Pulp is a lignocellulosic fibrous material prepared by chemically or mechanically separating cellulose fibres from wood, fiber crops, waste paper, or rags. Many kinds of paper are made from wood with nothing else mixed into them. This includes newspapers, magazines and even toilet paper. Pulp is one of the most abundant raw materials.
- 1 History
- 2 Wood pulp
- 3 Alternatives to wood pulp
- 4 Market pulp
- 5 Environmental concerns
- 6 Applications
- 7 Economics
- 8 See also
- 9 References
- 10 Bibliography
Pulp for papermaking was produced by macerating mulberry bark as early as the 2nd century in Han dynasty China, where the invention of paper is traditionally attributed to Cai Lun. Lu Ji, in his 3rd century commentary on the Classic of Poetry, mentions that people residing south of the Yangtze River would traditionally pound mulberry bark to make paper or clothing. By the 6th century, the mulberry tree was domesticated by farmers in China specifically for the purpose of producing pulp to be used in the papermaking process. In addition to mulberry, pulp was also made from bamboo, hibiscus bark, blue sandalwood, straw, and cotton. Papermaking using pulp made from hemp and linen fibers from tattered clothing, fishing nets and fabric bags spread to Europe in the 13th century, with an ever-increasing use of rags being central to the manufacture and affordability of rag paper, a factor in the development of printing. By the 1800s, demand often exceeding the available supply of rags, and also the manual labor of papermaking resulted in paper being still a relatively pricey product.
Using wood pulp to make paper is a fairly recent innovation, that was almost concurrent to the invention of automatic papermaking machines, both together resulting in paper and cardboard becoming an inexpensive commodity in modern times. Although the first use of paper made from wood pulp dates from 1800, as seen in some pages of a book published by Matthias Koops that year in London, large-scale wood paper production began with the development of mechanical pulping in Germany by Friedrich Gottlob Keller in the 1840s, and by the Canadian inventor Charles Fenerty in Nova Scotia, Chemical processes quickly followed, first with J. Roth's use of sulfurous acid to treat wood, then by Benjamin Tilghman's U.S. patent on the use of calcium bisulfite, Ca(HSO3)2, to pulp wood in 1867. Almost a decade later, the first commercial sulfite pulp mill was built, in Sweden. It used magnesium as the counter ion and was based on work by Carl Daniel Ekman. By 1900, sulfite pulping had become the dominant means of producing wood pulp, surpassing mechanical pulping methods. The competing chemical pulping process, the sulfate, or kraft, process, was developed by Carl F. Dahl in 1879; the first kraft mill started, in Sweden, in 1890. The invention of the recovery boiler, by G.H. Tomlinson in the early 1930s, allowed kraft mills to recycle almost all of their pulping chemicals. This, along with the ability of the kraft process to accept a wider variety of types of wood and to produce stronger fibres, made the kraft process the dominant pulping process, starting in the 1940s.
Global production of wood pulp in 2006 was 175 million tons (160 million tonnes). In the previous year, 63 million tons (57 million tonnes) of market pulp (not made into paper in the same facility) was sold, with Canada being the largest source at 21 percent of the total, followed by the United States at 16 percent. The wood fiber sources required for pulping are "45% sawmill residue, 21% logs and chips, and 34% recycled paper" (Canada, 2014). Chemical pulp made up 93 percent of market pulp.
The timber resources used to make wood pulp are referred to as pulpwood. While in theory, any tree can be used for pulp-making, coniferous trees are preferred because the cellulose fibers in the pulp of these species are longer, and therefore make stronger paper. Some of the most commonly used softwood trees for paper making include spruce, pine, fir, larch and hemlock, and hardwoods such as eucalyptus, aspen and birch. There is also increasing interest in genetically modified tree species (such as GM eucalyptus and GM poplar), because of several major benefits these can provide, such as increased ease of breaking down lignin and increased growth rate.
A pulp mill is a manufacturing facility that converts wood chips or other plant fibre source into a thick fiberboard which can be shipped to a paper mill for further processing. Pulp can be manufactured using mechanical, semi-chemical or fully chemical methods (kraft and sulfite processes). The finished product may be either bleached or non-bleached, depending on the customer requirements.
Wood and other plant materials used to make pulp contain three main components (apart from water): cellulose fibers (desired for papermaking), lignin (a three-dimensional polymer that binds the cellulose fibres together) and hemicelluloses, (shorter branched carbohydrate polymers). The aim of pulping is to break down the bulk structure of the fibre source, be it chips, stems or other plant parts, into the constituent fibres.
Chemical pulping achieves this by degrading the lignin and hemicellulose into small, water-soluble molecules which can be washed away from the cellulose fibres without depolymerizing the cellulose fibres (chemically depolymerizing the cellulose weakens the fibres). The various mechanical pulping methods, such as groundwood (GW) and refiner mechanical (RMP) pulping, physically tear the cellulose fibres one from another. Much of the lignin remains adhering to the fibres. Strength is impaired because the fibres may be cut. There are a number of related hybrid pulping methods that use a combination of chemical and thermal treatment to begin an abbreviated chemical pulping process, followed immediately by a mechanical treatment to separate the fibres. These hybrid methods include thermomechanical pulping, also known as TMP, and chemithermomechanical pulping, also known as CTMP. The chemical and thermal treatments reduce the amount of energy subsequently required by the mechanical treatment, and also reduce the amount of strength loss suffered by the fibres.
|Pulp category||Production [M ton]|
|Total virgin fibres||187.0|
Most pulp mills use good forest management practices in harvesting trees to ensure that they have a sustainable source of raw materials. One of the major complaints about harvesting wood for pulp mills is that it reduces the biodiversity of the harvested forest. Pulp tree plantations account for 16 percent of world pulp production, old-growth forests 9 percent, and second- and third- and more generation forests account for the rest. Reforestation is practiced in most areas, so trees are a renewable resource. The FSC (Forest Stewardship Council), SFI (Sustainable Forestry Initiative), PEFC (Programme for the Endorsement of Forest Certification), and other bodies certify paper made from trees harvested according to guidelines meant to ensure good forestry practices.
The number of trees consumed depends on whether mechanical processes or chemical processes are used. It has been estimated that based on a mixture of softwoods and hardwoods 12 metres (40 ft) tall and 15–20 centimetres (6–8 in) in diameter, it would take an average of 24 trees to produce 0.9 tonne (1 ton) of printing and writing paper, using the kraft process (chemical pulping). Mechanical pulping is about twice as efficient in using trees, since almost all of the wood is used to make fibre, therefore it takes about 12 trees to make 0.9 tonne (1 ton) of mechanical pulp or newsprint.
Preparation for pulping
Wood chipping is the act and industry of chipping wood for pulp, but also for other processed wood products and mulch. Only the heartwood and sapwood are useful for making pulp. Bark contains relatively few useful fibers and is removed and used as fuel to provide steam for use in the pulp mill. Most pulping processes require that the wood be chipped and screened to provide uniform sized chips.
There are a number of different processes which can be used to separate the wood fiber:
Manufactured grindstones with embedded silicon carbide or aluminum oxide can be used to grind small wood logs called "bolts" to make stone pulp (SGW). If the wood is steamed prior to grinding it is known as pressure ground wood pulp (PGW). Most modern mills use chips rather than logs and ridged metal discs called refiner plates instead of grindstones. If the chips are just ground up with the plates, the pulp is called refiner mechanical pulp (RMP) and if the chips are steamed while being refined the pulp is called thermomechanical pulp (TMP). Steam treatment significantly reduces the total energy needed to make the pulp and decreases the damage (cutting) to fibres. Mechanical pulps are used for products that require less strength, such as newsprint and paperboards.
Thermomechanical pulp is pulp produced by processing wood chips using heat (thus "thermo-") and a mechanical refining movement (thus "-mechanical"). It is a two-stage process where the logs are first stripped of their bark and converted into small chips. These chips have a moisture content of around 25–30 percent. A mechanical force is applied to the wood chips in a crushing or grinding action which generates heat and water vapour and softens the lignin thus separating the individual fibres. The pulp is then screened and cleaned, any clumps of fibre are reprocessed. This process gives a high yield of fibre from the timber (around 95 percent) and as the lignin has not been removed, the fibres are hard and rigid.
Wood chips can be pre-treated with sodium carbonate, sodium hydroxide, sodium sulfate and other chemicals prior to refining with equipment similar to a mechanical mill. The conditions of the chemical treatment are much less vigorous (lower temperature, shorter time, less extreme pH) than in a chemical pulping process since the goal is to make the fibers easier to refine, not to remove lignin as in a fully chemical process. Pulps made using these hybrid processes are known as chemi-thermomechanical pulps (CTMP).
Chemical pulp is produced by combining wood chips and chemicals in large vessels called digesters. There, heat and chemicals break down lignin, which binds cellulose fibres together, without seriously degrading the cellulose fibres. Chemical pulp is used for materials that need to be stronger or combined with mechanical pulps to give a product different characteristics. The kraft process is the dominant chemical pulping method, with the sulfite process second. Historically soda pulping was the first successful chemical pulping method.
Recycled pulp is also called deinked pulp (DIP). DIP is recycled paper which has been processed by chemicals, thus removing printing inks and other unwanted elements and freed the paper fibres. The process is called deinking.
DIP is used as raw material in papermaking. Many newsprint, toilet paper and facial tissue grades commonly contain 100 percent deinked pulp and in many other grades, such as lightweight coated for offset and printing and writing papers for office and home use, DIP makes up a substantial proportion of the furnish.
Organosolv pulping uses organic solvents at temperatures above 140 °C to break down lignin and hemicellulose into soluble fragments. The pulping liquor is easily recovered by distillation. The reason for using a solvent is to make the lignin more soluble in the cooking liquor. Most common used solvents are methanol, ethanol, formic acid and acetic acid often in combination with water.
Alternative pulping methods
Research is under way to develop biopulping (biological pulping), similar to chemical pulping but using certain species of fungi that are able to break down the unwanted lignin, but not the cellulose fibres. In the biopulping process, the fungal enzyme lignin peroxidase selectively digests lignin to leave remaining cellulose fibres. This could have major environmental benefits in reducing the pollution associated with chemical pulping. The pulp is bleached using chlorine dioxide stage followed by neutralization and calcium hypochlorite. The oxidizing agent in either case oxidizes and destroys the dyes formed from the tannins of the wood and accentuated (reinforced) by sulfides present in it.
The pulp produced up to this point in the process can be bleached to produce a white paper product. The chemicals used to bleach pulp have been a source of environmental concern, and recently the pulp industry has been using alternatives to chlorine, such as chlorine dioxide, oxygen, ozone and hydrogen peroxide.
Alternatives to wood pulp
Non-wood pulp made from rags, or from linters (short fibers discarded by the textile industry), is still manufactured today mostly as a pricey product perceived as being of better quality, especially for the art market and so-called "archival" paper. The modern source fiber is most often cotton, with a much higher value given to paper made from linen, hemp, abaca, kōzo or other fibers. 100% cotton, or a combination of cotton and linen pulp is used for certificates, currency, and passports. Abaca pulp has very long, strong fibers, and is used for teabags.
There is enough straw to meet much of North America's book, magazine, catalogue and copy paper needs. Agricultural-based paper does not come from tree farms. Some agricultural residue pulps take less time to cook than wood pulps. That means agricultural-based paper uses less energy, less water and fewer chemicals. Pulp made from wheat and flax straw has half the ecological footprint of pulp made from forests.
Hemp paper is a possible replacement, but processing infrastructure, storage costs and the low usability percentage of the plant means it is not a ready substitute.
However, wood is also a renewable resource, with about 90 percent of pulp coming from plantations or reforested areas. Non-wood fibre sources account for about 5–10 percent of global pulp production, for a variety of reasons, including seasonal availability, problems with chemical recovery, brightness of the pulp etc. In China, as of 2009, a higher proportion of non-wood pulp processing increased use of water and energy.
Market pulp is any variety of pulp that is produced in one location, dried and shipped to another location for further processing. Important quality parameters for pulp not directly related to the fibres are brightness, dirt levels, viscosity and ash content. In 2004 it accounted for about 55 million metric tons of market pulp.
Air dry pulp is the most common form to sell pulp. This is pulp dried to about 10 percent moisture content. It is normally delivered as sheeted bales of 250 kg. The reason to leave 10 percent moisture in the pulp is that this minimizes the fibre to fibre bonding and makes it easier to disperse the pulp in water for further processing to paper.
Roll pulp or reel pulp is the most common delivery form of pulp to non traditional pulp markets. Fluff pulp is normally shipped on rolls (reels). This pulp is dried to 5–6 percent moisture content. At the customer this is going to a comminution process to prepare for further processing.
Some pulps are flash dried. This is done by pressing the pulp to about 50 percent moisture content and then let it fall through silos that are 15–17 m high. Gas fired hot air is the normal heat source. The temperature is well above the char point of cellulose, but large amount of moisture in the fibre wall and lumen prevents the fibres from being incinerated. It is often not dried down to 10 percent moisture (air dry). The bales are not as densely packed as air dry pulp.
The major environmental impacts of producing wood pulp come from its impact on forest sources and from its waste products.
The impact of logging to provide the raw material for wood pulp is an area of intense debate. Modern logging practices, using forest management seek to provide a reliable, renewable source of raw materials for pulp mills. The practice of clear cutting is a particularly sensitive issue since it is a very visible effect of logging. Reforestation, the planting of tree seedlings on logged areas, has also been criticized for decreasing biodiversity because reforested areas are monocultures. Logging of old growth forests accounts for less than 10 percent of wood pulp, but is one of the most controversial issues.
Effluents from pulp mills
The process effluents are treated in a biological effluent treatment plant, which guarantees that the effluents are not toxic in the recipient.
Mechanical pulp is not a major cause for environmental concern since most of the organic material is retained in the pulp, and the chemicals used (hydrogen peroxide and sodium dithionite) produce benign byproducts (water and sodium sulfate (finally), respectively).
Chemical pulp mills, especially kraft mills, are energy self-sufficient and very nearly closed cycle with respect to inorganic chemicals.
The kraft pulping reaction in particular releases foul-smelling compounds. The hydrogen sulfide reagent that degrades lignin structure also causes some demethylation to produce methanethiol, dimethyl sulfide and dimethyl disulfide. These same compounds are released during many forms of microbial decay, including the internal microbial action in Camembert cheese, although the kraft process is a chemical one and does not involve any microbial degradation. These compounds have extremely low odor thresholds and disagreeable smells.
The main applications for pulp are paper and board production. The furnish of pulps used depends on the quality on the finished paper. Important quality parameters are wood furnish, brightness, viscosity, extractives, dirt count and strength.
Chemical pulps are used for making nanocellulose.
Speciality pulp grades have many other applications. Dissolving pulp is used in making regenerated cellulose that is used textile and cellophane production. It is also used to make cellulose derivatives. Fluff pulp is used in diapers, feminine hygiene products and nonwovens.
The Fourdrinier Machine is the basis for most modern papermaking, and it has been used in some variation since its conception. It accomplishes all the steps needed to transform a source of wood pulp into a final paper product.
- Paper chemicals
- Pulp mill
- Johan Richter. Developed the process for continuous cooking of pulp.
- World Forestry Congress
- Tsien, Tsuen-Hsuin (1985), Paper and Printing, Science and Civilisation in China: Chemistry and Chemical Technology, Vol. 5 Part 1, Cambridge University Press, p. 4
- Tsien, Tsuen-Hsuin (1985), Paper and Printing, Science and Civilisation in China: Chemistry and Chemical Technology, Vol. 5 Part 1, Cambridge University Press, pp. 56–61
- Hunter, Dard (1943). Papermaking, the history and technique of an ancient craft. Dover.
- Sjöström, E. (1993). Wood Chemistry: Fundamentals and Applications. Academic Press.
- Burger, PeterCharles Fenerty and his Paper Invention. Toronto: Peter Burger, 2007. ISBN 978-0-9783318-1-8 pp.25–30
- Biermann, Christopher J. (1993). Handbook of Pulping and Papermaking. San Diego: Academic Press. ISBN 0-12-097360-X.
- History of Paper. indiapapermarket.com
- "Pulp production growing in new areas (Global production)". Metso Corporation. September 5, 2006. Archived from the original on October 23, 2007. Retrieved 2007-10-13.
- Sixta, Herbert (2006). "Preface". Handbook of Pulp. 1. Wiley-VCH Verlag & Co KGaA. p. XXIII. ISBN 3-527-30999-3.
- "Overview of the Wood Pulp Industry". Market Pulp Association. 2007. Archived from the original on 2007-10-16. Retrieved 2007-10-13.
- Manthy, Robert S.; James, Lee Morton; Huber, Henry H. (1973). Michigan Timber Production: Now and in 1985. Michigan State University, Agricultural Experiment Station and Cooperative Extension service.
- Geman, Helyette (2014-12-29). Agricultural Finance: From Crops to Land, Water and Infrastructure. John Wiley & Sons. ISBN 9781118827376.
- Sixta, Herbert, ed. (2006). Handbook of pulp. 1. Winheim, Germany: Wiley-VCH. p. 9. ISBN 3-527-30997-7.
- Martin, Sam (2004). "Paper Chase". Ecology Communications, Inc. Archived from the original on 2007-06-19. Retrieved 2007-09-21.
- "Certification Tracking products from the forest to the shelf". Archived from the original on 2007-08-26. Retrieved 2007-09-21.
- Trees Into Paper. Conservatree. Retrieved on 2017-01-09.
- ""dead link"". Archived from the original on 2008-12-25. Retrieved 2009-02-05.
- Iggesund Paperboard AB (2008). "Paperboard the Iggesund Way": 15.
- Husaini, Ahmad; Fisol, Faisalina Ahmad; Yun, Liew Chia; Hussain, Mohd Hasnain; Muid, Sepiah; Roslan, Hairul Azman (2011). "Lignocellulolytic enzymes produced by tropical white rot fungi during biopulping of Acacia mangium wood chips". J Biochem Tech. 3 (2): 245–250.
- Avella, Maurizio; Bozzi, Claudio; Dell'Erba, Ramiro; Focher, Bonaventura; Marzetti, Annamaria; Martuscelli, Ezio (November 1995). "Steam-exploded wheat straw fibres as reinforcing material for polypropylene-based composites. Characterization and properties". Angewandte Makromolekulare Chemie. 233 (1): 149–166. doi:10.1002/apmc.1995.052330113.
- "Markets". delarue.com.
- "Banknotes design and production". Bank of Canada. Archived from the original on December 16, 2008. Retrieved February 7, 2009.
- "How Money is Made - Paper and Ink". BUREAU OF ENGRAVING AND PRINTING U.S. Department of the Treasury. Retrieved July 14, 2017.
- "Canopy's Straw Paper Campaign". canopyplanet.org. Archived from the original on 2013-09-03.
- Judt, Manfred (Oct–Dec 2001). "Nonwoody Plant Fibre Pulps". Inpaper International. Retrieved 2007-10-07.
- 造纸企业能入“绿色之门”的前提 南粤大地 南方网. News.southcn.com (2009-07-20). Retrieved on 2017-01-09.
- Stenius, Per (2000). "1". PForest Products Chemistry. Papermaking Science and Technology. 3. Finland: Fapet Oy. p. 29. ISBN 952-5216-03-9.
- Nanko, Hirko; Button, Allan; Hillman, Dave (2005). The World of Market Pulp. Appleton, Wisconsin, USA: WOMP, LLC. pp. 2–3. ISBN 0-615-13013-5.
- "Effluents from Pulp Mills using Bleaching – PSL1". ISBN 0-662-18734-2 DSS. Health Canada. 1991. Retrieved 2007-09-21. templatestyles stripmarker in
|work=at position 1 (help)
- Lefebrvre, Paul (February 4, 2009). Wood products market looks soft. The Chronicle.