Lab-scale experiment of a closed thermochemical heat storage system including honeycomb heat exchanger

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Lab-scale experiment of a closed thermochemical heat storage system including honeycomb heat exchanger. / Fopah-Lele, Armand; Rohde, Christian; Neumann, Karsten et al.
In: Energy, Vol. 114, 01.11.2016, p. 225-238.

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Fopah-Lele A, Rohde C, Neumann K, Tietjen T, Rönnebeck T, N'Tsoukpoe KE et al. Lab-scale experiment of a closed thermochemical heat storage system including honeycomb heat exchanger. Energy. 2016 Nov 1;114:225-238. doi: 10.1016/j.energy.2016.08.009

Bibtex

@article{c81bd6a58da84eb9963b8a0a10b6f51c,
title = "Lab-scale experiment of a closed thermochemical heat storage system including honeycomb heat exchanger",
abstract = "A lab-scale thermochemical heat storage reactor was developed in the European project “thermal battery” to obtain information on the characteristics of a closed heat storage system, based on thermochemical reactions. The present type of storage is capable of re-using waste heat from cogeneration system to produce useful heat for space heating. The storage material used was SrBr 2·6H 2O. Due to agglomeration or gel-like problems, a structural element was introduced to enhance vapour and heat transfer. Honeycomb heat exchanger was designed and tested. 13 dehydration-hydration cycles were studied under low-temperature conditions (material temperatures < 100 °C) for storage. Discharging was realized at water vapour pressure of about 42 mbar. Temperature evolution inside the reactor at different times and positions, chemical conversion, thermal power and overall efficiency were analysed for the selected cycles. Experimental system thermal capacity and efficiency of 65 kWh and 0.77 are respectively obtained with about 1 kg of SrBr 2·6H 2O. Heat transfer fluid recovers heat at a short span of about 43 °C with an average of 22 °C during about 4 h, acceptable temperature for the human comfort (20 °C on day and 16 °C at night). System performances were obtained for a salt bed energy density of 213 kWh·m 3. The overall heat transfer coefficient of the honeycomb heat exchanger has an average value of 147 W m −2 K −1. Though promising results have been obtained, ameliorations need to be made, in order to make the closed thermochemical heat storage system competitive for space heating. ",
keywords = "Energy research, Thermochemical storage, Honeycomb heat exchanger, Thermal performance, Cycling tests, Space heating, Salt hydrates",
author = "Armand Fopah-Lele and Christian Rohde and Karsten Neumann and Theo Tietjen and Thomas R{\"o}nnebeck and N'Tsoukpoe, {Kokouvi Edem} and Thomas Osterland and Oliver Opel and Ruck, {Wolfgang K.L.}",
year = "2016",
month = nov,
day = "1",
doi = "10.1016/j.energy.2016.08.009",
language = "English",
volume = "114",
pages = "225--238",
journal = "Energy",
issn = "0360-5442",
publisher = "Elsevier B.V.",

}

RIS

TY - JOUR

T1 - Lab-scale experiment of a closed thermochemical heat storage system including honeycomb heat exchanger

AU - Fopah-Lele, Armand

AU - Rohde, Christian

AU - Neumann, Karsten

AU - Tietjen, Theo

AU - Rönnebeck, Thomas

AU - N'Tsoukpoe, Kokouvi Edem

AU - Osterland, Thomas

AU - Opel, Oliver

AU - Ruck, Wolfgang K.L.

PY - 2016/11/1

Y1 - 2016/11/1

N2 - A lab-scale thermochemical heat storage reactor was developed in the European project “thermal battery” to obtain information on the characteristics of a closed heat storage system, based on thermochemical reactions. The present type of storage is capable of re-using waste heat from cogeneration system to produce useful heat for space heating. The storage material used was SrBr 2·6H 2O. Due to agglomeration or gel-like problems, a structural element was introduced to enhance vapour and heat transfer. Honeycomb heat exchanger was designed and tested. 13 dehydration-hydration cycles were studied under low-temperature conditions (material temperatures < 100 °C) for storage. Discharging was realized at water vapour pressure of about 42 mbar. Temperature evolution inside the reactor at different times and positions, chemical conversion, thermal power and overall efficiency were analysed for the selected cycles. Experimental system thermal capacity and efficiency of 65 kWh and 0.77 are respectively obtained with about 1 kg of SrBr 2·6H 2O. Heat transfer fluid recovers heat at a short span of about 43 °C with an average of 22 °C during about 4 h, acceptable temperature for the human comfort (20 °C on day and 16 °C at night). System performances were obtained for a salt bed energy density of 213 kWh·m 3. The overall heat transfer coefficient of the honeycomb heat exchanger has an average value of 147 W m −2 K −1. Though promising results have been obtained, ameliorations need to be made, in order to make the closed thermochemical heat storage system competitive for space heating.

AB - A lab-scale thermochemical heat storage reactor was developed in the European project “thermal battery” to obtain information on the characteristics of a closed heat storage system, based on thermochemical reactions. The present type of storage is capable of re-using waste heat from cogeneration system to produce useful heat for space heating. The storage material used was SrBr 2·6H 2O. Due to agglomeration or gel-like problems, a structural element was introduced to enhance vapour and heat transfer. Honeycomb heat exchanger was designed and tested. 13 dehydration-hydration cycles were studied under low-temperature conditions (material temperatures < 100 °C) for storage. Discharging was realized at water vapour pressure of about 42 mbar. Temperature evolution inside the reactor at different times and positions, chemical conversion, thermal power and overall efficiency were analysed for the selected cycles. Experimental system thermal capacity and efficiency of 65 kWh and 0.77 are respectively obtained with about 1 kg of SrBr 2·6H 2O. Heat transfer fluid recovers heat at a short span of about 43 °C with an average of 22 °C during about 4 h, acceptable temperature for the human comfort (20 °C on day and 16 °C at night). System performances were obtained for a salt bed energy density of 213 kWh·m 3. The overall heat transfer coefficient of the honeycomb heat exchanger has an average value of 147 W m −2 K −1. Though promising results have been obtained, ameliorations need to be made, in order to make the closed thermochemical heat storage system competitive for space heating.

KW - Energy research

KW - Thermochemical storage

KW - Honeycomb heat exchanger

KW - Thermal performance

KW - Cycling tests

KW - Space heating

KW - Salt hydrates

UR - http://www.scopus.com/inward/record.url?scp=84981277394&partnerID=8YFLogxK

U2 - 10.1016/j.energy.2016.08.009

DO - 10.1016/j.energy.2016.08.009

M3 - Journal articles

VL - 114

SP - 225

EP - 238

JO - Energy

JF - Energy

SN - 0360-5442

ER -