Building material
Building material is material used for construction. Many naturally occurring substances, such as clay, rocks, sand, wood, and even twigs and leaves, have been used to construct buildings and other structures, like bridges. Apart from naturally occurring materials, many man-made products are in use, some more and some less synthetic. The manufacturing of building materials is an established industry in many countries and the use of these materials is typically segmented into specific specialty trades, such as carpentry, insulation, plumbing, and roofing work. They provide the make-up of habitats and structures including homes.[1]
The total cost of building materials
In history, there are trends in building materials from being natural to becoming more human-made and composite; biodegradable to imperishable; indigenous (local) to being transported globally; repairable to disposable; chosen for increased levels of fire-safety, and improved seismic resistance. These trends tend to increase the initial and long-term economic, ecological, energy, and social costs of building materials.
Economic costs
The initial economic cost of building materials is the purchase price. This is often what governs decision making about what materials to use. Sometimes people take into consideration the energy savings or durability of the materials and see the value of paying a higher initial cost in return for a lower lifetime cost. For example, an asphalt shingle roof costs less than a metal roof to install, but the metal roof will last longer so the lifetime cost is less per year. Some materials may require more care than others, maintaining costs specific to some materials may also influence the final decision. Risks when considering lifetime cost of a material is if the building is damaged such as by fire or wind, or if the material is not as durable as advertised. The cost of materials should be taken into consideration to bear the risk to buy combustive materials to enlarge the lifetime. It is said that, "if it must be done, it must be done well".
Ecological costs
Pollution costs can be macro and micro. The macro, environmental pollution of extraction industries building materials rely on such as mining, petroleum, and logging produce environmental damage at their source and in transportation of the raw materials, manufacturing, transportation of the products, retailing, and installation. An example of the micro aspect of pollution is the off-gassing of the building materials in the building or indoor air pollution. Red List building materials are materials found to be harmful. Also the carbon footprint, the total set of greenhouse gas emissions produced in the life of the material. A life-cycle analysis also includes the reuse, recycling, or disposal of construction waste. Two concepts in building which account for the ecological economics of building materials are green building and sustainable development.
Energy costs
The initial energy costs include the amount of energy consumed to produce, deliver and install the material. The long term energy cost is the economic, ecological, and social costs of continuing to produce and deliver energy to the building for its use, maintenance, and eventual removal. The initial embodied energy of a structure is the energy consumed to extract, manufacture, deliver, install, the materials. The lifetime embodied energy continues to grow with the use, maintenance, and reuse/recycling/disposal of the building materials themselves and how the materials and design help minimize the life-time energy consumption of the structure.
Social costs
Social costs are injury and health of the people producing and transporting the materials and potential health problems of the building occupants if there are problems with the building biology. Globalization has had significant impacts on people both in terms of jobs, skills, and self-sufficiency are lost when manufacturing facilities are closed and the cultural aspects of where new facilities are opened. Aspects of fair trade and labor rights are social costs of global building material manufacturing.
Naturally occurring substances
Bio-based materials (especially plant-based materials) are used in a variety of building applications, including load-bearing, filling, insulating, and plastering materials.[2] These materials vary in structure depending on the formulation used.[2][3] Plant fibres can be combined with binders and then used in construction to provide thermal, hydric or structural functions. The behaviour of concrete based on plant fibre is mainly governed by the amount of the fibre constituting the material. Several studies have shown that increasing the amount of these plant particles increases porosity, moisture buffering capacity, and maximum absorbed water content on the one side, while decreasing density, thermal conductivity, and compressive strength on the other.
Plant-based materials are largely derived from renewable resources and mainly use co-products from agriculture or the wood industry. When used as insulation materials, most bio-based materials exhibit (unlike most other insulation materials) hygroscopic behaviour, combining high water vapour permeability and moisture regulation.[4]
Brush
Brush structures are built entirely from plant parts and were used in various cultures such as Native Americans and[5] pygmy peoples in Africa.[6] These are built mostly with branches, twigs and leaves, and bark, similar to a beaver's lodge. These were variously named wikiups, lean-tos, and so forth.
An extension on the brush building idea is the wattle and daub process in which clay soils or dung, usually cow, are used to fill in and cover a woven brush structure. This gives the structure more thermal mass and strength. Wattle and daub is one of the oldest building techniques.[7] Many older timber frame buildings incorporate wattle and daub as non load bearing walls between the timber frames.
Ice and snow
Snow and occasionally ice,[8] were used by the Inuit peoples for igloos and snow is used to build a shelter called a quinzhee. Ice has also been used for ice hotels as a tourist attraction in northern climates.[9]
Mud and clay
Clay based buildings usually come in two distinct types. One being when the walls are made directly with the mud mixture, and the other being walls built by stacking air-dried building blocks called mud bricks.
Other uses of clay in building is combined with straws to create light clay, wattle and daub, and mud plaster.
Wet-laid clay walls
Wet-laid, or damp, walls are made by using the mud or clay mixture directly without forming blocks and drying them first. The amount of and type of each material in the mixture used leads to different styles of buildings. The deciding factor is usually connected with the quality of the soil being used. Larger amounts of clay are usually employed in building with cob, while low-clay soil is usually associated with sod house or sod roof construction. The other main ingredients include more or less sand/gravel and straw/grasses. Rammed earth is both an old and newer take on creating walls, once made by compacting clay soils between planks by hand; nowadays forms and mechanical pneumatic compressors are used.[10]
Soil, and especially clay, provides good thermal mass; it is very good at keeping temperatures at a constant level. Homes built with earth tend to be naturally cool in the summer heat and warm in cold weather. Clay holds heat or cold, releasing it over a period of time like stone. Earthen walls change temperature slowly, so artificially raising or lowering the temperature can use more resources than in say a wood built house, but the heat/coolness stays longer.[10]
People building with mostly dirt and clay, such as cob, sod, and adobe, created homes that have been built for centuries in western and northern Europe, Asia, as well as the rest of the world, and continue to be built, though on a smaller scale. Some of these buildings have remained habitable for hundreds of years.[11][12]
Structural clay blocks and bricks
Mud-bricks, also known by their Spanish name adobe are ancient building materials with evidence dating back thousands of years BC. Compressed earth blocks are a more modern type of brick used for building more frequently in industrialized society since the building blocks can be manufactured off site in a centralized location at a brickworks and transported to multiple building locations. These blocks can also be monetized more easily and sold.
Structural mud bricks are almost always made using clay, often clay soil and a binder are the only ingredients used, but other ingredients can include sand, lime, concrete, stone and other binders. The formed or compressed block is then air dried and can be laid dry or with a mortar or clay slip.
Sand
Sand is used with cement, and sometimes lime, to make mortar for masonry work and plaster. Sand is also used as a part of the concrete mix. An important low-cost building material in countries with high sand content soils is the Sandcrete block, which is weaker but cheaper than fired clay bricks.[13] Sand reinforced polyester composite are used as bricks.
Stone or rock
Rock structures have existed for as long as history can recall. It is the longest-lasting building material available, and is usually readily available. There are many types of rock, with differing attributes that make them better or worse for particular uses. Rock is a very dense material so it gives a lot of protection; its main drawback as a building material is its weight and the difficulty of working it. Its energy density is both an advantage and disadvantage. Stone is hard to warm without consuming considerable energy but, once warm, its thermal mass means that can retain heat for useful periods of time.[14]
Dry-stone walls and huts have been built for as long as humans have put one stone on top of another. Eventually, different forms of mortar were used to hold the stones together, cement being the most commonplace now.
The granite-strewn uplands of Dartmoor National Park, United Kingdom, for example, provided ample resources for early settlers. Circular huts were constructed from loose granite rocks throughout the Neolithic and early Bronze Age, and the remains of an estimated 5,000 can still be seen today. Granite continued to be used throughout the Medieval period (see Dartmoor longhouse) and into modern times. Slate is another stone type, commonly used as roofing material in the United Kingdom and other parts of the world where it is found.
Stone buildings can be seen in most major cities, and some civilizations built predominantly with stone, such as the Egyptian and Aztec pyramids and the structures of the Inca civilization.
Thatch
Thatch is one of the oldest of building materials known. "Thatch" is another word for "grass"; grass is a good insulator and easily harvested. Many African tribes have lived in homes made completely of grasses and sand year-round. In Europe, thatch roofs on homes were once prevalent but the material fell out of favor as industrialization and improved transport increased the availability of other materials. Today, though, the practice is undergoing a revival. In the Netherlands, for instance, many new buildings have thatched roofs with special ridge tiles on top.
Wood and timber
Wood has been used as a building material for thousands of years in its natural state. Today, engineered wood is becoming very common in industrialized countries.
Wood is a product of trees, and sometimes other fibrous plants, used for construction purposes when cut or pressed into lumber and timber, such as boards, planks and similar materials. It is a generic building material and is used in building just about any type of structure in most climates. Wood can be very flexible under loads, keeping strength while bending, and is incredibly strong when compressed vertically. There are many differing qualities to the different types of wood, even among same tree species. This means specific species are better suited for various uses than others. And growing conditions are important for deciding quality.
"Timber" is the term used for construction purposes except the term "lumber" is used in the United States. Raw wood (a log, trunk, bole) becomes timber when the wood has been "converted" (sawn, hewn, split) in the forms of minimally-processed logs stacked on top of each other, timber frame construction, and light-frame construction. The main problems with timber structures are fire risk and moisture-related problems.[citation needed]
In modern times softwood is used as a lower-value bulk material, whereas hardwood is usually used for finishings and furniture. Historically timber frame structures were built with oak in western Europe, recently douglas fir has become the most popular wood for most types of structural building.
Many families or communities, in rural areas, have a personal woodlot from which the family or community will grow and harvest trees to build with or sell. These lots are tended to like a garden. This was much more prevalent in pre-industrial times, when laws existed as to the amount of wood one could cut at any one time to ensure there would be a supply of timber for the future, but is still a viable form of agriculture.
Man-made substances
Fired bricks and clay blocks
Bricks are made in a similar way to mud-bricks except without the fibrous binder such as straw and are fired ("burned" in a brick clamp or kiln) after they have air-dried to permanently harden them. Kiln fired clay bricks are a ceramic material. Fired bricks can be solid or have hollow cavities to aid in drying and make them lighter and easier to transport. The individual bricks are placed upon each other in courses using mortar. Successive courses being used to build up walls, arches, and other architectural elements. Fired brick walls are usually substantially thinner than cob/adobe while keeping the same vertical strength. They require more energy to create but are easier to transport and store, and are lighter than stone blocks. Romans extensively used fired brick of a shape and type now called Roman bricks.[15] Building with brick gained much popularity in the mid-18th century and 19th centuries. This was due to lower costs with increases in brick[16] manufacturing and fire-safety in increasingly crowded cities.
The cinder block supplemented or replaced fired bricks in the late 20th century often being used for the inner parts of masonry walls and by themselves.
Structural clay tiles (clay blocks) are clay or terracotta and typically are perforated with holes.
Cement composites
Cement bonded composites are made of hydrated cement paste that binds wood, particles, or fibers to make pre-cast building components. Various fiberous materials, including paper, fiberglass, and carbon-fiber have been used as binders.
Wood and natural fibers are composed of various soluble organic compounds like carbohydrates, glycosides and phenolics. These compounds are known to retard cement setting. Therefore, before using a wood in making cement bonded composites, its compatibility with cement is assessed.
Wood-cement compatibility is the ratio of a parameter related to the property of a wood-cement composite to that of a neat cement paste. The compatibility is often expressed as a percentage value. To determine wood-cement compatibility, methods based on different properties are used, such as, hydration characteristics, strength, interfacial bond and morphology. Various methods are used by researchers such as the measurement of hydration characteristics of a cement-aggregate mix;[17][18][19] the comparison of the mechanical properties of cement-aggregate mixes[20][21] and the visual assessment of microstructural properties of the wood-cement mixes.[22] It has been found that the hydration test by measuring the change in hydration temperature with time is the most convenient method. Recently, Karade et al.[23] have reviewed these methods of compatibility assessment and suggested a method based on the ‘maturity concept’ i.e. taking in consideration both time and temperature of cement hydration reaction. Recent work on aging of lignocellulosic materials in the cement paste showed hydrolysis of hemicelluloses and lignin[24] that affects the interface between particles or fibers and concrete and causes degradation.[25]
Bricks were laid in lime mortar from the time of the Romans until supplanted by Portland cement mortar in the early 20th century. Cement blocks also sometimes are filled with grout or covered with a parge coat.
Concrete
Concrete is a composite building material made from the combination of aggregate and a binder such as cement. The most common form of concrete is Portland cement concrete, which consists of mineral aggregate (generally gravel and sand), portland cement and water.
After mixing, the cement hydrates and eventually hardens into a stone-like material. When used in the generic sense, this is the material referred to by the term "concrete".
For a concrete construction of any size, as concrete has a rather low tensile strength, it is generally strengthened using steel rods or bars (known as rebars). This strengthened concrete is then referred to as reinforced concrete. In order to minimise any air bubbles, that would weaken the structure, a vibrator is used to eliminate any air that has been entrained when the liquid concrete mix is poured around the ironwork. Concrete has been the predominant building material in the modern age due to its longevity, formability, and ease of transport. Recent advancements, such as insulating concrete forms, combine the concrete forming and other construction steps (installation of insulation). All materials must be taken in required proportions as described in standards.
Fabric
The tent is the home of choice among nomadic groups all over the world. Two well-known types include the conical teepee and the circular yurt. The tent has been revived as a major construction technique with the development of tensile architecture and synthetic fabrics. Modern buildings can be made of flexible material such as fabric membranes, and supported by a system of steel cables, rigid or internal, or by air pressure.
Foam
Recently, synthetic polystyrene or polyurethane foam has been used in combination with structural materials, such as concrete. It is lightweight, easily shaped, and an excellent insulator. Foam is usually used as part of a structural insulated panel, wherein the foam is sandwiched between wood or cement or insulating concrete forms.
Glass
Glassmaking is considered an art form as well as an industrial process or material.
Clear windows have been used since the invention of glass to cover small openings in a building. Glass panes provided humans with the ability to both let light into rooms while at the same time keeping inclement weather outside.
Glass is generally made from mixtures of sand and silicates, in a very hot fire stove called a kiln, and is very brittle. Additives are often included the mixture used to produce glass with shades of colors or various characteristics (such as bulletproof glass or lightbulbs).
The use of glass in architectural buildings has become very popular in the modern culture. Glass "curtain walls" can be used to cover the entire facade of a building, or it can be used to span over a wide roof structure in a "space frame". These uses though require some sort of frame to hold sections of glass together, as glass by itself is too brittle and would require an overly large kiln to be used to span such large areas by itself.
Glass bricks were invented in the early 20th century.
Gypsum concrete
Gypsum concrete is a mixture of gypsum plaster and fibreglass rovings. Although plaster and fibres fibrous plaster have been used for many years, especially for ceilings, it was not until the early 1990s that serious studies of the strength and qualities of a walling system Rapidwall, using a mixture of gypsum plaster and 300mm plus fibreglass rovings, were investigated. With an abundance of gypsum (naturally occurring and by-product chemical FGD and phospho gypsums) available worldwide, Gypsum concrete-based building products, which are fully recyclable, offer significant environmental benefits.
Metal
Metal is used as structural framework for larger buildings such as skyscrapers, or as an external surface covering. There are many types of metals used for building. Metal figures quite prominently in prefabricated structures such as the Quonset hut, and can be seen used in most cosmopolitan cities. It requires a great deal of human labor to produce metal, especially in the large amounts needed for the building industries. Corrosion is metal's prime enemy when it comes to longevity.
- Steel is a metal alloy whose major component is iron, and is the usual choice for metal structural building materials. It is strong, flexible, and if refined well and/or treated lasts a long time.
- The lower density and better corrosion resistance of aluminium alloys and tin sometimes overcome their greater cost.
- Copper is a valued building material because of its advantageous properties (see: Copper in architecture). These include corrosion resistance, durability, low thermal movement, light weight, radio frequency shielding, lightning protection, sustainability, recyclability, and a wide range of finishes. Copper is incorporated into roofing, flashing, gutters, downspouts, domes, spires, vaults, wall cladding, building expansion joints, and indoor design elements.
- Other metals used include chrome, gold, silver, and titanium. Titanium can be used for structural purposes, but it is much more expensive than steel. Chrome, gold, and silver are used as decoration, because these materials are expensive and lack structural qualities such as tensile strength or hardness.
Plastics
The term plastics covers a range of synthetic or semi-synthetic organic condensation or polymerization products that can be molded or extruded into objects, films, or fibers. Their name is derived from the fact that in their semi-liquid state they are malleable, or have the property of plasticity. Plastics vary immensely in heat tolerance, hardness, and resiliency. Combined with this adaptability, the general uniformity of composition and lightness of plastics ensures their use in almost all industrial applications today. High performance plastics such as ETFE have become an ideal building material due to its high abrasion resistance and chemical inertness. Notable buildings that feature it include: the Beijing National Aquatics Center and the Eden Project biomes.[26]
Around twenty percent of all plastics and seventy percent of all polyvinyl chloride (PVC) produced in the world each year are used by the construction industry.[27][28] It is predicted that much more will be produced and used in the future.[27] "In Europe, approximately 20% of all plastics produced are used in the construction sector including different classes of plastics, waste and nanomaterials."[28]
Common types:[28]
- Polyvinyl chloride (PVC)[28]
- Polyethylene (PE)[28]
- Polypropylene (PP)[28]
- Expandable polystyrene (EPS)[28]
- Polyurethane (PU)[28]
Indirect use (packaging of construction materials) examples:[28]
Direct use (construction materials containing plastics) examples:[28]
- Building products[28]
- Building service installations[28]
- Surface treatments[28]
- Covers[28]
- Shrink wrap[28]
- Tarpaulins[28]
Papers and membranes
Building papers and membranes are used for many reasons in construction. One of the oldest building papers is red rosin paper which was known to be in use before 1850 and was used as an underlayment in exterior walls, roofs, and floors and for protecting a jobsite during construction. Tar paper was invented late in the 19th century and was used for similar purposes as rosin paper and for gravel roofs. Tar paper has largely fallen out of use supplanted by asphalt felt paper. Felt paper has been supplanted in some uses by synthetic underlayments, particularly in roofing by synthetic underlayments and siding by housewraps.
There are a wide variety of damp proofing and waterproofing membranes used for roofing, basement waterproofing, and geomembranes.
Ceramics
Fired clay bricks have been used since the time of the Romans. Special tiles are used for roofing, siding, flooring, ceilings, pipes, flue liners, and more.[citation needed]
Living building materials
A relatively new category of building materials, living building materials are materials that are either composed of, or created by a living organism; or materials that behave in a manner that's reminiscent of such. Potential use cases include self-healing materials, and materials that replicate (reproduce) rather than be manufactured.
Building products
In the market place, the term "building products" often refers to ready-made particles or sections made from various materials, that are fitted in architectural hardware and decorative hardware parts of a building. The list of building products excludes the building materials used to construct the building architecture and supporting fixtures, like windows, doors, cabinets, millwork components, etc. Building products, rather, support and make building materials work in a modular fashion.
"Building products" may also refer to items used to put such hardware together, such as caulking, glues, paint, and anything else bought for the purpose of constructing a building.
Research and development
To facilitate and optimize the use of new materials and up-to-date technologies, ongoing research is being undertaken to improve efficiency, productivity and competitiveness in world markets.[citation needed]
Material research and development may be commercial, academical or both, and can be conducted at any scale.
Rapid prototyping allows researchers to develop and test materials quickly, making adjustments and solving issues during the process. Rather than developing materials theoretically and then testing them, only to discover fundamental flaws, rapid prototypes allow for comparatively quick development and testing, shortening the time to market for a new materials to a matter of months, rather than years.[29]
Sustainability
In 2017, buildings and construction together consumed 36% of the final energy produced globally while being responsible for 39% of the global energy related CO2 emissions.[30] The shares from the construction industry alone were 6% and 11% respectively. Energy consumption during building material production is a dominant contributor to the construction industry's overall share, predominantly due to the use of electricity during production. Embodied energy of relevant building materials in the US are provided in the table below.[31]
Material | Embodied energy | |
Btu/lb | MJ/kg | |
bricks | 1,600 | 3.7 |
cement | 3,230 | 7.5 |
clay | 15,200 | 35.4 |
concrete | 580 | 1.3 |
copper | 25,770 | 59.9 |
flat glass | 10,620 | 24.7 |
gypsum | 10,380 | 24.1 |
hardwood plywood & veneer | 15,190 | 35.3 |
lime | 1,920 | 4.5 |
mineral wool insulation | 12,600 | 29.3 |
primary aluminum | 80,170 | 186.5 |
softwood plywood & veneer | 3,970 | 9.2 |
stone | 1,430 | 3.3 |
virgin steel | 10,390 | 24.2 |
wood lumber | 2,700 | 6.3 |
Testing and certification
- ASTM International
- UL (safety organization)
- ETL SEMKO — Building Product Testing Laboratory in the USA, part of Intertek, based in London
- EU Construction Product Regulation
See also
- Alternative natural materials
- Biocidal natural building material
- Glass in green buildings
- Green building and wood
- Greystone
- Hemp as a building material
- Hempcrete
- List of building materials
- Materiality (architecture)
- Natural building
- Phenomenology (architecture)
- Prefabrication
- Thermal emittance
- Thermal mass
References
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- ^ a b Bennai, Fares (28 June 2017). Étude des mécanismes de transferts couplés de chaleur et d'humidité dans les matériaux poreux de construction en régime insaturé (Thesis) (in French).[page needed]
- ^ Othmen, Inès; Poullain, Philippe; Leklou, Ali-Nordine (June 2014). "Etude numérique des techniques d'isolation : application à la réhabilitation du bâti ancien en tuffeau". 32èmes Rencontres Universitaires de Génie Civil.
- ^ Bourbia, S.; Kazeoui, H.; Belarbi, R. (2023). "A review on recent research on bio-based building materials and their applications". Materials for Renewable and Sustainable Energy. 12 (2): 117–139. doi:10.1007/s40243-023-00234-7.
- ^ Nabokov, Peter; Easton, Robert (1989). Native American Architecture. Oxford University Press. p. 16. ISBN 978-0-19-506665-4.
- ^ Kent, Susan (1993). Domestic Architecture and the Use of Space: An Interdisciplinary Cross-Cultural Study. Cambridge University Press. p. 131. ISBN 978-0-521-44577-1.
- ^ Shaffer, Gary D. (Spring 1993). "An Archaeomagnetic Study of a Wattle and Daub Building Collapse". Journal of Field Archaeology. 20 (1): 59–75. doi:10.2307/530354. JSTOR 530354.
- ^ Lyon, George Francis (1824). The Private Journal of Captain G.F. Lyon, of H.M.S. Hecla: During the Recent Voyage of Discovery Under Captain Parry. J. Murray. pp. 280–281. OCLC 367961511.
- ^ Hall, Michael; Saarinen, Jarkko (2010). Tourism and Change in Polar Regions: Climate, Environments and Experiences. Routledge. p. 30. ISBN 978-1-136-97199-0.
- ^ a b McHenry, Paul Graham (1984). Adobe and Rammed Earth Buildings: Design and Construction. Wiley. p. 104. ISBN 978-0-471-87677-9.
- ^ Smith, Michael G. (2002). "Cob Building, Ancient and Modern". In Kennedy, Joseph F.; Wanek, Catherine; Smith, Michael G. (eds.). The Art of Natural Building: Design, Construction, Resources. New Society Publishers. pp. 132–133. ISBN 978-0-86571-433-5.
- ^ [1] Earliest Chinese building brick appeared in Xi'an (中國最早磚類建材在西安現身)]. takungpao.com (2010-1-28)
- ^ Zoya Kpamma, Z. Mohammed Kamil, K. Adinkrah-Appiah, "Making Wall Construction Process Lean:The Interlocking Blocksystem as a Toole" [sic], International Conference on Infrastructural Development In Africa (ICIDA), KNUST, Kumasi, Ghana, March 2012. https://www.academia.edu/2647016/MAKING_WALL_CONSTRUCTION_PROCESS_LEAN_THE_INTERLOCKING_BLOCK_SYSTEM_AS_A_TOOL accessed 12/11/2013
- ^ "Thermal mass". Your Home. Australian Government. Retrieved 2020-08-17.
- ^ [2] Archived 2013-04-02 at the Wayback Machine History of bricks wienerberger.com
- ^ "Top 5 Reasons Why Bricks Are The Most Popular Building Material". primedb.co. May 11, 2017.
- ^ Sandermann, Wilhelm; Kohler, Roland (January 1964). "Über eine kurze Eignungsprüfung von Hölzern für zementgebundene Werkstoffe - Studien über mineralgebundene Holzwerkstoffe, VI. Mitteilung". Holzforschung. 18 (1–2): 53–59. doi:10.1515/hfsg.1964.18.1-2.53.
- ^ Weatherwax, R C; Tarkow, H (1964). "Effect of Wood on Setting of Portland Cement". Forest Products Journal. 14: 567–568.
- ^ Hachmi, M.; Moslemi, A. A.; Campbell, A. G. (October 1990). "A new technique to classify the compatibility of wood with cement". Wood Science and Technology. 24 (4): 345–354. doi:10.1007/BF00227055.
- ^ Lee, A. W. C; Hong, Zhongli (1986). "Compressive strength of cylindrical samples as an indicator of wood-cement compatibility". Forest Products Journal. 36 (11–12): 87–90. INIST 8084764.
- ^ Demirbaş, A; Aslan, A (August 1998). "Effects of ground hazelnut shell, wood, and tea waste on the mechanical properties of cement22Communicated by A.K. Chatterjee". Cement and Concrete Research. 28 (8): 1101–1104. doi:10.1016/S0008-8846(98)00064-7.
- ^ Ahn, W.Y.; Moslemi, A.A. "SEM examination of wood-Portland cement bonds". Wood Science. 13 (2): 77–82.
- ^ Karade, S. R.; Irle, M.; Maher, K. (30 October 2003). "Assessment of Wood-Cement Compatibility: A New Approach". Holzforschung. 57 (6): 672–680. doi:10.1515/HF.2003.101.
- ^ Li, Juan; Kasal, Bohumil (September 2022). "The immediate and short-term degradation of the wood surface in a cement environment measured by AFM". Materials and Structures. 55 (7). doi:10.1617/s11527-022-01988-8.
- ^ Li, Juan; Kasal, Bohumil (July 2023). "Degradation Mechanism of the Wood-Cell Wall Surface in a Cement Environment Measured by Atomic Force Microscopy". Journal of Materials in Civil Engineering. 35 (7). doi:10.1061/JMCEE7.MTENG-14910.
- ^ "The Advantages of ETFE Fluoropolymer Tubing". Fluorotherm. April 1, 2015.
- ^ a b Smethurst, Tom (18 May 2023). "Why we must limit use of construction plastics". RICS. Retrieved 5 Dec 2024.
- ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae af ag Hernandez, German; Low, Joanne; Nand, Ashveen; Bu, Alex; Wallis, Shannon L; Kestle, Linda; Berry, Terri-Ann (13 Jun 2022). "Quantifying and managing plastic waste generated from building construction in Auckland, New Zealand". Waste Management & Research: The Journal for a Sustainable Circular Economy. 41 (1). SAGE Publications: 205–213. doi:10.1177/0734242x221105425. hdl:10652/5874. ISSN 0734-242X.
- ^ "Rapid prototyping quickly becoming the standard in construction". The Manufacturer. Retrieved 2021-09-30.
- ^ "Global Status Report 2017". www.worldgbc.org. World Green Building Council. Retrieved 2019-03-12.
- ^ Dixit, Manish K.; Culp, Charles H.; Fernandez-Solis, Jose L. (3 February 2015). "Embodied Energy of Construction Materials: Integrating Human and Capital Energy into an IO-Based Hybrid Model". Environmental Science & Technology. 49 (3): 1936–1945. Bibcode:2015EnST...49.1936D. doi:10.1021/es503896v. PMID 25561008.
Further reading
- Svoboda, Luboš(2018). Stavební hmoty (Building materials), 1000 p.
- "Download = Souhlasím". People.fsv.cvut.cz. Archived from the original on 2013-10-16. Retrieved 2018-10-03.
External links
- Materiales de Construcción – Bilingual (Spanish/English) Scientific journal published by Consejo Superior de Investigaciones Científicas, Spain.
- Informes de la Construcción – Scientific journal published by Consejo Superior de Investigaciones Científicas, Spain.