Abo Bibliothek: Guest
Digitales Portal Digitale Bibliothek eBooks Zeitschriften Referenzen und Berichte Forschungssammlungen
Heat Transfer Research
Impact-faktor: 0.404 5-jähriger Impact-Faktor: 0.8 SJR: 0.264 SNIP: 0.504 CiteScore™: 0.88

ISSN Druckformat: 1064-2285
ISSN Online: 2162-6561

Volumes:
Volumen 50, 2019 Volumen 49, 2018 Volumen 48, 2017 Volumen 47, 2016 Volumen 46, 2015 Volumen 45, 2014 Volumen 44, 2013 Volumen 43, 2012 Volumen 42, 2011 Volumen 41, 2010 Volumen 40, 2009 Volumen 39, 2008 Volumen 38, 2007 Volumen 37, 2006 Volumen 36, 2005 Volumen 35, 2004 Volumen 34, 2003 Volumen 33, 2002 Volumen 32, 2001 Volumen 31, 2000 Volumen 30, 1999 Volumen 29, 1998 Volumen 28, 1997

Heat Transfer Research

DOI: 10.1615/HeatTransRes.v38.i3.70
pages 275-290

New Activated-Carbon Materials for Systems of Storing Natural Gas in an Absorbed State

Leonid L. Vasiliev, Jr.
Byelorussian Academy of Sciences; and Luikov Heat & Mass Transfer Institute, Porous Media Laboratory, P. Brovka Str. 15, 220072 Minsk, Belarus
Donatas Mishkinis
IberEspacio, Calle Magallanes 3, 4th floor, 28015, Madrid, Spain
Andrei G. Kulakov
Laboratory of Porous Media, A.V.Luikov Heat and Mass Transfer Institute, National Academy of Sciences, P.Brovka 15, 220072, Minsk, Belarus
N. K. Luneva
Institute of General and Inorganic Chemistry of the National Academy of Sciences of Belarus, Minsk, Belarus
A. M. Safonova
nstitute of General and Inorganic Chemistry of the National Academy of Sciences of Belarus, Minsk, Belarus
Yu. V. Ginzburg
Ben Gurion University, Beer Sheva, Israel
S. Rozin
Ben Gurion University, Beer Sheva, Israel

ABSTRAKT

This article presents the results of an experimental study of microporous carbon materials: Busofit-type activated carbon fiber and activated carbon sorbents made of industrial wood residue by an original technology, developed in the National Academy of Sciences of Belarus. Large specific surfaces of the investigated samples and volumes of micropores bear evidence to a substantial potential of these materials for the purposes of natural gas storage. This is supported by the methane sorption isotherms, received for particular samples. The studied materials possess a sufficiently high sorption capacity for methane (8−12 wt.%) at a pressure of 3.5 MPa and a temperature of 20°C. A linear equation for assessing the sorption capacity of materials for methane, depending on the specific surface of the samples, is proposed on the basis of the authors' experimental data and the literature data. The increase in the bulk density of methane storage is associated primarily with the increase in the bulk density of sorbents. Thus, if we increase the density of the materials to 1.1 kg/liter, simultaneously preserving their sorption properties, we can achieve the methane storage densities on the order of 180 liter/liter, which corresponds to systems for storage and transportation of compressed natural gas at a pressure of 200−250 atm.


Articles with similar content:

TRANSIENT NUMERICAL STUDY OF NOVEL COMPOSITE ADSORBENT FOR COOLING APPLICATIONS
Second Thermal and Fluids Engineering Conference, Vol.1, 2017, issue
Sourav Mitra, Bidyut Baran Saha, Kyaw Thu, Animesh Pal
EVALUATION OF CaCl2−SILICA GEL SORBENT FOR WATER SORPTION COOLING SYSTEMS
Heat Pipe Science and Technology, An International Journal, Vol.6, 2015, issue 3-4
Claire McCague, Khorshid Fayazmanesh, Cecilia Berlanga, Majid Bahrami
HEAT CONDUCTION IN ZEOLITE BEDS
International Heat Transfer Conference 7, Vol.2, 1982, issue
J. Volkl
POROUS STRUCTURE AND HYDRIC PROPERTIES OF COB
Journal of Porous Media, Vol.13, 2010, issue 2
Marjorie Bart, Jacques Miriel, Laurent Serres, Florence Collet
HYPERSONIC WIND TUNNELS BASED ON PRESSURE MULTIPLIERS PART I, PRACTICAL REQUIREMENTS: SCHEMES OF HYPERSONIC WIND TUNNELS
TsAGI Science Journal, Vol.49, 2018, issue 5
Anatolyi Petrovich Kurshin