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1. The family of wood composite materials
Maloney, T M . Forest Products Journal ; Madison Ā Vol.Ā 46,Ā Ed.Ā 2,Ā (Feb 1996): 18.
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RESUMO
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Wood composites are defined as materials that have the commonality of being glued or bonded together. A certain
group of composites are now being grouped together and described as engineered wood products. A description is
given for panel products, including: 1. softwood plywood, 2. blockboard, 3. hardwood plywood, 4. particleboard, 5.
medium density fiberboard, 6. insulating board, 7. hardboard, 8. Com-Ply panels, 9. oriented strandboard, and 10.
waferboard. The history of molded products, inorganic-bonded products, and lumber and timber products is
presented.
TEXTO COMPLETO
Ā
Millions of tons of wood composites are now manufactured annually from previously unused species as well as
forest and mill residues (and agricultural residues). The development of these wood composites has occurred
mostly over the past 40 years. It is a revolution in the forest products industry, albeit a "silent revolution" not
recognized by the general public.
The term "wood composites" is relatively new. The forest products industry has struggled to properly name the
many different materials that have been developed by gluing small particles or other elements into larger
materials. In this discussion, composites are defined as materials that have the commonality of being glued or
bonded together. This description covers a multitude of products and it is used to avoid the use of trade names
that may confuse people.
Most of today's wood composites are of relatively recent origin, within the past 40 years. Composites include not
only panels, but also molded products, lumber, large timbers, components, and products made with combinations
of wood and other materials (e.g., plastic fiber or straw). Composites utilize what was previously waste wood
residue or little used or noncommercial species. Even agricultural residues can be used. Very little raw material is
wasted in the manufacture of composites.
Wood is a very energy efficient raw material. Almost half of the industrial materials manufactured in the United
States are wood products; however, only about 4 percent of the total energy needed to manufacture all industrial
materials is used by the forest products industry. Wood composites efficiently use this energy-conserving
renewable resource.
THE FAMILY OF ... WOOD COMPOSITES...
The term "composite" seems to be the most appropriate to describe any wood material made of smaller pieces and
glued together. Some composite materials found in today's world are panels, molded products, inorganic-bonded
products, and lumber or timber products. This composite family is shown on page 20.
This family can be expanded easily to include all types of laminated materials (from overlaid panels to laminated
beams), edge-glued panels, components (I-beams, T-beam panels, stress-skin panels), and perhaps in the future
even to large molded building parts or even buildings.
A certain group of composites are now being grouped together and described as engineered wood products (EWP),
for example, plywood, variations of structural panels, and glued laminated timber. Other composites such as
particleboard and medium density fiberboard (MDF) have also recently been described as engineered wood
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2. products.
Almost all of the composites can be engineered to various specifications, thus taking full advantage of wood's
inherent properties while at the same time improving upon these properties through materials science and
technology. Also, almost all of these composites can be used structurally. For some reason, recent publications
have called particleboard and MDF "nonstructural." This is untrue. These materials are being used in North
America and elsewhere in the world as structural panels in building. They are approved for structural use by
various building codes and government agencies. Even low density insulating board is approved for structural use.
... PANEL PRODUCTS... SOFTWOOD PLYWOOD...
Softwood plywood has dominated the North American structural panel market for many years. However, oriented
strandboard (OSB) now claims a very high proportion of this market because it usually is a lower cost product to
manufacture. Significant improvements in plywood manufacturing have resulted in reduced production costs,
which has enabled the softwood plywood industry to increase production and remain competitive with OSB. In the
past few years, however, a reduced timber supply in the western United States as well as increases in veneer log
prices have caused a considerable number of plants to close. Plywood plants are now, for the most part,
attempting to produce mostly higher value products rather than sheathing, subfloor, and other basic building
panels, leaving much of the sheathing market to the lower cost OSB.
Softwood plywood manufacture has undergone a dramatic change in recent years. Some examples of the
manufacturing changes include pretreatment of the veneer blocks, which has enhanced veneer quality and the
amount of veneer produced; computerized X-Y peeler block chargers; ultrasonic veneer block scanning; powered
nose bars; and linear-positioned lathe knife carriages, which have become part of the conventional lathe and
further increase the amount of veneer produced. Also, new lathes have been introduced that can peel blocks to
cores of less than 2 inches in diameter. Changes in the gluing system, such as gluing higher moisture content
veneer and foaming the glue, have reduced the amount of adhesive required and, hence, have lowered production
costs.
A major breakthrough is the development of phenolic glues for use with veneers at moisture contents of 10
percent or more instead of 3 or 4 percent. This has resulted in higher dryer productivity, improved press
productivity, lowered glue spreads, better pre-pressing, better assembly time tolerance, improved veneer gluability,
and fewer panel blows. Some plants have obtained up to a 20 percent savings in glue cost, while simultaneously
saving on dryer and press costs.
Gluing veneer with a high moisture content (up to 15 percent) results in a product closer to the equilibrium value in
actual use, thus reducing warp and dimensional changes. However, a plant must operate under strict process
controls to be successful in gluing high moisture content veneer, otherwise product quality will be reduced
significantly.
HARDWOOD PLYWOOD...
Unlike softwood plywood, which is used mostly for structural applications, hardwood plywood is used both
structurally and also as decorative panels. This is a product that can be traced back to ancient times. Today, in the
United States, hardwood plywood includes hardwood veneer applied over other substrate materials such as
particleboard.
A number of developments have taken place over the years that enable a plant to recover more veneer from a
given log and to produce quality plywood more efficiently. The newer versions of lengthwise veneer slicers have
been installed in many plants, particularly in East Asia, Australia, and now in North America. These slicers do not
have the output of conventional slicers, but they work well in smaller plants. They allow the recovery of difficult-to-
process wood in conventional operations and allow sawmills to produce veneer from quality wood material. Thus,
sawmills have the opportunity for a value-added product by producing veneer as well as lumber.
Some of the reasons for using lengthwise slicers include low investment, no foundation requirements, low energy
consumption, complete, or near complete, utilization of the flitches, automatic operation, and the ability to produce
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3. thin veneer with high-quality surfaces as well as thick veneer. The combination of a sawmill and veneer mill has
resulted in significantly increased product recovery and profit.
A major competitor to hardwood plywood is thin MDF. With appropriate high-quality overlays or prints, thin MDF
appears the same as hardwood plywood. This product has captured significant amounts of the hardwood plywood
market.
BLOCKBOARD...
Blockboard is often overlooked today, but its old technology, or variations on the old technology, could provide
panel-building products in many places. Conventional blockboard panels have been made with strips of lumber in
the core with crossbands of veneer or hardboard faces. A newer version is produced by glue edge jointing the core
lumber strips and using thin lumber faces rather than veneer. The adhesive cost can be quite low. About 14 new
plants have been built in Europe using this new technology. Blockboard is used for paneling, furniture, and
extensively for concrete formwork in Europe.
PARTICLEBOARD...
Particleboard is a generic term for a panel that is manufactured from lignocellulosic materials (usually wood,
primarily in the form of discrete pieces or particles, as distinguished from fibers) combined with a synthetic resin
or other suitable binder and then bonded together under heat and pressure in a hot press. The process uses the
added binder to create the entire interparticle bond; other materials may be added during manufacture to improve
certain properties. Particleboards are further defined by the method of pressing. When the pressure is applied in
the direction perpendicular to the faces, as in a conventional multi-platen hot press, they are defined as flat-platen
pressed; and when the applied pressure is parallel to the faces, they are defined as extruded. Particleboard
remains the world's dominant furniture panel, although considerable amounts of its production also go into
structural applications such as manufactured home floors, roof sheathing, wall panels, stair treads, and for house
floors elsewhere in the world.
The first platen-pressed particleboard plant started operation in Dubuque, Iowa, in 1933. This small plant ran until
1942. A larger commercial plant commenced operation in Germany in 1941. The great increase in particleboard
production started in the 1950s.
Extruded particleboard was developed in Germany in 1947-49. A similar process was developed in the United
States. Numerous plants were built throughout the world including the United States. However, low production
capacities and some board physical property limitations kept extruded particleboard from becoming a major
product line.
The basic raw materials for particleboard are plant residues or low-quality logs. Planer shavings and sawdust are
the dominant raw materials in the United States and Canada because of the huge sawmill industry in these
countries. Some recycled wood material, where it is economical to use such a substance, is now part of the raw
material supply. A new facility that manufactures particleboard from straw just began operation in North Dakota.
Bagasse (sugar cane stalks) has been used for board in a few countries.
MEDIUM DENSITY FIBERBOARD...
MDF is a dry-formed panel product manufactured from lignocellulosic fibers combined with a synthetic resin or
other suitable binder. The panels are compressed to a density of 0.50 to 0.80 specific gravity (31 to 50 pcf) in a hot
press by a process in which the entire interfiber bond is created by the added binder. Other materials may have
been added during manufacture to improve certain properties. It is generally accepted that MDF production started
in Deposit, New York, in 1966, but arguments can be made that the first MDF was made in a plant in Oakridge,
Oregon, or in a plant in Meridian, Mississippi.
Many new MDF plants have been erected recently and many others are in the planning stages. There are now well
over 100 plants worldwide. Thin and thick boards are being produced. Thin MDF is usually produced by newer
continuous presses, however, most of the newer plants also use these types of presses to produce thicker panels.
A wide variety of raw material types can be handled in an MDF plant: pulp chips, planer shavings, plywood trim, and
sawdust. Care must be taken to introduce all of these different raw material types into the process line at
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4. appropriate levels to ensure a consistent quality of fiber. Much of the world uses pulp chips to manufacture MDF;
however, it is common in the United States and Canada to mostly use the same raw material as for particleboard:
planer shavings and sawdust. Other nonwood materials such as bagasse also make excellent MDF. Many new
MDF plants are under construction, particularly in Southeast Asia and Indonesia.
The technology for producing MDF has improved greatly in recent years. It appears that a mixture of species can
be handled better in an MDF plant than in a particleboard plant. However, there are still some problems when there
are significant chemical differences between the species, particularly in designing the resin system. Urea-
formaldehyde is still the dominant resin used. The interaction between the chemistry of the wood species and the
urea-formaldehyde is well known. Control of the species chemistry is needed to ensure that quality MDF is
produced consistently.
MDF lends itself well as a substitute for clear lumber. It does not have a grain structure, but finishes and overlays
can be used effectively to provide an MDF product that, in appearance, looks like wood. A considerable amount is
now used for moldings or millwork, replacing solid wood.
INSULATING BOARD (NON-COMPRESSED FIBERBOARD)...
Insulating board development started in 1914 in Minnesota, but its manufacture has been slowly decreasing. This
is a wet-process system where great amounts of water are used in the process, somewhat like in the manufacture
of pulp and paper. The need to clean the water effluent has been a major problem and competition from foamed
plastic panels has been a further factor in the decline of insulating board manufacture. Many surviving plants use
mineral fiber rather than wood fiber in order to make products that are resistant to fire.
One insulating board product still enjoying great success in the United States is Homosote. This product is made
of waste newspaper and groundwood paper publications waste. Manufacture started in 1916 (based on
technology from Agasote Millboard in the United Kingdom). Homosote is a structural product based on recycled
wood fiber. Besides various panels, components for walls and roofs are produced, which combine the board with
rigid urethane foams, foils, fiberglass, and other materials.
HARDBOARD (COMPRESSED FIBERBOARD)...
Hardboard is a generic term for a panel manufactured primarily from interfelted lignocellulosic fibers (usually
wood) and consolidated under heat and pressure in a hot press to a density of 31 pcf or greater; other materials
such as resin may be added during manufacture to improve certain board properties.
Wet-process hardboard uses large amounts of water in the processing, similar to the manufacture of insulating
board. This hardboard continues to be an important panel product worldwide. Like insulating board, there are
questions about cleaning the waste water. Stricter environmental regulations have eliminated some previous uses
of waste water, such as for irrigation. Research on enzymes and bacteria that may clean the water is being
conducted and may provide some important developments for wet-process hardboard.
Siding has been a major market for wet-process hardboard in the United States, but the development of OSB siding
has increased competition in this market. Wet-process hardboard is also being used as a substitute for solid wood
in trim applications. Expansion of product lines has included roof covering material in the form of tiles or simulated
wood shingles or shakes; this material is untreated and is being manufactured and used in South Africa and the
United States.
Dry-process hardboard is now becoming quite confused with thin MDF because the processes used for each are
somewhat similar. However, usually dry-process hardboard is of higher density than thin MDF. The dry-process
hardboard is bound together with synthetic adhesives the same as particleboard and MDF. The board usually has
poorer properties under wet conditions than does wet-process hardboard because the hemicelluloses, with their
affinity for water, are retained in the furnish rather than partially washed away as in wet-process hardboard.
However, a significant development of dry-process hardboard technology (some would argue this is MDF) is the
production of door skins. This development will be discussed under molded products; it is a major product line in
the United States.
COM-PLY(R)PANELS...
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5. COM-PLY panels are made with veneer and particles/flakes. Three-layer panels have veneer faces and particle
cores while five-layer panels have a veneer core (laid up with its grain direction at 90 degrees to the face veneer
grain direction). Panel-producing plants commenced production in the mid-1970s; however, all but one are no
longer operating. Today, one plant in Oregon is producing the five-layer board very successfully for subfloors,
sheathing, combination subfloor/floor, and siding.
WAFERBOARD...
Waferboard was first produced in 1955 in Dover, Idaho, in a plant that closed in the 1970s. The process, invented
by James d'A. Clark, uses large flakes, called wafers, that are bonded together into the final panel. The wafers,
more or less square in shape, are randomly oriented throughout the panel. Generally made from low-density
hardwoods, mostly aspen, waferboard was well accepted in several sheathing applications. The first large
production of waferboard occurred in Canada starting in the 1960s. Further production of waferboard in the United
States didn't happen until the late 1970s. waferboard has now been replaced in large part by OSB.
ORIENTED STRANDBOARD...
OSB panels are made from compressed strands lined up (oriented) and arranged in layers (usually three to live)
that are oriented more or less at right angles to one another. At times, the core layer may be of random orientation.
Panel stiffness and strength approaches that of plywood. OSB came to prominence in the 1980s as the technology
developed for manufacturing this product.
Almost all of the panels are used in structural applications in the same way as plywood. An exception is the
phenolic paper overlaid OSB that is used for siding. OSB is usually thinner compared to waferboard for the same
end uses, e.g., 7/16 inch versus 1/2 inch. Thus, there is a material savings when manufacturing OSB.
The OSB industry can use small irregular logs as the raw material, but it prefers ones that are relatively straight
and about 14 inches in diameter. The reasoning behind this is that usually the logs are debarked with ring-type
debarkers. Such debarking with the smaller logs is very time consuming and inefficient. However, a large amount
of the logs used are smaller than 14 inches in diameter. Drum debarkers designed especially for smaller-diameter
logs are now being used, but then there is some damage to the wood in the debarking operation.
There are now over 60 OSB plants in operation, with 20 others expected to begin production before 1998. Almost
all of the plants are in the United States and Canada. Other plants in operation or being constructed are in France,
Venezuela, Ireland, and Scotland. Great interest in OSB production is being expressed in Southeast Asia.
Most OSB is now made with strands that are 3 inches or longer in the surface layers. The core may be of smaller
strands and may or may not be oriented. The OSB segment of the industry has become an important part of the
structural panel business in recent years, comprising about 30 percent of the structural panel market.
This industry was developed using low-density hardwoods such as aspen; however, additional species such as
southern pine, lodgepole pine, jack pine, and Scotch pine are now being used. High-density species are still difficult
to use because boards produced from such species are also quite high in density. These boards are difficult to
handle, cut, and nail, and they are more expensive to ship.
...MOLDED PRODUCTS...
Molded products of fiber or particles have a long history in the industry, particularly in western Europe and in the
United States. Pallets, table tops, and door casings are some of the molded products made using particles. Molded
parts made out of wood fiber and plastic fiber have gained market share in the automobile industry, displacing
plastic products. The combination of wood fiber and plastic fiber makes it possible to produce inside car door
panels with deep draws or impressions and a high strength-to-weight ratio. These panels are overlaid with various
plastic coverings.
In recent years, door skins have become an important new molded fiberboard product. Door skins are thin MDF or
dry process hardboard panels molded (pressed) into one of many panel door patterns. These skins (one on each
side) are then glued to a wood frame to make up the final door. These doors are a replacement for solid wood
doors and their manufacture has attracted worldwide interest.
Molded structural parts for building offer excellent opportunities in the future. For example, folded plate designs
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6. for use in roof and floor members offer great strength with a minimum use of material. Perhaps molded wood
products will find a new life if the cost of plastics continues to increase.
...INORGANIC-BONDED PRODUCTS...
Inorganic-bonded panel products are composed of flakes, excelsior (wood wool), fibers, or other small particles
that are bonded together with inorganic materials, e.g., Portland cement or gypsum. The first cement-bonded
product was made in Austria in 1914 (excelsior bonded with cement). A plant producing this type of material
operated in Chewelah, Washington, in the 1930s and 1940s and these products were used for acoustic purposes in
many large auditoriums in the Eastern United States.
New developments in fast-curing bonding materials and processes have sparked worldwide interest in inorganic-
bonded panels. Gypsum fiberboard that utilizes these new technologies has been developed in Germany over the
past 20 years and has captured a significant part of the German gypsum board market. Conventional gypsum
board has the gypsum between two thick sheets of paper, but this new gypsum fiberboard product has fiber evenly
blended throughout the board. The gypsum fiberboard has to be cut and applied differently from the conventional
board. The raw material for this product can be all recycled material: waste paper for the fiber and gypsum
reclaimed from coal-burning electrical-generating plants. Gypsum fiberboard is being produced in one plant in
North America, in Eastern Canada.
Roof shingles and shakes are now being produced using wood particles or fibers bonded with cement. Currently,
several U.S. plants are making these products.
...LUMBER AND TIMBER PRODUCTS...
The decreasing quality of the world's forest and the amount of timber available for producing either conventional
lumber or high-quality lumber has led to a tremendous interest in producing composite lumber-like materials.
Research has shown that such materials can be made and, indeed, plants are now producing these lumber-like
products, which include laminated veneer lumber (LVL), COM-PLY, parallel strand lumber (PSL), and oriented
strand lumber (OSL).
LAMINATED VENEER LUMBER...
LVL has become the most important new lumber construction material. Primarily a structural material, it is made
of veneer laid up in one grain direction. It is made in billets 27 to 50 inches wide in either platen or continuous
presses. Long press times of over 20 minutes are needed to cure the adhesive in the billets, which are usually 1-
1/2 or 1-3/4 inches thick. Radio-frequency (RF) curing of the gluelines is now being used to significantly reduce the
press times.
The veneers are nondestructively tested to insure consistent strength in the structural-type LVL. The Trus Joist
Corporation (now Trus Joist MacMillan) pioneered the commercial development of LVL starting in the 1960s.
There are several LVL plants now operating in the United States. LVL used as flanges in I-joists has garnered about
30 percent of the U.S. wood floor market.
LVL products have been used primarily for structural applications, but millwork and furniture also utilize LVL. LVL
products mostly use phenolic glues, but new isocyanate and urethane technology is also available. Exposed LVL
can be made with colorless glues when desired. It is difficult to tell such products from solid wood.
COM-PLY
COM-PLY lumber, developed by the USDA Forest Service in the 1970s, is a material composed of random or
oriented wood flakes or particles sandwiched between one or more layers of veneer. One or more layers of veneer
are placed on the faces or edges of the lumber. A plant for producing COM-PLY lumber was in operation in North
Carolina. This plant produced an oriented flakeboard product that was cut into desired widths for making
composite lumber. Several layers of veneer were then laminated onto each edge of the flakeboard to make the
COM-PLY joist lumber. Veneer was laminated onto the flakeboard faces to make truss lumber. Although this
particular plant failed, there is still considerable interest in this product.
PARALLEL STRAND LUMBER...
ParallamTM is a PSL product developed by MacMillan Bloedel, Ltd., of Canada (now Trus Joist MacMillan). Many
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7. years of research and development led to the pilot plant production of Parallam. PSL products are made of
oriented strands of waste softwood veneer or from veneer peeled specifically for the PSL plant. Strand dimensions
are about 1R inch wide and up to about 37 inches long. Exterior-type plywood glue is applied to the strands, which
are oriented and laid-up into a mat in the lengthwise direction. The mat is then processed through a continuous
press. A microwave-type heating system was invented to permit the production of such a thick billet. The billet
sizes are generally either 11 by 18 inches or 11 by 14 inches. The billet is sawn into desired lengths, thicknesses,
and widths or used as produced. The resulting PSL serves markets where high-strength lumber or timber materials
are needed.
ScrimberTM is a product developed in Australia. "Scrim" is a term from the textile industry that means loosely
woven; "ber" in the name Scrimber comes from timber. For this product, small logs are crushed between rollers,
glue is applied, and the oriented mat of material is consolidated in a hot press into lumber. The details of the
process are proprietary. The first commercial plant was put into operation in the late 1980s, but it failed. It is now
being evaluated for a return to production. The Japanese have developed a similar product called ZephyrwoodTM
that is reportedly ready for commercialization.
ORIENTED STRAND LUMBER...
MacMillan Bloedel, Ltd. developed an OSL lumber product that is now called TimberStrandTM LSL (laminated
strand lumber). This is OSL made with nominal 12-inch- (300 mm) long strands. The lumber is pressed in a steam-
injection press that produces uniform density throughout. A relatively short press time results from the use of
steam-injection pressing. The first manufacturing plant is operated by Trus Joist MacMillan in Minnesota. Other
new plants are under construction.
OSB manufacturers are interested in this product and some are already producing it. OSB plants are designed so
that all the strands in a product can be aligned in one direction, which makes it convenient to produce both OSB
and OSL.
OSL faces a struggle to enter conventional lumber markets as a common building material because strength
properties must be measured and design values assigned to the lumber by testing organizations. This takes
considerable time and effort, but this effort is well underway.
Railroad ties can be produced by recycling old railroad ties. A product called Cedrite was invented in the 1970s,
and was being manufactured in a plant designed to produce 1,600 ties per day. In this process, old ties are
chipped; the metal is removed; the chips are hammermilled and then blended with resin in preparation for
production. The blended furnish is then placed into metal molds. Hardwood stiffeners are placed in the center of
the mats, which measure about 30 inches high, before being compressed to a final thickness of about 7 inches.
Once a mat is compressed into a mold, a top plate is secured over the compressed mat. The mold then goes into
an oven to cure the resin.
... WHAT'S AHEAD...
Much has happened in the field of composites over the last 40 years. Materials are now manufactured in
quantities that once were only dreams. It can be estimated that roughly 21 million tons of composite products are
manufactured annually in the United States alone, mostly out of previously unusable raw materials. The
development of composites has led to a far more efficient use of the trees that are harvested. Machinery and
production line developments have resulted in manufacturing efficiencies that further conserve raw materials. In
the future, the manufacture of wood composites will increase even more because it is expected that the forest
resource will provide fewer larger trees, particularly the conifers preferred for so long in the manufacture of lumber
and plywood. Composite products have become a large and important segment of the forest products industry,
and even more new composite plants are expected to begin production in the next few years.
...BIBLIOGRAPHY...
American Hardboard Association. 1988. Basic hardboard. ANSI/AHA A 135.4. American Hardboard Assoc.
Palatine, 111.
Food and Agriculture Organization of the United Nations, Secretariat. 1990. World production capacities: plywood,
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8. particleboard, and fibre board. FAO World Survey 1989. FAO Committee on Wood-Based Panel Products.
WPP/90/2. FAO, Rome, Italy.
Maloney, T.M. 1993. Modern Particleboard 5 Dry-Process Manufacturing. Updated edition. Miller Freeman
Publications, San Francisco, Calif.
Maloney, T.M., ed. 1967-1995. Proceedings of the International Particleboard/Composite Materials Symposium. 29
volumes. Washington State Univ. Pullman, Wash.
Moslemi, A.A., ed. 1988-1994. Proceedings of the Series of Conferences on Inorganic Bonded Wood and Wood
Fiber Composite Materials. 4 volumes. University of Idaho, Moscow. Idaho.
National Particleboard Association. 1993. Particleboard. ANSI A208.1. NPA, Gaithersburg. Md.
National Particleboard Association. 1994. Medium density fiberboard for interior use. ANSI/A 208.2. NPA,
Gaithersburg, Md.
Suchsland, O. and G. Woodson. 1986. Agriculture Handbook 640. USDA Forst Serv., Washington, D.C.
DETALHES
Assunto: Wood products; History; Composite materials; Applications
ClassificaĆ§Ć£o: 8630: Lumber &wood products industries, includes paper
TĆtulo: The family of wood composite materials
Autor: Maloney, T M
TĆtulo da publicaĆ§Ć£o: Forest Products Journal; Madison
Volume: 46
EdiĆ§Ć£o: 2
PƔginas: 18
NĆŗmero de pĆ”ginas: 9
Ano de publicaĆ§Ć£o: 1996
Data de publicaĆ§Ć£o: Feb 1996
Editora: Forest Products Society
Local de publicaĆ§Ć£o: Madison
PaĆs de publicaĆ§Ć£o: United States, Madison
Assunto da publicaĆ§Ć£o: Forests And Forestry--Lumber And Wood, Building And Construction
ISSN: 00157473
CODEN: FPJOAB
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