# Problem Definition (v-1.0)
The problem is to simulate a double pedestal blender (mixer) with diameters of 0.03 m and 0.1 m, length of 0.3 m, rotating at 28 rpm. This mixer is filled with 24000 particles. The integration time step is 0.00001 s. There is one type of particle in this mixer. Particles are positioned to fill the mixer before the simulation starts.
* **24000** particles with **5 mm** diameter are positioned, in order, and let to be settled under gravity. After settling particles, this blender starts to rotate at t=**1s**. 

<html>
<body>
<div align="center"><b>
	a view of the tote-blender while rotating 
</div></b>
<div align="center">
<img src="https://github.com/PhasicFlow/phasicFlow/blob/media/media/Tote-blender.gif", width=700px>
</div>
<div align="center"><i>
	particles are colored according to their velocity
</div></i>
</body>
</html>

# Setting up the Case
As explained in the previous cases, the simulation case setup is based on text-based scripts. Here, the simulation case setup files are stored in two folders: `caseSetup`, `setting` (see the folders above). Unlike the previous cases, this case does not have a `stl` file and the surfaces are defined based on the built-in utilities in phasicFlow. See the next section for more information on how to set up the geometry and its rotation.

## Geometry 

### Defining rotation axis
In file `settings/geometryDict` the information of rotating axis and speed of rotation are defined. The rotation of this blender starts at time=**0.5 s** and ends at time=**9.5 s**.

```C++
// information for rotatingAxisMotion motion model 
rotatingAxisInfo
{
	axisOfRotation 
	{
		p1 (-0.1 0.0 0.15);	// first point for the axis of rotation 
		p2 ( 0.1 0.0 0.15);	// second point for the axis of rotation
		
		omega 1.5708; 		// rotation speed ==> 15 rad/s
		
		// Start time of Geometry Rotating (s) 		
		startTime 0.5;
		
		// End time of Geometry Rotating (s)
		endTime 9.5;
	}
}
```


### Surfaces 
In `settings/geometryDict` file, the surfaces and motion component of each surface are defined to form a rotating tote-blender. The geometry is composed of top and bottom cylinders, top and bottom cones, a cylindrical shell and top and bottom Gates.

```C++
surfaces
{
	
	topGate
	{
		// type of wall
		type cylinderWall;
		
		// begin point of cylinder axis 
		p1 (0.0    0.0   0.3);
		
		// end point of cylinder axis 
		p2 (0.0    0.0   0.301);
		
		// radius at p1  
		radius1  0.03;
		
		// radius at p2		
		radius2	 0.0001;
		
		// material of wall
		material solidProperty;
		
		// motion component name
		motion axisOfRotation;	
	}

    topCylinder
	{
		// type of the wall
		type 		cylinderWall;
		
		// begin point of cylinder axis 	
		p1 			(0.0 0.0 0.28);
		
		// end point of cylinder axis  
		p2 			(0.0 0.0 0.3);
		
		// radius at p1  
		radius1 	0.03;
		
		// radius at p2		
		radius2 	0.03;
		
		// number of divisions		
		resolution 	36;
		
		// material name of this wall
		material 	solidProperty;
		
		// motion component name   	
		motion axisOfRotation;		
	}

	coneShelltop
	{	
		// type of the wall	
		type 		cylinderWall;
		
		// begin point of cylinder axis  	
		p1 			(0.0 0.0 0.2);
		
		// end point of cylinder axis  
		p2 			(0.0 0.0 0.28);
		
		// radius at p1  
		radius1 	0.1;
		
		// radius at p2		
		radius2 	0.03;
		
		// number of divisions		
		resolution 	36;
		
		// material name of this wall      	
		material 	solidProperty;
		
		// motion component name   	
		motion axisOfRotation;		
	}

	cylinderShell
	{
		// type of the wall
		type 		cylinderWall;
		
		// begin point of cylinder axis  	
		p1 			(0.0 0.0 0.1);
		
		// end point of cylinder axis
		p2 			(0.0 0.0 0.2);
		
		// radius at p1	  
		radius1 	0.1;
		
		// radius at p2			
		radius2 	0.1;
		
		// number of divisions		
		resolution 	36;
		
		// material name of this wall	      	
		material 	solidProperty; 
		
		// motion component name  	
		motion axisOfRotation;		
	}

	coneShelldown
	{
		
		// type of the wall
		type 		cylinderWall;
		
		// begin point of cylinder axis  	
		p1 			(0.0 0.0 0.02);
		
		// end point of cylinder axis  
		p2 			(0.0 0.0 0.1);
		
		// radius at p1  
		radius1 	0.03;
		
		// radius at p2		
		radius2 	0.1;
		
		// number of divisions		
		resolution 	36;
		
		// material name of this wall	      	
		material 	solidProperty;
		
		// motion component name   	
		motion axisOfRotation;		
	}

	bottomCylinder
	{
		// type of the wall
		type 		cylinderWall;  	
		
		// begin point of cylinder axis	
		p1 			(0.0 0.0 0.0);
		
		// end point of cylinder axis	  
		p2 			(0.0 0.0 0.02);
		
		// radius at p1  
		radius1 	0.03;
		
		// radius at p2			
		radius2 	0.03;
		
		// number of divisions			
		resolution 	36;
		
		// material name of this wall	      	
		material 	solidProperty;
		
		// motion component name	   	
		motion axisOfRotation;		
	}

	exitGate
	{
		
		// type of the wall
		type 		cylinderWall;  	
		
		// begin point of cylinder axis	
		p1 			(0.0 0.0 -0.001);
		
		// end point of cylinder axis	  
		p2 			(0.0 0.0 0.0);
		
		// radius at p1  
		radius1 	0.03;
		
		// radius at p2			
		radius2 	0.0001;
		
		// number of divisions			
		resolution 	36;
		
		// material name of this wall	      	
		material 	solidProperty;
		
		// motion component name	   	
		motion axisOfRotation;			
	}
		
}
```

## Defining particles 
### Diameter and material of spheres 
In the `caseSetup/shapes` the diameter and the material name of the particles are defined.

<div align="center"> 
in <b>caseSetup/shapes</b> file
</div>

```C++
// name of shapes 
names 		(sphere1); 	

// diameter of shapes (m)
diameters 	(0.005);

// material name for shapes 	
materials	(solidProperty);
```
### Particle positioning before start of simulation 
Particles are positioned before the start of simulation. The positioning can be ordered or random. Here we use ordered positioning. 24000 particles are positioned in a cylinderical region inside the tote-blender.

<div align="center"> 
in <b>settings/particlesDict</b> file
</div>

```C++
// positions particles 
positionParticles
{
	// ordered positioning
	method 	ordered;     
	// perform initial sorting based on morton code 
	mortonSorting 	Yes;  
  orderedInfo
  {
		// minimum space between centers of particles
		diameter 0.005;
		
		// number of particles in the simulation 	 	
		numPoints 24000;
	
		// axis order for filling the space with particles		 	
		axisOrder (x y z);  
	}           
	
regionType     cylinder;                     // other options: box and sphere               
	
cylinderInfo                                 // cylinder for positioning particles 
	{
		p1         (0.0 0.0 0.09);               // Coordinates of bottom cylinderRegion (m,m,m)
		
		p2         (0.0 0.0 0.21);               // Coordinates of top cylinderRegion (m,m,m)
		
		radius     0.09;                         // radius of cylinder
	}
}
```

 ## Interaction between particles
 In `caseSetup/interaction` file, material names and properties and interaction parameters are defined. Since we are defining 1 material type in the simulation, the interaction matrix is 1x1 (interactions are symmetric). 
```C++
 // a list of materials names
materials      (solidProperty);

// density of materials [kg/m3]
densities      (1000.0);   

contactListType   sortedContactList; 

model
{
   contactForceModel       nonLinearNonLimited;
    
   rollingFrictionModel    normal;
   
   /*
   Property (solidProperty-solidProperty);
   */
    
   // Young modulus [Pa]
   Yeff  (1.0e6);       

   // Shear modulus [Pa]
   Geff  (0.8e6);       
    
   // Poisson's ratio [-]
   nu    (0.25);        
    
   // coefficient of normal restitution
   en    (0.7);                  

   // dynamic friction
   mu    (0.3);          

   // rolling friction
   mur   (0.1);                  
}
```

# Performing Simulation and previewing the results 
To perform simulations, enter the following commands one after another in the terminal. 

Enter `particlesPhasicFlow` command to create the initial fields for particles.  
Enter `geometryPhasicFlow` command to create the geometry.  
At last, enter `sphereGranFlow` command to start the simulation.  
After finishing the simulation, you can use  `pFlowtoVTK` to convert the results into vtk format stored in ./VTK folder.