Coke and Chemistry. Vol. 59, No. 6, Pages 207-212, 2016

A. M. Gerasimov^a,*, A. A. Abrosimov^b,**, Yu. G. Pimenov^c, and V. M. Strakhov^d,***Translated by Bernard Gilbert

^aNPK Mekhanobr-Tekhnika, Vasilyevsky Ostrov, Dvadtsat’ Vtoraya Liniya 3, St. Petersburg, 199106 Russia

^bGubkin Russian State University of Oil and Gas, pr. Leninskii 65, Moscow, 119991 Russia

^dKuznetsk Center, Eastern Coal Chemistry Research Institute (VUKhIN), ul. Klimasenko 19, Novokuznetsk, 654040 Russia

Correspondence to: e-mail: *gerasimov_am@npk-mt.spb.ru, **andreich.gis@gmail.com, ***vuhin2013@yandex.ru

Abstract—Attention focuses here on methods of coal processing that require minimal quantities of water and yield products that may be effectively used as commercial and secondary raw materials. In the heat treatment of coals associated with semicoking, the accompanying physicochemical transformation of the coal significantly affects its potential for further processing. In semicoking, the filtration system within the coal pieces changes. The initial coal sample contains phytopores of equivalent diameter d_e up to 0.22 μm. More than 54% of these are pores smaller than 10 μm, mainly (65%) of slot and disk form. A small proportion (10%) of supercapillary cavities (d_e > 0.1 μm) is also observed. After heat treatment, the content of small pores is sharply reduced to 10% (450°C semicoke) and 6.6% (550°C semicoke) – that is, almost sixfold – while the content of supercapillary cavities is increased approximately fourfold (in 550°C semicoke).

Keywords: coal, dry enrichment, semicoking, semicoke, heat treatment, phytopores

Change in Composition and Porous Structure of Coal on Thermal Conditioning