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Добірка наукової літератури з теми "ENERGY STORAGE APPLICATIONS"

Автор: Grafiati
Опубліковано: 11 вересня 2023

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Статті в журналах з теми "ENERGY STORAGE APPLICATIONS"

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Niu, Jianna, George You Zhou, and Tong Wu. "Embedded Battery Energy Storage System for Diesel Engine Test Applications." International Journal of Materials, Mechanics and Manufacturing 3, no. 4 (2015): 294–98. http://dx.doi.org/10.7763/ijmmm.2015.v3.213.

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Azrul, Mohd. "Applications of Energy Storage Systems in Wind Based Power System." International Journal of Trend in Scientific Research and Development Volume-2, Issue-6 (October 31, 2018): 284–91. http://dx.doi.org/10.31142/ijtsrd18468.

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Schoenung, S. M., and C. Burns. "Utility energy storage applications studies." IEEE Transactions on Energy Conversion 11, no. 3 (1996): 658–65. http://dx.doi.org/10.1109/60.537039.

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Kousksou, T., P. Bruel, A. Jamil, T. El Rhafiki, and Y. Zeraouli. "Energy storage: Applications and challenges." Solar Energy Materials and Solar Cells 120 (January 2014): 59–80. http://dx.doi.org/10.1016/j.solmat.2013.08.015.

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Abbey, Chad, and Gza Joos. "Supercapacitor Energy Storage for Wind Energy Applications." IEEE Transactions on Industry Applications 43, no. 3 (2007): 769–76. http://dx.doi.org/10.1109/tia.2007.895768.

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USACHEVA, IRINA V., ELENA A. GLADKAYA, and SERGEY V. LANDIN. "HYBRID ENERGY STORAGE: PROBLEMS AND PROSPECTS OF ENERGY STORAGE TECHNOLOGIES." Scientific Works of the Free Economic Society of Russia 236, no. 4 (2022): 149–67. http://dx.doi.org/10.38197/2072-2060-2022-236-4-149-167.

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Анотація:
The ever-increasing trend of renewable energy sources (RES) in energy systems of various levels has increased uncertainty in their operation and management. The vulnerability of RES to unforeseen changes in meteorological conditions requires additional resources to support, which are energy storage systems (ESS). However, existing ETSs have limited capacity to meet all the requirements of a modern enterprise energy system. Thus, the hybridization of multiple ETSs to form a composite ETS is a potential solution to this problem. As a flexible energy source, energy storage has many potential applications for integration into renewable energy generation, transmission and distribution networks. This paper analyzes the prospects for hybrid energy storage applications and summarizes the latest experience in terms of the maturity of these technologies, efficiency, scale, lifetime, cost and applications, taking into account their impact on the entire power system, including generation, transmission, distribution and utilization. The challenges of large-scale applications of energy storage in power systems are presented in terms of technical and economic considerations.
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Çakır, Abdülkadir, and Ertuğrul Furkan Kurmuş. "Energy storage technologies for building applications." Heritage and Sustainable Development 1, no. 1 (December 23, 2019): 41–47. http://dx.doi.org/10.37868/hsd.v1i1.10.

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Анотація:
Energy generated from renewable sources is not available at any time or any location. To make this available at any time, energy storage plays an important role. Many energy storage systems have been developed but none of them has exactly the features needed by all applications. A single energy storage technique is not always suitable for every application. This study investigated energy storage and energy main storage methods include mechanical energy storage, thermal energy storage, magnetic energy storage, fuel cells and hydrogen storage as well as batteries. In terms of buildings, proper orienteation combined with a storage methos will increase efficiency of strage technology, which requires a preliminarily study and cost analysis.
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Du, Yining, Mingyang Wang, Xiaoling Ye, Benqing Liu, Lei Han, Syed Hassan Mujtaba Jafri, Wencheng Liu, Xiaoxiao Zheng, Yafei Ning, and Hu Li. "Advances in the Field of Graphene-Based Composites for Energy–Storage Applications." Crystals 13, no. 6 (June 4, 2023): 912. http://dx.doi.org/10.3390/cryst13060912.

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To meet the growing demand in energy, great efforts have been devoted to improving the performances of energy–storages. Graphene, a remarkable two-dimensional (2D) material, holds immense potential for improving energy–storage performance owing to its exceptional properties, such as a large-specific surface area, remarkable thermal conductivity, excellent mechanical strength, and high-electronic mobility. This review provides a comprehensive summary of recent research advancements in the application of graphene for energy–storage. Initially, the fundamental properties of graphene are introduced. Subsequently, the latest developments in graphene-based energy–storage, encompassing lithium-ion batteries, sodium-ion batteries, supercapacitors, potassium-ion batteries and aluminum-ion batteries, are summarized. Finally, the challenges associated with graphene-based energy–storage applications are discussed, and the development prospects for this field are outlined.
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Bocklisch, Thilo. "Hybrid energy storage approach for renewable energy applications." Journal of Energy Storage 8 (November 2016): 311–19. http://dx.doi.org/10.1016/j.est.2016.01.004.

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Bocklisch, Thilo. "Hybrid Energy Storage Systems for Renewable Energy Applications." Energy Procedia 73 (June 2015): 103–11. http://dx.doi.org/10.1016/j.egypro.2015.07.582.

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Дисертації з теми "ENERGY STORAGE APPLICATIONS"

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Rowlands, Stephen E. "Electrochemical supercapacitors for energy storage applications." Thesis, De Montfort University, 2002. http://hdl.handle.net/2086/4077.

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Du, Yanping. "Cold energy storage : fundamentals and applications." Thesis, University of Leeds, 2014. http://etheses.whiterose.ac.uk/8622/.

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Анотація:
This thesis concerns cold energy storage (CES) technology. Such a technology produces cold energy by consuming electricity in a refrigerator and stores cold energy in an eutectic phase change material (PCM) in a temperature range of (TPCM is the PCM storage temperature and Ta is the environmental temperature), resulting in a cold exergy efficiency less than 100%. The stored cold energy can be either directly extracted by a cold discharge process or utilized through a Rankine cycle at peak hours for electricity generation. The aim of the research is to study fundamental aspects and address the scientific and technological challenges associated with the CES technology. Methods for storing high grade, high energy density and temperature-adaptive cold energy are to be developed. Another objective is to develop innovative solutions for enhancing charge/ discharge processes. Particular attention is paid to the use of a prototype CO2 based CES system to investigate the feasibility of CES technology for small scale systems. In this work, a criteria for PCM selection for high grade and high energy density cold storage is established. For enhancing charging/ discharging rate of a PCM device, metal foams are embedded in PCM to form a PCM composite. Parametric study on the CES system is done based on a CO2 Rankine cycle for achieving an optimal cold storage efficiency. Investigations have been carried out on the performance of a small scale CES system. These include CES with an open and a close Rankine cycle and a piston based engine for cold to power conversion in the cycle. A method for improving grade of stored cold energy is using eutectic salt-water solutions for forming a binary/ ternary cold storage system, by which the eutectic temperature is lowered. PCMs with lower freezing temperature and smaller molecular weight are selected as components in the binary/ ternary system. However, due to the potential issue of compatibility of PCM molecular structures, it is critical to select PCMs which have comparable melting temperatures and compatible molecular structures. PCM composite is formed by embedding metal foams in PCM solutions. Cold discharging rate, defined as the power transfer of cold energy per unit time during the discharge process, is greatly affected by thermal diffusivity and thermal conductivity of the PCM composite. Combined effect of cold radiation and convection is to be considered for assessing the value of cold discharging rate, which becomes more significant for large PCM capsules under low PCM temperatures and low Reynolds number (Re). Cold utilisation in a CES system using Rankine cycles is theoretically studied. Storage efficiency of the CES system is a round trip efficiency of electricity, which is defined as ratio of output electricity to the input electricity. A storage efficiency as high as 43.9% has been shown to be possible for the CES system. However, the storage efficiency is generally between 30%~40% in consideration of the actual efficiencies of cryogen pump, regenerator, engine and refrigerator. Piston based engines with a new valve scheme is experimentally investigated. Compared with small engine, large engine system has apparently larger capacity for power generation, but the engine efficiency is reduced due to the block of the exhaust gas in the chamber. In the presented case study, the efficiency of the large engine is 38.5% while the storage efficiency of the CES system is approximately 22.0%. In the point view of net electricity output for peak-shifting, CES is a feasible technology that need to be further developed. In brief, the work of the CES research are summarized as follows: • Improvement of cold charging/ discharging rate by embedding open-cell metal foams in PCM; • Assessment of cold discharging rate by considering the combined effect of cold radiation and convection; • Optimization of cold storage efficiency by developing computer program based on sub-critical CO2 properties; • Cold to power conversion by using a piston based engine coupled with a new valve scheme.
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Yang, Hao. "Graphene-based Supercapacitors for Energy Storage Applications." The Ohio State University, 2013. http://rave.ohiolink.edu/etdc/view?acc_num=osu1376918924.

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Edwards, Jacob N. "Thermal energy storage for nuclear power applications." Thesis, Kansas State University, 2017. http://hdl.handle.net/2097/36238.

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Анотація:
Master of Science
Department of Mechanical and Nuclear Engineering
Hitesh Bindra
Storing excess thermal energy in a storage media that can later be extracted during peak-load times is one of the better economical options for nuclear power in future. Thermal energy storage integration with light water-cooled and advanced nuclear power plants is analyzed to assess technical feasibility of different storage media options. Various choices are considered in this study; molten salts, synthetic heat transfer fluids, and packed beds of solid rocks or ceramics. In-depth quantitative assessment of these integration possibilities are then analyzed using exergy analysis and energy density models. The exergy efficiency of thermal energy storage systems is quantified based on second law thermodynamics. The packed bed of solid rocks is identified as one of the only options which can be integrated with upcoming small modular reactors. Directly storing thermal energy from saturated steam into packed bed of rocks is a very complex physical process due to phase transformation, two phase flow in irregular geometries and percolating irregular condensate flow. In order to examine the integrated physical aspects of this process, the energy transport during direct steam injection and condensation in the dry cold randomly packed bed of spherical alumina particles was experimentally and theoretically studied. This experimental setup ensures controlled condensation process without introducing significant changes in the thermal state or material characteristics of heat sink. Steam fronts at different flow rates were introduced in a cylindrical packed bed and thermal response of the media was observed. The governing heat transfer modes in the media are completely dependent upon the rate of steam injection into the system. A distinct differentiation between the effects of heat conduction and advection in the bed were observed with slower steam injection rates. A phenomenological semi-analytical model is developed for predicting quantitative thermal behavior of the packed bed and understanding physics. The semi-analytical model results are compared with the experimental data for the validation purposes. The steam condensation process in packed beds is very stable under all circumstances and there is no effect of flow fluctuations on thermal stratification in packed beds. With these experimental and analytical studies, it can be concluded that packed beds have potential for thermal storage applications with steam as heat transfer fluid. The stable stratification and condensation process in packed beds led to design of a novel passive safety heat removal system for advanced boiling water reactors.
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Nagar, Bhawna. "Printed Graphene for energy storage and sensing applications." Doctoral thesis, Universitat Autònoma de Barcelona, 2019. http://hdl.handle.net/10803/667240.

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El objetivo de esta tesis ha sido el diseño y la preparación de electrodos flexibles basados en grafeno utilizando diferentes técnicas de impresión para aplicaciones de almacenamiento de energía, específicamente supercondensadores y sensores electroquímicos. Se han empleado diferentes estrategias teniendo en cuenta la aplicación final y, por consiguiente, el grafeno o sus híbridos se prepararon utilizando diferentes rutas sintéticas junto con una selección cuidadosa de las técnicas de impresión disponible, así como los sustratos. Para la parte de almacenamiento de energía (Capítulo 2), se han demostrado dispositivos de tipo supercondensador con alta capacidad, energía y densidad de potencia sobre tela (tela de carbono), papel (papel A4 común) y sustratos plásticos utilizando diferentes técnicas de impresión, híbridos de grafeno y electrolitos híbridos. En el caso de las aplicaciones de sensores (Capítulo 3), se han demostrado dos sensores sobre sustratos plásticos. Se muestra un (bio)sensor de ADN de alta sensibilidad para virus que utiliza la impresión fácil en un solo paso, y cuyo principio de operación y estructura se pueden extender a otros bioanalitos con interés para aplicaciones en diversas áreas. En otro estudio, se preparó una tinta inyectable de grafeno muy estable y de muy alta concentración y se demostró su uso como sensor bacteriano como prueba de concepto. La tinta de grafeno preparada podría producir impresiones altamente conductoras que, en principio, pueden ser aplicables a otros sensores bio- o químicos con alta sensibilidad. Se llevaron a cabo estudios de diferentes técnicas de impresión y se formularon y probaron las tintas adecuadas para cada técnica con la optimización de los parámetros de impresión para obtener películas reproducibles y, por lo tanto, la fabricación del dispositivo reproducible ha sido el objetivo final. Las principales técnicas de impresión / recubrimiento utilizadas en esta Tesis son el recubrimiento tipo Doctor blade, la impresión por chorro de tinta (inkjet), la serigrafía (screen printing y la novedosa técnica de estampado con cera. El proyecto implicó, por lo tanto, una parte muy importante de síntesis y caracterización del grafeno y derivados, la formulación de tintas y, finalmente, la integración y ensayo de dispositivos.
The focus of this thesis has been the design and preparation of flexible graphene-based electrodesand their printing using different techniques for applications in energy storage, specifically supercapacitors and electrochemical sensing devices. Different strategies have been employed keeping in mind the end application and accordingly graphene or its hybrids wereprepared using different synthetic routes along with careful selection of the available printing techniques as well as the substrates. For energy storage part(Chapter 2), Supercapacitor devices with high capacitances, energy and power density have been demonstrated over Cloth (Carbon), Paper (Common A4 paper) and Plastic substrates using different printing techniques, graphene hybrids as well as hybrid electrolytes. In the case of Sensing applications(Chapter 3),two sensors have been demonstrated over plastic substrates. A high sensitivity DNA (Bio)sensor for viruses using one step facile printing is shown, which structure and operation principle can be extended to other bio-analytes with interest for applications in various areas. In another study, extremely high concentration yet stable graphene inkjet printable ink has been prepared and its use as a bacterial sensor has been demonstrated as a proof of concept. The graphene ink prepared could produce highly conducting patterns that in principle can offer other bio or chemical sensing with high sensitivities. Studies of different printing techniques were carried out and suitable inks were formulated and tested for each technique with optimization of the printing parameters in order to obtain reproducible films and hence reproducible device fabrication has been the focus. The main printing/coating techniques used in this Thesis are Doctor blade coating, Inkjet printing, screen printing and wax stamping technique. The project therefore involved a very important part of synthesis and characterization of graphene and derivatives, formulation of inks and finally device integration and testing
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Mangu, Raghu. "NANOSTRUCTURED ARRAYS FOR SENSING AND ENERGY STORAGE APPLICATIONS." UKnowledge, 2011. http://uknowledge.uky.edu/gradschool_diss/207.

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Vertically aligned multi walled carbon nanotube (MWCNT) arrays fabricated by xylene pyrolysis in anodized aluminum oxide (AAO) templates without the use of a catalyst, were integrated into a resistive sensor design. The steady state sensitivities as high as 5% and 10% for 100 ppm of NH3 and NO2 respectively at a flow rate of 750 sccm were observed. A study was undertaken to elucidate (i) the dependence of sensitivity on the thickness of amorphous carbon layers, (ii) the effect of UV light on gas desorption characteristics and (iii) the dependence of room temperature sensitivity on different NH3 and NO2 flow rates. An equivalent circuit model was developed to understand the operation and propose design changes for increased sensitivity. Multi Walled Carbon NanoTubes (MWCNTs) – Polymer composite based hybrid sensors were fabricated and integrated into a resistive sensor design for gas sensing applications. Thin films of MWCNTs were grown onto Si/SiO2 substrates via xylene pyrolysis using chemical vapor deposition technique. Polymers like PEDOT:PSS and Polyaniline (PANI) mixed with various solvents like DMSO, DMF, 2-Propanol and Ethylene Glycol were used to synthesize the composite films. These sensors exhibited excellent response and selectivity at room temperature when exposed to low concentrations (100ppm) of gases like NH3 and NO2. Effect of various solvents on the sensor response imparting selectivity to CNT – Polymer nanocomposites was investigated extensively. Sensitivities as high as 28% was observed for a MWCNT – PEDOT:PSS composite sensor when exposed to 100ppm of NH3 and -29.8% sensitivity for a MWCNT-PANI composite sensor to 100ppm of NO2. A novel nanostructured electrode design for Li based batteries and electrochemical capacitor applications was developed and tested. High density and highly aligned metal oxide nanowire arrays were fabricated via template assisted electrochemical deposition. Nickel and Molybdenum nanowires fabricated via cathodic deposition process were converted into respective oxides via thermal treatments and were evaluated as electrodes for batteries and capacitor applications via Cyclic Voltammetery (CV). Several chemical baths were formulated for the deposition of pristine molybdenum nanowires. Superior electrochemical performance of metal (Ni and Mo) oxide nanowires was observed in comparison to the previously reported nano-particle based electrodes.
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Parra, Mendoza David. "Optimum community energy storage for end user applications." Thesis, University of Nottingham, 2014. http://eprints.nottingham.ac.uk/27708/.

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Анотація:
The UK government determined that 30% of the total electricity and 15% of the total energy should be generated from renewable sources by 2020 according to the Low Carbon Transition Plan. However, most renewable energy technologies are intermittent because they depend on weather conditions and they do not offer matching capability. Energy storage is attracting intensive attention as a technology which converts renewable energy technologies into a dispatchable product which meets variable demand loads. There is increasing interest for energy storage located very close to consumers which is able to augment the amount of local renewable generation consumed on site, provides demand side flexibility and helps to decarbonise the heating sector. This thesis optimises community energy storage (CES) for end user applications including battery, hydrogen and thermal storage performing PV energy time-shift, load shifting and the combination of them. The optimisation method obtains the economic benefits of CES by quantifying the levelised cost, levelised value and internal rate of return. The method follows a community approach and the optimum CES system was calculated as a function of the size of the community, from a single home to a 100-home community. A complimentary methodology was developed including three reference years (2012, 2020 and zero carbon year) to show the evolution of the economic benefits during the low carbon transition. Additionally, a sensitivity analysis including the key parameters which affect the performance and the economic benefits was developed. The community approach reduced the levelised cost down to 0.30 £/kWh and 0.14 £/kWh for PV energy time shift and load shifting respectively when projected to the year 2020. These values meant a cost reduction by 37% and 55% regarding a single home. A cost of the storage medium of 275 £/kWh for Li-ion batteries (equivalent to a 10% subsidy over the assumed cost, 310 £/kWh) is the break-even point for Li-ion batteries by 2020 for an electricity price equal to 16.3 p/kWh (R^2=0.6). Secondly, this thesis presents a new community hydrogen storage system integrated in a low carbon community and the experimental results when performing PV energy time-shift, load shifting and the combination of them. Long term ES was demonstrated when the community storage hydrogen system performed load shifting and the capacity factor of the electrolyser increased by 116% when PV energy time-shift was performed in addition to load shifting. This system was designed in collaboration with industrial partners and the key findings obtained during the construction and testing phases are shared.
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Roberts, Aled Deakin. "Ice-templated porous carbons for energy storage applications." Thesis, University of Liverpool, 2016. http://livrepository.liverpool.ac.uk/3006170/.

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Анотація:
Porous carbons prepared via templating methodologies have shown excellent performance for various energy storage applications, such as electrodes in batteries, supercapacitors and as gas storage materials. Despite the impressive performances often reported, various issues such as complex and multi-step synthesis strategies have impeded their implementation in practical devices, and so there is a need to develop new, low-cost and commercially viable strategies for their fabrication. This thesis explores an unconventional method for the preparation of templated carbons - a process termed ice-templating. Ice-templating, as will be discussed in the forthcoming chapters, is a relatively simple technique holds several advantages over more conventional templating strategies. Having its own difficulties and shortcomings, only a few papers had been published on ice-templated porous carbons (ITPCs) prior to the commencement of this PhD. This thesis describes the ways in which we explored and overcame these difficulties to successfully prepare a number of ice-templated porous carbons, before evaluating their performance as materials for various energy storage devices.
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Mistry, Priyen C. "Coated metal hydrides for stationary energy storage applications." Thesis, University of Nottingham, 2016. http://eprints.nottingham.ac.uk/38798/.

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This thesis explores suitable materials for energy stores for stationary applications, specifically a prototype hydrogen store, domestic thermal store operating between 25-100 C and a moderate thermal store for a concentrated solar power (CSP) plant operating at 400 C. The approach incorporated a unique coating technique to deliver prototype hydrogen and thermal storage media, where the coating could offer commercial advantages, for example, in the form of hydride activation and enhanced kinetics during successive cycling. The highly reversible Mg-MgH2 system is particularly promising for thermal storage, obtaining an enthalpy of reaction of 74.5 kJ/mol H2 that translates to a thermal energy capacity of approximately 2800 kJ/kg of MgH2. Nevertheless, magnesium is hindered by slow activation and poor kinetics of (de)hydrogenation, even when approaching temperatures ideal for concentrated solar power applications (in the region 400 C). Elevated temperature cycling studies were performed on commercial atomised Mg powder with magnetron sputtered catalysts (chromium, iron, vanadium and stainless steel) applied to their surfaces; the aim of which was to fabricate hydrogen storage materials that possess (de)hydrogenation characteristics equal to or even bettering their nanocrystalline equivalents, yet in a potentially economic and scalable manner. Following 50 cycles at 400 C, the coatings were found to have little to no positive impact on the behaviour of the atomised Mg powders. In addition, for both uncoated and coated samples the effects of an activation process at 400 C are matched by cycling the material 5 times from the outset, after which identical behaviour is observed during subsequent cycles. At 350 C, the benefits of catalyst coatings on the hydrogen storage properties of atomised Mg powders are evident during activation and successive cycling up to 90 times. The material undergoes different microstructural evolution during cycling when in the presence of a surface catalyst, causing an enhancement of the `nucleation and growth' stage of (de)hydrogenation. This was attributed to particle reorientation dominating particle sintering, whereas the opposite occurs for the uncoated material. For the domestic thermal and prototype hydrogen stores a selection of AB and AB2 intermetallic hydrides enhanced through catalysis or thermodynamic modification were investigated. TiFe produced via powder atomisation obtained thermodynamic properties (dehydrogenation H = 28.9 kJ/mol H2 and S = 105 J/K.mol H2) in line with published results. The minor substitution of Ni into TiFe1-xNix resulted in different hydrogenation characteristics to TiFe, for example, TiFe0:96Ni0:04 possessed a dehydrogenation of H = 29.9 kJ/mol H2 and S = 107 J/K.mol H2. Discrepancies between maximum achieved and theoretical capacities were observed for both atomised TiFe and TiFe0:96Ni0:04 and a range of possible contributing factors are discussed. A minor addition of Pd (1.17 wt.%) magnetron sputtered to the surface of TiFe0:96Ni0:04 enabled successful room temperature hydrogenation with no activation treatment required. Characterisation (SEM and TEM) confirmed it is not necessary to have complete Pd coverage in the form of a uniform coating and XPS was utilised to derive a theory for the activation mechanism. The AB2 alloy comparison between the commercially available Hydralloy C5 and in house fabricated Ti0:9Zr0:2Mn1:5V0:2Cr0:3 showed that Hydralloy C5 was the most promising alloy for the hydrogen store application with the higher working capacity (ca. 0.96 wt.%) in the pressure range of 4-15 bar at 22 C, despite Ti0:9Zr0:2Mn1:5V0:2Cr0:3 obtaining a higher maximum storage capacity (1.82 wt.%). The hydrogenation kinetics of both alloys were studied with corresponding activation energies and hydrogen diffusion coefficients determined. The kinetics of hydrogenation for both alloys is sufficiently fast that only the heat transfer of the storage system is the rate limiting parameter for hydrogen exchange for most technical applications.
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Ek, Ludvig, and Tim Ottosson. "Optimization of energy storage use for solar applications." Thesis, Linköpings universitet, Elektroniska Kretsar och System, 2018. http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-149305.

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Анотація:
Energy storage systems is very useful to use in solar panel systems to save money, but also tobe more environment-friendly. The project was given by the solar energy companyPerpetuum Automobile (PPAM) and the project is for their customer, the condominiumcompound Ekoxen. The task is to make a energy regulation for Ekoxen's energy storage sothey can save more money. The energy storage primary task is to shave the top-peaks of theconsumption for Ekoxen. Which means that the battery will supply the household instead forthe three-phase grid. This will make the electric bill for Ekoxen cheaper. Thesimulation/analysis of the energy regulation is done in a spreadsheet tool, where one partworks as a Time-of-Use program and the other work as a modbus feature. Time-of-Use is aweb-based program for PV systems with battery storage, where time-periods can be set toaffect the battery behavior. The modbus feature simulates a system where an algorithm can beimplemented. The results will show that the time-periods for charging the battery with theTime-of-Use program needs to be changed two times per year. One time for the summermonths and a second time for the rest of the months. The results will also show that themodbus feature is better on peak shaving than the time-of-use program.
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Книги з теми "ENERGY STORAGE APPLICATIONS"

1

Nalwa, Hari Singh. Nanomaterials for energy storage applications. Stevenson Ranch, Calif: American Scientific Publishers, 2009.

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2

E, Pérez-Davis Marla, and NASA Glenn Research Center, eds. Energy storage for aerospace applications. [Cleveland, Ohio]: National Aeronautics and Space Administration, Glenn Research Center, 2001.

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3

Rosen, Marc (Marc A.), ed. Thermal energy storage: Systems and applications. 2nd ed. Hoboken, N.J: Wiley, 2010.

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4

Dinter, Frank, Michael A. Geyer, and Rainer Tamme, eds. Thermal Energy Storage for Commercial Applications. Berlin, Heidelberg: Springer Berlin Heidelberg, 1991. http://dx.doi.org/10.1007/978-3-642-48685-2.

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5

Balakrishnan, Neethu T. M., and Raghavan Prasanth, eds. Electrospinning for Advanced Energy Storage Applications. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-15-8844-0.

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6

Rowlands, S. E. Electrochemical supercapacitors for energy storage applications. Leicester: De Montfort University, 2002.

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7

Saxena, Amit, Bhaskar Bhattacharya, and Felipe Caballero-Briones. Applications of Nanomaterials for Energy Storage Devices. Boca Raton: CRC Press, 2022. http://dx.doi.org/10.1201/9781003216308.

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8

Olivier, David. Energy storage systems: Past, present and future applications. Barnet: Maclean Hunter Business Studies, 1989.

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9

Ikram, Muhammad, Ali Raza, and Salamat Ali. 2D-Materials for Energy Harvesting and Storage Applications. Cham: Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-030-96021-6.

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10

Stand-alone and hybrid wind energy systems: Technology, energy storage and applications. Boca Raton: CRC Press, 2010.

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Більше джерел

Частини книг з теми "ENERGY STORAGE APPLICATIONS"

1

Delamare, Jérôme, and Orphée Cugat. "Mobile Applications and Micro-Power Sources." In Energy Storage, 83–114. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2013. http://dx.doi.org/10.1002/9781118557808.ch4.

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2

Fleischer, Amy S. "Energy Storage Applications." In Thermal Energy Storage Using Phase Change Materials, 7–35. Cham: Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-20922-7_2.

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3

Wang, Zhaohui, and Leif Nyholm. "Energy Storage Applications." In Emerging Nanotechnologies in Nanocellulose, 237–65. Cham: Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-031-14043-3_8.

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Zaccagnini, Pietro, and Andrea Lamberti. "Energy Storage Applications." In High Resolution Manufacturing from 2D to 3D/4D Printing, 233–67. Cham: Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-031-13779-2_9.

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5

Dinçer, İbrahim, and Calin Zamfirescu. "Energy Storage." In Sustainable Energy Systems and Applications, 431–78. Boston, MA: Springer US, 2011. http://dx.doi.org/10.1007/978-0-387-95861-3_11.

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6

Barrade, Philippe. "Supercapacitors: Principles, Sizing, Power Interfaces and Applications." In Energy Storage, 217–41. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2013. http://dx.doi.org/10.1002/9781118557808.ch9.

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7

Huggins, Robert A. "Energy Storage for Medium- to Large-Scale Applications." In Energy Storage, 427–71. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-21239-5_22.

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8

Huggins, Robert A. "Energy Storage for Medium-to-Large Scale Applications." In Energy Storage, 367–82. Boston, MA: Springer US, 2010. http://dx.doi.org/10.1007/978-1-4419-1024-0_21.

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9

Tripathi, Manoj, Akanksha Verma, and Ashish Bhatnagar. "Energy Storage Application." In Nanotechnology for Electronic Applications, 49–62. Singapore: Springer Singapore, 2022. http://dx.doi.org/10.1007/978-981-16-6022-1_3.

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10

Ali, Hafiz Muhammad, Furqan Jamil, and Hamza Babar. "Energy Storage Materials in Thermal Storage Applications." In Thermal Energy Storage, 79–117. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-16-1131-5_5.

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Тези доповідей конференцій з теми "ENERGY STORAGE APPLICATIONS"

1

Oudalov, Alexandre, Tilo Buehler, and Daniel Chartouni. "Utility Scale Applications of Energy Storage." In 2008 IEEE Energy 2030 Conference (Energy). IEEE, 2008. http://dx.doi.org/10.1109/energy.2008.4780999.

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2

Divakar, B. P., K. W. E. Cheng, and D. Sutanto. "Understanding the conducting states of active and passive switches in an inverter circuit used for power system applications." In Energy Storage. IEEE, 2011. http://dx.doi.org/10.1109/pesa.2011.5982967.

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3

Vidhya, M. Sangeetha, G. Ravi, R. Yuvakkumar, P. Kumar, Dhayalan Velauthapillai, B. Saravanakumar, and E. Sunil Babu. "Cu2S electrochemical energy storage applications." In PROCEEDINGS OF ADVANCED MATERIAL, ENGINEERING & TECHNOLOGY. AIP Publishing, 2020. http://dx.doi.org/10.1063/5.0019377.

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4

"Energy storage systems in renewable energy applications." In 2016 IEEE International Conference on Industrial Technology (ICIT). IEEE, 2016. http://dx.doi.org/10.1109/icit.2016.7475056.

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5

Johnson, Anthony, Martin Dooley, Andrew G. Gibson, and S. M. Barrans. "Practical energy storage utilising Kinetic Energy Storage Batteries (KESB)." In 2012 2nd International Symposium on Environment-Friendly Energies and Applications (EFEA). IEEE, 2012. http://dx.doi.org/10.1109/efea.2012.6294076.

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6

Meddeb, Amira B., and Zoubeida Ounaies. "Polymer Nanocomposites for Energy Storage Applications." In ASME 2010 Conference on Smart Materials, Adaptive Structures and Intelligent Systems. ASMEDC, 2010. http://dx.doi.org/10.1115/smasis2010-3884.

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Анотація:
High dielectric polymer nanocomposites are promising candidates for energy storage applications. The main criteria of focus are high dielectric breakdown strength, high dielectric constant and low dielectric loss. In this study, we investigate the effect of the addition of TiO2 particles to PVDF matrix on the dielectric constant, breakdown and energy density of the system. The dispersion of the particles is qualified by scanning electron microscopy (SEM). The morphology of the composites is characterized by polarized light microscopy, Fourier transform infrared spectroscopy (FTIR) and differential scanning calorimetry (DSC). The dielectric properties are measured by a Novocontrol system with an Alpha analyzer. Finally, the breakdown measurements are carried out by a QuadTech hipot tester.
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7

Rao, V. Vasudeva, Shyamalendu M. Bose, S. N. Behera, and B. K. Roul. "Superconducting Magnetic Energy Storage and Applications." In MESOSCOPIC, NANOSCOPIC AND MACROSCOPIC MATERIALS: Proceedings of the International Workshop on Mesoscopic, Nanoscopic and Macroscopic Materials (IWMNMM-2008). AIP, 2008. http://dx.doi.org/10.1063/1.3027184.

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8

Tarrant, C. "Kinetic energy storage for railway applications." In IEE Recent Developments in Railway Electrification Seminar. IEE, 2004. http://dx.doi.org/10.1049/ic:20040044.

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9

Bahramirad, S., and W. Reder. "Islanding applications of energy storage system." In 2012 IEEE Power & Energy Society General Meeting. New Energy Horizons - Opportunities and Challenges. IEEE, 2012. http://dx.doi.org/10.1109/pesgm.2012.6345706.

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10

Tudor, Cody, Eric Sprung, Justin Meyer, and Russ Tatro. "Low power-energy storage system for energy harvesting applications." In 2013 IEEE 14th International Conference on Information Reuse & Integration (IRI). IEEE, 2013. http://dx.doi.org/10.1109/iri.2013.6642530.

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Звіти організацій з теми "ENERGY STORAGE APPLICATIONS"

1

Denholm, P., J. Jorgenson, M. Hummon, T. Jenkin, D. Palchak, B. Kirby, O. Ma, and M. O'Malley. Value of Energy Storage for Grid Applications. Office of Scientific and Technical Information (OSTI), May 2013. http://dx.doi.org/10.2172/1079719.

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2

Akhil, A. A., P. Butler, and T. C. Bickel. Battery energy storage and superconducting magnetic energy storage for utility applications: A qualitative analysis. Office of Scientific and Technical Information (OSTI), November 1993. http://dx.doi.org/10.2172/10115548.

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3

Swaminathan, S., and R. K. Sen. Electric utility applications of hydrogen energy storage systems. Office of Scientific and Technical Information (OSTI), October 1997. http://dx.doi.org/10.2172/674694.

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4

Denholm, Paul, Jennie Jorgenson, Marissa Hummon, Thomas Jenkin, David Palchak, Brendan Kirby, Ookie Ma, and Mark O'Malley. The Value of Energy Storage for Grid Applications. Office of Scientific and Technical Information (OSTI), May 2013. http://dx.doi.org/10.2172/1220050.

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5

Twitchell, Jeremy, Sarah Newman, Rebecca O'Neil, and Matthew McDonnell. Planning Considerations for Energy Storage in Resilience Applications. Office of Scientific and Technical Information (OSTI), March 2020. http://dx.doi.org/10.2172/1765370.

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6

Banerjee, Sanjoy. The CUNY Energy Institute Electrical Energy Storage Development for Grid Applications. Office of Scientific and Technical Information (OSTI), March 2013. http://dx.doi.org/10.2172/1111423.

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7

Swaminathan, S., and R. K. Sen. Review of power quality applications of energy storage systems. Office of Scientific and Technical Information (OSTI), May 1997. http://dx.doi.org/10.2172/661550.

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8

Tomlinson, J. J. (Thermal energy storage technologies for heating and cooling applications). Office of Scientific and Technical Information (OSTI), December 1990. http://dx.doi.org/10.2172/6285319.

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9

Gonzales, Ivana. Computational material design for energy and gas storage applications. Office of Scientific and Technical Information (OSTI), February 2013. http://dx.doi.org/10.2172/1063254.

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10

Babinec, Susan. Lithium Ion Cell Development for Photovoltaic Energy Storage Applications. Office of Scientific and Technical Information (OSTI), February 2012. http://dx.doi.org/10.2172/1064418.

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