Hydro-Thermal-Transmission Extended Network (HTTEN)

Network Model of Short-Term Optimal Hydrothermal Power Flow with Security Constraints

Publication TypeProceedings Article
Year of Publication1995
AuthorsChiva, A.; Heredia, F.J.; Nabona, N.
Conference NameIEEE '95 Stockholm Power Tech
Series TitleInternational Symposium on Electric Power Engineering
Volume6, PS
Pagination67-73
Conference Start Date18/06/1995
PublisherRoyal Institute of Technology and IEEE Power Engineering Society
Conference LocationStockholm, Sweden
Key Wordsresearch; nonlinear network flows; side constraints; power systems; short-term hydrothermal OPF; spinning reserve; transmission security contraints; paper
URLClick Here
DOIhttp://hdl.handle.net/2117/14936
ExportTagged XML BibTex

Network Model of Short-Term Optimal Hydrothermal Power Flow with Security Constraints

Publication TypeConference Paper
Year of Publication1995
AuthorsChiva, A.; Heredia, F.J.; Nabona, N.
Conference NameIEEE '95 Stockholm Power Tech
Series TitleInternational Symposium on Electric Power Engineering
Volume6, PS
Pagination67-73
Conference Date18-22/06/1995
PublisherRoyal Institute of Technology and IEEE Power Engineering Society
Conference LocationStockholm, Sweden
Type of WorkContributed oral presentation
Key Wordsresearch; nonlinear network flows; side constraints; power systems; short-term hydrothermal OPF; spinning reserve; transmission security contraints; research
URLClick Here
ExportTagged XML BibTex

Optimum Short-Term Hydrothermal Schedulling with Spinning Reserve through Network Flows

Publication TypeJournal Article
Year of Publication1995
AuthorsHeredia, F. J.; Nabona, N.
Journal TitleIEEE Trans. on Power Systems
Volume10
Issue3
Pages10
Start Page1642
PublisherThe Institue of Electrical and Electronic Engineering
ISSN Number0885-8950
Key Wordsnonlinear network flows; side constraints; power systems; short-term hydrothermal OPF; spinning reserve; research; paper
AbstractOptimizing the thermal production of electricity in the short term in an integrated power system when a thermal unit commitment has been decided means coordinating hydro and thermal generation in order to obtain the minimum thermal generation costs over the time period under study. Fundamental constraints to be satisfied are the covering of each hourly load and satisfaction of spinning reserve requirements and transmission capacity limits. A nonlinear network flow model with linear side constraints with no decomposition into hydro and thermal subproblems was used to solve the hydrothermal scheduling. Hydrogeneration is linearized with respect to network variables and a novel thermal generation and transmission network is introduced. Computational results are reported
URLClick Here
DOIhttp://dx.doi.org/10.1109/59.466476
ExportTagged XML BibTex
Syndicate content