Intensified processes for catalytic recycling of waste products

废品催化回收强化工艺

• 批准号: RGPIN-2016-05918
• 负责人: ILIUTA, MARIA
• 金额: $ 3.13万
• 依托单位: Université Laval
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=710061
• 关键词: Intensified; processes; catalytic; recycling; waste

Important wastes are continuously produced in different industrial processes. Glycerol and carbon dioxide are among the components produced not only in very large amounts but which are expected to grow in coming decades. Glycerol is the main by-product of bio-diesel production process. Approximately 100 kg of glycerol is obtained for each ton of bio-diesel. Intense energy demand as well as increased role of biodiesel in the world energy matrix progressively increased glycerol production and caused its oversupply at the global market. CO2 is considered to have a major contribution to the global climate change. About one third of all anthropogenic CO2 emissions come from fossil fuels used for energy generation. In addition, various industrial processes (oil refineries, cement works, iron ntial alternative to Diesel with high energetic efficiency and low emissions) is an interesting and efficient alternative to CO2 sequestration by chemical recycling. The application of conventional processes is not yet industrially acceptable due to the low conversions, product yield and selectivity. Thereby, development of a selective catalytic process with high conversion is essential from both of environmental and economic points of view. This research program is directed towards glycerol and CO2 valorization to high value products by intensified catalytic processes. Our long-term research program is directed towards glycerol and CO2 valorization to value-added products by intensified catalytic processes. The short-term research program for the next five years will be divided into three directions: H2 production by intensified steam glycerol reforming, glycerol valorization into value-added products by an intensified photocatalytic process, and CO2 valorization to methanol and dimethyl ether by intensified catalytic conversion. As the research program is directed towards different aspects related to environmental engineering, all students involved in different projects (4 PhD, 2 MSc and 6 undergraduate) will have the opportunity to interact with each other and share their experience and their skills with one another. They will be trained in important research areas such as gas separations, industrial residues/waste valorization, CO2 chemical recycling, production of hydrogen and high-value products, catalysis, thus preparing them for the job market in both academic, research and industrial areas.

在不同的工业过程中不断产生重要的废物。甘油和二氧化碳不仅是产量非常大的成分，而且预计在未来几十年内还会增长。甘油是生物柴油生产过程中的主要副产物。每吨生物柴油可获得约100 kg甘油。强烈的能源需求以及生物柴油在世界能源矩阵中的作用日益增加，逐步增加了甘油的生产，并导致其在全球市场上供过于求。二氧化碳被认为是全球气候变化的主要原因。所有人为CO2排放量中约有三分之一来自用于发电的化石燃料。此外，各种工业过程（炼油厂，水泥厂，具有高能量效率和低排放的柴油的铁替代品）是通过化学回收进行CO2封存的有趣且有效的替代品。由于转化率、产品产率和选择性较低，传统工艺的应用在工业上还不能接受。因此，从环境和经济的角度来看，开发具有高转化率的选择性催化方法是必要的。该研究计划旨在通过强化催化工艺将甘油和CO2增值为高价值产品。我们的长期研究计划旨在通过强化催化工艺将甘油和二氧化碳转化为增值产品。未来五年的短期研究计划将分为三个方向：通过强化蒸汽甘油重整生产H2，通过强化光催化过程将甘油增值为增值产品，以及通过强化催化转化将CO2增值为甲醇和二甲醚。 由于研究计划针对与环境工程相关的不同方面，所有参与不同项目的学生（4名博士，2名硕士和6名本科生）将有机会相互交流，分享他们的经验和技能。他们将接受重要研究领域的培训，如气体分离，工业残留物/废物增值，二氧化碳化学品回收，氢气和高价值产品的生产，催化，从而为学术，研究和工业领域的就业市场做好准备。