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vermiculite

 
Dictionary: ver·mic·u·lite   (vər-mĭk'yə-līt') pronunciation
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n.
Any of a group of micaceous hydrated silicate minerals related to the chlorites and used in heat-expanded form as insulation and as a planting medium.

[Latin vermiculus, diminutive of vermis, worm; see vermicular + -ITE1.]


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How Products are Made: How is vermiculite made?
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Background

The term vermiculite applies to a group of minerals characterized by their ability to expand into long, worm-like strands when heated. This expansion process is called exfoliation. The name vermiculite is derived from a combination of the Latin word vermiculare meaning "to breed worms," and the English suffix-ite, meaning mineral or rock. In its expanded form, vermiculite has a very low density and thermal conductivity, which makes it attractive for use as a soil amendment, lightweight construction aggregate, and thermal insulation filler. Expanded vermiculite also has a very large chemically active surface area, which makes it useful as an absorbent in some chemical processes. When vermiculite is ground into a fine powder, it is used as a filler in inks, paints, plastics, and other materials.

History

Vermiculite and its unique properties were known as early as 1824, when Thomas H. Webb experimented with it in Worcester, Massachusetts. It was Webb who gave the mineral its fanciful name because he thought the long strands looked like a mass of small worms. Vermiculite was regarded as not much more than a scientific curiosity until the early 1900s when more practical uses were sought. The first commercial mining effort occurred in 1915 in Colorado. The material was sold as tung ash, but did not find sufficient buyers, and the venture failed. The first successful vermiculite mine was started by the Zonolite Company in Libby, Montana, in 1923. The mine continued to operate until 1990.

The largest vermiculite mining operation in the world is located in the Phalabowra (also sometimes spelled Palabora) district of the Republic of South Africa. Other countries producing significant amounts of vermiculite include the United States, China, Russia, Brazil, Japan, Zimbabwe, and Australia.

In 1999, there were three active vermiculite mining operations in the United States, two in South Carolina and one in Virginia, which shipped concentrated vermiculite ore to exfoliation plants located throughout the country. In addition to using concentrated vermiculite from domestic mining operations, these plants also imported about 77,000 tons (70,000 metric tons) of concentrated vermiculite from foreign sources—mostly South Africa.

Raw Materials

Technically, vermiculite encompasses a large group of hydrated laminar magnesium-aluminum-iron silicates, which resemble mica. There are two keys to the unique properties of vermiculite. The first is its laminar (or layered) crystalline structure, which provides the hinged plates that make the material expand or unfold in a linear manner, like an accordion. The second is the fact that it contains trapped water, which flashes into steam when heated to force the layers open. There are a great many naturally occurring vermiculite minerals and soils, and their identification often requires sophisticated scientific analysis.

One of the most common forms of vermiculite is generally known as commercial vermiculite. This is the form that is mined and processed for various end uses. It is derived from rocks containing large crystals of the minerals biotite and iron-bearing phlogopite. As these rocks are exposed to the weather, they start to decompose, allowing water to enter and react with the various chemicals present. As the decomposition and chemical reactions proceed, vermiculite is formed.

A typical chemical analysis of commercial vermiculite shows it contains 38-46% silicon oxide (SiO2), 16-35% magnesium oxide (MgO), 10-16% aluminum oxide (Al2O3), 8-16% water, plus lesser amounts of several other chemicals.

When commercial vermiculite flakes are heated and expanded, they undergo a color change that depends on the chemicals present and the temperature of the furnace. The resulting expanded vermiculite granules are usually a gold-brown color with a bulk density of about 4-10 lb/cu ft (64-160 kg/cu m), depending on the size of the granules.

The Manufacturing Process

The manufacturing process used to produce commercial expanded vermiculite consists of two separate operations. The mining and concentrating operations that produce raw vermiculite flakes are conducted at one location. The exfoliation and classifying operations that produce various sizes of lightweight, expanded vermiculite granules for use in other products are conducted in another location. Sometimes these two locations can be half a world apart.

There are many different methods used in both of these operations. The exact methods vary from mine to mine and plant to plant. Here is a typical manufacturing process used to produce commercial expanded vermiculite.

Mining

  • l Rocks containing vermiculite are dug from a huge open pit in the ground. The soil on top of the rocks, called the overburden, is removed with power shovels or earth scrapers. The exposed rock layers are then drilled with large pneumatic or hydraulic drills, and the holes are filled with explosive charges. When all personnel and equipment have been moved out of the area, the explosive charges are detonated.
  • The resulting heap of loose rocks are scooped up with power shovels and dumped into trucks or train cars, which carry the rocks to a nearby processing plant.

Concentrating

  • The rocks are fed through a series of crushers and screens to reduce their size. The vermiculite is separated from the surrounding rocks and dirt using various wet or dry techniques depending on the particular mining operation and local environmental regulations. These techniques may include froth flotation, gravity separations, winnowing, or electrostatic separation. In each of these techniques, either the vermiculite itself or the other materials are trapped and separated from each other until the resulting vermiculite flakes are about 90% pure by weight.
  • The vermiculite flakes extracted from various sections of the mine may be blended together before further processing to ensure uniformity of the product.

Grading

  • The separated vermiculite flakes are sorted by size. This may be done with a series of screens or it may be done in a long enclosed wind tunnel. In the wind tunnel, the flakes are fed into the upstream end of the tunnel and are carried along the length of the tunnel by the flow of air. The larger flakes, being heavier, fall out of the air stream first and are caught in a hopper at the bottom of the tunnel. This separation by weight continues down the length of the tunnel until all the flakes are caught in hoppers. By controlling the length of each hopper opening and the velocity of the air, the flakes can be sorted into various sizes, or grades, ranging from about 0.63 in (16 mm) down to about 0.02 in (0.8 mm) in diameter. If the particular vermiculite being mined tends to form a high percentage of large flakes, the flakes may be slightly crushed to delaminate them and reduce their size. This process is called debooking and allows the flakes to be quickly heated during the exfoliation process.
  • The graded vermiculite flakes are dumped into large plastic bags or other containers for shipping to various exfoliation plants. If the flakes are to be shipped to plants overseas, they are loaded in bulk into the holds of ships for transport.

Exfoliating

  • The vermiculite flakes are transported by truck or train from the port or mine to the exfoliation plant, where they are offloaded and stored in a covered area to protect them from contaminants and the weather. It is important to prevent the flakes from absorbing moisture. Otherwise, it will take too much energy to heat the flakes to the required temperature to make them expand.
  • The flakes are loaded onto a conveyor belt and lifted to the top of a 20-25 ft (6.1-7.6 m) high vertical furnace lined with ceramic bricks. As the flakes fall down the length of the furnace, they pass through one or more burners fired by natural gas. The temperature inside the furnace reaches approximately 1,000-1,500°F (540-810°C), which is sufficient to make the trapped water in the flakes flash to steam and cause the flakes to expand into worm-like particles. At the bottom of the furnace, the particles slide down an inclined plane. This delays the exit of the particles from the furnace and allows the vermiculite to be heated further in order to reach full expansion. Other exfoliation plants may use different furnace configurations, but the general sequence of operations is similar.

Classifying

  • The hot, expanded vermiculite particles are then drawn up a vertical tube by a vacuum. Any small stones or other solid contaminants are too heavy to be carried upward by the gentle flow of air and fall out the bottom of the tube. The air flow also acts to cool the hot vermiculite.
  • If a customer or application requires fine particles, the vermiculite may be ground and screened to produce a specific size or range of sizes before it is packaged for shipping. In some exfoliation plants, the larger particles may also be screened or sorted into various sizes, depending on the final use.
  • The sorted, or classified, vermiculite particles are then deposited into storage hoppers, where they are dispensed into individual 4-6 cu ft (0.10-0.15 cu m) paper or plastic bags for retail sales or placed into larger 50 cu ft (1.3 cu m) bags for use in various commercial applications. The bags are sealed, labeled, and moved to a warehouse for shipping.

Health Aspects

Vermiculite ore deposits may also contain a variety of other materials such as mica, quartz, and feldspar. These deposits vary from one mining location to another. During the manufacturing process, some of these materials may pose potential health hazards to workers. In the United States and many other countries, these hazards are defined in Material Safety Data Sheets (MSDS), which identify the hazard and provide information on the safe handling and disposal of the material.

One of the most common health hazards in processing vermiculite comes from quartz, which is crystalline silica. It is usually only present as larger particles, but when it is ground into finer particles, the dust can be inhaled and cause a lung disease called silicosis. As a result, strict dust control and personal protection measures are incorporated into those areas of the vermiculite-processing operation where the materials are ground, sifted, and bagged. At the consumer level, exposure to silica dust is negligible and does not pose a health hazard.

In some vermiculite ore deposits, there may also be certain amounts of various forms of asbestos. None of the ore bodies currently used by major vermiculite producers pose an asbestos health risk to workers when the material is processed in accordance with the applicable MSDS. In August 2000, the United States Environmental Protection Agency (EPA) issued a report regarding vermiculite sold as a soil amendment. In the report, they concluded there was little or no risk to consumers from asbestos.

The Future

Although there are several other materials that may be used as a substitute for vermiculite, vermiculite's extremely low density and thermal conductivity continue to make it attractive for many applications. In 1999, it was estimated there were approximately 55 million tons (50 million metric tons) of vermiculite reserves in the world.

Where to Learn More

Books

Hombostel, Caleb. "Vermiculite." In Construction Materials: Types, Uses, and Applications. New York: John Wiley & Sons, Inc., 1991.

Other

Grace Construction Products "Grace Specialty Vermiculite History." (2000). http://www.graceconstruction.com/vermiculite/verm_prodhist.html (January 2001).

Hindman, James R. "Vermiculite as an Industrial Mineral" (1997). http://www.mcn.net/~vermiculite/overview.htm (March 22, 2000).

Hindman, James R. "Vermiculite Products and Applications." (1997). http://www.mcn.net/~vermiculite/uses.htm (March 22, 2000).

Potter, Michael J. "Vermiculite." U.S. Geological Survey, Mineral Commodity Summaries, February 2000.http://minerals.usgs.gov/minerals/pubs/comodity/vermiculite/index.html (May 18, 2000).

The Schundler Company. "Basic Vermiculite Information and Data." http://www.schundler.com/techverm.htm (May 18, 2000).

The Vermiculite Association. "About Vermiculite." http://www.vermiculite.org (May 18, 2000).

[Article by: Chris Cavette]


Sci-Tech Encyclopedia: Vermiculite
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A group of minerals common in some soils and clays and belonging to the family of minerals called layer silicates. Species within the vermiculite group are denoted as either dioctahedral vermiculite or trioctahedral vermiculite, with two or three octahedral cation sites occupied per formula unit, respectively. Trioctahedral vermiculite is a 2:1 layer silicate with a fundamental unit similar to that of mica. An octahedral sheet forms the basis of the layer and is sandwiched between two opposing tetrahedral sheets. See also Mica.

Perfect basal cleavage develops by the layerlike structure. Density varies but is near 2.4 g/cm3; hardness on Mohs scale is near 1.5; and luster is pearly. Thin sheets deform easily and may be yellow to brown. See also Hardness scales.

Heat-treated and expanded vermiculite is used as an insulator in construction. Mixed with plaster and cement, vermiculite is used to make lightweight versions of these materials. Vermiculite is also useful as an absorbent for some environmentally hazardous liquids. See also Clay minerals; Silicate minerals.

Architecture: vermiculite
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A natural mica expanded by heat(i.e., exfoliated) to form lightweight thermal insulating

vermiculated work
material, used in the expanded state alone as loose-fill or as aggregate with other materials.
Gardener's Dictionary: vermiculite
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Home > Library > Home & Garden > Dictionary for Gardeners

A micaceous mineral, heated until it explodes into spongelike kernels that are highly porous but exceedingly lightweight. It is a component of some soilless mixes.

Geological Glossary: Vermiculite
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Home > Library > Science > Geological Glossary

A hydrated mica that swells and writhes in wormlike fashion when heated, used as a moisture retainer in potting soils and for an insulating plaster.


Wikipedia: Vermiculite
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Vermiculite
General
Category Mineral
Chemical formula (MgFe,Al)3(Al,Si)4O10(OH)2·4H2O
Identification
Color Bronze-Yellow
Crystal habit Clay, scaly, aggregate
Crystal system Monoclinic
Cleavage Perfect
Fracture Uneven
Mohs Scale hardness 1.5-2
Luster Vitreous
Streak Pale yellow
Specific gravity 2.4-2.7
Refractive index Translucent
Pleochroism None

Vermiculite is a natural mineral that expands with the application of heat. The expansion process is called exfoliation and it is routinely accomplished in purpose-designed commercial furnaces. Vermiculite is formed by hydration of certain basaltic minerals. Large commercial vermiculite mines currently exist in South Africa, China, Brazil and several other countries.

Contents

Structure

Vermiculite is a 2:1 clay, meaning it has 2 tetrahedral sheets for every one octahedral sheet. It is a limited expansion clay with a medium shrink-swell capacity. Vermiculite has a high cation exchange capacity at 100-150 meq/100g. Vermiculite clays are weathered micas in which the K+ ions between the molecular sheets are replaced by Mg2+ and Fe2+ cations.

Commercial uses

  • moulded shapes, bonded with sodium silicate for use in:
  • soil conditioner
  • as loose-fill insulation
  • packing material, valued for its high absorbency
  • suitable as a substrate for various animals and/or incubation of eggs
  • lightweight aggregate for plaster, proprietary concrete compounds, firestop mortar and cementitious spray fireproofing
  • as an additive to fireproof wallboard
  • component of the interior fill for firestop pillows, along with graphite
  • carrier for dry handling and slow release of agricultural chemicals
  • soil additive for plants, together with perlite for potted plants
  • growing medium for hydroponics.
  • means to permit slow cooling of hot pieces in glassblowing, lampwork, steelwork, and glass beadmaking
  • used in in-ground swimming pools to provide a smooth pool base
  • used in commercial handwarmers
  • used as a sterile medium for the incubation of reptile eggs
  • light-weight insulative concrete [1]
  • used in AGA cookers as insulation
  • used in explosives storage as a blast mitigant
  • used to absorb hazardous liquids for solid disposal
  • used in gas fireplaces to simulate embers
  • used as a coating/impregnation on fiberglass sleeve, tape, rope and fabric to increase the useful temperature range and to add abrasion resistance. (http://www.vermiculitecoated.com)

Commercial manufacture of exfoliated vermiculite

Vermiculite output in 2005

In 2005, South Africa was the top producer of vermiculite with about 40% world share followed by the USA and China, reports the British Geological Survey.

While some exfoliators focus on only a few of the possible applications, others can provide vermiculite products for all its applications. It is common for vermiculite exfoliators to also exfoliate perlite, as both are often sold together. To set up a new exfoliation process, it is possible to find expert consultants to advise in the design and construction of the desired facilities. Vermiculite exfoliators have an international trade association called The Vermiculite Association to represent the industry's interests and to exchange information.[1] Many of its members also maintain memberships in The Perlite Institute.[2]

Fireproofing

For many years, since the advent of the asbestos removal business, before which nearly everyone sold asbestos-based spray fireproofing, vendors could be cleanly categorised into users of MMMF (man-made-mineral-fibres), which included both rockwool and ceramic fibres, and cementitious sprays, whereby the binder was typically portland cement and the lightweight aggregate inside the plaster was vermiculite. For many years, makers of the cementitious products would point out the ill health effects that are possible from overexposure and lack of proper industrial hygiene procedures when working with MMMF.[citation needed] Vendors of the MMMF products would point out the possibility of asbestos contamination, particularly with US mined vermiculite ore.[citation needed] Ironically, both sides were defending against lawsuits in the asbestos litigation and eventually stopped pointing out these particular weak spots about one another. Most affected manufacturers are still in receivership as a means of dealing with the results of the asbestos litigation.[citation needed] One large British manufacturer of asbestos products even had to discontinue selling anything to North America directly, having to rely on surrogate trading companies for sales to that continent now.[citation needed]

Asbestos contamination

Although not all vermiculite contains asbestos, some products were made with vermiculite that contained asbestos until the early 1990s. Vermiculite mines throughout the world are now regularly tested for it and are supposed to sell products that contain no asbestos. The former vermiculite mine in Libby, Montana, did have tremolite asbestos as well at winchite and richterite (both fibrous amphiboles) — in fact, it was formed underground through essentially the same geologic processes as the contaminants. A vermiculite mine in Virginia has also been found to be contaminated by asbestos.[3]

Pure vermiculite does not contain asbestos and is non-toxic, but it can become contaminated over long periods if there is a presence of a secondary mineral called diopside. After millions of years of weatherization, the biotite turns into vermiculite and the diopside turns into asbestos.

Controversy over health risks

The largest and oldest vermiculite mine in the United States was started in the 1920s, at Libby, Montana, and the vermiculite was sold under the commercial name Zonolite. The Zonolite brand and the mine was acquired by the W.R. Grace Company in 1963. Mining operations at the Libby site stopped in 1990 in response to asbestos contamination. While in operation, the Libby mine may have produced 80% of the world's supply of vermiculite.[4]

The United States government estimates that vermiculite was used in more than 35 million homes but does not recommend its removal. Nevertheless, homes or structures containing vermiculite or vermiculite insulation dating from before the mid 1990s, and especially those known to contain the "Zonolite" brand, may contain asbestos, and therefore may be a health concern.

An article published in the Salt Lake Tribune on December 3, 2006, reported that vermiculite and Zonolite had been found to contain asbestos, which had led to cancers such as those found in asbestos related cases. The article stated that there had been a "cover-up" by W.R. Grace Company and others regarding the health risks associated with vermiculite and that several sites in the Salt Lake Valley had been remediated by the EPA when they were shown to be contaminated with asbestos. W.R. Grace Company has vigorously denied these charges.

The vermiculite deposit at the Libby, Montana, mine, was (and is) heavily contaminated with asbestos. Numerous people were knowingly[5] exposed to the harmful dust of vermiculite that contained asbestos. Unfortunately, the mine had been operating since the 1920s, and environmental and industrial controls were virtually non-existent until the mine was purchased by the W.R. Grace Company in 1963. Yet, knowing the human health risks, the mining company still continued to operate there until 1990. Consequently, many of the former miners and residents of Libby have been affected and continue to suffer health problems. Over 200 people in the town have died from asbestos-related disease due to contamination from vermiculite mining from nearby Zonolite Mountain, where soil samples were found to be loaded with fibrous tremolite (known to be a very toxic form of asbestos), and countless others there who insulated their homes with Zonolite have succumbed to asbestos-related diseases, most of whom never were employed in environments where asbestos was an issue.[6]

After a 1999 Seattle Post-Intelligencer story claimed that asbestos-related disease was common in the town, the EPA, in response to political pressure, made cleanup of the site a priority and called Libby the worst case of community-wide exposure to a toxic substance in U.S. history.[7][8] The EPA has spent $120 million in Superfund money on cleanup.[8] In October 2006, W. R. Grace Company tried to appeal the fines levied on them from the EPA, but the Supreme Court rejected the appeal.[9] The United States government is also pursuing criminal charges against several former executives and managers of the mine for allegedly disregarding and covering up health risks to employees.[9] They are also accused of obstructing the government's cleanup efforts and wire fraud. To date, according to the indictment, approximately 1,200 residents of the Libby area have been identified as suffering from some kind of asbestos-related abnormality.[10] Jury selection was to have been completed in February, 2009.[11][12] The case ended in acquittals on May 8, 2009.[13]. On June 17, 2009. the EPA issued a public health emergency in and near Libby allowing Federal agencies to provide funding for health care, and removal of contaminated insulation from affected homes.[14]

See also

References

  1. ^ "The Vermiculite Association". http://www.vermiculite.org/. 
  2. ^ "The Perlite Institute". http://www.perlite.org/. 
  3. ^ http://www.seattlepi.com/uncivilaction/asb04.shtml
  4. ^ "Libby Site Background". United States Environmental Protection Agency. http://www.epa.gov/region8/superfund/libby/background.html. 
  5. ^ Dean, Cornelia. http://www.hereandnow.org/shows/2009/02/rundown-219/ The "Here and Now" radio show played a recording of testimony from a 1989 court case. The person testifying was a mine supervisor in mid-1950s. He testified unambiguously that the mine management knew that there was asbestos present, that it was toxic, and that the miners were being exposed to it.
  6. ^ "Deadly dust". CBC News. 2003-02-07. http://www.cbc.ca/national/news/deadly_dust/. 
  7. ^ "A town left to die: hundreds of miners and family members killed and sickened". Seattle PI. 1999-11-18. http://seattlepi.nwsource.com/uncivilaction/. 
  8. ^ a b "Libby Asbestos". United States Environmental Protection Agency. http://www.epa.gov/region8/superfund/libby/. 
  9. ^ a b Verhovek, Sam Howe (2006-10-11). "Firm Must Pay Asbestos Costs". LA Times. http://www.latimes.com/news/nationworld/nation/la-na-grace11oct11,1,3194269.story?coll=la-headlines-nation. 
  10. ^ "W.R. Grace and executives charged with fraud, obstruction of justice, and endangering Libby, Montana community". 2005-02-07. http://www.usdoj.gov/opa/pr/2005/February/05_enrd_048.htm. 
  11. ^ Johnson, Carrie (2007-07-13). "Asbestos Evidentiary Ruling Goes Against Grace". The Washington Post. pp. D05. http://www.washingtonpost.com/wp-dyn/content/article/2007/07/12/AR2007071201799.html. 
  12. ^ Johnson, Kirk (2009-02-19). "Ex-Grace Officials on Trial in Asbestos Poisoning". The New York Times. pp. A1. http://www.nytimes.com/2009/02/19/us/19asbestos.html. 
  13. ^ http://abcnews.go.com/US/wireStory?id=7539715
  14. ^ Dean, Cornelia. U.S. Cites Emergency in Asbestos-Poisoned Town New York Times, June 18, 2009.

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Dictionary. The American Heritage® Dictionary of the English Language, Fourth Edition Copyright © 2007, 2000 by Houghton Mifflin Company. Updated in 2009. Published by Houghton Mifflin Company. All rights reserved.  Read more
How Products are Made. How Products are Made. Copyright © 2002 by The Gale Group, Inc. All rights reserved.  Read more
Sci-Tech Encyclopedia. McGraw-Hill Encyclopedia of Science and Technology. Copyright © 2005 by The McGraw-Hill Companies, Inc. All rights reserved.  Read more
Architecture. McGraw-Hill Dictionary of Architecture and Construction. Copyright © 2003 by McGraw-Hill Companies, Inc. All rights reserved.  Read more
Gardener's Dictionary. Taylor's Dictionary for Gardeners, by Frances Tenenbaum. Copyright © 1997 by Houghton Mifflin Company. Published by Houghton Mifflin Company. All rights reserved.  Read more
Geological Glossary. Peterson Field Guide to Rocks and Minerals, by Frederick H. Pough. Copyright © 1998 by Houghton Mifflin Company. Published by Houghton Mifflin Company. All rights reserved.  Read more
Wikipedia. This article is licensed under the Creative Commons Attribution/Share-Alike License. It uses material from the Wikipedia article "Vermiculite" Read more