A comprehensive state‐of‐the‐art survey on power generation expansion planning with intermittent renewable energy source and energy storage

Babatunde, Olubayo Moses; Munda, Josiah L.; Hamam, Yskandar

doi:10.1002/er.4388

Cited by 103 publications

(65 citation statements)

References 233 publications

(616 reference statements)

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“…Constraints are applied on the DG allocation problem to exert restrictions over the optimisation of the objective function(s) in respect of some decision variables. The most common constraints used in the optimal REHDG allocation problem formulations are grouped into seven . These are (i)Technical constraints: These are the technical constraints: •The set of power balance equality constraints placed on real and reactive power at each bus of the network (Kirchoff's current law). •The set of inequality constraints such as transformer or line overloading or capacity limits, transmission supply limits, limited buses for DG installation, etc. (ii)System reliability constraints: They ensure continuous and constant transmission and supply of power to the end users.…”

Section: Formulation Of Rehdg Allocation Planning Problemmentioning

confidence: 99%

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Towards maximising the integration of renewable energy hybrid distributed generations for small signal stability enhancement: A review

2020

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Summary Integrating renewable energy hybrid distributed generation (REHDG) into distribution network systems (DNSs) has become increasingly important because of various technical, economic, and environmental advantages accruing from it. However, the output power of REHDGs from photovoltaic (PV) and wind is highly variable because of its dependency on intermittent parameters such as solar irradiance, temperature, and wind speed. Such variability of generated power from large‐scale REHDGs or load introduces small signal instabilities (oscillations). Meanwhile, different locations of integration and sizes of REHDGs in the DNS affect the system oscillation modes by either improving or depriving the small‐signal stability (SSS) of the network. Consequently, a significant number of research has been conducted on the planning of optimal allocation of REHDGs in DNS. In this regard, this paper reviews the existing planning models, optimisation techniques, and resources' uncertainty modelling employed in REHDGs allocations in terms of their capability in obtaining optimal solutions and enhancing SSS of the system. Planning models with optimisation algorithms are evaluated for modelling renewable resource uncertainties and curtailing SSS variables. Research works on planning of optimal allocation of these generations attain minimum cost, but were unable to satisfy the SSS requirements of the system. The existing models for the planning and design of optimal timing, sizing, and placement of REHDGs will need to be improved to optimally allocate REHDGs and satisfy the SSS of the DNS after the integration.

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Section: Formulation Of Rehdg Allocation Planning Problemmentioning

confidence: 99%

“…The most common constraints used in the optimal REHDG allocation problem formulations are grouped into seven. 4,[7][8][9][10]13,[35][36][37]42 These are (i) Technical constraints: These are the technical constraints:…”

Section: Constraintsmentioning

confidence: 99%

Towards maximising the integration of renewable energy hybrid distributed generations for small signal stability enhancement: A review

2020

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“…In the following, we present the suggested exploration approach in the framework of capacity expansion problems (CEP), but the approach is applicable to any problem considering investment decisions. The CEP categorization covers several problems such as the generation expansion (GEP), demand forecasting, distribution expansion planning, and transmission expansion planning [2]. All problems have the common goal of finding the optimal design of the considered part of the energy system, wherefore also combined models frequently are seen.…”

Section: Maximized Diversity Solutionsmentioning

confidence: 99%

Finding a Portfolio of Near-Optimal Aggregated Solutions to Capacity Expansion Energy System Models

Buchholz

Gamst

Pisinger

2020

SN Oper. Res. Forum

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Energy system models are frequently being influenced by simplifications, assumption errors, uncertainties, incompleteness, and soft constraints which are challenging to model in a good way. In capacity expansion modeling, also the long time horizon and the high shares of renewable energies feed into the uncertainties. Consequently, a single optimal solution might not provide enough information to stand alone. Contrarily, a portfolio of different solutions, all being within an acceptance span of the system costs, would create more valuable decision support tool. This idea is known from the literature where a near-optimal solution space typically is explored by introducing integer cuts that iteratively cut off solutions as they are found. Generalizing this idea, we suggest an approach that explores the near-optimal solution space by iteratively finding new solutions which are as different as possible from earlier solutions with respect to investment decisions. Our method deviates from the literature since it maximizes the difference of the found solutions rather than finding k similar solutions. An advantage of this approach is that the resulting portfolio holds high diversity which creates a better basis for good decision-making. Moreover, it overcomes a potential struggle of getting symmetric solutions and it strengthens the robustness arguments of the different investment decisions. Furthermore, we suggest to search for alternative solutions in an aggregated solution space whereas the original solution space typically has been used for the search in previous work. We hereby exploit the speedup achieved through aggregation to find more solutions, and we observe that these solutions might indicate must have investments of the non-aggregated problem. The suggested approach is tested on a case study for three different limitations on the system costs. Results show that our approach by far outperforms the approach known from the literature when the neighborhood size exceeds 0.7%. Furthermore, using our approach, a portfolio of eight solutions with

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“…The capacity planning problem in the power systems has been divided into demand forecasting, distribution expansion planning, transmission expansion planning, and generation expansion planning (GEP). For each capacity planning problem, the time horizon can be divided into long-term, mediumterm, or short-term studies [11]. Short-term planning is associated with day-to-day system operation.…”

Section: Generation Expansion Planningmentioning

confidence: 99%

Modelling energy systems of Vietnam with integration of renewable power sources

Edelev¹,

Karamov²,

Sidorov³

et al. 2019

The International Workshop on Information, Computation, and Control Systems for Distributed Environments 2019

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The paper addresses the research of the large-scale penetration of renewable energy into the power system of Vietnam. The proposed approach presents the optimization of operational decisions in different power generation technologies as a Markov decision process. It uses a stochastic base model that optimizes a deterministic lookahead model. The first model applies the stochastic search to optimize the operation of power sources. The second model captures hourly variations of renewable energy over a year. The approach helps to find the optimal generation configuration under different market conditions.

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A comprehensive state‐of‐the‐art survey on power generation expansion planning with intermittent renewable energy source and energy storage

Cited by 103 publications

References 233 publications

Towards maximising the integration of renewable energy hybrid distributed generations for small signal stability enhancement: A review

Towards maximising the integration of renewable energy hybrid distributed generations for small signal stability enhancement: A review

Finding a Portfolio of Near-Optimal Aggregated Solutions to Capacity Expansion Energy System Models

Modelling energy systems of Vietnam with integration of renewable power sources

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