Showing total 10 results

1. Characterization of products obtained from pyrolysis and steam gasification of wood waste, RDF, and RPF.

Author

Hwang IH, Kobayashi J, and Kawamoto K

Subjects

Models, Chemical, Paper, Plastics chemistry, Steam, Wood chemistry, Energy-Generating Resources statistics & numerical data, Incineration methods, Refuse Disposal methods, Waste Products analysis, Wood analysis

Abstract

Pyrolysis and steam gasification of woody biomass chip (WBC) obtained from construction and demolition wastes, refuse-derived fuel (RDF), and refuse paper and plastic fuel (RPF) were performed at various temperatures using a lab-scale instrument. The gas, liquid, and solid products were examined to determine their generation amounts, properties, and the carbon balance between raw material and products. The amount of product gas and its hydrogen concentration showed a considerable difference depending on pyrolysis and steam gasification at higher temperature. The reaction of steam and solid product, char, contributed to an increase in gas amount and hydrogen concentration. The amount of liquid products generated greatly depended on temperature rather than pyrolysis or steam gasification. The compositions of liquid product varied relying on raw materials used at 500°C but the polycyclic aromatic hydrocarbons became the major compounds at 900°C irrespective of the raw materials used. Almost fixed carbon (FC) of raw materials remained as solid products under pyrolysis condition whereas FC started to decompose at 700°C under steam gasification condition. For WBC, both char utilization by pyrolysis at low temperature (500°C) and syngas recovery by steam gasification at higher temperature (900°C) might be practical options. From the results of carbon balance of RDF and RPF, it was confirmed that the carbon conversion to liquid products conspicuously increased as the amount of plastic increased in the raw material. To recover feedstock from RPF, pyrolysis for oil recovery at low temperature (500°C) might be one of viable options. Steam gasification at 900°C could be an option but the method of tar reforming (e.g. catalyst utilization) should be considered., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2014

2. Gaseous fuel production from nonrecyclable paper wastes by using supported metal catalysts in high-temperature liquid water.

Author

Yamaguchi A, Hiyoshi N, Sato O, Bando KK, and Shirai M

Subjects

Catalysis, Gases, Hot Temperature, Hydrogen, Metals, Methane, Water, Biofuels, Conservation of Natural Resources methods, Energy-Generating Resources, Industrial Waste prevention & control, Paper

Abstract

Paper wastes are used for the production of gaseous fuels over supported metal catalysts. The gasification of the nonrecyclable paper wastes, such as shredded documents and paper sludge, is carried out in high-temperature liquid water. The order of the catalytic activity for the gasification is found to be ruthenium>rhodium>>platinum>>palladium. A charcoal-supported ruthenium catalyst (Ru/C) is the most effective for the gasification of paper and cellulose. Paper wastes are gasified to a limited degree (32.6 carbon %) for 30 min in water at 523 K to produce methane and carbon dioxide, with a small amount of hydrogen. At 573 K, more complete gasification with almost 100 carbon % is achieved within 10 min in water. At 523 K, the gas yield of paper gasification over Ru/C is higher than that of cellulose powder. The gas yields are increased by ball-milling treatment of the recycled paper and cellulose powder. Printed paper wastes are also gasified at 523 K in water.

Published

2010

3. Pyrolysis of municipal plastic wastes: Influence of raw material composition.

Author

López A, de Marco I, Caballero BM, Laresgoiti MF, and Adrados A

Subjects

Carbon Dioxide analysis, Carbon Monoxide analysis, Catalysis, Cities, Conservation of Natural Resources, Gases analysis, Metals analysis, Metals chemistry, Paper, Energy-Generating Resources, Hot Temperature, Incineration, Industrial Waste analysis, Plastics chemistry

Abstract

The objective of this work is the study of pyrolysis as a feedstock recycling process, for valorizing the rejected streams that come from industrial plants, where packing and packaging wastes are classified and separated for their subsequent mechanical recycling. Four real samples collected from an industrial plant at four different times of the year, have been pyrolysed under nitrogen in a 3.5dm(3) autoclave at 500 degrees C for 30min. Pyrolysis liquids are a complex mixture of organic compounds containing valuable chemicals as styrene, ethyl-benzene, toluene, etc. Pyrolysis solids are composed of the inorganic material contained in the raw materials, as well as of some char formed in the pyrolysis process, and pyrolysis gases are mainly composed of hydrocarbons together with some CO and CO(2), and have very high gross calorific values (GCV). It has been proved by the authors that the composition of the raw material (paper, film, and metals contents) plays a significant role in the characteristics of pyrolysis products. High paper content yields water in the pyrolysis liquids, and CO and CO(2) in the gases, high PE film content gives rise to high viscosity liquids, and high metals content yields more aromatics in the liquid products, which may be attributed to the metals catalytic effect., (Copyright 2009 Elsevier Ltd. All rights reserved.)

Published

2010

4. Emissions of particulate matter, carbon monoxide and nitrogen oxides from the residential burning of waste paper briquettes and other fuels

Author

Phong K. Thai, Ali Mohammad Pourkhesalian, Lidia Morawska, Svetlana Stevanovic, Meng Xiu, and Md. Mostafizur Rahman

Subjects

Paper, Energy-Generating Resources, Briquette, 020209 energy, Air pollution, 02 engineering and technology, 010501 environmental sciences, medicine.disease_cause, Combustion, 01 natural sciences, Biochemistry, Fires, Heating, Criteria air contaminants, 0202 electrical engineering, electronic engineering, information engineering, medicine, Coal, 0105 earth and related environmental sciences, General Environmental Science, Air Pollutants, Carbon Monoxide, Waste management, business.industry, Australia, Particulates, Wood, Waste treatment, Environmental science, Nitrogen Oxides, Particulate Matter, Heat of combustion, business

Abstract

Using waste paper as fuel for domestic heating is a beneficial recycling option for small island developing states where there are lacks of resources for energy and waste treatment. However, there are concerns about the impact of air pollutants emitted from the burning of the self-made paper briquettes as household air pollution is recognised as the greatest environmental risk for human. In this study, combustion tests were carried out for paper briquettes made in one Pacific island and three commercial fuels in Australia including wood briquettes, kindling firewood and coal briquettes in order to: 1) characterise the emissions of three criteria air pollutants including particulate matters, CO and NOx including their emission factors (EF) from the tested fuels; and 2) compare the EFs among the tested fuels and with others reported in the literature. The results showed that waste paper briquettes burned quickly and generated high temperature but the heat value is relatively low. Paper briquettes and coal briquettes produced higher CO concentration than the others while paper briquettes generated the highest NOx level. Only PM2.5 concentration emitted from paper briquettes was similar to kindling firewood and lower than wood briquettes. Burning of paper briquettes and wood briquettes produced particulate matter with large average count median diameter (72 and 68 nm) than coal briquette and kindling firewood (45 and 51 nm). The EFs for CO, NOx and PM2.5 of paper briquettes were within the range of EFs reported in this study as well as in the literature. Overall, the results suggested that using paper briquettes as fuel for domestic heating will not likely to generate higher level of three major air pollutants compared to other traditional fuels.

Published

2018

5. Mass, energy and material balances of SRF production process. Part 1: SRF produced from commercial and industrial waste

Author

Pasi Vainikka, Janne Hannula, Markku Hurme, Muhammad Nasrullah, and Janne Kärki

Subjects

Paper, Energy-Generating Resources, Mass flow, Industrial Waste, input and output streams, Fraction (chemistry), Incineration, STREAMS, Industrial waste, Magnetics, Natural rubber, Recycling, mechanical treatment, Waste Management and Disposal, Refuse-derived fuel, Waste Products, Waste management, Air, material balances, Temperature, cardboard, Equipment Design, Refuse Disposal, Commercial and industrial waste, Biofuels, visual_art, visual_art.visual_art_medium, Environmental science, Rubber, solid recovered fuel, Plastics, Mass fraction

Abstract

This paper presents the mass, energy and material balances of a solid recovered fuel (SRF) production process. The SRF is produced from commercial and industrial waste (C&IW) through mechanical treatment (MT). In this work various streams of material produced in SRF production process are analyzed for their proximate and ultimate analysis. Based on this analysis and composition of process streams their mass, energy and material balances are established for SRF production process. Here mass balance describes the overall mass flow of input waste material in the various output streams, whereas material balance describes the mass flow of components of input waste stream (such as paper and cardboard, wood, plastic (soft), plastic (hard), textile and rubber) in the various output streams of SRF production process. A commercial scale experimental campaign was conducted on an MT waste sorting plant to produce SRF from C&IW. All the process streams (input and output) produced in this MT plant were sampled and treated according to the CEN standard methods for SRF: EN 15442 and EN 15443. The results from the mass balance of SRF production process showed that of the total input C&IW material to MT waste sorting plant, 62% was recovered in the form of SRF, 4% as ferrous metal, 1% as non-ferrous metal and 21% was sorted out as reject material, 11.6% as fine fraction, and 0.4% as heavy fraction. The energy flow balance in various process streams of this SRF production process showed that of the total input energy content of C&IW to MT plant, 75% energy was recovered in the form of SRF, 20% belonged to the reject material stream and rest 5% belonged with the streams of fine fraction and heavy fraction. In the material balances, mass fractions of plastic (soft), plastic (hard), paper and cardboard and wood recovered in the SRF stream were 88%, 70%, 72% and 60% respectively of their input masses to MT plant. A high mass fraction of plastic (PVC), rubber material and non-combustibles (such as stone/rock and glass particles), was found in the reject material stream

Published

2014

6. Characterization of products obtained from pyrolysis and steam gasification of wood waste, RDF, and RPF

Author

In Hee Hwang, Jun Kobayashi, and Katsuya Kawamoto

Subjects

Paper, Waste Products, Energy-Generating Resources, Materials science, Waste management, Biomass, Tar, Incineration, Raw material, Wood, Refuse Disposal, Steam, Models, Chemical, Char, Plastics, Waste Management and Disposal, Refuse-derived fuel, Pyrolysis, Syngas

Abstract

Pyrolysis and steam gasification of woody biomass chip (WBC) obtained from construction and demolition wastes, refuse-derived fuel (RDF), and refuse paper and plastic fuel (RPF) were performed at various temperatures using a lab-scale instrument. The gas, liquid, and solid products were examined to determine their generation amounts, properties, and the carbon balance between raw material and products. The amount of product gas and its hydrogen concentration showed a considerable difference depending on pyrolysis and steam gasification at higher temperature. The reaction of steam and solid product, char, contributed to an increase in gas amount and hydrogen concentration. The amount of liquid products generated greatly depended on temperature rather than pyrolysis or steam gasification. The compositions of liquid product varied relying on raw materials used at 500 °C but the polycyclic aromatic hydrocarbons became the major compounds at 900 °C irrespective of the raw materials used. Almost fixed carbon (FC) of raw materials remained as solid products under pyrolysis condition whereas FC started to decompose at 700 °C under steam gasification condition. For WBC, both char utilization by pyrolysis at low temperature (500 °C) and syngas recovery by steam gasification at higher temperature (900 °C) might be practical options. From the results of carbon balance of RDF and RPF, it was confirmed that the carbon conversion to liquid products conspicuously increased as the amount of plastic increased in the raw material. To recover feedstock from RPF, pyrolysis for oil recovery at low temperature (500 °C) might be one of viable options. Steam gasification at 900 °C could be an option but the method of tar reforming (e.g. catalyst utilization) should be considered.

Published

2014

7. Gaseous fuel production from nonrecyclable paper wastes by using supported metal catalysts in high-temperature liquid water

Author

Kyoko K. Bando, Norihito Hiyoshi, Aritomo Yamaguchi, Masayuki Shirai, and Osamu Sato

Subjects

Paper, Conservation of Natural Resources, Energy-Generating Resources, Materials science, Hot Temperature, Hydrogen, General Chemical Engineering, chemistry.chemical_element, Industrial Waste, Methane, Catalysis, Rhodium, chemistry.chemical_compound, Fuel gas, Environmental Chemistry, Organic chemistry, General Materials Science, Cellulose, Water, Ruthenium, General Energy, chemistry, Chemical engineering, Metals, Biofuels, Gases, Carbon

Abstract

Paper wastes are used for the production of gaseous fuels over supported metal catalysts. The gasification of the nonrecyclable paper wastes, such as shredded documents and paper sludge, is carried out in high-temperature liquid water. The order of the catalytic activity for the gasification is found to be ruthenium > rhodium >> platinum >> palladium. A charcoal-supported ruthenium catalyst (Ru/C) is the most effective for the gasification of paper and cellulose. Paper wastes are gasified to a limited degree (32.6 carbon%) for 30 min in water at 523 K to produce methane and carbon dioxide, with a small amount of hydrogen. At 573 K, more complete gasification with almost 100 carbon % is achieved within 10 min in water. At 523 K, the gas yield of paper gasification over Ru/C is higher than that of cellulose powder. The gas yields are increased by ball-milling treatment of the recycled paper and cellulose powder. Printed paper wastes are also gasified at 523 K in water.

Published

2010

8. Production of pulp from Salix viminalis energy crops using the FIRSST process

Author

Jean-Michel Lavoie, Henri Gauvin, Esteban Chornet, and Eva Capek-Menard

Subjects

Paper, Energy-Generating Resources, Environmental Engineering, Bioengineering, engineering.material, Kappa number, complex mixtures, Lignin, chemistry.chemical_compound, stomatognathic system, Polysaccharides, Biomass, Cellulose, Waste Management and Disposal, Chromatography, High Pressure Liquid, Ethanol, Renewable Energy, Sustainability and the Environment, Pulp (paper), Salix, General Medicine, Pulp and paper industry, Biorefinery, Wood, stomatognathic diseases, Kraft process, chemistry, Biofuels, Soda pulping, engineering, Kraft paper, Biotechnology

Abstract

In this work, isolation of the cellulose fibres was carried out via the Feedstock Impregnation Rapid and Sequential Steam Treatment process (FIRSST). The latter allows the separation of extractives, hemicellulosic sugars and lignin isolating the cellulose fibres. Quantitative data on the constitutive macromolecules of biomass was obtained using ASTM or TAPPI standard methods. Carbohydrates found in the hemicelluloses were also quantified using HPLC. Kraft pulp from whole biomass has also been produced at a bench scale (few kg per batch) using known and established pulping conditions. The pulps from both pulping techniques were tested following ATTPC standard methods. Pulp yields were of 34% for the classical Kraft processes (using whole biomass) while the FIRSST process showed yields around 30%. The average fibre lengths were similar for FIRSST pulp (0.39 mm) and Kraft pulp (0.41 mm) and the mechanical properties of the FIRSST pulp were as good as those of the Kraft pulp.

Published

2009

9. Physical and Chemical Processes for Solid Waste Treatment Applied To a Crewed Space Habitat

Author

George M. Savage

Subjects

Paper, Chemical process, Conservation of Natural Resources, Energy-Generating Resources, Engineering, Environmental Engineering, Municipal solid waste, Forms of energy, Air Conditioning, Cellulose, Oxidized, Spacecraft, Resource recovery, Energy recovery, Ethanol, Waste management, Weightlessness, business.industry, Space Flight, Pollution, Refuse Disposal, Waste treatment, business, Ecological Systems, Closed, Life Support Systems, Space habitat

Abstract

Solid wastes can be processed for material and energy recovery using a number of unit operations and system approaches. The selection and configuration of unit operations and systems depends upon the characteristics of the wastes to be processed and the uses for recovered secondary materials and for recovered energy forms. The discussion focuses on the types of materials and forms of energy potentially recoverable from solid wastes, waste processing and conversion systems, and design considerations.

Published

1991

10. Oxidative lime pretreatment of high-lignin biomass: poplar wood and newspaper

Author

Mark T. Holtzapple, Vincent S. Chang, Murlidhar Nagwani, and Chul-Ho Kim

Subjects

Paper, Energy-Generating Resources, Carbohydrates, Biomass, Conservation of Energy Resources, Bioengineering, Cellulase, Xylose, engineering.material, Applied Microbiology and Biotechnology, Biochemistry, Lignin, chemistry.chemical_compound, Botany, Hardwood, Food science, Sugar, Molecular Biology, Lime, chemistry.chemical_classification, biology, Hydrolysis, Oxides, General Medicine, Calcium Compounds, Chemical Engineering, Wood, Reducing sugar, chemistry, biology.protein, engineering, Oxidation-Reduction, Biotechnology

Abstract

Lime (Ca[OH]2) and oxygen (O2) were used to enhance the enzymatic digestibility of two kinds of high-lignin biomass: poplar wood and newspaper. The recommended pretreatment conditions for poplar wood are 150 degrees C, 6 h, 0.1 g of Ca(OH)2/g of dry biomass, 9 mL of water/g of dry biomass, 14.0 bar absolute oxygen, and a particle size of -10 mesh. Under these conditions, the 3-d reducing sugar yield of poplar wood using a cellulase loading of 5 filter paper units (FPU)/g of raw dry biomass increased from 62 to 565 mg of eq. glucose/g of raw dry biomass, and the 3-d total sugar (glucose + xylose) conversion increased from 6 to 77% of raw total sugars. At high cellulase loadings (e.g., 75 FPU/g of raw dry biomass), the 3-d total sugar conversion reached 97%. In a trial run with newspaper, using conditions of 140 degrees C, 3 h, 0.3 g of Ca(OH)2/g of dry biomass, 16 mL of water/g of dry biomass, and 7.1 bar absolute oxygen, the 3-d reducing sugar yield using a cellulase loading of 5 FPU/g of raw dry biomass increased from 240 to 565 mg of eq. glucose/g of raw dry biomass. A material balance study on poplar wood shows that oxidative lime pretreatment solubilized 38% of total biomass, including 78% of lignin and 49% of xylan; no glucan was removed. Ash increased because calcium was incorporated into biomass during the pretreatment. After oxidative lime pretreatment, about 21% of added lime could be recovered by CO2 carbonation.

Published

2000