A stochastic mixed-integer convex programming model for long-term distribution system expansion planning considering greenhouse gas emission mitigation

Tutkimustuotos: Lehtiartikkeli

Standard

A stochastic mixed-integer convex programming model for long-term distribution system expansion planning considering greenhouse gas emission mitigation. / Home-Ortiz, Juan M.; Melgar-Dominguez, Ozy D.; Pourakbari-Kasmaei, Mahdi; Mantovani, José Roberto Sanches.

julkaisussa: International Journal of Electrical Power and Energy Systems, Vuosikerta 108, 01.06.2019, s. 86-95.

Tutkimustuotos: Lehtiartikkeli

Harvard

APA

Vancouver

Author

Bibtex - Lataa

@article{b5fb1ce42acb41698b2a927e1a5d2955,
title = "A stochastic mixed-integer convex programming model for long-term distribution system expansion planning considering greenhouse gas emission mitigation",
abstract = "This paper proposes a multistage convex distribution system planning model to find the best reinforcement plan over a specified horizon. This strategy determines planning actions such as reinforcement of existing substations, conductor replacement of overloaded feeders, and siting and sizing of renewable and dispatchable distributed generation units. Besides, the proposed approach aims at mitigating the greenhouse gas emissions of electric power distribution systems via a monetary form. Inherently, this problem is a non-convex optimization model that can be an obstacle to finding the optimal global solution. To remedy this issue, convex envelopes are used to recast the original problem into a mixed integer conic programming (MICP) model. The MICP model guarantees convergence to optimal global solution by using existing commercial solvers. Moreover, to address the prediction errors in wind output power and electricity demands, a two-stage stochastic MICP model is developed. To validate the proposed model, detail analysis is carried out over various case studies of a 34-node distribution system under different conditions, while to show its potential and effectiveness a 135-node system with two substations is used. Numerical results confirm the effectiveness of the proposed planning scheme in obtaining an economic investment plan at the presence of several planning alternatives and to promote an environmentally committed electric power distribution network.",
keywords = "Conic programming, Distributed energy, Multistage distribution system expansion planning, Renewable energy sources, Stochastic programming",
author = "Home-Ortiz, {Juan M.} and Melgar-Dominguez, {Ozy D.} and Mahdi Pourakbari-Kasmaei and Mantovani, {Jos{\'e} Roberto Sanches}",
year = "2019",
month = "6",
day = "1",
doi = "10.1016/j.ijepes.2018.12.042",
language = "English",
volume = "108",
pages = "86--95",
journal = "International Journal of Electrical Power and Energy Systems",
issn = "0142-0615",
publisher = "Elsevier Limited",

}

RIS - Lataa

TY - JOUR

T1 - A stochastic mixed-integer convex programming model for long-term distribution system expansion planning considering greenhouse gas emission mitigation

AU - Home-Ortiz, Juan M.

AU - Melgar-Dominguez, Ozy D.

AU - Pourakbari-Kasmaei, Mahdi

AU - Mantovani, José Roberto Sanches

PY - 2019/6/1

Y1 - 2019/6/1

N2 - This paper proposes a multistage convex distribution system planning model to find the best reinforcement plan over a specified horizon. This strategy determines planning actions such as reinforcement of existing substations, conductor replacement of overloaded feeders, and siting and sizing of renewable and dispatchable distributed generation units. Besides, the proposed approach aims at mitigating the greenhouse gas emissions of electric power distribution systems via a monetary form. Inherently, this problem is a non-convex optimization model that can be an obstacle to finding the optimal global solution. To remedy this issue, convex envelopes are used to recast the original problem into a mixed integer conic programming (MICP) model. The MICP model guarantees convergence to optimal global solution by using existing commercial solvers. Moreover, to address the prediction errors in wind output power and electricity demands, a two-stage stochastic MICP model is developed. To validate the proposed model, detail analysis is carried out over various case studies of a 34-node distribution system under different conditions, while to show its potential and effectiveness a 135-node system with two substations is used. Numerical results confirm the effectiveness of the proposed planning scheme in obtaining an economic investment plan at the presence of several planning alternatives and to promote an environmentally committed electric power distribution network.

AB - This paper proposes a multistage convex distribution system planning model to find the best reinforcement plan over a specified horizon. This strategy determines planning actions such as reinforcement of existing substations, conductor replacement of overloaded feeders, and siting and sizing of renewable and dispatchable distributed generation units. Besides, the proposed approach aims at mitigating the greenhouse gas emissions of electric power distribution systems via a monetary form. Inherently, this problem is a non-convex optimization model that can be an obstacle to finding the optimal global solution. To remedy this issue, convex envelopes are used to recast the original problem into a mixed integer conic programming (MICP) model. The MICP model guarantees convergence to optimal global solution by using existing commercial solvers. Moreover, to address the prediction errors in wind output power and electricity demands, a two-stage stochastic MICP model is developed. To validate the proposed model, detail analysis is carried out over various case studies of a 34-node distribution system under different conditions, while to show its potential and effectiveness a 135-node system with two substations is used. Numerical results confirm the effectiveness of the proposed planning scheme in obtaining an economic investment plan at the presence of several planning alternatives and to promote an environmentally committed electric power distribution network.

KW - Conic programming

KW - Distributed energy

KW - Multistage distribution system expansion planning

KW - Renewable energy sources

KW - Stochastic programming

UR - http://www.scopus.com/inward/record.url?scp=85059578096&partnerID=8YFLogxK

U2 - 10.1016/j.ijepes.2018.12.042

DO - 10.1016/j.ijepes.2018.12.042

M3 - Article

VL - 108

SP - 86

EP - 95

JO - International Journal of Electrical Power and Energy Systems

JF - International Journal of Electrical Power and Energy Systems

SN - 0142-0615

ER -

ID: 31553276