Showing total 2,756 results

201. Comprehensive review of power system oscillations in large-scale power electronic-based renewable energy power plants.

Author

Liu, Ni, Wang, Hong, Zhou, Dangsheng, Shi, Hexi, and Chen, Zhe

Subjects

RENEWABLE energy sources, OSCILLATIONS, HYBRID power systems, FREQUENCIES of oscillating systems, POWER electronics, POWER plants, DECOMPOSITION method, ALTERNATING currents

Abstract

Recently, the large-scale integration of power electronic-based renewable energy power plants has changed the operation and response mechanism of the power system, resulting in several emerging oscillation issues that have seriously been threatening the system's stability. It helps us to recognize the similarities and differences among the triggering causes and formation mechanisms of oscillation scenarios. Following several typical oscillation events in the real world and the timescale decomposition method, this paper comprehensively reviews the wide-bandwidth oscillation study from the aspects of the analysis methods, possible cause, mechanism, and mitigation solution. The paper provides a perspective to classify the oscillations in the modern power systems on the basis of the oscillation frequency and the main oscillation module. This classification framework involves not only emerging oscillations in the power system with large-scale renewable energy sources integration but also includes typical oscillations in traditional power systems. It also systematically presents the relative relationship, development process, and inner influence between emerging oscillations and typical oscillations. Based on this review, the future research is suggested to focus on the relationship between different analytical methods or oscillation mechanisms, as well as the stability risk assessment of hybrid alternating current and direct current power systems. [ABSTRACT FROM AUTHOR]

Published

2023

202. Merchant Energy Storage Investment Analysis Considering Multi-Energy Integration.

Author

Wang, Long

Subjects

ENERGY storage, INVESTMENT analysis, BATTERY storage plants, POWER plants, DISTRIBUTED power generation, POWER distribution networks, ENERGY development, MERCHANTS

Abstract

In this paper, a two-stage model of an integrated energy demand response is proposed, and the quantitative relationship between the two main concerns of investors, i.e., investment return and investment cycle and demand response, is verified by the experimental data. Energy storage technology is a key means through which to deal with the instability of modern energy sources. One of the key development paths in the electricity market is the development by energy merchants of energy storage power plants in the distribution network to engage in a grid demand response. This research proposes a two-stage energy storage configuration approach for a cold-heat-power multi-energy complementary multi-microgrid system. Considering the future bulk connections of distributed power generation, the two most critical points of energy storage station construction are the power generation equipment and specific scenarios for serving the community, as well as the purchase and sale price of electricity for serving the community microgrid (which directly affects the investment revenue). Therefore, this paper focuses on analyzing the different impacts caused by these two issues; namely, the two most important concerns for the construction of energy storage configurations. First, the basic model enabling wholesale electricity traders to construct energy storage power plants is presented. Second, for a multi-microgrid system with a complementary cold-heat-power multi-energy scenario, a two-stage optimum allocation model is constructed, whereby the upper model calculates the energy storage allocation problem and the lower model calculates the optimal dispatch problem. The lower model's dispatch computation validates the upper configuration model's reasonableness. Finally, the two-layer model is converted to a single-layer model by the KKT condition, and the nonlinear problem is converted to a linear problem with the big-M method. The validity is proved via mathematical examples, and it is demonstrated that the planned energy storage plants by merchants may accomplish resource savings and mutual advantages for both users and wholesale power traders. [ABSTRACT FROM AUTHOR]

Published

2023

203. Power system flexibility assessment for future flexibility needs: high-level screening method of the Macedonian power system.

Author

MALCHESKI, Stojan, KUZAREVSKI, Sime, VULETIC, Jovica, and ANGELOV, Jordanco

Subjects

MONTE Carlo method, RENEWABLE energy sources, ENERGY industries, POWER plants, ECOLOGICAL impact, COAL-fired power plants, PHASOR measurement

Abstract

Copyright of Przegląd Elektrotechniczny is the property of Przeglad Elektrotechniczny and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

204. Exergy Analysis of Thermal Power Plant for Three Different Loads.

Author

Ćehajić, Nurdin

Subjects

EXERGY, STEAM power plants, THERMAL analysis, POWER plants

Abstract

This paper presents the energy and exergy analysis of thermal power plant Tuzla in Tuzla, Bosnia and Herzegovina. The main aim of this paper is to analyze the components of a 200 MW steam power plant unit in order to identify and quantify the sites with the highest exergy losses and to calculate exergy efficiency values of all components when operating at nominal load. The influence of the change in ambient temperature and block load on the value of exergy losses and exergy efficiency was taken into analysis. The analysis further includes the impact of steam block operation without high-pressure and low-pressure heaters on the exergy efficiency of the steam block. The goal of the analysis is to determine the functional state of individual steam block components after a long period of exploitation and maintenance in order to take appropriate measures to improve their technical performance. Exergy losses during nominal operation of the steam power plant unit are the largest in boiler and amount to 313.42 MW, followed by a turbine with 205.60 MW, condenser 1 with 6.03 MW, condenser 2 with 5.75 MW, while other components of the steam power plant have exergy losses in the range of 0.03 to 2.15 MW. Operation of the unit at nominal load without HPH results in an exergy efficiency decrease from 5.60 to 9.80 %, while in case of operation without HPH and LPH it results in a decrease in exergy efficiency from 9.86 to 16.40 % depending on the pattern used to calculate. The conclusion after the analysis indicates that the biggest exergy losses are in the boiler and turbine and consequently these components have the lowest exergy efficiency values. The increase in ambient temperature has different effects on individual components of the thermal power plant, increasing exergy losses of the boiler while reducing the turbine exergy losses and condensers. [ABSTRACT FROM AUTHOR]

Published

2023

205. fipptec: Forum für Fachgespräche.

Subjects

WATER treatment plants, PILOT plants, MATHEMATICAL optimization, PAPER mills, POWER plants, DRAINAGE, CONSUMERS, TRADE shows

Abstract

Copyright of Wochenblatt für Papierfabrikation is the property of dfv Mediengruppe and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

206. A 'spatial‐temporal' bi‐layer optimal control strategy of large‐scale electric vehicles (EVs) in a multi‐area Virtual Power Plant (VPP) oriented to dual carbon target.

Author

Li, Jianfang, Peng, Daogang, Zhao, Huirong, Wang, Danhao, and Qi, Erjiang

Subjects

POWER resources, POWER plants, ELECTRIC vehicles, CARBON emissions, TRANSACTION costs, ELECTRIC power distribution grids

Abstract

Virtual power plant (VPP) is a comprehensive demand response (DR) technology to aggregate various power supply and consumption resources to help stabilise power grid fluctuations and reduce CO2 emissions. Fast‐charging electric vehicles (EVs) with higher charging power and shorter charging time are the most potential high‐quality DR resources of VPP in the future. In this paper, a new 'spatial‐temporal' bi‐layer optimal control strategy is proposed to solve the daily real‐time DR dispatching problem of large‐scale EVs including fast‐charging ones in a multi‐area VPP oriented to China's dual carbon target. This proposed bi‐layer strategy has two main contributions in both spatial and temporal domains. One is that, compared with the limited geographical area in traditional VPP, the upper layer of the proposed strategy considers the DR problem of EVs in a VPP with multiple geographical areas and establishes a spatial optimisation model of EVs DR considering both energy and carbon transaction costs of the overall VPP. The other is that rather than traditional slow‐charging EVs DR control with 1‐h temporal interval, the lower layer of the proposed strategy adds fast‐charging EVs in the real‐time orderly charging and discharging DR control by a shorter temporal interval of 15 min and designs two different charging and discharging price stimulation scenarios. The simulation results in the last section of this paper show that the proposed 'spatial‐temporal' bi‐layer optimal control strategy can effectively guide the charging and discharging behaviours of EVs in both spatial and temporal domains of a multi‐area VPP, achieving lower energy and carbon transaction cost and smaller load fluctuations. [ABSTRACT FROM AUTHOR]

Published

2022

207. The Impact of Conventional Power Block Startup Procedures on the Fatigue Behavior of Drum Materials.

Author

Okrajni, Jerzy, Wacławiak, Krzysztof, Twardawa, Mariusz, and Junak, Grzegorz

Subjects

MATERIAL fatigue, FATIGUE life, DRUM playing, ENERGY industries, ELECTRIC power consumption, MECHANICAL properties of condensed matter, TEMPERATURE distribution

Abstract

Varying demands for electricity within the energy sector require the modification of operating modes to ensure both an uninterrupted electricity supply and the upholding of safety standards. This paper presents a method for the prediction of drum fatigue life, via the local analysis of stress–strain fields and low-cycle fatigue tests of the drum material. The analysis compares the fatigue properties of an unused material and a material that has undergone many years of operation. In addition, this paper suggests drum operating conditions based on the results of load testing under industrial conditions. The drum model was developed on the basis of technical documentation. The analysis includes the calculations of time-dependent temperature distributions, stresses, and strains for various drum startup modes. The drum material fatigue properties are determined under low-cycle conditions. Using the modeling results and fatigue properties, predictions of drum life for different startup modes are presented. The paper summarizes the impact of a range of startup procedures and the drum material fatigue properties on the fatigue life of a working drum, under various mechanical and thermal loads. In addition, this paper proposes a methodological approach to fatigue life assessment, as a combination of multiple research methods. [ABSTRACT FROM AUTHOR]

Published

2022

208. Analysis of sub‐synchronous resonance between DC‐side dynamics of large‐scale PV plants and nearby synchronous generators shaft.

Author

Pourheydari, Mohammad, Parniani, Mostafa, and Ravanji, Mohammad Hasan

Subjects

SUBSYNCHRONOUS resonance, SYNCHRONOUS generators, MODAL analysis, MAXIMUM power point trackers, ELECTRIC capacity, OSCILLATIONS, ELECTRIC inductance, POWER plants

Abstract

This paper investigates the dynamic interactions between large‐scale PV plants and nearby synchronous generators. To this end, a comprehensive model of a PV plant, including the PV arrays characteristic and their voltage controller, DC/DC converter, DC‐link dynamic, DC/AC inverter controllers, and output filter, is obtained. Then, the eigenvalues of the PV plant model are calculated, and it is revealed that the PV plant has a dynamic mode in the sub‐synchronous oscillations (SSOs) range. Furthermore, the modal analysis method is employed, and it is shown that the inductance of the DC/DC converter and the DC‐link capacitor significantly contribute to the PV sub‐synchronous mode. Also, it is shown that this mode oscillations penetrate the grid and increase the risk of sub‐synchronous resonance (SSR). Then, the mechanism of dynamic interactions between large‐scale PV plants and torsional modes of nearby synchronous generators is revealed. This paper also investigates the required conditions for these interactions and shows that solar irradiation level and the DC‐link capacitance are the essential factors that can intensify these interactions. [ABSTRACT FROM AUTHOR]

Published

2023

209. New Software for the Techno–Economic Analysis of Small Hydro Power Plants.

Author

Guzović, Zvonimir, Barbarić, Marina, Bačelić Medić, Zlatko, and Degiuli, Nastia

Subjects

WATER management, HYDROELECTRIC power plants, POWER plants, COMPUTER software, COMPUTER software testing, INVESTORS

Abstract

Project SMART (Strategies to Promote Small-Scale Hydro Electricity Production in Europe) from the Intelligent Energy Europe (IEE) program, in which 7 institutions from 5 European states participate, pointed to the important barriers for the expansion of small hydro power plants (SHP) in Europe. One of the main barriers is the lack of suitable methodology and software able to create a clear view of the SHP potential in the given territory, as well as a complete techno-economic analysis for certain locations. Worldwide, there are a certain number of software for this purpose, and will be presented in this paper. However, in practical application for concrete cases, they show certain disadvantages. For example, one software is not able to take into account all the specifics of watercourses and plants; another does not have the option of selecting all types of turbines; in others, the calculation models are based on a limited number of equations that do not describe all possible cases; in some, economic analysis is oversimplified, etc. The aim of this paper is to develop software that is more comprehensive than any existing software. A new software for the techno-economic analysis of SHP is developed using Python and will be presented in this paper. The software is very useful for experts in the field of SHP, but also much wider, for decision-makers, potential investors, and stakeholders, especially in developing countries. It will improve water resources management, disseminate opportunities to investors, and increase the interest of stakeholders to invest in SHP, resulting in their wider use. The software is tested on location for SHP in the Republic of Croatia by comparison with the results obtained by the usual classical calculation. The agreement of the results is satisfactory. [ABSTRACT FROM AUTHOR]

Published

2023

210. Floating Photovoltaic Power Plant and Estimation of Potential in Bosnia and Herzegovina.

Author

Zeljković, Sarah, Panjeta, Naida, Ajkunić, Emir, and Avdaković, Samir

Subjects

PHOTOVOLTAIC power generation, ELECTRIC power consumption, POWER plants, PLANT surfaces, PHOTOVOLTAIC power systems, COAL-fired power plants

Abstract

Generation of photovoltaic power plants is growing rapidly in the last ten years in the world. One of the key factors for the construction of floating photovoltaic power plants is to provide space for their construction. This paper presents statistical indicators of installed capacities of floating photovoltaic power plants, as well as a detailed description of the components of these power plants. Approaches to construction and maintenance recommendations are described in more detail. The basic results of simulations are presented on a concrete example of a floating photovoltaic 1 MW power plant on Lake Modrac. The available areas of artificial lakes in Bosnia and Herzegovina were analysed, and it was shown that the installation of floating photovoltaic power plants on 5% of the surface of artificial lakes would provide around 10% of the total electricity consumption in Bosnia and Herzegovina. [ABSTRACT FROM AUTHOR]

Published

2023

211. Common Failures in Hydraulic Kaplan Turbine Blades and Practical Solutions.

Author

Khalid Mohammed Ridha, Waleed, Reza Kashyzadeh, Kazem, and Ghorbani, Siamak

Subjects

HYDRAULIC turbines, TURBINE blades, FOREIGN bodies, FRACTURE mechanics, MANUFACTURING processes, MATERIAL fatigue, GAS power plants, POWER plants

Abstract

Kaplan turbines, as one of the well-known hydraulic turbines, are generally utilized worldwide for low-head and high-flow conditions. Any failure in each of the turbine components can result in long-term downtime and high repair costs. In a particular case, if other parts are damaged due to the impact of the broken blades (e.g., the main shaft of the turbine), the whole power plant may be shut down. On the other hand, further research on the primary causes of failures in turbines can help improve the present failure evaluation methodologies in power plants. Hence, the main objective of this paper is to present the major causes of Kaplan turbine failures to prevent excessive damage to the equipment and provide practical solutions for them. In general, turbines are mainly subjected to both Internal Object Damage (IOD) and Foreign Object Damage (FOD). Accordingly, this paper presents a state-of-the-art review of Kaplan turbine failures related to material and physical defects, deficiencies in design, deficits in manufacturing and assembly processes, corrosion failures, fatigue failure, cavitation wear, types of cavitation in hydro turbines, hydro-abrasive problems, and hydro-erosion problems. Eventually, the authors have attempted to discuss practical hints (e.g., nanostructured coatings) to prevent damages and improve the performance of Kaplan turbines. [ABSTRACT FROM AUTHOR]

Published

2023

212. Implementation and Evaluation of a Complex Pumped-Storage Hydropower Plant with Four Units, Common Penstock, and Surge Tank in a Real-Time Digital Simulator †.

Author

Akbari, Hasan, Pérez-Díaz, Juan I., Sarasúa, José-Ignacio, and Schürhuber, Robert

Subjects

PUMPED storage power plants, POWER plants, RENEWABLE energy sources, ELECTRIC transients, ENERGY storage, POLYNOMIAL approximation, ENERGY consumption

Abstract

The demand for energy storage systems is rising together with the proportion of renewable energy sources (RES) in power systems. The highest capacity among the various energy storage systems in power systems is provided by pumped-storage hydropower (PSH). In this paper, the ability of the real-time digital simulator (RTDS), e.g., dSpace–SCALEXIO, to emulate a complex pumped-storage hydropower plant with four units, two common penstocks, a surge tank, and a long headrace tunnel is investigated. The RTDS is the smart brain of an advanced lab setup called power hardware in the loop (PHIL), which is an extremely safe and useful lab system for electrical power system research and testing hardware and methods under various conditions. In this research, the capability of an RTDS to emulate the behavior of a pumped-storage hydropower plant including four Francis pump-turbines, four short penstocks, two common penstocks, a surge tank, and a long headrace tunnel is evaluated. Francis pump-turbines are modelled based on the hill chart-based interpolation and waterways including penstocks and headrace tunnel are modelled based on the polynomial approximation of a hyperbolic function. Finally, the results from the RTDS are presented and discussed. According to the results of the paper, we confirm that the RTDS can accurately emulate the hydraulic, mechanical, and electrical transients of a pumped-storage hydropower plant with a complex configuration. [ABSTRACT FROM AUTHOR]

Published

2023

213. Can Hydrogen Production Be Economically Viable on the Existing Gas-Fired Power Plant Location? New Empirical Evidence.

Author

Dumančić, Andrea, Vlahinić Lenz, Nela, and Majstrović, Goran

Subjects

GAS power plants, POWER plants, INDUSTRIAL location, NATURAL gas prices, CONSTRUCTION cost estimates, ELECTRICITY pricing, PRICES, HYDROGEN as fuel, HYDROGEN production

Abstract

The paper provides an economic model for the assessment of hydrogen production at the site of an existing thermal power plant, which is then integrated into the existing gas grid. The model uses projections of electricity prices, natural gas prices, and CO2 prices, as well as estimates of the cost of building a power-to-gas system for a 25-year period. The objective of this research is to calculate the yellow hydrogen production price for each lifetime year of the Power-to-gas system to evaluate yellow hydrogen competitiveness compared to the fossil alternatives. We test if an incentive scheme is needed to make this technology economically viable. The research also provides several sensitivity scenarios of electricity, natural gas, and CO2 price changes. Our research results clearly prove that yellow hydrogen is not yet competitive with fossil alternatives and needs incentive mechanisms for the time being. At given natural gas and CO2 prices, the incentive for hydrogen production needs to be 52.90 EUR/MWh in 2025 and 36.18 EUR/MWh in 2050. However, the role of hydrogen in the green transition could be very important as it provides ancillary services and balances energy sources in the power system. [ABSTRACT FROM AUTHOR]

Published

2023

214. Virtual Power Plant with Renewable Energy Sources and Energy Storage Systems for Sustainable Power Grid-Formation, Control Techniques and Demand Response.

Author

Liu, Jiaqi, Hu, Hongji, Yu, Samson S., and Trinh, Hieu

Subjects

BIOMASS energy, RENEWABLE energy sources, ENERGY storage, ELECTRIC power distribution grids, POWER resources, ENERGY industries, POWER plants, BATTERY storage plants

Abstract

As the climate crisis worsens, power grids are gradually transforming into a more sustainable state through renewable energy sources (RESs), energy storage systems (ESSs), and smart loads. Virtual power plants (VPP) are an emerging concept that can flexibly integrate distributed energy resources (DERs), managing manage the power output of each DER unit, as well as the power consumption of loads, to balance electricity supply and demand in real time. VPPs can participate in energy markets, enable self-scheduling of RESs, facilitate energy trading and sharing, and provide demand-side frequency control ancillary services (D-FCAS) to enhance the stability of the system frequency. As a result, studies considering VPPs have become the focus of recent energy research, with the purpose of reducing the uncertainty resulting from RESs distributed in the power grid and improving technology related to energy management system (EMS). However, comprehensive reviews of VPPs considering their formation, control techniques, and D-FCAS are still lacking in the literature. Therefore, this paper aims to provide a thorough overview of state-of-the-art VPP technologies for building sustainable power grids in the future. The review mainly considers the development of VPPs, the information transmission and control methods among DERs and loads in VPPs, as well as the relevant technologies for providing D-FCAS from VPPs. This review paper describes the significant economic, social, and environmental benefits of VPPs, as well as the technological advancements, challenges, and possible future research directions in VPP research. [ABSTRACT FROM AUTHOR]

Published

2023

215. A process-model-free method for model predictive control via a reference model-based proportional-integral-derivative controller with application to a thermal power plant.

Author

Gengjin Shi, Miaomiao Ma, Donghai Li, Yanjun Ding, and Lee, Kwang Y.

Subjects

POWER plants, STEAM power plants, PREDICTION models, COAL-fired power plants, COMPUTER performance

Abstract

Introduction: Model predictive control (MPC) is an advanced control strategy which can achieve fast reference tracking response and deal with process constraints, time delay and multivariable problems. However, thermal processes in coal-fired power plants are usually difficult to model accurately, which limits the application of MPC to thermal power plants. Methods: To solve the problem, this paper proposes a process-model-free method for MPC via a reference model (RM)-based controller, i.e., a desired dynamic equational (DDE) proportional-integral-derivative (PID) controller (DDE-PID). Results and Discussion: The DDE-PID can provide the design model and enhance the disturbance rejection ability for MPC. Simulations and results of field tests on a coal-fired unit show the superiorities of the proposed controller in reference tracking, disturbance rejection and robustness, which indicates the promising prospect of the field application of the MPC with DDE-PID, or MPC-DDE in short, to thermal power plants. [ABSTRACT FROM AUTHOR]

Published

2023

216. Advances in Fault Detection and Diagnosis for Thermal Power Plants: A Review of Intelligent Techniques.

Author

Khalid, Salman, Song, Jinwoo, Raouf, Izaz, and Kim, Heung Soo

Subjects

POWER plants, STEAM power plants, ENERGY development, THRESHOLD energy, MAINTENANCE costs, SUSTAINABLE development

Abstract

Thermal power plants (TPPs) are critical to supplying energy to society, and ensuring their safe and efficient operation is a top priority. To minimize maintenance shutdowns and costs, modern TPPs have adopted advanced fault detection and diagnosis (FDD) techniques. These FDD approaches can be divided into three main categories: model-based, data-driven-based, and statistical-based methods. Despite the practical limitations of model-based methods, a multitude of data-driven and statistical techniques have been developed to monitor key equipment in TPPs. The main contribution of this paper is a systematic review of advanced FDD methods that addresses a literature gap by providing a comprehensive comparison and analysis of these techniques. The review discusses the most relevant FDD strategies, including model-based, data-driven, and statistical-based approaches, and their applications in enhancing the efficiency and reliability of TPPs. Our review highlights the novel and innovative aspects of these techniques and emphasizes their significance in sustainable energy development and the long-term viability of thermal power generation. This review further explores the recent advancements in intelligent FDD techniques for boilers and turbines in TPPs. It also discusses real-world applications, and analyzes the limitations and challenges of current approaches. The paper highlights the need for further research and development in this field, and outlines potential future directions to improve the safety, efficiency, and reliability of intelligent TPPs. Overall, this review provides valuable insights into the current state-of-the-art in FDD techniques for TPPs, and serves as a guide for future research and development. [ABSTRACT FROM AUTHOR]

Published

2023

217. 考虑发电工况和站内损耗的风电场 可用发电功率估算方法.

Author

杨健, 柳玉, 黄坤鹏, 罗亚洲, 牛四清, 王伟, 环加飞, 张雷, 张沛, and 李华伟

Subjects

WIND power, STANDARD deviations, WIND power plants, RANK correlation (Statistics), MANAGEMENT information systems, POWER plants, WIND turbines

Abstract

Copyright of Power Generation Technology is the property of Power Generation Technology Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

218. Wind Power Potential Assessment at Different Locations in Lebanon: Best-Fit Probability Distribution Model and Techno-Economic Feasibility.

Author

Kassem, Youssef, Gokcekus, Huseyin, and Essayah, Ahmed Mohamed Salah

Subjects

DISTRIBUTION (Probability theory), WIND power, BETA distribution, BETA functions, WIND speed, POWER plants, WIND power plants

Abstract

The objective of the current paper is to evaluate Lebanon's wind energy generation potential as an alternative solution to the electricity supply to households and to enhance sustainable technological development. Firstly, the paper aims to investigate the appropriateness of 44 distribution function models for the evaluation of wind speed characteristics and compared them with popular models at 12 locations in Lebanon for the first time. The results showed that Wakeby and Beta distribution functions gave the best fit to the actual data for most locations. Secondly, the techno-economic and environmental feasibility assessment for 10MW grid-connected wind farms was developed based on variations in financial parameters using RETScreen Experts software. The findings demonstrate that the proposed power plant is both technically and financially feasible. It was found that Ain ed Dabaa is the most viable location for the installation of a wind farm. [ABSTRACT FROM AUTHOR]

Published

2023

219. PERFORMANCE AND BEHAVIOR ANALYSIS OF WATER CIRCULATION SYSTEM OF A THERMAL POWER PLANT.

Author

Sharma, Seema and Sushma

Subjects

POWER plants, CONDENSERS (Vapors & gases), FUZZY numbers

Abstract

This paper analyses the performance and behavior of water circulation system (WCS) of a thermal power plant in fuzzy environment. For this purpose, fuzzy 1-t technique coupled with petrinet modelling has been used. To address the vagueness in data, trapezoidal fuzzy numbers have been employed in fuzzy 1-t technique. Various reliability indicators of WCS viz. failure rate, repair time, expected number of failures, mean time between failures, reliability and availability have been computed at ±15%, ±25% and ±40% spreads using fuzzy 1-t technique. Further, fuzzy values of reliability indicators have been defuzzified employing COA method and the failure dynamics of WCS have been studied on account of decreasing / increasing trends of reliability indicators. The outcomes of this study are of great importance for plant personnel / management to enhance the availability of WCS. [ABSTRACT FROM AUTHOR]

Published

2023

220. Risk-based asset life management for steam turbines and generators.

Author

Decoussemaeker, Pascal, Vittal, Sameer, and Ahmed, Shayan I

Subjects

STEAM generators, TURBINE generators, STEAM-turbines, ASSET management, STEAM power plants, POWER plants, PLANT performance

Abstract

To ensure a good return on investment, it is important for power plant operators to set up an asset management program that will ensure reliable operation over the commercial life of the plant. General Electric (GE) has been applying a variety of asset management technologies to improve power plant life and performance for our customers. These methods consider various inputs including equipment design knowledge; asset condition assessed from real-time monitoring and inspection data; and lessons learned from repairing, operating and maintaining thousands of assets globally. In this paper, a subset of that information is applied to develop a methodology to perform risk-based health and life assessments for steam turbines and generators. The method has been used on several steam power plants around the world, to help operators of ageing steam plants make the right decisions related to end-of-life management or life extension. [ABSTRACT FROM AUTHOR]

Published

2023

221. EXPERIMENTAL RESEARCH ON A KINETIC HYDRO TURBINE - GENERATOR ASSEMBLY.

Author

MILCA, ALEXANDRU SPIRIDON, BUNEA, FLORENTINA, NEDELCU, ADRIAN, NICOLAIE, SERGIU, BABUTANU, CORINA ALICE, and SIMIONESCU, CRISTIAN

Subjects

TURBINES, CHANNEL flow, WATER depth, WATER power, TURBINE generators, POWER plants, ELECTRIC generators

Abstract

The present paper is part of a larger project whose purpose is to develop a new hydrokinetic turbine-generator assembly, suitable for very low head water courses. It presents the experimental results of a turbine--generator physical model, installed on the tailrace of Mihailesti Hydropower Plant. In order to carry out the measurements, a floating structure and an anchoring system was installed on the power plant tailrace. This system also allowed the translation of the assembly between the two shores. A first set of measurements followed the water velocity and depth in the channel at various load values of the hydropower plant units, in order to determine the proper conditions for testing the model. The turbine gives the possibility of blades adjustment at three different angles, 0, 9 and 14 degrees respectively. Therefore, a set of measurements has been performed for each position of the blades. The measured parameters were the electric parameters of the generator such as voltage, current and the power variation with rotation speed. For the blades adjustment of 9 degrees and 1.76 m/s water velocity, the generator reached its maximum power of 500 W. The results retrieved will be used for the optimization and design of a new enlarged scale turbine--generator assembly. They will also be used as input data for the numerical modeling of the generator. Also, the exact knowledge of the channel geometry and flow parameters is valuable in studies preceding testing a prototype in the site. [ABSTRACT FROM AUTHOR]

Published

2023

222. Real-Time Multi-Home Energy Management with EV Charging Scheduling Using Multi-Agent Deep Reinforcement Learning Optimization.

Author

Kaewdornhan, Niphon, Srithapon, Chitchai, Liemthong, Rittichai, and Chatthaworn, Rongrit

Subjects

REINFORCEMENT learning, DEEP learning, ELECTRIC vehicle charging stations, ENERGY management, BATTERY storage plants, ELECTRIC vehicle batteries, POWER plants, ENERGY industries

Abstract

Energy management for multi-home installation of solar PhotoVoltaics (solar PVs) combined with Electric Vehicles' (EVs) charging scheduling has a rich complexity due to the uncertainties of solar PV generation and EV usage. Changing clients from multi-consumers to multi-prosumers with real-time energy trading supervised by the aggregator is an efficient way to solve undesired demand problems due to disorderly EV scheduling. Therefore, this paper proposes real-time multi-home energy management with EV charging scheduling using multi-agent deep reinforcement learning optimization. The aggregator and prosumers are developed as smart agents to interact with each other to find the best decision. This paper aims to reduce the electricity expense of prosumers through EV battery scheduling. The aggregator calculates the revenue from energy trading with multi-prosumers by using a real-time pricing concept which can facilitate the proper behavior of prosumers. Simulation results show that the proposed method can reduce mean power consumption by 9.04% and 39.57% compared with consumption using the system without EV usage and the system that applies the conventional energy price, respectively. Also, it can decrease the costs of the prosumer by between 1.67% and 24.57%, and the aggregator can generate revenue by 0.065 USD per day, which is higher than that generated when employing conventional energy prices. [ABSTRACT FROM AUTHOR]

Published

2023

223. Environmental impacts of Indian coal thermal power plants and associated human health risk to the nearby residential communities: A potential review.

Author

Vig N, Ravindra K, and Mor S

Subjects

Humans, Asian People, Soil chemistry, India, Soil Pollutants chemistry, Coal toxicity, Environmental Pollutants toxicity, Power Plants

Abstract

Worldwide, harmful emissions from coal power plants cause many illnesses contribute to premature deaths burden. Despite its high impact on human health and being a major source of toxic pollutants, coal has been considered a component of global energy for decades. Hence, this work was envisaged to understand the rising environmental and multiple health issues from coal power plants. Studies on the adverse impacts of coal power plants on the environment, including soil, surface water, groundwater and air, were critically evaluated. The health risk from exposure to different pollutants and toxic metals released from the power plant was also demonstrated. The study also highlighted the government initiatives and policies regarding coal power operation and generation. Lastly, the study focused on guiding coal power plant owners and policymakers in identifying the essential cues for the risk assessment and management. The current study found an association between environmental and human health risks due to power generation, which needs intervention from the scientific and medical fields to jointly address public concerns. It is also suggested that future research should concentrate on exposure assessment techniques by integrating source-identification and geographic information systems to assess the health effects of different contaminants from power plants and to mitigate their adverse impact., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 Elsevier Ltd. All rights reserved.)

Published

2023

224. The influence of hazard control and prevention toward safety behaviors and safety outcomes in coal-fired power plants using PLS-SEM.

Author

Arifin K, Ali MXM, Abas A, Ahmad MA, Ahamad MA, and Sahimi AS

Subjects

Humans, Latent Class Analysis, Least-Squares Analysis, Coal, Power Plants, Safety Management

Abstract

Introduction: The electrical utility industry, which plays a vital role in sustaining other sectors, contributes to high occupational accident rates in the utility industries. The high accident rate shows that there has been insufficient effort made to control unsafe actions and conditions in the workplace. This study aims to examine the influence of hazard control and prevention as leading indicators of safety behaviors and outcomes in coal-fired power plants in Malaysia., Methods: This quantitative research was conducted by distributing survey questionnaires randomly to five coal-fired power plants in Peninsular Malaysia. A total of 340 respondents were involved in this research. Partial least squares structural equation modeling (PLS-SEM) analysis was performed using SmartPLS to validate and examine the relationship of the proposed model., Results: The results validate the construct of hazard control and prevention consisting of planning, action, managing, and verifying, while the safety outcomes construct consists of occupational accidents, fatal accidents, near misses, and lost time injuries. The results indicate that hazard control and prevention significantly relate to safety compliance, safety participation, safety motivation, and safety knowledge. Moreover, safety outcomes were influenced negatively by hazard control and prevention through safety compliance., Conclusion: The model provides a better understanding of the influence of hazard control and prevention on safety behavior and outcomes., Practical Applications: The model can be used as guidance for practitioners and researchers in planning and implementing hazard control and prevention to improve health and safety in the workplace., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 National Safety Council and Elsevier Ltd. All rights reserved.)

Published

2023

225. Comparison of efficiency power plant method in generation expansion planning.

Author

Fajri, Amrisal Kamal, Sarjiya, Sarjiya, and Multanto, Lesnanto Putra

Subjects

RENEWABLE energy sources, CENTRAL economic planning, COAL-fired power plants, OPERATING costs, POWER plants

Abstract

The development of a variety of methods by sequencing on economic planning and optimization can be realized by emphasizing collaborative, multi-purpose aspects, as well as increasing the variety of solutions that are environmentally friendly, make cost savings, and focus on using low carbon in this approach, use Generation Expansion Planning (GEP), which is the center for reducing the amount of carbon through the calculation process for the development of conventional power plants. In this study modeled the efficiency of Generation Expansion Planning (GEP). In this paper uses the planning method for socio cultural. This research focuses on making energy in a more flexible way. GEP can be a source of renewable energy solutions. In this literature focus on various methods for planning generation expansion through the GEP approach, in terms of finding the total investment and operating costs. This approach provides various guidelines for conducting new research projects. This model has various technicalities in increasing the efficiency of power plants for planning power generation expansion. [ABSTRACT FROM AUTHOR]

Published

2022

226. Simplified approach to determine the requirements of a "flexible nuclear reactor" in power system with high insertion of variable renewable energy sources.

Author

Mazauric, Anne-Laure, Sciora, Pierre, Pascal, Vincent, Droin, Jean-Baptiste, Bésanger, Yvon, Hadjsaïd, Nouredine, Tran, Quoc Tuan, and Guyonneau, Nicolas

Subjects

RENEWABLE energy sources, NUCLEAR reactors, NUCLEAR energy, INDEPENDENT system operators, POWER plants

Abstract

The objective of the paper is to study the potential behaviour of a power system with high share of nuclear and less thermal plants, in which variable RES insertion increases − for example the French case −, in order to determine the specifications for the design of a potential nuclear reactor with high "manoeuvrability". Moreover, the flexible reactor may participate more in the supply − demand balance and in particular during large frequency fluctuations caused by the high variability of RES. The studies are carried out with the PowerFactory software, which make it possible to highlight specific needs regarding the power ramp for an "ideal" flexible nuclear reactor. Using a benchmark network, the Kundur "2 areas-4 machines", the flexibility requirements are obtained as a function of the grid disturbances. For this purpose, the penetration of variable RES is progressively increased, while nuclear power is reduced and thermal power plants are totally suppressed. The study shows that a drop in RES production directly impacts the minimal frequency. A faster response speed of nuclear power makes it possible to restore this stability and return to normal operating conditions imposed by the grid operator. This paper describes therefore the process of obtaining the flexibility criterion for different cases of insertion of variable RES. [ABSTRACT FROM AUTHOR]

Published

2022

227. ADVANTAGES OF BIOGAS POWER PLANTS IN ENERGY TRANSITION OF PANNONIAN COUNTRIES -- BENEFITS FOR THE LOCAL COMMUNITY.

Author

IVANOVIĆ, Milan and GLAVAŠ, Hrvoje

Subjects

BIOGAS, RENEWABLE energy sources, POWER plants, ORGANIC fertilizers, SOCIAL cohesion, RURAL hospitals, CONSTRUCTION planning

Abstract

This paper points out the benefits for the local community from the construction of biogas power plants (BgP) - which are no from using other renewable energy sources. Benefits from BgP for local community are: additional income to local farmers, higher level of agro technologies in the village, strengthening social cohesion, ecological disposal of rural waste, electricity and heat production, organic fertilizer, hiring local labor and better quality of life for all inhabitants. In paper presented and important elements for planning the construction of biogas power plants. [ABSTRACT FROM AUTHOR]

Published

2022

228. A Wasserstein‐distance‐based distributionally robust chance constrained bidding model for virtual power plant considering electricity‐carbon trading.

Author

Fan, Qiang and Liu, Dong

Subjects

BIDS, CARBON offsetting, DUALITY theory (Mathematics), LINEAR programming, ELECTRICITY markets, POWER plants, COAL-fired power plants

Abstract

Virtual power plant (VPP) can aggregate distributed energy resources (DER) and controllable loads to participate in the bidding of electricity market and carbon trading market. However, the uncertainty of renewable power production brings high transaction risks to VPP. Given this background, this paper proposes a novel Wasserstein‐distance based two‐stage distributionally robust chance constrained (DRCC) bidding model for VPP participating in the electricity‐carbon coupled market. The uncertainties are modelled as an ambiguity set based on Wasserstein distance, in which the two‐sided chance constraints are guaranteed satisfied. In the first stage, VPP's revenue is maximized according to the forecast information. In the second stage, the re‐dispatch measures are determined to hedge against the perturbation of uncertainties under the worst‐case distribution within the ambiguity set. Finally, a reformulation approach based on strong duality theory and conditional value‐at‐risk (CVaR) approximation is proposed to transform the DRCC problem into a tractable mixed‐integer linear programming (MILP) framework. Case studies are carried out on the IEEE 30‐bus system to verify the effectiveness and efficiency of the proposed approach. [ABSTRACT FROM AUTHOR]

Published

2024

229. Optimal Capacity Configuration of Energy Storage in PV Plants Considering Multi-Stakeholders.

Author

Sun, Fan, Wang, Weiqing, and Nan, Dongliang

Subjects

PARTICLE swarm optimization, ENERGY storage, POWER plants, BATTERY storage plants, ELECTRIC power distribution grids, PHOTOVOLTAIC effect, RENEWABLE energy sources

Abstract

With the integration of large-scale renewable energy generation, some new problems and challenges are brought for the operation and planning of power systems with the aim of mitigating the adverse effects of integrating photovoltaic plants into the grid and safeguarding the interests of diverse stakeholders. In this paper, a methodology for allotting capacity is introduced, which takes into account the active involvement of multiple stakeholders in the energy storage system. The objective model for maximizing the financial proceeds of the PV plant, the system for the storage of energy, and a power grid company is studied. Then, in order to maximize the benefit of three stakeholders, a modified particle swarm optimization algorithm is devised, employing the prevailing typical allocation strategy. Finally, a case study is provided based on the modified IEEE 14-bus and the actual power grid from South Xinjiang, China. The simulation results and findings of the case study conclusively illustrate that the proposed methodology adeptly ensures the maximization of interests for the triad of stakeholders. [ABSTRACT FROM AUTHOR]

Published

2024

230. From Local Energy Communities towards National Energy System: A Grid-Aware Techno-Economic Analysis.

Author

Terrier, Cédric, Loustau, Joseph René Hubert, Lepour, Dorsan, and Maréchal, François

Subjects

ENERGY infrastructure, ELECTRICITY pricing, RENEWABLE energy sources, LINEAR programming, PRICES, POWER plants, PHOTOVOLTAIC power systems

Abstract

Energy communities are key actors in the energy transition since they optimally interconnect renewable energy capacities with the consumers. Despite versatile objectives, they usually aim at improving the self-consumption of renewable electricity within low-voltage grids to maximize revenues. In addition, energy communities are an excellent opportunity to supply renewable electricity to regional and national energy systems. However, effective price signals have to be designed to coordinate the needs of the energy infrastructure with the interests of these local stakeholders. The aim of this paper is to demonstrate the integration of energy communities at the national level with a bottom–up approach. District energy systems with a building scale resolution are modeled in a mixed-integer linear programming problem. The Dantzig–Wolfe decomposition is applied to reduce the computational time. The methodology lies within the framework of a renewable energy hub, characterized by a high share of photovoltaic capacities. Both investments into equipment and its operation are considered. The model is applied on a set of five typical districts and weather locations representative of the Swiss building stock. The extrapolation to the national scale reveals a heterogeneous photovoltaic potential throughout the country. Present electricity tariffs promote a maximal investment into photovoltaic panels in every region, reaching an installed capacity of 67.2 GW and generating 80 TWh per year. Placed in perspective with the optimal PV capacity forecast at 15.4 GW   p e a k at the national level, coordinated investment between local and national actors is needed to prevent dispensable expenses. An uncoordinated design is expected to increase the total costs for residential energy systems from 12% to 83% and curtails 48% of local renewable electricity. [ABSTRACT FROM AUTHOR]

Published

2024

231. Optimal economic dispatch of a virtual power plant based on gated recurrent unit proximal policy optimization.

Author

Gao, Zhiping, Kang, Wenwen, Chen, Xinghua, Gong, Siru, Liu, Zongxiong, He, Degang, Shi, Shen, Shangguan, Xing-Chen, Wang, Weiyu, and Yingping, Cao

Subjects

REINFORCEMENT learning, DEEP reinforcement learning, ARTIFICIAL neural networks, PARTIALLY observable Markov decision processes, BATTERY storage plants, POWER plants

Abstract

The intermittent renewable energy in a virtual power plant (VPP) brings generation uncertainties, which prevents the VPP from providing a reliable and user-friendly power supply. To address this issue, this paper proposes a gated recurrent unit proximal policy optimization (GRUPPO)-based optimal VPP economic dispatch method. First, electrical generation, storage, and consumption are established to form a VPP framework by considering the accessibility of VPP state information. The optimal VPP economic dispatch can then be expressed as a partially observable Markov decision process (POMDP) problem. A novel deep reinforcement learning method called GRUPPO is further developed based on VPP time series characteristics. Finally, case studies are conducted over a 24-h period based on the actual historical data. The test results illustrate that the proposed economic dispatch can achieve a maximum operation cost reduction of 6.5% and effectively smooth the supply-demand uncertainties. [ABSTRACT FROM AUTHOR]

Published

2024

232. Multiobjective Stochastic Power System Expansion Planning Considering Wind Farms and Demand Response.

Author

Ghadimi, Ali Asghar, Ahmadi, Abdollah, and Miveh, Mohammad Reza

Subjects

STOCHASTIC systems, RENEWABLE energy sources, NONLINEAR programming, LINEAR programming, ELECTRIC power consumption, POWER plants, WIND power plants

Abstract

In recent years, due to the increase in electricity consumption and environmental problems, power system expansion planning requires new technologies. In this regard, the incorporation of renewable energy sources (RESs) and utilization of demand response (DR) programs need disruptive variations in the present power system configurations. This paper proposes a mixed-integer linear robust multiobjective model for generation and transmission expansion planning (GEP-TEP) taking into account wind farms (WFs) and a DR program based on time-of-use pricing. The suggested model is presented via mixed-integer nonlinear programming (MINLP) at the first stage and then transformed into mixed-integer linear programming (MILP) using the Big M linearization technique. Moreover, long- and short-term uncertainties of load demand and WFs are incorporated into the recommended model to achieve more accurate results. The interval-based method is applied for taking into account long-term uncertainties while the scenario-based stochastic model is applied for modeling short-term uncertainties in the recommended GEP–TEP model. Lastly, the suggested model is investigated on various standard test systems to evaluate the effectiveness of the GEP-TEP model. [ABSTRACT FROM AUTHOR]

Published

2024

233. Rock Mass Structure Classification of Caves Based on the 3D Rock Block Index.

Author

Dong, Jun, Chen, Qingqing, Yuan, Guangxiang, and Xie, Kaiyan

Subjects

POWER plants, WATER conservation projects, SEISMIC waves, HYDROELECTRIC power plants, HYDRAULIC structures, MONTE Carlo method, GEOPHYSICAL prospecting

Abstract

In large-scale water conservancy and hydropower projects, complex rock structures are considered to be the main factor controlling the stability of hydraulic structures. The classification of rock mass structure plays an important role in the safety of all kinds of large buildings, especially underground engineering buildings. As a quantitative classification index of rock mass, the rock block index is very common in the classification of borehole and dam foundation rock mass structures. However, there are few studies on the classification of underground engineering rock masses. Moreover, their classification criteria have disadvantages in spatial dimension. Therefore, this paper takes the long exploratory cave CPD1 in the water transmission and power generation system of the Qingtian pumped storage power station in Zhejiang Province as the research object and launches a study on the structural classification of the rock mass of a flat cave based on the 3D rock block index. According to the group distribution of joints, the sections are statistically homogeneous. Additionally, the Monte Carlo method is used to carry out random simulations to generate a three-dimensional joint network model. The virtual survey lines are arranged along the center of the shape of the three different orthogonal planes of the 3D joint network model to represent the boreholes, and the RBI values of the virtual survey lines on each orthogonal plane are counted to classify the rock mass structure of the flat cave in a refined manner using the rock block index of the rock mass in 3D. The above method realizes the application of the 3D rock block index in underground engineering and overcomes the limitations of traditional rock mass classification methods in terms of classification index and dimension. The results show that: (1) Three-dimensional joint network simulations built on statistical and probabilistic foundations can visualize the structure of the rock mass and more accurately reflect the structural characteristics of the actual rock mass. (2) Based on the 3D rock block index, the rock mass structure of the long-tunnel CPD1 is classified, from that of a continuous structure to a blocky structure, corresponding to the integrity of the rock mass from complete to relatively complete. The classification results are consistent with the evaluation results of horizontal tunnel seismic wave geophysical exploration. (3) Based on the 3D joint network model, it is reasonable and feasible to use the 3D rock block index as a quantitative evaluation index to determine the structure type of flat cave rock masses. The above method is helpful and significant in the classification of underground engineering rock mass structures. [ABSTRACT FROM AUTHOR]

Published

2024

234. Energy, Exergy, Economic and Exergoeconomic Analyses of Chemical Looping Combustion Plant Using Waste Bark for District Heat and Power Generation with Negative Emissions.

Author

Surywanshi, Gajanan Dattarao, Leion, Henrik, and Soleimanisalim, Amir H.

Subjects

CHEMICAL-looping combustion, CHEMICAL plants, ANALYTICAL chemistry, POWER plants, CARBON sequestration, GREENHOUSE gases, EXERGY

Abstract

The greenhouse gas emissions from the boiler of pulp and paper industries can be minimized by adapting chemical looping combustion (CLC) technology. This work aims to analyze the energy, exergy, economic, and exergoeconomic performance of an industrial scale CLC plant for district heat and electricity generation using waste bark from the paper and pulp industry. The CLC plant with one natural ore and one industrial waste oxygen carrier (OC) is modeled using Aspen Plus. The performance of the CLC plant has been compared to Örtofta combined heat and power plant without CO2 capture and with post‐combustion CO2 capture as the reference cases. Results showed that the CLC‐based power plant is energetically, exegetically, and economically efficient compared to the reference cases. The circulating fluidized bed boiler unit contributes the highest exergy destruction (about 50–80%). Among the CO2 capture plants, the CLC plant with ilmenite has the lowest levelized cost of district heat (4.58 € GJ−1), and a payback period (9.69 years) followed by the CLC plant with LD slag (5.91 € GJ−1 and 11.84 years), and the plant with PCC (6.94 € GJ−1 and 13.58 years). The exergoeconomic analysis reveals that the CLC reactors have the highest cost reduction potential, followed by the steam turbine. [ABSTRACT FROM AUTHOR]

Published

2024

235. Design and development of waste heat re-utilisation technology by using artificial intelligence at thermal power plant.

Author

Mishra, Rabindra Kumar, Venkatesan, S., and Barpanda, N. K.

Subjects

WASTE heat, ARTIFICIAL intelligence, POWER plants, STEAM power plants, INTELLIGENT control systems

Abstract

The primary goal of this research paper is to inculcate AI approaches in thermal power plants to raise automation at power plants by expanding the integrated control idea to thermal power plants and implementing it using AI approaches. The recommended control method will be analysed and contrasted with established strategies. The crucial condition will be evaluated even though the suggested type of control system doesn't come up with an effective result. The development of the conceptual model is predicated on the state of power generation technologies. There will be no suggestion to use newer or different technology, such as fluidised bed combustion, sliding pressure units or ultra-supercritical plants, in the process of producing electricity. This study specifically focuses on the operational features of the control system instead of the hardware technologies. [ABSTRACT FROM AUTHOR]

Published

2024

236. Calibration Techniques for Water Content Measurements in Solid Biofuels.

Author

Kjeldsen, Henrik, Østergaard, Peter Friis, Strauss, Helena, Nielsen, Jan, Tallawi, Bayan, Georgin, Eric, Sabouroux, Pierre, Nielsen, Jan G., and Hougaard, Jens Ole

Subjects

BIOMASS energy, UNITS of measurement, CALIBRATION, POWER plants, MEASUREMENT, AIR flow

Abstract

This paper presents methodologies and equipment for SI-traceable inline measurements of water content (a critical quality parameter) in solid biofuels. Inline measurement systems for water content are commonly used at CHP plants, providing continuous real-time data. However, the accuracy of these systems is in most cases unsatisfactory, mainly because the systems are not calibrated representatively for the relevant material, and until now, calibrations traceable to the SI system have not been available. To provide reliable and accurate inline water content data, new procedures and equipment for calibrating measurement systems were developed. Two reference methods for the determination of water content were developed; one measures the airflow and dewpoint of desorbed water in the air passing a test sample, while the other uses a P2O₅-sensor. Additionally, a transfer standard based on a cavity resonance sensor was developed for fast onsite calibration of the inline sensor at the power plant. This new instrument allows for quick and accurate measurements. The transfer standard is made metrologically traceable to the primary measurement standards. The entire system was demonstrated by calibrating an inline microwave-based (MW) sensor at the CHP plant of VERDO in Randers, Denmark. Thus, a complete metrological traceability chain was established from an industrial to a primary standard. [ABSTRACT FROM AUTHOR]

Published

2024

237. An Opportunity for Coal Thermal Power Plants Facing Phase-Out: Case of the Power Plant Vojany (Slovakia).

Author

Stričík, Michal, Kuhnová, Lenka, Variny, Miroslav, Szaryszová, Petra, Kršák, Branislav, and Štrba, Ľubomír

Subjects

POWER plants, STEAM power plants, ALTERNATIVE fuels, THERMAL coal, CLEAN energy, HEAT of combustion, ECONOMIC efficiency

Abstract

The study deals with the possibilities of using alternative types of fuels to produce electricity. Power Plant Vojany (PPV) is a thermal power plant (TPP) in eastern Slovakia, which is part of the company Slovenské elektrárne, a. s. (SE). PPV primarily used black coal to produce electricity, which had to be imported from abroad (the Russian Federation). This activity has become inefficient both economically and environmentally, due to the high price of CO2 permits and the high emission factor of this type of fuel. PPV decided to co-combust biomass and refuse-derived fuel (RDF), which resulted in much better economic conditions due to their price, economic efficiency, and partly closed CO2 cycle. The aim of the paper is to explore the possibilities related to the production of energy in the cleanest possible way and with the least possible damage to the environment in coal thermal power plants using the example of operating Power Plant Vojany located in eastern part of Slovakia and to inspire each other for the modern transformation. For the purposes of hypothesis verification, analytical methods focused on overview studies of average fuel prices, comparisons, and the balance of fuels in connection with eliminated CO2 emissions, as well as municipal waste (MW) management in the EU and V4 countries, were used. The authors also focused on the energy recovery and combustion of MW and tracking the achieved CO2 savings in connection with the development of fuel sources in PPV. The results point to the fact that PPV is one of the power plants that could use biomass and RDF as fuel, which confirms the economic advantages of this procedure. The results confirm that the potential of RDF production in Slovakia is sufficient to ensure the operation of PPV at planned, even higher volumes of electricity production. The transformation to cleaner operation of coal thermal power plants represents a significant contribution of this study. [ABSTRACT FROM AUTHOR]

Published

2024

238. Fundamentals, Operation and Global Prospects for the Development of Biogas Plants—A Review.

Author

Gadirli, Gulnar, Pilarska, Agnieszka A., Dach, Jacek, Pilarski, Krzysztof, Kolasa-Więcek, Alicja, and Borowiak, Klaudia

Subjects

CLEAN energy, PLANT development, COST benefit analysis, BIOGAS production, ENERGY crops, GREENHOUSES, POWER plants

Abstract

As the global demand for renewable energy continues to rise, biogas production has emerged as a promising solution for sustainable energy generation. This review article presents the advantages of biogas technologies (mainly agricultural, based on waste of animal and plant origin) and extensively discusses the main principles of biogas production in the anaerobic digestion (AD). In this respect, the main parameters of the process, which require monitoring and decisive for its efficiency are described, therefore: temperature, pH value, retention time and organic loading rate (OLR). The principles of substrate selection are also discussed and the necessity and advantages of the use of organic waste according to the model of a circular economy and the concept of sustainable development, are indicated. It is emphasized that according to the new European regulations, the crops classified as food cannot be considered energy crops. The part on biogas production is summarised with an explanation of the necessity to treat and purify biogas. Biogas purification is important from the point of view of the efficiency of its conversion into electricity. A special place in this paper is devoted to the design, construction, functioning and operation of biogas plants, based on both scientific and practical aspects. In conclusion of this chapter, the economic aspects and profitability of operating biogas plants are discussed. Cost and benefit analyses are the major tool used for the systematic evaluation of the financial costs and potential benefits associated with the operation of biogas plants. The important fact is that the return on investment can be achieved within a few years, provided the activities are well-planned and executed. In addition to the fundamental issues of the operation of biogas plants, this article presents the global situation regarding the development of biogas plants, discussing in detail the specific needs and limitations on different continents. It is a interesting and extensive part of this article. The global agricultural biogas market is at very different levels of development. Most such installations are located in Asia and Europe. China has the highest number of biogas plants, with more than 100,000 biogas plants, followed by Germany with over 10,000 plants. In addition to the 100,000 biogas plants, China also has a large number of household biogas units, which gives a total of approx. 40 million operating units. The article concludes with a discussion of opportunities and barriers to the development of biogas plants, pointing to: financial issues, access to feedstock, political regulations, public awareness and the geopolitical situation. The most frequently cited reasons for investment failure include economic problems, lack of professional knowledge. [ABSTRACT FROM AUTHOR]

Published

2024

239. NAMAKHVANI HPP: A DECOMMISSIONED PROJECT AND ITS REVERBERATIONS IN GEORGIA.

Author

Giga, Tvauri and Vakhtang, Charaia

Subjects

COMMUNITY involvement, ENVIRONMENTAL responsibility, EXPERTISE, ECONOMIC development, ENERGY security, SOUND reverberation, POWER plants, ENVIRONMENTAL impact analysis, BEST practices

Abstract

The Namakhvani Hydro Power Plant (HPP) loomed large, not just as an ambitious energy project, but as a potential paradigm shift for Georgia's economic landscape. This article delves into the intricate machinery of the project, from its initial aspirations to its unforeseen derailment. It dissects the economic repercussions of its abandonment, casting a dark shadow on the nation's investment climate. Beyond the concrete details, the paper delves into the critical anatomy of the Namakhvani saga. What factors conspired to prevent its completion? What crucial lessons can be gleaned from this missed opportunity? To answer these questions, the article ventures beyond Georgia's borders, exploring successful HPP projects in other countries, and meticulously analyzing their blueprints and community engagement strategies. Drawing from both domestic and international experiences, it paves the way for a revised roadmap for future endeavors. Namakhvani stands not as a monument to failure, but as a potent catalyst for introspection and improvement. This article serves as a critical mirror, reflecting not just the technical missteps but also the fundamental need for transparency, public trust, and rigorous environmental assessments. It champions the integration of local expertise and international best practices, advocating for a collaborative approach that prioritizes both economic progress and ecological responsibility. [ABSTRACT FROM AUTHOR]

Published

2024

240. Optimal Control of Cascade Hydro Plants as a Prosumer-Oriented Distributed Energy Depot.

Author

Ignaciuk, Przemysław and Morawski, Michał

Subjects

CASCADE control, CLEAN energy, HYDROELECTRIC power plants, POWER plants, ENERGY consumption, PRICE fluctuations, RENEWABLE energy sources

Abstract

For political and economic reasons, renewable sources of energy have gained much importance in establishing a sustainable energy economy. By their very nature, however, their benefits depend on changeable weather conditions, and are unrelated to the generation and consumption patterns in industrial or home environments. This generation–dissipation disparity induces price fluctuations and threatens the stability of the supply system, yet can be alleviated by installing energy depots. While the classic methods of energy storage are hardly cost-effective, they may be supplemented, or replaced, by a distributed system of small-scale hydropower plants with ponds used as energy reservoirs. In this paper, following a rigorous mathematical argument, a dynamic model of a multi-cascade of hydropower plants is constructed, and a cost-optimal controller, with formally proven properties, is designed. On the one hand, it allows for an increase in the owners' revenue by as much as 30% (compared to a free-flow state); on the other hand, it reduces the load fluctuation imposed on the grid and the legacy supply system. Moreover, the risk of floods and droughts downstream resulting from inappropriate use of the plants is averted. [ABSTRACT FROM AUTHOR]

Published

2024

241. Performance Assessment of a Real PV System Connected to a Low-Voltage Grid.

Author

Magdy, Gaber, Metwally, Mostafa, Elbaset, Adel A., and Zaki, Esam

Subjects

PHOTOVOLTAIC power systems, SOLAR power plants, SOLAR radiation, SOLAR energy, CLEAN energy, SOLAR panels, POWER plants, MICROGRIDS, ELECTRIC power factor

Abstract

The generation of photovoltaic (PV) solar energy is increasing continuously because it is renewable, unlimited, and clean energy. In the past, generation systems depended on non-renewable sources such as oil, coal, and gas. Therefore, this paper assesses the performance of a 51 kW PV solar power plant connected to a low-voltage grid to feed an administrative building in the 6th of October City, Egypt. The performance analysis of the considered gridconnected PV system is carried out using power system simulator for Engineering (PSS/E) software. Where the PSS/E program, monitors and uses the power analyzer that displays the parameters and measures some parameters such as current, voltage, total power, power factor, frequency, and current and voltage harmonics, the used inverter from the type of grid inverter for the considered system. The results conclude that when the maximum solar radiation is reached, the maximum current can be obtained from the solar panels, thus obtaining the maximum power and power factor. Decreasing total voltage harmonic distortion, a current harmonic distortion within permissible limits using active harmonic distortion because this type is fast in processing up to 300 microseconds. The connection between solar stations and the national grid makes the system more efficient. [ABSTRACT FROM AUTHOR]

Published

2024

242. Energy management of distribution network with inverter‐based renewable virtual power plant considering voltage security index.

Author

Azarhooshang, Alireza and Rezazadeh, Alireza

Subjects

ENERGY management, DISTRIBUTION management, POWER plants, REACTIVE power control, ENERGY dissipation, ELECTRICAL load

Abstract

Virtual power plants (VPP) with resources and storages are able to control the active power of the network. They are also connected to the network through an inverter, which is capable of controlling reactive power. Therefore, it is expected that the optimal use of inverter‐based VPP can play an effective role in improving the economic and technical status of the distribution network. So, the operation of a smart distribution system is presented in this paper by considering inverter‐based VPPs constrained to the operator's measures. The weighted sum of expected energy loss (EEL) and voltage security index (VSI) is minimized while considering AC optimal power flow equations, restrictions of network's security, and operating model of the inverter‐based VPPs. Uncertainties with an origin of the amount of demand, renewable energy, and parameters of mobile energy storage are also discussed. The uncertainties are modelled using a stochastic optimization approach relying on the unscented transformation (UT). Evaluating inverter‐based VPP performance, providing models of flexible resources such as responsive loads and mobile storages, checking network voltage security status, and modelling uncertainties using the UT method are among the innovations of this study. According to the results, it is demonstrated that the technical situation of the distribution system is improved with the help of optimal management of the VPP. With energy management of the inverter‐based VPP, the suggested design has succeeded to enhance the operating status (voltage security) of the system by approximately 33–73% (12%) in comparison to power flow studies. [ABSTRACT FROM AUTHOR]

Published

2024

243. Contextual Rule-Based System for Brightness Energy Management in Buildings.

Author

Ferreira, Vasco, Pinto, Tiago, and Baptista, José

Subjects

ENERGY management, INTELLIGENT buildings, ENERGY industries, POWER plants, DISTRIBUTED power generation

Abstract

The increase in renewable generation of a distributed nature has brought significant new challenges to power and energy system management and operation. Self-consumption in buildings is widespread, and with it rises the need for novel, adaptive and intelligent building energy management systems. Although there is already extensive research and development work regarding building energy management solutions, the capabilities for adaptation and contextualization of decisions are still limited. Consequently, this paper proposes a novel contextual rule-based system for energy management in buildings, which incorporates a contextual dimension that enables the adaptability of the system according to diverse contextual situations and the presence of multiple users with different preferences. Results of a case study based on real data show that the contextualization of the energy management process can maintain energy costs as low as possible, while respecting user preferences and guaranteeing their comfort. [ABSTRACT FROM AUTHOR]

Published

2024

244. Thermal stability of film forming amines‐based corrosion inhibitors in high temperature power plant water solutions.

Author

Vidojkovic, Sonja, Mijajlovic, Miroslav, Lindeboom, Ralph E. F., and Jovicic, Vojislav

Subjects

PLANT-water relationships, WATER power, THERMAL stability, POWER plants, AQUATIC plants, CORROSION & anti-corrosives

Abstract

Film forming amines (FFA) are corrosion inhibitors added to power plant water. The major concern associated with their application is the thermal stability in the high temperature power plant water medium, along with the risk of decomposition into low molecular weight organic acids that can cause corrosive damages in the water/steam cycle. However, there is still a lack of sufficient data on the thermal stability of FFA corrosion inhibitors. This paper presents a comprehensive critical review and state‐of‐the‐art assessment of the results obtained from studying the thermolysis of FFA corrosion inhibitors in power plant water/steam cycle conditions, highlighting the relevance for practical application and research needs. Temperature, exposure time, initial concentration, and alkalizing agents were identified as key factors influencing the thermal stability of FFA in high temperature power plant water. Organic acids are found in concentrations harmless to metal tubes. Advanced scientific background information and additional research are required on this topic. [ABSTRACT FROM AUTHOR]

Published

2024

245. A Technical and Economic Feasibility Study for on-Grid Solar PV in Libya.

Author

Elmnifi, Monaem, Mhmood, Ali H., Abdullah Saieed, Ali Najim, Alturaihi, Muna Hameed, Ayed, Sadoon K., and Majdi, Hasan Shakir

Subjects

RENEWABLE energy sources, PHOTOVOLTAIC power systems, CARBON emissions, POWER plants, ALTERNATIVE fuels, CITIES & towns, SINGLE family housing

Abstract

In this research, the technical, economic and environmental feasibility of a gridconnected solar photovoltaic (PV) system for a single-family residential home in several Libyan cities with separate locations was studied. In Libya, the rate of electricity consumption is the largest in the domestic sector, with 60% of the total electricity consumption. Due to the frequent power outages in Libya, and the dependence of power generation mainly on traditional sources, pollution problems, and energy alternatives are an important priority. To overcome these problems, we propose maximizing the exploitation of renewable energy sources for energy production. In this paper, the HOMER Pro Renewable Energy Modeling Software was used to conduct a technical evaluation of a grid-connected solar PV system's economic viability, where the design was proposed for a residential house for six Libyan cities. The size of the PV system for a residential home is estimated at 15 kW. The findings indicated that the suggested design could supply 85% of the household's electrical requirements. AlKufra was the best location in terms of economics and the environment for a grid plus PV system, as the initial cost of the system was $9,570, the Cost of Energy (COE) was $0.0314, and the carbon dioxide emissions were 56,982 kg/year. Overall, lower prices for PV modules and PV components combined with long life, less maintenance needs, and minimum parity near the grid. The results show that PV systems connected to the residential grid are an effective energy management option in most Libyan cities. [ABSTRACT FROM AUTHOR]

Published

2024

246. Economic Dispatch between Distribution Grids and Virtual Power Plants under Voltage Security Constraints.

Author

Yang, Tiankai, Wang, Jixiang, Liang, Yongliang, Xiang, Chuan, and Wang, Chao

Subjects

ELECTRIC power distribution grids, POWER plants, ELECTRICAL load, VOLTAGE, ECONOMIC models

Abstract

Due to the high penetration of virtual power plants (VPPs), the bi-directional power flow between VPPs and active distribution grids makes the grid operation complex. Without congestion management, the operation schedule only considers the economic benefits, and power flow constraints might be violated. Hence, it is necessary to conduct power interaction within the operation constraints. This paper proposes a coordinated economic dispatch method under voltage security constraints. The linear expressions were derived by simplifying the AC power flow equations to reduce the computation complicity. Then, optimal economic dispatch models with voltage security constraints were established for the active distribution grid and VPPs, respectively. Meanwhile, the transacted power and clearing price were set as the communication variables, and a coordinated strategy was proposed for the overall optimal goal. The modified IEEE 33-node and PG&E-node distribution grids were utilized for the simulations, and the results affirmed the validity of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2024

247. Self-Unit Commitment of Combined-Cycle Units with Real Operational Constraints.

Author

González-Sierra, Mauro and Wogrin, Sonja

Subjects

COMBINED cycle power plants, GAS turbine combustion, POWER plants, INDEPENDENT system operators, GAS turbines, STEAM-turbines, GAS distribution, BUSINESS hours

Abstract

This paper highlights the importance of accurately modeling the operational constraints of Combined-Cycle Gas Turbines (CCGTs) within a unit-commitment framework. In practice, in Colombia, when given an initial dispatch by the Independent System Operator, CCGT plants are operated according to the results of heuristic simulation codes. Such heuristics often omit technical operating constraints, including hot, warm, or cold startup ramps; the minimum operation hours required for a gas turbine to start a steam turbine; the relationship between the dispatched number of steam and gas turbines; the load distribution among gas turbines; and supplementary fires. Most unit-commitment models in the literature represent standard technical constraints like startup, shutdown, up/down ramps, and in some cases, supplementary fires. However, they typically overlook other real-life CCGT operating constraints, which were considered in this work. These constraints are crucial in integrated energy systems to avoid equipment damage, which can potentially put CCGT plants out of service and ultimately lead to lower operating costs. [ABSTRACT FROM AUTHOR]

Published

2024

248. Detecting broken receiver tubes in CSP plants using intelligent sampling and dual loss.

Author

Pérez-Cutiño, M. A., Valverde, J., and Díaz-Báñez, J. M

Subjects

BOOSTING algorithms, MACHINE learning, PARABOLIC troughs, SOLAR power plants, SOLAR energy, TUBES, ALTERNATIVE fuels, POWER plants

Abstract

Concentrated solar power (CSP) is one of the growing technologies that is leading the process of change from fossil fuels to renewable energies for electricity production. The sophistication and size of the systems require an increase in maintenance tasks to ensure reliability, availability, maintainability, and safety. Currently, automatic detection of broken glass envelopes of receiver tubes in CSP plants using parabolic trough collector systems has two main drawbacks: 1) the devices in use need to be manually placed near the receiver tube, 2) the machine learning–based solutions have only been tested in constrained environments. We address both gaps by combining the data collected by an unmanned aerial vehicle with data provided by sensors placed within 7 real CSP plants. The resulting dataset is the first of this type and can help standardize research activities for the problem of fault detection in this type of power plant. Our work proposes supervised machine-learning algorithms for detecting broken envelopes of the receiver tubes in CSP plants. The proposed solution takes the class imbalance problem into account, boosting the accuracy of the algorithms for the minority class without harming the overall performance of the models. For a deep residual network, we solve an imbalance and a balance problem at the same time, which increases the recall of the minority class by 5% with no harm to the F1 score. Additionally, the random under-sampling technique boosts the performance of traditional machine learning models. The histogram gradient boost classifier was found to be the algorithm with the highest increase (3%) in the F1 score. To the best of our knowledge, this paper is the first to provide an automated solution to this problem using data from operating plants, drones, and highly unbalanced datasets. [ABSTRACT FROM AUTHOR]

Published

2023

249. Optimal combined wake and active power control of large‐scale wind farm considering available power.

Author

Chen, Weimin, Wang, Pengda, Huang, Sheng, Huang, Lingxiang, Tang, Wenbo, and Wu, Qiuwei

Subjects

INDEPENDENT system operators, WIND speed, WIND power plants, WIND turbines, POWER plants

Abstract

The high‐order nonlinear complex characteristics of traditional static wake model (SWM) restrict the fast optimization of wake effect. Therefore, this paper introduces a dynamic wake model (DWM) to describe the time‐varying wake characteristics of wind turbines (WTs) with low computational cost. The traditional SWM is linearized to derive the wake wind speed sensitivity coefficients, which represents the sensitivity of wake wind speed deficit with respect to the active power reference. Considering the natural propagation characteristics of wake effect, a wake delay function is added to realize the future wind speed prediction of different locations of the wind farm. And a joint control strategy of wake and active power based on model predictive control (MPC) is proposed to optimize the power contribution of each WT to minimize wake effects, and maximize total available power. Thus, the increased available power is able to satisfy the power demand from Transmission System Operator (TSO) for ancillary services and enhance power support capability. The control performance of the proposed control strategy is evaluated by simulations under constant and varying incoming wind speed. [ABSTRACT FROM AUTHOR]

Published

2023

250. Formation mechanism of on-grid power tariff using game model of complete information.

Author

Li, Jiaojiao, Zhao, Linfeng, and Dong, Lihao

Subjects

*ELECTRICITY markets, *HYBRID power systems, *POWER plants, *MARKET power, *BIDDING strategies, *ELECTRICITY pricing

Abstract

The key to the reform of the power system is to design a fair bidding and trading system. Analyzing the transaction process of electricity price competition, suppressing market power and other unfavorable factors, and finding a perfect bidding system are the research goals of this paper. In order to study the competition in the power spot market and power contract market, this paper employs the game model of complete information and the game theory as a tool. The power spot market adopts the Market Clearing Price (MCP) settlement method, in which the power grid determines the maximal real-time price of the generator node as the MCP. The price is based on the three bidding strategy curves of the power plant. As a result, a Nash equilibrium of power plant revenue is formed. According to the Cournot model and Stackelberg model that analyze the power contract market, the long-term equilibrium price of Stackelberg model in the power contract market is higher than that of the perfectly competitive market and less than or equal to the output of perfect monopoly market. The long-term equilibrium price and output in the power contract market are both certain and stable. This paper has analyzed the static game of complete information in the power market and carried out practical application. The results show that the bidding strategies of power plants have a Nash equilibrium and they have an incentive to collude. The MCP mechanism cannot solve the problem of market power influence. The conclusion of the research provides a basis for the design of the power hybrid auction system. [ABSTRACT FROM AUTHOR]

Published

2023