<p><b>Power flow is an integral part of distribution system planning,
monitoring, operation, and analysis. This two-part paper proposes a sensitivity-based
three-phase weather-dependent power flow approach for accurately simulating
distribution networks with local voltage controllers (LVC). This part II,
firstly, presents simulation results of the proposed approach in an 8-Bus and 7-Bus
network, which are validated using dynamic simulation. Secondly, simulation
results for the IEEE 8500-node network are also presented. An extensive
comparison is conducted between the proposed sensitivity-based approach and the
other existing power flow approaches with respect to result accuracy and
convergence speed. Moreover, the influence of weather and magnetic effects on
the power flow results and the LVC states is also investigated. Simulation
results confirm that the proposed sensitivity-based approach produces more
accurate results than the existing approaches since it considers the actual
switching sequence of LVCs as well as the weather and magnetic effects on the network.
Moreover, the proposed algorithm exhibits accelerated convergence due to the usage
of the sensitivity parameters, which makes it an important tool for distribution
system analysis. </b></p>