Lignocellulosic Biomass Feeding in Biogas Pathway: State of the Art and Plant Layouts☆

Abstract The traditional pathway for biogas production consists in the anaerobic digestion of starchy and sugar biomass mainly from dedicated energy crops, needing agricultural land and heavy irrigation. A retrofitting of the existing biogas plants is proposed in order to reduce competition with food crops and to increase the sustainability of the whole chain in terms of land and water consumption; moreover the use of the lignocellulosic biomass is evaluated. The biomass after physical, chemical or biological pretreatment can be digested in a biogas plant to reduce the current diet without affecting the biogas production. The present study analyzes the state of the art in the lignocellulosic biomass feeding into biogas plants and describes a preliminary techno-economical study of the pathway and the layout to be adopted, including the efficiencies and energy yields of the involved processes

Mass and Energy Flows of Cardoon Oil in a Prototype System for Seeds Milling and Vegetable Oil Treatment and Cogeneration

Abstract The experimentation was carried out in a prototype for the production of vegetable oil from seeds. The system consists of seeds storage, mill, filtration system, oil tanks and diesel engine for combined heat and power production. The vegetable oil tested is cardoon oil; cardoon biomass is the main topic of BIT3G project, that aims to develop biorefineries integrated in the territory through the use of biomass residues or sustainable energy crops (cardoon, black locust, miscanthus) in marginal lands. In this study the milling step was monitored in order to evaluate mass and energy flows; input biomass was separated into biomass residues and seeds, and each part was evaluated in terms of mass, moisture, low heating value. The milling products, vegetable oil and solid panel, were evaluated in terms of mass, moisture and energy content, estimating oil efficiency in the press and main characteristics. Finally an energy balance was performed monitoring the process energy consumption and energy potential using all obtained products, oil, panel and residues for power, heat and cooling purposes

An Innovative Tool for Technical, Environmental and Economic Design of Building Energy Plants: A Case Study in Umbria

Abstract The European goals on environmental sustainability and carbon footprint reduction should be reached by the installation of Renewable Energy Sources (RES) plants. However, the massive development of RES plants has inevitably caused new relevant problems and critical situations due to their low energy density, their social acceptance and the non-programmability of some sources. A smart tool is proposed to evaluate the integration feasibility of different energy plants; this tool is also able to estimate the environmental impacts caused by the several proposed plants for building energy production in terms of land usage, carbon footprint and water consumption. A case study, a rural tower shaped building in Umbria, is analyzed to validate the innovative tool: environmental, energy and economic parameters are calculated to allow the designer to define the best energy plant configuration

Energy refurbishment of historical buildings with public function: pilot case study

AbstractIn the last few decades, an increasing attention has been paid to the enhancement of energy performance and indoor comfort conditions of historical buildings, where the architectural heritage and artistic value do not allow typical retrofit intervention. The need to enhance the energy efficiency and environmental sustainability of historic buildings is addressed in this paper, through energy modeling and dynamic simulation of a real building with the integration of renewable energy plants for building heating and cooling. The pilot case study is "Palazzo Gallenga Stuart", a historical university building located in Perugia, Italy. The energy performance of the building has been evaluated in order to reduce the building energy demand through the implementation of high-efficiency technologies in historic buildings. The increase of the energy efficiency of the building has been pursued through the improvement of the actual energy plants' technology by introducing a more effective heat pump plant, in order to prevent the use of visually impacting external units on building historic façade

architectural and energy refurbishment of the headquarter of the university of teramo

Abstract The recent seismic events, which distressed the population of the Central Italy, have caused the incompliance with national safety standards of several historical buildings. In particular, the headquarter of the University of Teramo revealed some structural damages which make necessary to operate a restoration of the buildings. It represents a rare opportunity for investigating possible applications of a cluster of technologies and approaches largely recognized as efficient and high-performing to such particular buildings in order to achieve an upgrading in terms of energy efficiency. The proposal includes the improvement of the exploitation of renewable energy sources through adequate systems, which do not modify the visual perception of the pavilions. In that regards, the required electricity could be produced by a PV roofing installed on the parking area, while a biomass boiler and an absorption chiller could allow supplying the thermal and cooling needs. Furthermore, the rain water recovery system permits to reduce the exploitation of potable water for uses which do not require a high quality, such as irrigation. On the other hand, the envelope energy efficiency could be enhanced by applying passive strategies for reducing the heat losses ( winter conditions ) and gains ( summer conditions ) through facades and roof. The results confirmed the reliability of those interventions and the consequent advantages from an economical and energy point of view

Energy valorization of poultry manure in a thermal power plant: experimental campaign

Abstract According with EU Directives, waste management is a major task with respect to the industrial productive cycles. Getting energy from residues can be possible by means of several technologies, to be chosen as a function of the waste main properties. The present paper will present an example of energetic valorization of poultry manure in an innovative gasification thermal power plant (300 kWt). Such experience has been developed by CRB (Biomass Research Center – University of Perugia) during the implementation of a national funded research project. Physical and chemical characterization of the litter will be shown, together with both the monitoring of the demo plant performances and the relevant features of the exhaust gases at the chimney

A Batch Digester Plant for Biogas Production and Energy Enhancement of Organic Residues from Collective Activities

Abstract An innovative little-sized batch biogas plant has been recently developed by the Italian Biomass Research Centre. It was fed by the residual biomass (agriculture residues and zootechnical wastes) produced by a farm located in the countryside of Perugia, Italy. The successful experience allowed the research group to design an upgrade of the existing plant, making it replicable to every communitarian activity such as Conference Halls, Schools, Condos, where organic biomass is produced as waste. Biomass recovery from markets, canteens and little food companies represents an opportunity for the installation of new residues-powered plants, achieving the production of both electricity and thermal energy for house heating and industrial processes. The collected biomass could also be integrated with pruning or residual biomass from the maintenance of the green and the neighbouring municipal wastewater from a septic tank. The simplicity, automaticity, and the cost-effectiveness of the plant, together with the incentives from electric energy injection to the grid, made the investment payable in a few years, allowing the operator to gain from renewable sources. Little sized biogas plants solves the problem of harvesting and disposal of the organic waste, reducing its transportation costs and producing green energy. The paper presents the preliminary design of the plant

refugee camps as an opportunity for promoting alternative development strategies based on carbon credits

Abstract The difficult social issues faced by non-governmental organizations regarding planning, management, and evolution of the refugee camps led to evaluating alternative development strategies. Indeed, innovative technologies could be promoted for sustainably enhancing local economy. The present model suggests the exploitation of high-albedo materials to generate cool oases in hot climate contexts. The benefits derived by this proposal were investigated by simulating the application of high-albedo devices on shelters in Zaatari, then the avoided carbon emissions were quantified, and several scenarios were discussed. In the framework of the Emissions Trading System, the carbon credits, which can be obtained and sold by contributing to the global warming mitigation process, are estimated to be around 150,000 tons CO 2-eq . Considering the market tendencies presented during the COP21 in Paris, the intervention is demonstrated to be sustainable in economic and environmental terms. The payback period is estimated in 3 years in the most reliable scenario. The work presents the main results of a wider research that also included consideration about the urban planning of the camps

Lignin as co-product of second generation bioethanol production from ligno-cellulosic biomass

Abstract To improve the economic viability of the biofuel production from biomass, it is of increasing importance to add value to the lignin produced as a bio-residue. Moreover, to meet the goal to replace 30% of fossil fuel by biofuels by 2030, a huge amount of lignin will soon be produced. The first major step involved to add value to the unconverted lignin is its separation from other biomass constituents to give high purity lignin. In this current work, extraction of lignin from a bio-residue (containing ca. 40% lignin) from second generation bioethanol production is presented. The biomass chosen is Arundo donax L. (or giant reed), which is non-food plant, can tolerate a wide variety of ecological conditions with all types of soils, and has increasingly importance as raw material for industrial purposes as a source of fibers alternative to wood, which availability is decreasing. Slightly different extraction procedures are investigated. Methods used are simple, mild, safe, and avoid destruction of fiber content in the bio- residue, with the final aim to valorize all fractions of the bio-residue, which is an essential step to make biofuel production to be cost effective. Lignins extracted are characterized by morphological analysis, using Scanning Electron Microscopy, SEM, and in terms of thermal behavior -using thermo gravimetric analysis TGA- which is critical for determining suitability of the lignin for polymer composite preparation with improved thermomechanical performance. The method judged as the best of the three leads rapidly to extraction of lignin free from fibers and ash, with thermal behavior suitable for composite preparation

A Comparative Study on Opto-Thermal Properties of Natural Clay Bricks Incorporating Dredged Sediments

The brick industry is currently facing a shortage of natural resources. Despite this, the demand for construction bricks is progressively increasing. Alternative materials, such as dredged sediments and solid organic waste, have been recently proposed as options to replace natural clay in brick manufacturing. Potential exploitation of dredged sediments in clay bricks is evaluated in this study. The chemical composition of the mixtures and the opto-thermal properties of brick samples, which differed for the dredged sediment content (from 10% to 50% of the clay weight), were investigated. Chemical analyses detected lower concentrations of heavy metals in bricks incorporating dredged sediments (DS). Negligible variations in thermal conductivity, thermal diffusivity, and specific heat were observed by increasing the amount of DS in the mixture. In particular, the thermal conductivity values ranged between 0.45 ± 0.03 W m−1 K−1 (DS-50) and 0.50 ± 0.03 W m−1 K−1 (DS-30). Conversely, the color shift value and spectral reflectance in the infrared field were found directly proportional to the concentration of DS. Using dredged sediments as building material demonstrated to be a solution to the problem of their disposal and the scarcity of raw materials, reducing the global warming score by up to 2.8%