adapted Druckrohrleitungscode to include pipeline

incline - not sure if code reproduces physical behavior because initial
pressure seems to disipate way too quickly

Druckrohrleitung/Druckrohrleitung_ETH_class_file.py

@@ -0,0 +1,171 @@
+import numpy as np
+
+#importing pressure conversion function
+import sys
+import os
+current = os.path.dirname(os.path.realpath(__file__))
+parent = os.path.dirname(current)
+sys.path.append(parent)
+from functions.pressure_conversion import pressure_conversion
+
+
+class Druckrohrleitung_class:
+# units
+    acceleration_unit   = r'$\mathrm{m}/\mathrm{s}^2$'
+    angle_unit          = '°'
+    area_unit           = r'$\mathrm{m}^2$'
+    density_unit        = r'$\mathrm{kg}/\mathrm{m}^3$'
+    flux_unit           = r'$\mathrm{m}^3/\mathrm{s}$'
+    length_unit         = 'm'
+    pressure_unit       = 'Pa'
+    time_unit           = 's'
+    velocity_unit       = r'$\mathrm{m}/\mathrm{s}$' # for flux and pressure propagation
+    volume_unit         = r'$\mathrm{m}^3$'
+
+    acceleration_unit_print   = 'm/s²'
+    angle_unit_print          = '°'
+    area_unit_print           = 'm²'
+    density_unit_print        = 'kg/m³'
+    flux_unit_print           = 'm³/s'
+    length_unit_print         = 'm'
+    pressure_unit_print       = 'Pa'
+    time_unit_print           = 's'
+    velocity_unit_print       = 'm/s' # for flux and pressure propagation
+    volume_unit_print         = 'm³'
+    
+
+# init
+    def __init__(self,total_length,diameter,number_segments,pipeline_angle,Darcy_friction_factor,rho=1000,g=9.81):
+        self.length     = total_length
+        self.dia        = diameter
+        self.n_seg      = number_segments
+        self.angle      = pipeline_angle
+        self.f_D        = Darcy_friction_factor     # = Rohrreibungszahl oder flow coefficient        
+        self.density    = 1000
+        self.g          = g
+        
+        self.dx      = total_length/number_segments
+        self.l_vec      = np.arange(0,(number_segments+1)*self.dx,self.dx)
+
+        # initialize for get_info method
+        self.c          = '--'
+        self.dt         = '--'
+
+# setter
+    def set_pressure_propagation_velocity(self,c):
+        self.c      = c
+        self.dt     = self.dx/c
+
+    def set_number_of_timesteps(self,number_timesteps):
+        self.nt     = number_timesteps
+        if self.c == '--':
+            raise Exception('Please set the pressure propagation velocity before setting the number of timesteps.')
+        else:
+            self.t_vec = np.arange(0,self.nt*self.dt,self.dt)
+
+    def set_initial_pressure(self,pressure,input_unit = 'Pa'):
+        p,_ = pressure_conversion(pressure,input_unit,target_unit=self.pressure_unit)
+        if np.size(p) == 1:
+            self.p0 = np.full_like(self.l_vec,p)
+        elif np.size(p) == np.size(self.l_vec):
+            self.p0 = p
+        else:
+             raise Exception('Unable to assign initial pressure. Input has to be of size 1 or' + np.size(self.l_vec))
+        
+        #initialize the vectors in which the old and new pressures are stored for the method of characteristics
+        self.p_old = self.p0.copy()
+        self.p = np.empty_like(self.p_old)
+    
+    def set_initial_flow_velocity(self,velocity):
+        if np.size(velocity) == 1:
+            self.v0 = np.full_like(self.l_vec,velocity)
+        elif np.size(velocity) == np.size(self.l_vec):
+            self.v0 = velocity
+        else:
+             raise Exception('Unable to assign initial velocity. Input has to be of size 1 or' + np.size(self.l_vec))    
+
+        #initialize the vectors in which the old and new velocities are stored for the method of characteristics
+        self.v_old = self.v0.copy()
+        self.v = np.empty_like(self.v_old)
+    
+    def set_boundary_conditions_next_timestep(self,v_reservoir,p_reservoir,v_turbine,input_unit_pressure = 'Pa'):
+        rho                 = self.density
+        c                   = self.c
+        f_D                 = self.f_D
+        dt                  = self.dt
+        D                   = self.dia
+        p_old               = self.p_old[-2]    # @ second to last node (the one before the turbine)
+        v_old               = self.v_old[-2]    # @ second to last node (the one before the turbine)
+        self.v_boundary_res = v_reservoir
+        self.v_boundary_tur = v_turbine
+        self.p_boundary_res,_ = pressure_conversion(p_reservoir,input_unit_pressure,target_unit=self.pressure_unit)
+        self.p_boundary_tur = p_old+rho*c*v_old-rho*c*f_D*dt/(2*D)*abs(v_old)*v_old
+        self.v[0]       = self.v_boundary_res.copy()
+        self.v[-1]      = self.v_boundary_tur.copy()
+        self.p[0]       = self.p_boundary_res.copy()
+        self.p[-1]      = self.p_boundary_tur.copy()
+
+# getter
+    def get_info(self):
+        new_line = '\n'
+
+        # :<10 pads the self.value to be 10 characters wide
+        print_str = (f"The pipeline has the following attributes: {new_line}" 
+            f"----------------------------- {new_line}"
+            f"Length                =       {self.length:<10} {self.length_unit_print} {new_line}"
+            f"Diameter              =       {self.dia:<10} {self.length_unit_print} {new_line}"
+            f"Number of segemnts    =       {self.n_seg:<10} {new_line}"
+            f"Number of nodes       =       {self.n_seg+1:<10} {new_line}"
+            f"Length per segment    =       {self.dx:<10} {self.length_unit_print} {new_line}"
+            f"Pipeline angle        =       {self.angle:<10} {self.angle_unit_print} {new_line}"
+            f"Darcy friction factor =       {self.f_D:<10} {new_line}"
+            f"Density of liquid     =       {self.density:<10} {self.density_unit_print} {new_line}"
+            f"Pressure wave vel.    =       {self.c:<10} {self.velocity_unit_print} {new_line}"
+            f"Simulation timesteps  =       {self.dt:<10} {self.time_unit_print } {new_line}"
+            f"Number of timesteps   =       {self.nt:<10} {new_line}"
+            f"----------------------------- {new_line}"
+            f"Velocity and pressure distribution are vectors and are accessible by the .v and .p attribute of the pipeline object")
+
+        print(print_str)    
+        
+
+    def get_boundary_conditions_next_timestep(self,target_unit_pressure ='bar'):
+        print('The pressure at the reservoir for the next timestep is', '\n', \
+                pressure_conversion(self.p_boundary_res,self.pressure_unit_print,target_unit_pressure), '\n', \
+            'The velocity at the reservoir for the next timestep is', '\n', \
+                self.v_boundary_res, self.velocity_unit, '\n', \
+            'The pressure at the turbine for the next timestep is', '\n', \
+                pressure_conversion(self.p_boundary_tur,self.pressure_unit_print,target_unit_pressure), '\n', \
+            'The velocity at the turbine for the next timestep is', '\n', \
+                self.v_boundary_tur, self.velocity_unit)         
+
+
+    def timestep_characteristic_method(self):
+        #number of nodes
+        nn  = self.n_seg+1
+        rho = self.density
+        c   = self.c
+        f_D = self.f_D
+        dt  = self.dt
+        D   = self.dia
+
+        for i in range(1,nn-1):
+            self.v[i] = 0.5*(self.v_old[i-1]+self.v_old[i+1])+0.5/(rho*c)*(self.p_old[i-1]-self.p_old[i+1]) \
+                -f_D*dt/(4*D)*(abs(self.v_old[i-1])*self.v_old[i-1]+abs(self.v_old[i+1])*self.v_old[i+1])
+
+            self.p[i] = 0.5*rho*c*(self.v_old[i-1]-self.v_old[i+1])+0.5*(self.p_old[i-1]+self.p_old[i+1]) \
+                -rho*c*f_D*dt/(4*D)*(abs(self.v_old[i-1])*self.v_old[i-1]-abs(self.v_old[i+1])*self.v_old[i+1])
+
+        self.p_old = self.p.copy()
+        self.v_old = self.v.copy()        
+
+
+
+
+
+
+
+
+
+
+