def test_case57(): net = pn.case57() assert net.converged pp.runpp(net, trafo_model='pi') assert len(net.bus) == 57 assert len(net.line) + len(net.trafo) == 80 assert len(net.ext_grid) + len(net.gen) + len(net.sgen) == 7 assert net.converged
def __init__(self, system: str, tap_step=0.00625) -> None: self.system = system if system == "14": from pandapower.networks import case14 self.network = case14() elif system == "30": from pandapower.networks import case_ieee30 self.network = case_ieee30() elif system == "57": from pandapower.networks import case57 self.network = case57() self.tap_step = tap_step self.get_network_parameters() return
def test_case57(): net = pn.case57() assert net.converged _ppc_element_test(net, 57, 80, 7, True)
#!/usr/bin/env python3 # -*- coding: utf-8 -*- """ Created on Fri May 8 16:37:59 2020 @author: saraborchers """ import pandapower as pp import pandapower.networks as nw print("YAY!!") print("Hi Sara!!") # @cmgeery # CREATE NETWORK: create network, establish ideal voltages by load type net = nw.case57() # ADJUST NETWORK LOADS: bump voltages in various areas according to scenarios # SCENARIO 1: increased home charging # SCENARIO 2: increased quick charging stations # SCENARIO 3: mix of quick charging and home charging # RUN OPF # CREATE DEMAND PROFILES: time series calculations/load changes with time # EVALUATE EV USER CHARGES