Difference between revisions of "Inputs"

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(Premixed flame)
(Multiple Inlet)
Line 65: Line 65:
  
  
  //Inlet i
+
  //Inlet i
  listInlets.push_back(new MultipleInlet(
+
  new Inlet i
                "Temperature",
+
  T =
                "Pressure",
+
  Pressure =
                "Mass flow rate",
+
  MassFlowRate =
                "Xk",
+
  Xk =
                "Yk",
+
  EvaporationModel = false or true (0 or 1)
                /*evaporationModel*/ true or false,
+
  DropletDiameter =
                /*DropletDiameter*/,
+
  EvaporationTime =
                /*Tau_vj (characteristic time of evaporation)*/,
+
  liquidDensity =
                /*liquidDensity*/,
+
  EvaporationLatentHeat =
                /*EvaporationlatentHeat*/));
+
//EndInlet
  
Coupled with the inlet of burned gases :
 
  
  //BurnedGases
 
  listInlets.push_back(new MultipleInlet(
 
                "Temperature",
 
                "Pressure",
 
                "Mass flow rate",
 
                "Xk",
 
                "Yk",
 
                /*evaporationModel*/ false,
 
                /*DropletDiameter*/0.0,
 
                /*Tau_vj (characteristic time of evaporation)*/0.0,
 
                /*liquidDensity*/0.0,
 
                /*EvaporationlatentHeat*/ 0.0,
 
                /*tau_t (mixing time)*/,
 
                /*delta_t (time step)*/0.0,
 
                /*nbIterations*/0.0,
 
                /*BurnedGases*/ true ));
 
  
 +
Some last parameters are necessary :
  
One last parameter is necessary :
 
  
 +
NewMixing =
  
new_mixing = "true or false"
+
which determine if the mixing of the fluid particles is new or set from a previous mixing. For the first step of the analysis, this parameter is set to true, and false for all the other steps of the study, so the random mixing of the first step is re-used for the other ones.
  
 
+
  MixingTime =
which determine if the mixing of the fluid particles is new or set from a previous mixing. For the first step of the analysis, this parameter is set to true, and false for all the other steps of the study, so the random mixing of the first step is re-used for the other ones.
+
  TimeStep =
 +
  IterationNumber =
  
 
=== QSS and optimisation key words ===
 
=== QSS and optimisation key words ===

Revision as of 14:28, 1 February 2019

General keywords

All the necessary key words are contained in the file "input_file.ini", this is where you specify the characteristics of your flame and the ORCh step you want to run.

First, you choose the studied combustion regime (premixed flame, auto-ignition ou multiple Inlet regime) with the key word "configuration".

Then, the ORCh step you want to perform (DRGEP_species, DRGEP_reactions, ComputeTrajectories, computeQSSCriteria, getQSSfile, getQSSfileFORTRAN, Optimisation, or Lumping) with the key word "step".


The reference chemical scheme (key word mech_ref) (by default it is the scheme "mech" from which the user begins the step) and his associated trajectory file (key word : trajectory_ref) are optional.

Note that mech_ref and trajectory_ref are optional and useful only if the user wants to plot and calculate the fitness with other reference schemes than the default one. To use the default one, put "mech_ref = None"

The reference scheme (mech) of the current step, and the mechanism description (mech_desc) (the mech_desc doesn't change through the ORCh steps and corresponds to the id of the mechanism) :

The level of debug wanted (generally 1)


The species trajectories and/or the temperature and the flame speed (in Premixed configuration) the user wants to vizualise during the step (key word speciesToPlot).

Also if you want to plot the temperature and the flame velocity :

plot_T = 1 or 0 //temperature plot
plot_U = 1 or 0 //flame speed plot 

Then you define your target species with the key word "Target".

Premixed flame

If you want to reduce schemes for premixed flames, firstly you will run a flame with the following inputs :


configuration = PremixedFlames


//Flame 0
Tf =    //fuel temperature
To =   //oxidiser temperature
Pressure =
Equivalence_ratio = 
Xf =  //fuel molar composition
Xo = //oxidiser molar composition
Initial_flame =
Final_flame = 


In order to converge faster, you have to indicate a reference flame with characteristics close to the ones you want to run.

Note that you can perform the steps on several premixed flames, by adding more flames and the associated reference trajectories in the same order.


//Flame 0
...
//Flame 1
...
trajectory_ref = ...
trajectory_ref = ...

Multiple Inlet

Concerning this regime, as many inlets as needed can be added with the following characteristics :


 //Inlet i
 new Inlet i
 T = 
 Pressure = 
 MassFlowRate = 
 Xk = 
 EvaporationModel = false or true (0 or 1)
 DropletDiameter = 
 EvaporationTime = 
 liquidDensity = 
 EvaporationLatentHeat = 
//EndInlet


Some last parameters are necessary :


NewMixing = 

which determine if the mixing of the fluid particles is new or set from a previous mixing. For the first step of the analysis, this parameter is set to true, and false for all the other steps of the study, so the random mixing of the first step is re-used for the other ones.

 MixingTime = 
 TimeStep = 
 IterationNumber =

QSS and optimisation key words

Concerning the QSS part, the user have to fill a vector with the species put in QSS assumption. The user can test several scenarios (definition of multiple vectors)

  //------QSS Scenarios------//
   string array1[17] {"species1", "species2"};
   vector<string> vec(array1, array1 + sizeof(array1) /sizeof(array1[0]));
   listQSSscenarios.push_back(new QSSscenario(vec));
 
   ...


For the optimisation step, the user must indicate the size of the population at each generation, the number of generation that will be calculated, the number of the best solutions to copy generation to generation, the cross and mutation rate (best let to 0.75 and 0.02) and finally the allowed variation on the Arrhenius factors.

   //------Optimisation------//
   //MAKE SURE THE "listQSSscenarios" THAT IS PUSHED FIRST, IS THE SCENARIO YOU WANT TO OPTIMISE
    int PopSize = 22;
    int MaxAllowableGenerations = 10;
    int NbElitism = 1;
    double CrossoverRate = 0.75;
    double MutationRate = 0.02;
    double AllowedVariation_A = 0.005;
    double AllowedVariation_b = 0;
    double AllowedVariation_E = 0;
    listOptimScenarios = new OptimScenario(PopSize, MaxAllowableGenerations, NbElitism, CrossoverRate, MutationRate, AllowedVariation_A, AllowedVariation_b, AllowedVariation_E);