41
|
Girnik I.S.
, Aristov Y.I.
A HeCol Cycle for Upgrading the Ambient Heat: The Dynamic Verification of Desorption Stage
Applied Thermal Engineering. 2019.
V.146. P.608-612. DOI: 10.1016/j.applthermaleng.2018.10.040
WOS
Scopus
РИНЦ
|
42
|
Brancato V.
, Gordeeva L.G.
, Sapienza A.
, Palomba V.
, Vasta S.
, Grekova A.D.
, Frazzica A.
, Aristov Y.I.
Experimental Characterization of the LiCl/Vermiculite Composite for Sorption Heat Storage Applications
International Journal of Refrigeration. 2019.
V.105. P.92-100. DOI: 10.1016/j.ijrefrig.2018.08.006
WOS
Scopus
РИНЦ
РИНЦ
|
43
|
Kim S.T.
, Miura H.
, Takasu H.
, Kato Y.
, Shkatulov A.
, Aristov Y.
Adapting the MgO-CO2 Working Pair for Thermochemical Energy Storage by Doping with Salts: Effect of the (LiK)NO3 Content
Energies. 2019.
V.12. N11. 2262
:1-13. DOI: 10.3390/en12122262
WOS
Scopus
РИНЦ
|
44
|
Mezentsev I.V.
, Aristov Y.I.
, Mezentseva N.N.
, Mukhin V.A.
Reversible Heat Exchange in the Nozzle with Water–Ice Phase Transition in Filtration of Air
Journal of Engineering Thermophysics (Russian Journal of Engineering Thermophysics до 2001 года). 2019.
V.28. N1. P.103-113. DOI: 10.1134/S1810232819010089
WOS
Scopus
РИНЦ
|
45
|
Grekova A.
, Strelova S.
, Gordeeva L.
, Aristov Y.
“LiCl/vermiculite - Methanol” as Working Pair for Adsorption Heat Storage: Adsorption Equilibrium and Dynamics
Energy. 2019.
V.186. 115775
:1-8. DOI: 10.1016/j.energy.2019.07.105
WOS
Scopus
РИНЦ
|
46
|
Tokarev M.M.
, Zlobin A.A.
, Aristov Y.I.
A New Version of the Large Pressure Jump (T-LPJ) Method for Dynamic Study of Pressure-Initiated Adsorptive Cycles for Heat Storage and Transformation
Energy. 2019.
V.179. P.542-548. DOI: 10.1016/j.energy.2019.04.164
WOS
Scopus
РИНЦ
|
47
|
Grekova A.D.
, Gordeeva L.G.
, Lu Z.
, Wang R.
, Aristov Y.I.
Composite “LiCl/MWCNT” as Advanced Water Sorbent for Thermal Energy Storage: Sorption Dynamics
Solar Energy Materials and Solar Cells. 2018.
V.176. P.273-279. DOI: 10.1016/j.solmat.2017.12.011
WOS
Scopus
РИНЦ
|
48
|
Sapienza A.
, Frazzica A.
, Freni A.
, Aristov Y.
Measurement of Adsorption Dynamics: An Overview
Глава монографии
Dynamics of Adsorptive Systems for Heat Transformation.
– Springer International Publishing.,
2018.
– C.19-29. – ISBN 9783319512853. DOI: 10.1007/978-3-319-51287-7_2
WOS
Scopus
РИНЦ
|
49
|
Sapienza A.
, Frazzica A.
, Freni A.
, Aristov Y.
Experimental Findings: Main Factors Affecting the Adsorptive Temperature-Driven Cycle Dynamics
Глава монографии
Dynamics of Adsorptive Systems for Heat Transformation.
– Springer International Publishing.,
2018.
– C.31-68. – ISBN 9783319512853. DOI: 10.1007/978-3-319-51287-7_3
WOS
Scopus
РИНЦ
|
50
|
Sapienza A.
, Frazzica A.
, Freni A.
, Aristov Y.
Optimization of an “Adsorbent/Heat Exchanger” Unit
Глава монографии
Dynamics of Adsorptive Systems for Heat Transformation.
– Springer International Publishing.,
2018.
– C.69-87. – ISBN 9783319512853. DOI: 10.1007/978-3-319-51287-7_4
WOS
Scopus
РИНЦ
|
51
|
Solovyeva M.V.
, Gordeeva L.G.
, Krieger T.A.
, Aristov Y.I.
MOF-801 as a Promising Material for Adsorption Cooling: Equilibrium and Dynamics of Water Adsorption
Energy Conversion and Management. 2018.
V.174. P.356-363. DOI: 10.1016/j.enconman.2018.08.032
WOS
Scopus
РИНЦ
|
52
|
Okunev B.N.
, Voskresensky N.M.
, Girnik I.S.
, Aristov Y.I.
Thermodynamic Analysis of the New Adsorption Cycle “HeCol” for Ambient Heat Upgrading: Ideal Heat Transfer
Journal of Engineering Thermophysics (Russian Journal of Engineering Thermophysics до 2001 года). 2018.
V.27. N3. P.327-338. DOI: 10.1134/s1810232818030086
WOS
Scopus
РИНЦ
|
53
|
Shkatulov A.I.
, Aristov Y.
Thermochemical Energy Storage using LiNO3-Doped Mg(OH)2: A Dehydration Study
Energy Technology. 2018.
V.6. N9. P.1844-1851. DOI: 10.1002/ente.201800050
WOS
Scopus
РИНЦ
|
54
|
Tokarev M.M.
, Gordeeva L.G.
, Shkatulov A.I.
, Aristov Y.I.
Testing the Lab-Scale "Heat from Cold" Prototype with the "LiCl/Silica - Methanol" Working Pair
Energy Conversion and Management. 2018.
V.159. P.213-220. DOI: 10.1016/j.enconman.2017.12.099
WOS
Scopus
РИНЦ
|
55
|
Gordeeva L.G.
, Tokarev M.M.
, Aristov Y.I.
New Adsorption Cycle for Upgrading the Ambient Heat
Theoretical Foundations of Chemical Engineering. 2018.
V.52. N2. P.195-205. DOI: 10.1134/S0040579518020069
WOS
Scopus
РИНЦ
|
56
|
Tokarev M.M.
, Gordeeva L.G.
, Grekova A.D.
, Aristov Y.I.
Adsorption Cycle “Heat From Cold” for Upgrading the Ambient Heat: The Testing a Lab-Scale Prototype with the Composite sorbent CaClBr/Silica
Applied Energy. 2018.
V.211. P.136-145. DOI: 10.1016/j.apenergy.2017.11.015
WOS
Scopus
РИНЦ
|
57
|
Гордеева Л.Г.
, Токарев М.М.
, Аристов Ю.И.
Новый адсорбционный цикл преобразования теплоты окружающей среды
Теоретические основы химической технологии. 2018.
Т.52. №2. С.171-182. DOI: 10.7868/S0040357118020057
РИНЦ
|
58
|
Aristov Y.I.
Adsorptive Transformation and Storage of Renewable Heat: Review of Current Trends in Adsorption Aynamics
Renewable Energy. 2017.
V.110. NSI. P.105-114. DOI: 10.1016/j.renene.2016.06.055
WOS
Scopus
РИНЦ
|
59
|
Henninger S.K.
, Ernst S-J.
, Gordeeva L.
, Bendix P.
, Fröhlich D.
, Grekova A.D.
, Bonaccorsi L.
, Aristov Y.
, Jaenchen J.
New Materials for Adsorption Heat Transformation and Storage
Renewable Energy. 2017.
V.110. NSI. P.59-68. DOI: 10.1016/j.renene.2016.08.041
WOS
Scopus
РИНЦ
|
60
|
Solovyeva M.V.
, Aristov Y.I.
, Gordeeva L.G.
NH2-MIL-125 as Promising Adsorbent for Adsorptive Cooling: Water Adsorption Dynamics
Applied Thermal Engineering. 2017.
V.116. P.541-548. DOI: 10.1016/j.applthermaleng.2017.01.080
WOS
Scopus
РИНЦ
|