Design and modelling of microgrid
The demand for power is growing globally and the development of microgrids is turning into a conceivably appealing alternative to meet the escalating energy demand. Microgrid reflects a new way of thinking about designing, and outlining smart grids. A microgrid system consists of distributed gene...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2016
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/65880 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | The demand for power is growing globally and the development of microgrids is
turning into a conceivably appealing alternative to meet the escalating energy demand.
Microgrid reflects a new way of thinking about designing, and outlining smart grids.
A microgrid system consists of distributed generation units, storage devices, loads
which can be operated either parallelly with the electric utility network or in isolated
mode.
The principal sources of electrical energy generation are fossil fuels (coal, oil and gas),
nuclear fuels, etc. which cannot be replenished and due to the environmental impacts,
the need for renewable energy sources is hastening. There a good scope for large
number of distributed generations powered by renewable energy generation units
connected to grid in the immediate future. Microgrids are low voltage networks,
designed to deliver energy to relatively smaller areas rather than massive regions. The
coordinated control of generation sources with presumably contradictory
requirements, limited communication and significantly high transmission losses
enforces the adoption of distributed intelligence techniques. The relatively smaller
scale alleviates transmission loss with superior control, better security, improved
reliability and design flexibility.
The major objective of the project is to design a microgrid system by setting up models
of different distributed generation sources and evaluate the system performance by
computer simulation. The modelled microgrid employs the combination of solar
photovoltaic system (with maximum power point tracking and inverter control), fuel
cell and battery systems. Asynchronous motor loads and RL loads have been utilized
in the model. A synchronous generator with Hydraulic Turbine and Governor (HTG)
system and excitation system is used for regulating the microgrid voltage and
frequency during changeover between grid-connected mode and isolated modes of
operation. The results have been obtained from the MATLAB & SIMULINK
environment. |
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