机构地区:[1]水发集团有限公司,山东济南250101 [2]山东环保产业研究院有限公司,山东济南250100 [3]山东大学能源与动力工程学院,山东济南250061
出 处:《煤炭学报》2023年第11期4205-4212,共8页Journal of China Coal Society
基 金:山东省自然科学基金重点资助项目(ZR2020KE042);国家自然科学基金联合基金重点资助项目(U22A20435)。
摘 要:全球CO_(2)排放量在过去几个世纪迅速上升,尤其是最近几十年,CO_(2)排放量的提高加剧了温室效应。CO_(2)排放主要来自化石燃料燃烧,特别是燃煤发电厂。钙循环,即CaO的碳酸化/煅烧循环,是燃煤电厂最有前景的CO_(2)捕集技术之一。同时,燃煤发电厂也是NOx排放的主要来源之一。由于具有成本低、毒性小等优点,CO可以作为NO的还原剂。CaO对于CO还原NO具有催化作用。煅烧炉中CaCO3分解所需的能量由生物质燃烧提供。一些未燃尽的焦炭随CaO流入碳酸化炉,与烟气中的O_(2)反应生成CO。因此,在钙循环的碳酸化炉内捕集CO_(2)的同时可实现NO脱除。但关于CaO在碳酸化阶段催化CO还原NO的微观反应机理尚不清楚。利用密度泛函理论(DFT)计算研究了钙循环碳酸化阶段CaO催化CO还原NO的机理,确定了CaO(100)表面上CO和NO分子的结构、吸附和反应路径参数,包括原子布局、键长、吸附能和能垒。CO和NO分子在CaO(100)表面的最佳吸附位是O-top位,吸附能分别为-0.35和-0.79 eV。在CO_(2)存在下,CaO(100)表面上CO、NO的吸附能分别为-0.36、-0.20 eV。CO和NO分子在CaO(100)表面上共吸附是可行的,但CO_(2)对共吸附有明显抑制作用。在CaO(100)表面进行的CO还原NO反应路径,在经历CO_(2)形成与吸附、N2形成这2个基元反应后,最终生成1个N2分子与3个CO_(3)^(2-),总能垒为11.08 eV。其中,CO_(2)形成及吸附(R→IM1→IM2)为整个反应过程的决速步骤。Global CO_(2) concentration rapidly increases over the past few centuries,particularly in recent decades,and the greenhouse effect is sharply accelerated by the increase of CO_(2) emissions.CO_(2) emissions are mainly produced from fossil fuel combustion,in particular coal-fired power plants.Calcium looping,i.e.the carbonation/calcination cycles of CaO,is one of the most promising CO_(2) capture technologies for coal-fired power plant.At the same time,coal-fired power plants are also one of the main sources of NOx emissions.CO can be used as a reducing agent for NO due to its low cost and low toxicity.CaO is a suitable catalyst for NO reduction by CO.The combustion of biomass is used to provide the required en-ergy for the decomposition of CaCO_(3) in the calciner.Few unburned char and CaO flow into the carbonator,where the un-burned char reacts with O2 in the flue gas to generate CO.Thus,the simultaneous NO removal and CO_(2) capture in the car-bonator of the calcium looping process can be realized.However,the reaction mechanism of the effect of CaO on NO re-moval by CO in the carbonation stage is unclear.The mechanism of NO reduction with CO catalyzed by CaO in the car-bonation stage is investigated by the density functional theory(DFT)calculations.The structural,adsorption,and reaction path parameters,including atomic layout,bond length,adsorption energy,and energy barrier of CO and NO molecules on the CaO(100)surface,are determined.The optimal adsorption sites of CO and NO molecules on the CaO(100)surface are O-top sites,and the adsorption energies are-0.35 and-0.79 eV,respectively.The CO and NO adsorption energies on the CaO(100)surface in the presence of CO_(2) are-0.36 and-0.20 eV,respectively.The co-adsorption of CO and NO mo-lecules appears feasible on the CaO(100)surface,while CO_(2) exhibits obvious inhibition for the co-adsorption.The reac-tion path of NO reduction by CO on the CaO(100) surface undergoes two elementary reaction stages:CO_(2) formation and adsorption,and N2 generation.Finally,one N_(2)
关 键 词:钙循环 碳酸化阶段 CO_(2)捕集 CO脱除NO 密度泛函理论
分 类 号:X7[环境科学与工程—环境工程]
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