First cycle simulations of the Honigmann process with LiBr/H2O and NaOH/H2O as working fluid pairs as a thermochemical energy storage: Fid-Bau Portal

Fachinformationsdienst BAUdigital

Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik

First cycle simulations of the Honigmann process with LiBr/H2O and NaOH/H2O as working fluid pairs as a thermochemical energy storage

Jahnke, Anna / Strenge, Lia / Fleßner, Christian / Wolf, Niklas / Jungnickel, Tim / Ziegler, Felix

A thermochemical energy storage invented in the 19th century, the so-called ‘Honigmann process’, is reconsidered for the storage of renewable energies or waste heat. In this work, one basic process option of charging with the input of low-grade heat and discharging with the release of mechanical work is studied. A fundamental model based on transient energy and mass balances was implemented with the help of the modelling language Modelica. First simulation results indicate a relatively constant power output in spite of the non-steady-state nature of the process.

Zugriff

Seitennavigation

Dokumentinformationen

Ähnliche Titel

Exportieren, teilen und zitieren

First cycle simulations of the Honigmann process with LiBr/H2O and NaOH/H2O as working fluid pairs as a thermochemical energy storage

Jahnke, Anna / Strenge, Lia / Fleßner, Christian / Wolf, Niklas / Jungnickel, Tim / Ziegler, Felix

A thermochemical energy storage invented in the 19th century, the so-called ‘Honigmann process’, is reconsidered for the storage of renewable energies or waste heat. In this work, one basic process option of charging with the input of low-grade heat and discharging with the release of mechanical work is studied. A fundamental model based on transient energy and mass balances was implemented with the help of the modelling language Modelica. First simulation results indicate a relatively constant power output in spite of the non-steady-state nature of the process.

First cycle simulations of the Honigmann process with LiBr/H2O and NaOH/H2O as working fluid pairs as a thermochemical energy storage

Jahnke, Anna / Strenge, Lia / Fleßner, Christian / Wolf, Niklas / Jungnickel, Tim / Ziegler, Felix

A thermochemical energy storage invented in the 19th century, the so-called ‘Honigmann process’, is reconsidered for the storage of renewable energies or waste heat. In this work, one basic process option of charging with the input of low-grade heat and discharging with the release of mechanical work is studied. A fundamental model based on transient energy and mass balances was implemented with the help of the modelling language Modelica. First simulation results indicate a relatively constant power output in spite of the non-steady-state nature of the process.

Zugriff

Seitennavigation

Dokumentinformationen

Ähnliche Titel

Exportieren, teilen und zitieren

Dokumentinformationen

Titel:

First cycle simulations of the Honigmann process with LiBr/H2O and NaOH/H2O as working fluid pairs as a thermochemical energy storage

Beteiligte:

Jahnke, Anna (Autor:in) / Strenge, Lia (Autor:in) / Fleßner, Christian (Autor:in) / Wolf, Niklas (Autor:in) / Jungnickel, Tim (Autor:in) / Ziegler, Felix (Autor:in)

Erschienen in:

International journal of low-carbon technologies ; 8 ; i55-

Erscheinungsdatum:

01.07.2013

ISSN:

1748-1317 , 1748-1325

DOI:

https://doi.org/10.1093/ijlct/ctt022

Medientyp:

Aufsatz (Zeitschrift)

Format:

Elektronische Ressource

Sprache:

Englisch

Ähnliche Titel

Experimental Study of LiCl/LiBr-Zeolite Composite Adsorbent for Thermochemical Heat Storage

Depeng Chen / Xin Chen / Zhiwei Ma et al. | DOAJ | 2022

Freier Zugriff

Thermochemical Energy Storage Systems

Saha, Bidyut Baran / Rakshit, Dibakar / Jain, Kartik et al. | Wiley | 2024

Energy storage system based on thermochemical energy storage and Rankine cycle and operation method

SUN ZIHAO / XU QIANGHUI / SHEN JUN et al. | Europäisches Patentamt | 2023

Freier Zugriff

Feasibility study of combining the Stirling cycle with a solar thermochemical energy storage scheme

Eusha, M. / Mir, F. / Schories, G. | Wiley | 2020

A review on high-temperature thermochemical energy storage based on metal oxides redox cycle

Wu, Sike / Zhou, Cheng / Doroodchi, Elham et al. | BASE | 2018

Freier Zugriff