Development Of Current Injection Based Three Phase Unbalanced Continuation Power Flow For Distribution System

Toppo, Shilpa

10 December 2010

Voltage stability studies (VSS) of the electric network is a crucial factor to make the system operate in stable region and to prevent power blackouts. There are several commercial tools available for VSS of electric transmission systems (TS) but not many for distribution systems (DS). With increasing penetration of distributed renewable generations and meshed network within DS, shipboard power system (SPS) and microgrid, these VSS tools need to be extended for DS. Due to inherent characteristic like high R/X ratio, three phase and unbalanced operation, DS or SPS requires different mathematical approach than TS. Unbalanced three phase power flow and continuation power flow tools were developed using current injection and corrector predictor methods in this work for VSS. Maximum loading point for given DS or SPS can be computed using developed tools to guide required preventive and corrective actions. Developed tool was tested and validated for several different test cases.

Load flow analysis

Power distribution relaibility

Power system dynamics stability

A Simulation Environment for a Personal Portable Power System

Morrison, Shane Leland

30 April 2011

With the increased requirements for personal portable power systems to be more capable and better matched to the load and the mission, manufacturers have become interested in improved methods for predicting the performance of these systems. Personal portable power systems must meet challenging energy and portability requirements that require better predictive knowledge of these systems in integrated systems with realistic mission scenarios. This thesis presents the development of a modeling and simulation environment to further expand and predict the needs and requirements of personal portable power systems. The proposed personal portable power system is a diverse system consisting of energy and power sources, controllers, a DC-DC converter, batteries, and loads. An outcome of this initial simulation environment development is a tool that can be used in future work to plan scenarios and tasks.

power system

modeling

portable

Matlab

simulation

power

Simulink

Analysis and characterization of general security regions in power networks

Banakar, M. Hadi

January 1980

No description available.

Electric power system stability.

Electric power systems -- Control.

Voltage Regulation Control on a Power System with Static Var Compensator

Mandali, Anusree

08 September 2017

No description available.

Electrical Engineering

Advancements in power system monitoring and inter-operability

Mohan, Vinoth Mohan

11 December 2009

In a typical utility control center, there could be hundreds of applications running to take care of day-to-day functionality. In many cases, these applications are custom-built by different vendors. With the expectation for high reliability of the electric power grid, many utilities are increasingly moving towards sharing data with each other and with security coordinators. But this data exchange is hampered by incompatible electrical applications built on proprietary data formats and file systems. Electric Power Research Institute's (EPRI‟s) Common Information Model (CIM) was envisioned as a one-sizeits-all data model to remove incompatibility between applications. This research work utilizes the CIM models to exchange power system models and measurements between a state estimator application and sensor web application. The CIM was further extended to include few unique devices from the shipboard medium voltage DC power system. Finally, a wide-area monitoring test bed was set up at MSU to perform wide-area monitoring using phasor measurement units (PMU). The outputs from the Phasor Data Concentrator (PDC) were then converted into CIM/XML documents to make them compatible with the sensor web application. These applications have created advancements in power system monitoring and interoperability

Power system monitoring

phasor measurement unit

common information model

Protection and Automation of Microgrids for Flexible Distribution of Energy and Storage Resources

Haj-ahmed, Mohammed A.

13 August 2015

No description available.

Electrical Engineering

Optimal Expansion Strategy for a Developing Power System under the Conditions of Market Economy and Environmental Constraint: Case of Armenia

Avetisyan, Misak G.

26 September 2006

No description available.

Power system

Mathematical model

Environmental constraints

Optimal expansion

Strategy

Power system availability determination through Petri net simulation

Scruggs, James N.

January 1995

No description available.

Power System Elements

Single Breaker Markov Model

PETRI Net Models

Unit Response Modeling and Forecasting for a Large Electric Power System

Kandil, Nahi A.

January 1989

No description available.

Electrical Engineering

Unit response

medleing

forecasting

electric power system

Resilient Control Strategy and Analysis for Power Systems using (n, k)-Star Topology

Gong, Ning

January 2016

This research focuses on developing novel approaches in load balancing and restoration problems in electrical power distribution systems. The first approach introduces an inter-connected network topology, referred to as (n, k)-star topology. While power distribution systems can be constructed in different communication network topologies, the performance and fault assessment of the networked systems can be challenging to analyze. The (n, k)-star topologies have well defined performance and stability analysis metrics. Typically, these metrics are defined based on: i) degree, ii) diameter, and iii) conditional diagnosability of a faulty node. These parameters could be evaluated and assessed before a physical (n, k)-star topology power distribution system is constructed. Moreover, in the second approach, we evaluate load balancing problems by using a decentralized algorithm, i.e., the Multi-Agent System (MAS) based consensus algorithm on an (n, k)-star power topology. With aforementioned research approaches, an (n, k)-star power distribution system can be assessed with proposed metrics and assessed with encouraging results compared to other topology networked systems. Other encouraging results are found in efficiency and performance enhancement during information exchange using the decentralized algorithm. It has been proven that a load balance solution is convergent and asymptotically stable with a simple gain controller. The analysis can be achieved without constructing a physical network to help evaluate the design. Using the (n, k)-star topology and MAS, the load balancing/restoration problems can be solved much more quickly and accurately compared to other approaches shown in the literature. / Electrical and Computer Engineering

Electrical Engineering

Consensus Control

K)-star Topology

Power System

Resilience