Showing total 10 results

1. Deep Learning Based Distributionally Robust Joint Chance Constrained Economic Dispatch Under Wind Power Uncertainty.

Author

Ning, Chao and You, Fengqi

Subjects

*DEEP learning, *WIND power, *GENERATIVE adversarial networks, *RENEWABLE energy sources, *ENERGY consumption, *CONSTRAINED optimization, *DISTRIBUTION (Probability theory)

Abstract

This paper proposes a holistic framework of data-driven distributionally robust joint chance constrained economic dispatch (ED) optimization, which seamlessly incorporates deep learning-based optimization for effective utilization of renewable energy in power systems. By leveraging a deep generative adversarial network (GAN), an f-divergence-based ambiguity set of wind power distributions is constructed as a ball centered around the probability distribution induced by a generator neural network. In particular, the GAN is well suited for capturing complicated spatial and temporal correlations of wind power. Based upon this ambiguity set, a distributionally robust joint chance constrained ED model is developed to hedge against distributional uncertainty present in multiple constraints, without assuming a perfectly known probability distribution. The proposed deep learning based ED optimization framework greatly mitigates the conservatism inflicting on distributionally robust individual chance constrained optimization. Theoretical a priori bound on the required number of synthetic wind power data generated by GAN is explicitly derived for the multi-period ED problem to guarantee a predefined risk level. The effectiveness and scalability of the proposed approach are demonstrated in the six-bus and IEEE 118-bus systems by comparing with the state-of-the-art methods. [ABSTRACT FROM AUTHOR]

Published

2022

2. Cost-Efficient Strategy for High Renewable Energy Penetration in Isolated Power Systems.

Author

Semshchikov, Evgenii, Negnevitsky, Michael, Hamilton, James, and Wang, Xiaolin

Subjects

*RENEWABLE energy sources, *ENERGY consumption, *POWER resources, *COMBUSTION efficiency, *WIND power, *ELECTRIC power system reliability, *DIESEL fuels

Abstract

Remote areas and islands isolated from the main electric power system ensure reliability and stability of power supply using diesel generation. Due to the high purchase and transportation costs of diesel fuel, isolated communities are exploring other options for efficient and reliable power supply. Renewable energy sources can reduce operating costs, although are unable to achieve high penetration without expensive and complex enabling technologies such as energy storage. Furthermore, the stochastic and intermittent nature of renewable sources (i.e., wind and solar) makes the control system complex, decreasing power system reliability and requiring highly qualified personnel in local control centres. The problem becomes particularly acute when diesel engines are forced to operate at partial load, resulting in poor combustion efficiency and potential engine damage. This paper suggests a fuel-efficient control strategy, adopting low load diesel application to reduce fuel consumption and improve renewable energy penetration without overcomplicating the control architecture. A mathematical model is initially developed, then validated against real data, to facilitate comparative assessment of various control approaches. Optimised control methodologies are shown to deliver fuel savings of 16.7%, with a 14% increase in renewable energy penetration, in comparison to conventional management. [ABSTRACT FROM AUTHOR]

Published

2020

3. Optimal Scheduling of Biogas–Solar–Wind Renewable Portfolio for Multicarrier Energy Supplies.

Author

Zhou, Bin, Xu, Da, Li, Canbing, Chung, Chi Yung, Cao, Yijia, Chan, Ka Wing, and Wu, Qiuwei

Subjects

*RENEWABLE energy sources, *BIOGAS, *SOLAR energy, *WIND power, *ENERGY conversion, *ENERGY consumption

Abstract

This paper proposes a multisource multiproduct framework for coupled multicarrier energy supplies with a biogas–solar–wind hybrid renewable system. In this framework, the biogas–solar–wind complementarities are fully exploited based on digesting thermodynamic effects for the synergetic interactions of electricity, gas, and heating energy flows, and a coupling matrix is formulated for the modeling of production, conversion, storage, and consumption of different energy carriers. The multienergy complementarity of biogas–solar–wind renewable portfolio can be utilized to facilitate the mitigation of renewable intermittency and the efficient utilization of batteries, and a multicarrier generation scheduling scheme is further presented to dynamically optimize dispatch factors in the coupling matrix for energy-efficient conversion and storage, while different energy demands of end-users are satisfied. The proposed methodology has been fully tested and benchmarked on a stand-alone Microgrid over a 24-h scheduling horizon. Comparative results demonstrate that the proposed scheme can lower the battery charging/discharging actions as well as the degradation cost, and also confirm its capability to accommodate high penetration of variable renewables. [ABSTRACT FROM AUTHOR]

Published

2018

4. A Base Station DTX Scheme for OFDMA Cellular Networks Powered by the Smart Grid

Author

Qiang Wang, Tiejun Chen, and Feng Zhao

Subjects

General Computer Science, Computer science, cellular networks, Distributed computing, resource allocation, 02 engineering and technology, Base station, 0203 mechanical engineering, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Resource management, distributed algorithm, Wind power, business.industry, General Engineering, 020206 networking & telecommunications, 020302 automobile design & engineering, Energy consumption, Solar energy, power control, Renewable energy, TK1-9971, Smart grid, Distributed algorithm, Greenhouse gas, Cellular network, Resource allocation, Electrical engineering. Electronics. Nuclear engineering, DTX, business, Efficient energy use

Abstract

Discontinuous transmission (DTX) is an efficient technology to improve the energy efficiency of the wireless cellular networks. DTX enables the deactivation of some components of the base station in sufficient short time, which can decrease the energy consumption without affecting the normal operation of the mobile networks. In addition, we consider distributed smart grid which can power the cellular networks using renewable and conventional energy. The distributed smart grid has many different energy retailers with variant energy resource, such as solar energy, wind energy, and conventional energy. Comparing with conventional energy, the renewable energy is more environmental friendly, but more expensive. As a result, it is necessary to obtain a good tradeoff between the operation cost and greenhouse gas (GHG) emission. In this paper, we jointly optimize the DTX, resource allocation, and smart grid energy procurement to maximize the profit of the network operators and minimize the GHG emission. We formulate the joint optimization problem as a mixed integer programming problem. By exploiting the structure of the coupled constraint of the problem, we propose a suboptimal distributed algorithm based on the Lagrangian dual method, and the algorithm can be performed at cellular network and smart grid alternately, which can significantly decrease the signaling and computational overhead. Simulation results illustrate that the proposed DTX scheme can significantly enhance the energy saving, and further improve the energy efficiency of the cellular networks.

Published

2018

5. Economic optimization for configuration and sizing of micro integrated energy systems

Author

Chen Jia, Haibo Yu, Bian Haifeng, Zhang Chao, Chenjun Sun, and Deng Zuqiang

Subjects

Mathematical optimization, Engineering, TK1001-1841, 020209 energy, Energy balance, Energy Engineering and Power Technology, Mechanical engineering, TJ807-830, 02 engineering and technology, Economic optimization, Renewable energy sources, Production of electric energy or power. Powerplants. Central stations, 020401 chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, 0204 chemical engineering, Wind power, Renewable Energy, Sustainability and the Environment, business.industry, Pareto principle, Energy consumption, Prime mover, Uncertainties, Non-dominated sorting genetic algorithm (NSGA-II), Renewable energy, Micro integrated energy system (MIES), Distributed generation, business, Thermal energy

Abstract

Based on analysis of construction and operation of micro integrated energy systems (MIES), this paper presents economic optimization for their configuration and sizing. After presenting typical models for MIES, a residential community MIES is developed by analyzing residential direct energy consumption within a general design procedure. Integrating with available current technologies and local resources, the systematic design considers a prime mover, fed by natural gas, with wind power, photovoltaic generation, and two storage devices serving thermal energy and power to satisfy cooling, heating and electricity demands. Control strategies for MIES also are presented in this study. Multi-objective formulas are obtained by analyzing annual cost and dumped renewable energy to achieve optimal coordination of energy supply and demand. According to historical load data and the probability distribution of distributed generation output, clustering methods based on K-means and discretization methods are employed to obtain typical scenarios representative of uncertainties. The modified non-dominated sorting genetic algorithm is applied to find the Pareto frontier of the constructed multi-objective formulas. In addition, aiming to explore the Pareto frontier, the dumped energy cost ratio is defined to check the energy balance in different MIES designs and provide decision support for the investors. Finally, simulations and comparision show the appropriateness of the developed model and the applicability of the adopted optimization algorithm.

Published

2017

6. A Distributed Model Predictive Control approach for the integration of flexible loads, storage and renewables

Author

Giancarlo Mantovani, Giuseppe Tommaso Costanzo, and Luca Ferrarini

Subjects

Engineering, Wind power, business.industry, Renewable Energy Integration, Control engineering, Energy consumption, Smart Grids, Energy storage, Reliability engineering, Renewable energy, Model predictive control, Smart grid, Smart Buildings, SDG 7 - Affordable and Clean Energy, business, Heuristics, Model Predictive Control, Building automation

Abstract

This paper presents an innovative solution based on distributed model predictive controllers to integrate the control and management of energy consumption, energy storage, PV and wind generation at customer side. The overall goal is to enable an advanced prosumer to auto-produce part of the energy he needs with renewable sources and, at the same time, to optimally exploit the thermal and electrical storages, to trade off its comfort requirements with different pricing schemes (including real-time pricing), and apply optimal control techniques rather than sub-optimal heuristics.

Published

2014

7. Design and evaluation of an architecture for future smart grid service provisioning

Author

Matthias Strobbe, Tom Verschueren, Filip De Turck, Chris Develder, Thierry Pollet, Kevin Mets, Stijn Van de Veire, Stijn Melis, De Turck, Filip, Paschoal Gaspary, Luciano, and Medhi, Deep

Subjects

Technology and Engineering, Wind power, business.industry, Computer science, Energy management, Distributed computing, Software as a service, SPLE, Energy consumption, Renewable energy, SaaS, Smart grid, Design methodology, Clouds, Distributed generation, Embedded system, IBCN, business, Efficient energy use

Abstract

In recent years, there has been a growing interest in cloud technologies. Using current cloud solutions, it is however difficult to create customizable multi-tenant applications, especially if the application must support varying Quality of Service (QoS) guarantees. Software Product Line Engineering (SPLE) and feature modeling techniques are commonly used to address these issues in non-cloud applications, but these techniques cannot be ported directly to a cloud context, as the common approaches are geared towards customization of on-premise deployed applications, and do not support multi-tenancy. In this paper, we propose an architecture for the development and management of customizable Software as a Service (SaaS) applications, built using SPLE techniques. In our approach, each application is a composition of services, where individual services correspond to specific application functionalities, referred to as features. A feature-based methodology is described to abstract and convert the application information required at different stages of the application life-cycle: development, customization and deployment. We specifically focus on how development feature models can be adapted ensuring a one-to-one correspondence between features and services exists, ensuring the composition of services yields an application containing the corresponding features. These runtime features can then be managed using feature placement techniques. The proposed approach enables developers to define significantly less features, while limiting the amount of automatically generated features in the application runtime stage. Conversion times between models are shown to be in the order of milliseconds, while execution times of management algorithms are shown to improve by 5 to 17% depending on the application case.

Published

2012

8. Wind/solar hybrid generation-based roadway microgrids

Author

Wei Qiao, Laurence R. Rilett, Jerry L. Hudgins, Elizabeth G. Jones, and Anuj Sharma

Subjects

Engineering, Wind power, Smart grid, business.industry, Power electronics, Electrical engineering, Energy consumption, Electric power, Microgrid, business, Grid, Automotive engineering, Renewable energy

Abstract

This paper presents the concept and design of a novel roadway microgrid. It operates as a smart microgrid that optimally utilizes the public right-of-way and roadway infrastructure to provide cost-effective, highly efficient, and reliable wind/solar electric power production, distribution, storage, and utilization. The fundamental unit of the microgrid is called the energy-plus roadway/traffic signal light (EPRTL), which contains a grid-connected wind/solar hybrid generation system installed on the pole of a roadway/traffic signal light for clean electric power production. The term “energy-plus” stands for annual energy consumption that is less than production. The generated electric power will be consumed locally by the roadway/traffic signal light; the excess power generated will be stored in batteries, optimally distributed in the microgrid, and supplied to the utility main grid. The deployment of the proposed roadway microgrid will dramatically change the role of the public right-of-way from an energy consumer to an energy producer, leading to energy-plus roadways. This will not only reduce the roadway agency operating costs but also generate new revenues for the Highway Trust Fund. The use of renewable electric power will also promote the development of green roadways.

Published

2011

9. Power electronics for renewable energy systems

Author

Frede Blaabjerg and Florin Iov

Subjects

Pumped-storage hydroelectricity, Energy conservation, Engineering, Wind power, Energy development, business.industry, Distributed generation, Intermittent energy source, Electrical engineering, Energy consumption, Environmental economics, business, Renewable energy

Abstract

The global electrical energy consumption is still rising and there is a demand to double the power capacity within 20 years. The production, distribution and use of energy should be as technological efficient as possible and incentives to save energy at the end-user should also be set up. Deregulation of energy has in the past lowered the investment in larger power plants, which means the need for new electrical power sources may be very high in the near future. Two major technologies will play important roles to solve the future problems. One is to change the electrical power production sources from the conventional, fossil (and short term) based energy sources to renewable energy resources. Another is to use high efficient power electronics in power generation, power transmission/distribution and end-user application. This paper discuss some of the most emerging renewable energy sources, wind energy and photovoltaics, which by means of power electronics are changing from being minor energy sources to be acting as important power sources in the energy system.

Published

2009

10. Assessment of the Romanian pilot site energy consumption indicators and technical prerequisites in the implementation of the RE-COGNITION Horizon project

Author

Timea Farkas, Levente Czumbil, Mihaela Cretu, Denisa Stet, Alexis Polycarpou, Laura Darabant, Dan D. Micu, and Andrei Ceclan

Subjects

Wind power, Risk analysis (engineering), renewable energy sources, thermal and electrical energy consumption, greenhouse gas emissions, Computer science, business.industry, Information and Communications Technology, Frame (networking), Integration platform, Context (language use), Energy consumption, business, Renewable energy, Efficient energy use

Abstract

The main ambition of the RE-COGNITION Horizon 2020 project (https://re-cognition-project.eu/), in which Technical University of Cluj-Napoca is involved, is to develop a future and technology-proof integration solution aiming to maximize the utilization of the energy that is locally produced by building-level Renewable Energy Sources (RES) technologies, and the reduction of implicit and explicitly induced costs. In the frame of the project, a RES Integration Platform is developed, which incorporate existing, as well as newly developed RES and storage components, along with peripheral electrical and thermal load equipment (HVACs, chillers, ICT devices, conventional load equipment etc.). The RES Integration Platform aims to optimize the building energy flows, regardless of type and conditions. Several pilots with different building environments and climate zones, all around Europe, will be selected to test the RE-COGNITION framework components. This will sufficiently fulfil the validation purposes of the developed technologies and comply with the end-user needs. In this paper, we present the general description of the Romanian pilot site, as well as the energy consumption indicators measured in the last 3 years prior to the project’s start. An analysis of the local context which provides the technical/socio/economic constraints that the project should handle is also presented.