Eucalyptus bark: A new source of fiber from the wood pulp industry for feeding to beef feedlot cattle

Juan Clariget; Alejandro La Manna; Santiago Luzardo; Eduardo Perez; Enrique Fernández; Gonzalo Roig; Valentín Aznárez; Georgget Banchero

doi:10.15232/aas.2020-02002

In Situ Avoidance Response Of Adult Atlantic Salmon To Waste From The Wood Pulp Industry

Water Air & Soil Pollution ◽

10.1007/s11270-005-5418-9 ◽

2005 ◽

Vol 165 (1-4) ◽

pp. 187-194 ◽

Cited By ~ 9

Author(s):

Eva B. Thorstad ◽

Torbjørn Forseth ◽

Ingar Aasestad ◽

Finn ØKland ◽

Bjørn Ove Johnsen

Keyword(s):

Atlantic Salmon ◽

Avoidance Response ◽

Wood Pulp ◽

Pulp Industry

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THE IMPACT OF POLYSACCHARIDE CHEMISTRY ON THE WOOD PULP INDUSTRY

27th International Congress of Pure and Applied Chemistry ◽

10.1016/b978-0-08-023936-1.50030-7 ◽

1980 ◽

pp. 291-298

Author(s):

Olof Samuelson

Keyword(s):

Wood Pulp ◽

Pulp Industry ◽

The Impact

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FOREST RESOURCES AND THE WOOD PULP INDUSTRY IN AUSTRALIA

Australian Forestry ◽

10.1080/00049158.1964.10674113 ◽

1964 ◽

Vol 28 (1) ◽

pp. 51-57

Author(s):

A. J. Leslie

Keyword(s):

Wood Pulp ◽

Forest Resources ◽

Pulp Industry

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Modern technologies in the pulp industry

Известия СПбЛТА ◽

10.21266/2079-4304.2018.223.267-284 ◽

2018 ◽

Author(s):

Е.Д. Софронова ◽

В.А. Липин

Keyword(s):

Textile Industry ◽

Single Point ◽

Black Liquor ◽

Wood Pulp ◽

Raw Material ◽

Cellulose Esters ◽

Pulp Industry ◽

Wood Processing ◽

Polymer Industry ◽

Modern Technologies

Целлюлоза, являясь природным полимером, имеет огромный потенциал использования в полимерной промышленности. Главным видом сырья для получения сложных эфиров целлюлозы является хлопок благодаря своему высокому содержанию «чистой» целлюлозы. Также позволяют достигать ее высокого качества современные технологии химической переработки древесной целлюлозы. Развитие целлюлозной промышленности идет по пути создания биокомплексов по переработке древесины, где происходит максимально полное использование древесного сырья с целью получения различных видов продукции при низкой экологической нагрузке на окружающую среду. Экстрагирование из образующегося черного щелока различных компонентов в виде глюкозы, гемицеллюлоз, экстрактивных веществ и лигнина позволяет при дальнейшей переработке использовать в медицине, в виде биотоплива, текстильной промышленности для придания определённых качеств и в других областях. Технология газификации черного щелока позволяет получить биотопливо в виде метана или диметилового эфира. Двухступенчатая кислородно-щелочная отбелка позволяет достигнуть более «мягких» условий для извлечения нецеллюлозных компонентов, лигнина и экстрактивных веществ. Экологичность производства является еще одним направлением активного развития технологии переработки древесины. Сбор и сжигание неконденсируемых газов, создание одной точки сброса очищенных газов, применение нетоксичных отбельных реагентов позволяет снизить нагрузку на окружающую среду. Технология газификации, которая обеспечивает экологически чистое производство биогаза для нужд завода, позволяет прекратить использование ископаемых видов топлива, а также позволяет получать и жидкие виды топлива, например, бензин. Современные реалии развития полимерной отрасли создают отличную конкурентную среду для раскрытия потенциала древесной целлюлозы. Возможны также варианты коренной модернизации целлюлозного производства на основе энергосберегающей и экологически безопасной технологии. Cellulose – as a natural polymer, has a huge potential for use in the polymer industry. The main type of raw material for the production of cellulose esters is cotton due to its high content of «pure» cellulose. Also, modern technologies of chemical processing of wood pulp can be achieved to its high quality. The development of the pulp industry follows the path of creating biocomplexes for wood processing, where the maximum use of wood raw materials takes place in order to obtain various types of products with low environmental load on the environment. Extraction of various components in the form of glucose, hemicelluloses, extractives and lignin from the formed black liquor allows to use in the medicine, in the form of biofuel, the textile industry for imparting certain qualities in other areas. The technology of gasification of black liquor allows to obtain biofuel in the form of methane or dimethyl ether. Two- stage oxygen-alkaline bleaching allows to achieve more «soft» conditions for extraction of non-cellulose components, lignin and extractives. Environmental friendliness of production is another area of active development of wood processing technology. The collection and combustion of non-condensable gases, the creation of a single point for the discharge of purified gases, the use of non-toxic bleaching agents, can reduce the burden on the environment. Gasification technology that provides environmentally friendly production of biogas for the needs of the plant, allows to stop the use of fossil fuels, and also allows to receive also liquid fuels, for example, gasoline. The current realities of the development of the polymer industry create an excellent competitive environment for revealing the potential of wood pulp. Variants of radical modernization of cellulose production on the basis of energy-saving and environmentally safe technology are also possible.

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Optimal atmospheric emission control in the wood pulp industry

Atmospheric Environment (1967) ◽

10.1016/0004-6981(72)90124-2 ◽

1972 ◽

Vol 6 (2) ◽

pp. 93-102

Author(s):

J.P. Heaney ◽

L. Doughty

Keyword(s):

Emission Control ◽

Wood Pulp ◽

Atmospheric Emission ◽

Pulp Industry

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Environmental auditing in India: A case study from the wood pulp industry

Environmental Quality Management ◽

10.1002/tqem.20176 ◽

2008 ◽

Vol 17 (3) ◽

pp. 55-65 ◽

Cited By ~ 1

Author(s):

N. S. Raman ◽

Mamta Makode ◽

Sukumar Devotta

Keyword(s):

Wood Pulp ◽

Environmental Auditing ◽

Pulp Industry

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Lignosulfonate as a byproduct of wood pulp production: A potential precursor for the preparation of functional hybrid materials

Annales Universitatis Mariae Curie-Sklodowska sectio AA – Chemia ◽

10.17951/aa.2016.71.1.47 ◽

2016 ◽

Vol 71 (1) ◽

pp. 47

Author(s):

Łukasz Klapiszewski ◽

Tadeusz J. Szalaty ◽

Tomasz Szatkowski ◽

Teofil Jesionowski

Keyword(s):

Hybrid Materials ◽

Sol Gel ◽

Waste Product ◽

Diffraction Method ◽

Wood Pulp ◽

Point Of View ◽

Waste Products ◽

Pulp Industry ◽

Potential Applications ◽

Polymer Fillers

<p>Functional hybrid materials based on magnesium lignosulfonate and silica were obtained and characterized. Magnesium lignosulfonate is a common waste product of the wood pulp industry, while silica is a well-known inorganic material with exceptional physicochemical properties. In this study, silicas with a spherical particle shape were synthesized using a sol-gel method and alternatively in a nonpolar medium. Silica was found to improve the thermal and electrokinetic properties of the final products. The resulting lignosulfonate/silica hybrid materials were analyzed with the use of advanced techniques and measuring methods: scanning electron microscopy, a laser diffraction method enabling particle size measurements, Fourier transform infrared spectroscopy, elemental analysis, thermogravimetry, electrophoretic light scattering, zeta potential measurements, low-temperature nitrogen sorption, and colorimetric analysis. The results enabled the hybrid materials to be characterized from the point of view of potential applications in various branches of industry (for example as polymer fillers, electroactive blends and biosorbents). We additionally indicate new methods for the utilization of waste products, a category to which lignosulfonate certainly belongs.</p>

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