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Article

Characterization of Various Biomass Feedstock Suitable for Small-Scale Energy Plants as Preliminary Activity of Biocheaper Project

1
Department of Engineer, University of Perugia, via G. Duranti,63, 06125 Perugia, Italy
2
CIRIAF-CRB Section, University of Perugia, via G. Duranti,63, 06125 Perugia, Italy
3
Department for Innovation in Biological and AgroForestry Systems, University of Tuscia, via del paradiso n.47, 01100 Viterbo, Italy
*
Author to whom correspondence should be addressed.
Sustainability 2020, 12(16), 6678; https://0-doi-org.brum.beds.ac.uk/10.3390/su12166678
Submission received: 17 June 2020 / Revised: 3 August 2020 / Accepted: 11 August 2020 / Published: 18 August 2020

Abstract

:
The PRIN (Research Project with Relevant National Interest) project “Biocheaper—biomasses circular holistic economy approach to energy equipments” started in September 2019 and involves several universities: Palermo as the university coordinator, Perugia, Cassino, Enna, Pavia and Bolzano. The main goal of the project is to increase the energy efficiency and reduce the pollutants emissions in small-scale biomass plant for energy (heat and power) production. The project focuses on residual lignocellulosic feedstocks from the agriculture and forestry sector, from energy crops in marginal lands and residues from rivers maintenance. Starting from the selection and characterization of potential feedstocks, the project aims at developing some prototypes for retrofit applications in existing biomass boilers, like a mini-cyclone for the reduction of particulate emissions and an exhaust air-water condensing system for the recovery of water and the reuse in agriculture. This work presents the first results of the project, in particular regarding the selection and the chemical–physical characterization of different biomass, available in different zones of Italy; in particular the authors investigated cardoon chips, carthamus chips, olive and wine pruning, residues from rivers maintenance. Each biomass sample was characterized in terms of moisture content, ashes content, volatile substances, fixed carbon, low and high heating value, content of carbon, nitrogen, hydrogen and main metals.

1. Introduction

The main target of the PRIN project “Biocheaper—biomasses circular holistic economy approach to energy equipments” is the study of sustainable solid-biomass energy pathways for small-size plants, in order to select the best technologies for the reduction of emissions and for the reuse of byproducts of the energy conversion processes (in agriculture and other sectors), in the perspective of a circular economy. In particular, the goal for this first stage is to select, collect and perform a physico-chemical characterization of local biomasses to be used for the overall purposes of the project. The use of lignocellulosic feedstocks and in particular the residues from agriculture and forestry sectors can reduce greenhouse gas emission and improve the environmental performance of bioenergy conversion systems. Also some energy crops, like cardoon and safflower, have a potential of growing since they are cultivated on the marginal lands and would not compete with conventional crops for food and feed [1,2]. A strategic sector that could significantly contribute to solid biomass supply is the maintenance of rivers to prevent hydrogeological and fire risk. Models have been developed for the management of the forest biomass growing in riverbeds, in order to achieve the objective of risk prevention and to plan the production of biomass available for bioenergy production [3].
The national legislation on waste management promotes the reuse of the forest biomass growing in the riverbeds which, according to article 183, paragraph 1, letter n, of Legislative Decree no. 152/2006, can be harvested for energy production in derogation of the waste management laws. The mentioned biomass, after being subjected to control operations functional to the recycling and the preparation for reuse, loses the qualification of urban waste (article 184, paragraph 2, letter d), of Legislative Decree no. 152/2006), and is not subjected to the provisions on the transport, treatment and disposal of waste provided [4]. The biomass in question can now be destined to energy plants for the production of bioenergy according to the UNI EN 17225-4 standard. The valorization of different biomasses for energy generation in different thermal and/or cogeneration/polygeneration plants, allow to improve energy efficiency and reduce the environmental impacts of selected sustainable solid biomasses supply chain [5].
The small-size biomass-based heating systems market, characterized by low energy efficiency and environmental performance, the use of different innovative technologies for the retrofitting of existing systems and the development of different strategic uses of biomasses (sustainable solid biomass residues to be used in different plant typologies) will help the downscaling of successful technologies to the scale of biomass systems and cover a relevant and specific technological need [6]. The advancement of knowledge gained by the use of these innovative technologies and practices will regard both energy efficiency, reduction of particulate through innovative techniques and environmental performances through the use of retrofit-oriented, easy-to-deploy and cost-effective technical solutions.
The paper investigated the characterization of biomass performances, either energetic, physical, and chemical of different biomass feedstocks: the lignocellulosic residues of cardoon energy crop, the prunings of grapevine and olive trees and the residues from the river maintenance (turkey oak). The choice of these biomasses was dictated by their great availability on the local territory, and for what concerns olive and vine prunings and turkey oak, they represent a residue of the agro-industrial supply chain and not a virgin resource [7,8]. Cardoon represents a more interesting energy crop, one that grows very well on the marginal lands of the Umbria region, has a low demand for water and does not compete with the food supply chain. This gives the preliminary information useful to further improving the average efficiency of different supply bioenergy pathways in Italy, having investigated the best physical and chemical conditions under which to perform the energy harvesting process [9].
The mentioned characterization is a relevant and preliminary phase of the project: the obtained results in terms of chemical, physical and energetic properties of such interesting resources for supplying small-size biomass plants and boilers constitute a useful database for the scientific community. Most of the articles in this research field focus on a specific biomass, while this paper provides a critical measurement-based comparison of different opportunities for small-size plants and boiler. This is to be considered the innovative aspect of the paper, which gives data also useful for the optimization of the working phases of the aforesaid plants.

2. Materials and Methods

2.1. Biomass Sample Collection

The biomasses employed in this work were collected from two regions of Italy, specifically Umbria and Sardegna. The residual, agro-industrial biomasses such as olive and grapevine prunings were collected from the private cultivation property of one of the authors of this article, which is located in Umbria, near the Perugia countryside, while the Turkey oak, deriving from the cleaning of the river banks, were harvested from the Umbrian section of Montecalvello ditch, a river section affected by cleaning operations of the riverbed and banks. Cardoon was instead kindly provided by Matrica S.p.A (Porto Torres, Sardegna). The amount of feedstock collected was between 5 and 10 kg in weight. Before performing the analyses, the biomasses were subjected to quartering in order to obtain a homogenous and representative sample.
The samples of olive and vine prunings are mainly composed of cut branches, while the cardoon sample comprises only the stems of the plant. The feedstocks were dried under atmospheric conditions over a period of a week. The dried samples were milled into a fine powder, with a particle average size of 200 µm [10]. All experimental analyses were conducted in three replicates.

2.2. Proximate and Ultimate Analysis

Proximate analysis was carried out on each biomass to find out the amount of moisture, ash, volatile matter and fixed carbon of the analyzed samples. The analysis was carried out using a TGA-701 LECO thermogravimetric analyzer, in accord to the ASTM D 5142 protocol. A series of ceramic crucibles were weighed and then loaded with a maximum 5.0 g of powdered biomass sample. After placing the crucibles inside the instrument and closing the cover, the temperature is increased up to 900 °C under nitrogen atmosphere. The scope of ultimate analysis is to determine the percentage content of carbon, hydrogen and nitrogen of the biomass. The analyses were conducted with a TrueSpec CHN LECO elemental analyzer observing ASTM D5373 protocol for analysis and the results were expressed as dry basis of biomass [11].
The analyses were performed loading up to 0.05–0.1 g of sample into a pre-weighed tin capsule and then loaded into the CHN analyzer. The furnace was heated to 950 °C under a constant flow of helium and oxygen. Data were collected by the TrueSpec LECO software.

2.3. Higher Heat Value Determination

The higher heat value (HHV) was calculated from the elemental composition using the following [12] Equation (1):
H H V = ( 35.5 × % C + 142.3 × % H 15.4 × % O 14.5 % N ) × 10 2
where C, H, O, N are respectively carbon, hydrogen, oxygen and nitrogen composition percentages. The oxygen value was indirectly calculated by difference, assuming negligible sulfur content, using the following [12] Equation (2):
O % = 100 % a s h % C % H % N %

2.4. Analysis of Micro- and Macro- Nutrients of the Biomass

The analyses of micro- and macro- nutrients content of the biomass were conducted following UNI CEN/TS 15290:2006 protocol, using a Perkin-Elmer Optima 8000 ICP-OES Spectrophotometer [13]. The samples were first mineralized using a Milestone ETHOS ONE Microwave-assisted extractor (MAE) in order to fully oxidize all traces of organic components, leaving only the inorganic fraction of the biomass. Up to 500 mg of sample were loaded inside the MAE vessel, to which was then added 9 mL of the oxidizing solution (8:1 mixture of HNO3 and H2O2). Mineralization was conducted at a temperature of 180 °C with a heating ramp of 10 min and a hold time of 30 min.
After mineralization, the resulting solution was diluted to 50 mL and analyzed at the ICP-OES. After calibrating the instrument using calibration and reagent blanks, which are the solvent in which the samples are dissolved and the mineralization solution, respectively, the following parameters were introduced: nebulizer flow, 0.70 L/min; radio frequency power, 1450 W; sample introduction, 1.1 mL/min; flush time, 10 s; delay time, 30 s; read time, 5 s; wash time, 50 s; replicates, three (each sample read three times). Standards were prepared from 1000 ppm stock solutions and diluted with deionized water and later acidified with 67% HNO3 in order to have a final, standard solution of metal in 10% HNO3. 5-point calibration curves were registered for every analyzed metal. Table 1 shows the wavelengths selected for each metal. The amount of metal present in the biomass was reported in the Table 1, expressed in parts per million (ppm) and all calculation were done by the analysis software.

2.5. Compositional Analysis

All the biomasses used in this work were characterized in terms of cellulose, hemicellulose, acetyls, lignin and extractives content. The moisture of the samples was measured with a METTLER TOLEDO HB43-S halogen moisture analyzer, showing values equal to 2.14% of water content for grapevine pruning, 8.48% for olive pruning, 5.83% for turkey oak and 2.78% for cardoon. The biomasses samples were characterized following the NREL lap [14]. Cellulose and hemicellulose were calculated indirectly by measuring the concentration of glucose and C5 sugars through high performance liquid chromatography (HPLC) analysis using a Thermo Scientific Dionex Ultimate 3000 UHPLC after centrifugation and filtration of characterized samples through 0.22 μm nylon filters. The monomeric sugars present in the liquid fraction were measured directly by HPLC. The oligomeric sugars were determined as the difference between the total monomeric sugars obtained after acid hydrolysis of the liquid fraction (in 4% w/w H2SO4 at 121 °C for 1 h) and the monomeric sugars measured in the liquid fraction before acid hydrolysis. The UHPLC system was equipped with a Bio-rad Aminex HPX-87H column and a ERC Refractomax 520 refractive index detector. The working conditions were 0.600 mL/min, at 50 °C and with H2SO4 0.01 N mobile phase.

3. Results

A sustainable and alternative energy source, in order to be preferred to fossil fuels, should be economically viable, environmentally friendly, provide energy security, reducing greenhouse emissions, not compete with food crops and biodiversity. Under this considerations, the characterization of residual biomasses will play an important role in bioenergy production. Discovering new sources of raw materials for the production of biofuels in a sustainable way is very important, and their characterization is crucial [15].

3.1. Chemical Composition of Biomasses

The cellulose, hemicellulose, acetyls, lignin and extractives content of each biomass sample were graphically reported with a bar chart in Figure 1 and in Table 2 were reported the values for each component for better visualizing the data.
The cellulose content of these biomasses, although slightly different between each type of biomass, is high in general, showing their validity for possible use in biofuel production. Cardoon shows the highest content in cellulose (37.65%); other factors that make this biomass interesting is the low content of lignin and extractives and acetyls (3.96%), although the last in particular could negatively affect further microbial processes. Other work on the production of bioethanol using cardon harvested in Spain, showed similar composition values [16]. Hemicellulose content is similar, around 15–16%, in every considered biomass; this is due to the fact that all these biomasses are hardwood and arbustives. In case of herbaceous biomasses, hemicellulose content would have been higher [17]. The hemicellulose content is in major part hydrolyzed during pre-treatment process and recovered in liquid fraction, with the possibility of employment for other scope, like co-digestion for biogas production [18]. The acetyls content, that like previously mentioned could negatively affect the microbial fermentation, is low for each sample. The grapevine pruning and turkey oak show a higher content of lignin, equal to 28.67% and 28.01% respectively. the high content of lignin represent an obstacle for saccharification phase of bioethanol production, because don’t make the cellulose easily accessible for the enzymes [16]. For what concerns extractives, which are all the impurities or chemical compounds that can be extracted with water and ethanol and could interfere with analytical procedure, the olive pruning shows a high percentage of these extractives. This is due to its intrinsic high concentration of polyphenols (18.12%) that make this biomass not suitable for fermentation processes, as these molecules exhibit strong antioxidant and antimicrobial activities [19].

3.2. Proximate and Ultimate Analysis Results

The results of proximate analysis conducted on biomasses samples in terms of moisture content, volatile matter, ash and fixed carbon, along with their respective dry values, were reported in Table 3 and graphically in Figure 2, the graph allows for a more clear visualization of the differences among the biomasses.
The moisture content represents the quantity of water present in the biomass, expressed as a percentage of the raw material weight. High moisture content has a significantly lower carbon burn rate [20]. Among the biomasses examined in this work, the moisture content is very low and similar for each type of biomass [21]. The volatile matter of biomass is composed by condensable vapor and permanent gases (exclusive of water vapor) released when the biomass is heated to 925 °C for few minutes. During this heating, the biomass decomposes into gases and solid matter is left out as char. The presence of volatile matter in biomass influences fuel reactivity, it has been observed that an increase in the volatile matter content of the biomasssample causes, as a general tendency, an increase in the peak temperature. The peak temperature is the point on the burning profile at which the rate of weight loss due to combustion is maximum. The burning profile peak temperature is usually taken as ameasure of the reactivity of the sample [22]. The volatile matter content is also an important parameter for evaluating anaerobic digestion for biogas production [21]. The olive pruning residues could be again reutilized as anaerobic digestion raw material. The ash content represents the amount of the solid, inorganic residue left after the complete burning of the biomass. It is an integral part of plant material with a wide range of elements. The primary components of biomass ash are oxides of silica, aluminium, iron, calcium, magnesium, titanium, sodium and potassium. For example, knowing the exact composition of the ashes of a biomass aids in predicting both its tendency to form deposits in the boiler components and the composition of the char produced during pyrolysis and gasification processes, which in turn also influence the combustion rate. The percentage and composition varies according to the type of biomass [15]. Cardoon shows an ash content equal to 9.12%, greater than other samples, possessing an ash content of about 2–3% due to perennial crops having more ash than wood crops. A factor which could influence ash content is soil contamination [23]. Fixed carbon is the solid combustible residue that remains after biomass is heated and volatile matter is expelled excluding the ash and moisture content [21]. The fixed carbon and volatile matter can influence the biological conversion of the fuel. Woody biomass has a much higher fixed carbon content as compared to arbustives and perennial crops. Cardoon indeed shows 14.67% of fixed carbon, diverging from other samples that present values around 18%. Ultimate analysis, as shown in Figure 3, is mainly focused on carbon, hydrogen and nitrogen content. These elements are the major component of biomass and determine the fuel efficacy and the possible pollutant behavior [15]. Maximum carbon content was recorded in turkey oak with a value 47.63% and the minimum in the cardoon with 41.57%, although the difference between the two is low. Both hydrogen and nitrogen contents were very small compared to carbon content. Hydrogen content is practically the same in each biomass as for nitrogen, with only olive pruning showing very low nitrogen content of about 1.28%, the low nitrogen content results in a reduction of NOx production during combustion [24].
The HHV of any fuel is the energy released per unit of mass per unit of volume of the fuel when it is completely burned. The HHV refers to the condition where water is condensed out of the combustion products and represents the gross calorific value. The HHV, which is another way to represent the energetic density of these biomasses, reported in Table 4, were calculated from the elemental composition on the basis of an empirical formula and expressed in MJ/kg. The HHV of a lignocellulosic fuel is a function of its lignin content, it can be compared the HHVs with the chemical composition data. The HHVs of these lignocellulosic feedstock increase with increase of their lignin contents, demonstrate that the HHV is highly correlated with lignin content [25]. The cardoon in fact shows the lowest HHV value (14.73), while the grapevine prunings and the turkey oak show the highest values among the biomasses investigated, (19.24) and (19.22) respectively.

3.3. Micro and Macro Nutrient Composition

Table 5 shows the results of the ICP analyses performed on samples of every biomass studied in this work:
ICP measurements were done with two objectives in mind; first, in order to assess each biomass’ composition in terms of the most common micro- and macro- nutrients to determine the suitability of the biomass in thermal processes; during combustion, metals present in the biomass form reactive species which could corrode and degrade the mechanical parts of the machine [15]. It is evident how biomasses with low concentration of metals are to be preferred for this type of application. The micro nutrient concentration is correlated to the age of the plants, meaning that older plants exhibit higher concentrations of these elements [26]. For a sustainable energy system based on biomass, the nutrient substances in the ash should be recycled to the forest. The fly ash from boilers may contain high amount of unburnt carbon and not suitable for direct recycling. The high level of unburnt carbon not reflect only the inefficiency of boiler but reduce the ash stabilization and increase the volume of fly produced [26]. To enable recycling, the boiler combustion efficiency must be improved. From the collected data, high concentration of all of the investigated species suggest the possibility of employing all the considered biomasses in biogas production processes, while instead use as a fuel should be avoided, unless very efficient plants are used.

4. Conclusions

The first activities of the “Biocheaper” project were performed through the selection and collection of four lignocellulosic biomass typologies and the characterization of the samples to determine their possible applications in small-scale energy plants. The aim of the project is the efficient retrofitting of existing old plants in combination with the reutilization of agro-industrial residues. With this in mind, the complete characterization of the local biomasses is a crucial information to obtain in order to proceed on this way. All the selected biomasses showed concentrations of ashes around 2%, but cardoon residues showed more than 9%. The higher ash content and the higher moisture content are negative aspects to be considered for small scale biomass boilers supply. Higher heating values are also similar between samples and around 19 MJ/kg, except for cardoon which shows approximately 15 MJ/kg, lower than the others, data in correlation with its lowest lignin content. In light of these considerations, it can be said that cardoon is not recommended as a fuel for small energy production plants, but shows interesting value for bio-ethanol production or other bio-product. The concentrations of the micro- and macro-elements analyzed are compatible with the use as biofuels in small-scale applications. In the next stages of the Biocheaper project, the collected data will be used as preliminary information to carry out the fluidodynamics simulations and the test performances into biomass boilers.

Author Contributions

A.B. and A.P., carried out analysis on the biomasses, G.C. designed the study and drafted the manuscript, V.C., A.F. and A.N. drafted the manuscript, and F.C. designed the study and supervised the research. All authors read and approved the manuscript.

Funding

This study was funded by the Italian Ministry for Education and Scientific Research (MIUR) through the project: “BIOmasses Circular Holistic Economy Approach to EneRgy equipment (BIO-CHEAPER) (Projeckt prot. PRIN 2017_20175TXJER).

Acknowledgments

We would like to thank Matrica for supplying the cardoon biomass and Cantine Giorgio Lungarotti for supplying the grapevine prunings used in the experimentation.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Patel, M.; Zhang, X.; Kumar, A. Techno-economic and life cycle assessment on lignocellulosic biomass thermochemical conversion technologies: A review. Renew. Sustain. Energy Rev. 2016, 53, 1486–1499. [Google Scholar] [CrossRef]
  2. Cotana, F.; Cavalaglio, G.; Coccia, V.; Petrozzi, A. Energy opportunities from lignocellulosic biomass for a biorefinery case study. Energies 2016, 9, 748. [Google Scholar] [CrossRef]
  3. Pedrazzi, S.; Allesina, G.; Morselli, N.; Puglia, M.; Barbieri, L.; Lancellotti, I.; Ceotto, E.; Cappelli, G.A.; Ginaldi, F.; Giorgini, L. The energetic recover of biomass from river maintenance: The REBAF project. In Proceedings of the 25th European Biomass Conference and Exhibition, Stockholm, Sweden, 12–15 July 2017; pp. 12–15. [Google Scholar]
  4. Lgs, D. 152/2006. Decreto Legislativo; Istituto Poligrafico e Zecca dello Stato: Rome, Italy, 2006. [Google Scholar]
  5. Vakalis, S.; Baratieri, M. Calculating the overall efficiency of polygeneration plants–introducing an integrated thermodynamic decision tool for biomass gasification. In Proceedings of the Symbiosis International Conference 2014, Athens, Greece, 19–21 June 2014. [Google Scholar]
  6. Maraver, D.; Sin, A.; Royo, J.; Sebastián, F. Assessment of CCHP systems based on biomass combustion for small-scale applications through a review of the technology and analysis of energy efficiency parameters. Appl. Energy 2013, 102, 1303–1313. [Google Scholar] [CrossRef]
  7. Torquati, B.; Marino, D.; Venanzi, S.; Porceddu, P.; Chiorri, M. Using tree crop pruning residues for energy purposes: A spatial analysis and an evaluation of the economic and environmental sustainability. Biomass Bioenergy 2016, 95, 124–131. [Google Scholar] [CrossRef]
  8. Cavalaglio, G.; Cotana, S. Recovery of vineyards pruning residues in an agro-energetic chain. Peach 2007, 2, 6. [Google Scholar]
  9. Angelini, L.G.; Ceccarini, L.; o Di Nasso, N.N.; Bonari, E. Long-term evaluation of biomass production and quality of two cardoon (Cynara cardunculus L.) cultivars for energy use. Biomass Bioenergy 2009, 33, 810–816. [Google Scholar] [CrossRef]
  10. Hames, B.; Ruiz, R.; Scarlata, C.; Sluiter, A.; Sluiter, J.; Templeton, D. Preparation of samples for compositional analysis. Lab. Anal. Proced. (LAP) 2008, 1617, 1–10. [Google Scholar]
  11. ASTM International. D5373-93 (1997): Standard Methods for Instrumental Determination of Carbon, Hydrogen, and Nitrogen in Laboratory Samples of Coal and Coke; ASTM International: West Conshohocken, PA, USA, 1993. [Google Scholar]
  12. Zhang, L.; Xu, C.C.; Champagne, P. Energy recovery from secondary pulp/paper-mill sludge and sewage sludge with supercritical water treatment. Bioresour. Technol. 2010, 101, 2713–2721. [Google Scholar] [CrossRef] [PubMed]
  13. Telmo, C.; Lousada, J.; Moreira, N. Proximate analysis, backwards stepwise regression between gross calorific value, ultimate and chemical analysis of wood. Bioresour. Technol. 2010, 101, 3808–3815. [Google Scholar] [CrossRef] [PubMed]
  14. Sluiter, A.; Hames, B.; Ruiz, R.; Scarlata, C.; Sluiter, J.; Templeton, D.; Crocker, D. Determination of structural carbohydrates and lignin in biomass. Lab. Anal. Proced. 2008, 1617, 1–16. [Google Scholar]
  15. Singh, Y.D.; Mahanta, P.; Bora, U. Comprehensive characterization of lignocellulosic biomass through proximate, ultimate and compositional analysis for bioenergy production. Renew. Energy 2017, 103, 490–500. [Google Scholar] [CrossRef]
  16. Vergara, P.; Ladero, M.; García-Ochoa, F.; Villar, J.C. Pre-treatment of corn stover, Cynara cardunculus L. stems and wheat straw by ethanol-water and diluted sulfuric acid: Comparison under different energy input conditions. Bioresour. Technol. 2018, 270, 449–456. [Google Scholar] [CrossRef] [PubMed]
  17. Iyer, P.V.; Wu, Z.-W.; Kim, S.B.; Lee, Y.Y. Ammonia recycled percolation process for pretreatment of herbaceous biomass. Appl. Biochem. Biotechnol. 1996, 57, 121. [Google Scholar] [CrossRef]
  18. Dos Santos, L.C.; Adarme, O.F.H.; Baêta, B.E.L.; Gurgel, L.V.A.; de Aquino, S.F. Production of biogas (methane and hydrogen) from anaerobic digestion of hemicellulosic hydrolysate generated in the oxidative pretreatment of coffee husks. Bioresour. Technol. 2018, 263, 601–612. [Google Scholar] [CrossRef]
  19. Conde, E.; Cara, C.; Moure, A.; Ruiz, E.; Castro, E.; Domínguez, H. Antioxidant activity of the phenolic compounds released by hydrothermal treatments of olive tree pruning. Food Chem. 2009, 114, 806–812. [Google Scholar] [CrossRef]
  20. Grandesso, E.; Gullett, B.; Touati, A.; Tabor, D. Effect of moisture, charge size, and chlorine concentration on PCDD/F emissions from simulated open burning of forest biomass. Environ. Sci. Technol. 2011, 45, 3887–3894. [Google Scholar] [CrossRef]
  21. Cai, J.; He, Y.; Yu, X.; Banks, S.W.; Yang, Y.; Zhang, X.; Yu, Y.; Liu, R.; Bridgwater, A.V. Review of physicochemical properties and analytical characterization of lignocellulosic biomass. Renew. Sustain. Energy Rev. 2017, 76, 309–322. [Google Scholar] [CrossRef] [Green Version]
  22. Haykırı-Açma, H. Combustion characteristics of different biomass materials. Energy Convers. Manag. 2003, 44, 155–162. [Google Scholar] [CrossRef]
  23. Coulson, M.; Dahl, J.; Gansekoele, E.; Bridgwater, A.; Obernberger, I.; Van de Beld, L. Ash characteristics of perennial energy crops and their influence on thermal processing. In Proceedings of the 2nd World Biomass Conference, Rome, Italy, 10–14 May 2004; pp. 359–362. [Google Scholar]
  24. Thomas, K.M. The release of nitrogen oxides during char combustion. Fuel 1997, 76, 457–473. [Google Scholar] [CrossRef]
  25. Demirbas, A. Relationships between Heating Value and Lignin, Moisture, Ash and Extractive Contents of Biomass Fuels. Energy Explor. Exploit. 2002, 20, 105–111. [Google Scholar] [CrossRef]
  26. Demirbaş, A. Heavy metal contents of fly ashes from selected biomass samples. Energy Sources 2005, 27, 1269–1276. [Google Scholar] [CrossRef]
Figure 1. Chemical composition of each biomass.
Figure 1. Chemical composition of each biomass.
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Figure 2. Graphical representation of proximate analysis conducted with TGA, in the graph are distinguished on a dry basis from those on the raw material.
Figure 2. Graphical representation of proximate analysis conducted with TGA, in the graph are distinguished on a dry basis from those on the raw material.
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Figure 3. Ultimate analysis for the biomass samples.
Figure 3. Ultimate analysis for the biomass samples.
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Table 1. Wavelength selected for the reading the investigated metals.
Table 1. Wavelength selected for the reading the investigated metals.
MetalWavelength (nm)
P21.914
Mg285.213
Na589.592
K766.490
Ca315.887
Fe238.204
Cu327.393
Al308.215
Table 2. Chemical composition of each biomass.
Table 2. Chemical composition of each biomass.
CelluloseHemicelluloseAcetylsLigninExtractives
Cardoon37.65%16.70%3.96%17.51%5.55%
Grapevine prunings30.70%16.32%5.43%28.67%7.33%
Olive prunings29.70%15.58%3.42%17.22%18.12%
River bank residues35.56%15.19%4.29%28.01%7.34%
Table 3. TGA analysis results for each sample investigated.
Table 3. TGA analysis results for each sample investigated.
MoistureVolatile MatterAshFixed CarbonDry Volatile MatterDry AshDry Fixed Carbon
cardoon8.38%68.17%9.12%14.67%74.14%9.91%15.95%
grapevine pruning7.22%71.45%2.68%18.98%76.73%2.87%20.39%
olive pruning5.56%74.63%1.94%17.87%79.03%2.05%18.93%
River bank residues6.19%73.25%2.25%18.31%78.09%2.40%19.42%
Table 4. HHV expressed in MJ/kg for each biomass.
Table 4. HHV expressed in MJ/kg for each biomass.
SampleHHV (MJ/kg)
Cardoon14.73
Grapevine pruning19.24
Olive pruning18.62
Turkey oak19.22
Table 5. Macroelements analysed with ICP for each sample.
Table 5. Macroelements analysed with ICP for each sample.
ElementConcentration (mg/kg)
CardoonGrapevine Olive Turkey Oak
P11,387.721,159.512,752.7437.278
Mg7335.0426,909.68665.55493.107
Na51,214510,2291503.850.57956
K186,35585,429.541,801.303145.38
Ca182,968150,563110,2006654.87
Fe263,6048161.55237.33111.909
Cu445,788458,507131,9142.94479
Al3323.2211,476.9729,48391.1731

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Cavalaglio, G.; Cotana, F.; Nicolini, A.; Coccia, V.; Petrozzi, A.; Formica, A.; Bertini, A. Characterization of Various Biomass Feedstock Suitable for Small-Scale Energy Plants as Preliminary Activity of Biocheaper Project. Sustainability 2020, 12, 6678. https://0-doi-org.brum.beds.ac.uk/10.3390/su12166678

AMA Style

Cavalaglio G, Cotana F, Nicolini A, Coccia V, Petrozzi A, Formica A, Bertini A. Characterization of Various Biomass Feedstock Suitable for Small-Scale Energy Plants as Preliminary Activity of Biocheaper Project. Sustainability. 2020; 12(16):6678. https://0-doi-org.brum.beds.ac.uk/10.3390/su12166678

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Cavalaglio, Gianluca, Franco Cotana, Andrea Nicolini, Valentina Coccia, Alessandro Petrozzi, Alessandro Formica, and Alessandro Bertini. 2020. "Characterization of Various Biomass Feedstock Suitable for Small-Scale Energy Plants as Preliminary Activity of Biocheaper Project" Sustainability 12, no. 16: 6678. https://0-doi-org.brum.beds.ac.uk/10.3390/su12166678

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