Portland cement is the most common type of cement in general use around the world as a basic ingredient of concrete, mortar, stucco, and non-specialty grout. It was developed from other types of hydraulic lime in England in the early 19th century by Joseph Aspdin, and is usually made from limestone. It is a fine powder, produced by heating limestone and clay minerals in a kiln to form clinker, and then grinding the clinker with the addition of several percent (often around 5%) gypsum. Several types of portland cement are available. The most common, historically called ordinary portland cement (OPC), is grey, but white portland cement is also available. Its name is derived from its resemblance to Portland stone which is quarried on the Isle of Portland in Dorset, England. It was named by Joseph Aspdin who obtained a patent for it in 1824. His son William Aspdin is regarded as the inventor of "modern" portland cement due to his developments in the 1840s.[1]

Refer to caption
Bags of portland cement wrapped and stacked on a pallet.
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Blue Circle Southern Cement works near Berrima, New South Wales, Australia.

The low cost and widespread availability of the limestone, shales, and other naturally occurring materials used in portland cement make it a relatively cheap building material. Its most common use is in the production of concrete, a composite material consisting of aggregate (gravel and sand), cement, and water.

History

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Plaque in Leeds commemorating Joseph Aspdin
 
William Aspdin is considered the inventor of "modern" portland cement.[1]
 
Freshly poured concrete sidewalk on West Winnemucca Boulevard approaching Melarkey Street in Winnemucca, Nevada in 2014

Portland cement was developed from natural cements made in Britain beginning in the middle of the 18th century. Its name is derived from its similarity to Portland stone, a type of building stone quarried on the Isle of Portland in Dorset, England.[2]

The development of modern portland cement (sometimes called ordinary or normal portland cement) began in 1756, when John Smeaton experimented with combinations of different limestones and additives, including trass and pozzolanas, intended for the construction of a lighthouse,[3] now known as Smeaton's Tower. In the late 18th century, Roman cement was developed and patented in 1796 by James Parker.[4] Roman cement quickly became popular, but was largely replaced by portland cement in the 1850s.[3] In 1811, James Frost produced a cement he called British cement.[4] James Frost is reported to have erected a manufactory for making of an artificial cement in 1826.[5] In 1811 Edgar Dobbs of Southwark patented a cement of the kind invented 7 years later by the French engineer Louis Vicat. Vicat's cement is an artificial hydraulic lime, and is considered the "principal forerunner"[3] of portland cement.

The name portland cement is recorded in a directory published in 1823 being associated with a William Lockwood and possibly others.[6] In his 1824 cement patent, Joseph Aspdin called his invention "portland cement" because of its resemblance to Portland stone.[2] Aspdin's cement was nothing like modern portland cement, but a first step in the development of modern portland cement, and has been called a "proto-portland cement".[3]

William Aspdin had left his father's company, to form his own cement manufactury. In the 1840s William Aspdin, apparently accidentally, produced calcium silicates which are a middle step in the development of portland cement. In 1848, William Aspdin further improved his cement. Then, in 1853, he moved to Germany, where he was involved in cement making.[6] William Aspdin made what could be called "meso-portland cement" (a mix of portland cement and hydraulic lime).[7] Isaac Charles Johnson further refined the production of "meso-portland cement" (middle stage of development), and claimed to be the real father of portland cement.[8]

In 1859, John Grant of the Metropolitan Board of Works, set out requirements for cement to be used in the London sewer project. This became a specification for portland cement. The next development in the manufacture of portland cement was the introduction of the rotary kiln, patented by Frederick Ransome in 1885 (U.K.) and 1886 (U.S.); which allowed a stronger, more homogeneous mixture and a continuous manufacturing process.[3] The Hoffmann "endless" kiln which was said to give "perfect control over combustion" was tested in 1860 and shown to produce a superior grade of cement. This cement was made at the Portland Cementfabrik Stern at Stettin, which was the first to use a Hoffmann kiln.[9] The Association of German Cement Manufacturers issued a standard on portland cement in 1878.[10]

Portland cement had been imported into the United States from Germany and England, and in the 1870s and 1880s, it was being produced by Eagle Portland cement near Kalamazoo, Michigan. In 1875, the first portland cement was produced in the Coplay Cement Company Kilns under the direction of David O. Saylor in Coplay, Pennsylvania.[11] By the early 20th century, American-made portland cement had displaced most of the imported portland cement.

Composition

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ASTM C150[12] defines portland cement as:

hydraulic cement (cement that not only hardens by reacting with water but also forms a water-resistant product) produced by pulverizing clinkers which consist essentially of hydraulic calcium silicates, usually containing one or more of the forms of calcium sulphate as an inter ground addition.[13]

The European Standard EN 197-1 uses the following definition:

Portland cement clinker is a hydraulic material which shall consist of at least two-thirds by mass of calcium silicates, (3 CaO·SiO2, and 2 CaO·SiO2), the remainder consisting of aluminium- and iron-containing clinker phases and other compounds. The ratio of CaO to SiO2 shall not be less than 2.0. The magnesium oxide content (MgO) shall not exceed 5.0% by mass.

(The last two requirements were already set out in the German Standard, issued in 1909).

Clinkers make up more than 90% of the cement, along with a limited amount of calcium sulphate (CaSO4, which controls the set time), and up to 5% minor constituents (fillers) as allowed by various standards. Clinkers are nodules (diameters, 0.2–1.0 inch [5.1–25.4 millimetres]) of a sintered material that is produced when a raw mixture of predetermined composition is heated to high temperature. The key chemical reaction distinguishing portland cement from other hydraulic limes occurs at these high temperatures (>1,300 °C (2,370 °F)) as belite (Ca2SiO4) combines with calcium oxide (CaO) to form alite (Ca3SiO5).[14]

Manufacturing

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A father and a son in Goma, Congo, in 2017.

Portland cement clinker is made by heating, in a cement kiln, a mixture of raw materials to a calcining temperature of above 600 °C (1,112 °F) and then a fusion temperature, which is about 1,450 °C (2,640 °F) for modern cements, to sinter the materials into clinker.

The materials in cement clinker are alite, belite, tricalcium aluminate, and tetracalcium alumino ferrite. The aluminium, iron, and magnesium oxides are present as a flux allowing the calcium silicates to form at a lower temperature,[15] and contribute little to the strength. For special cements, such as low heat (LH) and sulphate resistant (SR) types, it is necessary to limit the amount of tricalcium aluminate (3 CaO·Al2O3) formed.

The major raw material for the clinker-making is usually limestone (CaCO3) mixed with a second material containing clay as source of alumino-silicate. Normally, an impure limestone which contains clay or SiO2 is used. The CaCO3 content of these limestones can be as low as 80%. Secondary raw materials (materials in the raw mix other than limestone) depend on the purity of the limestone. Some of the materials used are clay, shale, sand, iron ore, bauxite, fly ash, and slag. When a cement kiln is fired by coal, the ash of the coal acts as a secondary raw material.

Cement grinding

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A 10 MW cement mill, producing cement at 270 tonnes per hour.

To achieve the desired setting qualities in the finished product, a quantity (2–8%, but typically 5%) of calcium sulphate (usually gypsum or anhydrite) is added to the clinker, and the mixture is finely ground to form the finished cement powder. This is achieved in a cement mill. The grinding process is controlled to obtain a powder with a broad particle size range, in which typically 15% by mass consists of particles below 5 μm diameter, and 5% of particles above 45 μm. The measure of fineness usually used is the 'specific surface area', which is the total particle surface area of a unit mass of cement. The rate of initial reaction (up to 24 hours) of the cement on addition of water is directly proportional to the specific surface area. Typical values are 320–380 m2·kg−1 for general purpose cements, and 450–650 m2·kg−1 for 'rapid hardening' cements. The cement is conveyed by belt or powder pump to a silo for storage. Cement plants normally have sufficient silo space for one to 20 weeks of production, depending upon local demand cycles. The cement is delivered to end users either in bags, or as bulk powder blown from a pressure vehicle into the customer's silo. In industrial countries, 80% or more of cement is delivered in bulk.

Typical constituents of portland clinker plus gypsum
showing cement chemist notation (CCN)
Clinker CCN Mass
Tricalcium silicate (CaO)3 · SiO2 C3S 25–50%
Dicalcium silicate (CaO)2 · SiO2 C2S 20–45%
Tricalcium aluminate (CaO)3 · Al2O3 C3A 5–12%
Tetracalcium aluminoferrite (CaO)4 · Al2O3 · Fe2O3 C4AF 6–12%
Gypsum CaSO4 · 2 H2O CS̅H2 2–10%
Typical constituents of portland cement
showing cement chemist notation
Cement CCN Mass
Calcium oxide, CaO C 61–67%
Silicon dioxide, SiO2 S 19–23%
Aluminium oxide, Al2O3 A 2.5–6%
Ferric oxide, Fe2O3 F 0–6%
Sulphur (VI) oxide, SO3 1.5–4.5%

Setting and hardening

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Cement sets when mixed with water by way of a complex series of chemical reactions still only partly understood.[citation needed] The different constituents slowly crystallise, and the interlocking of their crystals gives cement its strength. Carbon dioxide is slowly absorbed to convert the portlandite (Ca(OH)2) into insoluble calcium carbonate. After the initial setting, immersion in warm water will speed up setting. Gypsum is added as an inhibitor to prevent flash (or quick) setting.

 
Decorative use of portland cement panels on London's Grosvenor estate[16]

The most common use for portland cement is in the production of concrete.[17] Concrete is a composite material consisting of aggregate (gravel and sand), cement, and water. As a construction material, concrete can be cast in almost any shape desired, and once hardened, can become a structural (load bearing) element. Concrete can be used in the construction of structural elements like panels, beams, and street furniture, or may be cast-in situ for superstructures like roads and dams. These may be supplied with concrete mixed on site, or may be provided with 'ready-mixed' concrete made at permanent mixing sites. Portland cement is also used in mortars (with sand and water only), for plasters and screeds, and in grouts (cement/water mixes squeezed into gaps to consolidate foundations, road-beds, etc.).

When water is mixed with portland cement, the product sets in a few hours and hardens over a period of weeks. These processes can vary widely, depending upon the mix used and the conditions of curing of the product,[18] but a typical concrete sets in about 6 hours and develops a compressive strength of 8 MPa in 24 hours. The strength rises to 15 MPa at 3 days, 23 MPa at 1 week, 35 MPa at 4 weeks, and 41 MPa at 3 months. In principle, the strength continues to rise slowly as long as water is available for continued hydration, but concrete is usually allowed to dry out after a few weeks and this causes strength growth to stop.

Types

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General

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ASTM C150

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Five types of portland cements exist, with variations of the first three according to ASTM C150.[12][19]

Type I portland cement is known as common or general-purpose cement. It is generally assumed unless another type is specified. It is commonly used for general construction, especially when making precast, and precast-prestressed concrete that is not to be in contact with soils or ground water. The typical compound compositions of this type are:

55% (C3S), 19% (C2S), 10% (C3A), 7% (C4AF), 2.8% MgO, 2.9% (SO3), 1.0% ignition loss, and 1.0% free CaO (utilizing cement chemist notation).

A limitation on the composition is that the (C3A) shall not exceed 15%.

Type II provides moderate sulphate resistance, and gives off less heat during hydration. This type of cement costs about the same as type I. Its typical compound composition is:

51% (C3S), 24% (C2S), 6% (C3A), 11% (C4AF), 2.9% MgO, 2.5% (SO3), 0.8% ignition loss, and 1.0% free CaO.

A limitation on the composition is that the (C3A) shall not exceed 8%, which reduces its vulnerability to sulphates. This type is for general construction exposed to moderate sulphate attack, and is meant for use when concrete is in contact with soils and ground water, especially in the western United States due to the high sulphur content of the soils. Because of similar price to that of type I, type II is much used as a general purpose cement, and the majority of portland cement sold in North America meets this specification.

Note: Cement meeting (among others) the specifications for types I and II has become commonly available on the world market.

Type III has relatively high early strength. Its typical compound composition is:

57% (C3S), 19% (C2S), 10% (C3A), 7% (C4AF), 3.0% MgO, 3.1% (SO3), 0.9% ignition loss, and 1.3% free CaO.

This cement is similar to type I, but ground finer. Some manufacturers make a separate clinker with higher C3S and/or C3A content, but this is increasingly rare, and the general purpose clinker is usually used, ground to a specific surface area typically 50–80% higher. The gypsum level may also be increased a small amount. This gives the concrete using this type of cement a three-day compressive strength equal to the seven-day compressive strength of types I and II. Its seven-day compressive strength is almost equal to 28-day compressive strengths of types I and II. The only downside is that the six-month strength of type III is the same or slightly less than that of types I and II. Therefore, the long-term strength is sacrificed. It is usually used for precast concrete manufacture, where high one-day strength allows fast turnover of molds. It may also be used in emergency construction and repairs, and construction of machine bases and gate installations.

Type IV portland cement is generally known for its low heat of hydration. Its typical compound composition is:

28% (C3S), 49% (C2S), 4% (C3A), 12% (C4AF), 1.8% MgO, 1.9% (SO3), 0.9% ignition loss, and 0.8% free CaO.

The percentages of (C2S) and (C4AF) are relatively high and (C3S) and (C3A) are relatively low. A limitation on this type is that the maximum percentage of (C3A) is seven, and the maximum percentage of (C3S) is thirty-five. This causes the heat given off by the hydration reaction to develop at a slower rate. Consequently, the strength of the concrete develops slowly. After one or two years the strength is higher than the other types after full curing. This cement is used for very large concrete structures, such as dams, which have a low surface to volume ratio. This type of cement is generally not stocked by manufacturers, but some might consider a large special order. This type of cement has not been made for many years, because portland-pozzolan cements and ground granulated blast furnace slag addition offer a cheaper and more reliable alternative.

Type V is used where sulphate resistance is important. Its typical compound composition is:

38% (C3S), 43% (C2S), 4% (C3A), 9% (C4AF), 1.9% MgO, 1.8% (SO3), 0.9% ignition loss, and 0.8% free CaO.

This cement has a very low (C3A) composition which accounts for its high sulphate resistance. The maximum content of (C3A) allowed is 5% for type V portland cement. Another limitation is that the (C4AF) + 2(C3A) composition cannot exceed 20%. This type is used in concrete to be exposed to alkali soil and ground water sulphates which react with (C3A) causing disruptive expansion. It is unavailable in many places, although its use is common in the western United States and Canada. As with type IV, type V portland cement has mainly been supplanted by the use of ordinary cement with added ground granulated blast furnace slag or tertiary blended cements containing slag and fly ash.

Types Ia, IIa, and IIIa have the same composition as types I, II, and III. The only difference is that in Ia, IIa, and IIIa, an air-entraining agent is ground into the mix. The air-entrainment must meet the minimum and maximum optional specification found in the ASTM manual. These types are only available in the eastern United States and Canada, only on a limited basis. They are a poor approach[clarification needed] to air-entrainment which improves resistance to freezing under low temperatures.

Types II(MH) and II(MH)a have a similar composition as types II and IIa, but with a mild heat.

EN 197 norm

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The European norm EN 197-1 defines five classes of common cement that comprise portland cement as a main constituent. These classes differ from the ASTM classes.

Class Description Constituents
CEM I Portland cement Comprising portland cement and up to 5% of minor additional constituents
CEM II Portland-composite cement Portland cement and up to 35% of other* single constituents
CEM III Blast furnace cement Portland cement and higher percentages of blast furnace slag
CEM IV Pozzolanic cement Portland cement and up to 55% of pozzolanic constituents
CEM V Composite cement Portland cement, blast furnace slag or fly ash and pozzolana

*Constituents that are permitted in portland-composite cements are artificial pozzolans (blast furnace slag (in fact a latent hydraulic binder), silica fume, and fly ashes), or natural pozzolans (siliceous or siliceous aluminous materials such as volcanic ash glasses, calcined clays and shale).

CSA A3000-08

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The Canadian standards describe six main classes of cement, four of which can also be supplied as a blend containing ground limestone (where a suffix L is present in the class names).

Class Description
GU, GUL (a.k.a. Type 10 (GU) cement) General use cement
MS Moderate sulphate resistant cement
MH, MHL Moderate heat cement
HE, HEL High early strength cement
LH, LHL Low heat cement
HS High sulphate resistant; generally develops strength less rapidly than the other types.

White portland cement

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White portland cement or white ordinary portland cement (WOPC) is similar to ordinary gray portland cement in all respects, except for its high degree of whiteness. Obtaining this colour requires high purity raw materials (low Fe2O3 content), and some modification to the method of manufacture, among others a higher kiln temperature required to sinter the clinker in the absence of ferric oxides acting as a flux in normal clinker. As Fe2O3 contributes to decrease the melting point of the clinker (normally 1450 °C), the white cement requires a higher sintering temperature (around 1600 °C). Because of this, it is somewhat more expensive than the grey product. The main requirement is to have a low iron content which should be less than 0.5 wt.% expressed as Fe2O3 for white cement, and less than 0.9 wt.% for off-white cement. It also helps to have the iron oxide as ferrous oxide (FeO) which is obtained via slightly reducing conditions in the kiln, i.e., operating with zero excess oxygen at the kiln exit. This gives the clinker and cement a green tinge. Other metallic oxides such as Cr2O3 (green), MnO (pink), TiO2 (white), etc., in trace content, can also give colour tinges, so for a given project it is best to use cement from a single batch.

Safety issues

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Bags of cement routinely have health and safety warnings printed on them, because not only is cement highly alkaline, but the setting process is also exothermic. As a result, wet cement is strongly caustic and can easily cause severe skin burns if not promptly washed off with water. Similarly, dry cement powder in contact with mucous membranes can cause severe eye or respiratory irritation.[20][21] The reaction of cement dust with moisture in the sinuses and lungs can also cause a chemical burn, as well as headaches, fatigue,[22] and lung cancer.[23]

The production of comparatively low-alkalinity cements (pH<11) is an area of ongoing investigation.[24]

In Scandinavia, France, and the United Kingdom, the level of chromium(VI), which is considered to be toxic and a major skin irritant, may not exceed 2 parts per million (ppm).

In the US, the Occupational Safety and Health Administration (OSHA) has set the legal limit (permissible exposure limit) for portland cement exposure in the workplace as 50 mppcf (million particles per cubic foot) over an 8-hour workday. The National Institute for Occupational Safety and Health (NIOSH) has set a recommended exposure limit (REL) of 10 mg/m3 total exposure and 5 mg/m3 respiratory exposure over an 8-hour workday. At levels of 5000 mg/m3, portland cement is immediately dangerous to life and health.[25]

Environmental effects

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Portland cement manufacture can cause environmental impacts at all stages of the process. These include emissions of airborne pollution in the form of dust; gases; noise and vibration when operating machinery and during blasting in quarries; consumption of large quantities of fuel during manufacture; release of CO
2
from the raw materials during manufacture, and damage to countryside from quarrying. Equipment to reduce dust emissions during quarrying and manufacture of cement is widely used, and equipment to trap and separate exhaust gases are coming into increased use. Environmental protection also includes the re-integration of quarries into the countryside after they have been closed down by returning them to nature or re-cultivating them.

Portland cement is caustic, so it can cause chemical burns.[12] The powder can cause irritation or, with severe exposure, lung cancer, and can contain a number of hazardous components, including crystalline silica and hexavalent chromium. Environmental concerns are the high energy consumption required to mine, manufacture, and transport the cement, and the related air pollution, including the release of the greenhouse gas carbon dioxide, dioxin,[citation needed] NOx, SO2, and particulates. Production of portland cement contributes about 10% of world carbon dioxide emissions.[26] The International Energy Agency has estimated that cement production will increase by between 12 and 23% by 2050 to meet the needs of the world's growing population.[27] There are several ongoing researches targeting a suitable replacement of portland cement by supplementary cementitious materials.[28]

Epidemiologic Notes and Reports Sulfur Dioxide Exposure in Portland Cement Plants, from the Centers for Disease Control, states:

Workers at portland cement facilities, particularly those burning fuel containing sulfur, should be aware of the acute and chronic effects of exposure to SO
2
[sulfur dioxide], and peak and full-shift concentrations of SO
2
should be periodically measured.[29]

An independent research effort of AEA Technology to identify critical issues for the cement industry today concluded the most important environment, health and safety performance issues facing the cement industry are atmospheric releases (including greenhouse gas emissions, dioxin, NOx, SO
2
, and particulates), accidents, and worker exposure to dust.[30][better source needed]

The CO
2
associated with portland cement manufacture comes mainly from four sources:

CO
2
source
Amount
Decarbonation of limestone Fairly constant: minimum around 0.47 kg (1.0 lb) CO
2
per kg of cement, maximum 0.54, typical value around 0.50 worldwide.[citation needed]
Kiln fuel combustion Varies with plant efficiency: efficient precalciner plant 0.24 kg (0.53 lb) CO
2
per kg cement, low-efficiency wet process as high as 0.65, typical modern practices (e.g. UK) averaging around 0.30.[citation needed]
Produced by vehicles in cement plants and distribution Almost insignificant at 0.002–0.005. So typical total CO
2
is around 0.80 kg (1.8 lb) CO
2
per kg finished cement.
Electrical power generation Varies with local power source. Typical electrical energy consumption is on the order of 90–150 kWh per tonne cement, equivalent to 0.09–0.15 kg (0.20–0.33 lb) CO
2
per kg finished cement if the electricity is coal-generated.

Overall, with nuclear or hydroelectric power, and efficient manufacturing, CO
2
generation can be reduced to 0.7 kg (1.5 lb) per kg cement, but can be twice as high.[clarification needed] The thrust of innovation for the future is to reduce sources 1 and 2 by modification of the chemistry of cement, by the use of wastes, and by adopting more efficient processes.[citation needed] Although cement manufacturing is clearly a very large CO
2
emitter, concrete (of which cement makes up about 15%) compares quite favourably with other modern building systems in this regard.[citation needed]. Traditional materials such as lime based mortars as well as timber and earth based construction methods emit significantly less CO2.[31]

Cement plants used for waste disposal or processing

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Used tyres being fed to a pair of cement kilns

Due to the high temperatures inside cement kilns, combined with the oxidising (oxygen-rich) atmosphere and long residence times, cement kilns are used as a processing option for various types of waste streams; indeed, they efficiently destroy many hazardous organic compounds. The waste streams also often contain combustible materials which allow the substitution of part of the fossil fuel normally used in the process.

Waste materials used in cement kilns as a fuel supplement:[32]

Portland cement manufacture also has the potential to benefit from using industrial byproducts from the waste stream.[33] These include in particular:

See also

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References

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  1. ^ a b Courland, Robert (2011). Concrete planet : the strange and fascinating story of the world's most common man-made material. Amherst, N.Y.: Prometheus Books. ISBN 978-1616144814. Retrieved 28 August 2015.
  2. ^ a b Gillberg, B. Fagerlund, G. Jönsson, Å. Tillman, A-M. (1999). Betong och miljö [Concrete and environment] (in Swedish). Stockholm: AB Svensk Byggtjenst. ISBN 978-91-7332-906-4.{{cite book}}: CS1 maint: multiple names: authors list (link)
  3. ^ a b c d e Robert G. Blezard, "The History of Calcareous Cements" in Hewlett, Peter C., ed.. Leaʼs chemistry of cement and concrete. 4. ed. Amsterdam: Elsevier Butterworth-Heinemann, 2004. 1–24. Print.
  4. ^ a b Saikia, Mimi Das. Bhargab Mohan Das, Madan Mohan Das. Elements of Civil Engineering. New Delhie: PHI Learning Private Limited. 2010. 30. Print.
  5. ^ Reid, Henry (1868). A practical treatise on the manufacture of Portland cement. London: E. & F.N. Spon.
  6. ^ a b Francis, A.J. (1977). The Cement Industry 1796–1914: A History.
  7. ^ Rayment, D. L. (1986). "The electron microprobe analysis of the C-S-H phases in a 136-year-old cement paste". Cement and Concrete Research. 16 (3): 341–344. doi:10.1016/0008-8846(86)90109-2.
  8. ^ Hahn, Thomas F., and Emory Leland Kemp. Cement mills along the Potomac River. Morgantown, WV: West Virginia University Press, 1994. 16. Print.
  9. ^ Reid, Henry (1877). The Science and Art of the Manufacture of Portland Cement with observations on some of its constructive applications. London: E&F.N. Spon.
  10. ^ "125 Years of Research for Quality and Progress". German Cement Works' Association. Archived from the original on 16 January 2015. Retrieved 30 September 2012.{{cite web}}: CS1 maint: bot: original URL status unknown (link)
  11. ^ Meade, Richard Kidder. Portland cement: its composition, raw materials, manufacture, testing and analysis. Easton, PA: 1906. The Chemical Publishing Co. 4–14. Print.
  12. ^ a b c "ASTM C185-15a, Standard Test Method for Air Content of Hydraulic Cement Mortar". www.ASTM.org. West Conshohocken, PA: ASTM International. 2015. doi:10.1520/C0185-15A. Retrieved 16 May 2017.
  13. ^ "Portland Cement". dot.gov. Archived from the original on 7 June 2014.
  14. ^ Dylan Moore. "Cement Kilns: Clinker Thermochemistry". cementkilns.co.uk. Archived from the original on 6 March 2014.
  15. ^ McArthur, Hugh, and Duncan Spalding. Engineering materials science: properties, uses, degradation and remediation. Chichester, U.K.: Horwood Pub., 2004. 217. Print.
  16. ^ "Housing Prototypes: Page Street". housingprototypes.org. Archived from the original on 16 September 2012. Retrieved 19 January 2007.
  17. ^ U.S. Geological Survey, 2020, Mineral commodity summaries 200 p. doi:10.3133/mcs2020
  18. ^ "Portland Cement Strength – Pavement Interactive". Retrieved 16 August 2024.
  19. ^ The contractor's guide to quality concrete construction. 3rd ed. St. Louis, MO: American Society of Concrete Contractors ;, 2005. 17. Print.
  20. ^ "Archived copy" (PDF). Archived (PDF) from the original on 4 June 2011. Retrieved 15 February 2011.{{cite web}}: CS1 maint: archived copy as title (link)
  21. ^ Bolognia, Jean L.; Joseph L. Jorizzo; Ronald P. Rapini (2003). Dermatology, volume 1. Mosby. ISBN 978-0-323-02409-9.
  22. ^ Oleru, U. G. (1984). "Pulmonary function and symptoms of Nigerian workers exposed to cement dust". Environ. Research. 33 (2): 379–385. Bibcode:1984ER.....33..379O. doi:10.1016/0013-9351(84)90036-7. PMID 6714189.
  23. ^ Rafnsson, V; H. Gunnarsdottir; M. Kiilunen (1997). "Risk of lung cancer among masons in Iceland". Occup. Environ. Med. 54 (3): 184–188. doi:10.1136/oem.54.3.184. PMC 1128681. PMID 9155779.
  24. ^ Coumes, Céline Cau Dit; Simone Courtois; Didier Nectoux; Stéphanie Leclercq; Xavier Bourbon (December 2006). "Formulating a low-alkalinity, high-resistance and low-heat concrete for radioactive waste repositories" (PDF). Cement and Concrete Research. 36 (12). Elsevier Ltd.: 2152–2163. doi:10.1016/j.cemconres.2006.10.005. S2CID 96407505. Archived (PDF) from the original on 9 October 2022.
  25. ^ "CDC – NIOSH Pocket Guide to Chemical Hazards – portland cement". www.cdc.gov. Archived from the original on 21 November 2015. Retrieved 21 November 2015.
  26. ^ Scrivener, Karen L.; John, Vanderley M.; Gartner, Ellis M. (June 2018). "Eco-efficient cements: Potential economically viable solutions for a low-CO2 cement-based materials industry" (PDF). Cement and Concrete Research. 114: 2–26. doi:10.1016/j.cemconres.2018.03.015. hdl:10044/1/51016. S2CID 139685537. Archived (PDF) from the original on 9 October 2022.
  27. ^ "Technology Roadmap - Low-Carbon Transition in the Cement Industry: Foldout". IEA webstore.
  28. ^ Lothenbach, Barbara; Scrivener, Karen; Hooton, R.D. (December 2011). "Supplementary cementitious materials". Cement and Concrete Research. 41 (12): 1244–1256. doi:10.1016/j.cemconres.2010.12.001.
  29. ^ "Epidemiologic Notes and Reports Sulfur Dioxide Exposure in Portland Cement Plants". cdc.gov. Archived from the original on 25 June 2017.
  30. ^ "Toward a Sustainable Cement Industry: Environment, Health & Safety Performance Improvement" (PDF). wbcsd.ch. Archived from the original (PDF) on 28 September 2007. Retrieved 5 December 2006.
  31. ^ Kent, Douglas (22 October 2007). "Response: Lime is a much greener option than cement, says Douglas Kent". the Guardian. Retrieved 22 March 2022.
  32. ^ Chris Boyd (December 2001). "Recovery of Wastes in Cement Kilns" (PDF). World Business Council for Sustainable Development. Archived from the original (PDF) on 24 June 2008. Retrieved 25 September 2008.
  33. ^ S.H. Kosmatka; W.C. Panarese (1988). Design and Control of Concrete Mixtures. Skokie, Illinois: Portland Cement Association. p. 15. ISBN 978-0-89312-087-0. As a generalization, probably 50% of all industrial byproducts have potential as raw materials for the manufacture of portland cement.
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