ReactingCloudI.H
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25 
26 #include "fvmSup.H"
27 
28 // * * * * * * * * * * * * * * * Member Functions * * * * * * * * * * * * * //
29 
30 template<class CloudType>
31 inline const Foam::ReactingCloud<CloudType>&
32 Foam::ReactingCloud<CloudType>::cloudCopy() const
33 {
34  return cloudCopyPtr_();
35 }
36 
37 
38 template<class CloudType>
39 inline const typename CloudType::particleType::constantProperties&
40 Foam::ReactingCloud<CloudType>::constProps() const
41 {
42  return constProps_;
43 }
44 
45 
46 template<class CloudType>
47 inline typename CloudType::particleType::constantProperties&
48 Foam::ReactingCloud<CloudType>::constProps()
49 {
50  return constProps_;
51 }
52 
53 
54 template<class CloudType>
55 inline const Foam::PhaseChangeModel<Foam::ReactingCloud<CloudType>>&
56 Foam::ReactingCloud<CloudType>::phaseChange() const
57 {
58  return phaseChangeModel_;
59 }
60 
61 
62 template<class CloudType>
63 inline Foam::PhaseChangeModel<Foam::ReactingCloud<CloudType>>&
64 Foam::ReactingCloud<CloudType>::phaseChange()
65 {
66  return phaseChangeModel_();
67 }
68 
69 
70 template<class CloudType>
71 inline Foam::DimensionedField<Foam::scalar, Foam::volMesh>&
72 Foam::ReactingCloud<CloudType>::rhoTrans(const label i)
73 {
74  return rhoTrans_[i];
75 }
76 
77 
78 template<class CloudType>
79 inline
80 const Foam::PtrList<Foam::DimensionedField<Foam::scalar, Foam::volMesh>>&
81 Foam::ReactingCloud<CloudType>::rhoTrans() const
82 {
83  return rhoTrans_;
84 }
85 
86 
87 template<class CloudType>
88 inline Foam::PtrList<Foam::DimensionedField<Foam::scalar, Foam::volMesh>>&
89 Foam::ReactingCloud<CloudType>::rhoTrans()
90 {
91  return rhoTrans_;
92 }
93 
94 
95 template<class CloudType>
96 inline Foam::tmp<Foam::fvScalarMatrix> Foam::ReactingCloud<CloudType>::SYi
97 (
98  const label i,
99  const volScalarField& Yi
100 ) const
101 {
102  if (this->solution().coupled())
103  {
104  if (this->solution().semiImplicit("Yi"))
105  {
106  tmp<volScalarField> trhoTrans
107  (
108  volScalarField::New
109  (
110  this->name() + ":rhoTrans",
111  this->mesh(),
112  dimensionedScalar(dimMass/dimTime/dimVolume, 0)
113  )
114  );
115 
116  volScalarField& sourceField = trhoTrans.ref();
117 
118  sourceField.primitiveFieldRef() =
119  rhoTrans_[i]/(this->db().time().deltaTValue()*this->mesh().V());
120 
121  const dimensionedScalar Yismall("Yismall", dimless, small);
122 
123  return
124  fvm::Sp(neg(sourceField)*sourceField/(Yi + Yismall), Yi)
125  + pos0(sourceField)*sourceField;
126  }
127  else
128  {
129  tmp<fvScalarMatrix> tfvm(new fvScalarMatrix(Yi, dimMass/dimTime));
130  fvScalarMatrix& fvm = tfvm.ref();
131 
132  fvm.source() = -rhoTrans_[i]/this->db().time().deltaTValue();
133 
134  return tfvm;
135  }
136  }
137 
138  return tmp<fvScalarMatrix>(new fvScalarMatrix(Yi, dimMass/dimTime));
139 }
140 
141 
142 template<class CloudType>
143 inline Foam::tmp<Foam::DimensionedField<Foam::scalar, Foam::volMesh>>
144 Foam::ReactingCloud<CloudType>::Srho() const
145 {
146  tmp<volScalarField::Internal> trhoTrans
147  (
148  volScalarField::Internal::New
149  (
150  this->name() + ":rhoTrans",
151  this->mesh(),
152  dimensionedScalar
153  (
154  rhoTrans_[0].dimensions()/dimTime/dimVolume,
155  0
156  )
157  )
158  );
159 
160  if (this->solution().coupled())
161  {
162  scalarField& sourceField = trhoTrans.ref();
163  forAll(rhoTrans_, i)
164  {
165  sourceField += rhoTrans_[i];
166  }
167 
168  sourceField /= this->db().time().deltaTValue()*this->mesh().V();
169  }
170 
171  return trhoTrans;
172 }
173 
174 
175 template<class CloudType>
176 inline Foam::tmp<Foam::fvScalarMatrix>
177 Foam::ReactingCloud<CloudType>::Srho(const volScalarField& rho) const
178 {
179  if (this->solution().coupled())
180  {
181  tmp<volScalarField> trhoTrans
182  (
183  volScalarField::New
184  (
185  this->name() + ":rhoTrans",
186  this->mesh(),
187  dimensionedScalar(dimMass/dimTime/dimVolume, 0)
188  )
189  );
190 
191  scalarField& sourceField = trhoTrans.ref();
192 
193  if (this->solution().semiImplicit("rho"))
194  {
195 
196  forAll(rhoTrans_, i)
197  {
198  sourceField += rhoTrans_[i];
199  }
200  sourceField /= this->db().time().deltaTValue()*this->mesh().V();
201 
202  return fvm::SuSp(trhoTrans()/rho, rho);
203  }
204  else
205  {
206  tmp<fvScalarMatrix> tfvm(new fvScalarMatrix(rho, dimMass/dimTime));
207  fvScalarMatrix& fvm = tfvm.ref();
208 
209  forAll(rhoTrans_, i)
210  {
211  sourceField += rhoTrans_[i];
212  }
213 
214  fvm.source() = -trhoTrans()/this->db().time().deltaT();
215 
216  return tfvm;
217  }
218  }
219 
220  return tmp<fvScalarMatrix>(new fvScalarMatrix(rho, dimMass/dimTime));
221 }
222 
223 
224 // ************************************************************************* //
Foam::fvScalarMatrix
fvMatrix< scalar > fvScalarMatrix
Definition: fvMatricesFwd.H:42
forAll
#define forAll(list, i)
Loop across all elements in list.
Definition: UList.H:434
Foam::fvc::SuSp
tmp< GeometricField< Type, fvPatchField, volMesh > > SuSp(const volScalarField &sp, const GeometricField< Type, fvPatchField, volMesh > &vf)
Definition: fvcSup.C:102
Foam::compressible::New
autoPtr< CompressibleMomentumTransportModel > New(const volScalarField &rho, const volVectorField &U, const surfaceScalarField &phi, const viscosity &viscosity)
Definition: compressibleMomentumTransportModelTemplates.C:34
Foam::PhaseChangeModel
Templated phase change model class.
Definition: ReactingCloud.H:57
Foam::tmp::ref
T & ref() const
Return non-const reference or generate a fatal error.
Definition: tmpI.H:181
Foam::ReactingCloud::rhoTrans
const PtrList< volScalarField::Internal > & rhoTrans() const
Return const access to mass source fields.
Definition: ReactingCloudI.H:81
Foam::dimless
const dimensionSet dimless
Foam::ReactingCloud::SYi
tmp< fvScalarMatrix > SYi(const label i, const volScalarField &Yi) const
Return mass source term for specie i - specie eqn.
Definition: ReactingCloudI.H:97
Foam::ReactingCloud::Srho
tmp< volScalarField::Internal > Srho() const
Return tmp total mass source for carrier phase.
Definition: ReactingCloudI.H:144
mesh
fvMesh & mesh
Definition: createMeshesPostProcess.H:9
Foam::neg
dimensionedScalar neg(const dimensionedScalar &ds)
Definition: dimensionedScalar.C:212
Foam::dimTime
const dimensionSet dimTime
Foam::ReactingCloud::cloudCopy
const ReactingCloud & cloudCopy() const
Return a reference to the cloud copy.
Definition: ReactingCloudI.H:32
Foam::fvMatrix
A special matrix type and solver, designed for finite volume solutions of scalar equations. Face addressing is used to make all matrix assembly and solution loops vectorise.
Definition: fvPatchField.H:72
Foam::ReactingCloud::constProps
const parcelType::constantProperties & constProps() const
Return the constant properties.
Definition: ReactingCloudI.H:40
Foam::pos0
dimensionedScalar pos0(const dimensionedScalar &ds)
Definition: dimensionedScalar.C:201
Foam::GeometricField::primitiveFieldRef
Internal::FieldType & primitiveFieldRef()
Return a reference to the internal field.
Definition: GeometricField.C:1026
Foam::fvMatrix::source
Field< Type > & source()
Definition: fvMatrix.H:300
Foam::dimMass
const dimensionSet dimMass
Foam::name
word name(const complex &)
Return a string representation of a complex.
Definition: complex.C:47
Sp
const tmp< volScalarField::Internal > & Sp
Definition: alphaSuSp.H:7
Foam::ReactingCloud
Templated base class for reacting cloud.
Definition: ReactingCloud.H:72
Foam::dimensionedScalar
dimensioned< scalar > dimensionedScalar
Dimensioned scalar obtained from generic dimensioned type.
Definition: dimensionedScalarFwd.H:41
Foam::PtrList
A templated 1D list of pointers to objects of type <T>, where the size of the array is known and used...
Definition: List.H:70
Foam::DimensionedField
Field with dimensions and associated with geometry type GeoMesh which is used to size the field and a...
Definition: DimensionedField.H:51
Foam::dimVolume
const dimensionSet dimVolume
Foam::solution
Selector class for relaxation factors, solver type and solution.
Definition: solution.H:48
Foam::tmp
A class for managing temporary objects.
Definition: PtrList.H:53
Foam::ReactingCloud::phaseChange
const PhaseChangeModel< ReactingCloud< CloudType > > & phaseChange() const
Return const access to reacting phase change model.
Definition: ReactingCloudI.H:56
fvmSup.H
Calculate the matrix for implicit and explicit sources.