| Nome |
# |
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Switching the Light: From Chemical to Electrical [Historical], file e14fb26a-d536-3de1-e053-1705fe0ac030
|
2560
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Vanadium redox flow batteries: Potentials and challenges of an emerging storage technology, file e14fb26a-74ad-3de1-e053-1705fe0ac030
|
532
|
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Developing vanadium redox flow technology on a 9-kW 26-kWh industrial scale test facility: Design review and early experiments, file e14fb26b-3e3f-3de1-e053-1705fe0ac030
|
500
|
|
Thermal modeling of industrial-scale vanadium redox flow batteries in high-current operations, file e14fb26b-aeb9-3de1-e053-1705fe0ac030
|
311
|
|
Electric Waterborne Public Transportation in Venice: a Case Study, file e14fb267-bb3e-3de1-e053-1705fe0ac030
|
268
|
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Maximizing Vanadium Redox Flow Battery Efficiency: Strategies of Flow Rate Control, file e14fb26b-c4da-3de1-e053-1705fe0ac030
|
256
|
|
Comparison of energy losses in a 9 kW vanadium redox flow battery, file e14fb26b-a0e2-3de1-e053-1705fe0ac030
|
247
|
|
Particle based method and X-ray computed tomography for pore-scale flow characterization in VRFB electrodes, file e14fb26b-129c-3de1-e053-1705fe0ac030
|
227
|
|
Solidifying Power Electronics [Historical], file e14fb26a-d837-3de1-e053-1705fe0ac030
|
209
|
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Enhancing the efficiency of kW-class vanadium redox flow batteries by flow factor modulation: An experimental method, file e14fb26c-5a48-3de1-e053-1705fe0ac030
|
192
|
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A Real Multitechnology Microgrid in Venice: A Design Review, file e14fb26b-3e41-3de1-e053-1705fe0ac030
|
189
|
|
An Historical Survey on Light Technologies, file e14fb26a-e3a7-3de1-e053-1705fe0ac030
|
185
|
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A selective hybrid stochastic strategy for fuel-cell multi-parameter identification, file e14fb269-fbf9-3de1-e053-1705fe0ac030
|
178
|
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Revolving and Evolving-Early dc Machines, file e14fb26b-1737-3de1-e053-1705fe0ac030
|
175
|
|
Negative Feedback, Amplifiers, Governors, and More, file e14fb26a-77df-3de1-e053-1705fe0ac030
|
163
|
|
Seventy Years of Getting Transistorized, file e14fb26a-7cd1-3de1-e053-1705fe0ac030
|
163
|
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Matthew Fontaine Maury: The 19th-Century Forerunner of Big Data, file e14fb26b-5023-3de1-e053-1705fe0ac030
|
144
|
|
21 July 1969, file e14fb26b-87f1-3de1-e053-1705fe0ac030
|
143
|
|
Redox flow batteries for the storage of renewable energy: A review, file e14fb269-f184-3de1-e053-1705fe0ac030
|
141
|
|
Creating the First Web: The 19th-Century Expansion of Telegraphy, file e14fb26c-0bd3-3de1-e053-1705fe0ac030
|
113
|
|
CFD study on electrolyte distribution in redox flow batteries, file e14fb268-7c30-3de1-e053-1705fe0ac030
|
110
|
|
"Blowin' in the Wind", file e14fb26a-6f29-3de1-e053-1705fe0ac030
|
107
|
|
Trailblazers in Electromechanical Computing, file e14fb26a-727b-3de1-e053-1705fe0ac030
|
100
|
|
A Lesson from Past Energy Crises, file e14fb269-fc00-3de1-e053-1705fe0ac030
|
97
|
|
Multiphysics Finite–Element Modelling of an All–Vanadium Redox Flow Battery for Stationary Energy Storage, file e14fb267-bcc6-3de1-e053-1705fe0ac030
|
96
|
|
A Question of Coherence, file e14fb269-ed5f-3de1-e053-1705fe0ac030
|
94
|
|
Novel electrolyte rebalancing method for vanadium redox flow batteries, file e14fb26d-ea75-3de1-e053-1705fe0ac030
|
86
|
|
Electric Tramways of the 19th Century, file e14fb26d-0a03-3de1-e053-1705fe0ac030
|
50
|
|
Distributed and Lumped Parameter Models for Fuel Cells, file e14fb26c-c69d-3de1-e053-1705fe0ac030
|
44
|
|
Electrifying Water Buses: A Case Study on Diesel-to-Electric Conversion in Venice, file e14fb26a-7767-3de1-e053-1705fe0ac030
|
35
|
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The Roots of Automation Before Mechatronics, file e14fb26a-5b21-3de1-e053-1705fe0ac030
|
25
|
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Reconsidering Leonardo, file e14fb26c-5354-3de1-e053-1705fe0ac030
|
22
|
|
Messaging Before the Internet - Early Electrical Telegraphs, file e14fb26b-942f-3de1-e053-1705fe0ac030
|
21
|
|
Report On Available Funding Instruments At Eu Level For Students/Researchers Mobility And Results From A Questionnaire About Mobility In Europe, file e14fb26b-3b3a-3de1-e053-1705fe0ac030
|
15
|
|
The development of ac rotary machines, file e14fb26b-384d-3de1-e053-1705fe0ac030
|
14
|
|
Battery management system with testing protocols for kW-class vanadium redox flow batteries, file e14fb26d-d2cf-3de1-e053-1705fe0ac030
|
13
|
|
Standby thermal management system for a kW-class vanadium redox flow battery, file e14fb26e-1c8e-3de1-e053-1705fe0ac030
|
13
|
|
VRFB maintenance procedures: technical and economical relevance, file e14fb26f-abc8-3de1-e053-1705fe0ac030
|
13
|
|
A validated dynamical model of a kW-class Vanadium Redox Flow Battery, file e14fb26c-d438-3de1-e053-1705fe0ac030
|
12
|
|
Standby thermal management system for large scale vanadium redox flow batteries, file e14fb26f-e7e9-3de1-e053-1705fe0ac030
|
12
|
|
Before Lithium-Ion Batteries: The Age of Primary Cells, file b87a224d-acec-4fa3-b201-fbbf80be15d6
|
10
|
|
Dynamic response analysis on a 9 kW VRFB test facility, file e14fb26f-f3fb-3de1-e053-1705fe0ac030
|
10
|
|
Redox flow batteries: Status and perspective towards sustainable stationary energy storage, file e14fb26d-e8cf-3de1-e053-1705fe0ac030
|
9
|
|
Early Italian Computers: Mario Tchou's ELEA 9003, file e14fb26d-1f35-3de1-e053-1705fe0ac030
|
8
|
|
The Television: From Mechanics to Electronics, file e14fb26a-5442-3de1-e053-1705fe0ac030
|
7
|
|
Optimal energy storage systems for long charge/discharge duration, file e14fb26f-7c5e-3de1-e053-1705fe0ac030
|
7
|
|
Developing vanadium redox flow technology on a 9-kW 26-kWh industrial scale test facility: Design review and early experiments, file e14fb26b-2d1c-3de1-e053-1705fe0ac030
|
5
|
|
Early Italian Computers: Pier Giorgio Perotto's P101, file e14fb26e-3e4d-3de1-e053-1705fe0ac030
|
5
|
|
A straightforward deduction of the electric circuit power, file e14fb26a-5444-3de1-e053-1705fe0ac030
|
4
|
|
Modelling a Coupled Thermoelectromechanical Behaviour of Contact Elements via Fractal Surfaces, file e14fb26c-b488-3de1-e053-1705fe0ac030
|
3
|
|
Two-dimensional analytical modelling of a direct methanol fuel cell, file e14fb26c-c1bd-3de1-e053-1705fe0ac030
|
3
|
|
Multichannel Electrochemical Impedance Spectroscopy and equivalent circuit synthesis of a large-scale vanadium redox flow battery, file e14fb26e-9470-3de1-e053-1705fe0ac030
|
3
|
|
Flow and dispersion in anisotropic porous media: A lattice-Boltzmann study, file e14fb269-0e6d-3de1-e053-1705fe0ac030
|
2
|
|
A Glance at Circuit Theory Development, file e14fb26f-0d9d-3de1-e053-1705fe0ac030
|
2
|
|
A boundary integral formulation on unstructured dual grids for eddy-current analysis in thin shields, file e14fb267-9058-3de1-e053-1705fe0ac030
|
1
|
|
A Stochastic Approach for PEMFC material identification, file e14fb26b-1298-3de1-e053-1705fe0ac030
|
1
|
|
Stack-based technologies for energy storage: a comparative assessment, file e14fb26b-2e29-3de1-e053-1705fe0ac030
|
1
|
|
The VRFB Industrial-Scale Experiment at University of Padua, file e14fb26b-421f-3de1-e053-1705fe0ac030
|
1
|
|
Elementi di elettromagnetismo per l'elettrotecnica, file e14fb26b-a938-3de1-e053-1705fe0ac030
|
1
|
|
RICERCHE SPERIMENTALI E NUMERICHE SU BATTERIE A FLUSSO DI VANADIO DI SCALA INDUSTRIALE, file e14fb26b-bd56-3de1-e053-1705fe0ac030
|
1
|
|
Da Habilis a Jobs: due milioni di anni con la tecnologia, file e14fb26c-307c-3de1-e053-1705fe0ac030
|
1
|
|
Fili di seta intrecciati nel tempo, file e14fb26d-de6e-3de1-e053-1705fe0ac030
|
1
|
| Totale |
7961 |