Sewage sludge gasification. Dolomite performance under different operating conditions

Gasification is a technology that can replace traditional management alternatives used up to date to deal with this waste (landfilling, composting and incineration) and which fulfils the social, environmental and legislative requirements. The main products of sewage sludge gasification are permanent gases (useful to generate energy or to be used as raw material in chemical synthesis processes), liquids (tars) and char. One of the main problems to be solved in gasification is tar production. Tars are organic impurities which can condense at relatively high temperatures making impossible to use the produced gases for most applications. This work deals with the effect of some primary tar removal processes (performed inside the gasifier) on sewage sludge gasification products. For this purpose, analysis of the gas composition, tar production, cold gas efficiency and carbon conversion were carried out. The tests were performed with air in a laboratory scale plant consisting mainly of a bubbling bed gasifier. No catalyzed and catalyzed (10% wt of dolomite in the bed and in the feeding) tests were carried out at different temperatures (750ºC, 800ºC and 850ºC) in order to know the effect of these parameters in the gasification products. As far as tars were concerned, qualitative and quantitative tar composition was determined. In all tests the Equivalence Ratio (ER) was kept at 0.3. Temperature is one of the most influential variables in sewage sludge gasification. Higher temperatures favoured hydrogen and CO production while CO2 content decreased, which might be partially explained by the effect of the cracking, Boudouard and CO2 reforming reactions. At 850ºC, cold gas efficiency and carbon conversion reached 49% and 76%, respectively. The presence of dolomite as catalyst increased the production of H2 reaching contents of 15.5% by volume at 850 °C. Similar behaviour was found for CO whereas CO2 and CnHm (light hydrocarbons) production decreased. In the presence of dolomite, a tar reduction of up to 51% was reached in comparison with no catalyzed tests, as well as improvements on cold gas efficiency and carbon conversion. Several assays were developed in order to test catalyst performance under more rough gasification conditions. For this purpose, the throughput value (TR), defined as kg sludge “as received” fed to the gasifier per hour and per m2 of cross sectional area of the gasifier, was modified. Specifically, the TR values used were 110 (reference value), 215 and 322 kg/h·m2. When TR increased, the H2, CO and CH4 production decreased while the CO2 and the CnHm production increased. Tar production increased drastically with TR during no catalysed tests what is related to the lower residence time of the gas inside the reactor. Nevertheless, even at TR=322 kg/h·m2, tar production decreased by nearly 50% with in-bed use of dolomite in comparison with no catalyzed assays under the same operating conditions. Regarding relative tar composition, there was an increase in benzene and naphthalene content when temperature increased while the content of the rest of compounds decreased. The dolomite seemed to be effective all over the range of molecular weight studied showing tar removal efficiencies between 35-55% in most cases. High values of the TR caused a significant increase in tar production but a slight effect on tar composition.

Caracterización y análisis comparativo del comportamiento medioambiental de los materiales de aislamiento térmico utilizados en la envolvente del edificio, en función del sistema constructivo y de la situación geográfica

La construcción es uno de los causantes de mayor impacto ambiental y energético en el entorno. Por ello, los profesionales del sector deben empezar a cambiar la manera en la que diseñan la arquitectura, incorporando técnicas y parámetros sostenibles desde las primeras etapas del diseño, controlando la elección de los materiales y las soluciones constructivas. A través de las Declaraciones Ambientales de Producto (DAP) es posible conocer el perfil ambiental de los productos de la construcción, sin embargo, la mayoría de estos documentos solo poseen información de la etapa de producto (A1-A3) y de la etapa de fin de vida, contemplando solo un tipo de tratamiento (vertedero o incineración). Lo que propone esta investigación es generar información medioambiental del resto de las etapas del ciclo de vida relacionado con el producto, haciendo especial hincapié en la etapa de transporte (A4), puesta en obra (A5), transporte de obra a planta de tratamiento (C2) y etapa de fin de vida con vertedero e incineración. Para la realización de la investigación se ha generado un Inventario de Ciclo de Vida (ICV) con valores medios facilitados por las empresas. El ámbito de actuación es la península ibérica, considerándose un transporte en camión. La evaluación ambiental se ha realizado con la herramienta informática SimaPro (versión 7.3.3). Para los procesos que no han podido ser modelizados por falta de información, se ha recurrido a la base de datos Ecoinvent (versión 2.0). Las categorías de impacto analizadas son las contempladas en la UNE-EN ISO 15804+A1. Con esta investigación se propone una catalogación medioambiental del material de aislamiento térmico según los impactos asociados al transporte, puesta en obra y fin de vida del producto para que el prescriptor pueda escoger qué material es el más adecuado a incorporar en el proyecto, desde el punto de vista medioambiental. ABSTRACT _ Construction is one of the main causes of environmental and energy impacts in the environment. Therefore, the professionals of the sector should begin changing the way they design architecture, incorporating sustainable techniques and parameters from the first design stages, controlling the choice of materials and building solutions. It is possible to know the environmental profile of construction products through Environmental Product Declarations (EPD). However, most of these documents only provide information for the product stage (A1-A3) and the end-of-life stage, taking into account only one type of treatment (landfill or incineration). This research proposes the generation of environmental information for the rest of the life cycle stages related to the product, with particular emphasis on the transportstage (A4), construction installation (A5), transport from the construction site to the recycling facilities (C2) and end-of-life stage with landfill and incineration. A Life Cycle Inventory (LCI) has been generated for the development of the research, with mean values provided by the firms. The scope of action is the Iberian Peninsula, considering transport by lorry. The environmental assessment has been carried out with the SimaPro software (version 7.3.3). The Ecoinvent database (version 2.0) has been used for the processes that couldn’t be modelled due to lack of information. The impact categories analysed are those considered in standard UNE-EN ISO 15804+A1. This research proposes an environmental cataloguing of the thermal insulation material depending on the impacts associated with transport, construction installation and end-of-life of the product so that the prescriber might choose which material is the most suitable to implement in the project from an environmental point of view.