pow - 1); |
else ... |
Component |
Version 1 |
Version 2 |
r_1 | Present |
Equations in Version 1 | Equations in Version 2 |
algorithm |
|
result := if x >= func and func > nofunc or x <= func and nofunc > func then 1 else if x <= nofunc and func > nofunc or x >= nofunc and nofunc > func then 0 else (1 + Modelica_3_2_1_Build_4.Math.tanh(Modelica_3_2_1_Build_4.Math.tan( m*x + b)))/2; |
result := if x >= 0.999999*(func - nofunc) + nofunc and func > nofunc or x <= 0.999999*(func - nofunc) + nofunc and nofunc > func then 1 else if x <= 0.000001*(func - nofunc) + nofunc and func > nofunc or x >= 0.000001*( func - nofunc) + nofunc and nofunc > func then 0 else ((0.5*(exp(r_1) - exp( -r_1))/(0.5*(exp(r_1) + exp(-r_1))) + 1)/2); |
Equations in Version 1 | Equations in Version 2 |
algorithm |
|
dresult := if x >= func and func > nofunc or x <= func and nofunc > func or x <= nofunc and func > nofunc or x >= nofunc and nofunc > func then 0 else (1 - Modelica_3_2_1_Build_4.Math.tanh(Modelica_3_2_1_Build_4.Math.tan(m*x + b)) ^2)*(1 + Modelica_3_2_1_Build_4.Math.tan(m*x + b)^2)*(-m^2/ Modelica_3_2_1_Build_4.Constants.pi*(dfunc - dnofunc)*x + m*dx + m^2/ Modelica_3_2_1_Build_4.Constants.pi*(dfunc - dnofunc)*nofunc - m*dnofunc)/2; |
dresult := if x >= 0.999*(func - nofunc) + nofunc and func > nofunc or x <= 0.999*(func - nofunc) + nofunc and nofunc > func or x <= 0.001*(func - nofunc) + nofunc and func > nofunc or x >= 0.001*(func - nofunc) + nofunc and nofunc > func then 0 else (1 - Modelica_3_2_1_Build_2.Math.tanh( Modelica_3_2_1_Build_2.Math.tan(m*x + b))^2)*(1 + Modelica_3_2_1_Build_2.Math.tan(m*x + b)^2)*m*dx/2; |
Component |
Version 1 |
Version 2 |
medium2 | X(start={0.2,0.8}, each fixed=true) | X(start={0.2,0.8}, fixed=true) |
Component |
Version 1 |
Version 2 |
medium2 | X(start={0.2,0.1,0.3,0.4}, each fixed=true) | X(start={0.2,0.1,0.3,0.4}, fixed=true) |
Equations in Version 1 | Equations in Version 2 |
algorithm |
|
state := ThermodynamicState(p=p, T=Modelica_3_2_1_Build_4.Math.exp(s/cp_const + Modelica_3_2_1_Build_4.Math.log(reference_T) + R_gas* Modelica_3_2_1_Build_4.Math.log(p/reference_p))); |
state := ThermodynamicState(p=p, T=Modelica_3_2_1_Build_2.Math.exp(s/cp_const + Modelica_3_2_1_Build_2.Math.log(reference_T)) + R_gas* Modelica_3_2_1_Build_2.Math.log(p/reference_p)); |
Equations in Version 1 | Equations in Version 2 |
algorithm |
|
u := cp_const*(state.T - T0) - R_gas*state.T; | u := (cp_const - R_gas)*(state.T - T0); |
Equations in Version 1 | Equations in Version 2 |
algorithm |
|
f := specificInternalEnergy(state) - state.T*specificEntropy(state); | f := (cp_const - R_gas)*(state.T - T0) - state.T*specificEntropy(state); |
Component |
Version 1 |
Version 2 |
phase | start=0 | |
| =0 |
Component |
Version 1 |
Version 2 |
T_min | SIunits.Temperature | Media.Interfaces.Types.Temperature |
T_max | SIunits.Temperature | Media.Interfaces.Types.Temperature |
Equations in Version 1 | Equations in Version 2 |
... end for; |
|
p2[n] = 0.0; |
|
Component |
Version 1 |
Version 2 |
TREL | | parameter |
rhoREL | | parameter |
Component |
Version 1 |
Version 2 |
properties | Present | |
aux | Present |
Equations in Version 1 | Equations in Version 2 |
algorithm |
|
if (properties.region == 4) then | if (aux.region == 4) then |
rho_der = (properties.rho*(properties.rho*properties.cv/properties.dpT + 1.0)/(properties.dpT*properties.T))*p_der + (-properties.rho*properties.rho/(properties.dpT*properties.T))*h_der; |
rho_der = (aux.rho*(aux.rho*aux.cv/aux.dpT + 1.0)/(aux.dpT*aux.T))*p_der + (-aux.rho*aux.rho/(aux.dpT*aux.T))*h_der; |
elseif (properties.region == 3) then | elseif (aux.region == 3) then |
rho_der = ((properties.rho*(properties.cv*properties.rho + properties.pt))/(properties.rho*properties.rho*properties.pd* properties.cv + properties.T*properties.pt*properties.pt))*p_der + (-properties.rho*properties.rho*properties.pt/(properties.rho *properties.rho*properties.pd*properties.cv + properties.T*properties.pt*properties.pt))*h_der; |
rho_der = ((aux.rho*(aux.cv*aux.rho + aux.pt))/(aux.rho*aux.rho*aux.pd* aux.cv + aux.T*aux.pt*aux.pt))*p_der + (-aux.rho*aux.rho*aux.pt/(aux.rho *aux.rho*aux.pd*aux.cv + aux.T*aux.pt*aux.pt))*h_der; |
else | |
rho_der = (-properties.rho*properties.rho*(properties.vp*properties.cp - properties.vt/properties.rho + properties.T*properties.vt *properties.vt)/properties.cp)*p_der + (-properties.rho*properties.rho*properties.vt/(properties.cp))*h_der; |
rho_der = (-aux.rho*aux.rho*(aux.vp*aux.cp - aux.vt/aux.rho + aux.T*aux.vt *aux.vt)/aux.cp)*p_der + (-aux.rho*aux.rho*aux.vt/(aux.cp))*h_der; |
end if; ... |
Component |
Version 1 |
Version 2 |
properties | Present | |
aux | Present |
Equations in Version 1 | Equations in Version 2 |
algorithm |
|
if (properties.region == 4) then | if (aux.region == 4) then |
T_der = 1/properties.dpT*p_der; | T_der = 1/aux.dpT*p_der; |
elseif (properties.region == 3) then | elseif (aux.region == 3) then |
T_der = ((-properties.rho*properties.pd + properties.T*properties.pt)/(properties.rho*properties.rho*properties.pd*properties.cv + properties.T*properties.pt*properties.pt))*p_der + ((properties.rho*properties.rho*properties.pd)/(properties.rho*properties.rho *properties.pd*properties.cv + properties.T*properties.pt*properties.pt))*h_der; |
T_der = ((-aux.rho*aux.pd + aux.T*aux.pt)/(aux.rho*aux.rho*aux.pd*aux.cv + aux.T*aux.pt*aux.pt))*p_der + ((aux.rho*aux.rho*aux.pd)/(aux.rho*aux.rho *aux.pd*aux.cv + aux.T*aux.pt*aux.pt))*h_der; |
else | |
T_der = ((-1/properties.rho + properties.T*properties.vt)/properties.cp)*p_der + (1/properties.cp)*h_der; | T_der = ((-1/aux.rho + aux.T*aux.vt)/aux.cp)*p_der + (1/aux.cp)*h_der; |
end if; ... |
Component |
Version 1 |
Version 2 |
properties | Present | |
aux | Present |
Equations in Version 1 | Equations in Version 2 |
algorithm |
|
s_der := -1/(properties.rho*properties.T)*p_der + 1/properties.T*h_der; | s_der := -1/(aux.rho*aux.T)*p_der + 1/aux.T*h_der; |
Equations in Version 1 | Equations in Version 2 |
... aux.pt = aux.R*rho*f.delta*(f.fdelta - f.tau*f.fdeltatau); |
|
aux.cp = (aux.rho*aux.rho*aux.pd*aux.cv + aux.T*aux.pt*aux.pt)/(aux.rho*         aux.rho*aux.pd); |
|
aux.cv = aux.R*(-f.tau*f.tau*f.ftautau); | |
aux.cp = (aux.rho*aux.rho*aux.pd*aux.cv + aux.T*aux.pt*aux.pt)/(aux.rho*         aux.rho*aux.pd); |
|
aux.x = 0.0; ... |
Equations in Version 1 | Equations in Version 2 |
... for i in 1:size(LU, 1) loop |
|
assert(LU[i, i] <> 0, "Solving a linear system of equations with function \"Matrices.LU_solve2\" is not possible, since the LU decomposition is singular, i.e., no unique solution exists."); |
assert(LU[i, i] <> 0, "Solving a linear system of equations with function \"Matrices.LU_solve\" is not possible, since the LU decomposition is singular, i.e., no unique solution exists."); |
end for; ... |
Component |
Version 1 |
Version 2 |
lwork | Present |
Equations in Version 1 | Equations in Version 2 |
external "FORTRAN 77" dgelsx( nrow, ncol, nrhs, Awork, nrow, X, nx, jpvt, rcond, rank, work, info); |
external "FORTRAN 77" dgelsx( nrow, ncol, nrhs, Awork, nrow, X, nx, jpvt, rcond, rank, work, lwork, info); |
Component |
Version 1 |
Version 2 |
lwork | Present |
Equations in Version 1 | Equations in Version 2 |
external "FORTRAN 77" dgelsx( nrow, ncol, 1, Awork, nrow, x, nx, jpvt, rcond, rank, work, info); |
external "FORTRAN 77" dgelsx( nrow, ncol, 1, Awork, nrow, x, nx, jpvt, rcond, rank, work, lwork, info); |
Component |
Version 1 |
Version 2 |
equed | Present |
Equations in Version 1 | Equations in Version 2 |
external "FORTRAN 77" dgesvx( "N", transA, size(A, 1), size(B, 2), Awork, lda, AF, lda, ipiv, equed, R, C, B, lda, X, lda, rcond, ferr, berr, work, iwork, info); |
external "FORTRAN 77" dgesvx( "N", transA, size(A, 1), size(B, 2), Awork, lda, AF, lda, ipiv, "N", R, C, B, lda, X, lda, rcond, ferr, berr, work, iwork, info); |
Class | Version 1 | Version 2 |
class Modelica_3_2_1_Build_4.UsersGuide.ReleaseNotes.Version_3_2_1_build_4 | Present | |
class Modelica_3_2_1_Build_4.UsersGuide.ReleaseNotes.Version_3_2_1_build_3 | Present | |
model Modelica_3_2_1_Build_4.Mechanics.Rotational.Examples.Utilities.SpringDamperNoRelativeStates | Present | |
model Modelica_3_2_1_Build_4.Fluid.Examples.NonCircularPipes | Present | |
model Modelica_3_2_1_Build_4.Media.Examples.PsychrometricData | Present | |
model Modelica_3_2_1_Build_2.Media.Air.MoistAir.PsychrometricData | Present | |