Relevant bibliographies by topics / Green Energy Storage

Academic literature on the topic 'Green Energy Storage'

Author: Grafiati
Published: 10 December 2022
Last updated: 28 January 2023

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Journal articles on the topic "Green Energy Storage"

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Kausar, Ayesha. "Green Nanocomposites for Energy Storage." Journal of Composites Science 5, no. 8 (August 2, 2021): 202. http://dx.doi.org/10.3390/jcs5080202.

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The green nanocomposites have elite features of sustainable polymers and eco-friendly nanofillers. The green or eco-friendly nanomaterials are low cost, lightweight, eco-friendly, and highly competent for the range of energy applications. This article initially expresses the notions of eco-polymers, eco-nanofillers, and green nanocomposites. Afterward, the energy-related applications of the green nanocomposites have been specified. The green nanocomposites have been used in various energy devices such as solar cells, batteries, light-emitting diodes, etc. The main focus of this artifact is the energy storage application of green nanocomposites. The capacitors have been recognized as corporate devices for energy storage, particularly electrical energy. In this regard, high-performance supercapacitors have been proposed based on sustainable nanocomposites. Consequently, this article presents various approaches providing key knowledge for the design and development of multi-functional energy storage materials. In addition, the future prospects of the green nanocomposites towards energy storage have been discussed.
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Żygadło, Monika, Jerzy Kotowski, and Jacek Oko. "Green computing and energy storage systems." E3S Web of Conferences 44 (2018): 00202. http://dx.doi.org/10.1051/e3sconf/20184400202.

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Because of growing amount of the data(known as „big data”) needed to be store and process there is a rapid growth of usage electricity and emission. In this paper we present the IT solution of this problem: green computing, solutions to storage and manage the energy and IT support needed to manage and control those systems. The article presents the main idea and already implemented solutions.
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Yang, Zhenguo, Jianlu Zhang, Michael C. W. Kintner-Meyer, Xiaochuan Lu, Daiwon Choi, John P. Lemmon, and Jun Liu. "Electrochemical Energy Storage for Green Grid." Chemical Reviews 111, no. 5 (May 11, 2011): 3577–613. http://dx.doi.org/10.1021/cr100290v.

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Margeta, Jure. "Water storage as energy storage in green power system." Sustainable Energy Technologies and Assessments 5 (March 2014): 75–83. http://dx.doi.org/10.1016/j.seta.2013.12.002.

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OTAKA, Toshio. "F102 STUDY OF A GREEN ROOF BUILDING AIR-CONDITIONING SYSTEM WITH THERMAL ENERGY STORAGE UNITS USING LIGHT WEIGHT SOIL : PERFORMANCES OF THERMAL ENERGY STORAGE UNITS(Energy Storage and Load Leveling)." Proceedings of the International Conference on Power Engineering (ICOPE) 2009.1 (2009): _1–299_—_1–303_. http://dx.doi.org/10.1299/jsmeicope.2009.1._1-299_.

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Giaccherini, Andrea, Ivan Colantoni, Francesco D'Acapito, Antonio De Luca, Ferdinando Capolupo, Giordano Montegrossi, Maurizio Romanelli, Massimo Innocenti, and Francesco Di Benedetto. "Green synthesis of pyrite nanoparticles for energy conversion and storage: a spectroscopic investigation." European Journal of Mineralogy 28, no. 3 (September 23, 2016): 611–18. http://dx.doi.org/10.1127/ejm/2016/0028-2534.

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Ibrahim, Abdelrahman M., Ahmed A. Zewail, and Aylin Yener. "Green Distributed Storage Using Energy Harvesting Nodes." IEEE Journal on Selected Areas in Communications 34, no. 5 (May 2016): 1590–603. http://dx.doi.org/10.1109/jsac.2016.2545538.

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Filote, Constantin, Raluca-Andreea Felseghi, Filip Cârlea, Mihai Raţă, Claudia Steluţa Martiş, Alexandru Lavric, Daniel Fodorean, and Maria Simona Răboacă. "Green Hybrid Energy for Office Building." E3S Web of Conferences 111 (2019): 04026. http://dx.doi.org/10.1051/e3sconf/201911104026.

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This contribution presents a comparative study of operating a green energy hybrid system to sustain the power production mix of an office building. For this purpose, two scenarios of a hydrogen storage system (S1) and battery energy storage (S2) to sustain solar and wind energy inlets were compared from a technical, environmental and financial perspectives. S1 - hydrogen technology system was found to be more performing than S2 - battery technology in terms of energy efficiency, as well as CO2 emissions and initial costs.
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Chen, Bin. "Nanomaterials for Green Energy: Next-Generation Energy Conversion and Storage." IEEE Nanotechnology Magazine 6, no. 3 (September 2012): 4–7. http://dx.doi.org/10.1109/mnano.2012.2203875.

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TUDORACHE, V., M. MINESCU, N. ILIAS, and I. OFFENBERG. "FROM NATURAL GAS TO GREEN HYDROGEN." Neft i gaz, no. 4 (August 30, 2021): 125. http://dx.doi.org/10.37878/2708-0080/2021-4.09.

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Since hydrogen usually exists on Earth as part of a compound, it has to be synthesized in specific processes in order to be used as a product or energy source. This can be achieved by different technical methods, and various primary energy sources, – both fossil and renewable fuels, in solid, liquid or gaseous form, – can be used in these technical production processes. Hydrogen has only a very low volumetric energy density, which means that it has to be compressed for storage and transportation purposes. The most important commercial storage method, – especially for end users, – is the storage of hydrogen as a compressed gas. A higher storage density can be achieved by hydrogen liquefaction. Novel materials-based storage media (metal hydrides, liquids or sorbents) are still at the research and development stage. The storage of hydrogen (for example, to compression or liquefaction) requires energy; work is, in present, on more efficient storage methods. Unlike electricity, hydrogen can be successfully stored in large amounts for extended periods of time. For example, in long-term underground storage facilities hydrogen can play an important role as a buffer store for electricity from surplus provided by renewable energies. At present, pure hydrogen is generally transported by lorry in pressurize gas containers, and in some cases also in cryogenic liquid tanks. Moreover, local/regional hydrogen pipeline networks are available in some locations. Another solution for storage and transportation are Liquid Organic Hydrogen Carriers (LOHC) that can use long pipe networks and ships. In the near future, the natural gas supply infrastructure or oil (transportation pipelines and underground storage facilities) could also be used, in specific conditions, for the storage and transportation of pure or blended hydrogen with methane. This could be essential for transition because most important primary energy source for hydrogen production currently is natural gas, at 71%, followed by oil, coal and electricity (as a secondary energy resource). Steam reforming (from natural gas) is the most commonly used method for hydrogen production. In this new light, the article explores the trend and prospects for hydrogen, presented in the literature, as a source of energy competing with gas and oil resources in the global energy system of the future.
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Dissertations / Theses on the topic "Green Energy Storage"

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Gebresilassie, Yosef. "Sizing and modeling a microgrid containing renewable energy production, energy storage, electrical vehicles and other green technologies." Thesis, KTH, Skolan för elektroteknik och datavetenskap (EECS), 2020. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-289328.

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Optimal design of a microgrid containing renewable energy sources in a residential sector is important to have a technical and economical feasible investment. In this project a microgrid (MG) for a house cooperative in Hudiksvall, Sweden has been studied. The aim of this study is to estimate how the electric vehicles (EVs) will aid the MG assuming different availabilities. Furthermore, this study aims to investigate optimal sizes of photovoltaic (PV) power and solar collectors for the households as well as possible energy storage capacity to increase the self-consumption. To study the role of the EVs in aiding the MG a simulation was carried in MATLAB/SIMULINK. To estimate the optimal sizes of the PV cells a life cycle cost assessment (LCCA) was carried out. The optimal output from the SC was estimated by using the f -chart method. The results from this study points out that a higher EV capacity will be required when the EVs are available for longer hours of the day, which is mainly due to the large share of PV power produced and the limited range of charging/discharging capacity of the EV battery. The LCCA shows that a high PV capacity will lead to a low net present value and a longer payback period. The sensitivity analysis which was carried out indicates that the PV system investment is mostly sensitive to the investment cost. The f -chart method gives the recommended values for SC output and an estimation of the thermal energy storage capacity.
Ett mikronät som innehåller olika förnyelsebara energikällor behöver designas optimalt för kunna ha en både ekonomisk och teknisk genomförbar investering. I detta projekt studerades ett mikronät för en bostadsförening i Hudiksvall. Syftet med detta projekt var att studera hur elbilar kommer att kunna försörja nätet vid olika tillgänglighetstider hos bilarna. Utöver det syftade det här projektet också på att uppskatta den optimala effekten på solceller och solfångare för bostadsföreningen samt möjligheterna för energilagring för att utöka konsumtionen av närproducerad el och värme. En simulering i MATLAB/SIMULINK utfördes för att studera elbilarnas roll i att försörja mikronätet. För att få en bild av den optimala effekten på solcellerna utfördes en livscykelkostandsanalys. Den optimala effekten för solfångarna har beräknats genom f -chart metoden. Resultaten från denna studie visar att högre batterikapacitet på elbilar kommer att krävas när elbilarna är kopplade till mikronätet för längre perioder. Detta beror på den höga effektproduktionen från solcellerna samt den begränsade nivån för laddning/urladdning av elbilarnas batteri. Livcykelkostnadsanalysen gav ett lägre nuvärde samt längre återbetalningsperioder då en högre kapacitet på solcellerna installerades. Känslighetsanalysen som utfördes visar att nuvärdet av investeringen är mest känslig för investeringskostnaden. Med f -chart metoden kunde slutsatser gällande optimal solfångare och termisk energilagring dras.
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Ezeigwe, Ejikeme Raphael. "Green synthesis of graphene-metal oxides composites as a promising electrode for energy storage." Thesis, University of Nottingham, 2018. http://eprints.nottingham.ac.uk/52517/.

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The key motivation of this study is to investigate the potential of graphene/metal oxides nanocomposites as electrodes for electrochemical capacitor applications. It is envisioned that the positive synergistic effect between graphene and metal oxides (where novel graphene material acts as a highly conductive platform for ease of ion transfer kinetics and metal oxide acts as spacers to avoid the restacking of graphene sheets to make available more active surface areas) results in excellent electrode material for high performance electrochemical capacitor. In this thesis, a series of hybrid composites comprising of graphene and low cost transition metal oxides were synthesised and characterised for their potential as electrode for electrochemical capacitor applications. In order to achieve this, the graphene used in the preparation of the hybrid composites was successfully synthesised from highly pyrolytic graphene in a proper ratio of ethanol and water before the integration of the metal oxides via a solvothermal route. A parametric study was carried out in a step by step approach to validate the success of the composite synthesis before the electrochemical stage. X-ray Diffraction, Field emission and Transmission scanning electron microscopy, energy-dispersive X-ray and Raman spectroscopy, cyclic voltammetry and galvanostatic charge/discharge tests were used to verify the integrity of the as-produced graphene/metal oxide composites and their applicability to electrochemical capacitors. Upon the completion of the experimental work, the electrochemical tests demonstrated that the introduction of graphene to the metal oxide improved the electrochemical performance in-terms of capacitance, energy density, power density, equivalent series resistance and cycling stability. The results also indicated that the ratio of graphene to metal-oxide plays a significant role in the electrochemical performance of the composite. In comparison with the different graphene/Zinc oxide (ZnO) nanocomposites studied, the electrode material with a weight ratio of 1:8 (graphene: ZnO) displayed a specific capacitance of 236 F/g at a scan rate of 10 mV/s with energy and power densities of 11.80 Wh/kg and 42.48 kW/kg respectively. The specific capacitance of the graphene-Manganese oxide (MnO2) composite electrode material with a weight ratio of 1:16 (graphene: MnO2) demonstrated the best performance of 380 F/g at a scan rate of 5 mV/s among the four ratios studied. The G1Co4 composite electrode with a weight ratio of 1:8 (graphene: Co3O4) demonstrated a superior specific capacitance of 384 F/g at a current density of 0.3 A/g coupled with retention of 80% of its capacitance after 1000 cycles among the graphene-cobalt composites. The Graphene-Nickel cobaltite composite electrode with weight ratio of 1:8 (graphene: NiCo2O4) labelled G-8NC2 displayed a superior specific capacitance (698 F/g at a current density of 0.5 A/g) and good cycling stability (74% capacity retention after 5000 cycles at current density of 1 A/g). The 1:8 ratio exhibited well attached Nickel molybdate nanorods on the surface and edges of the graphene sheets with the highest specific capacitance of 670 F/g at 0.3 A/g, as compared to other tested composites. The significance of these findings details a synthesis route that provides an effective, simple and practical method of preparing graphene-metal oxide composite materials for electrochemical capacitor applications.
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Yu, Candice Yau May. "Modeling the heating of the Green Energy Lab in Shanghai by the geothermal heat pump combined with the solar thermal energy and ground energy storage." Thesis, Norges teknisk-naturvitenskapelige universitet, Institutt for energi- og prosessteknikk, 2012. http://urn.kb.se/resolve?urn=urn:nbn:no:ntnu:diva-19280.

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This work involves the study of heating systems that combine solar collectors, geothermal heat pumps and thermal energy storage in the ground. Solar collectors can reduce the electricity use in these systems by reducing the operation time of the geothermal heat pump and by increasing the ground source temperature. These systems can be designed in many ways, consequently the complexity is high. The purpose of this study has been to develop simulation models to study the behavior of these systems, with emphasis on the thermal energy storage in the ground. A simulation tool with several models has been developed in the simulation software TRNSYS based on the proposed heating system at the GEL under the metrological conditions of Shanghai. The program was used for an intensive simulation study, in which the interaction with the borehole heat exchanger, the geothermal heat pump, the evacuated tube collector and the load requirements could be analyzed. A base case was developed to make it possible to vary and compare the design parameters of interest, such as the ground storage volume, the flow rate of the solar collector and the solar collector area. The base case was based on the design parameters of the GEL. The GEL was used as reference building and was simulated in TRNBuild with the thermal characteristics of the building material. From the simulations the heating demand of the building could be obtained and the building model could later on be used as a heat load for the other simulation models. The results showed that the there were heating demand from November to March. The four operation modes of the proposed heating system at the GEL were presented. All of the operation modes were simulated in TRNSYS. The four operation modes were solar thermal ground storage, solar direct heating, direct heat exchange with the ground storage and geothermal heat pump. The operation modes worked in two different seasons, storage season and heating season. The ground storage mode was studied thoroughly by varying the parameters of interest. To test the significance of the borehole configuration, the storage volume was kept constant and the number of boreholes and the borehole spacing were varied. It was found that a compact pattern with a high number of boreholes and small borehole spacing is favorable for borehole thermal energy storages. The performance of a ground storage is directly linked to the storage size. The solar collector efficiency is highly dependent on the return temperature of the storage. It was decided to continue to work with a compact pattern of the storage, rather than the base case of the GEL. This is because this kind of storage showed the most promising storage efficiency and also reached a high ground temperature during storage season.Simulations of the heating modes showed that the solar direct heating mode, the direct heat exchange with ground storage mode and the geothermal heat pump mode can each cover 37%, 25% and 38% of the heating demand respectively. For the simulations of the geothermal heat pump it was shown that the borehole depth is a very important factor for the system performance. Too short borehole depth will cause unstable and too low temperatures at the inlet of the evaporator. To compare the electricity use of a geothermal heat pump system with and without solar collectors there were also performed simulations for a traditional geothermal heat pump system. Results showed that 26.1% of the electricity consumption could be saved. The savings was mostly due to the reduced operation time of the heat pump, since other heating modes could be used. The studies showed that due to the complexity of such systems it is very important to perform simulations to optimize the performance. There are many factors that play an important role since there are so many components involved. The simulations showed that sizing of the system is critical for the system performance.
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Kailas, Aravind. "Toward perpetual wireless networks: opportunistic large arrays with transmission thresholds and energy harvesting." Diss., Georgia Institute of Technology, 2010. http://hdl.handle.net/1853/34720.

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Solving the key issue of sustainability of battery-powered sensors continues to attract significant research attention. The prevailing theme of this research is to address this concern using energy-efficient protocols based on a form of simple cooperative transmission (CT) called the opportunistic large arrays (OLAs), and intelligent exploitation of energy harvesting and hybrid energy storage systems (HESSs). The two key contributions of this research, namely, OLA with transmission threshold (OLA-T) and alternating OLA-T (A-OLA-T), offer an signal-to-noise ratio (SNR) advantage (i.e., benefits of diversity and array (power) gains) in a multi-path fading environment, thereby reducing transmit powers or extending range. Because these protocols do not address nodes individually, the network overhead remains constant for high density networks or nodes with mobility. During broadcasting across energy-constrained networks, while OLA-T saves energy by limiting node participation within a single broadcast, A-OLA-T optimizes over multiple broadcasts and drains the the nodes in an equitable fashion. Another important contribution of this research is the design and analysis of a novel routing metric called communications using HESS (CHESS), which extends the rechargeable battery (RB)-life by relaying exclusively with supercapacitor (SC) energy, and is asymptotically optimal with respect to the number of nodes in the network.
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Gazey, Ross Neville. "Sizing hybrid green hydrogen energy generation and storage systems (HGHES) to enable an increase in renewable penetration for stabilising the grid." Thesis, Robert Gordon University, 2014. http://hdl.handle.net/10059/947.

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A problem that has become apparently growing in the deployment of renewable energy systems is the power grids inability to accept the forecasted growth in renewable energy generation integration. To support forecasted growth in renewable generation integration, it is now recognised that Energy Storage Technologies (EST) must be utilised. Recent advances in Hydrogen Energy Storage Technologies (HEST) have unlocked their potential for use with constrained renewable generation. HEST combines Hydrogen production, storage and end use technologies with renewable generation in either a directly connected configuration, or indirectly via existing power networks. A levelised cost (LC) model has been developed within this thesis to identify the financial competitiveness of the different HEST application scenarios when used with grid constrained renewable energy. Five HEST scenarios have been investigated to demonstrate the most financially competitive configuration and the benefit that the by-product oxygen from renewable electrolysis can have on financial competitiveness. Furthermore, to address the lack in commercial software tools available to size an energy system incorporating HEST with limited data, a deterministic modelling approach has been developed to enable the initial automatic sizing of a hybrid renewable hydrogen energy system (HRHES) for a specified consumer demand. Within this approach, a worst-case scenario from the financial competitiveness analysis has been used to demonstrate that initial sizing of a HRHES can be achieved with only two input data, namely – the available renewable resource and the load profile. The effect of the electrolyser thermal transients at start-up on the overall quantity of hydrogen produced (and accordingly the energy stored), when operated in conjunction with an intermittent renewable generation source, has also been modelled. Finally, a mass-transfer simulation model has been developed to investigate the suitability of constrained renewable generation in creating hydrogen for a hydrogen refuelling station.
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Lakshminarayanan, Srivathsan. "Nature Inspired Grey Wolf Optimizer Algorithm for Minimizing Operating Cost in Green Smart Home." University of Toledo / OhioLINK, 2015. http://rave.ohiolink.edu/etdc/view?acc_num=toledo1438102173.

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Eisenhart, Andrew. "Quantum Simulations of Specific Ion Effects in Organic Solvents." University of Cincinnati / OhioLINK, 2021. http://rave.ohiolink.edu/etdc/view?acc_num=ucin1626356392775228.

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Lewis, Courtney-Elyce. "Carbon-integrated vanadium oxide hydrate as a high-performance cathode material for zinc-ion batteries." Thesis, Queensland University of Technology, 2022. https://eprints.qut.edu.au/230254/1/Courtney-Elyce_Lewis_Thesis.pdf.

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This thesis investigates the viability of a new vanadium oxide cathode material to improve the performance of zinc ion battery technologies. Such systems promote the development of eco-friendly, renewable energy storage, and green portable devices. The focus material was thoroughly tested and characterised to gain a deeper understanding of the internal reaction and mechanisms of the battery cells, providing valuable insights relevant to the wider energy storage research community.
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Tizaoui, Abdelkhalek. "Etude théorique, numérique et expérimentale de l'échange de chaleur entre un fluide et le sol par un échangeur bitubulaire vertical." Valenciennes, 1989. https://ged.uphf.fr/nuxeo/site/esupversions/4e75693b-4fbb-4e3f-9f3d-b412562fb545.

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La thèse est consacrée à l’étude de l’échange de chaleur entre un fluide et un milieu solide tel que le sol par l’intermédiaire d’un échangeur bitubulaire vertical. Un modèle mathématique du comportement du système a été élaboré. Pour résoudre l’ensemble des équations, un algorithme de calcul numérique, basé sur l’utilisation des fonctions de Green afin de réduire le problème tridimensionnel à un problème bidimensionnel, a été mis au point. L’application du théorème de Duhamel a permis d’introduire la notion de réponse caractéristique de ce type d’échangeur. En vue de valider le modèle mathématique et numérique, une expérience a été réalisée en laboratoire. Les résultats des tests effectués avec des conditions aux limites différentes confirment avec une très bonne approximation les résultats théoriques. Ce modèle peut être alors utilisé comme un outil intéressant pour concevoir des échangeurs à puits multiples efficaces contribuant ainsi à l’élaboration de chaînes énergétiques rentables.
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Silva, Newton Rocha da. "TI verde – o armazenamento de dados e a eficiência energética no data center de um banco brasileiro." Universidade Nove de Julho, 2015. https://bibliotecatede.uninove.br/handle/tede/1155.

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Made available in DSpace on 2015-07-27T16:22:43Z (GMT). No. of bitstreams: 1 Newton Rocha da Silva.pdf: 1739667 bytes, checksum: 9f957689d728b32603a096b0af84765b (MD5) Previous issue date: 2015-03-04
The Green IT focuses on the study and design practice, manufacturing, use and disposal of computers, servers, and associated subsystems, efficiently and effectively, with less impact to the environment. It´s major goal is to improve performance computing and reduce energy consumption and carbon footprint. Thus, the green information technology is the practice of environmentally sustainable computing and aims to minimize the negative impact of IT operations to the environment. On the other hand, the exponential growth of digital data is a reality for most companies, making them increasingly dependent on IT to provide sufficient and real-time information to support the business. This growth trend causes changes in the infrastructure of data centers giving focus on the capacity of the facilities issues due to energy, space and cooling for IT activities demands. In this scenario, this research aims to analyze whether the main data storage solutions such as consolidation, virtualization, deduplication and compression, together with the solid state technologies SSD or Flash Systems are able to contribute to an efficient use of energy in the main data center organization. The theme was treated using qualitative and exploratory research method, based on the case study, empirical and documentary research such as technique to data collect, and interviews with IT key suppliers solutions. The case study occurred in the main Data Center of a large Brazilian bank. As a result, we found that energy efficiency is sensitized by technological solutions presented. Environmental concern was evident and showed a shared way between partners and organization studied. The maintaining of PUE - Power Usage Effectiveness, as energy efficiency metric, at a level of excellence reflects the combined implementation of solutions, technologies and best practices. We conclude that, in addition to reducing the consumption of energy, solutions and data storage technologies promote efficiency improvements in the Data Center, enabling more power density for the new equipment installation. Therefore, facing the digital data demand growth is crucial that the choice of solutions, technologies and strategies must be appropriate not only by the criticality of information, but by the efficient use of resources, contributing to a better understanding of IT importance and its consequences for the environment.
A TI Verde concentra-se em estudo e prática de projeto, fabricação, utilização e descarte de computadores, servidores e subsistemas associados, de forma eficiente e eficaz, com o mínimo ou nenhum impacto ao meio ambiente. Seu objetivo é melhorar o desempenho da computação e reduzir o consumo de energia e a pegada de carbono. Nesse sentido, a tecnologia da informação verde é a prática da computação ambientalmente sustentável e tem como objetivo minimizar o impacto negativo das operações de TI no meio ambiente. Por outro lado, o crescimento exponencial de dados digitais é uma realidade para a maioria das empresas, tornando-as cada vez mais dependentes da TI para disponibilizar informações em tempo real e suficiente para dar suporte aos negócios. Essa tendência de crescimento provoca mudanças na infraestrutura dos Data Centers dando foco na questão da capacidade das instalações devido à demanda de energia, espaço e refrigeração para as atividades de TI. Nesse cenário, esta pesquisa objetiva analisar se as principais soluções de armazenamento de dados, como a consolidação, a virtualização, a deduplicação e a compactação, somadas às tecnologias de discos de estado sólido do tipo SSD ou Flash são capazes de colaborar para um uso eficiente de energia elétrica no principal Data Center da organização. A metodologia de pesquisa foi qualitativa, de caráter exploratório, fundamentada em estudo de caso, levantamento de dados baseado na técnica de pesquisa bibliográfica e documental, além de entrevista com os principais fornecedores de soluções de TI. O estudo de caso foi o Data Center de um grande banco brasileiro. Como resultado, foi possível verificar que a eficiência energética é sensibilizada pelas soluções tecnológicas apresentadas. A preocupação ambiental ficou evidenciada e mostrou um caminho compartilhado entre parceiros e organização estudada. A manutenção do PUE - Power Usage Effectiveness (eficiência de uso de energia) como métrica de eficiência energética mantida em um nível de excelência é reflexo da implementação combinada de soluções, tecnologias e melhores práticas. Conclui-se que, além de reduzir o consumo de energia elétrica, as soluções e tecnologias de armazenamento de dados favorecem melhorias de eficiência no Data Center, viabilizando mais densidade de potência para a instalação de novos equipamentos. Portanto, diante do crescimento da demanda de dados digitais é crucial que a escolha das soluções, tecnologias e estratégias sejam adequadas, não só pela criticidade da informação, mas pela eficiência no uso dos recursos, contribuindo para um entendimento mais evidente sobre a importância da TI e suas consequências para o meio ambiente.
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Books on the topic "Green Energy Storage"

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Soni, Amit, Dharmendra Tripathi, Jagrati Sahariya, and Kamal Nayan Sharma. Energy Conversion and Green Energy Storage. Boca Raton: CRC Press, 2022. http://dx.doi.org/10.1201/9781003258209.

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Lee, Kun Sang. Underground Thermal Energy Storage. London: Springer London, 2013.

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Bart, Florence. Cement-Based Materials for Nuclear Waste Storage. New York, NY: Springer New York, 2013.

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Droste-Franke, Bert. Balancing Renewable Electricity: Energy Storage, Demand Side Management, and Network Extension from an Interdisciplinary Perspective. Berlin, Heidelberg: Springer Berlin Heidelberg, 2012.

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Organic nanostructured thin film devices and coatings for clean energy. Boca Raton: Taylor & Francis, 2010.

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Shao, Minhua. Electrocatalysis in Fuel Cells: A Non- and Low- Platinum Approach. London: Springer London, 2013.

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Tripathi, Dharmendra, Jagrati Sahariya, Kamal Nayan Sharma, and Amit Soni. Energy Conversion and Green Energy Storage. Taylor & Francis Group, 2022.

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Tripathi, Dharmendra, Jagrati Sahariya, Kamal Nayan Sharma, and Amit Soni. Energy Conversion and Green Energy Storage. Taylor & Francis Group, 2022.

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Soni, Amit. Energy Conversion and Green Energy Storage. CRC Press LLC, 2022.

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Soni, Amit. Energy Conversion and Green Energy Storage. CRC Press LLC, 2022.

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Book chapters on the topic "Green Energy Storage"

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(Stathis) Michaelides, Efstathios E. "Energy Storage." In Green Energy and Technology, 343–81. Berlin, Heidelberg: Springer Berlin Heidelberg, 2012. http://dx.doi.org/10.1007/978-3-642-20951-2_12.

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Platzer, Max F., and Nesrin Sarigul-Klijn. "Energy Storage Systems." In The Green Energy Ship Concept, 65–69. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-58244-9_18.

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Varin, Robert A., Tomasz Czujko, and Zbigniew S. Wronski. "Nanostructured Hydrides for Solid State Hydrogen Storage for Vehicular Applications." In Green Energy, 223–86. London: Springer London, 2011. http://dx.doi.org/10.1007/978-1-84882-647-2_6.

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Mitchell, Rob, and Marty Schmer. "Switchgrass Harvest and Storage." In Green Energy and Technology, 113–27. London: Springer London, 2012. http://dx.doi.org/10.1007/978-1-4471-2903-5_5.

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Tan, Zhongchao. "Carbon Capture and Storage." In Green Energy and Technology, 349–93. Singapore: Springer Singapore, 2014. http://dx.doi.org/10.1007/978-981-287-212-8_12.

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Ebrahimi, M., D. S. K. Ting, R. Carriveau, and A. McGillis. "Hydrostatically Compensated Energy Storage Technology." In Green Energy and Infrastructure, 211–35. First edition. | Boca Raton, FL : CRC Press, 2021.: CRC Press, 2020. http://dx.doi.org/10.1201/9781003095811-10.

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Anisur, M. R., M. A. Kibria, M. H. Mahfuz, R. Saidur, and I. H. S. C. Metselaar. "Latent Heat Thermal Storage (LHTS) for Energy Sustainability." In Energy Sustainability Through Green Energy, 245–63. New Delhi: Springer India, 2015. http://dx.doi.org/10.1007/978-81-322-2337-5_10.

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Priyadarshi, Himanshu, Kulwant Singh, and Ashish Shrivastava. "Green Technology Solutions for Energy Storage Devices." In Energy Conversion and Green Energy Storage, 117–32. Boca Raton: CRC Press, 2022. http://dx.doi.org/10.1201/9781003258209-9.

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Akiba, Etsuo. "Solid Hydrogen Storage Materials: Interstitial Hydrides." In Green Energy and Technology, 191–206. Tokyo: Springer Japan, 2016. http://dx.doi.org/10.1007/978-4-431-56042-5_14.

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Li, Hai-Wen, and Etsuo Akiba. "Hydrogen Storage: Conclusions and Future Perspectives." In Green Energy and Technology, 279–82. Tokyo: Springer Japan, 2016. http://dx.doi.org/10.1007/978-4-431-56042-5_20.

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Conference papers on the topic "Green Energy Storage"

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Wang, Weimin, K. W. E. Cheng, K. Ding, and W. F. Choi. "A website design in green energy teaching." In Energy Storage. IEEE, 2011. http://dx.doi.org/10.1109/pesa.2011.5982901.

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Yiu, Kevin. "Battery technologies for electric vehicles and other green industrial projects." In Energy Storage. IEEE, 2011. http://dx.doi.org/10.1109/pesa.2011.5982908.

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Tzeng, Ching-Biau, and Ching-Hsiang Tzeng. "Green energy storage monitor system : Electricity storage." In 2017 2nd International Conference Sustainable and Renewable Energy Engineering (ICSREE). IEEE, 2017. http://dx.doi.org/10.1109/icsree.2017.7951513.

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Sivathanu, Sankaran, Ling Liu, and Cristian Ungureanu. "Modeling the performance and energy of storage arrays." In 2010 International Conference on Green Computing (Green Comp). IEEE, 2010. http://dx.doi.org/10.1109/greencomp.2010.5598308.

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Silvetti, Brian. "Thermal Energy Storage - Btu's in the Land of kWh's." In 2012 IEEE Green Technologies Conference. IEEE, 2012. http://dx.doi.org/10.1109/green.2012.6200997.

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Hashmi, Md Umar, and Ana Busic. "Limiting Energy Storage Cycles of Operation." In 2018 IEEE Green Technologies Conference (GreenTech). IEEE, 2018. http://dx.doi.org/10.1109/greentech.2018.00022.

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Muljadi, Eduard, and Vahan Gevorgian. "Flywheel Energy Storage - Dynamic Modeling." In 2017 Ninth Annual IEEE Green Technologies Conference (GreenTech). IEEE, 2017. http://dx.doi.org/10.1109/greentech.2017.52.

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Nishikawa, Norifumi, Miyuki Nakano, and Masaru Kitsuregawa. "Energy aware RAID configuration for large storage systems." In 2011 International Green Computing Conference (IGCC). IEEE, 2011. http://dx.doi.org/10.1109/igcc.2011.6008568.

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Langaker, John T. "Green Energy Storage for Better Gas Turbine Efficiency." In ASME 2010 4th International Conference on Energy Sustainability. ASMEDC, 2010. http://dx.doi.org/10.1115/es2010-90012.

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Everyone with green ambitions wants to see a full fleet of 100 percent renewable energy sources drive the world’s electric power grids. Until that happens, the next best solution integrates renewable energy generators with existing gas-fired power plants to improve their warmer-weather efficiency when generating on their larger scale by using methods of energy storage and distribution. Relatively clean burning on their own, large gas turbine generators are examples of proven opportunities to gain significant efficiency and recover output by using stored thermal energy to cool their inlet air when called to operate during hotter seasons of the year. Sustainable energy sources like wind and solar, which today generate in peaks and troughs that are hard to manage on electric power grids, beckon to be put into service for thermal energy storage instead of direct on-line grid interconnection. This article steps through the implementation of such storage.
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Moreira da Silva, M., J. Ye, T. Shi, and R. Pastor. "Planning energy storage in power transmission networks." In 2014 IEEE Green Energy and Systems Conference (IGESC). IEEE, 2014. http://dx.doi.org/10.1109/igesc.2014.7018637.

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Reports on the topic "Green Energy Storage"

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Byrne, Raymond, Todd Olinsky-Paul, and Daniel Borneo. Green Mountain Power (GMP): Significant Revenues from Energy Storage. Office of Scientific and Technical Information (OSTI), June 2017. http://dx.doi.org/10.2172/1761803.

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Kolodziejczyk, Bart. Unsettled Issues Concerning the Use of Green Ammonia Fuel in Ground Vehicles. SAE International, February 2021. http://dx.doi.org/10.4271/epr2021003.

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While hydrogen is emerging as a clean alternative automotive fuel and energy storage medium, there are still numerous challenges to implementation, such as the economy of hydrogen production and deployment, expensive storage materials, energy intensive compression or liquefaction processes, and limited trial applications. Synthetic ammonia production, on the other hand, has been available on an industrial scale for nearly a century. Ammonia is one of the most-traded commodities globally and the second most-produced synthetic chemical after sulfuric acid. As an energy carrier, it enables effective hydrogen storage in chemical form by binding hydrogen atoms to atmospheric nitrogen. While ammonia as a fuel is still in its infancy, its unique properties render it as a potentially viable candidate for decarbonizing the automotive industry. Yet, lack of regulation and standards for automotive applications, technology readiness, and reliance on natural gas for both hydrogen feedstocks to generate the ammonia and facilitate hydrogen and nitrogen conversion into liquid ammonia add extra uncertainty to use scenarios. Unsettled Issues Concerning the Use of Green Ammonia Fuel in Ground Vehicles brings together collected knowledge on current and future prospects for the application of ammonia in ground vehicles, including the technological and regulatory challenges for this new type of clean fuel.
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Muelaner, Jody Emlyn. Unsettled Issues in Electrical Demand for Automotive Electrification Pathways. SAE International, January 2021. http://dx.doi.org/10.4271/epr2021004.

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With the current state of automotive electrification, predicting which electrification pathway is likely to be the most economical over a 10- to 30-year outlook is wrought with uncertainty. The development of a range of technologies should continue, including statically charged battery electric vehicles (BEVs), fuel cell electric vehicles (FCEVs), plug-in hybrid electric vehicles (PHEVs), and EVs designed for a combination of plug-in and electric road system (ERS) supply. The most significant uncertainties are for the costs related to hydrogen supply, electrical supply, and battery life. This greatly is dependent on electrolyzers, fuel-cell costs, life spans and efficiencies, distribution and storage, and the price of renewable electricity. Green hydrogen will also be required as an industrial feedstock for difficult-to-decarbonize areas such as aviation and steel production, and for seasonal energy buffering in the grid. For ERSs, it is critical to understand how battery life will be affected by frequent cycling and the extent to which battery technology from hybrid vehicles can be applied. Unsettled Issues in Electrical Demand for Automotive Electrification Pathways dives into the most critical issues the mobility industry is facing.
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