HertzianSinterInteraction Class Reference

Computes normal forces in case of a linear plastic visco-elastic interaction. More...

#include <HertzianSinterInteraction.h>

+ Inheritance diagram for HertzianSinterInteraction:

Public Member Functions

 HertzianSinterInteraction (BaseInteractable *P, BaseInteractable *I, unsigned timeStamp)
 Constructor. More...
 
 HertzianSinterInteraction (const HertzianSinterInteraction &p)
 Copy constructor. More...
 
 HertzianSinterInteraction ()
 
 ~HertzianSinterInteraction () override
 Destructor. More...
 
void computeSinterForce ()
 Creates a copy of an object of this class. (Deep copy) More...
 
void computeNormalForce ()
 Calls computeSinterForce(). More...
 
void read (std::istream &is) override
 Interaction read function, which accepts an std::istream as input. More...
 
void write (std::ostream &os) const override
 Interaction write function, which accepts an std::ostream as input. More...
 
virtual std::string getBaseName () const
 Returns the name of the interaction. More...
 
Mdouble getElasticEnergy () const override
 Computes and returns the amount of elastic energy stored in the spring. More...
 
const HertzianSinterNormalSpeciesgetSpecies () const
 
Mdouble getMaxOverlap () const
 
void setMaxOverlap (Mdouble)
 
Mdouble getUnloadingModulus () const
 
- Public Member Functions inherited from BaseInteraction
 BaseInteraction (BaseInteractable *P, BaseInteractable *I, unsigned timeStamp)
 A constructor takes the BaseInteractable objects which are interacting (come into contact) and time the interaction starts. More...
 
 BaseInteraction ()
 
 BaseInteraction (const BaseInteraction &p)
 Copy constructor. More...
 
 ~BaseInteraction () override
 The destructor. It removes this interactions from the objects that were interacting, and writes the time to a file when needed. More...
 
virtual void actionsOnErase ()
 If an interaction needs to do something before it gets erased, add it here. E.g. Liquid bridges rupture at the end of their lifetime, and the liquid bridge volume has to be redistributed. The reason this action is not done in the destructor is that this action should not be taken when erasing ghost interactions. More...
 
virtual void computeForce ()
 Virtual function that contains the force law between the two objects interacting. More...
 
void writeToFStat (std::ostream &os, Mdouble time) const
 Writes forces data to the FStat file. More...
 
std::string getName () const override
 Virtual function which allows interactions to be named. More...
 
void setDistance (Mdouble distance)
 Sets the interaction distance between the two interacting objects. More...
 
void setNormal (Vec3D normal)
 Sets the normal vector between the two interacting objects. More...
 
void setOverlap (Mdouble overlap)
 Set the overlap between the two interacting object. More...
 
void setContactPoint (Vec3D contactPoint)
 Set the location of the contact point between the two interacting objects. More...
 
void setTimeStamp (unsigned timeStamp)
 Updates the time step of the interacting. Note, time steps used to find completed interactions. More...
 
void setSpecies (const BaseSpecies *species)
 Set the Species of the interaction; note this can either be a Species or MixedSpecies. More...
 
void setP (BaseInteractable *P)
 Sets the first object involved in the interaction (normally a particle). More...
 
void setI (BaseInteractable *I)
 Sets the second object involved in the interaction (often particle or wall). More...
 
void importP (BaseInteractable *P)
 Sets the first object involved in the interaction (normally a particle). More...
 
void importI (BaseInteractable *I)
 Sets the second object involved in the interaction (often particle or wall). More...
 
Vec3D getIP () const
 
Vec3D getIC () const
 
Vec3D getCP () const
 
void setLagrangeMultiplier (Mdouble multiplier)
 
Mdouble getLagrangeMultiplier ()
 
void setHandler (InteractionHandler *handler)
 Sets the pointer to the interaction hander which is storing this interaction. More...
 
InteractionHandlergetHandler () const
 Gets a point to the interaction handlers to which this interaction belongs. More...
 
const Vec3DgetForce () const
 Gets the current force (vector) between the two interacting objects. More...
 
const Vec3DgetTorque () const
 Gets the current torque (vector) between the two interacting objects. More...
 
const Vec3DgetNormal () const
 Gets the normal vector between the two interacting objects. More...
 
const Vec3DgetContactPoint () const
 Gets constant reference to contact point (vector). More...
 
Mdouble getOverlap () const
 Returns a Mdouble with the current overlap between the two interacting objects. More...
 
Mdouble getOverlapVolume () const
 Returns the overlap volume between two interacting objects. More...
 
Mdouble getContactRadius () const
 Returns a Mdouble with the current contact between the two interacting objects. More...
 
void removeFromHandler ()
 Removes this interaction from its interaction hander. More...
 
void copySwitchPointer (const BaseInteractable *original, BaseInteractable *ghost) const
 This copies the interactions of the original particle and replaces the original with the ghost copy. More...
 
void gatherContactStatistics ()
 
BaseInteractablegetP ()
 Returns a pointer to first object involved in the interaction (normally a particle). More...
 
BaseInteractablegetI ()
 Returns a pointer to the second object involved in the interaction (often a wall or a particle). More...
 
const BaseInteractablegetP () const
 Returns a constant pointer to the first object involved in the interaction. More...
 
const BaseInteractablegetI () const
 Returns a constant pointer to the second object involved in the interaction. More...
 
Mdouble getTimeStamp () const
 Returns an Mdouble which is the time stamp of the interaction. More...
 
virtual void integrate (Mdouble timeStep)
 integrates variables of the interaction which need to be integrate e.g. the tangential overlap. More...
 
virtual Mdouble getTangentialOverlap () const
 get the length of the current tangential overlap More...
 
Mdouble getDistance () const
 Returns an Mdouble which is the norm (length) of distance vector. More...
 
const Vec3DgetRelativeVelocity () const
 Returns a constant reference to a vector of relative velocity. More...
 
Mdouble getNormalRelativeVelocity () const
 Returns a double which is the norm (length) of the relative velocity vector. More...
 
Mdouble getAbsoluteNormalForce () const
 Returns the absolute value of the norm (length) of the Normal force vector. More...
 
virtual BaseInteractioncopy () const =0
 Makes a copy of the interaction and returns a pointer to the copy. More...
 
void setFStatData (std::fstream &fstat, BaseParticle *P, BaseWall *I)
 
void setFStatData (std::fstream &fstat, BaseParticle *P, BaseParticle *I)
 
unsigned int getMultiContactIdentifier () const
 
void setMultiContactIdentifier (unsigned int multiContactIdentifier_)
 
virtual void rotateHistory (Matrix3D &rotationMatrix)
 When periodic particles are used, some interactions need certain history properties rotated (e.g. tangential springs). This is the function for that. More...
 
virtual void actionsAfterTimeStep ()
 
virtual unsigned getNumberOfFieldsVTK () const
 
virtual std::string getTypeVTK (unsigned i) const
 
virtual std::string getNameVTK (unsigned i) const
 
virtual std::vector< MdoublegetFieldVTK (unsigned i) const
 
void addForce (Vec3D force)
 add an force increment to the total force. More...
 
void addTorque (Vec3D torque)
 add a torque increment to the total torque. More...
 
void setForce (Vec3D force)
 set total force (this is used by the normal force, tangential forces are added use addForce) More...
 
void setTorque (Vec3D torque)
 set the total force (this is used by the normal force, tangential torques are added use addTorque) More...
 
const BaseSpeciesgetBaseSpecies () const
 Return a constant point to BaseSpecies of the interaction. More...
 
virtual void createMPIType ()
 
virtual void * createMPIInteractionDataArray (unsigned int numberOfInteractions) const
 
virtual void deleteMPIInteractionDataArray (void *dataArray)
 
virtual void getMPIInteraction (void *historyDataArray, unsigned int index) const
 copies the history interactions into the data array More...
 
virtual void getInteractionDetails (void *interactionDataArray, unsigned int index, unsigned int &identificationP, unsigned int &identificationI, bool &isWallInteraction, unsigned &timeStamp)
 
virtual void setMPIInteraction (void *interactionDataArray, unsigned int index, bool resetPointers)
 
void setBasicMPIInteractionValues (int P, int I, unsigned timeStamp, Vec3D force, Vec3D torque, bool isWallInteraction, bool resetPointers)
 
void setIdentificationP (unsigned int identification)
 
void setIdentificationI (int identification)
 
void setWallInteraction (bool flag)
 
unsigned int getIdentificationP ()
 
int getIdentificationI ()
 
bool isWallInteraction ()
 
virtual bool isBonded () const
 
- Public Member Functions inherited from BaseObject
 BaseObject ()=default
 Default constructor. More...
 
 BaseObject (const BaseObject &p)=default
 Copy constructor, copies all the objects BaseObject contains. More...
 
virtual ~BaseObject ()=default
 virtual destructor More...
 
virtual void moveInHandler (unsigned int index)
 Except that it is virtual, it does the same thing as setIndex() does. More...
 
void setIndex (unsigned int index)
 Allows one to assign an index to an object in the handler/container. More...
 
void setId (unsigned long id)
 Assigns a unique identifier to each object in the handler (container) which remains constant even after the object is deleted from the container/handler. More...
 
unsigned int getIndex () const
 Returns the index of the object in the handler. More...
 
unsigned int getId () const
 Returns the unique identifier of any particular object. More...
 
void setGroupId (unsigned groupId)
 
unsigned getGroupId () const
 

Private Attributes

Mdouble maxOverlap_
 

Additional Inherited Members

- Protected Member Functions inherited from BaseInteraction
virtual const Vec3D getTangentialForce () const
 
Mdouble getEffectiveRadius () const
 Returns a Mdouble to the effective radius of the interaction. (Not corrected for the overlap) More...
 
Mdouble getEffectiveMass () const
 Returns a Mdouble to the effective radius of the interaction. (Not corrected for the overlap) More...
 
void setRelativeVelocity (Vec3D relativeVelocity)
 set the relative velocity of the current of the interactions. More...
 
void setNormalRelativeVelocity (Mdouble normalRelativeVelocit)
 set the normal component of the relative velocity. More...
 
void setAbsoluteNormalForce (Mdouble absoluteNormalForce)
 the absolute values of the norm (length) of the normal force More...
 
virtual Mdouble getElasticEnergyAtEquilibrium (Mdouble adhesiveForce) const
 
virtual void reverseHistory ()
 When periodic particles some interaction need certain history properties reversing. This is the function for that. More...
 
void writeInteraction (std::ostream &os, bool created) const
 Writes information about a interaction to the interaction file. More...
 

Detailed Description

Computes normal forces in case of a linear plastic visco-elastic interaction.

Constructor & Destructor Documentation

◆ HertzianSinterInteraction() [1/3]

HertzianSinterInteraction::HertzianSinterInteraction ( BaseInteractable P,
BaseInteractable I,
unsigned  timeStamp 
)

Constructor.

Parameters
[in]P
[in]I
[in]timeStamp
43  : BaseInteraction(P, I, timeStamp)
44 {
45  maxOverlap_ = 0;
46 #ifdef DEBUG_CONSTRUCTOR
47  std::cout<<"HertzianSinterInteraction::HertzianSinterInteraction() finished"<<std::endl;
48 #endif
49 }
BaseInteraction()
Definition: BaseInteraction.cc:65
Mdouble maxOverlap_
Definition: HertzianSinterInteraction.h:116
double P
Uniform pressure.
Definition: TwenteMeshGluing.cpp:73

References maxOverlap_.

◆ HertzianSinterInteraction() [2/3]

HertzianSinterInteraction::HertzianSinterInteraction ( const HertzianSinterInteraction p)

Copy constructor.

Parameters
[in]p
55  : BaseInteraction(p)
56 {
58 #ifdef DEBUG_CONSTRUCTOR
59  std::cout<<"HertzianSinterInteraction::HertzianSinterInteraction(const HertzianSinterInteraction &p finished"<<std::endl;
60 #endif
61 }

References maxOverlap_.

◆ HertzianSinterInteraction() [3/3]

HertzianSinterInteraction::HertzianSinterInteraction ( )
default
Todo:
: MX add interaction to mpi

◆ ~HertzianSinterInteraction()

HertzianSinterInteraction::~HertzianSinterInteraction ( )
override

Destructor.

69 {
70 #ifdef DEBUG_DESTRUCTOR
71  std::cout<<"HertzianSinterInteraction::~HertzianSinterInteraction() finished"<<std::endl;
72 #endif
73 }

Member Function Documentation

◆ computeNormalForce()

void HertzianSinterInteraction::computeNormalForce ( )

Calls computeSinterForce().

194 {
196 }
void computeSinterForce()
Creates a copy of an object of this class. (Deep copy)
Definition: HertzianSinterInteraction.cc:107

References computeSinterForce().

◆ computeSinterForce()

void HertzianSinterInteraction::computeSinterForce ( )

Creates a copy of an object of this class. (Deep copy)

Computes the normal forces due to linear plastic visco elastic interaction.

108 {
109  // Compute the relative velocity vector of particle P w.r.t. I
111  getP()->getVelocityAtContact(getContactPoint()) - getI()->getVelocityAtContact(getContactPoint()));
112  // Compute the projection of vrel onto the normal (can be negative)
114 
115  if (getOverlap() > 0) //if contact forces
116  {
117  const HertzianSinterNormalSpecies* species = getSpecies();
118  Mdouble effectiveDiameter = 2.0 * getEffectiveRadius();
119 
120  //calculate the overlap above which the max. unloading stiffness becomes active (the 'fluid branch')
121  static Mdouble maxFactor = 1
123  cbrt((species->getLoadingModulus() + species->getCohesionModulus()) /
124  species->getUnloadingModulusMax()));
125  Mdouble deltaStar = species->getPenetrationDepthMax() * effectiveDiameter / maxFactor;
126 
127  //increase max overlap if necessary
128  if (getOverlap() > getMaxOverlap())
129  {
131  logger(INFO, ",%", getHandler()->getDPMBase()->getTime(), Flusher::NO_FLUSH);
132  }
133  //limit max overlap if necessary
134  if (getMaxOverlap() > deltaStar)
135  setMaxOverlap(deltaStar);
136 
137  //calculate the unloading modulus
138  Mdouble loadingCohesionModulus = species->getLoadingModulus() + species->getCohesionModulus();
139  Mdouble unloadingModulus = loadingCohesionModulus
140  + (species->getUnloadingModulusMax() - loadingCohesionModulus) *
141  (getMaxOverlap() / deltaStar);
142 
143  //calculate the overlap where the force is minimal
144  Mdouble factor = 1 - mathsFunc::square(cbrt(loadingCohesionModulus / unloadingModulus));
145  Mdouble minOverlap = factor * maxOverlap_;
146 
147  //add dissipative force
148  Mdouble normalForce = -species->getDissipation() * getNormalRelativeVelocity();
149 
150  //compute elastic force
151  if (getOverlap() < minOverlap)
152  {
153  //decrease max overlap if in cohesive range
154  logger(INFO, ".%", getHandler()->getDPMBase()->getTime(), Flusher::NO_FLUSH);
155  setMaxOverlap(getOverlap() / factor);
156  }
157  else
158  {
159  Mdouble contactRadius = sqrt(2.0 * effectiveDiameter * (getOverlap() - minOverlap));
160  normalForce += 4. / 3. * unloadingModulus * contactRadius * (getOverlap() - minOverlap);
161  }
162 
163  setAbsoluteNormalForce(std::abs(normalForce)); //used for the friction force calculations;
164 
165  Mdouble contactRadius = sqrt(2.0 * effectiveDiameter * getOverlap());
166  normalForce -= 4. / 3. * species->getCohesionModulus() * contactRadius * getOverlap();
167 
168  setForce(getNormal() * normalForce);
169  setTorque(Vec3D(0.0, 0.0, 0.0));
170 
171  //now add the sintering model 'modified Frenkel' of the Pokula paper
172  //plasticOverlap_+=species->getSinterRate()*(deltaStar-plasticOverlap_)*getHandler()->getDPMBase()->getTimeStep();
173  //x/a=sqrt(2*a*del)/a
174  Mdouble x = 1e-10 + sqrt(2.0 * maxOverlap_ / effectiveDiameter);
175  //Mdouble x2 = x*x;
176  Mdouble dx = 0.5 /
177  x;//+ x*(-0.5 + x2* (0.15625 + x2*(-0.0208333 +x2*(-0.00325521 +x2*(0.000189887 +x2*0.0000542535)))));
178  Mdouble doverlap = x * dx * effectiveDiameter;
179  //doverlap = 0.5/(factor*factor*plasticOverlap_);
180  maxOverlap_ += species->getSinterRate() * doverlap * getHandler()->getDPMBase()->getTimeStep();
181  }
182  else
183  {
185  setForce(Vec3D(0.0, 0.0, 0.0));
186  setTorque(Vec3D(0.0, 0.0, 0.0));
187  }
188 }
double Mdouble
Definition: GeneralDefine.h:34
Logger< MERCURYDPM_LOGLEVEL > logger("MercuryKernel")
Definition of different loggers with certain modules. A user can define its own custom logger here.
@ INFO
DPMBase * getDPMBase()
Gets the problem that is solved using this handler.
Definition: BaseHandler.h:725
const Vec3D & getRelativeVelocity() const
Returns a constant reference to a vector of relative velocity.
Definition: BaseInteraction.cc:573
void setAbsoluteNormalForce(Mdouble absoluteNormalForce)
the absolute values of the norm (length) of the normal force
Definition: BaseInteraction.cc:670
const Vec3D & getContactPoint() const
Gets constant reference to contact point (vector).
Definition: BaseInteraction.h:234
const Vec3D & getNormal() const
Gets the normal vector between the two interacting objects.
Definition: BaseInteraction.h:226
Mdouble getNormalRelativeVelocity() const
Returns a double which is the norm (length) of the relative velocity vector.
Definition: BaseInteraction.cc:584
Mdouble getEffectiveRadius() const
Returns a Mdouble to the effective radius of the interaction. (Not corrected for the overlap)
Definition: BaseInteraction.cc:793
void setRelativeVelocity(Vec3D relativeVelocity)
set the relative velocity of the current of the interactions.
Definition: BaseInteraction.cc:649
BaseInteractable * getI()
Returns a pointer to the second object involved in the interaction (often a wall or a particle).
Definition: BaseInteraction.h:285
BaseInteractable * getP()
Returns a pointer to first object involved in the interaction (normally a particle).
Definition: BaseInteraction.h:274
InteractionHandler * getHandler() const
Gets a point to the interaction handlers to which this interaction belongs.
Definition: BaseInteraction.cc:267
void setNormalRelativeVelocity(Mdouble normalRelativeVelocit)
set the normal component of the relative velocity.
Definition: BaseInteraction.cc:660
void setForce(Vec3D force)
set total force (this is used by the normal force, tangential forces are added use addForce)
Definition: BaseInteraction.cc:627
void setTorque(Vec3D torque)
set the total force (this is used by the normal force, tangential torques are added use addTorque)
Definition: BaseInteraction.cc:638
Mdouble getOverlap() const
Returns a Mdouble with the current overlap between the two interacting objects.
Definition: BaseInteraction.h:240
Mdouble getTimeStep() const
Returns the simulation time step.
Definition: DPMBase.cc:1250
void setMaxOverlap(Mdouble)
Definition: HertzianSinterInteraction.cc:229
Mdouble getMaxOverlap() const
Definition: HertzianSinterInteraction.cc:221
const HertzianSinterNormalSpecies * getSpecies() const
Definition: HertzianSinterInteraction.cc:213
HertzianSinterNormalSpecies contains the parameters used to describe a plastic-cohesive normal force ...
Definition: HertzianSinterNormalSpecies.h:38
Mdouble getCohesionModulus() const
Returns the cohesive stiffness of the linear plastic-viscoelastic normal force.
Definition: HertzianSinterNormalSpecies.cc:164
Mdouble getDissipation() const
Allows the normal dissipation to be accessed.
Definition: HertzianSinterNormalSpecies.cc:261
Mdouble getUnloadingModulusMax() const
Returns the maximum unloading stiffness of the linear plastic-viscoelastic normal force.
Definition: HertzianSinterNormalSpecies.cc:156
Mdouble getPenetrationDepthMax() const
Returns the maximum penetration depth of the linear plastic-viscoelastic normal force.
Definition: HertzianSinterNormalSpecies.cc:172
Mdouble getSinterRate() const
Allows the normal dissipation to be accessed.
Definition: HertzianSinterNormalSpecies.cc:269
Mdouble getLoadingModulus() const
Returns the loading stiffness of the linear plastic-viscoelastic normal force.
Definition: HertzianSinterNormalSpecies.cc:148
Definition: Vector.h:51
static Mdouble dot(const Vec3D &a, const Vec3D &b)
Calculates the dot product of two Vec3D: .
Definition: Vector.cc:76
T square(const T val)
squares a number
Definition: ExtendedMath.h:106

References Vec3D::dot(), HertzianSinterNormalSpecies::getCohesionModulus(), BaseInteraction::getContactPoint(), HertzianSinterNormalSpecies::getDissipation(), BaseHandler< T >::getDPMBase(), BaseInteraction::getEffectiveRadius(), BaseInteraction::getHandler(), BaseInteraction::getI(), HertzianSinterNormalSpecies::getLoadingModulus(), getMaxOverlap(), BaseInteraction::getNormal(), BaseInteraction::getNormalRelativeVelocity(), BaseInteraction::getOverlap(), BaseInteraction::getP(), HertzianSinterNormalSpecies::getPenetrationDepthMax(), BaseInteraction::getRelativeVelocity(), HertzianSinterNormalSpecies::getSinterRate(), getSpecies(), DPMBase::getTimeStep(), HertzianSinterNormalSpecies::getUnloadingModulusMax(), INFO, logger, maxOverlap_, NO_FLUSH, BaseInteraction::setAbsoluteNormalForce(), BaseInteraction::setForce(), setMaxOverlap(), BaseInteraction::setNormalRelativeVelocity(), BaseInteraction::setRelativeVelocity(), BaseInteraction::setTorque(), and mathsFunc::square().

Referenced by computeNormalForce().

◆ getBaseName()

std::string HertzianSinterInteraction::getBaseName ( ) const
virtual

Returns the name of the interaction.

Returns
std::string
100 {
101  return "HertzianSinter";
102 }

◆ getElasticEnergy()

Mdouble HertzianSinterInteraction::getElasticEnergy ( ) const
overridevirtual

Computes and returns the amount of elastic energy stored in the spring.

Returns
Mdouble
Todo:
TW this is not correct; we should count the return energy

Reimplemented from BaseInteraction.

202 {
203  if (getOverlap() > 0)
204  return 0.5 * (getSpecies()->getLoadingModulus() * mathsFunc::square(getOverlap()));
205  else
206  return 0.0;
208 }

References HertzianSinterNormalSpecies::getLoadingModulus(), BaseInteraction::getOverlap(), getSpecies(), and mathsFunc::square().

◆ getMaxOverlap()

Mdouble HertzianSinterInteraction::getMaxOverlap ( ) const
Returns
Mdouble plasticOverlap_
222 {
223  return maxOverlap_;
224 }

References maxOverlap_.

Referenced by computeSinterForce(), and getUnloadingModulus().

◆ getSpecies()

const HertzianSinterNormalSpecies * HertzianSinterInteraction::getSpecies ( ) const
Returns
const HertzianSinterNormalSpecies*
214 {
215  return static_cast<const HertzianSinterNormalSpecies*>(getBaseSpecies()->getNormalForce());
216 }
const BaseSpecies * getBaseSpecies() const
Return a constant point to BaseSpecies of the interaction.
Definition: BaseInteraction.cc:682
BaseNormalForce * getNormalForce() const
Definition: BaseSpecies.h:148

References BaseInteraction::getBaseSpecies(), and BaseSpecies::getNormalForce().

Referenced by computeSinterForce(), getElasticEnergy(), and getUnloadingModulus().

◆ getUnloadingModulus()

Mdouble HertzianSinterInteraction::getUnloadingModulus ( ) const
Returns
Mdouble
238 {
239  const HertzianSinterNormalSpecies* species = getSpecies();
240  Mdouble effectiveDiameter = 2.0 * getEffectiveRadius();
241  Mdouble deltaMaxFluid = species->getPenetrationDepthMax() * effectiveDiameter /
242  (1.0 - species->getLoadingModulus() / species->getUnloadingModulusMax());
243  if (getOverlap() > deltaMaxFluid)
244  return species->getUnloadingModulusMax();
245  else
246  return species->getLoadingModulus() +
247  (species->getUnloadingModulusMax() - species->getLoadingModulus()) * getMaxOverlap() / deltaMaxFluid;
248 }

References BaseInteraction::getEffectiveRadius(), HertzianSinterNormalSpecies::getLoadingModulus(), getMaxOverlap(), BaseInteraction::getOverlap(), HertzianSinterNormalSpecies::getPenetrationDepthMax(), getSpecies(), and HertzianSinterNormalSpecies::getUnloadingModulusMax().

◆ read()

void HertzianSinterInteraction::read ( std::istream &  is)
overridevirtual

Interaction read function, which accepts an std::istream as input.

Calls the read function of BaseInteraction().

Parameters
[in,out]is

Reimplemented from BaseInteraction.

90 {
92  std::string dummy;
93  is >> dummy >> maxOverlap_;
94 }
void read(std::istream &is) override
Interaction read function, which accepts an std::istream as input.
Definition: BaseInteraction.cc:188

References maxOverlap_, and BaseInteraction::read().

◆ setMaxOverlap()

void HertzianSinterInteraction::setMaxOverlap ( Mdouble  maxOverlap)
Parameters
[in]maxOverlap
230 {
231  maxOverlap_ = maxOverlap;
232 }

References maxOverlap_.

Referenced by computeSinterForce().

◆ write()

void HertzianSinterInteraction::write ( std::ostream &  os) const
overridevirtual

Interaction write function, which accepts an std::ostream as input.

Calls the write function of BaseInteraction().

Parameters
[in,out]os

Reimplemented from BaseInteraction.

80 {
82  os << " maxOverlap " << maxOverlap_;
83 }
void write(std::ostream &os) const override
Interaction print function, which accepts an std::ostream as input.
Definition: BaseInteraction.cc:159

References maxOverlap_, and BaseInteraction::write().

Member Data Documentation

◆ maxOverlap_

Mdouble HertzianSinterInteraction::maxOverlap_
private

The documentation for this class was generated from the following files: