Technology offer: Highly Microporous Activated Carbon from an Spanish Anthracite with Homogeneous Pore Size Distribution

Technology offer: Highly Microporous Activated Carbon from an Spanish Anthracite with Homogeneous Pore Size Distribution

Technology offer Highly Microporous Activated Carbon from an Spanish Anthracite with Homogeneous Pore Size Distribution Reference: TO-CARBON SUMMARY The Department of Inorganic Chemistry of the University of Alicante has developed technology and process to prepare activated carbons with a homogeneous micropore size distribution. Interestingly, the chemical activation by KOH of the Spanish anthracite produces an activated carbon with a very homogeneous micropore size distribution (almost exclusively microporosity of size between 0.7-0.9 nm) and BET surface areas close to 2000 m 2 /g. TECHNOLOGY DESCRIPTION It is well-known that materials of low cost and high carbon content can be used as precursors for the production of activated carbon and that the current trend is toward increasing use of cheap and readily available precursors as coals and lignocellulosic materials. The use of coals as activated carbon precursors could be an alternative to develop the market for this special use of coal. The use of Spanish coals as feedstocks for the production of activated carbons is of interest to our country as reflected by several projects being carried out at different universities and research institutes, granted by the ECSC (European Community of Steel and Coal), Ocicarbon, and the Science Ministry. This interest is a consequence of the large coal production (31.7 metric tons in 1993), and reserves and the current exclusive use of the Spanish coal as feedstocks for combustion processes. The Department of Inorganic Chemistry of the University of Alicante works since 1983 in activated carbons. Preparation of activated carbons with a given pore size distribution is a field of active research in which different precursors and preparation procedures are analysed. The Department has the expertise for the preparation and characterisation of activated carbons from different precursors. Materials of low cost and high carbon content as lignocellulosic materials, coal and carbon fibres can be used as such as precursors for the production of activated carbons. Mainly, two preparation procedures are available for the preparation of these materials: 2

The first possibility is the controlled gasification of carbon by reaction with CO 2 and steam. The second one is the so-called chemical activation in which the carbonaceous precursor is impregnated with a given chemical agent and pyrolysed. The pyrolysis process is usually done at lower temperature than that used in the controlled gasification process. The Department has analysed the activation of Spanish coals using the above methods. Different pore size distribution result depending on the rank of the coal and the activation process. Coals of different ranks develop microporosity by chemical activation, but an increase in the development of the largest pores is observed with decreasing the rank. Coals of lower rank present a wider porosity distribution. Especially interesting results have been obtained by chemical activation of Spanish anthracite with KOH. As it is well known, KOH is a good activating agent but the resulting activated carbons have a heterogeneous porosity in the range of 1-2 nm and very high surface area (for example the commercial AX21). Interestingly, the chemical activation by KOH of the Spanish anthracite produces an activated carbon with a very homogeneous micropore size distribution (almost exclusively microporosity of size between 0.7-0.9 nm) and BET surface areas close to 2000 m 2 /g. Although its surface area is lower than the AX21, its porosity is much more useful for many applications. Thus, the characterisation of this material has shown to be of relevance for several important technological applications. The chemical activation process presents the great advantage, compared to physical activation, of removing the inherent mineral matter of the coal. Activated carbons obtained by chemical activation exhibit much lower ash content than the corresponding original coals. The mineral matter content, abundantly present in Spanish coals, produces an undesirable effect: the increase of the inert part of the samples. INNOVATIVE ASPECTS: Materials of low cost and high carbon content as lignocellulosic materials, coal and carbon fibres can be used as precursors for the production of activated carbons. Different pore size distribution depends on the coal rank and the activation process. Very interesting properties are obtained by chemical activation of Spanish anthracite. 3

CURRENT STAGE OF DEVELOPMENT: The technology is available for demonstration. APPLICATION AREAS The characteristics of the activated carbon from Spanish anthracite have shown to be of relevance for several important technological applications like: Gas storage (CH 4 ) Gas separation (O 2 /N 2, CO 2 /CH 4 ) Gas phase adsorption (elimination of odours, flavours, organic impurities from drinking and waste water, some toxic chemicals, purification of air) INTELLECTUAL PROPERTY RIGHTS The investigation results have been published on several papers (see references below). There is a Spanish patent granted applied to the elimination of NO x. REFERENCES Research Projects: Activated carbon from Spanish subbituminous coals.comunidad Europea. CECA- 7220-EC/758 Preparación de carbones activos a partir de carbones minerales españoles. Ocicarbon, Fase II, C-23/275 Carbones activos a partir de carbones subbituminosos españoles. DGICYT CE91-0011-C03-01. Reducción de las emisiones de SO 2 mediante carbones activos cargados con calcio: estudio en planta piloto. Comunidad Económica Europea, CECA 7220-ED / 053. Reducción de las emisiones de SO 2 mediante carbones activos cargados con calcio: estudio en planta piloto. Comunidad Económica Europea, CECA 7220-ED / 053. Eliminación de SO 2 y NO x de gases de combustión mediante carbón. Ocicarbón C-23-435 4

Advanced Coal Materials by Controlled Gasification-Activation Technologies. EU/CECA. ECSC 7220-EC/766 Preparation of advanced carbon material from coal: Molecular sieve carbon for gas separation and activated carbon gas storage. EU/CECA. ECSC 7220-EC/766 Alternativa novedosa a la eliminación de SO 2 y NO x de emisiones gaseosas. CICYT AMB96-0799 Publications: 1) M.J. Muñoz, M.J. Illán, A. Linares, C. Salinas y J.M. Martín.;Activated carbons from Spanish coals: I) two stages CO 2 activation; Energy & Fuels, 6, 9-15 (1992) 2) M. J. Illán, A. Linares, C. Salinas y J. M. Calo;NO reduction by activated carbons. I The role of carbon porosity and surface area ; Energy & Fuels,7, 146-154, (1993) 3) M.J. Muñoz, A. Linares y C. Salinas; A Study of CaO-SO 2 Interraction; Applied Surface Science, 81, 409-415, (1994) 4) M.J. Muñoz, A. Linares y C. Salinas; A Study of CaO-SO 2 Interraction in the presence of O 2 ; Applied Surface Science, 81, 417-425, (1994) 5) M.J. Illán, A. Linares, L. R. Radovic y C. Salinas ; NO Reduction by Activated Carbons. 2. Catalytic Effect of Potassium ; Energy and Fuels, 9, 97-103, (1995) 6) M.J. Illán, A. Linares, L. R. Radovic y C. Salinas; NO Reduction by Activated Carbons. 3. Influence of Catalyst Loading... ; Energy and Fuels, 9, 104-111, (1995 7) M.J. Illán, A. Linares, L. R. Radovic y C. Salinas ; NO Reduction by Activated Carbons. 4. Catalytic Effect of Calcium; Energy and Fuels, 9, 112-118, (1995). 8) M.J. Illán, A. Linares, L. R. Radovic y C. Salinas ; NO Reduction by Activated Carbons. 5 Catalytic effect of iron ; Energy and Fuels, 9, 540-548, (1995) 9) M.J. Muñoz, A Linares y C. Salinas; A new parameter to characterize limestones as SO 2 sorbents; Applied Surface Science, 89, 197-203, (1995) 10) M.J. Illán, A. Linares y C. Salinas ; NO Reduction by Activated Carbons. 6 Catalysis by first series transition metals; Energy and Fuels, 9, 976-983, (1995) 11) M.C. Macías, A. Linares y C. Salinas ; Sulfur dioxide capture by calcium containing carbon; Coal Science, II, 1831-1834, (1995) 12) A. García, M.J. Illán, A. Linares y C. Salinas; NO x reduction by coal briquets ; Coal Science, II, 1787-1790, (1995). 13) M.J. Illán, A. Linares, L.R. Radovic y C. Salinas ; NO reduction by activated carbons. Some mechanistic aspects; Coal Science, II, 1799-1802, (1995) 14) M.J. Illán, A. Linares, L.R. Radovic y C. Salinas ; NO reduction by activated carbons. 7 Some mechanistic aspects of the uncatalyzed...; Energy and Fuels, 10, 158-168, (1996) 15) M.C. Macías, C. Salinas, C. Muñoz, y A. Linares ; Low temperature SO 2 capture by calcium based sorbents: Characterization of the active calcium; Fuel Chemistry, ACS, 41, Nº 1, 422-426, (1996) 5

16) García, A. Linares y C. Salinas ; NO reduction by Potassium containing coal briquettes. Effect of mineral matter... ; Fuel Chemistry, ACS, 41, Nº 1, 293-297, (1996) 17) MJ. Illan, C. Salinas, A. Linares, J. Phillips and C. Salinas ; Reduction of nitric oxide by low-rank coal chars ; Fuel Chemistry, ACS, 174-178, (1996) 18) M. J. Muñoz, A. Linares y C. Salinas ; High temperature SO 2 retention by CaO ; Applied Surface Science, 99, 111-117, (1996) 19) M.J. Illán, A. García, C. Salinas y A. Linares ; Activated carbons from Spanish Coals. 2. Chemical activation ; Energy and Fuels, 10, 1108-1114 (1996) 20) M. C. Muñoz, M.C. Macías, C. Salinas y A. Linares ; CaO dispersed on activated carbon as SO 2 sorbent.; Fuel, 76, 527-532 (1997). 21) A. García, M.J. Illán, A. Linares y C. Salinas; Potassium containing bindered coals for the reduction of NO and NO x ; Fuel, 76, 499-505 (1997) 22) B. Serrano, M.J. Muñoz, A.Linares y C.Salinas ; Activated carbons from Spanish coals. 3. Preoxidation effect on an anthracite activation; Energy and Fuels, 11, 785-791 (1997) 23) García, S. Chinchón, A.Linares y C.Salinas ; NO reduction by potassium containing coal briquettes. Effect of mineral matter ; Energy and Fuels, 11, 292-298 (1997) COLLABORATION SOUGHT The partners sought are industries with interest in activated carbons. The Department of Inorganic Chemistry is interested in: Transfer its knowledge and know-how to the industry Apply its expertise in the develop of industrial pilot plants and technology in the areas of preparation Realise characterisations and applications in gas separation, gas storage and gas adsorption DEPARTMENT OF INORGANIC CHEMISTRY PROFILE University of Alicante - Carbon and Environmental Group History The University of Alicante was created in 1979 and has rapidly established itself in Spain as a prestigious university, particularly in the teaching and research of science. The Carbon and Environmental Group involved in this research, belongs to the Department of Inorganic Chemistry in the Faculty of Sciences. Personnel 6

The group was established in 1983 when Prof. Ángel Linares-Solano joined the University of Alicante. Currently, it comprises two other membres of the Faculty, Prof. Concepción Salinas-Martínez de Lecea and Prof. Diego Cazorla-Amorós, three Assistant Professors, two PhD Research Fellows and eight PhD students. Research fields The main research fields of the group are: activated carbon preparation and characterisation, carbon fibre preparation, gas adsorption, gas-solid reactions, heterogeneous catalysis, pollution abatement, gas separation and gas storage. Experience The experience of the group in research can be summarised as follows: during the last 10 years, 22 research projects have been carried out with financial support from the Spanish government, EC and private industries; 85 papers have been published in high quality scientific journals, 8 PhD Thesis have been completed and over 100 presentations have been made at international conferences. Regarding the EC funding, our group has participated in 6 projects (5 ECSC, 1 BRITE), being the coordinator of three of them. CONTACT DETAILS Víctor Manuel Pérez Lozano Phone: +34 96 590 3467 Fax: +34 96 590 3803 E-Mail: otri@ua.es URL: http://sgitt-otri.ua.es/es/empresa/ofertas-tecnologicas.html 7