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Drywall (also known as plasterboard, wallboard, gypsum board, sheetrock, or LAGYP) is a panel made of gypsum plaster pressed between two thick sheets of paper. It is used to make interior walls and ceilings. Drywall construction became prevalent as a speedier alternative to traditional lath and plaster.
In many places, the product is sold under the trademarks Sheetrock or Gyproc. In New Zealand the category is known as plasterboard or gib board (originally "Gibraltar board"), the latter being a proprietary brand name but now largely a genericised trademark.
The first plasterboard plant in the UK was opened in 1888 in Rochester Kent. Sackett Board was invented in 1894 by Augustine Sackett and Fred Kane. It was made by layering plaster within four plies of wool felt paper. Sheets were 36" × 36" × 1/4" thick with open (untaped) edges.
Gypsum Board evolved between 1910 and 1930 beginning with wrapped board edges, and elimination of the two inner layers of felt paper in favor of paper-based facings. In 1910 United States Gypsum Corporation bought Sackett Plaster Board Company and by 1917 came out with a product they called sheetrock. Providing efficiency of installation, it was developed additionally as a measure of fire resistance. Later air entrainment technology made boards lighter and less brittle, then joint treatment materials and systems also evolved.
Rock Lath (gypsum lath) was an early substrate for plaster. An alternative to traditional wood or metal lath, it was a panel made up of compressed gypsum plaster board that was sometimes grooved or punched with holes to allow wet plaster to key into its surface. As it evolved, it was faced with paper impregnated with gypsum crystals that bonded with the applied facing layer of plaster.
A wallboard panel is made of a paper liner wrapped around an inner core made primarily from gypsum plaster. The raw gypsum, CaSO4·2 H2O, (mined or obtained from flue-gas desulfurization (FGD)) must be calcined before use to produce the hemihydrate of calcium sulfate (CaSO4·½ H2O). This is done in kettle or flash calciners, typically using natural gas today. The plaster is mixed with fiber (typically paper and/or fiberglass), plasticizer, foaming agent, finely ground gypsum crystal as an accelerator, EDTA, starch or other chelate as a retarder, various additives that may decrease mildew and increase fire resistance (fiberglass or vermiculite), wax emulsion or silanes for lower water absorption and water. This is then formed by sandwiching a core of wet gypsum between two sheets of heavy paper or fiberglass mats. When the core sets and is dried in a large drying chamber, the sandwich becomes rigid and strong enough for use as a building material.
Drying chambers typically use natural gas today. To dry 1 MSF ( 1,000 square feet (93 m2) ) of wallboard, between 1.75 and 2.49 million BTU is required. Organic dispersants/plasticisers are used mainly to reduce the amount of water, hence reduce the eventual drying time, needed to produce gypsum slurry flow during wallboard manufacture.
Drywall panels are manufactured in 48-inch (1.2 m) and 96-inch (2.4 m) wide panels in varying lengths to suit the application. Common panel thicknesses are 1⁄2-inch (13 mm) and 5⁄8-inch (16 mm), with panels also available in 1⁄4-inch (6.4 mm) and 3⁄8-inch (9.5 mm). Both 1⁄2-inch and 5⁄8-inch panels of Type X (a gypsum board with special core additives to increase the natural fire resistance of regular gypsum board) are used where a fire-resistance rating is desired. Sound transmission may be slightly reduced using regular 5⁄8-inch panels (with or without light-gauge resilient metal channels) but more effective are using two layers of drywall sometimes in combination with other factors or specially designed, sound-resistant drywall.
Drywall provides a thermal resistance R-value (in US units) of 0.32 for 3⁄8-inch board, 0.45 for 1⁄2-inch, 0.56 for 5⁄8-inch, and 0.83 for 1-inch board. In addition to increased R-value, thicker drywall has a higher sound transmission class.
In Europe plasterboard is manufactured in metric sizes, with the common sizes being corollaries of old imperial sizes.
Most plasterboard is made in 120 cm wide sheets, though 90 cm and 60 cm wide sheets are also made. 120 cm wide plasterboard is most commonly made in 240 cm lengths, though 250, 260, 270, 280, 300 cm and even longer (if ordered) are commonly available.
Thicknesses of plasterboard available are 9.5 mm to 25 mm.
Plasterboard is commonly made with one of three different edge treatments—tapered edge, where the long edges of the board are tapered with a wide bevel at the front to allow for jointing materials to be finished flush with the main board face, plain edge, used where the whole surface will receive a thin coating (skim coat) of finishing plaster, and finally bevelled on all four sides, used in products specialised for roofing. However four side chamfered drywall is not currently offered by major UK manufacturers for general use.
Plasterboard (instead of the term drywall) is used in Australia and New Zealand. Since both countries utilise the metric system, all building materials are made to suit metric measurements. Plasterboard is manufactured in thicknesses of 10mm, 13mm, and 16mm. There are also other thicknesses available up to 25mm. Panels are commonly sold in 1200x2400mm sheets or 1200x4800mm and 1200x6000mm sheets. Sheets are usually secured to either a timber or steel frame anywhere from 150 to 300mm centres along the beam and 400 to 600mm across members.
Various manufacturers such as Boral and CSR manufacture plasterboard under different names such as Gyprock. In addition, various types are available to suit normal residential installations, wet areas such as bathrooms, and fire-rated panels.
As an alternative to a week-long plaster application, an entire house can be drywalled in one or two days by two experienced drywallers, and drywall is easy enough to use that it can be installed by many amateur home carpenters. In large-scale commercial construction, the work of installing and finishing drywall is often split between the drywall mechanics, or hangers, who install the wallboard, and the tapers and mudmen, or float crew, who finish the joints and cover the nailheads with drywall compound.
Drywall is cut to size, using a large T-square, by scoring the paper on the front side (usually white) with a utility knife, breaking the sheet along the cut, and cutting the paper backing. Small features such as holes for outlets and light switches are usually cut using a keyhole saw or a small high-speed bit in a rotary tool. Drywall is then fixed to the wall structure with nails, glue, or more commonly in recent years, the now-ubiquitous drywall screws.
Drywall fasteners, also referred to as drywall clips or stops, are gaining popularity in both residential and commercial construction. Drywall fasteners are used for supporting interior drywall corners and replacing the non-structural wood or metal blocking that traditionally was used to install drywall. Their function serves to save on material and labour expenses, to minimize call-backs due to truss uplift, to increase energy efficiency, and to make plumbing and electrical installation simpler.
Drywall screws heads have a curved taper, allowing them to self-pilot and install rapidly without punching through the paper cover. These screws are set slightly into the drywall. When drywall is hung on wood framing, screws having an acute point and widely spaced threads are used. When drywall is hung on light-gauge steel framing, screws having an acute point and finely spaced threads are used. If the steel framing is heavier than 20-gauge, self-tapping screws with finely spaced threads must be used. In some applications, the drywall may be attached to the wall with adhesives.
After the sheets are secured to the wall studs or ceiling joists, the seams between drywall sheets are concealed using joint tape and several layers of joint compound (sometimes called mud). This compound is also applied to any screw holes or defects. The compound is allowed to air dry then typically sanded smooth before painting. Alternatively, for a better finish, the entire wall may be given a skim coat, a thin layer (about 1 mm or 1/16 inch) of finishing compound, to minimize the visual differences between the paper and mudded areas after painting.
Another similar skim coating is always done in a process called veneer plastering, although it is done slightly thicker (about 2 mm or 1/8 inch). Veneering uses a slightly different specialized setting compound ("finish plaster") that contains gypsum and lime putty. This application uses blueboard, which has special treated paper to accelerate the setting of the gypsum plaster component. This setting has far less shrinkage than the air-dry compounds normally used in drywall, so it only requires one coat. Blueboard also has square edges rather than the tapered-edge drywall boards. The tapered drywall boards are used to countersink the tape in taped jointing whereas the tape in veneer plastering is buried beneath a level surface. One coat veneer plaster over dry board is an intermediate style step between full multi-coat "wet" plaster and the limited joint-treatment-only given "dry" wall.
The method of installation and type of drywall can reduce sound transmission through walls and ceilings. Several builders books state that thicker drywall reduces sound transmission but engineering manuals recommend using multiple layers of drywall, sometimes of different thicknesses and glued together, or special type of drywall designed to reduce noise. Also important are the construction details of the framing with steel studs, wider stud spacing, double studding, insulation, and other details reducing sound transmission. Sound transmission class (STC) ratings can be reduced from 33 for an ordinary stud-wall to as high a rating as 59 with double 1/2" sheetrock on both sides of a wood stud wall with resilient channels on one side and fiberglass bat insulation between the studs.
Drywall may become damaged when exposed to water, especially if the drywall remains exposed to the water for an extended period of time. Often, when a room features drywall installed and an unintended introduction of water occurs and the water comes into contact with the drywall at the base of the wall where the drywall touches the ground, wicking will occur. Capillary action may introduce moisture anywhere from several inches to several feet above the floor depending upon the length of time the wall is exposed to water and how long the drywall remains in contact with the water supply.
Water that enters a room from overhead may cause ceiling drywall tape to separate from the ceiling as a result of the grooves immediately behind the tape where the drywall pieces meet become saturated. The drywall may also soften around the screws holding the drywall in place and with the aid of gravity, the weight of the water may cause the drywall to sag and eventually collapse, requiring replacement.
In many circumstances, especially when the drywall has been exposed to water or moisture for less than 48 hours, professional restoration experts familiar with structural drying methodologies can introduce rapid drying techniques designed to eliminate necessary elements required to support microbial activity while also restoring most or all of the drywall and thus avoiding the cost, inconvenience and difficulty of removing and replacing the affected sheetrock.
While it can be waterproofed through covalent waterproofing, if waterproofing is absent or if the waterproofing layer is punctured, water can penetrate the drywall and create an opportunity for bacteria to multiply and settled mold spores to begin germination.
The gypsum that makes the core of drywall does not readily support the growth of mold, but the paper backing found on most gypsum boards will.
A substantial amount of defective drywall was imported into the United States from China and incorporated into tens of thousands of homes during rebuilding in 2006 and 2007 following Hurricane Katrina and in other places. Complaints included foul odor, health effects, and corrosion of metal within the structure. This is caused by the emission of sulfurous gases. The same drywall was sold in Asia without problems resulting, but U.S. homes are built much more tightly than homes in China, with less ventilation.
Volatile sulfur compounds, including hydrogen sulfide, have been detected as emissions from the imported drywall and may be linked to health problems. These compounds are emitted from many different types of drywall, and at least one investigation has pointed to high levels being emitted from drywalls manufactured in the United States.
Coal-fired power stations include devices called "scrubbers" to remove sulfur from their exhaust emissions. The sulfur is absorbed by powdered limestone in a process called flue-gas desulfurization (FGD), which produces a number of new substances. One is called "FGD gypsum". This is commonly used in drywall construction in the United States and elsewhere.
A number of lawsuits are underway in many jurisdictions, but many of the sheets of drywall are simply marked, "Made in China", thus making identification of the manufacturer difficult. An investigation by the Consumer Product Safety Commission, CPSC, was underway in 2009. In November 2009, the CPSC reported a "strong association" between Chinese drywall and corrosion of pipes and wires reported by thousands of homeowners in the United States.
When used as a component in fire barriers, drywall is a passive fire protection item. In its natural state, gypsum contains the water of crystallization bound in the form of hydrates. When exposed to heat or fire, this water is vapourised, retarding heat transfer. Therefore, a fire in one room that is separated from an adjacent room by a fire-resistance rated drywall assembly will not cause this adjacent room to get any warmer than the boiling point (100°C) until the water in the gypsum is gone. This makes drywall an ablative material because as the hydrates sublime, a crumbly dust is left behind, which, along with the paper, is sacrificial. Generally, the more layers of Type X drywall one adds, the more one increases the fire-resistance of the assembly, up to four hours for walls and three hours for ceilings. Evidence of this can be found both in publicly available design catalogues, including DIN4102 Part 4 and the Canadian Building Code on the topic, as well as common certification listings, including certification listings provided by Underwriters Laboratories and Underwriters Laboratories of Canada (ULC). "Type X" drywall is formulated by adding glass fibers to the gypsum, to increase the resistance to fires, especially once the hydrates are spent, which leaves the gypsum in powder form. Type X is typically the material chosen to construct walls and ceilings that are required to have a fire-resistance rating.
Fire testing of drywall assemblies for the purpose of expanding national catalogues, such as the National Building Code of Canada, Germany's Part 4 of DIN4102 and its British cousin BS476, are a matter of routine research and development work in more than one nation and can be sponsored jointly by national authorities and representatives of the drywall industry. For example, the National Research Council of Canada routinely publishes such findings. The results are printed as approved designs in the back of the building code. Generally, exposure of drywall on a panel furnace removes the water and calcines the exposed drywall and also heats the studs and fasteners holding the drywall. This typically results in deflection of the assembly towards the fire, as that is the location where the sublimation occurs, which weakens the assembly, due to the fire influence.
When tests are cosponsored, resulting in code recognized designs with assigned fire-resistance ratings, the resulting designs become part of the code and are not limited to use by any one manufacturer, provided the material used in the field configuration can be demonstrated to meet the minimum requirements of Type X drywall (such as an entry in the appropriate category of the UL Building Materials Directory) and that sufficient layers and thicknesses are used. Fire test reports for such unique third party tests are confidential.
It's important to consider deflection of drywall assemblies to maintain their assembly integrity to preserve their ratings. Deflection of drywall assemblies can vary somewhat from one test to another. Importantly, penetrants do not follow the deflection movement of the drywall assemblies they penetrate. For example, see cable tray movement in a German test. It is, therefore, important to test firestops in full scale wall panel tests, so that the deflection of each applicable assembly can be taken into account.
The size of the test wall assembly alone is not the only consideration for firestop tests. If the penetrants are mounted to and hung off the drywall assembly itself during the test, this does not constitute a realistic deflection exposure insofar as the firestop is concerned. In reality, on a construction site, penetrants are hung off the ceiling above. Penetrants may increase in length, push and pull as a result of operational temperature changes (e.g., hot and cold water in a pipe), particularly in a fire. But it is a physical impossibility to have the penetrants follow the movement of drywall assemblies that they penetrate, since they are not mounted to the drywalls in a building.
It is, therefore, counterproductive to suspend penetrants from the drywall assembly during a fire test. As downward deflection of the drywall assembly and buckling towards the fire occurs, the top of the firestop is squeezed and the bottom of the firestop is pulled. This is motion above that caused by expansion of metallic penetrants due to heat exposure in a fire. Both types of motion occur because metal first expands in a fire, and then softens once the critical temperature has been reached, as is explained under structural steel. To simulate the drywall deflection effect, one can simply mount the penetrants to the steel frame holding the test assembly. The operational and fire-induced motion of the penetrants, which is independent of the assemblies penetrated, can be separately arranged.
North America is one of the largest gypsum board users in the world with a total wallboard plant capacity of 42,000,000,000 square feet (3.9×109 m2) per year (world wide 85,000,000,000 square feet (7.9×109 m2) per year). Moreover, the home building and remodeling markets in North America in the late 1990s and early 2000s increased demand. The gypsum board market was one of the biggest beneficiaries of the housing boom as "an average new American home contains more than 7.31 metric tons of gypsum."
The introduction in March 2005 of the Clean Air Interstate Rule by the United States Environmental Protection Agency requires power plants to "cut sulfur dioxide emissions by 73%" by 2018. The Clean Air Interstate Rule also requested that the power plants install new scrubbers (industrial pollution control devices) to remove sulfur dioxide present in the output waste gas. Scrubbers use the technique of flue-gas desulfurization (FGD), which produces synthetic gypsum as a usable by-product. In response to the new supply of this raw material, the gypsum board market was predicted to shift significantly. However, issues such as mercury release during calcining need to be resolved.
Because up to 17% of drywall is wasted during the manufacturing and installation processes and the drywall material is frequently not re-used, disposal can become a problem. Some landfill sites have banned the dumping of drywall. Some manufacturers take back waste wallboard from construction sites and recycle it into new wallboard. Recycled paper is typically used during manufacturing. More recently, recycling at the construction site itself is being researched. There is potential for using crushed drywall to amend certain soils at building sites, such as sodic clay and silt mixtures (bay mud), as well as using it in compost.
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