diff --git a/tutorials/sphereGranFlow/rotatingDrumSmall/README.md b/tutorials/sphereGranFlow/rotatingDrumSmall/README.md
new file mode 100644
index 00000000..300b61d8
--- /dev/null
+++ b/tutorials/sphereGranFlow/rotatingDrumSmall/README.md
@@ -0,0 +1,235 @@
+## Problem definition
+The problem is to simulate a rotating drum with the diameter 0.24 m and the length 0.1 m rotating at 11.6 rpm. It is filled with 30,000 4-mm spherical particles. The timestep for integration is 0.00001 s.
+
+a view of rotating drum
+
+
+
+
+***
+
+## Setting up the case
+PhasicFlow simulation case setup is based on the text-based scripts that we provide in two folders located in the simulation case folder: `settings` and `caseSetup` (You can find the case setup files in the above folders.
+All the commands should be entered in the terminal while the current working directory is the simulation case folder (at the top of the `caseSetup` and `settings`).
+
+
+### Creating particles
+
+Open the file `settings/particlesDict`. Two dictionaries, `positionParticles` and `setFields` position particles and set the field values for the particles.
+In dictionary `positionParticles`, the positioning `method` is `positionOrdered`, which position particles in order in the space defined by `box`. `box` space is defined by two corner points `min` and `max`. In dictionary `positionOrderedInfo`, `numPoints` defines number of particles; `diameter`, the distance between two adjacent particles, and `axisOrder` defines the axis order for filling the space by particles.
+
+
+in settings/particlesDict file
+
+
+```C++
+positionParticles
+{
+ method positionOrdered; // ordered positioning
+ maxNumberOfParticles 40000; // maximum number of particles in the simulation
+ mortonSorting Yes; // perform initial sorting based on morton code?
+
+ box // box for positioning particles
+ {
+ min (-0.08 -0.08 0.015); // lower corner point of the box
+ max ( 0.08 0.08 0.098); // upper corner point of the box
+ }
+
+ positionOrderedInfo
+ {
+ diameter 0.004; // minimum space between centers of particles
+ numPoints 30000; // number of particles in the simulation
+ axisOrder (z y x); // axis order for filling the space with particles
+ }
+}
+```
+In dictionary `setFields`, dictionary `defaultValue` defines the initial value for particle fields (here, `velocity`, `acceleration`, `rotVelocity`, and `shapeName`). Note that `shapeName` field should be consistent with the name of shape that you later set for shapes (here one shape with name `sphere1`).
+
+
+in settings/particlesDict file
+
+
+```C++
+setFields
+{
+ defaultValue
+ {
+ velocity realx3 (0 0 0); // linear velocity (m/s)
+ acceleration realx3 (0 0 0); // linear acceleration (m/s2)
+ rotVelocity realx3 (0 0 0); // rotational velocity (rad/s)
+ shapeName word sphere1; // name of the particle shape
+ }
+ selectors
+ {}
+}
+```
+
+Enter the following command in the terminal to create the particles and store them in `0` folder.
+
+`> particlesPhasicFlow`
+
+### Creating geometry
+In file `settings/geometryDict` , you can provide information for creating geometry. Each simulation should have a `motionModel` that defines a model for moving the surfaces in the simulation. `rotatingAxisMotion` model defines a fixed axis which rotates around itself. The dictionary `rotAxis` defines an motion component with `p1` and `p2` as the end points of the axis and `omega` as the rotation speed in rad/s. You can define more than one motion component in a simulation.
+
+
+in settings/geometryDict file
+
+
+```C++
+motionModel rotatingAxisMotion;
+.
+.
+.
+rotatingAxisMotionInfo
+{
+ rotAxis
+ {
+ p1 (0.0 0.0 0.0); // first point for the axis of rotation
+ p2 (0.0 0.0 1.0); // second point for the axis of rotation
+ omega 1.214; // rotation speed (rad/s)
+ }
+}
+```
+In the dictionary `surfaces` you can define all the surfaces (walls) in the simulation. Two main options are available: built-in geometries in PhasicFlow, and providing surfaces with stl file. Here we use built-in geometries. In `cylinder` dictionary, a cylindrical shell with end radii, `radius1` and `radius2`, axis end points `p1` and `p2`, `material` name `prop1`, `motion` component `rotAxis` is defined. `resolution` sets number of division for the cylinder shell. `wall1` and `wall2` define two plane walls at two ends of cylindrical shell with coplanar corner points `p1`, `p2`, `p3`, and `p4`, `material` name `prop1` and `motion` component `rotAxis`.
+
+
+in settings/geometryDict file
+
+
+```C++
+surfaces
+{
+ cylinder
+ {
+ type cylinderWall; // type of the wall
+ p1 (0.0 0.0 0.0); // begin point of cylinder axis
+ p2 (0.0 0.0 0.1); // end point of cylinder axis
+ radius1 0.12; // radius at p1
+ radius2 0.12; // radius at p2
+ resolution 24; // number of divisions
+ material prop1; // material name of this wall
+ motion rotAxis; // motion component name
+ }
+ wall1
+ {
+ type planeWall; // type of the wall
+ p1 (-0.12 -0.12 0.0); // first point of the wall
+ p2 ( 0.12 -0.12 0.0); // second point
+ p3 ( 0.12 0.12 0.0); // third point
+ p4 (-0.12 0.12 0.0); // fourth point
+ material prop1; // material name of the wall
+ motion rotAxis; // motion component name
+ }
+ wall2
+ {
+ type planeWall;
+ p1 (-0.12 -0.12 0.1);
+ p2 ( 0.12 -0.12 0.1);
+ p3 ( 0.12 0.12 0.1);
+ p4 (-0.12 0.12 0.1);
+ material prop1;
+ motion rotAxis;
+ }
+}
+```
+Enter the following command in the terminal to create the geometry and store it in `0/geometry` folder.
+
+`> geometryPhasicFlow`
+
+### Defining properties and interactions
+In the file `caseSetup/interaction` , you find properties of materials. `materials` defines a list of material names in the simulation and `densities` sets the corresponding density of each material name. model dictionary defines the interaction model for particle-particle and particle-wall interactions. `contactForceModel` selects the model for mechanical contacts (here nonlinear model with limited tangential displacement) and `rollingFrictionModel` selects the model for calculating rolling friction. Other required prosperities should be defined in this dictionary.
+
+
+in caseSetup/interaction file
+
+
+```C++
+materials (prop1); // a list of materials names
+densities (1000.0); // density of materials [kg/m3]
+.
+.
+.
+model
+{
+ contactForceModel nonLinearNonLimited;
+ rollingFrictionModel normal;
+
+ Yeff (1.0e6); // Young modulus [Pa]
+ Geff (0.8e6); // Shear modulus [Pa]
+ nu (0.25); // Poisson's ratio [-]
+ en (0.7); // coefficient of normal restitution
+ et (1.0); // coefficient of tangential restitution
+ mu (0.3); // dynamic friction
+ mur (0.1); // rolling friction
+}
+```
+
+Dictionary `contactSearch` sets the methods for particle-particle and particle-wall contact search. `method` specifies the algorithm for finding neighbor list for particle-particle contacts and `wallMapping` shows how particles are mapped onto walls for finding neighbor list for particle-wall contacts. `updateFrequency` sets the frequency for updating neighbor list and `sizeRatio` sets the size of enlarged cells (with respect to particle diameter) for finding neighbor list. Larger `sizeRatio` include more particles in the neighbor list and you require to update it less frequent.
+
+
+in caseSetup/interaction file
+
+
+```C++
+contactSearch
+{
+ method NBS; // method for broad search particle-particle
+ wallMapping cellsSimple; // method for broad search particle-wall
+
+ NBSInfo
+ {
+ updateFrequency 20; // each 20 timesteps, update neighbor list
+ sizeRatio 1.1; // bounding box size to particle diameter (max)
+ }
+
+ cellsSimpleInfo
+ {
+ updateFrequency 20; // each 20 timesteps, update neighbor list
+ cellExtent 0.7; // bounding box for particle-wall search (> 0.5)
+ }
+
+}
+```
+
+In the file `caseSetup/sphereShape`, you can define a list of `names` for shapes (`shapeName` in particle field), a list of diameters for shapes and their `properties` names.
+
+
+in caseSetup/sphereShape file
+
+
+```C++
+names (sphere1); // names of shapes
+diameters (0.004); // diameter of shapes
+materials (prop1); // material names for shapes
+```
+
+Other settings for the simulation can be set in file `settings/settingsDict`. The dictionary `domain` defines the a rectangular bounding box with two corner points for the simulation. Each particle that gets out of this box, will be deleted automatically.
+
+
+in settings/settingsDict file
+
+
+```C++
+dt 0.00001; // time step for integration (s)
+startTime 0; // start time for simulation
+endTime 10; // end time for simulation
+saveInterval 0.1; // time interval for saving the simulation
+timePrecision 6; // maximum number of digits for time folder
+g (0 -9.8 0); // gravity vector (m/s2)
+domain
+{
+ min (-0.12 -0.12 0);
+ max (0.12 0.12 0.11);
+}
+integrationMethod AdamsBashforth2; // integration method
+```
+
+## Running the case
+The solver for this simulation is `sphereGranFlow`. Enter the following command in the terminal. Depending on the computational power, it may take a few minutes to a few hours to complete.
+
+`> sphereGranFlow`
+
+## Post processing
+After finishing the simulation, you can render the results in Paraview. To convert the results to VTK format, just enter the following command in the terminal. This will converts all the results (particles and geometry) to VTK format and store them in folder `VTK/`.
+
+`> pFlowToVTK`