1
|
Grekova A.
, Strelova S.
, Solovyeva M.
, Tokarev M.
The Thermophysical Properties of a Promising Composite Adsorbent Based on Multi-Wall Carbon Nanotubes for Heat Storage
Materials for Renewable and Sustainable Energy. 2024.
V.13. DOI: 10.1007/s40243-023-00243-6
WOS
Scopus
|
2
|
Grekova A.D.
, Tokarev M.M.
, Aristov Y.I.
On the Use of Finned Flat-Tube Heat Exchangers for Adsorptive Heat Storage and Transformation
Journal of Energy Storage. 2024.
V.84. NPart B. 110973
:1-12. DOI: 10.1016/j.est.2024.110973
WOS
Scopus
|
3
|
Grekova A.
, Lysikov A.
, Solovyeva M.
, Tokarev M.
Modeling of Finned Flat Tube Heat Exchangers and Search of Nusselt-Reynolds Numbers Correlations
Journal of Physics: Conference Series. 2024.
V.2701. N1. 012140
:1-12. DOI: 10.1088/1742-6596/2701/1/012140
Scopus
|
4
|
Misyura S.Y.
, Tokarev M.M.
, Morozov V.S.
, Grekova A.D.
, Gordeeva L.G.
Influence of Flow Rate of Thermal Fluid on Duration of Heating of SWS-1L Adsorbent in Heat Exchanger
Journal of Engineering Thermophysics (Russian Journal of Engineering Thermophysics до 2001 года). 2024.
V.33. N1. P.9-20. DOI: 10.1134/s1810232824010028
WOS
Scopus
|
5
|
Grekova A.
, Krivosheeva I.
, Solovyeva M.
, Tokarev M.
Express Method for Assessing Optimality of Industrial Heat Exchangers for Adsorption Heat Transformation
Fluids. 2023.
V.8. N1. 14
:1-16. DOI: 10.3390/fluids8010014
WOS
Scopus
РИНЦ
|
6
|
Grekova A.
, Strelova S.
, Lysikov A.
, Tokarev M.
The Heat Transfer in Plate Fin Heat Exchanger for Adsorption Energy Storage: Theoretical Estimation and Experimental Verification of the Methodology for Heat Accumulation Process
Fluids. 2023.
V.8. N8. 228
:1-14. DOI: 10.3390/fluids8080228
WOS
Scopus
РИНЦ
|
7
|
Grekova A.
, Solovyeva M.
, Cherpakova A.
, Tokarev M.
Composites Based on CaCl2-CaBr2 Salt System for Adsorption Applications: Designing the Optimal Sorbent for Gas Drying and Air Conditioning
Separations. 2023.
V.10. N9. 473
:1-15. DOI: 10.3390/separations10090473
WOS
Scopus
РИНЦ
|
8
|
Tokarev M.M.
, Girnik I.S.
, Aristov Y.I.
Adsorptive Transformation of Ultralow-Temperature Heat Using a “Heat from Cold” Cycle
Energy. 2022.
V.238. NPart C. 122083
:1-9. DOI: 10.1016/j.energy.2021.122083
WOS
Scopus
РИНЦ
|
9
|
Grekova A.
, Tokarev M.
An Optimal Plate Fin Heat Exchanger for Adsorption Chilling: Theoretical Consideration
International Journal of Thermofluids. 2022.
V.16. 100221
:1-10. DOI: 10.1016/j.ijft.2022.100221
Scopus
РИНЦ
|
10
|
Sharma R.
, Kumar E.A.
, Dutta P.
, Murthy S.S.
, Aristov Y.I.
, Tokrev M.
, Li T.X.
, Wang R.Z.
Ammoniated Salt Based Solid Sorption Thermal Batteries: A Comparative Study
Applied Thermal Engineering. 2021.
V.191. 116875
:1-14. DOI: 10.1016/j.applthermaleng.2021.116875
WOS
Scopus
РИНЦ
|
11
|
Nizovskii A.I.
, Matvienko A.A.
, Rogozhnikov V.N.
, Tokarev M.M.
, Bukhtiyarov V.I.
Hydrogen Cartridge Material Based on Aluminum Commercial Alloys Activated by Ga-In Eutectic
Materials Today: Proceedings. 2020.
V.25. N3. P.505-508. DOI: 10.1016/j.matpr.2020.01.045
WOS
Scopus
РИНЦ
|
12
|
Girnik I.
, Tokarev M.
, Aristov Y.
Thermodynamic Analysis of Working Fluids for a New “Heat from Cold” Cycle
Entropy. 2020.
V.22. N8. 808
:1-19. DOI: 10.3390/e22080808
WOS
Scopus
РИНЦ
|
13
|
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
|
14
|
Tokarev M.
A Double-Bed Adsorptive Heat Transformer for Upgrading Ambient Heat: Design and First Tests
Energies. 2019.
V.12. N21. 4037
:1-14. DOI: 10.3390/en12214037
WOS
Scopus
РИНЦ
|
15
|
Kowsari M.M.
, Niazmand H.
, Tokarev M.M.
Bed Configuration Effects on the Finned Flat-Tube Adsorption Heat Exchanger Performance: Numerical Modeling and Experimental Validation
Applied Energy. 2018.
V.213. P.540-554. DOI: 10.1016/j.apenergy.2017.11.019
WOS
Scopus
РИНЦ
|
16
|
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
|
17
|
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
|
18
|
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
|
19
|
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
|
20
|
Tokarev M.M.
, Aristov Y.I.
A New Version of the Large Temperature Jump Method: The Thermal Response (T–LTJ)
Energy. 2017.
V.140. N1. P.481-487. DOI: 10.1016/j.energy.2017.08.093
WOS
Scopus
РИНЦ
|