Wood industry explained

The wood industry or timber industry (sometimes lumber industry -- when referring mainly to sawed boards) is the industry concerned with forestry, logging, timber trade, and the production of primary forest products and wood products (e.g. furniture) and secondary products like wood pulp for the pulp and paper industry. Some of the largest producers are also among the biggest owners of forest. The wood industry has historically been and continues to be an important sector in many economies.

Distinction

In the narrow sense of the terms, wood, forest, forestry and timber/lumber industry appear to point to different sectors, in the industrialized, internationalized world, there is a tendency toward huge integrated businesses that cover the complete spectrum from silviculture and forestry in private primary or secondary forests or plantations via the logging process up to wood processing and trading and transport (e.g. timber rafting, forest railways, logging roads).

Processing and products differs especially with regard to the distinction between softwood and hardwood.[1] [2] [3] [4] [5] While softwood primarily goes into the production of wood fuel and pulp and paper, hardwood is used mainly for furniture, floors, etc.. Both types can be of use for building and (residential) construction purposes (e.g. log houses, log cabins, timber framing).

Production chain

Lumber and wood products, including timber for framing, plywood, and woodworking, are created in the wood industry from the trunks and branches of trees through several processes, commencing with the selection of appropriate logging sites and concluding with the milling and treatment processes of the harvested material. In order to determine which logging sites and milling sites are responsibly producing environmental, social and economic benefits, they must be certified under the Forests For All Forever (FCS) Certification that ensures these qualities.[6]

Harvesting

Mature trees are harvested from, both, plantations and native forests. Trees harvested at a younger age produce smaller logs, and these can be turned into lower-value products. Factors such as location, climate conditions, species, growth rate, and silviculture can affect the size of a mature tree.[7]

Timber mills

The native hardwood saw-milling industry originally consisted of small family-owned mills, but has recently changed to include a small number of larger mills. Mills produce large volumes of material and aim to ensure delivery of a high quality standard of product. Their goal is to do this efficiently and safely, at low cost, with rapid production time and high output.[7]

Production and use

Once the timber has been manipulated in the required fashion, it can be shipped out for usage. There are many different purposes for wood including plywood, veneer, pulp, paper, particleboard, pallets, craft items, toys, instrument-making, furniture production, packing cases, wine barrels, cardboard, firewood, garden mulch, fibre adhesives, packaging and pet litter. Western Australia has a unique substance called ‘biochar’, which is made from jarrah and pine and sometimes from crop and forestry residues, along with the former materials. Biochar can be used to manufacture silicone and as a soil additive.

Softwoods, such as the Australian eucalyptus, are highly valued, a are used mainly for construction, paper making, and cladding. The term 'round wood' describes all the wood removed from forests in log form and used for purposes other than fuel. Wood manufacturing residues, such as sawdust and chippings, are collectively known as "pulp".[7] The United States industrial production index hit a 13-year high during the COVID-19 pandemic, according to a report from the Board of Governors of the Federal Reserve System.[8] [9]

Transport

Originally, trees were felled from native forests using axes and hand-held cross-cut saws – a slow process involving significant manual labor. Since sawmills were traditionally located within forests, milled timber had to be transported over long distances via rough terrain or waterways to reach its destination. Logs were later transported via train and tram lines, first by steam-powered log haulers then by steam-powered locomotives, and finally diesel and petrol-powered locomotives. Even in the modern era, timber is dried in kilns. When the first steam railway in Australia opened in Melbourne in 1854, timber transportation changed dramatically. Trains made the transportation of lumber quicker and more affordable, making it possible for the Australian sawmill industry to move inland.[7]

Wood is transported by a variety of methods, typically by road vehicle and log driving over shorter distances. For longer journeys, wood is transported by sea on timber carriers, subject to the IMO TDC Code.[10]

Top producers

As of 2019, the top timberland owners in the US were structured as real-estate investment trusts and include:[11]

In 2008 the largest lumber and wood producers in the US were[12]

As these companies are often publicly traded, their ultimate owners are a diversified group of investors. There are also timber-oriented real-estate investment trusts.

According to sawmilldatabase, the world top producers of sawn wood in 2007 were:[14]

! Company ! Production or Capacity in m3/yr
West Fraser Timber Co Ltd 8460000
6900000
6449000
4646000
4300000
3760000
3550000
3200000
Hampton Affiliates[15] 3100000
2800000
Tolko Industries Ltd 2500000
Pfeifer Group[16] 2200000

Issues

Safety

Noise

Workers within the forestry and logging industry sub-sector fall within the agriculture, forestry, fishing, and hunting (AFFH) industry sector as characterized by the North American Industry Classification System (NAICS).[17] The National Institute for Occupational Safety and Health (NIOSH) has taken a closer look at the AFFH industry's noise exposures and prevalence of hearing loss. While the overall industry sector had a prevalence of hearing loss lower than the overall prevalence of noise-exposed industries (15% v. 19%), workers within forestry and logging exceeded 21%.[18] Thirty-six percent of workers within forest nurseries and gathering of forest products, a sub-sector within forestry and logging, experienced hearing loss, the most of any AFFH sub-sector. Workers within forest nurseries and gathering of forest products are tasked with growing trees for reforestation and gathering products such as rhizomes and barks. Comparatively, non-noise-exposed workers have only a 7% prevalence of hearing loss.[19]

Worker noise exposures in the forestry and logging industry have been found to be up to 102 dBA.[20] NIOSH recommends that a worker have an 8-hour time-weighted average of noise exposure of 85 dBA.[21] Excessive noise puts workers at an increased risk of developing hearing loss. If a worker were to develop a hearing loss as a result of occupational noise exposures, it would be classified as occupational hearing loss. Noise exposures within the forestry and logging industry can be reduced by enclosing engines and heavy equipment, installing mufflers and silencers, and performing routine maintenance on equipment.[20] Noise exposures can also be reduced through the hierarchy of hazard controls where removal or replacement of noisy equipment serves as the best method of noise reduction.

Injury

The Bureau of Labor Statistics (BLS) has found that fatalities of forestry and logging workers have increased from 2013 to 2016, up from 81 to 106 per year. In 2016, there were 3.6 cases of injury and illness per 100 workers within this industry.[22]

Illegal logging

Economy

The existence of a wood economy, or more broadly, a forest economy (in many countries a bamboo economy predominates), is a prominent matter in many developing countries as well as in many other nations with a temperate climate and especially in those with low temperatures. These are generally the countries with greater forested areas so conditions allow for development of local forestry to harvest wood for local uses. The uses of wood in furniture, buildings, bridges, and as a source of energy are widely known. Additionally, wood from trees and bushes, can be used in a variety of products, such as wood pulp, cellulose in paper, celluloid in early photographic film, cellophane, and rayon (a substitute for silk).

At the end of their normal usage, wood products can be burnt to obtain thermal energy or can be used as a fertilizer. The potential environmental damage that a wood economy could occasion include a reduction of biodiversity due to monoculture forestry (the intensive cultivation of very few trees types); and CO2 emissions. However, forests can aid in the reduction of atmospheric carbon dioxide and thus limit climate change.[23]

Paper is today the most used wood product.

History of use of wood

The wood economy was the starting point of the civilizations worldwide, since eras preceding the Paleolithic and the Neolithic. It necessarily preceded ages of metals by many millennia, as the melting of metals was possible only through the discovery of techniques to light fire (usually obtained by the scraping of two very dry wooden rods) and the building of many simple machines and rudimentary tools, as canes, club handles, bows, arrows, lances. One of the most ancient handmade articles ever found is a polished wooden spear tip (Clacton Spear) 250,000 years old (third interglacial period), that was buried under sediments in England, at Clacton-on-Sea.[24] [25]

Dimensions and geography

The main source of the lumber used in the world is forests, which can be classified as virgin, semivirgin and plantations. Much timber is removed for firewood by local populations in many countries, especially in the third world, but this amount can only be estimated, with wide margins of uncertainty.

In 1998, the worldwide production of "Roundwood" (officially counted wood not used as firewood), was about 1500000000m2, amounting to around 45% of the wood cultivated in the world. Cut logs and branches destined to become elements for building construction accounted for approximately 55% of the world's industrial wood production. 25% became wood pulp (including wood powder and broccoli) mainly destined for the production of paper and paperboard, and approximately 20% became panels in plywood and valuable wood for furniture and objects of common use (FAO 1998).[26] The World's largest producer and consumer of officially accounted wood are the United States, although the country that possesses the greatest area of forest in Russia.

By 2001 the rainforest areas of Brazil were reduced by a fifth (respect of 1970), to around 4,000,000 km2; the ground cleared was mainly destined for cattle pasture—Brazil is the world's largest exporter of beef with almost 200,000,000 head of cattle.[27] The booming Brazilian ethanol economy based upon sugar cane cultivation, is likewise reducing forests area. Canadian forest was reduced by almost 30% to 3,101,340 km2 over the same period.[28]

Importance in limiting climate change

See also: Land use, land-use change, and forestry and Deforestation and climate change. Regarding the problem of climate change, it is known that burning forests increase CO2 in the atmosphere, while intact virgin forest or plantations act as sinks for CO2, for these reasons wood economy fights greenhouse effect. The amount of CO2 absorbed depends on the type of trees, lands and the climate of the place where trees naturally grow or are planted. Moreover, by night plants do not photosynthesize, and produce CO2, eliminated the successive day. Paradoxically in summer oxygen created by photosynthesis in forests near to cities and urban parks, interacts with urban air pollution (from cars, etc.) and is transformed by solar beams in ozone (molecule of three oxygen atoms), that while in high atmosphere constitutes a filter against ultraviolet beams, in the low atmosphere is a pollutant, able to provoke respiratory disturbances.[29] [30]

In a low-carbon economy, forestry operations will be focused on low-impact practices and regrowth. Forest managers will make sure that they do not disturb soil-based carbon reserves too much. Specialized tree farms will be the main source of material for many products. Quick maturing tree varieties will be grown on short rotations to maximize output.[31]

Production by country

In Brazil

Brazil has a long tradition in the harvesting of several types of trees with specific uses. Since the 1960s, imported species of pine tree and eucalyptus have been grown mostly for the plywood and paper pulp industries. Currently high-level research is being conducted, to apply the enzymes of sugar cane fermentation to cellulose in wood, to obtain methanol, but the cost is much higher when compared with ethanol derived from corn costs.[32]

In Canada and the US

There is a close relation in the forestry economy between these countries; they have many tree genera in common, and Canada is the main producer of wood and wooden items destined to the US, the biggest consumer of wood and its byproducts in the world. The water systems of the Great Lakes, Erie Canal, Hudson River and Saint Lawrence Seaway to the east coast and the Mississippi River to the central plains and Louisiana allows transportation of logs at very low costs. On the west coast, the basin of the Columbia River has plenty of forests with excellent timber.

Canada

The agency Canada Wood Council calculates that in the year 2005 in Canada, the forest sector employed 930,000 workers (1 job in every 17), making around $108 billion of value in goods and services. For many years products derived from trees in Canadian forests had been the most important export items of the country. In 2011, exports around the world totaled some $64.3 billion – the single largest contributor to Canadian trade balance.[34]

Canada is the world leader in sustainable forest management practices. Only 120000000ha (28% of Canadian forests) are currently managed for timber production while an estimated 32000000ha are protected from harvesting by the current legislation.[35]

The Canadian timber industry has led to environmental conflict with Indigenous people protecting their land from logging. For example, the Asubpeeschoseewagong First Nation set up the Grassy Narrows road blockade for twenty years beginning in 2002 to prevent clearcutting of their land.[36] [37]

United States

Nigeria

Wood obtained from Nigeria's wood industry undergoes processing in various wood processing sectors, including furniture manufacturing, sawmill operations, plywood mills, pulp and paper facilities, and particleboard mills.[45]

In the Caribbean and Central America

In Europe

Italy

Poplar

in Italy is the most important species for tree plantations, is used for several purposes as plywood manufacture, packing boxes, paper, matches, etc. It needs good quality grounds with good drainage, but can be used to protect the cultivations if disposed in windbreak lines. More than 70% of Italian poplar cultivations are located in the pianura Padana. Constantly the extension of the cultivation is being reduced, from 650 km2 in the 1980s to current 350 km2. The yield of poplars is about 1,500 t/km2 of wood every year.[46] The production from poplars is around 45–50% of the total Italian wood production.[47]

Portugal

In Fennoscandia[49] and Russia

In Sweden, Finland and to an extent Norway, much of the land area is forested, and the pulp and paper industry is one of the most significant industrial sectors. Chemical pulping produces an excess of energy, since the organic matter in black liquor, mostly lignin and hemicellulose breakdown products, is burned in the recovery boiler. Thus, these countries have high proportions of renewable energy use (25% in Finland, for instance). Considerable effort is directed towards increasing the value and usage of forest products by companies and by government projects.

Outputs

Combustion

See main article: Wood fuel. Combustion of wood is linked to the production of micro-environmental pollutants, as carbon dioxide (CO2), carbon monoxide (CO) (an invisible gas able to provoke irreversible saturation of blood's hemoglobine), as well as nanoparticles.[50]

Charcoal

See main article: Charcoal. Charcoal is the dark grey residue consisting of impure carbon obtained by removing water and other volatile constituents from animal and vegetation substances. Charcoal is usually produced by slow pyrolysis, the heating of wood or other substances in the absence of oxygen. Charcoal can then be used as a fuel with a higher combustion temperature.

Wood gasogen

Wood gas generator (gasogen): is a bulky and heavy device (but technically simple) that transforms burning wood in a mix of molecular hydrogen (H2), carbon monoxide (CO), carbon dioxide (CO2), molecular nitrogen (N2) and water vapor (H2O). This gas mixture, known as "wood gas", "poor gas" or "syngas" is obtained after the combustion of dry wood in a reductive environment (low in oxygen) with a limited amount of atmospheric air, at temperatures of 900 °C, and can fuel an internal combustion engine.[51]

Construction

See main article: Lumber. Wood is relatively light in weight, because its specific weight is less than 500 kg/m3, this is an advantage, when compared against 2,000–2,500 kg/m3 for reinforced concrete or 7,800 kg/m3 for steel.

Wood is strong, because the efficiency of wood for structural purposes has qualities that are similar to steel.

Material E/f
Concrete (Rck300, fck 25 M-Pascal) 1250
Structural steelFe430 (ft = 430 MPa) 480
Glued laminated timber(BS 11 ÷ BS 18)470
Aluminium (alloy 7020, ft 355 MPa) 200

Bridges, levees, microhydro, piers

Wood is used to build bridges (as the Magere bridge in Amsterdam), as well as water and air mills, and microhydro generators for electricity.

Housing

Hardwood is used as a material in wooden houses, and other structures with a broad range of dimensions. In traditional homes wood is preferred for ceilings, doors, floorings and windows. Wooden frames were traditionally used for home ceilings, but they risk collapse during fires.

The development of energy efficient houses including the "passive house" has revamped the importance of wood in construction, because wood provides acoustic and thermal insulation, with much better results than concrete.

Earthquake resistant buildings

In Japan, ancient buildings, of relatively high elevation, like pagodas, historically had shown to be able to resist earthquakes of high intensity, thanks to the traditional building techniques, employing elastic joints, and to the excellent ability of wooden frames to elastically deform and absorb severe accelerations and compressive shocks.

In 2006, Italian scientists from CNR patented[52] a building system that they called "SOFIE",[53] a seven-storey wooden building, 24 meters high, built by the "Istituto per la valorizzazione del legno e delle specie arboree" (Ivalsa) of San Michele all'Adige. In 2007 it was tested with the hardest Japanese antiseismic test for civil structures: the simulation of Kobe's earthquake (7.2 Richter scale), with the building placed over an enormous oscillating platform belonging to the NIED-Institute, located in Tsukuba science park, near the city of Miki in Japan. This Italian project, employed very thin and flexible panels in glued laminated timber, and according to CNR researchers could lead to the construction of much more safe houses in seismic areas.[54]

Shipbuilding

One of the most enduring materials is the lumber from virginian southern live oak and white oak, specially live oak is 60% stronger than white oak and more resistant to moisture. As an example, the main component in the structure of battle ship, the world's oldest commissioned naval vessel afloat (launched in 1797) is white oak.[55]

Woodworking

Woodworking is the activity or skill of making items from wood, and includes cabinet making (cabinetry and furniture), wood carving, joinery, carpentry, and woodturning. Millions of people make a livelihood on woodworking projects.

See also

Bibliography

External links

See also

Notes and References

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  2. Web site: Softwood Lumber. Foreign Affairs Trade and Development Canada. Government of Canada. 3 November 2008. GAC.
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  5. 10.1016/S1389-9341(01)00063-6 . 3 . 3–4 . Production strategies in the Swedish softwood sawmilling industry . Forest Policy and Economics . 189–197. 2001 . Roos . Anders . Flinkman . Matti . Jäppinen . Armas . Lönner . Göran . Warensjö . Mats . 2001ForPE...3..189R .
  6. Web site: FCS . Forests For All Forever.
  7. Web site: Forestry Sustainability School Activities, Lesson Plans & Resources | Forest Learning. www.forestlearning.edu.au.
  8. Web site: Board of Governors of the Federal Reserve System (US). 1972-01-01. Industrial Production: Manufacturing: Durable Goods: Wood Product (NAICS = 321). 2021-08-25. FRED, Federal Reserve Bank of St. Louis.
  9. Web site: Wood production hits 13-year high—but lumber prices are still up 171% since COVID started. 2021-08-25. www.yahoo.com. 31 March 2021 . en-US.
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  11. Web site: Timberland REITs Nareit. www.reit.com. 2 September 2019.
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  23. Web site: Adaptation of Forests and Forest Management to Changing Climate with Emphasis on Forest Health: a Review of Science, Policies, and Practices. Umeå, Sweden. August 25–28, 2008. 13 May 2017.
  24. Tecnologia Dalle Origini al 2000, pag. 18
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  26. http://www.unece.org/trade/timber/mis/energy/output.htm#2007 FAO 1998
  27. Web site: Brazil seizes cattle illegally grazing on Amazon forest lands. 13 May 2017.
  28. Web site: Canadian Forests – Quick Facts. 13 May 2017.
  29. Web site: Air quality levels in Europe — European Environment Agency.
  30. Web site: YourLungHealth.org – The Effects of Ozone Pollution. 8 February 2021. 4 April 2019. https://web.archive.org/web/20190404053655/http://www.yourlunghealth.org/healthy_living/pollution/outdoor/effects/. dead.
  31. http://www.woodland-trust.org.uk/campaigns/briefingsmore/carbonmgt.htm Trees and their role in carbon management for land and business
  32. Web site: Brazzil Mag – Trying to understand Brazil since 1989. 8 February 2021. 22 August 2009. https://web.archive.org/web/20090822052938/http://www.brazzilmag.com/content/view/8280/54/. dead.
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  34. Web site: Wood-Works – Program of the Canadian Wood Council. 8 February 2021. 12 January 2008. https://web.archive.org/web/20080112002653/http://www.wood-works.org/. dead.
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  36. News: Turner . Logan . 2023 . Grassy Narrows marks 20 years of the blockade protecting its land from logging . CBC .
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  39. A History of the Vegetable Kingdom – Page 334
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  46. Web site: Federlegno – Italian federation of wood producers and industry. 13 May 2017.
  47. Fonte:http://www.federlegno.it/tool/home.php?s=0,1,29,37,417,1042
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  51. UNITED STATES DEPARTMENT OF AGRICULTURE Gasogens Report (Original report dated 1944): now in the possession of the University of Wisconsin
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