M-ulti-objective operation strategy for a PV-integrated hybrid UPS-ESS using predictive heuristics and receding-horizon control-Seong-Soo Jeong-Department of Electrical and Computer Engineering The Graduate School Sungkyunkwan University

 

Abstract 

 A Multi-Objective Operation Strategy for a PV-Integrated Hybrid UPS–ESS using Predictive Heuristics and Receding-Horizon Control In recent industry, the adoption of renewable energy using photovoltaics (PV) has been promoted as part of efforts to address climate change. In precision manufacturing facilities, an uninterruptible power supply (UPS) is required to respond to momentary voltage sags and outages, and an energy storage system (ESS) is essential to compensate for the intermittent output of PV. Accordingly, this study investigates a multi-objective control strategy for a hybrid UPS–ESS (HUE) system integrated with PV. Short-term forecasts of load and PV generation are performed using a Long Short-Term Memory (LSTM) model. Based on these forecasts, the minimum state of charge (SOC) required to secure HUE reserve power and the target SOC for system operation are calculated at each time step. Subsequently, the weights of each objective function are derived using Multi-Criteria Decision Making (MCDM), and a real-time operation strategy is constructed by combining predictive heuristics and Receding-Horizon Control (RHC). The predictive heuristic determines charge and discharge actions under operational constraints, while RHC updates the control decision at each time step by incorporating both forecasted and actual values. The proposed control aims to maintain an adequate SOC headroom for UPS readiness, suppress grid peaks to reduce electricity costs, and limit unnecessary SOC fluctuations that accelerate battery degradation. Simulation results demonstrate that the proposed multi-objective operation strategy combining predictive heuristics and RHC outperforms the comparison scenarios in terms of SOC stability, grid operation reliability, and cost efficiency.

Development of Large-Scale Seawater Battery Cells for High Energy Density-저자 Youngjin Kim 발행사항 울산 : Ulsan National Institute of Science and Technology, 2023 학위논문사항 학위논문(박사) -- Ulsan National Institute of Science and Technology , Engineering Energy Engineering (Battery Science and Technology) , 2023

 

ABSTRACT Lithium-ion batteries (LIBs) are the most widely used rechargeable energy storage systems. However, the future expanding of the LIB technology is limited due to the high cost and scarcity of both core elements of lithium and cobalt. The use of cheap earth-abundant metals such as sodium, aluminum, potassium, calcium, and magnesium in their corresponding metal-based batteries which working on the same principle as LIBs, would greatly reduce the cost of battery technology. Nevertheless, despite the economic advantage of production process, the large-scale production of these metal-based batteries have been limited by their lower gravimetric and volumetric energy densities. Rechargeable seawater batteries (SWBs) are regarded as sustainable alternatives to Li-ion batteries due to the use of an unlimited and free source of Na ion active materials. Although many approaches including the introduction of new catalysts have successfully improved the performance of SWBs, reconsidering the cell design is an urgent requirement to improve the performance and scale up the production of practical batteries. In this study, by adjusting the maximum space efficiency, a rectangular cell is developed which due to its unique architecture, benefits from optimized contact to improve the overall charge transfer in the system. In view of the rigidity of the solid electrolyte, the novel cell model is intended to have adequate flexibility to be easily transported and practically utilized. At the same time as the development of the cell platform, energy efficiency was also improved by improving the materials and assembly methods for each part of the seawater battery, which will be an indicator for future battery development. Furthermore, the enhanced efficiency of the parallel stacked modules, indicates the capability of this cell in practical use. The seawater battery module was actually operated in the ocean to prove its potential, and an automated pilot design for uniform cell production was also carried out. The designed catalyst-free cell system shows a record capacity of 3.8 Ah (47.5 Ah kg−1), energy of 11 Wh (137.5 Wh kg−1), and peak power of 523 mW for individual unit cell, while it also retains performance up to 100 cycles. This design paves the way for commercializing rechargeable seawater batteries.

ORIGINAL LINK: 

https://www.riss.kr/search/detail/DetailView.do?p_mat_type=be54d9b8bc7cdb09&control_no=b3b401c8481ee0b7ffe0bdc3ef48d419&keyword=BATTERY%20%20UPS%20%20IN%20PARALLEL

Full-scale Shaking Table Test of Uninterruptible Power Supply Installed in 2-stories Steel Structure 2-층 철골 구조물에 설치된 무정전전원장치의 실규모 진동대 실험연구-Lee, Ji-Eon ; Park, Won-Il ; Choi, Kyoung-Kyu (Department of Architecture Engineering, Soongsil University) ; Oh, Sang-Hoon ; Park, Hoon-Yang)KOREA

 

Full-scale Shaking Table Test of Uninterruptible Power Supply Installed in 2-stories Steel Structure 2층 철골 구조물에 설치된 무정전전원장치의 실규모 진동대 실험연구 Lee, Ji-Eon ; Park, Won-Il ; Choi, Kyoung-Kyu (Department of Architecture Engineering, Soongsil University) ; Oh, Sang-Hoon ; Park, Hoon-Yang 

이지언 (숭실대학교 건축학부) ; 박원일 (숭실대학교 건축학부) ; 최경규 (숭실대학교 건축학부) ; 오상훈 (부산대학교 건축공학과) ; 박훈양 ((주) 에너테크 기술연구소 Korea Institute for Structural Maintenance Inspection (한국구조물진단유지관리공학회) 

 Abstract

 In this study, the shaking table tests were carried out on six types of non-structural elements installed on a full-scale two-story steel structure. The shaking table tests were performed for non-structural elements with and without seismic isolators. In this study, the seismic performance of Uninterruptible Power Supply (UPS) specimens was tested and investigated. Non-seismic details were composed of conventional channel section steel beams, and the seismic isolators were composed of high damping rubber bearing (HDRB) and wire isolator. The input acceleration time histories were artificially generated to satisfy the requirements proposed by the ICC-ES AC156 code. Based on the test results, the damage and dynamic characteristics of the UPS with the seismic isolator were investigated in terms of the natural frequency, damping ratio, acceleration time history responses, dynamic amplification factors, and relative displacements. The results from the shaking table showed that the dynamic characteristics of the UPS including the acceleration response were significantly improved when using the seismic isolator. 본 연구에서는 실규모의 2층 철골 구조물에 7종의 건축 및 비건축 비구조요소를 설치하여 진동대 실험을 수행하였다. 진동대 실험은 현행 비내진상세와 면진장치를 적용한 실험으로 두 차례 수행되었으며 본 연구에서는 무정전전원장치(UPS)의 내진성능에 대하여 실험 및 분석하였다. 비내진정착상세로는 UPS 하단에 ㄷ형강 다리부가 설치되었고, 면진장치로는 고감쇠고무와 와이어로프로 구성된 개발 복합면진장치가 사용되었다. 지진하중모사를 위하여 ICC-ES AC156 (2010)에 따라 인공지진파를 생성 후, 동일 지진파의 크기를 점증하여 가진하였다. 진동대실험을 통해 복합면진장치의 적용여부에 따른 UPS의 거동 및 동적 특성(응답가속도, 응답변위, 동증폭계수, 고유진동수, 감쇠비)을 비교 및 분석하였다. 실험결과, 복합면진장치를 적용함에 따라 UPS의 고유진동수가 감소하여 응답가속도 및 증폭계수가 크게 감소하는 것으로 확인되었다.

 ORIGINAL LINK KOREA:https://koreascience.kr/article/JAKO202220362436736.pub

ENGLISH TRANSLATED VERSION :

https://www.mediafire.com/file/w9fmh000y32rgny/Full-scale+Shaking+Table+Test+of+Uninterruptible+Power+Supply+Installed+in+2-stories+Steel+Structure.en.dual.pdf/file

TRANSLATED VERSION INTO PORTUGUESE:

https://www.mediafire.com/file/xc2aeuquo8ja1c7/Full-scale+Shaking+Table+Test+of+Uninterruptible+Power+Supply+Installed+in+2-stories+Steel+Structure.pt-BR.dual.pdf/file

A SYSTEM FOR STATE-OF-HEALTH DIAGNOSIS OF LEAD-ACID BATTERIES INTEGRATED WITH A BATTERY CHARGER Telles B. Lazzarin1 and Ivo Barbi2 1Federal Institute of Santa Catarina (IFSC), Florianópolis - SC, Brazil 2Federal University of Santa Catarina (UFSC), Florianópolis - SC, Brazil

 

A SYSTEM FOR STATE-OF-HEALTH DIAGNOSIS OF LEAD-ACID BATTERIES INTEGRATED WITH A BATTERY CHARGER 

Author Telles B. Lazzarin1 and Ivo Barbi

 Abstract – This paper reports a theoretical and experimental study on a proposal for a lead–acid battery charger applied in UPS, which has an integrated on-line test system to determine the state-of-health (SoH) of the batteries. The charger control structure is designed to ensure an appropriate charge for every battery in the pack. The battery evaluation system is based on historical analysis of the periodic measurements, such as internal impedance, DC voltage and operation temperature, performed for each battery. The periodic monitoring of these parameters provided by the integration of systems eliminates the disadvantages of online tests and thus allows the user to analyze the batteries adequately. The structure was experimentally verified on a prototype, where the battery SoH diagnosis system was integrated with a 1.5 kW battery charger. The system was designed for a bank of sixteen batteries associated in series.

LINK : https://journal.sobraep.org.br/index.php/rep/article/view/398/358

Comparative fire hazards of lithium-ion battery chemistries: Linking thermal behavior, gas toxicity, and state-of-charge to composite risk profiles Aamir Iqbal , Ashish Kakoria , Syed Talha Riaz , Jingmin Xu , Robert Illango Pushparaj , Guang Xu * Department of Mining and Explosives Engineering, Missouri University of Science and Technology, Rolla, MO, 65401, USA

 

ABSTRACT 

Lithium-ion batteries (LIB) are widely used in electric vehicles (EVs) for their high energy density. However, their fire safety causes concerns because of the toxic gases emission and the challenge to extinguish. The type and quantity of toxic gases released during battery fires remain among the least studied hazards, with limited data available despite their serious health risks. This study examines the thermal and gaseous emission behavior of LIB cells after thermal runaway (TR). Five cell types, Lithium Iron Phosphate (LFP), Lithium Titanate (LTO), and three Lithium Nickel Manganese Cobalt oxide (NMC). The three NMC variants share the same base formula (LiNiMnCoO2); NMC1 and NMC3 differ only by manufacturer, while NMC2 has added Ni and Co for enhanced performance. These cells were tested under controlled thermal abuse conditions using a Ni-Chrom resistance wire powered by a DC voltage regulator. Tests were conducted at five states of charge (0 %, 25 %, 50 %, 75 %, 100 % SOC). Temperature profiles and fire/explosion observations were recorded along with the ten types of gas release rates including Carbon Monoxide (CO), Methane (CH4), Carbon Dioxide (CO2), Ammonia (NH3), Ethene (C2H4), Propene(C3H6), Formaldehyde (CH2O), Acrolein (C3H4O), Hydrogen Cyanide (HCN) and Hydrogen Fluoride (HF). CO showed the highest levels of toxic emissions reaching 150–200 L/kWh. Peak emission rates were highest for CO2 across all chemistries. A quantitative risk assessment was performed by combining the measured factors into a risk index (RI). These data were visualized in a color-coded heat map, allowing comparison of overall hazard across chemistries and charge levels. Key contributions include the first systematic measurement of formaldehyde emissions during LIB fires and the introduction of a cell-level safety rating, an actionable safety tool. This study contributes to the understanding of gas emissions during LIB fire, and evaluates the risks related to the types of battery and SOC. 

 LINK:https://scholarsmine.mst.edu/cgi/viewcontent.cgi?article=3000&context=min_nuceng_facwork

Les nouvelles stratégies de contrôle d’onduleurs pour un système électrique 100% interfacé par électronique de puissance by Guillaume Denis-

 From grid-following to grid-forming: The new strategy to build 100 % power-electronics interfaced transmission system with enhanced transient behavior Les nouvelles stratégies de contrôle d’onduleurs pour un système électrique 100% interfacé par électronique de puissance 

 Thèse présentée en vue d’obtenir le grade de Docteur En Spécialité: Génie Électrique Par Guillaume Denis Doctorat délivré par Centrale Lille Résumé In the context of renewable energy and HVDC links development in power systems, the present work concerns the technical operations of such systems. As wind power, solar photovoltaics and HVDC links are interfaced to the transmission grid with power-electronics, can the system be operated in the extreme case where the load is fed only through static converters?Driving a power system only based on power electronic interfaced generation is a tremendous change of the power system paradigm that must be clearly understood by transmission grid operators. The traditional “grid-feeding” control strategy of inverters exhibits a stability limit when their proportion becomes too important. The inverter control strategy must be turned into a “parallel grid-forming” strategy.This thesis first analyses the power system needs, proposes the requirements for “parallel grid-forming” converters and describes the associated challenges. Accordingly, the thesis gives a method for designing a stable autonomous synchronization controls so that grid-forming sources can operate in parallel with a good level of reliability. Then, a method is proposed to design a voltage control for a grid-forming PWM source taking into account the limited dynamic of large converters. The robustness of the solution is discussed for different configuration of the grid topology. A current limiting strategy is presented to solve the current sensitivity issue of grid-forming converters, subject to different stressing events of the transmission grid. The ideas developed on a single converter are then applied on small grids with a limited number of converters to allow a physical interpretation on the simulation results.

VIEW FULL THESIS: https://hal.science/tel-01905827v1

Direct AC Voltage Control for Grid-Forming Inverters Taoufik Qorai , Chuanyue Li , Ko Oue , Francois Gruson , Fréderic Colas , Xavier Guillaud

Direct AC Voltage Control for Grid-Forming Inverters Taoufik Qorai (1) , Chuanyue Li (1) , Ko Oue (1) , Francois Gruson (1) , Fréderic Colas (1) , Xavier Guillaud (1) 

 Résumé 

 Grid-forming inverters usually use inner cascaded controllers to regulate output AC voltage and converter output current. However, at the power transmission system level where the power inverter bandwidth is limited, i.e., low switching frequency, it is difcult to tune controller parameters to achieve the desired performances because of control loop interactions. In this paper, a direct AC voltage control-based state-feedback control is applied. Its control gains are tuned using a linear quadratic regulator. In addition, a sensitivity analysis is proposed to choose the right cost factors that allow the system to achieve the imposed specifcations. Conventionally, a system based on direct AC voltage control has no restriction on the inverter current. Hence, in this paper, a threshold virtual impedance has been added to the state-feedback control in order to protect the inverter against overcurrent. The robustness of the proposed control is assessed for diferent short-circuit ratios using smallsignal stability analysis. Then, it is checked in diferent grid topologies using time domain simulations. An experimental test bench is developed in order to validate the proposed control.

FUL PAPER: https://hal.science/hal-02458108v1

Resilient microgrids with high dynamic stability in the presence of massive integration of variable renewables BY Kevin Banjar Nahor -THÈSE Pour obtenir le grade de DOCTEUR DE LA COMMUNAUTE UNIVERSITE GRENOBLE ALPES Spécialité : Génie Electrique

 

Resilient microgrids with high dynamic stability in the presence of massive integration of variable renewables Kevin Banjar Nahor 

Abstract This thesis deals with the stability issues introduced by the interconnection of massive renewables into an isolated microgrid. This research aims to identify the problems related to the topic, the indices to help understand the issues, and the strategy to enhance microgrid stability from the power system point of view.In the first part, a state of the art on the evolution of power stability is addressed. A short history of power system stability since its first identification and how it has evolved is firstly presented. This part also provides a literature review of the power system stability, including its classification, and how it has evolved due to two reasons: the microgrid concept and the trend towards the integration of more inverter-based generation. A review of the practical indices for grid stability assessment is also reported, including the ones that we propose. This part is also useful for analyzing the positioning of this PhD research.The second part of thesis presents the efforts to enhance the dynamic stability of microgrids characterized by massive renewable penetration. The main challenges and the current efforts are reviewed, which have shown that the current solutions focus on maintaining the philosophy of a classical power grid. With the advent of more intermittent energy, the current efforts have proven to be costly. Therefore, a new perspective is proposed. Here, the generating elements and the customers are exposed with higher deviations in voltage and frequency, which are necessary so that that the power equilibrium and the stability of the microgrid can be maintained. This perspective is suitable with the microgrid concept to realize the dream of universal electricity.The concept is then developed into a novel regulation strategy in which the system frequency and voltage are maintained in such a way to keep their ratio essentially constant around 1 (p.u. voltage to p.u. frequency). This strategy can potentially be implemented on all grid forming technologies. The benefits of employing this strategy include assurance that the electrical machinery is not harmed, plug-and-play feature, compatibility with current grid-tied inverter technologies, and no need for fast communication systems. Finally, this proposed strategy is easy to implement and does not require revolution in terms of power system equipment and control. This implementation of this concept provides a very valuable piece of flexibility: time, which enhances the resilience and stability of a microgrid. However, wider frequency and voltage deviations occur and have to be accepted by all the actors within the microgrid. A validation through computer simulations in Power Factory and real-time hardware in the loop experiments has been carried out with satisfactory results.

LINK FULL THESIS: https://hal.science/tel-03042626v1

Analysis and control of the stability of power systems with a high penetration of renewable energy BY Hung Cuong Nguyen-Pour obtenir le grade de DOCTEUR DE L’UNIVERSITÉ GRENOBLE ALPES École doctorale : EEATS - Electronique, Electrotechnique, Automatique, Traitement du Signal Spécialité : Génie électrique Unité de recherche : CEA - Laboratoire d'Innovation pour les Technologies des Energies Nouvelles et les Nanomatériaux

DOCTEUR DE L’UNIVERSITÉ GRENOBLE ALPES École doctorale : EEATS - Electronique, Electrotechnique, Automatique, Traitement du Signal Spécialité : Génie électrique Unité de recherche : CEA - Laboratoire d'Innovation pour les Technologies des Energies Nouvelles et les Nanomatériaux 

Analyse et contrôle de la stabilité des réseaux électriques à fort taux d'énergie renouvelable. Analysis and control of the stability of power systems with a high penetration of renewable energy. Présentée par : Hung Cuong NGUYEN

ABSTRACT In response to the challenges associated with the use of fossil fuels, there is a global energy transition towards renewable energy sources (RES), such as solar photovoltaic (PV) and wind energy, which offer cleaner and more sustainable alternatives. However, the variable nature of RES energy production, which depends on weather conditions, introduces intermittency and poses challenges for the reliability of power systems. Additionally, RES are typically connected to the grid through power electronic interfaces, which have low inertia compared to synchronous generators (SGs). These characteristics of RES negatively affect grid stability, influencing frequency, voltage, and rotor angle stability.Historically, stability studies focused on rotor angle stability and voltage stability in systems with rotating machines. With the integration of RES and power electronic inverters, and the consequent reduction in conventional synchronous generators, it has become necessary to perform more comprehensive studies, particularly on grids with high levels of RES penetration. Our thesis addresses this issue by using both static and dynamic analyses to assess grid stability, with a particular focus on frequency stability.The contributions of this thesis include the following:• State of the Art on the Impacts of RES on Stability: Analyzing how the lack of inertia and the intermittent nature of RES production lead to instability issues such as frequency, rotor angle, and voltage instability, and studying methods to enhance system stability.• Stability Analysis via Simulation: Using dynamic simulation methods to examine the impact of high RES penetration on overall grid stability, identifying the thresholds of RES integration beyond which grids become unstable.• Stochastic Simulations: Utilizing stochastic simulations to identify extreme scenarios that could lead to instability in power systems integrated with RES after disturbances, due to the intermittent nature of RES production.• Innovative Solutions: Proposing methods to stabilize power systems in critical scenarios, aiming for up to 100% RES integration while maintaining grid reliability. This includes the application of Fault Ride-Through (FRT) requirements and Energy Storage Systems (ESS).• Parameter Optimization: Using particle swarm optimization (PSO) to determine the optimal parameters for ESS controllers and Power System Stabilizers (PSS), thereby improving the quality and resilience of system responses.• Hybrid AC-DC Grids: Investigating the effects of hybrid AC-DC grids integrated with RES and proposing strategies to improve grid stability. This includes using HVDC-VSC technology as a firewall against disturbances and optimizing HVDC-VSC parameters to accommodate higher levels of RES penetration.

ORIGINAL LINK: https://theses.hal.science/tel-04998145v1