Power System Planning Sullivan Ebook 11
Power System Planning by Robert Sullivan: A Review
Power system planning is the process of designing and developing electric power systems to meet the demand and reliability requirements of customers and society. It involves various aspects such as generation, transmission, distribution, load forecasting, reliability analysis, maintenance scheduling, economic evaluation, and environmental impact assessment. Power system planning is a complex and challenging task that requires a comprehensive understanding of the technical, economic, and social factors that affect the performance and operation of power systems.
One of the classic textbooks on power system planning is Power System Planning by Robert Sullivan, published in 1977. This book provides a systematic and rigorous treatment of the fundamental concepts and methods of power system planning, with an emphasis on reliability and optimization techniques. The book covers the following topics:
power system planning sullivan ebook 11
Power system reliability calculation: This chapter introduces the basic concepts and definitions of power system reliability, such as outage probability, loss of load probability, loss of energy expectation, frequency and duration method, and reliability indices. It also presents the methods of calculating the reliability of generation systems and transmission networks using convolution, deconvolution, cumulants, and state enumeration techniques.
Power system probabilistic production simulation: This chapter discusses the simulation techniques for analyzing the operation and performance of power systems under random load and generation variations. It describes the Monte Carlo method, the fast Fourier transform method, and the convolution method for simulating the load duration curve, the load frequency control, and the economic dispatch of power systems.
Maintenance scheduling of generating units in a power system: This chapter addresses the problem of scheduling the preventive maintenance of generating units in a power system to minimize the expected cost of operation and maintenance. It formulates the problem as a mixed-integer programming problem and proposes a branch-and-bound algorithm for solving it.
Generation system planning: This chapter deals with the problem of determining the optimal expansion plan for a generation system to meet the future load demand at minimum cost. It considers various factors such as load growth rate, fuel cost, capital cost, operating cost, discount rate, reserve margin, reliability criterion, and environmental constraint. It presents several methods for solving the generation expansion planning problem, such as dynamic programming, integer programming, linear programming relaxation, decomposition-coordination method, and heuristic method.
Transmission network planning: This chapter focuses on the problem of designing and expanding a transmission network to deliver the power from generation sources to load centers at minimum cost. It takes into account various factors such as transmission line capacity, voltage level, power flow limit, loss factor, investment cost, operating cost, reliability criterion, and security constraint. It introduces several methods for solving the transmission network planning problem, such as linear programming, nonlinear programming, mixed-integer programming, branch-and-bound method, sensitivity analysis method, and heuristic method.
Forecasting techniques and applications: This chapter reviews the basic concepts and methods of forecasting techniques for power system planning. It covers various types of forecasting models such as trend analysis models, regression models, time series models, econometric models, input-output models, scenario analysis models, and expert judgment models. It also discusses the applications of forecasting techniques for load forecasting, fuel price forecasting, electricity price forecasting, and demand-side management.
The book is well-written and well-organized. It provides clear explanations and derivations of the mathematical formulations and algorithms for power system planning problems. It also includes numerous examples, case studies, tables, figures, and exercises to illustrate and reinforce the concepts and methods presented in each chapter. The book is suitable for undergraduate and graduate students who want to learn about power system planning as well as for practicing engineers who want to update their knowledge and skills in this field.
The book is also available as an ebook in PDF format. The ebook version has 324 pages and can be downloaded for free from Archive.org. The ebook version is identical to the original print version except for some minor formatting differences. The ebook version is convenient for readers who prefer to read on their electronic devices or who have difficulty accessing the print version.
In conclusion, Power System Planning by Robert Sullivan is a comprehensive and authoritative textbook on power system planning that covers both theory and practice. It is a valuable resource for students and engineers who want to learn about or improve their skills in power system planning.