The effect of distributed electricity generation using natural gas on the electric and natural gas grids

The effect of distributed electricity generation using natural gas on the electric and natural gas grids

•Gas-fueled distributed generation increases dependency of electric grid on gas grid.•Optimal operation of group of 10kW and 50kW electric generators for load flattening.•Consider effects of centralized vs. decentralized decision making and seasonality. The efficient and economical design and operat...

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Bibliographic Details
Published in:Applied energy Vol. 177; pp. 500 - 514
Main Authors: Touretzky, Cara R., McGuffin, Dana L., Ziesmer, Jena C., Baldea, Michael
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-09-2016
Subjects:
Demand response
Distributed generation
Durability
Economics
Electric grid
Electric power distribution
Electricity
Infrastructure
Load flattening
Natural gas
Natural gas grid
Small scale
Load flattening
Distributed generation
Demand response
Electric grid
Natural gas grid
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Summary:•Gas-fueled distributed generation increases dependency of electric grid on gas grid.•Optimal operation of group of 10kW and 50kW electric generators for load flattening.•Consider effects of centralized vs. decentralized decision making and seasonality. The efficient and economical design and operation of individual small-scale distributed generation (DG) units has received considerable attention. It is now plausible to envision a future scenario where a large number of such units, spanning capacities from the kW to the MW scale, are deployed in a region. As distributed electricity generation using natural gas becomes more widespread, the dependency of the electric grid on the natural gas grid will increase. This concerns multiple interaction points along the two networks, and reaches beyond the natural gas demand of large-scale load following or baseload gas-fired powerplants. More specifically, a better understanding is required of the potential changes in the dynamic behavior and interaction of the electricity and natural gas grids at or close to residential use sites (neighborhoods), where the small-scale DG infrastructure is likely to be located. In this paper, an optimization-based framework is developed for analyzing the operation of an ensemble of small-scale natural gas fueled DG units, and quantify their ability to flatten the electric grid load (i.e., reduce the peak demand) of the neighborhood that they serve. Our analysis relies on realistic energy use data and takes into account capacity limitations of the current natural gas distribution infrastructure, centralized vs. decentralized control of the DG unit operation, equipment durability considerations, heating preferences of home users, and seasonal effects. There is a substantial increase in natural gas consumption near consumers for all scenarios considered, which has implications for the control of the natural gas grid. We demonstrate the importance of having a centralized decision-making scheme when multiple distributed generation resources are present, and make recommendations for the optimal sizing of generators.
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ISSN:0306-2619
1872-9118
DOI:10.1016/j.apenergy.2016.05.098