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Wikipedia

Engineered wood

February 16, 2024

Engineered wood, also called mass timber, composite wood, human-made wood, or manufactured board, includes a range of derivative wood products which are manufactured by binding or fixing the strands, particles, fibres, or veneers or boards of wood, together with adhesives, or other methods of fixation[1] to form composite material. The panels vary in size but can range upwards of 64 by 8 feet (19.5 by 2.4 m) and in the case of cross-laminated timber (CLT) can be of any thickness from a few inches to 16 inches (410 mm) or more.[2] These products are engineered to precise design specifications, which are tested to meet national or international standards and provide uniformity and predictability in their structural performance. Engineered wood products are used in a variety of applications, from home construction to commercial buildings to industrial products.[3] The products can be used for joists and beams that replace steel in many building projects.[4] The term mass timber describes a group of building materials that can replace concrete assemblies.[5]

Very large self-supporting wooden roof. Built for Expo 2000, Hanover, Germany
75-unit apartment building, made largely of wood, in Mission, British Columbia

Typically, engineered wood products are made from the same hardwoods and softwoods used to manufacture lumber. Sawmill scraps and other wood waste can be used for engineered wood composed of wood particles or fibers, but whole logs are usually used for veneers, such as plywood, medium-density fibreboard (MDF), or particle board. Some engineered wood products, like oriented strand board (OSB), can use trees from the poplar family, a common but non-structural species.

Wood-plastic composite, one kind of engineered wood

Alternatively, it is also possible to manufacture similar engineered bamboo from bamboo; and similar engineered cellulosic products from other lignin-containing materials such as rye straw, wheat straw, rice straw, hemp stalks, kenaf stalks, or sugar cane residue, in which case they contain no actual wood but rather vegetable fibers.

Flat-pack furniture is typically made out of human-made wood due to its low manufacturing costs and its low weight.

Types of products edit

 
Engineered wood products in a Home Depot store

There are a wide variety of engineered wood products for both structural and non-structural applications. This list is not comprehensive, and is intended to help categorize and distinguish between different types of engineered wood.

Wood-based panels edit

Wood structural panels are a collection of flat panel products, used extensively in building construction for sheathing, decking, cabinetry and millwork, and furniture. Examples include plywood and oriented strand board (OSB). Non-structural wood-based panels are flat-panel products, used in non-structural construction applications and furniture. Non-structural panels are usually covered with paint, wood veneer, or resin paper in their final form. Examples include fibreboard and particle board.[6]

Plywood edit

Plywood, a wood structural panel, is sometimes called the original engineered wood product.[7] Plywood is manufactured from sheets of cross-laminated veneer and bonded under heat and pressure with durable, moisture-resistant adhesives. By alternating the grain direction of the veneers from layer to layer, or "cross-orienting", panel strength and stiffness in both directions are maximized. Other structural wood panels include oriented strand boards and structural composite panels.[8]

Oriented strand board edit

Oriented strand board (OSB) is a wood structural panel manufactured from rectangular-shaped strands of wood that are oriented lengthwise and then arranged in layers, laid up into mats, and bonded together with moisture-resistant, heat-cured adhesives. The individual layers can be cross-oriented to provide strength and stiffness to the panel. Similar to plywood, most OSB panels are delivered with more strength in one direction. The wood strands in the outermost layer on each side of the board are normally aligned into the strongest direction of the board. Arrows on the product will often identify the strongest direction of the board (the height, or longest dimension, in most cases). Produced in huge, continuous mats, OSB is a solid panel product of consistent quality with no laps, gaps, or voids.[9] OSB is delivered in various dimensions, strengths, and levels of water resistance.

OSB and plywood are often used interchangeably in building construction.

Fibreboard edit

Medium-density fibreboard (MDF) and high-density fibreboard (hardboard or HDF) are made by breaking down hardwood or softwood residuals into wood fibers, combining them with wax and a resin binder, and forming panels by applying high temperature and pressure.[10] MDF is used in non-structural applications.

Particle board edit

Particle board is manufactured from wood chips, sawmill shavings, or even sawdust, and a synthetic resin or another suitable binder, which is pressed and extruded.[11] Research published in 2017 showed that durable particle board can be produced from agricultural waste products, such as rice husk or guinea corn husk.[12] Particleboard is cheaper, denser, and more uniform than conventional wood and plywood and is substituted for them when the cost is more important than strength and appearance. A major disadvantage of particleboard is that it is very prone to expansion and discoloration due to moisture, particularly when it is not covered with paint or another sealer. Particle board is used in non-structural applications.

Structural composite lumber edit

Structural composite lumber (SCL) is a class of materials made with layers of veneers, strands, or flakes bonded with adhesives. Unlike wood structural panels, structural composite lumber products generally have all grain fibers oriented in the same direction. The SCL family of engineered wood products are commonly used in the same structural applications as conventional sawn lumber and timber, including rafters, headers, beams, joists, rim boards, studs, and columns.[13] SCL products have higher dimensional stability and increased strength compared to conventional lumber products.

Laminated veneer edit

Laminated veneer lumber (LVL) is produced by bonding thin wood veneers together in a large billet, similar to plywood. The grain of all veneers in the LVL billet is parallel to the long direction (unlike plywood). The resulting product features enhanced mechanical properties and dimensional stability that offer a broader range in product width, depth, and length than conventional lumber.

Parallel strand edit

Parallel strand lumber (PSL) consists of long veneer strands laid in parallel formation and bonded together with an adhesive to form the finished structural section. The length-to-thickness ratio of strands in PSL is about 300. A strong, consistent material, it has a high load-carrying ability and is resistant to seasoning stresses so it is well suited for use as beams and columns for post and beam construction, and for beams, headers, and lintels for light framing construction.[13]

Laminated strand edit

Laminated strand lumber (LSL) and oriented strand lumber (OSL) are manufactured from flaked wood strands that have a high length-to-thickness ratio. Combined with an adhesive, the strands are oriented and formed into a large mat or billet and pressed. LSL and OSL offer good fastener-holding strength and mechanical-connector performance and are commonly used in a variety of applications, such as beams, headers, studs, rim boards, and millwork components. LSL is manufactured from relatively short strands—typically about 1 foot (0.30 m) long—compared to the 2-to-8-foot-long (0.61–2.44 m) strands used in PSL.[14] The length-to-thickness ratio of strands is about 150 for LSL and 75 for OSL.[13]

I-joists edit

I-joists are "I"-shaped structural members designed for use in floor and roof construction. An I-joist consists of top and bottom flanges of various widths united with webs of various depths. The flanges resist common bending stresses, and the web provides shear performance.[15] I-joists are designed to carry heavy loads over long distances while using less lumber than a dimensional solid wood joist of a size necessary to do the same task. As of 2005, approximately half of all wood light framed floors were framed using I-joists.[citation needed]

Mass timber edit

Mass timber, also known as engineered timber, is a class of large structural wood components for building construction. Mass timber components are made of lumber or veneers bonded with adhesives or mechanical fasteners. Certain types of mass timber, such as nail-laminated timber and glue-laminated timber, have existed for over a hundred years.[16] Mass timber enjoyed increasing popularity from 2012 to 2022, due to growing concern around the sustainability of building materials, and interest in prefabrication, off site construction, and modularization, for which mass timber is well suited. The various types of mass timber share the advantage of faster construction times as the components are manufactured off-site, and pre-finished to exact dimensions for simple on-site fastening.[17] Mass timber has been shown to have structural properties competitive with steel and concrete, opening the possibility to build large, tall buildings out of wood. Extensive testing has demonstrated the natural fire resistance properties of mass timber – primarily due the creation of a char layer around a column or beam which prevents fire from reaching the inner layers of wood.[2] In recognition of the proven structural and fire performance of mass timber, the International Building Code, a model code that forms the basis of many North American building codes, adopted new provisions in the 2021 code cycle that permit mass timber to be used in high-rise construction up to 18 stories.[18][19]

Cross-laminated timber edit

Cross-laminated timber (CLT) is a versatile multi-layered panel made of lumber. Each layer of boards is placed perpendicular to adjacent layers for increased rigidity and strength.[20] It is relatively new and gaining popularity within the construction industry as it can be used for long spans and all assemblies, e.g. floors, walls, or roofs.[20][21]

Glue-laminated timber edit

Glue-laminated timber (glulam) is composed of several layers of dimensional timber glued together with moisture-resistant adhesives, creating a large, strong, structural member that can be used as vertical columns or horizontal beams. Glulam can also be produced in curved shapes, offering extensive design flexibility.[21]

Dowel-laminated timber edit

Dowel laminated timber (DLT) is a less known type of mass timber product.  It is made by placing multiple boards of softwood lumber next to each together, each with a hole so that a hardwood dowel can be friction fitted through all of them.  As the hardwood dowel dries to reach an equilibrium moisture content with the softwood lumber, it expands into the surrounding boards creating a connection.  The use of a dowel connection eliminates the need for any metal fasteners or adhesives.[21]

Nail-laminated timber edit

Nail laminated timber (NLT) is a mass timber product that consists of parallel boards fastened with nails.[22] It can be used to create floors, roofs, walls, and elevator shafts within a building.[21] It is one of the oldest types of mass timber, being used in warehouse construction during the Industrial Revolution. Like DLT, no chemical adhesives are used, and wood fibers are oriented in the same direction.

Engineered wood flooring edit

Engineered wood flooring is a type of flooring product, similar to hardwood flooring, made of layers of wood or wood-based composite laminated together. The floor boards are usually milled with a tongue-and-groove profile on the edges for consistent joinery between boards.

Lamella edit

The lamella is the face layer of the wood that is visible when installed. Typically, it is a sawn piece of timber. The timber can be cut in three different styles: flat-sawn, quarter-sawn, and rift-sawn.

Types of core/substrate edit

  1. Wood ply construction ("sandwich core"): Uses multiple thin plies of wood adhered together. The wood grain of each ply runs perpendicular to the ply below it. Stability is attained from using thin layers of wood that have little to no reaction to climatic change. The wood is further stabilized due to equal pressure being exerted lengthwise and widthwise from the plies running perpendicular to each other.
  2. Finger core construction: Finger core engineered wood floors are made of small pieces of milled timber that run perpendicular to the top layer (lamella) of wood. They can be 2-ply or 3-ply, depending on their intended use. If it is three-ply, the third ply is often plywood that runs parallel to the lamella. Stability is gained through the grains running perpendicular to each other, and the expansion and contraction of wood are reduced and relegated to the middle ply, stopping the floor from gapping or cupping.
  3. Fibreboard: The core is made up of medium or high-density fibreboard. Floors with a fibreboard core are hygroscopic and must never be exposed to large amounts of water or very high humidity - the expansion caused by absorbing water combined with the density of the fibreboard, will cause it to lose its form. Fibreboard is less expensive than timber and can emit higher levels of harmful gases due to its relatively high adhesive content.
  4. An engineered flooring construction that is popular in parts of Europe is the hardwood lamella, softwood core laid perpendicular to the lamella, and a final backing layer of the same noble wood used for the lamella. Other noble hardwoods are sometimes used for the back layer but must be compatible. This is thought by many to be the most stable of engineered floors.

Other types of modified wood edit

New techniques have been introduced in the field of engineered wood in recent years.[when?] Natural wood is being transformed in laboratories through various chemical and physical treatments to achieve tailored mechanical, optical, thermal, and conduction properties, by influencing the wood's structure.

Densified wood edit

Densified wood can be made by using a mechanical hot press to compress wood fibers, sometimes in combination with chemical modification of the wood. These processes have been shown to increase the density by a factor of three.[23] This increase in density is expected to enhance the strength and stiffness of the wood by a proportional amount.[24] Studies published in 2018[25] combined chemical processes with traditional mechanical hot press methods. These chemical processes break down lignin and hemicellulose that are found naturally in the wood. Following dissolution, the cellulose strands that remain are mechanically hot compressed. Compared to the three-fold increase in strength observed from hot pressing alone, chemically processed wood has been shown to yield an 11-fold improvement. This extra strength comes from hydrogen bonds formed between the aligned cellulose nanofibers.

The densified wood possessed mechanical strength properties on par with steel used in building construction, opening the door for applications of densified wood in situations where regular strength wood would fail. Environmentally, wood requires significantly less carbon dioxide to produce than steel.[26]

Thermally efficient wood edit

Removing lignin from wood has several other applications, apart from providing structural advantages. Delignification alters the mechanical, thermal, optical, fluidic and ionic properties and functions of the natural wood and is an effective approach to regulating its thermal properties, as it removes the thermally conductive lignin component, while generating a large number of nanopores in the cell walls which help reduce temperature change. Delignified wood reflects most incident light and appears white in color.[27][28] White wood (also known as nanowood) has high reflection haze, as well as high emissivity in the infrared wavelengths. These two characteristics generate a passive radiative cooling effect, with an average cooling power of 53 W⋅m−2 over a 24-hour period,[28] meaning that this wood does not "absorb" heat and therefore only emits the heat embedded in it.[29] Moreover, white wood not only possesses a lower thermal conductivity than natural wood, and it has better thermal performance than most commercially available insulating materials.[27] The modification of the mesoporous structure of the wood is responsible for the changes in wood performance.[27][30]

White wood can also be put through a compression process, similar to the process mentioned for densified wood, which increases its mechanical performance compared to natural wood (8.7 times higher in tensile strength and 10 times higher in toughness).[28] The thermal and structural advantages of nanowood make it an attractive material for energy-efficient building construction.[30] However, the changes made in the wood's structural properties, like the increase in structural porosity and the partially isolated cellulose nanofibrils, damage the material's mechanical robustness. To deal with this issue, several strategies have been proposed, with one being to further densify the structure, and another to use cross-linking. Other suggestions include hybridizing natural wood with other organic particles and polymers to enhance its thermal insulation performance.[27]

Moldable wood edit

Using similar chemical modification techniques to chemically densified wood, wood can be made extremely moldable using a combination of delignification and water shock treatment. This is an emerging technology and is not yet used in industrial processes. However, initial tests show promising advantages in improved mechanical properties, with the molded wood exhibiting strength comparable to some metal alloys.[31]

Transparent wood composites edit

Transparent wood composites are new materials, currently[when?] only made at the laboratory scale, that combines transparency and stiffness via a chemical process that replaces light-absorbing compounds, such as lignin, with a transparent polymer.[32]

Environmental benefits edit

New construction is in high demand due to growing worldwide population. However, the main materials used in new construction are currently steel and concrete. The manufacturing of these materials creates comparatively high emissions of carbon dioxide (CO2) into the atmosphere. Engineered wood has the potential to reduce carbon emissions if it replaces steel and/or concrete in the construction of buildings.[33][34]

In 2014, steel and cement production accounted for about 1320 megatonnnes (Mt) CO2 and 1740 Mt CO2 respectively, which made up about 9% of global CO2 emissions that year.[35] In a study that did not take the carbon sequestration potential of engineered wood into account, it was found that roughly 50 Mt CO2e (carbon dioxide equivalent[a]) could be eliminated by 2050 with the full uptake of a hybrid construction system utilizing engineered wood and steel.[37] When considering the added effects that carbon sequestration can have over the lifetime of the material, the emissions reductions of engineered wood is even more substantial, as laminated wood that is not incinerated at the end of its lifecycle absorbs around 582 kg of CO2/m3, while reinforced concrete emits 458 kg CO2/m3 and steel 12.087 kg CO2/m3.[38]

There is not a strong consensus for measuring the carbon sequestration potential of wood. In life-cycle assessment, sequestered carbon is sometimes called biogenic carbon. ISO 21930, a standard that governs life cycle assessment, requires the biogenic carbon from a wood product can only be included as a negative input (i.e. carbon sequestration) when the wood product originated in a sustainably managed forest. This generally means that wood needs to be FSC or SFI-certified to qualify as carbon sequestering.[39]

Advantages edit

Engineered wood products are used in a variety of ways,[40] often in applications similar to solid wood products:

  • Mass timber (MT) is lightweight allowing the wood to be easily handled, manufactured, and transported. This contributes to it being cost effective and easy to use on site.[41]
  • MT offers greater strength and stiffness (based on its strength to weight ratio), increased dimensional stability, and uniformity in structures.[41]
  • When compared to steel/concrete, MT built buildings use up to 15% less energy because of the reduced energy needed to create these wood products.[41]
  • MT buildings on average save 20-25% in time when compared to conventional steel/concrete buildings and 4.2% on capital cost.[41]
  • MT products sequester carbon and store it within themselves over their lifespan.  Using this instead of concrete and steel in buildings will reduce the embodied emissions in buildings.[21]
  • Using MT has an estimated savings of around 20% in embodied carbon when compared to steel or concrete.  This is because MT is a lot lighter when compared to these two materials, so it is less intensive for the machinery to transport both to site and once delivered.[21]
  • MT products also have high levels of airtightness and low coefficients of thermal conductivity meaning that the air inside cannot escape, and heat isn't lost easily.[21]
  • MT built buildings perform very well in seismic events because they are roughly half the mass and half the stiffness when compared to reinforced concrete buildings which properties that are desirable.  Having half the stiffness allows MT buildings to be ductile which leads to it being able to resist lateral distortion without compromising the structural integrity of the building.[21]
  • MT is fire resistant to an extent.  Although it is considered a combustible material, MT burns slowly and in a predictable manner.  When it is burned, a charred layer is formed on the outside that protects the inner layers of the wood.  However, once the charred layer falls off, the inner layers will be exposed which can compromise the integrity of the material.[21]

All mass timber products offer different types of advantages, and they can be seen in the following:

  • CLT: Offers high dimensional stability, high strength and stiffness and is easy to manufacture.[21]
  • Glulam: Offers high strength and stiffness, is structurally efficient, and can be manufactured into complex shapes.[21]
  • NLT: Doesn't require any specialized equipment to manufacture, is cost effective, and easy to handle.[21]
  • DLT: Offers high dimensional stability, is easy and safe to manufacture, and no metal fasteners or adhesive is required.[21]
  • SCL: Is able to withstand greater loads compared to solid timber and is not prone to shrinking, splitting or warping.[21]

Engineered wood products may be preferred over solid wood in some applications due to certain comparative advantages:

  • Because engineered wood is human-made, it can be designed to meet application-specific performance requirements. Required shapes and dimension do not drive source tree requirements (length or width of the tree)
  • Engineered wood products are versatile and available in a wide variety of thicknesses, sizes, grades, and exposure durability classifications, making the products ideal for use in unlimited construction, industrial, and home project application.[42]
  • Engineered wood products are designed and manufactured to maximize the natural strength and stiffness characteristics of wood. The products are very stable and some offer greater structural strength than typical wood building materials.[43]
  • Glued laminated timber (glulam) has greater strength and stiffness than comparable dimensional lumber and, pound for pound, is stronger than steel.[3]
  • Engineered wood panels are easy to work with using ordinary tools and basic skills. They can be cut, drilled, routed, jointed, glued, and fastened. Plywood can be bent to form curved surfaces without loss of strength. Large panel sizes speeds up construction by reducing the number of pieces that need to be handled and installed.[42]
  • Engineered wood products are a more efficient use of wood as they can be made from wood that has defects, underutilized species or smaller pieces of wood which also enables the use of smaller trees[44]
  • Wooden trusses are competitive in many roof and floor applications, and their high strength-to-weight ratios permit long spans offering flexibility in floor layouts.[45]
  • Sustainable design advocates recommend using engineered wood, which can be produced from relatively small trees, rather than large pieces of solid dimensional lumber, which requires cutting a large tree.[14]

Disadvantages edit

  • Like solid wood, when exposed to high moisture conditions or termites, biodeteriorations and/or fungi decay will occur which reduces the structural integrity and durability of the wood product; essentially the wood will start to rot.[41]
  • Raises concerns about potential widespread deforestation but can be mitigated with a sustainable forestry management plan.[21]
  • MT buildings are susceptible to wind driven oscillation because of the relative flexibility of the MT material which may cause discomfort to people in the building.[21]

All mass timber products have different disadvantages, and they can be seen in the following:

  • CLT and Glulam: They both have high cost.[21]
  • NLT: It is labor intensive to make and there is significant potential for human error.[21]
  • DLT: It has limited panel sizing and thickness.[21]
  • SCL: It has limited panel sizing and thickness and is more suitable for low rise buildings.[21]

When compared to solid wood the following disadvantages are prevalent:

  • They require more primary energy for their manufacture than solid lumber.[46]
  • The adhesives used in some products may be toxic. A concern with some resins is the release of formaldehyde in the finished product, often seen with urea-formaldehyde bonded products.[46]

Properties edit

Plywood and OSB typically have a density of 560–640 kg/m3 (35–40 lb/cu ft). For example, 9.5 mm (38 in) plywood sheathing or OSB sheathing typically has a surface density of 4.9–5.9 kg/m2 (1–1.2 lb/sq ft).[47] Many other engineered woods have densities much higher than OSB.

Adhesives edit

The types of adhesives used in engineered wood include:

A more inclusive term is structural composites. For example, fiber cement siding is made of cement and wood fiber, while cement board is a low-density cement panel, often with added resin, faced with fiberglass mesh.

Health concerns edit

While formaldehyde is an essential ingredient of cellular metabolism in mammals, studies have linked prolonged inhalation of formaldehyde gases to cancer. Engineered wood composites have been found to emit potentially harmful amounts of formaldehyde gas in two ways: unreacted free formaldehyde and the chemical decomposition of resin adhesives. When excessive amounts of formaldehyde are added to a process, the surplus will not have any additive to bond with and may seep from the wood product over time. Cheap urea-formaldehyde (UF) adhesives are largely responsible for degraded resin emissions. Moisture degrades the weak UF molecules, resulting in potentially harmful formaldehyde emissions. McLube offers release agents and platen sealers designed for those manufacturers who use reduced-formaldehyde UF and melamine-formaldehyde adhesives. Many OSB and plywood manufacturers use phenol-formaldehyde (PF) because phenol is a much more effective additive. Phenol forms a water-resistant bond with formaldehyde that will not degrade in moist environments. PF resins have not been found to pose significant health risks due to formaldehyde emissions. While PF is an excellent adhesive, the engineered wood industry has started to shift toward polyurethane binders like pMDI to achieve even greater water resistance, strength, and process efficiency. pMDIs are also used extensively in the production of rigid polyurethane foams and insulators for refrigeration. pMDIs outperform other resin adhesives, but they are notoriously difficult to release and cause buildup on tooling surfaces.[48]

Mechanical fasteners edit

Some engineered wood products, such as DLT, NLT, and some brands of CLT, can be assembled without the use of adhesives using mechanical fasteners or joinery. These can range from profiled interlocking jointed boards,[49][50] proprietary metal fixings, nails or timber dowels.[51]

Building codes and standards edit

Throughout the years mass timber was used in buildings, codes were added to and adopted by the International Building Code (IBC) to create standards for them for the proper use and handling. For example, in 2015, CLT was incorporated into the IBC.[33] The 2021 IBC is the latest issue of building codes, and has added three new codes regarding construction with timber material.  The new three construction types go as follows, IV-A, IV-B, and IV-C, and they allow mass timber to be used in buildings up to 18, 12, and nine stories respectively.[52]

The following standards are related to engineered wood products:

  • EN 300 - Oriented Strand Boards (OSB) — Definitions, classification, and specifications
  • EN 309 - Particleboards — Definition and classification
  • EN 338 - Structural timber - Strength classes
  • EN 386 - Glued laminated timber — performance requirements and minimum production requirements
  • EN 313-1 - Plywood — Classification and terminology Part 1: Classification
  • EN 313-2 - Plywood — Classification and terminology Part 2: Terminology
  • EN 314-1 - Plywood — Bonding quality — Part 1: Test methods
  • EN 314-2 - Plywood — Bonding quality — Part 2: Requirements
  • EN 315 - Plywood — Tolerances for dimensions
  • EN 387 - Glued laminated timber — large finger joints - performance requirements and minimum production requirements
  • EN 390 - Glued laminated timber — sizes - permissible deviations
  • EN 391 - Glued laminated timber — shear test of glue lines
  • EN 392 - Glued laminated timber — Shear test of glue lines
  • EN 408 - Timber structures — Structural timber and glued laminated timber — Determination of some physical and mechanical properties
  • EN 622-1 - Fibreboards — Specifications — Part 1: General requirements
  • EN 622-2 - Fibreboards — Specifications — Part 2: Requirements for hardboards
  • EN 622-3 - Fibreboards — Specifications — Part 3: Requirements for medium boards
  • EN 622-4 - Fibreboards — Specifications — Part 4: Requirements for soft boards
  • EN 622-5 - Fibreboards — Specifications — Part 5: Requirements for dry process boards (MDF)
  • EN 1193 - Timber structures — Structural timber and glued laminated timber - Determination of shear strength and mechanical properties perpendicular to the grain
  • EN 1194 - Timber structures — Glued laminated timber - Strength classes and determination of characteristic values
  • EN 1995-1-1 - Eurocode 5: Design of timber structures — Part 1-1: General — Common rules and rules for buildings
  • EN 12369-1 - Wood-based panels — Characteristic values for structural design — Part 1: OSB, particleboards, and fibreboards
  • EN 12369-2 - Wood-based panels — Characteristic values for structural design — Part 2: Plywood
  • EN 12369-3 - Wood-based panels — Characteristic values for structural design — Part 3: Solid wood panels
  • EN 14080 - Timber structures — Glued laminated timber — Requirements
  • EN 14081-1 - Timber structures - Strength graded structural timber with rectangular cross-section - Part 1: General requirements
  • ISO 21930:2017 - Sustainability in buildings and civil engineering works - Core rules for environmental product declarations of construction products and services

Examples of mass timber structures edit

Plyscrapers edit

Plyscrapers are skyscrapers that are either partially made of wood or entirely made of wood. Around the world, there have been many different plyscrapers built including Ascent MKE building and the Stadthaus building.[53]

The Ascent MKE building was built in 2022 in Milwaukee, Wisconsin and is the tallest high-rise building using different mass timber components in combination with some steel and concrete.  This plyscraper is 87 meters tall and has 25 stories.[54]

The Stadthaus building is a residential building built in 2009 in Hackney, London.  It has 9 stories reaching 30 meters tall.  It uses CLT panels as load-bearing walls and floor 'slabs'.[55]

Bridges edit

The Mistissini Bridge built in Quebec, Canada, in 2014 is a 160-meter-long bridge that features both glulam beams and CLT panels.  The bridge was designed to cross over the Uupaachikus Pass.[56]

The Placer River Pedestrian Bridge built in Alaska, United States, in 2013.  It spans 85 metres (280 ft) long and is located in the Chugach National Forest.  This bridge features glulam as it was used create the trusses.[56]

Parking structures edit

The Glenwood CLT Parking Garage in Springfield, Oregon, is going to be a 19,100-square-metre (206,000 sq ft) garage that features CLT.  It will be 4 stories tall and hold 360 parking spaces.  The parking garage however is under construction as of December 2022, and the year of completion is not yet known.[57]

Notes edit

  1. ^ Carbon dioxide equivalent (CO2e) is a way of measuring the global warming potential of multiple greenhouse gases using a common unit. 1 kg of methane emissions, for instance, has the same global warming potential as 25 kg of CO2 emissions, so 1 kg of methane emissions can be reported as 25 kg CO2e.[36]

References edit

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  4. ^ Naturally:wood Engineered wood Archived May 22, 2016, at the Portuguese Web Archive. Naturallywood.com. Retrieved on February 15, 2012.
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  • Engineered Wood Products Association

February 16, 2024
engineered, wood, also, called, mass, timber, composite, wood, human, made, wood, manufactured, board, includes, range, derivative, wood, products, which, manufactured, binding, fixing, strands, particles, fibres, veneers, boards, wood, together, with, adhesiv. Engineered wood also called mass timber composite wood human made wood or manufactured board includes a range of derivative wood products which are manufactured by binding or fixing the strands particles fibres or veneers or boards of wood together with adhesives or other methods of fixation 1 to form composite material The panels vary in size but can range upwards of 64 by 8 feet 19 5 by 2 4 m and in the case of cross laminated timber CLT can be of any thickness from a few inches to 16 inches 410 mm or more 2 These products are engineered to precise design specifications which are tested to meet national or international standards and provide uniformity and predictability in their structural performance Engineered wood products are used in a variety of applications from home construction to commercial buildings to industrial products 3 The products can be used for joists and beams that replace steel in many building projects 4 The term mass timber describes a group of building materials that can replace concrete assemblies 5 Very large self supporting wooden roof Built for Expo 2000 Hanover Germany75 unit apartment building made largely of wood in Mission British ColumbiaTypically engineered wood products are made from the same hardwoods and softwoods used to manufacture lumber Sawmill scraps and other wood waste can be used for engineered wood composed of wood particles or fibers but whole logs are usually used for veneers such as plywood medium density fibreboard MDF or particle board Some engineered wood products like oriented strand board OSB can use trees from the poplar family a common but non structural species Wood plastic composite one kind of engineered woodAlternatively it is also possible to manufacture similar engineered bamboo from bamboo and similar engineered cellulosic products from other lignin containing materials such as rye straw wheat straw rice straw hemp stalks kenaf stalks or sugar cane residue in which case they contain no actual wood but rather vegetable fibers Flat pack furniture is typically made out of human made wood due to its low manufacturing costs and its low weight Contents 1 Types of products 1 1 Wood based panels 1 1 1 Plywood 1 1 2 Oriented strand board 1 1 3 Fibreboard 1 1 4 Particle board 1 2 Structural composite lumber 1 2 1 Laminated veneer 1 2 2 Parallel strand 1 2 3 Laminated strand 1 3 I joists 1 4 Mass timber 1 4 1 Cross laminated timber 1 4 2 Glue laminated timber 1 4 3 Dowel laminated timber 1 4 4 Nail laminated timber 1 5 Engineered wood flooring 1 5 1 Lamella 1 5 2 Types of core substrate 1 6 Other types of modified wood 1 6 1 Densified wood 1 6 2 Thermally efficient wood 1 6 3 Moldable wood 1 6 4 Transparent wood composites 2 Environmental benefits 3 Advantages 4 Disadvantages 5 Properties 6 Adhesives 6 1 Health concerns 6 2 Mechanical fasteners 7 Building codes and standards 8 Examples of mass timber structures 8 1 Plyscrapers 8 2 Bridges 8 3 Parking structures 9 Notes 10 References 11 External linksTypes of products edit nbsp Engineered wood products in a Home Depot storeThere are a wide variety of engineered wood products for both structural and non structural applications This list is not comprehensive and is intended to help categorize and distinguish between different types of engineered wood Wood based panels edit Wood structural panels are a collection of flat panel products used extensively in building construction for sheathing decking cabinetry and millwork and furniture Examples include plywood and oriented strand board OSB Non structural wood based panels are flat panel products used in non structural construction applications and furniture Non structural panels are usually covered with paint wood veneer or resin paper in their final form Examples include fibreboard and particle board 6 Plywood edit Plywood a wood structural panel is sometimes called the original engineered wood product 7 Plywood is manufactured from sheets of cross laminated veneer and bonded under heat and pressure with durable moisture resistant adhesives By alternating the grain direction of the veneers from layer to layer or cross orienting panel strength and stiffness in both directions are maximized Other structural wood panels include oriented strand boards and structural composite panels 8 Oriented strand board edit Oriented strand board OSB is a wood structural panel manufactured from rectangular shaped strands of wood that are oriented lengthwise and then arranged in layers laid up into mats and bonded together with moisture resistant heat cured adhesives The individual layers can be cross oriented to provide strength and stiffness to the panel Similar to plywood most OSB panels are delivered with more strength in one direction The wood strands in the outermost layer on each side of the board are normally aligned into the strongest direction of the board Arrows on the product will often identify the strongest direction of the board the height or longest dimension in most cases Produced in huge continuous mats OSB is a solid panel product of consistent quality with no laps gaps or voids 9 OSB is delivered in various dimensions strengths and levels of water resistance OSB and plywood are often used interchangeably in building construction Fibreboard edit Medium density fibreboard MDF and high density fibreboard hardboard or HDF are made by breaking down hardwood or softwood residuals into wood fibers combining them with wax and a resin binder and forming panels by applying high temperature and pressure 10 MDF is used in non structural applications Particle board edit Particle board is manufactured from wood chips sawmill shavings or even sawdust and a synthetic resin or another suitable binder which is pressed and extruded 11 Research published in 2017 showed that durable particle board can be produced from agricultural waste products such as rice husk or guinea corn husk 12 Particleboard is cheaper denser and more uniform than conventional wood and plywood and is substituted for them when the cost is more important than strength and appearance A major disadvantage of particleboard is that it is very prone to expansion and discoloration due to moisture particularly when it is not covered with paint or another sealer Particle board is used in non structural applications Structural composite lumber edit Structural composite lumber SCL is a class of materials made with layers of veneers strands or flakes bonded with adhesives Unlike wood structural panels structural composite lumber products generally have all grain fibers oriented in the same direction The SCL family of engineered wood products are commonly used in the same structural applications as conventional sawn lumber and timber including rafters headers beams joists rim boards studs and columns 13 SCL products have higher dimensional stability and increased strength compared to conventional lumber products Laminated veneer edit Laminated veneer lumber LVL is produced by bonding thin wood veneers together in a large billet similar to plywood The grain of all veneers in the LVL billet is parallel to the long direction unlike plywood The resulting product features enhanced mechanical properties and dimensional stability that offer a broader range in product width depth and length than conventional lumber Parallel strand edit Parallel strand lumber PSL consists of long veneer strands laid in parallel formation and bonded together with an adhesive to form the finished structural section The length to thickness ratio of strands in PSL is about 300 A strong consistent material it has a high load carrying ability and is resistant to seasoning stresses so it is well suited for use as beams and columns for post and beam construction and for beams headers and lintels for light framing construction 13 Laminated strand edit Laminated strand lumber LSL and oriented strand lumber OSL are manufactured from flaked wood strands that have a high length to thickness ratio Combined with an adhesive the strands are oriented and formed into a large mat or billet and pressed LSL and OSL offer good fastener holding strength and mechanical connector performance and are commonly used in a variety of applications such as beams headers studs rim boards and millwork components LSL is manufactured from relatively short strands typically about 1 foot 0 30 m long compared to the 2 to 8 foot long 0 61 2 44 m strands used in PSL 14 The length to thickness ratio of strands is about 150 for LSL and 75 for OSL 13 I joists edit I joists are I shaped structural members designed for use in floor and roof construction An I joist consists of top and bottom flanges of various widths united with webs of various depths The flanges resist common bending stresses and the web provides shear performance 15 I joists are designed to carry heavy loads over long distances while using less lumber than a dimensional solid wood joist of a size necessary to do the same task As of 2005 approximately half of all wood light framed floors were framed using I joists citation needed Mass timber edit Mass timber also known as engineered timber is a class of large structural wood components for building construction Mass timber components are made of lumber or veneers bonded with adhesives or mechanical fasteners Certain types of mass timber such as nail laminated timber and glue laminated timber have existed for over a hundred years 16 Mass timber enjoyed increasing popularity from 2012 to 2022 due to growing concern around the sustainability of building materials and interest in prefabrication off site construction and modularization for which mass timber is well suited The various types of mass timber share the advantage of faster construction times as the components are manufactured off site and pre finished to exact dimensions for simple on site fastening 17 Mass timber has been shown to have structural properties competitive with steel and concrete opening the possibility to build large tall buildings out of wood Extensive testing has demonstrated the natural fire resistance properties of mass timber primarily due the creation of a char layer around a column or beam which prevents fire from reaching the inner layers of wood 2 In recognition of the proven structural and fire performance of mass timber the International Building Code a model code that forms the basis of many North American building codes adopted new provisions in the 2021 code cycle that permit mass timber to be used in high rise construction up to 18 stories 18 19 Cross laminated timber edit Cross laminated timber CLT is a versatile multi layered panel made of lumber Each layer of boards is placed perpendicular to adjacent layers for increased rigidity and strength 20 It is relatively new and gaining popularity within the construction industry as it can be used for long spans and all assemblies e g floors walls or roofs 20 21 Glue laminated timber edit Glue laminated timber glulam is composed of several layers of dimensional timber glued together with moisture resistant adhesives creating a large strong structural member that can be used as vertical columns or horizontal beams Glulam can also be produced in curved shapes offering extensive design flexibility 21 Dowel laminated timber edit Dowel laminated timber DLT is a less known type of mass timber product It is made by placing multiple boards of softwood lumber next to each together each with a hole so that a hardwood dowel can be friction fitted through all of them As the hardwood dowel dries to reach an equilibrium moisture content with the softwood lumber it expands into the surrounding boards creating a connection The use of a dowel connection eliminates the need for any metal fasteners or adhesives 21 Nail laminated timber edit Nail laminated timber NLT is a mass timber product that consists of parallel boards fastened with nails 22 It can be used to create floors roofs walls and elevator shafts within a building 21 It is one of the oldest types of mass timber being used in warehouse construction during the Industrial Revolution Like DLT no chemical adhesives are used and wood fibers are oriented in the same direction Engineered wood flooring edit Engineered wood flooring is a type of flooring product similar to hardwood flooring made of layers of wood or wood based composite laminated together The floor boards are usually milled with a tongue and groove profile on the edges for consistent joinery between boards Lamella edit The lamella is the face layer of the wood that is visible when installed Typically it is a sawn piece of timber The timber can be cut in three different styles flat sawn quarter sawn and rift sawn Types of core substrate edit Wood ply construction sandwich core Uses multiple thin plies of wood adhered together The wood grain of each ply runs perpendicular to the ply below it Stability is attained from using thin layers of wood that have little to no reaction to climatic change The wood is further stabilized due to equal pressure being exerted lengthwise and widthwise from the plies running perpendicular to each other Finger core construction Finger core engineered wood floors are made of small pieces of milled timber that run perpendicular to the top layer lamella of wood They can be 2 ply or 3 ply depending on their intended use If it is three ply the third ply is often plywood that runs parallel to the lamella Stability is gained through the grains running perpendicular to each other and the expansion and contraction of wood are reduced and relegated to the middle ply stopping the floor from gapping or cupping Fibreboard The core is made up of medium or high density fibreboard Floors with a fibreboard core are hygroscopic and must never be exposed to large amounts of water or very high humidity the expansion caused by absorbing water combined with the density of the fibreboard will cause it to lose its form Fibreboard is less expensive than timber and can emit higher levels of harmful gases due to its relatively high adhesive content An engineered flooring construction that is popular in parts of Europe is the hardwood lamella softwood core laid perpendicular to the lamella and a final backing layer of the same noble wood used for the lamella Other noble hardwoods are sometimes used for the back layer but must be compatible This is thought by many to be the most stable of engineered floors Other types of modified wood edit New techniques have been introduced in the field of engineered wood in recent years when Natural wood is being transformed in laboratories through various chemical and physical treatments to achieve tailored mechanical optical thermal and conduction properties by influencing the wood s structure Densified wood edit Densified wood can be made by using a mechanical hot press to compress wood fibers sometimes in combination with chemical modification of the wood These processes have been shown to increase the density by a factor of three 23 This increase in density is expected to enhance the strength and stiffness of the wood by a proportional amount 24 Studies published in 2018 25 combined chemical processes with traditional mechanical hot press methods These chemical processes break down lignin and hemicellulose that are found naturally in the wood Following dissolution the cellulose strands that remain are mechanically hot compressed Compared to the three fold increase in strength observed from hot pressing alone chemically processed wood has been shown to yield an 11 fold improvement This extra strength comes from hydrogen bonds formed between the aligned cellulose nanofibers The densified wood possessed mechanical strength properties on par with steel used in building construction opening the door for applications of densified wood in situations where regular strength wood would fail Environmentally wood requires significantly less carbon dioxide to produce than steel 26 Thermally efficient wood edit Removing lignin from wood has several other applications apart from providing structural advantages Delignification alters the mechanical thermal optical fluidic and ionic properties and functions of the natural wood and is an effective approach to regulating its thermal properties as it removes the thermally conductive lignin component while generating a large number of nanopores in the cell walls which help reduce temperature change Delignified wood reflects most incident light and appears white in color 27 28 White wood also known as nanowood has high reflection haze as well as high emissivity in the infrared wavelengths These two characteristics generate a passive radiative cooling effect with an average cooling power of 53 W m 2 over a 24 hour period 28 meaning that this wood does not absorb heat and therefore only emits the heat embedded in it 29 Moreover white wood not only possesses a lower thermal conductivity than natural wood and it has better thermal performance than most commercially available insulating materials 27 The modification of the mesoporous structure of the wood is responsible for the changes in wood performance 27 30 White wood can also be put through a compression process similar to the process mentioned for densified wood which increases its mechanical performance compared to natural wood 8 7 times higher in tensile strength and 10 times higher in toughness 28 The thermal and structural advantages of nanowood make it an attractive material for energy efficient building construction 30 However the changes made in the wood s structural properties like the increase in structural porosity and the partially isolated cellulose nanofibrils damage the material s mechanical robustness To deal with this issue several strategies have been proposed with one being to further densify the structure and another to use cross linking Other suggestions include hybridizing natural wood with other organic particles and polymers to enhance its thermal insulation performance 27 Moldable wood edit Using similar chemical modification techniques to chemically densified wood wood can be made extremely moldable using a combination of delignification and water shock treatment This is an emerging technology and is not yet used in industrial processes However initial tests show promising advantages in improved mechanical properties with the molded wood exhibiting strength comparable to some metal alloys 31 Transparent wood composites edit Transparent wood composites are new materials currently when only made at the laboratory scale that combines transparency and stiffness via a chemical process that replaces light absorbing compounds such as lignin with a transparent polymer 32 Environmental benefits editNew construction is in high demand due to growing worldwide population However the main materials used in new construction are currently steel and concrete The manufacturing of these materials creates comparatively high emissions of carbon dioxide CO2 into the atmosphere Engineered wood has the potential to reduce carbon emissions if it replaces steel and or concrete in the construction of buildings 33 34 In 2014 steel and cement production accounted for about 1320 megatonnnes Mt CO2 and 1740 Mt CO2 respectively which made up about 9 of global CO2 emissions that year 35 In a study that did not take the carbon sequestration potential of engineered wood into account it was found that roughly 50 Mt CO2e carbon dioxide equivalent a could be eliminated by 2050 with the full uptake of a hybrid construction system utilizing engineered wood and steel 37 When considering the added effects that carbon sequestration can have over the lifetime of the material the emissions reductions of engineered wood is even more substantial as laminated wood that is not incinerated at the end of its lifecycle absorbs around 582 kg of CO2 m3 while reinforced concrete emits 458 kg CO2 m3 and steel 12 087 kg CO2 m3 38 There is not a strong consensus for measuring the carbon sequestration potential of wood In life cycle assessment sequestered carbon is sometimes called biogenic carbon ISO 21930 a standard that governs life cycle assessment requires the biogenic carbon from a wood product can only be included as a negative input i e carbon sequestration when the wood product originated in a sustainably managed forest This generally means that wood needs to be FSC or SFI certified to qualify as carbon sequestering 39 Advantages editEngineered wood products are used in a variety of ways 40 often in applications similar to solid wood products Mass timber MT is lightweight allowing the wood to be easily handled manufactured and transported This contributes to it being cost effective and easy to use on site 41 MT offers greater strength and stiffness based on its strength to weight ratio increased dimensional stability and uniformity in structures 41 When compared to steel concrete MT built buildings use up to 15 less energy because of the reduced energy needed to create these wood products 41 MT buildings on average save 20 25 in time when compared to conventional steel concrete buildings and 4 2 on capital cost 41 MT products sequester carbon and store it within themselves over their lifespan Using this instead of concrete and steel in buildings will reduce the embodied emissions in buildings 21 Using MT has an estimated savings of around 20 in embodied carbon when compared to steel or concrete This is because MT is a lot lighter when compared to these two materials so it is less intensive for the machinery to transport both to site and once delivered 21 MT products also have high levels of airtightness and low coefficients of thermal conductivity meaning that the air inside cannot escape and heat isn t lost easily 21 MT built buildings perform very well in seismic events because they are roughly half the mass and half the stiffness when compared to reinforced concrete buildings which properties that are desirable Having half the stiffness allows MT buildings to be ductile which leads to it being able to resist lateral distortion without compromising the structural integrity of the building 21 MT is fire resistant to an extent Although it is considered a combustible material MT burns slowly and in a predictable manner When it is burned a charred layer is formed on the outside that protects the inner layers of the wood However once the charred layer falls off the inner layers will be exposed which can compromise the integrity of the material 21 All mass timber products offer different types of advantages and they can be seen in the following CLT Offers high dimensional stability high strength and stiffness and is easy to manufacture 21 Glulam Offers high strength and stiffness is structurally efficient and can be manufactured into complex shapes 21 NLT Doesn t require any specialized equipment to manufacture is cost effective and easy to handle 21 DLT Offers high dimensional stability is easy and safe to manufacture and no metal fasteners or adhesive is required 21 SCL Is able to withstand greater loads compared to solid timber and is not prone to shrinking splitting or warping 21 Engineered wood products may be preferred over solid wood in some applications due to certain comparative advantages Because engineered wood is human made it can be designed to meet application specific performance requirements Required shapes and dimension do not drive source tree requirements length or width of the tree Engineered wood products are versatile and available in a wide variety of thicknesses sizes grades and exposure durability classifications making the products ideal for use in unlimited construction industrial and home project application 42 Engineered wood products are designed and manufactured to maximize the natural strength and stiffness characteristics of wood The products are very stable and some offer greater structural strength than typical wood building materials 43 Glued laminated timber glulam has greater strength and stiffness than comparable dimensional lumber and pound for pound is stronger than steel 3 Engineered wood panels are easy to work with using ordinary tools and basic skills They can be cut drilled routed jointed glued and fastened Plywood can be bent to form curved surfaces without loss of strength Large panel sizes speeds up construction by reducing the number of pieces that need to be handled and installed 42 Engineered wood products are a more efficient use of wood as they can be made from wood that has defects underutilized species or smaller pieces of wood which also enables the use of smaller trees 44 Wooden trusses are competitive in many roof and floor applications and their high strength to weight ratios permit long spans offering flexibility in floor layouts 45 Sustainable design advocates recommend using engineered wood which can be produced from relatively small trees rather than large pieces of solid dimensional lumber which requires cutting a large tree 14 Disadvantages editLike solid wood when exposed to high moisture conditions or termites biodeteriorations and or fungi decay will occur which reduces the structural integrity and durability of the wood product essentially the wood will start to rot 41 Raises concerns about potential widespread deforestation but can be mitigated with a sustainable forestry management plan 21 MT buildings are susceptible to wind driven oscillation because of the relative flexibility of the MT material which may cause discomfort to people in the building 21 All mass timber products have different disadvantages and they can be seen in the following CLT and Glulam They both have high cost 21 NLT It is labor intensive to make and there is significant potential for human error 21 DLT It has limited panel sizing and thickness 21 SCL It has limited panel sizing and thickness and is more suitable for low rise buildings 21 When compared to solid wood the following disadvantages are prevalent They require more primary energy for their manufacture than solid lumber 46 The adhesives used in some products may be toxic A concern with some resins is the release of formaldehyde in the finished product often seen with urea formaldehyde bonded products 46 Properties editPlywood and OSB typically have a density of 560 640 kg m3 35 40 lb cu ft For example 9 5 mm 3 8 in plywood sheathing or OSB sheathing typically has a surface density of 4 9 5 9 kg m2 1 1 2 lb sq ft 47 Many other engineered woods have densities much higher than OSB Adhesives editThe types of adhesives used in engineered wood include Urea formaldehyde resins UF most common cheapest and not waterproof Phenol formaldehyde resins PF yellow brown and commonly used for exterior exposure products Melamine formaldehyde resins MF white heat and water resistant and often used in exposed surfaces in more costly designs Polymeric methylene diphenyl diisocyanate pMDI or polyurethane PU resins expensive generally waterproof and does not contain formaldehyde notoriously more difficult to release from platens and engineered wood presses A more inclusive term is structural composites For example fiber cement siding is made of cement and wood fiber while cement board is a low density cement panel often with added resin faced with fiberglass mesh Health concerns edit While formaldehyde is an essential ingredient of cellular metabolism in mammals studies have linked prolonged inhalation of formaldehyde gases to cancer Engineered wood composites have been found to emit potentially harmful amounts of formaldehyde gas in two ways unreacted free formaldehyde and the chemical decomposition of resin adhesives When excessive amounts of formaldehyde are added to a process the surplus will not have any additive to bond with and may seep from the wood product over time Cheap urea formaldehyde UF adhesives are largely responsible for degraded resin emissions Moisture degrades the weak UF molecules resulting in potentially harmful formaldehyde emissions McLube offers release agents and platen sealers designed for those manufacturers who use reduced formaldehyde UF and melamine formaldehyde adhesives Many OSB and plywood manufacturers use phenol formaldehyde PF because phenol is a much more effective additive Phenol forms a water resistant bond with formaldehyde that will not degrade in moist environments PF resins have not been found to pose significant health risks due to formaldehyde emissions While PF is an excellent adhesive the engineered wood industry has started to shift toward polyurethane binders like pMDI to achieve even greater water resistance strength and process efficiency pMDIs are also used extensively in the production of rigid polyurethane foams and insulators for refrigeration pMDIs outperform other resin adhesives but they are notoriously difficult to release and cause buildup on tooling surfaces 48 Mechanical fasteners edit Some engineered wood products such as DLT NLT and some brands of CLT can be assembled without the use of adhesives using mechanical fasteners or joinery These can range from profiled interlocking jointed boards 49 50 proprietary metal fixings nails or timber dowels 51 Building codes and standards editThroughout the years mass timber was used in buildings codes were added to and adopted by the International Building Code IBC to create standards for them for the proper use and handling For example in 2015 CLT was incorporated into the IBC 33 The 2021 IBC is the latest issue of building codes and has added three new codes regarding construction with timber material The new three construction types go as follows IV A IV B and IV C and they allow mass timber to be used in buildings up to 18 12 and nine stories respectively 52 The following standards are related to engineered wood products EN 300 Oriented Strand Boards OSB Definitions classification and specifications EN 309 Particleboards Definition and classification EN 338 Structural timber Strength classes EN 386 Glued laminated timber performance requirements and minimum production requirements EN 313 1 Plywood Classification and terminology Part 1 Classification EN 313 2 Plywood Classification and terminology Part 2 Terminology EN 314 1 Plywood Bonding quality Part 1 Test methods EN 314 2 Plywood Bonding quality Part 2 Requirements EN 315 Plywood Tolerances for dimensions EN 387 Glued laminated timber large finger joints performance requirements and minimum production requirements EN 390 Glued laminated timber sizes permissible deviations EN 391 Glued laminated timber shear test of glue lines EN 392 Glued laminated timber Shear test of glue lines EN 408 Timber structures Structural timber and glued laminated timber Determination of some physical and mechanical properties EN 622 1 Fibreboards Specifications Part 1 General requirements EN 622 2 Fibreboards Specifications Part 2 Requirements for hardboards EN 622 3 Fibreboards Specifications Part 3 Requirements for medium boards EN 622 4 Fibreboards Specifications Part 4 Requirements for soft boards EN 622 5 Fibreboards Specifications Part 5 Requirements for dry process boards MDF EN 1193 Timber structures Structural timber and glued laminated timber Determination of shear strength and mechanical properties perpendicular to the grain EN 1194 Timber structures Glued laminated timber Strength classes and determination of characteristic values EN 1995 1 1 Eurocode 5 Design of timber structures Part 1 1 General Common rules and rules for buildings EN 12369 1 Wood based panels Characteristic values for structural design Part 1 OSB particleboards and fibreboards EN 12369 2 Wood based panels Characteristic values for structural design Part 2 Plywood EN 12369 3 Wood based panels Characteristic values for structural design Part 3 Solid wood panels EN 14080 Timber structures Glued laminated timber Requirements EN 14081 1 Timber structures Strength graded structural timber with rectangular cross section Part 1 General requirements ISO 21930 2017 Sustainability in buildings and civil engineering works Core rules for environmental product declarations of construction products and servicesExamples of mass timber structures editPlyscrapers edit Plyscrapers are skyscrapers that are either partially made of wood or entirely made of wood Around the world there have been many different plyscrapers built including Ascent MKE building and the Stadthaus building 53 The Ascent MKE building was built in 2022 in Milwaukee Wisconsin and is the tallest high rise building using different mass timber components in combination with some steel and concrete This plyscraper is 87 meters tall and has 25 stories 54 The Stadthaus building is a residential building built in 2009 in Hackney London It has 9 stories reaching 30 meters tall It uses CLT panels as load bearing walls and floor slabs 55 Bridges edit The Mistissini Bridge built in Quebec Canada in 2014 is a 160 meter long bridge that features both glulam beams and CLT panels The bridge was designed to cross over the Uupaachikus Pass 56 The Placer River Pedestrian Bridge built in Alaska United States in 2013 It spans 85 metres 280 ft long and is located in the Chugach National Forest This bridge features glulam as it was used create the trusses 56 Parking structures edit The Glenwood CLT Parking Garage in Springfield Oregon is going to be a 19 100 square metre 206 000 sq ft garage that features CLT It will be 4 stories tall and hold 360 parking spaces The parking garage however is under construction as of December 2022 update and the year of completion is not yet known 57 Notes edit Carbon dioxide equivalent CO2e is a way of measuring the global warming potential of multiple greenhouse gases using a common unit 1 kg of methane emissions for instance has the same global warming potential as 25 kg of CO2 emissions so 1 kg of methane emissions can be reported as 25 kg CO2e 36 References edit Brettsperrholz dataholz com Archived from the original on September 6 2017 a b Green Michael 2011 The Case for Tall Wood Buildings ISBN 1366377419 a b A Guide To Engineered Wood Products Form C800 Apawood org Retrieved on February 10 2012 Naturally wood Engineered wood Archived May 22 2016 at the Portuguese Web Archive Naturallywood com Retrieved on February 15 2012 Mass Timber in North America PDF American Wood Council November 8 2018 Retrieved February 7 2020 Allen Edward 2019 Fundamentals of building construction materials and methods Joseph Iano Seventh ed Hoboken New Jersey ISBN 978 1 119 45024 5 OCLC 1081381140 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link Milestones in the History of Plywood Archived July 17 2011 at the Wayback Machine APA The Engineered Wood Association Accessed October 22 2007 APA A glossary of Engineered Wood Terms Archived November 26 2010 at the Wayback 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Wayback Machine Apawood org Retrieved on February 10 2012 Lehman Eben October 15 2018 October 15 1934 Glued Laminated Timber Comes to America Forest History Society Retrieved November 12 2022 Kaufmann Hermann Krotsch Stefan Winter Stefan October 24 2022 Manual of Multistorey Timber Construction DETAIL doi 10 11129 9783955535827 ISBN 978 3 95553 582 7 Breneman Scott Timmers Matt Richardson Dennis August 22 2019 Tall Wood Buildings and the 2021 IBC Up to 18 Stories of Mass Timber PDF Woodworks Retrieved November 19 2022 IBC 2021 International Building Code International Code Council Country Club Hills 2020 ISBN 978 1 60983 955 0 OCLC 1226111757 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link CS1 maint others link a b FPInnovations Cross Laminated Timber A Primer PDF Retrieved on February 10 2012 a b c d e f g h i j k l m n o p q r s t Abed Joseph amp Rayburg Scott amp Rodwell John amp Neave Melissa 2022 A Review of the Performance and Benefits of Mass Timber as an Alternative to Concrete and Steel for Improving the Sustainability of Structures Sustainability 14 5570 10 3390 su14095570 Nail Laminated Timber Construction NLT Lumber Think Wood Retrieved November 13 2022 Erickson E C O 1965 Mechanical properties of laminated modified wood ScholarsArchive OSU Forest Products Laboratory Ashby M F Medalist R F Mehl September 1 1983 The mechanical properties of cellular solids Metallurgical Transactions A 14 9 1755 1769 Bibcode 1983MTA 14 1755A doi 10 1007 BF02645546 ISSN 0360 2133 S2CID 135765088 Song Jianwei Chen Chaoji Zhu Shuze Zhu Mingwei Dai Jiaqi Ray Upamanyu Li Yiju Kuang Yudi Li Yongfeng February 2018 Processing bulk natural wood into a high performance structural material Nature 554 7691 224 228 Bibcode 2018Natur 554 224S doi 10 1038 nature25476 ISSN 1476 4687 PMID 29420466 S2CID 4469909 Ramage Michael H Burridge Henry Busse Wicher Marta Fereday George Reynolds Thomas Shah Darshil U Wu Guanglu Yu Li Fleming Patrick Densley Tingley Danielle Allwood Julian Dupree Paul Linden P F Scherman Oren February 1 2017 The wood from the trees The use of timber in construction Renewable and Sustainable Energy Reviews 68 333 359 doi 10 1016 j rser 2016 09 107 hdl 10044 1 42921 ISSN 1364 0321 a b c d Chen Chaoji Kuang Yudi Zhu Shuze Burgert Ingo Keplinger Tobias Gong Amy Li Teng Berglund Lars Eichhorn Stephen J Hu Liangbing September 2020 Structure property function relationships of natural and engineered wood Nature Reviews Materials 5 9 642 666 Bibcode 2020NatRM 5 642C doi 10 1038 s41578 020 0195 z ISSN 2058 8437 S2CID 218484374 a b c Mao Yimin Hu Liangbing Ren Zhiyong Jason May 4 2022 Engineered wood for a sustainable future Matter 5 5 1326 1329 doi 10 1016 j matt 2022 04 013 ISSN 2590 2385 S2CID 248350196 What is Radiation Cooling www hko gov hk Retrieved December 1 2022 a b Kumar Anuj Jyske Tuula Petric Marko May 2021 Delignified Wood from Understanding the Hierarchically Aligned 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in sustainable building is uh wood Vox Archived from the original on August 14 2022 Churkina Galina Organschi Alan Reyer Christopher P O Ruff Andrew Vinke Kira Liu Zhu Reck Barbara K Graedel T E Schellnhuber Hans Joachim April 2020 Buildings as a global carbon sink Nature Sustainability 3 4 269 276 doi 10 1038 s41893 019 0462 4 ISSN 2398 9629 S2CID 213032074 Davis Steven J 2018 Net zero emissions energy systems Science 360 6396 doi 10 1126 science aas9793 PMID 29954954 S2CID 206666797 Brander Matthew August 2012 Greenhouse Gases CO 2 CO 2 e and Carbon What Do All These Terms Mean PDF Econometrica Archived PDF from the original on June 28 2022 D Amico Bernardino Pomponi Francesco Hart Jim 2021 Global potential for material substitution in building construction The case of cross laminated timber Journal of Cleaner Production 279 123487 doi 10 1016 j jclepro 2020 123487 S2CID 224927490 Zabalza Bribian Ignacio Valero Capilla Antonio Aranda Uson Alfonso 2011 sec2 Life cycle assessment of building materials Comparative analysis of energy and environmental impacts and evaluation of the eco efficiency improvement potential Building and Environment 46 5 1133 1140 doi 10 1016 j buildenv 2010 12 002 Retrieved November 18 2021 a href Template Cite journal html title Template Cite journal cite journal a Check url value help Breton Charles Blanchet Pierre Amor Ben Beauregard Robert Chang Wen Shao June 14 2018 Assessing the Climate Change Impacts of Biogenic Carbon in Buildings A Critical Review of Two Main Dynamic Approaches Sustainability 10 6 2020 doi 10 3390 su10062020 hdl 20 500 11794 30525 ISSN 2071 1050 The Advantages of Engineered Hardwood Flooring Really Cheap Floors June 9 2018 Retrieved May 10 2019 a b c d e Ayanleye Samuel Udele Kenneth Nasir Vahid Zhang Xuefeng Militz Holger April 2022 Durability and protection of mass timber structures A review Journal of Building Engineering 46 103731 doi 10 1016 j jobe 2021 103731 ISSN 2352 7102 S2CID 244563808 a b Wood University Wood University Retrieved on February 10 2012 Naturally wood engineered wood Archived May 22 2016 at the Portuguese Web Archive Naturallywood com Retrieved on February 10 2012 APA Engineered Wood and the Environment Facts and Figures Archived January 27 2011 at the Wayback Machine Apawood org Retrieved on February 10 2012 Naturally wood Engineered wood Naturallywood com Retrieved on February 10 2012 a b Johnson Chad February 22 2017 Wood Composite The Alternative Sustainable Solution to Timber Build Abroad Retrieved September 30 2020 Weights of building materials pounds per square foot PSF permanent dead link Boise Cascade Engineered wood products 2009 Formaldehyde in pressed wood products www nicnas gov au Retrieved March 12 2018 Interlocking Cross Laminated Timber Could Use Up Square Miles Of Beetle Killed Lumber and Look Gorgeous Too treehugger com Wohnen und Leben mit der Natur soligno com Archived from the original on December 17 2013 Retrieved December 17 2013 Sotayo Adeayo Bradley Daniel Bather Michael Sareh Pooya Oudjene Marc El Houjeyri Imane Harte Annette M Mehra Sameer O Ceallaigh Conan Haller Peer Namari Siavash Makradi Ahmed Belouettar Salim Bouhala Lyazid Deneufbourg Francois February 1 2020 Review of state of the art of dowel laminated timber members and densified wood materials as sustainable engineered wood products for construction and building applications Developments in the Built Environment 1 100004 doi 10 1016 j dibe 2019 100004 hdl 10379 15861 ISSN 2666 1659 S2CID 212960329 Status of Building Code Allowances for Tall Mass Timber in the IBC WoodWorks Wood Products Council Retrieved December 13 2022 Gorvett Zaria Plyscrapers The rise of the wooden skyscraper www bbc com Retrieved December 13 2022 World s tallest timber building opens US Forest Service July 29 2022 Retrieved December 13 2022 Stadthaus Waugh Thistleton Architects Archello Retrieved December 13 2022 a b Bridges APA The Engineered Wood Association www apawood org Retrieved December 13 2022 Glenwood CLT Parking Garage Study SRG Partnership www srgpartnership com Retrieved December 13 2022 External links edit nbsp Wikimedia Commons has media related to Engineered wood APA The Engineered Wood Association Canadian Wood Council Engineered Wood Products Engineered Wood Products Association Retrieved from https en wikipedia org w index php title Engineered wood amp oldid 1198030495, wikipedia, wiki, book, books, library,

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