A Novel Hybrid Framework for Co-Optimization of Power and Natural Gas Networks Integrated With Emerging Technologies
In a power system with high penetration of renewable power sources, gas-fired units can be considered as a back-up option to improve the balance between generation and consumption in short-term scheduling. Therefore, closer coordination between power and natural gas systems is anticipated. This arti...
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| Veröffentlicht in: | IEEE systems journal 2020-09, Vol.14 (3), p.3598-3608 |
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| creator | Mirzaei, Mohammad Amin Nazari-Heris, Morteza Mohammadi-Ivatloo, Behnam Zare, Kazem Marzband, Mousa Anvari-Moghaddam, Amjad |
| description | In a power system with high penetration of renewable power sources, gas-fired units can be considered as a back-up option to improve the balance between generation and consumption in short-term scheduling. Therefore, closer coordination between power and natural gas systems is anticipated. This article presents a novel hybrid information gap decision theory (IGDT)-stochastic cooptimization problem for integrating electricity and natural gas networks to minimize total operation cost with the penetration of wind energy. The proposed model considers not only the uncertainties regarding electrical load demand and wind power output, but also the uncertainties of gas load demands for the residential consumers. The uncertainties of electric load and wind power are handled through a scenario-based approach, and residential gas load uncertainty is handled via IGDT approach with no need for the probability density function. The introduced hybrid model enables the system operator to consider the advantages of both approaches simultaneously. The impact of gas load uncertainty associated with the residential consumers is more significant on the power dispatch of gas-fired plants and power system operation cost since residential gas load demands are prior than gas load demands of gas-fired units. The proposed framework is a bilevel problem that can be reduced to a one-level problem. Also, it can be solved by the implementation of a simple concept without the need for Karush-Kuhn-Tucker conditions. Moreover, emerging flexible energy sources such as the power to gas technology and demand response program are considered in the proposed model for increasing the wind power dispatch, decreasing the total operation cost of the integrated network as well as reducing the effect of system uncertainties on the total operating cost. Numerical results indicate the applicability and effectiveness of the proposed model under different working conditions. |
| doi_str_mv | 10.1109/JSYST.2020.2975090 |
| format | Article |
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Therefore, closer coordination between power and natural gas systems is anticipated. This article presents a novel hybrid information gap decision theory (IGDT)-stochastic cooptimization problem for integrating electricity and natural gas networks to minimize total operation cost with the penetration of wind energy. The proposed model considers not only the uncertainties regarding electrical load demand and wind power output, but also the uncertainties of gas load demands for the residential consumers. The uncertainties of electric load and wind power are handled through a scenario-based approach, and residential gas load uncertainty is handled via IGDT approach with no need for the probability density function. The introduced hybrid model enables the system operator to consider the advantages of both approaches simultaneously. The impact of gas load uncertainty associated with the residential consumers is more significant on the power dispatch of gas-fired plants and power system operation cost since residential gas load demands are prior than gas load demands of gas-fired units. The proposed framework is a bilevel problem that can be reduced to a one-level problem. Also, it can be solved by the implementation of a simple concept without the need for Karush-Kuhn-Tucker conditions. Moreover, emerging flexible energy sources such as the power to gas technology and demand response program are considered in the proposed model for increasing the wind power dispatch, decreasing the total operation cost of the integrated network as well as reducing the effect of system uncertainties on the total operating cost. Numerical results indicate the applicability and effectiveness of the proposed model under different working conditions.</description><identifier>ISSN: 1932-8184</identifier><identifier>EISSN: 1937-9234</identifier><identifier>DOI: 10.1109/JSYST.2020.2975090</identifier><identifier>CODEN: ISJEB2</identifier><language>eng</language><publisher>New York: IEEE</publisher><subject>Alternative energy sources ; Co-optimization of integrated gas and power system ; Consumers ; Decision theory ; demand response (DR) program ; Electric power systems ; Electrical loads ; Energy conservation ; Energy management ; hybrid information gap decision theory (IGDT)-stochastic ; Hybrid power systems ; Hybrid systems ; Kuhn-Tucker method ; Load modeling ; Natural gas ; New technology ; Operating costs ; Optimization ; Penetration ; Power consumption ; Power dispatch ; Power sources ; power-to-gas (P2G) technology ; Probability density functions ; Renewable energy sources ; Uncertainty ; Wind power ; Wind power generation</subject><ispartof>IEEE systems journal, 2020-09, Vol.14 (3), p.3598-3608</ispartof><rights>Copyright The Institute of Electrical and Electronics Engineers, Inc. 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Therefore, closer coordination between power and natural gas systems is anticipated. This article presents a novel hybrid information gap decision theory (IGDT)-stochastic cooptimization problem for integrating electricity and natural gas networks to minimize total operation cost with the penetration of wind energy. The proposed model considers not only the uncertainties regarding electrical load demand and wind power output, but also the uncertainties of gas load demands for the residential consumers. The uncertainties of electric load and wind power are handled through a scenario-based approach, and residential gas load uncertainty is handled via IGDT approach with no need for the probability density function. The introduced hybrid model enables the system operator to consider the advantages of both approaches simultaneously. The impact of gas load uncertainty associated with the residential consumers is more significant on the power dispatch of gas-fired plants and power system operation cost since residential gas load demands are prior than gas load demands of gas-fired units. The proposed framework is a bilevel problem that can be reduced to a one-level problem. Also, it can be solved by the implementation of a simple concept without the need for Karush-Kuhn-Tucker conditions. Moreover, emerging flexible energy sources such as the power to gas technology and demand response program are considered in the proposed model for increasing the wind power dispatch, decreasing the total operation cost of the integrated network as well as reducing the effect of system uncertainties on the total operating cost. Numerical results indicate the applicability and effectiveness of the proposed model under different working conditions.</description><subject>Alternative energy sources</subject><subject>Co-optimization of integrated gas and power system</subject><subject>Consumers</subject><subject>Decision theory</subject><subject>demand response (DR) program</subject><subject>Electric power systems</subject><subject>Electrical loads</subject><subject>Energy conservation</subject><subject>Energy management</subject><subject>hybrid information gap decision theory (IGDT)-stochastic</subject><subject>Hybrid power systems</subject><subject>Hybrid systems</subject><subject>Kuhn-Tucker method</subject><subject>Load modeling</subject><subject>Natural gas</subject><subject>New technology</subject><subject>Operating costs</subject><subject>Optimization</subject><subject>Penetration</subject><subject>Power consumption</subject><subject>Power dispatch</subject><subject>Power sources</subject><subject>power-to-gas (P2G) technology</subject><subject>Probability density functions</subject><subject>Renewable energy sources</subject><subject>Uncertainty</subject><subject>Wind power</subject><subject>Wind power generation</subject><issn>1932-8184</issn><issn>1937-9234</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2020</creationdate><recordtype>article</recordtype><sourceid>RIE</sourceid><recordid>eNo9kE1PwkAQhhujiYj-Ab1s4rm4H223eySEL0PABIzx1KztbFlsu7i7SPDXW8B4mjm8zzuZJwjuCe4RgsXT8_J9uepRTHGPCh5jgS-CDhGMh4Ky6PK00zAlaXQd3Di3wThOYy46ge-jufmGCk0OH1YXaGRlDXtjP5EyFg1MuNh6Xesf6bVpkFHoxezBItkUaC79zsoKjaVDc_BHyKFp46G00kOB3rRfo2ENttRNiVaQrxtTmVKDuw2ulKwc3P3NbvA6Gq4Gk3C2GE8H_VmYMyZ8qCIGKgeSQMJiHCnCkgJSlUcxoSJWkqr2YSELnKeQMpKIhBOZJJyThHJJOesGj-ferTVfO3A-25idbdqTGY2Y4JiJWLQpek7l1jhnQWVbq2tpDxnB2dFudrKbHe1mf3Zb6OEMaQD4BwSOGMeE_QLitHZt</recordid><startdate>202009</startdate><enddate>202009</enddate><creator>Mirzaei, Mohammad Amin</creator><creator>Nazari-Heris, Morteza</creator><creator>Mohammadi-Ivatloo, Behnam</creator><creator>Zare, Kazem</creator><creator>Marzband, Mousa</creator><creator>Anvari-Moghaddam, Amjad</creator><general>IEEE</general><general>The Institute of Electrical and Electronics Engineers, Inc. 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Therefore, closer coordination between power and natural gas systems is anticipated. This article presents a novel hybrid information gap decision theory (IGDT)-stochastic cooptimization problem for integrating electricity and natural gas networks to minimize total operation cost with the penetration of wind energy. The proposed model considers not only the uncertainties regarding electrical load demand and wind power output, but also the uncertainties of gas load demands for the residential consumers. The uncertainties of electric load and wind power are handled through a scenario-based approach, and residential gas load uncertainty is handled via IGDT approach with no need for the probability density function. The introduced hybrid model enables the system operator to consider the advantages of both approaches simultaneously. The impact of gas load uncertainty associated with the residential consumers is more significant on the power dispatch of gas-fired plants and power system operation cost since residential gas load demands are prior than gas load demands of gas-fired units. The proposed framework is a bilevel problem that can be reduced to a one-level problem. Also, it can be solved by the implementation of a simple concept without the need for Karush-Kuhn-Tucker conditions. Moreover, emerging flexible energy sources such as the power to gas technology and demand response program are considered in the proposed model for increasing the wind power dispatch, decreasing the total operation cost of the integrated network as well as reducing the effect of system uncertainties on the total operating cost. 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| subjects | Alternative energy sources Co-optimization of integrated gas and power system Consumers Decision theory demand response (DR) program Electric power systems Electrical loads Energy conservation Energy management hybrid information gap decision theory (IGDT)-stochastic Hybrid power systems Hybrid systems Kuhn-Tucker method Load modeling Natural gas New technology Operating costs Optimization Penetration Power consumption Power dispatch Power sources power-to-gas (P2G) technology Probability density functions Renewable energy sources Uncertainty Wind power Wind power generation |
| title | A Novel Hybrid Framework for Co-Optimization of Power and Natural Gas Networks Integrated With Emerging Technologies |
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