253,752 research outputs found
Transient Control of Synchronous Machine Active and Reactive Power in Micro-Grid Power Systems
There are two main topics associated with this dissertation. The first is to investigate
phase–to–neutral fault current magnitude occurring in generators with multiple zero–sequence
current sources. The second is to design, model, and tune a linear control system for oper-
ating a micro–grid in the event of a separation from the electric power system.
In the former case, detailed generator, AC8B excitation system, and four–wire electric
power system models are constructed. Where available, manufacturers data is used to
validate the generator and exciter models. A gain–delay with frequency droop control
is used to model an internal combustion engine and governor. The four wire system is
connected through a transformer impedance to an infinite bus. Phase–to–neutral faults are
imposed on the system, and fault magnitudes analyzed against three–phase faults to gauge
their severity.
In the latter case, a balanced three–phase system is assumed. The model structure from
the former case – but using data for a different generator – is incorporated with a model for
an energy storage device and a net load model to form a micro–grid. The primary control
model for the energy storage device has a high level of detail, as does the energy storage
device plant model in describing the LC filter and transformer. A gain–delay battery and
inverter model is used at the front end.
The net load model is intended to be the difference between renewable energy sources and
load within a micro–grid system that has separated from the grid. Given the variability of
iiboth renewable generation and load, frequency and voltage stability are not guaranteed.
This work is an attempt to model components of a proposed micro–grid system at the
University of Wisconsin Milwaukee, and design, model, and tune a linear control system
for operation in the event of a separation from the electric power system. The control
module is responsible for management of frequency and active power, and voltage and
reactive power.
The scope of this work is to
❼ develop a mathematical model for a salient pole, 2 damper winding synchronous
generator with d axis saturation suitable for transient analysis,
❼ develop a mathematical model for a voltage regulator and excitation system using
the IEEE AC8B voltage regulator and excitation system template,
❼ develop mathematical models for an energy storage primary control system, LC filter
and transformer suitable for transient analysis,
❼ combine the generator and energy storage models in a micro–grid context,
❼ develop mathematical models for electric system components in the stationary abc
frame and rotating dq reference frame,
❼ develop a secondary control network for dispatch of micro–grid assets,
❼ establish micro–grid limits of stable operation for step changes in load and power
commands based on simulations of model data assuming net load on the micro–grid,
and
❼ use generator and electric system models to assess the generator current magnitude
during phase–to–ground faults
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Photovoltaic and Behind-the-Meter Battery Storage: Advanced Smart Inverter Controls and Field Demonstration
Commercial-off-the-shelf simulation package interoperability: Issues and futures
Commercial-Off-The-Shelf Simulation Packages (CSPs) are widely used in industry to simulate discrete-event models. Interoperability of CSPs requires the use of distributed simulation techniques. Literature presents us with many examples of achieving CSP interoperability using bespoke solutions. However, for the wider adoption of CSP-based distributed simulation it is essential that, first and foremost, a standard for CSP interoperability be created, and secondly, these standards are adhered to by the CSP vendors. This advanced tutorial is on an emerging standard relating to CSP interoperability. It gives an overview of this standard and presents case studies that implement some of the proposed standards. Furthermore, interoperability is discussed in relation to large and complex models developed using CSPs that require large amount of computing resources. It is hoped that this tutorial will inform the simulation community of the issues associated with CSP interoperability, the importance of these standards and its future
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An Assessment of PIER Electric Grid Research 2003-2014 White Paper
This white paper describes the circumstances in California around the turn of the 21st century that led the California Energy Commission (CEC) to direct additional Public Interest Energy Research funds to address critical electric grid issues, especially those arising from integrating high penetrations of variable renewable generation with the electric grid. It contains an assessment of the beneficial science and technology advances of the resultant portfolio of electric grid research projects administered under the direction of the CEC by a competitively selected contractor, the University of California’s California Institute for Energy and the Environment, from 2003-2014
Implementation of a Human-Computer Interface for Computer Assisted Translation and Handwritten Text Recognition
A human-computer interface is developed to provide services of computer assisted machine translation (CAT) and computer assisted transcription of handwritten text images (CATTI). The back-end machine translation (MT) and handwritten text recognition (HTR) systems are provided by the Pattern Recognition and Human Language Technology (PRHLT) research group. The idea is to provide users with easy to use tools to convert interactive translation and transcription feasible tasks. The assisted service is provided by remote servers with CAT or CATTI capabilities. The interface supplies the user with tools for efficient local edition: deletion, insertion and substitution.Ocampo Sepúlveda, JC. (2009). Implementation of a Human-Computer Interface for Computer Assisted Translation and Handwritten Text Recognition. http://hdl.handle.net/10251/14318Archivo delegad
Towards a generic platform for developing CSCL applications using Grid infrastructure
The goal of this paper is to explore the possibility of using CSCL component-based software under a Grid infrastructure. The merge of these technologies represents an attractive, but probably quite laborious enterprise if we consider not only the benefits but also the barriers that we have to overcome. This work presents an attempt toward this direction by developing a generic platform of CSCL components and discussing the advantages that we could obtain if we adapted it to the Grid. We then propose a means that could make this adjustment possible due to the high degree of genericity that our library component is endowed with by being based on the generic programming paradigm. Finally, an application of our library is proposed both for validating the adequacy of the platform which it is based on and for indicating the possibilities gained by using it under the Grid.Peer ReviewedPostprint (published version
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Developing a grid computing system for commercial-off-the-shelf simulation packages
Today simulation is becoming an increasingly
pervasive technology across major business
sectors. Advances in COTS Simulation Packages
and Commercial Simulation Software have made
it easier for users to build models, often of large complex processes. These two factors combined are to be welcomed and when used correctly can be of great benefit to organisations that make use of the technology. However, it is also the case
that users hungry for answers do not always have the time, or possibly the patience, to wait for results from multiple replications and multiple experiments as standard simulation practice would demand. There is therefore a need to support this advance in the use of simulation within today’s business with improved computing technology. Grid computing has been put forward as a potential commercial solution to this requirement. To this end, Saker Solutions and the Distributed Systems Research Group at Brunel University have developed a dedicated Grid Computing System (SakerGrid) to support the deployment of simulation models across a desktop grid of PCs. The paper identifies route taken to solve this challenging issue and suggests where the future may lie for this exciting integration of two effective but underused technologies
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