Sridharan Balaji, Genuino Homer C, Jardan Daniela, Wilbers Erwin, van de Bovenkamp Henk H, Winkelman Jozef G M, Venderbosch Robbie H, Heeres Hero J
Department of Chemical Engineering, Engineering and Technology Institute Groningen (ENTEG), University of Groningen, Nijenborgh 4, 9747 AGGroningen, Netherlands.
Biomass Technology Group B.V., Josink Esweg 34, 7545 PNEnschede, Netherlands.
Energy Fuels. 2022 Oct 20;36(20):12628-12640. doi: 10.1021/acs.energyfuels.2c02044. Epub 2022 Oct 11.
The thermochemical decomposition of woody biomass has been widely identified as a promising route to produce renewable biofuels. More recently, the use of molten salts in combination with pyrolysis has gathered increased interest. The molten salts may act as a solvent, a heat transfer medium, and possibly also a catalyst. In this study, we report experimental studies on a process to convert woody biomass to a liquid hydrocarbon product with a very low oxygen content using molten salt pyrolysis (350-450 °C and atmospheric pressure) followed by subsequent catalytic conversions of the liquids obtained by pyrolysis. Pyrolysis of woody biomass in molten salt (ZnCl/NaCl/KCl with a molar composition of 60:20:20) resulted in a liquid yield of 46 wt % at a temperature of 450 °C and a molten salt/biomass ratio of 10:1 (mass). The liquids are highly enriched in furfural (13 wt %) and acetic acid (14 wt %). To reduce complexity and experimental issues related to the production of sufficient amounts of pyrolysis oils for further catalytic upgrading, model studies were performed to convert both compounds to hydrocarbons using a three-step catalytic approach, viz., (i) ketonization of acetic acid to acetone, (ii) cross-aldol condensation between acetone and furfural to C-C products, followed by (iii) a two-stage catalytic hydrotreatment of the latter to liquid hydrocarbons. Ketonization of acetic acid to acetone was studied in a continuous setup over a ceria-zirconia-based catalyst at 250 °C. The catalyst showed no signs of deactivation over a period of 230 h while also achieving high selectivity toward acetone. Furfural was shown to have a negative effect on the catalyst performance, and as such, a separation step is required after pyrolysis to obtain an acetic-acid-enriched fraction. The cross-aldol condensation reaction between acetone and furfural was studied in a batch using a commercial Mg/Al hydrotalcite as the catalyst. Furfural was quantitatively converted with over 90% molar selectivity toward condensed products with a carbon number between C and C. The two-stage hydrotreatment of the condensed product consisted of a stabilization step using a Ni-based Picula catalyst and a further deep hydrotreatment over a NiMo catalyst, in both batch setups. The final product with a residual 1.5 wt % O is rich in (cyclo)alkanes and aromatic hydrocarbons. The overall carbon yield for the four-step approach, from pinewood biomass to middle distillates, is 21%, assuming that separation of furfural and acetic acid after the pyrolysis step can be performed without losses.
木质生物质的热化学分解已被广泛认为是生产可再生生物燃料的一条有前景的途径。最近,熔盐与热解相结合的应用引起了越来越多的关注。熔盐可以充当溶剂、传热介质,甚至可能还起到催化剂的作用。在本研究中,我们报告了关于一个过程的实验研究,该过程通过熔盐热解(350 - 450°C和常压)将木质生物质转化为氧含量极低的液态烃产品,随后对热解得到的液体进行后续催化转化。在熔盐(摩尔组成为60:20:20的ZnCl/NaCl/KCl)中对木质生物质进行热解,在450°C的温度和10:1(质量)的熔盐/生物质比下,液体产率为46 wt%。这些液体中富含糠醛(13 wt%)和乙酸(14 wt%)。为了降低与生产足够量热解油以进行进一步催化提质相关的复杂性和实验问题,进行了模型研究,使用三步催化方法将这两种化合物转化为烃类,即:(i)将乙酸酮化为丙酮,(ii)丙酮与糠醛之间进行交叉羟醛缩合生成碳 - 碳产物,随后(iii)对后者进行两步催化加氢处理得到液态烃。在连续装置中,在基于二氧化铈 - 氧化锆的催化剂上于250°C研究了乙酸酮化为丙酮的反应。该催化剂在230小时内没有失活迹象,同时对丙酮也具有高选择性。结果表明糠醛对催化剂性能有负面影响,因此在热解后需要一个分离步骤以获得富含乙酸的馏分。在间歇操作中,使用商业Mg/Al水滑石作为催化剂研究了丙酮与糠醛之间的交叉羟醛缩合反应。糠醛以超过90%的摩尔选择性被定量转化为碳数在C和C之间的缩合产物。缩合产物的两步加氢处理包括在间歇装置中使用镍基Picula催化剂进行稳定化步骤,以及在NiMo催化剂上进行进一步的深度加氢处理。最终产物的残余氧含量为可实现的1.5 wt%,富含(环)烷烃和芳烃。假设热解步骤后糠醛和乙酸的分离可以无损失地进行,从松木生物质到中间馏分的四步方法的总碳产率为21%。
