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A new version of the Large Temperature Jump method : The thermal response (T–LTJ). / Tokarev, M. M.; Aristov, Yu I.

In: Energy, Vol. 140, 01.12.2017, p. 481-487.

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Tokarev MM, Aristov YI. A new version of the Large Temperature Jump method: The thermal response (T–LTJ). Energy. 2017 Dec 1;140:481-487. doi: 10.1016/j.energy.2017.08.093

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Tokarev, M. M. ; Aristov, Yu I. / A new version of the Large Temperature Jump method : The thermal response (T–LTJ). In: Energy. 2017 ; Vol. 140. pp. 481-487.

BibTeX

@article{e36f4519c08743df8417844d6df433b0,
title = "A new version of the Large Temperature Jump method: The thermal response (T–LTJ)",
abstract = "In this communication, we propose a new version of the Large Temperature Jump (LTJ) method for studying the ad/desorption dynamics on representative pieces of heat exchangers (HEx) used in real adsorption chillers. This method is based on direct measurement of the temperature difference ΔT of a heat carrier at the inlet and outlet of the tested HEx fragment after a fast drop/jump of the inlet temperature. This tightly repeats the procedure used in real HExs for transformation and storage of low temperature heat. For the sake of validation, the measurements were carried out with the same adsorbent (AQSOA FAM-Z02) and HEx as well as under the same conditions already comprehensively studied in [1]. It is demonstrated that the measured ΔT-response allows studying ad/desorption dynamics, extracting the characteristic process time and heat with sufficient accuracy. The new Thermal Large Temperature Jump (T-LTJ) method gives similar information as the G-LTJ version being more simple in realization and close to the common procedure for evaluating dynamic performance of real adsorptive chillers. Moreover, the T-LTJ provides valuable information about the heat flux directly transferred to a heat carrier fluid that is not available from other LTJ versions.",
keywords = "Adsorption dynamics, Adsorptive chillers, Characteristic time, Large Temperature Jump method, Specific cooling power, ADSORBERS, CHILLERS, PERFORMANCE, ADSORPTION DYNAMICS, PAIR",
author = "Tokarev, {M. M.} and Aristov, {Yu I.}",
year = "2017",
month = dec,
day = "1",
doi = "10.1016/j.energy.2017.08.093",
language = "English",
volume = "140",
pages = "481--487",
journal = "Energy",
issn = "0360-5442",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - A new version of the Large Temperature Jump method

T2 - The thermal response (T–LTJ)

AU - Tokarev, M. M.

AU - Aristov, Yu I.

PY - 2017/12/1

Y1 - 2017/12/1

N2 - In this communication, we propose a new version of the Large Temperature Jump (LTJ) method for studying the ad/desorption dynamics on representative pieces of heat exchangers (HEx) used in real adsorption chillers. This method is based on direct measurement of the temperature difference ΔT of a heat carrier at the inlet and outlet of the tested HEx fragment after a fast drop/jump of the inlet temperature. This tightly repeats the procedure used in real HExs for transformation and storage of low temperature heat. For the sake of validation, the measurements were carried out with the same adsorbent (AQSOA FAM-Z02) and HEx as well as under the same conditions already comprehensively studied in [1]. It is demonstrated that the measured ΔT-response allows studying ad/desorption dynamics, extracting the characteristic process time and heat with sufficient accuracy. The new Thermal Large Temperature Jump (T-LTJ) method gives similar information as the G-LTJ version being more simple in realization and close to the common procedure for evaluating dynamic performance of real adsorptive chillers. Moreover, the T-LTJ provides valuable information about the heat flux directly transferred to a heat carrier fluid that is not available from other LTJ versions.

AB - In this communication, we propose a new version of the Large Temperature Jump (LTJ) method for studying the ad/desorption dynamics on representative pieces of heat exchangers (HEx) used in real adsorption chillers. This method is based on direct measurement of the temperature difference ΔT of a heat carrier at the inlet and outlet of the tested HEx fragment after a fast drop/jump of the inlet temperature. This tightly repeats the procedure used in real HExs for transformation and storage of low temperature heat. For the sake of validation, the measurements were carried out with the same adsorbent (AQSOA FAM-Z02) and HEx as well as under the same conditions already comprehensively studied in [1]. It is demonstrated that the measured ΔT-response allows studying ad/desorption dynamics, extracting the characteristic process time and heat with sufficient accuracy. The new Thermal Large Temperature Jump (T-LTJ) method gives similar information as the G-LTJ version being more simple in realization and close to the common procedure for evaluating dynamic performance of real adsorptive chillers. Moreover, the T-LTJ provides valuable information about the heat flux directly transferred to a heat carrier fluid that is not available from other LTJ versions.

KW - Adsorption dynamics

KW - Adsorptive chillers

KW - Characteristic time

KW - Large Temperature Jump method

KW - Specific cooling power

KW - ADSORBERS

KW - CHILLERS

KW - PERFORMANCE

KW - ADSORPTION DYNAMICS

KW - PAIR

UR - http://www.scopus.com/inward/record.url?scp=85029125578&partnerID=8YFLogxK

U2 - 10.1016/j.energy.2017.08.093

DO - 10.1016/j.energy.2017.08.093

M3 - Article

AN - SCOPUS:85029125578

VL - 140

SP - 481

EP - 487

JO - Energy

JF - Energy

SN - 0360-5442

ER -

ID: 9915193