Hybrid Renewable Energy Systems for Isolated Farms. A Review

Maican, E.; Vlăduț, V.; Vîlcu, Constantin; Sorică, C.; Dorian, Marin; Mirea, D.P.; Bogateanu, Radu

doi:10.35633/inmateh-59-09

Cited by 8 publications

(3 citation statements)

References 4 publications

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“…(a) -F2F agrifood chain management for grapes products, to the graph 1. (b) -Graphic diagram of the F2F agri-food value chain: 1-Farm, 2-Fork, 3-Crop storage, 4-Food processing, 5-Distributor transporter, 6-Agri-food market, 7-Food health safety (FHS), 8-web platform UTOPIA, which is the basis of Fuzzy neural processing in the software module integrated of TZP-UTOPIA-F2F concept, (INMA), [6][7][8].…”

Section: What Is Needed To Solve the Problem?mentioning

confidence: 99%

Smart-Field of the Farm, First Relevant Link of Transparent Path of Grapes in the Farm to Fork Value Chain: A Review

Vîlcu¹,

Vanlanduit²,

Kara³

et al. 2023

Sustainable Regional Planning

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Data-based farming facilitates the zonal management (Smart-FIELD) in the smart farm (SF) vineyards. The classic SCADA for data acquisition and processing system, used especially in rapid industrial processes, can also be adapted for the slow processes (during a vegetation period) of horticultural crops (including the vineyards). The Smart-SCADA core software activities will develop through AI modules the CPS technique for integrating IoT devices with operational applicability in vineyards SF. The Web Smart-SCADA core interconnection with the European platforms in use (UTOPIA, ATLAS, DEMETER, PANTHEON, SmartAgriHubs, …) will add value in the transparency of the traceability of the F2F value chain of grapes.

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Section: What Is Needed To Solve the Problem?mentioning

confidence: 99%

Smart-Field of the Farm, First Relevant Link of Transparent Path of Grapes in the Farm to Fork Value Chain: A Review

Vîlcu¹,

Vanlanduit²,

Kara³

et al. 2023

Sustainable Regional Planning

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“…O2 reservoir tube, 9. Dry cell electrolyzer Hydrogen production via electrolysis of water combined with renewable energy is a promising strategy for future energy sustainability [13]. The high cost and energy required for water electrolysis prevents its widespread applicability on a large scale.…”

Section: Electrolysis Processmentioning

confidence: 99%

The Comparison of Hydrogen Purity on Brown’s Gas Using Dry Cell Electrolyzer with/without Polyvinyl Alcohol (PVA) Separator Membrane

Rahmadina,

Bow,

Yusi

2023

IJRVOCAS

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Global environmental issues that demand good air quality have encouraged various energy sources to develop environmentally friendly energy. Brown’s Gas is produced by using an electrolysis system to separate water into Hydrogen (H2) and Oxygen (O2) gas. The dry cell is an electrolyzer that is widely used for both small and large-scale hydrogen production systems. A dry cell electrolyzer was designed with 12 stages of 316 stainless steel with Polyvinyl Alcohol as a polymer membrane to prevent mixing H2 and O2 to get a high percentage of hydrogen purity. This study compares hydrogen purity on Brown’s gas using a dry cell electrolyzer with PVA with/without a PVA separator membrane. The result shows that the PVA membrane significantly impacted hydrogen purity. The hydrogen purity on Brown’s gas without PVA membrane for KOH, NaOH, KCl, and Seawater was 58.37%, 56.42 %, 50.16%, and 55.22 %. Compared to using the membrane was 78.32%, 77.80%, 63.16%, and 74.0 %, with the highest hydrogen obtained was KOH electrolyte.

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“…From the same sources it is known that the superficial velocities of the synthesis gas are from 0.03 m/s to 0.04 m/s (PM < 5 mg/MJ), far below the critical level of 0.1 m/s where the specific PM2.5 concentration increases above 2.4 mg/MJ. Upon leaving the reactor, the flue gas has a flow rate of 0.007 m 3 /s and an average temperature of 695° C [11].…”

Section: The Objective Of Testingmentioning

confidence: 99%

Experimental research on a hot air generator working on the TLUD principle

Pavel¹,

Rădoi²,

Matache³

et al. 2019

E3S Web Conf.

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The current paper presents the processes of data acquisition and air temperature monitoring in the key points of a hot air generator working on the TLUD principle, which uses temperature sensors, a data acquisition board and an application developed in LabView that numerically and graphically displays temperature variation during burning. The results of the monitoring were obtained on an experimental model, developed by research scientists at INOE 2000-IHP. The data acquired is then used to establish the algorithm for opening the air supply valves for gasification and combustion air, in order to optimize combustion by maintaining the optimum temperature at the funnel.

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Hybrid Renewable Energy Systems for Isolated Farms. A Review

Cited by 8 publications

References 4 publications

Smart-Field of the Farm, First Relevant Link of Transparent Path of Grapes in the Farm to Fork Value Chain: A Review

Smart-Field of the Farm, First Relevant Link of Transparent Path of Grapes in the Farm to Fork Value Chain: A Review

The Comparison of Hydrogen Purity on Brown’s Gas Using Dry Cell Electrolyzer with/without Polyvinyl Alcohol (PVA) Separator Membrane

Experimental research on a hot air generator working on the TLUD principle

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