Lucien Magson, Dario Maggiolo, Angela Sasic Kalagasidis, Stefan Henninger, Gunther Munz, Markus Knäbbeler-Buß, Helen Hölzel, Kasper Moth-Poulsen, Ignacio Funes-Ardoiz, Diego Sampedro
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引用次数: 0
摘要
随着可再生能源技术在全球范围内的加速应用,找到高效的能源储存方法将有助于应对不断变化的能源需求。分子太阳能热(MOST)储能技术不仅在太阳能收集方面,而且在无排放供热方面都是一个有前景的选择。MOST 应用的一个核心部分是开发释放存储能量的方法。在这里,我们在一个专门设计的填料床反应器中探索了四环烷(QC)催化降冰片二烯的逆反应。研究了四种不同尺寸和特意合成的活性炭上铂催化剂,以引发高能量 QC 异构体的热释放。利用各种结构、表面和光谱技术对催化剂进行了全面表征。研究还探讨了在流动条件下优化催化转化和热释放的参数,包括粒度和填料行为、流速和分子停留时间。此外,利用 CO 脉冲化学吸附技术,报告了位点时间产率值和周转次数。作为对流动反应的补充,还对两个不同粒度范围的催化填料床进行了计算流体动力学模拟,以评估反应器床内的流体动力学行为,从而确定在 MOST 应用中进行催化反应的理想粒度和填料密度。
Sustainable Heat Generation in Flow from a Molecular Solar Thermal Energy Storage System
As the global deployment of renewable technologies accelerate, finding efficient ways to store energy will aid in responding to shifting energy demands. A prospective option not only in harvesting solar energy but also in emission-free heating is MOlecular Solar Thermal (MOST) energy storage. A central part of MOST applications is to develop methods to release the stored energy. Herein, the Quadricyclane (QC)-to-Norbornadiene catalyzed back reaction is explored in a specially designed packed-bed reactor. Four distinctly sized and purposely synthesized platinum on activated carbon catalysts are studied to trigger the heat release from the energy-dense QC isomer. The catalysts are fully characterized using a variety of structural, surface, and spectroscopic techniques. Parameters to optimize catalytic conversion and heat release in flow conditions are explored including particle size and packing behavior, flow rates, and molecular residence times. Moreover, using CO pulse chemisorption technique, site time yield values and a turnover number are reported. Complementary to the flow reactions, computational fluid dynamic simulations applying lattice Boltzmann methods to two catalytic packed beds of different size ranges are done to evaluate fluid-dynamic behavior within the reactor bed to ascertain the ideal particle size and packing density for catalysis in MOST applications.
期刊介绍:
Advanced Energy and Sustainability Research is an open access academic journal that focuses on publishing high-quality peer-reviewed research articles in the areas of energy harvesting, conversion, storage, distribution, applications, ecology, climate change, water and environmental sciences, and related societal impacts. The journal provides readers with free access to influential scientific research that has undergone rigorous peer review, a common feature of all journals in the Advanced series. In addition to original research articles, the journal publishes opinion, editorial and review articles designed to meet the needs of a broad readership interested in energy and sustainability science and related fields.
In addition, Advanced Energy and Sustainability Research is indexed in several abstracting and indexing services, including:
CAS: Chemical Abstracts Service (ACS)
Directory of Open Access Journals (DOAJ)
Emerging Sources Citation Index (Clarivate Analytics)
INSPEC (IET)
Web of Science (Clarivate Analytics).
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