Decentral Production of Green Hydrogen for Energy Systems: An Economically and Environmentally Viable Solution for Surplus Self-Generated Energy in Manufacturing Companies?

Kalchschmid, Vincent; Erhart, Veronika; Angerer, Kerstin; Roth, S.; Hohmann, Andrea

doi:10.3390/su15042994

Cited by 8 publications

(4 citation statements)

References 26 publications

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“…Although fossil fuels have long been relied upon as a cost-effective and versatile energy source, their significant drawbacks, such as greenhouse gas emissions, acid rain, and rapid depletion, have limited their use in various industries. , As a result, there is an urgent need to explore alternative, clean, and efficient energy options. Hydrogen or H 2 has emerged as a promising solution, serving as a critical industrial raw material with wide-ranging applications in power generation, transportation, synthetic fuels, and industrial processes . Its exceptional gravimetric heating value, reaching up to 141.9 MJ/kg, surpasses those of methane, gasoline, diesel, and methanol, making it highly appealing.…”

Section: Introductionmentioning

confidence: 99%

“…Hydrogen or H 2 has emerged as a promising solution, serving as a critical industrial raw material with wide-ranging applications in power generation, transportation, synthetic fuels, and industrial processes. 3 Its exceptional gravimetric heating value, reaching up to 141.9 MJ/kg, surpasses those of methane, gasoline, diesel, and methanol, 4 making it highly appealing. Additionally, hydrogen offers the distinct advantage of emitting zero emissions when utilized for combustion.…”

Section: Introductionmentioning

confidence: 99%

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Bipolar Membrane Seawater Splitting for Hydrogen Production: A Review

Adisasmito,

Khoiruddin,

Sutrisna

et al. 2024

ACS Omega

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The growing demand for clean energy has spurred the quest for sustainable alternatives to fossil fuels. Hydrogen has emerged as a promising candidate with its exceptional heating value and zero emissions upon combustion. However, conventional hydrogen production methods contribute to CO 2 emissions, necessitating environmentally friendly alternatives. With its vast potential, seawater has garnered attention as a valuable resource for hydrogen production, especially in arid coastal regions with surplus renewable energy. Direct seawater electrolysis presents a viable option, although it faces challenges such as corrosion, competing reactions, and the presence of various impurities. To enhance the seawater electrolysis efficiency and overcome these challenges, researchers have turned to bipolar membranes (BPMs). These membranes create two distinct pH environments and selectively facilitate water dissociation by allowing the passage of protons and hydroxide ions, while acting as a barrier to cations and anions. Moreover, the presence of catalysts at the BPM junction or interface can further accelerate water dissociation. Alongside the thermodynamic potential, the efficiency of the system is significantly influenced by the water dissociation potential of BPMs. By exploiting these unique properties, BPMs offer a promising solution to improve the overall efficiency of seawater electrolysis processes. This paper reviews BPM electrolysis, including the water dissociation mechanism, recent advancements in BPM synthesis, and the challenges encountered in seawater electrolysis. Furthermore, it explores promising strategies to optimize the water dissociation reaction in BPMs, paving the way for sustainable hydrogen production from seawater.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Bipolar Membrane Seawater Splitting for Hydrogen Production: A Review

Adisasmito,

Khoiruddin,

Sutrisna

et al. 2024

ACS Omega

View full text Add to dashboard Cite

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“…Universities, as centers of research and learning, increasingly understand the importance of embracing environmentally sustainable energy solutions [2]. This paradigm shift is motivated not only by environmental concerns but also by the possibility for educational institutions to serve as models for sustainable practices [3]. In today's energy consumption situation, the need to shift toward more sustainable methods is becoming increasingly clear [4].…”

Section: Introductionmentioning

confidence: 99%

H2 URESONIC: Design of a Solar-Hydrogen University Renewable Energy System for a New and Innovative Campus

Joshua,

Park,

Kwon

2024

Applied Sciences

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The necessity to move to sustainable energy solutions has inspired an investigation of innovative technologies for satisfying educational institutions’ sustainable energy needs. The possibility of a solar-hydrogen storage system and its integration into university energy management is investigated in this article. The study opens by providing context, noting the growing relevance of renewable energy in universities as well as the necessity for effective energy storage systems. The goal is to delve into solar-hydrogen technology, outlining its components, operating mechanism, and benefits over typical storage systems. The chapter on Integration Design examines current university energy infrastructure, identifies problems, and provides ways for integrating solar-hydrogen systems seamlessly. This integration relies heavily on technological and economic considerations, such as a cost-benefit analysis and scalability studies. Case studies include real-world examples, performance measurements, and significant insights learned from successful implementations. The chapter Future Prospects investigates new trends in solar-hydrogen technology as well as the impact of government legislation, providing a forward-looking viewpoint for colleges considering adoption. The report concludes with a summary of significant findings, emphasizing the benefits of solar-hydrogen integration and making recommendations for future implementations. The limitation of this research is that it only focuses on design and simulation as a phase of preliminary study.

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“…Fuel cells are becoming more popular as a direct energy conversion technology, especially in microgrid [2]. The significance of hydrogen energy and PEMFCs in microgrid is gradually growing as a result of the increased global energy demand [3]. Hydrogen energy from PEMFCs offers a significant means to manage and balance power flows, as opposed to other renewable energy sources like solar and wind, which have intermittency issues, power balancing issues, and high maintenance costs [4].…”

Section: Introductionmentioning

confidence: 99%

A High Voltage Gain Interleaved DC-DC Converter Integrated Fuel Cell for Power Quality Enhancement of Microgrid

et al. 2023

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Fuel cells have drawn a lot of interest in recent years as one of the most promising alternative green power sources in microgrid systems. The operating conditions and the integrated components greatly impact the quality of the fuel cell’s voltage. Energy management techniques are required in this regard to regulate the fuel cell’s power in a microgrid. The active/reactive power in the microgrid should be adjusted in line with US Energy Star’s regulations whereas the grid current needs to follow the standard set by IEEE 519 2014 to enhance the power quality of the electrical energy injected into the microgrid. Uncontrolled energy injection from the fuel cell can have serious impacts including superfluous energy demand, overloading, and power losses, especially in high power and medium voltage systems. Although fuel cells have many advantages, they cannot yet produce high voltages individually to compensate for the demand of a microgrid system. Due to these reasons, the fuel cell must be interfaced with a DC-DC converter. This research proposes a novel high voltage gain converter integrated 1.26 kW fuel cell for microgrid power management that can boost the fuel cell’s voltage up to 20 times. Due to this high voltage gain, the voltage and current ripple of the fuel cell is also reduced substantially. According to the analysis, the proposed converter demonstrated optimal performance when compared to the other converters due to its high voltage gain and extremely low voltage ripple. As a result, the harmonic profile of the microgrid current persists with a reduced THD of 3.22% and a very low voltage ripple of 4 V. To validate the converter’s performance, along with extensive simulation, a hardware prototype was also built. The voltage of the fuel cell is regulated using a simplified proportional integral controller. The operating principle of the converter integrated fuel cell along with its application in microgrid power management is demonstrated. A comparative analysis is also shown to verify how the proposed converter is improving the system’s performance when compared against other converters.

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Decentral Production of Green Hydrogen for Energy Systems: An Economically and Environmentally Viable Solution for Surplus Self-Generated Energy in Manufacturing Companies?

Cited by 8 publications

References 26 publications

Bipolar Membrane Seawater Splitting for Hydrogen Production: A Review

Bipolar Membrane Seawater Splitting for Hydrogen Production: A Review

H2 URESONIC: Design of a Solar-Hydrogen University Renewable Energy System for a New and Innovative Campus

A High Voltage Gain Interleaved DC-DC Converter Integrated Fuel Cell for Power Quality Enhancement of Microgrid

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