Title of Invention	REINFORCED WALLBOARD
Abstract	A reinforced wallboard core is prepared from a slurry comprising a mixture of ß-calcium sulfate hemihydrate, a cellulose ether additive other than CMC and an amount of water that is sufficient to form a slurry and resulting in a wallboard density of less than 0.8 g/cc. The ß-calcium sulfate hemihydrate is hydrated by the water forming a wallboard core reinforced by the cellulose ether additive. The cellulose ether, having a molecular weight of at least about 20,000 and a viscosity grade of at least 100 cps, is selected to give the reinforced wallboard core improved nail pull resistance and greater flexural strength than unreinforced wallboard of the same density. The reinforced wallboard core may be used for reduced-paper wallboard and / or for lightweight wallboard, for example.

Title of Invention

REINFORCED WALLBOARD

Abstract

A reinforced wallboard core is prepared from a slurry comprising a mixture of ß-calcium sulfate hemihydrate, a cellulose ether additive other than CMC and an amount of water that is sufficient to form a slurry and resulting in a wallboard density of less than 0.8 g/cc. The ß-calcium sulfate hemihydrate is hydrated by the water forming a wallboard core reinforced by the cellulose ether additive. The cellulose ether, having a molecular weight of at least about 20,000 and a viscosity grade of at least 100 cps, is selected to give the reinforced wallboard core improved nail pull resistance and greater flexural strength than unreinforced wallboard of the same density. The reinforced wallboard core may be used for reduced-paper wallboard and / or for lightweight wallboard, for example.

Full Text	REINFORCED WALLBOARD RELATED APPLICATION [0001] This application claims the benefit of U.S. Provisional Application No. 60/425,924, filed November 12,2002, the entire disclosure of which is incorporated by reference herein. FIELD OF THE INVENTION (0002] The field of the invention is wallboards for use in construction, including paper-covered wallboard, paperless wallboard, sheathing board, moisture resistant board, type-X board, insulation board, shaft liner, soffit board, backing board, core board, ceiling board, gypsum glass mat board and a method of manufacturing such wallboards. BACKGROUND OF THE INVENTION [0003] A modified cellulose, also referred to herein as a cellulose derivative, is used in plaster and joint compounds as a thickener (or to modify the rheology in some way) and to improve the workability of gypsum-based compounds. Cellulose ethers have been known to improve some other properties, including the consistency, adhesion and water retention of gypsum- based joint compounds and tile adhesives. However, some of these properties, specifically thickening, are not considered beneficial for the production of wallboard. Wallboard is formed from a slurry that is continuously mixed and fed onto a belt. Thus, it is desirable for the slurry used to make wallboard to be thinner than a plaster. [0004] Typically, a small amount, e.g. less than 0.25 wt%, of cellulose ethers is added to the dry ingredients of plaster or joint compound, which may be limestone-based rather than gypsum-based, prior to mixing with water. This tends to improve the strength of the plaster or joint compound somewhat, as well as providing the desired thickening. However, additions of cellulose ethers greater than 0.25 wt%, particularly at high viscosity grade (the viscosity of an aqueous solution of the cellulose ether measured at a 2 wt% concentration of the cellulose ether in water), tend to reduce the strength of gypsum-based products. See Udo Ludwig and N.B. Singh, Il Cemento, v.1 (1979) 39-50, and Felix Brandt and Dirk Basbach, Journal of Crystal Growth, v.233 (2001) 837-845, reporting that the addition of high viscosity grades of cellulose ethers, for example methyl cellulose, adversely affects the development of gypsum crystals and strength. Thus, larger additions of cellulose ethers are usually avoided in commercial plasters. [0005] Wallboard, which is used herein to also designate such products as sheathing board, moisture resistant board, type-X board, insulation board, shaft liner, soffit board, backing board, core board, ceiling board, gypsum glass mat board, and paperless wallboard, is typically prepared by mixing dehydrated inorganic materials such as calcined gypsum or stucco with water and pouring the resulting slurry into molds, forms or sheets where it hydrates, hardens and dries. Calcined gypsum powder (calcium sulfate hemihydrate and/or calcium sulfate anhydrite) is usually mixed with water and less than 1 wt% of a variety of additives, for example accelerants. Dissolution of the calcined gypsum powder in the water and a resulting hydration reaction causes crystallization of gypsum crystals (calcium sulfate dihydrate) forming the wallboard core. Application of multi-ply face sheets is usually integrated with the formation of the wallboard core. This is often followed by mild heating to drive off the remaining free (unreacted) water to yield a dry product, having face sheets adhered to gypsum core. [0006] Lukevich et al. (WO 99/54265) discloses a method to produce formed gypsum products by extrusion of an a-gypsum paste (using a-calcium sulfate hemihydrate). It is known that a-gypsum is slow setting and drying; therefore, Lukevich et al. prepares an extrudable paste using a nearly stoichiometric combination of a-gypsum plaster and water; however, addition of a clay rheology modifier and a methyl cellulose binder are added to reduce friability (page 1, paragraph 4). The resulting composition is an extrudable paste having near stoichiometric composition of water and a-gypsum and not a slurry. [0007] Thus, Lukevich et al. teaches away from using P-calcium sulfate hemihydrate, which requires an excess of water over and above the stoichiometric limits taught by Lukevich, to form a slurry that can be extruded and requiring a step of drying (page 1, paragraph 3). Additionally, the extrusion of the nearly dry, non-fluid paste, containing clay as a rheology modifier and a cellulose ether as a binder, results in a plaster product with a much greater density and vastly different microstructure than a wallboard core prepared using a slurry of p-calcium sulfate hemihydrate and water. [0008] Morris et al., U.S. Pat. No. 5,482,551, which issued January 9, 1996, disclose a gypsum-based, extruded construction material with a high modulus of rupture and a method of extrusion processing of the construction material. Morris et al. teach a formulation having a low fraction of water to dry ingredients, including gypsum, clay, perlite, a powdered ethyl cellulose binder/rheology aid and fiberized cellulose paper, such that the mixture is a crumbly, semi-dry extrudable composition that maximizes the wet modulus of rupture. Morris et al. teach that an extruded wall panel must have a high enough wet strength to be self supporting. [0009] However, the extruded construction material of Morris et al., like that of Lukevich, is too dense to be used commercially as wallboard. Even with substantial inclusions of lightweight perlite (16% by weight of the dry ingredients) and near the maximum ratio of water:gypsum allowed by Morris et al. (0.8), the density of the product was still 54.8 pcf (0.88 g/cc). Typical densities were about 69 pcf (1.1 g/cc). These densities are unacceptable for production of commercial wallboard, because the added weight of the wallboard adds significantly to higher transportation, handling, and installation costs compared to conventional wallboard. [0010] Gypsum-based wallboard is used primarily as inexpensive and easily formable coverings with adequate compressive strength, nail pull resistance, flexural strength and good fire resistance. However, even conventional gypsum-based wallboard products are heavy compared to other modern building materials, and this extra weight adds to the cost of production, delivery, installation and disposal of gypsum-based construction materials compared to competing products. Thus, it is desirable to retain the beneficial qualities of gypsum-based wallboard while reducing the overall cost of installed wallboard sheets by reducing the weight of gypsum-based wallboard. [0011] Also, strength of conventional wallboard is related primarily to the strength of the facing paper, typically an oriented fiber, multi-ply facing paper that is applied to the gypsum-based slurry, which forms the core of the wallboard, during a continuous forming process. For a 1/2 inch wallboard with a density of about 0.6 g/cc, approximately one-half of the nail pull resistance and two-thirds of the flexural strength are supplied by the paper face sheets, which also account for 40% of the manufacturing costs. The core is usually exceptionally poor at handling tensile loads of any kind. [0012] Others have reduced the weight of the core further by adding porosity and/or a low-density, expanded filler (e.g. perlite) into the conventional material. Adding such porosity or filler decreases the density of the core, but also reduces the strength of the wallboard. The strength of gypsum sheets decreases dramatically with density. For example, a dramatic decrease of the nail-pull resistance with density of 1/2-inch gypsum wallboard, both papered and non-papered, can be seen in Fig. 3. {0013] Typically, the rate of loss in strength is not merely proportional with the reduction in density, but instead the strength-to-weight ratio of the wallboard core decreases with the addition of porosity and/or low-density filler, such as perlite, compared to that of a fully dense gypsum wallboard core. The resulting flexural strength of the wallboard may be acceptable, so long as the strength of the multiply facing is sufficient to offset any weakening of the core, and the reduced core density does not cause the failure mode to change from tensile failure of the facing to crushing of the core. However, nail pull resistance of the wallboard is reduced by addition of such porosity, because increasing porosity rapidly reduces the resistance of the core to crushing and densification. Therefore, the nail pull resistance of the wallboard, which depends greatly on the nail pull resistance of the core, becomes the limiting criterion for wallboard with low-density cores covered by face sheets. For paperless wallboard core, the flexural strength may be the limiting failure criterion, because unreinforced gypsum wallboard cores have little, if any, resistance to the tensile load components in the flexural strength test. [0014] Another way of compensating for the introduction of lower density substitutes (e.g., expanded perlite or air voids) for part of the set gypsum matrix is to increase the strength of the set gypsum above normal levels in order to maintain overall core strength. A number of additives, such as cellulosic particles and fibers, have been included to further improve the mechanical properties of cementitious products. More expensive glass fibers are used in place of wood in applications where high fire resistance is required, such as the shaft liner for elevators. However, conventional fibers, particularly glass, do not adhere well to the gypsum matrix and decrease the workability of the gypsum slurry, thus limiting possible improvements to the core strength. Glass fibers are also brittle and can be easily dislodged during board handling, installation, or demolition to cause irritation of the skin or respiratory tract. {0015] More recently, there has been increasing interest in improving the strength and wear resistance of construction materials by incorporating polymers and/or starches into the core material, although starches are not generally considered strength enhancers. Cementitious composites containing water-dispersible polymers having modest improvement in strength-to-weight have been found by adding latex or other strengthening polymers to the cementitious materials. [0016] However, several unique challenges have thus far restricted the commercialization of polymer reinforced cementitious products to relatively expensive niche products. For example, the nail pull resistance may decrease with the addition of some organic additives or an increase in nail pull resistance may require concentrations of polymers greater than 5 wt%, which can lead to problems such as inflammability, reduced extinguishability, commercially unacceptable cost of the wallboard, and mold susceptibility. Therefore, there is a longstanding and unresolved need for an additive that can increase both the nail pull resistance and the flexural strength of wallboard core, allowing the core density to be reduced. [0017] Cellulose is a polysaccharide composed of individual anhydroglucose units which are linked through a glycosidic bond (Figure 16). The number V of anhydroglucose units in the polymer chain is defined as the degree of polymerisation. Typically, production of cellulose ethers (CE's) involves replacing some of the hydroxyl hydrogen groups of cellulose with a substituent group, for example a methyl group, an ethyl group, a carboxymethyl group, a hydroxyehthyl group, a hydroxypropyl group, or some combination thereof. For example, a hydroxyethyl methyl cellulose (HEMC) may be produced by replacing some of the groups of cellulose with hydroxyethyl groups and methyl groups. Likewise, a hydroxypropyl methyl cellulose (HPMC) may be produced with hydroxypropyl and methyl groups replacing some of the hydroxyl groups of the cellulose. [00181 The number of substituted hydroxyl groups per anhydroglucose unit is expressed as the degree of substitution (DS). The DS can vary between 0 and 3. As with all polymer reactions, this reaction does not occur uniformly along the polymer chain. The reported degree of substitution is therefore a mean degree of substitution over the whole polymer chain. Alternatively, molar substitution (MS) may be used to report the number of moles of substituent groups, such as a hydroxypropyl group, per mole of anhydroglucose. Often, manufacturers follow a convention whereby one of the substituents is reported by DS and the other by MS, where the substituent reported by MS may replace a hydroxyl group or may attach to another substituent in a chain. The DS is not always reported, and we have found that the value reported is often inaccurate or given as a broad range, as shown in Table I. [0019] In another alternative, the weight percent of substituents is reported. Weight percent of substituents may be directly related to DS and MS. For example, the following equations show the conversion for HPMC: [0020] Cellulose ethers are conventionally differentiated by type of substituent and the viscosity of an aqueous solution of the cellulose ether. For example methyl cellulose (MC), ethyl cellulose (EC), carboxymethyl cellulose (CMC), hydroxyethyl cellulose (HEC), ethyl hydroxyethyl cellulose (EHEC), ethyl hydroxypropyl cellulose (EHPC) and hydroxypropyl cellulose (HPC) are named for the type of substituent group used to replace the hydroxyl group in cellulose. The viscosity of an aqueous solution including a cellulose ether is an important characteristic for its typical use as a thickener; therefore, cellulose ethers are also differentiated by viscosity, which depends on the degree of polymerization (directly related to the measured molecular weight), and the type and degree of substitution of substituent groups. As the molecular weight increases, the viscosity of an aqueous solution of the cellulose ether increases also. However, the effect of the degree of substitution depends on the particular type of substituent group, which may also effect the solubility of the cellulose ether. [00211 Manufacturers characterize the effect of a particular cellulose ether on the viscosity by reporting the measured viscosity of a 2 wt% aqueous solution of the cellulose ether. Herein, we refer to this 2 wt% viscosity as the viscosity grade of the particular cellulose ether. Typically, the viscosity grade is measured by one of two techniques: Brookfield and Ubbelohde. Often, the measured viscosity grade differs between the two techniques. For example, results using both techniques are shown in Table I for some cellulose ethers. [0022] Cellulose ethers are not typically used in wallboard products, but may be used at low molecular weights (low viscosity) and low concentrations to provide proper water retention, pumpabiliry and/or increase mixing blade life. SUMMARY OF THE INVENTION [0023] A wallboard core comprises water, P-calcium sulfate hemihydrate and an additive, which are mixed together to form the wallboard core. Herein, the term wallboard is used to also designate such products as sheathing board, moisture resistant board, type-X board, insulation board, shaft liner, soffit board, backing board, core board, ceiling board, gypsum glass mat board, and paperless wallboard, which may be used to finish walls and ceilings in the construction industry. [0024] Upon mixing with the water, the P-calcium sulfate hemihydrate may dissolve or partially dissolve in the water and hydrates, over time, forming gypsum crystals. The additive is selected from one or more cellulose ethers having, for example, a molecular weight of at least 20,000 and a viscosity grade of at least 100 cps, such as HPC, HEC, MC, HPMC, EHEC, EHPC and HEMC, without limiting in any way to those listed here, increasing both the nail pull resistance and flexural strength of the wallboard core. Preferably, the weight percent of cellulose ether to P-calcium sulfate hemihydrate is selected to be less than 5 wt%, more preferably less than 3 wt%, whereby the cellulose ether has a negligible effect on the inflamability and extinguishability of the wallboard. Even more preferably, the weight percent is selected from 0.5 wt%, alternatively from 0.5 - 3 wt%, for cellulose ethers that show a continuously increasing nail pull resistance from 0.5 wt% to 3 wt%, which greatly simplifies the mixing process. Alternatively, a cellulose ether with a low degree of substitution (DS) is chosen. [0025] The increased nail pull resistance and flexural strength imparted to the reinforced wallboard core makes it possible to reduce or eliminate the costly and heavy multi-ply paper surfaces of the wallboard. The multi-ply paper facing can also increase the undesirable mold susceptibility of wallboard by feeding mold growth after absorbing water from the surrounding environment. Thus, a mold resistant wallboard may be fabricated using a reduced paper wallboard core that is strengthened by a cellulose ether additive. Although paper is a cellulose, cellulose derivatives, such as cellulose ethers, do not tend to feed mold growth when added to the wallboard core, as shown by mold resistance tests of specimen maintained at 32 degrees C in an incubator with 90% humidity and in the presence of mold spores. In an alternative embodiment, a skim layer is added to at least one surface provides even greater mold resistance. There is a longstanding and unresolved need for low cost wallboard having such mold resistance. [0026] A lightweight wallboard, for example with a conventional multi-ply facing sheet or sheets, may be fabricated by reducing the density of the wallboard core without sacrificing the nail pull resistance of the wallboard. For example, the density may be reduced below 0.75 g/cc using a lightweight filler or by introducing porosity into the core in the form of voids or air bubbles while maintaining the flexural strength and nail pull resistance of the wallboard. [0027] Addition of an excess amount of water to the slurry, over and above the stoichiometric amount of water needed to hydrate the powdered dry ingredients, reduces the density of the wallboard core. It is believed, without being limiting in any way, that the excess water forms droplets in the wallboard core that, after drying, remain in the wallboard core as pores. A general, empirical correlation has been found for predicting the wallboard density in g/cc (p) with the water to powdered dry ingredient ratio (W:P), if foaming is negligible: p = 0.8324(W:P)-07629. The addition of foaming, whether by rapid stirring or addition of a foaming agent, may further reduce the density by introducing porosity into the wallboard core in addition to the amount introduced by the excess water. [0028] By adding additional water to the slurry, viscosity of the slurry is reduced. Thus, a slurry containing substantially no clay may be extruded in a continuous extrusion process, forming lightweight, reinforced wallboard. By substantially no clay, it is meant that no clay is added to the dry ingredients as a rheology modifier. Of course, clay may be present as an impurity in the dry ingredients or the water at a level that does not significantly affect the rheology of the extrusion process. [0029] One method of producing the wallboard core mixes dry ingredients comprising ß-calcium sulfate hemihydrate powder and a powdered additive selected from cellulose ethers other than CMC, the cellulose ether being selected to have a degree of substitution (DS) that is soluble in water (e.g. from 1.2 to 2.4 for MC). For commercially available cellulose ethers, having a range of DS from 1.6 to 1.9, for example, a viscosity grade of at least about 100 cps and a molecular weight of at least about 20,000 MW is preferred. [0030] For a high degree of substitution (DS), e.g. greater than 1.8 for methyl cellulose (MC), a higher viscosity grade (e.g. at least about 200 cps) is preferred. Surprisingly, a higher DS is associated with a lower nail pull resistance for cellulose ethers, such as MC. Thus, a low DS (e.g. in a range from 1.2 to 1.8 for MC) is preferred, because a lower viscosity grade cellulose ether may be selected or a lower fraction of the cellulose ether additive may be added, while still achieving the same nail pull resistance. By lowering the viscosity grade, the slurry becomes easier to mix, given the same amount of water. By lowering the amount of water, the wallboard dries quicker, given the same slurry viscosity. By lowering the fraction of cellulose additive in the slurry, the manufacturing cost of the wallboard is decreased. [0031] Thus, a range of DS from 1.2 to 1.6 for MC is even more preferred, for example. Although MC is not available commercially in this range, the surprising and unexpected correlations for such low DS cellulose ethers, providing greatly enhanced flexural strength and nail pull resistance, the low cost of manufacturing such cellulose ethers, and the high volumes of MC to be used in reinforced wallboard manufacture is expected to drive the development of commercial grades of MC in this Tange of DS. 10032] In another embodiment, it is preferable to select a viscosity grade of at least about 400 cps. Surprisingly, by selecting a cellulose ether greater than this viscosity grade, the nail pull resistance of the resulting wallboard core increases significantly compared to unreinforced wallboard core for additions of from 0.5 wt% to 3 wt% of all cellulose ethers tested, except for CMC, so long as the cellulose ether is well dispersed throughout the p-calcium sulfate hemihydrate prior to adding to water, even at relatively high DS. At low DS, the correlations show that nail pull index and flexural strength index are dramatically increased compared to any conventional wallboard. [0033] An amount of water may be selected to form a slurry with the dry ingredients that results in a finished wallboard core density of 0.75 g/cc after extrusion, setting and drying in an oven at 45 oC until the density remains constant. In addition, many other additives, including other cellulose ethers may be added to tailor the properties of the wallboard core without diminishing the nail pull resistance and strength of the wallboard core. [0034] In one embodiment, these dry ingredients may be well mixed to thoroughly disperse the additive throughout the P-calcium sulfate hemihydrate powder. Then, the dry ingredients are added to and mixed with the water, poured onto a form, formed into a sheet, allowed to set, dried and trimmed. The amount of water selected will always be in excess of the amount needed for extrusion and for the amount of water required for a stoichiometric combination of the p- calcium sulfate hemihydrate and water to form gypsum. Preferably, the amount of water is selected to produce a wallboard core with a density less than 0.8 g/cc, more preferably less than 0.75 g/cc, even more preferably in a range from 0.45 g/cc to 0.7 g/cc for lightweight wallboard. [0035] By a "slurry," it is meant that the mixture of dry ingredients and water forms a homogeneous fluid that can be well mixed, dissolving at least a portion of the P-calcium sulfate hemihydrate in the water prior to extruding the slurry. The amount of water required depends, for example, on the amount of ß- calcium sulfate hemihydrate, the amount of additive and other dry ingredients, as well as the temperature and the type of additive or additives included in the slurry. The amount of water used significantly alters the microstructure of the wallboard core, for example by affecting the amount of porosity, the extent of dissolution of the P-calcium sulfate hemihydrate, the rate of hydration and the morphology of the gypsum crystals, which in turn affects the nail pull resistance and flexural strength of the wallboard. A foam may be added to the slurry, instead of adding additional water, in order to reduce the density to a preferred range for a specific application. For example, a foaming agent, such as a surfactant or chemically active foaming agent, may be added in the water and/or the slurry to cause foam during stirring of the water and/or slurry. Adding a foam may result in a shorter drying time and/or a more preferable distribution of the porosity than a process that would produce a wallboard with an equivalent density by merely increasing the amount of water. Alternatively, a low density filler may be added. [0036] The process may be a continuous process, whereby the dry ingredients are mixed, added to the water, blended into a slurry and the slurry is poured onto a moving surface to form the wallboard core. A form may both contain the slurry and form the two edges of the wallboard, while one or more rolls or restrictions spread and flatten the free surface of the slurry, whereby an elongated, continuous sheet is formed. Following forming of the continuous wallboard core, the end of the elongated sheet of slurry, after being allowed to set at least partially, is cut into lengths from the rest of the elongated, continuous sheet. Then, the wallboard is trimmed if necessary and dried. Alternatively, one or more facing sheets may be added during the process on one or both sides of the wallboard core. [0037] Another method of producing the wall board mixes a strengthening additive with the water before mixing with the powdered P- calcium sulfate hemihydrate. In this method, the additive, whether dry, paste, gel or liquid, is at least partially dissolved in the water. Then, the dry ingredients, including the ß-calcium sulfate hemihydrate and optionally other dry additional additives, are added to and mixed with the aqueous solution to form a slurry. The slurry is then processed as before. [0038] One or more paper layers may be adhered to one or both sides of the wallboard core or facing sheets, for example for decorative purposes and/or to impart improved strength. The paper may have fibers, which may be oriented to strengthen the wallboard in a preferred direction. Alternatively, no paper layers may be added or a non-paper layer may be adhered to one or both sides of the wallboard core. In yet another alternative, a second additive may be included in the dry ingredients that segregates to one or both surfaces of the wallboard, forming an in situ surface layer on the wallboard. [0039] "At least about" 100 cps means that cellulose ether should be selected from cellulose ethers having a viscosity grade of about 100 cps or greater, and "about" 100 cps should be understood to take into consideration normal variations in commercial measurements of the viscosity grade, based for example on the use of different measurement techniques. For example, differing selection of shear rate for measuring viscosity grade may cause variations in the measured value. A. variation of as much as 30% from the viscosity grade reported by manufacturers is to be expected at low viscosity grades up to 1000 cps. Viscosity grades greater than about 1000 cps show an even greater variation in the viscosity grade. [0040] "At least about" 20,000 MW means that cellulose ether should be selected from cellulose ethers having a molecular weight of "about" 20,000 or greater. It should be understood that the mean value of the molecular weight for a specific type of commercial cellulose ether with a specific degree of substitution may be 20,000, but that variations between batches and variations within a batch allow for significant commercial variances in the mean and standard deviation from the mean of the molecular weight. Typically, the mean molecular weight may vary by as much as 20% from the manufacturer's specification. The standard deviation within a batch depends, for example, on manufacturing tolerances, the process chosen to manufacture a particular cellulose ether, and the variations already present in the raw cellulose prior to substitution. [0041] A nail pull index and flexural strength index are presented herein that normalize the measurements of nail pull resistance and flexural strength for wallboard and ceiling board specimens having a spectrum of board weights by comparing the strength measurements to the strength of specimens prepared without a strengthening additive at the same wallboard weight and thickness. For example, the nail pull resistance versus board weight for conventional wallboard is shown in Fig. 3 for specimens with and without paper. The nail putt index, as shown in Fig. 5 for some embodiments, is a comparative measure nail pull resistance of a reinforced specimen to a conventional specimen at the same density (board weight). Therefore, a nail pull index of 1.0 means that a reinforced wallboard specimen has the same nail pull resistance as a specimen prepared conventionally without reinforcing additions. /ACCOMPANYING BRIEF DESCRIPTION OF THF/DRAWINGS [0042] Fig. 1 shows the improvement in nail pull resistance of several embodiments of the present invention at a concentration of 1g of additive / 100 g ß-calcium sulfate hemihydrate. [0043} Fig. 2 shows the improvement in flexural strength of the same embodiments as shown in Fig. 1. [0044] Fig. 3 shows the nail pull resistance versus board weight of wallboard specimens prepared according to the prior art. [0045] Fig. 4 shows a minimum board weight to satisfy ASTM Standard C473-95 for a Vz inch thick wallboard versus nail pull index for papered and non-papered wallboard. [0046] Fig. 5 shows the nail pull index versus weight fraction for several embodiments of the present invention. [0047] Fig. 6 shows the nail pull index versus weight fraction for several low viscosity cellulose ethers. [0048] Fig. 7 shows the nail pull index versus viscosity grade for HPMC at a weight fraction of lg of HPMC per 100 g ß-calcium sulfate hemihydrate with and without a paper backing. [0049] Fig. 8 shows the minimum board weight versus viscosity grade for HPMC at a weight fraction of lg of HPMC per 100 g p-calcium sulfate hemihydrate with and without a paper backing. [0050] Fig. 9 shows the nail pull index versus patty diameter (an indicator of the viscosity that decreases with increasing viscosity) for HPMC. [0051] Fig. 10 shows the nail pull index versus weight fraction for several embodiments of the present invention having treated surfaces to delay dissolution. [0052] Fig. 11 shows the nail pull index versus weight fraction for four alternative embodiments comprising a paperless wallboard and a HPMC strengthening additive. [0053] Fig. 12 shows the flexural strength index versus weight fraction for the same four embodiments as shown in Fig. 11. [0054] Fig. 13 shows the nail pull index versus weight fraction for two alternative embodiments of a HEC reinforced wallboard or ceiling board. [0055] 4 Fig. 14 shows the data and a correlation for the nail pull index versus viscosity grade for another embodiment comprising a paperless MC-reinforced wallboard. [0056] 5 Fig. 15 shows the data and a correlation for the nail pull index versus viscosity grade for another embodiment comprising a paperless HPMC-reinforced wallboard. [0057] Fig. 16 shows the chemical formula for cellulose. [0058] Fig. 17 shows the chemical formula of a methyl cellulose. [0059] Fig. 18 shows the chemical formula of a hydroxypropyl methyl cellulose. \|0060] Figs. 19 and 20, based on a correlation with data, show graphically the calculated effect of percent substitution of methyl groups in methyl cellulose on the nail pull index and flexural strength index for various viscosity grades and weight percent additions of methyl cellulose. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0061] A reinforced wallboard and/or ceiling board comprises a calcium sulfate hemihydrate, a reinforcing additive and water. The calcium sulfate hemihydrate is preferably ß-calcium sulfate hemihydrate and may be produced by calcining gypsum, for example. The reinforcing additive is dispersable in water and may be produced and used in various forms, such as aqueous solutions, granules and powders. For example, one reinforcing additive is a cellulose ether. Cellulose ethers may be used with a wide variety of substituent groups. For example, HPC, HEC, MC, HPMC, EHEC, EHPC and HEMC may be used as the reinforcing additive. [0062] In one embodiment, dry ß- calcium sulfate hemihydrate powder and powdered HPMC are mixed together, dispersing the powdered HPMC additive throughout the P-calcium sulfate hemihydrate powder. The dry ingredients are then added to water, including an excess of water beyond that required to hydrate the ß-calcium sulfate hemihydrate stoichiometrically, forming a slurry by stirring of the powder/water mixture. For example, the amount of water used is selected such that the finished wallboard has a density less than 0.8 g/cc, more preferably less than 0.75 g/cc. Then, the slurry is extruded through a die or a form or a series of dies and forms. The extruded slurry is then fed onto a belt into a continuous sheet. The slurry is allowed to harden, which is also referred to as setting and is a result of the P-calcium sulfate hemihydrate at least partially dissolving and hydrating, forming calcium sulfate dihydrate crystals, referred to herein as gypsum crystals. [0063] Then, the setting wallboard or wallboard specimen is dried. Air drying or drying in a furnace evaporates the excess water that has not reacted during hydration, but that is required to form a slurry. Excess water also tends to increase the amount of porosity dried wallboard core, because the evaporation of the excess water leaves behind porous microstructure. The sheets may then be trimmed, sized, weighed and tested. [0064] Tests include measuring the nail pull resistance, flexural strength, humidified deflection, mold resistance, and inflamability, for example using ASTM standard test procedures. Mold resistance is defined as showing no signs of mold growth on a wallboard or wallboard core surface after 24 days of exposure to mold spores within an environment maintained at 90% humidity and a temperature of 32 °C. [0065] Preferably, the cellulose ethers used as additives to the wallboard slurry have a high molecular weight, which is associated with a high viscosity grade. Surprisingly, both nail pull resistance and flexural strength are greatly increased for specific cellulose ethers at particular molecular weights and viscosity grades, as shown in Figs. 1 and 2. Also, it is very surprising that both nail pull index and flexural strength index increase rapidly with increasing molecular weight and viscosity grade for some cellulose ethers, for example as shown in Figs. 7 and 15. This contradicts the earlier expectations of others in the field that relied on data from specimens prepared using stucco slurries using relatively low molecular weight additives, slurries of CMC, which do not show increasing nail pull resistance with weight fractions above about 0.25 wt%, and slurries prepared using processing methods that did not effectively disperse the cellulose ether powders. Furthermore, the present invention contradicts those references that indicated that high viscosity grades would weaken the gypsum crystal strength. [0066] Specimens of high molecular weight and high viscosity grade HPMC reinforced wallboard and HEMC reinforced wallboard have the greatest value of nail pull index of those tested, as shown in Fig. 1. Other embodiments show greatly improved nail pull index, as well, especially using high viscosity grade cellulose ethers. [0067] However, the results for low molecular weight cellulose ethers was disappointing, as shown in Fig. 6 and 14. As concentration of the cellulose ethers increased, the nail pull resistance decreased for low molecular weight cellulose ethers. Degradation of important properties with continued addition of an additive is highly disfavored in commercial processing, especially for an additive with a low overall weight fraction compared to other ingredients. [0068] During a mixing process, increasing the weight fraction of the additive in the mixture is accomplished by merely adding more of the additive to a batch or continuous stream of the mixture. However, it is problematic to dilute the weight fraction of additive once too much additive is mixed with the base material, because it requires mixing large quantities of the base material, in this case ß-calcium sulfate hemihydrate, into a mixture of additive and base material to dilute the weight fraction of additive. Thus, it is desirable for a robust mixing process to be able to allow an excess of additive without adversely affecting the properties of the finished product. Therefore, using an additive that continuously improves the properties of the product even with an inadvertent addition of excess additive is preferred. Even though the low molecular weight additives initially increase the nail pull resistance up to 0.25 wt%, the sharp decrease in properties with continued addition over a percent weight of 0.25 wt% makes them impractical for use in many commercial processes. [0069] Fig. 5 shows that for high molecular weight and high viscosity HPMC, HEMC, and HEC, the nail pull resistance increases logarithmically with the weight fraction of additive. This is a highly desirable trend, making for a robust and forgiving manufacturing process. 400 cps MC shows a linear increase in nail pull resistance with weight fraction of additive, which is also desirable. [0070] CMC is one of the most commonly used cellulose ethers, but, in the absence of other cellulose ethers, CMC greatly retards setting time and reduces nail pull resistance and flexural strength compared to unreinforced specimens. As mentioned previously CMC does not increase the strength of wallboard at the concentrations, high molecular weights and viscosities that are effective for the other cellulose ethers. It is believed, without being limiting in any way, that other cellulose ethers tend to have molecular interactions via hydrogen bonding. Thus, it is believed that the high molecular weight molecules tend to be immobilized and do not segregate to the drying surfaces of the wallboard, as some other soluble polymers do. Therefore, high molecular weight molecules, having substantial hydrogen bonding interactions, remain dispersed throughout the wallboard core and reinforce the matrix of hydrated gypsum crystals. [0071] A surface treatment may coat the cellulose ethers to delay the onset of dissolution, which would be expected to improve dispersion of the cellulose ethers in water. However, it is believed that, in practice, the delay in dissolution caused by the surface treatment results in incomplete dissolution of the surface treated cellulose ethers. Iodine stain tests showed that cellulose ethers that were surface treated did not disperse evenly throughout the wallboard specimen, especially for HEC surface-treated powders, while both untreated cellulose ethers and surface treated cellulose ethers that were pre-dissolved showed complete and even dispersion throughout the wallboard. One method of improving dispersion of untreated and surface-treated powdered cellulose ethers was to pre-mix the dry cellulose ethers until the powders were well dispersed with the dry ß-calcium sulfate hemihydrate before adding the mixture to water. Thereby, the agglomeration of the cellulose ethers was reduced and dissolution occurred more readily than for agglomerated particles. [00721 The nail pull index of surface treated cellulose ethers was less than the nail pull index of either pre-dissolved, surface treated cellulose ethers or untreated cellulose ethers, as shown in Figs. 1 and 2, and as shown against weight fraction, for example in Fig. 11 for HPMC with a viscosity grade of 45,000 cps (45 kcps) and in Fig. 13 for HEC with a molecular weight of 1.3 million (1.3M). [0073] The ftexural strength is not affected as greatly by incomplete dissolution, as shown versus weight fraction in Fig. 12 for HPMC at 45 kcps. It is believed that the difference between the effects in nail pull index and flexural strength index is due to the fact that nail pull index is sensitive to crushing of the specimen core, while the flexural strength index is less sensitive to crushing of the specimen of the core (distributed stresses). [0074] Fig. 8 shows the minimum board weight projected for meeting ASTM standards versus viscosity grade of wallboard specimens prepared with a weight percent of HPMC additive to ß-calcium sulfate hemihydrate of 1 wt%. As the viscosity grade increases the minimum board weight that is required to pass ASTM standards decreases. It should be understood that any additional reinforcements, such as fiber reinforcements, that are added to the slurry can also increase the strength, particularly the flexural strength, of the wallboard. This would also tend to reduce the minimum board weight required to pass ASTM standards. For example, it is common practice to incorporate cellulose fibers into the wallboard core. Other fiber reinforcements, such as glass, polymer and carbon fibers, may also be added to increase the flexural strength of the wallboard core. In one specific embodiment, short polyester fibers or nylon fibers or both are mixed into the dry ingredients prior to adding the dry ingredients to water to increase the flexural strength. Longer fibers can be introduced during extrusion to provide the core with oriented strengthening along the longitudinal direction of the wallboard. {00751 Slurry viscosity is a major concern in high speed wallboard production. Increased viscosity can lead to increased mixing and pumping demands, clogged machinery, and problems with board formation. Slurry viscosity is of even greater importance when selecting a CE additive because the primary purpose of CEs in conventional plaster formulations is to thicken the mixture. [00761 In order to fully hydrate the P-calcium sulfate hemihydrate and prepare a slurry that can be mixed and extruded, a greater amount of water is used than is used for plaster compounds, which use hydration of a-calcium sulfate hemihydrate to form gypsum. It is known that the amount of water added to the slurry has a profound effect on the quality and microstructure of the resulting wallboard. It is believed, without limiting the invention in any way, that addition of too little water prevents adequate mixing of the slurry, while too much water causes undesired porosity in the wallboard core. There can be a dramatic increase in viscosity with the addition of CEs, especially in formulations with elevated levels of high viscosity CE, which can make it difficult to adequately mix the dry ingredients and the water. Furthermore, an increase in viscosity can prevent the slurry from being poured into a form. One simple test that can be used to determine slurry viscosity is a "patty test" in which some amount of slurry is poured from a designated height and the resulting patty diameter is recorded. Furthermore, the rheology of wallboard slurry is a function of time, humidity and temperature. [0077} In general, the patty size increases inversely with an increase in the viscosity grade of a cellulose ether. As expected, the patty diameter increases with decreasing viscosity grade for HPMC In fact, patty diameter increases logarithmically with the inverse of viscosity grade; therefore, the nail pull index increases proportionally with the inverse of patty size, as shown in Fig. 9. [0078] In one embodiment, a slurry was formed by mixing p-calcium sulfate hemihydrate with less than 5 wt% of a powdered cellulose ether, such that the cellulose ether was evenly dispersed throughout the mixture. The mixture was then mixed with an amount of water to form a slurry, such that the wallboard core had a density of less than 0.8 g/cc upon drying. In an alternative embodiment, the cellulose ether was selected to have a molecular weight of at least 20,000 and a viscosity grade of at least 100 cps, and both the nail pull resistance and flexural strength were improved compared to unreinforced wallboard. In another embodiment, the amount of powdered cellulose ether was limited to a range of 0.5 wt% to 3 wt%, and the measured nail pull index continuously increased with addition of powdered cellulose ether. [0079] In yet another embodiment, the DS is limited to a range between 1.2 and 2.4 for a MC. In an alternative embodiment, the DS is limited to a range from 1.6 and 1.9 for a MC, having a viscosity grade of at least 10 cps, producing wallboard with improved nail pull index for viscosity grades of at least 100 cps, as shown in Figs. 14 and 15, for example. Fig. 14 shows a graph of nail pull index versus MC viscosity grade with 0.25,0.5,1.0, and 2.0 wt% of MC mixed with powdered p-calcium sulfate hemihydrate. The darker lines and point are the values calculated using a correlation, which is discussed elsewhere, while the lighter lines are the experimental values. Fig. 15 is a similar graph for HPMC mixed with powdered ß-calcium sulfate hemihydrate. In another alternative embodiment, a DS range from 1,2 to 1.6 for a MC, greatly increases the flexural strength index and increases the nail pull index for MC additions at a weight percent of 0.25 and 0.5 wt%, as shown in Fig. 19, which is based on the correlation used in Fig. 14. Fig. 20 shows that this trend applies also to higher weight percent additions of MC. This shows that increasing nail pull resistance occurs for wallboard processed using a MC with low DS, high viscosity grade and high molecular weight, high weight percent or a combination of these. [0080] It is believed, without being limiting in any way, that hydrogen-bonding interactions immobilize the cellulose ether molecules, and the degree of hydrogen bonding is affected by molecular weight and is reflected in the viscosity grade. It is also affected by the degree of substitution. Thus, degree of substitution, viscosity grade and molecular weight of the cellulose ether are critical factors in selecting a specific cellulose ether as a strengthening additive, because it is believed that the strength of the wallboard depends on the distribution of cellulose ether molecules in the wallboard core and bonding interactions among the molecules. Furthermore, it is believed that the effect of bonding interactions depends on both the degree of substitution and the weight percent of the addition. [0081] The percent substitution of specific cellulose ethers, which were used as reinforcing additives, were analyzed in accordance with standard test method ASTM D 3876, which is incorporated by reference herein in its entirety. ASTM D 3876 determines methoxyl and hydroxypropyl substitution in cellulose ether products by gas chromatography. The resolved substitution percentages of the various cellulose ethers, along with the viscosity grades taken from the literature, were compared to the mechanical testing results to determine the effect of the degree of substitution on flexural strength and nail pull resistance. Based on these empirical measurements, correlations were developed that relate the nail pull index and the flexural strength index to cellulose ether substitution pattern. The following regression models established the best correlation: These empirical correlations are useful in defining the effect of each of the weight percentage of cellulose ether (f), the degree or percent of substitution of the methyl (M) and hydoxypropyl (H) groups, and the viscosity grade (y) on the nail pull index and flexural strength index of wallboard core reinforced by MC and HPMC. [0082] Specifically, there is a correlation of the amount of cellulose ether additive in the wallboard core and the nail pull index and flexural strength index. As expected, the nail pull resistance increases with increasing weight percent of additive. There is also a correlation with viscosity grade. Surprisingly, the data shows that increasing viscosity grade increases the nail pull index for HPMC and MC, which was not reflected in the literature or in some of the Taw data, for example, as shown in Fig. 14 for MC. [0083] Finally, there is a very surprising and unexpected correlation with the percent substitution. Specifically, the nail pull index increases with decreasing degree of substitution (DS), as show in Figs. 19 and 20 for MC, for example. This unexpected and surprisingly strong correlation is sufficient to cause the dramatic dip in the nail pull index versus viscosity grade curve as shown in Fig. 14, for example. In Fig. 14, the commercially available MC had a percent substitution of methyl groups of 34%. Furthermore, this effect has gone unnoticed by others, which has probably discouraged others from adding cellulose ethers to wallboard as a strengthening additive. Specifically, the DS is often not reported for commercial cellulose ethers. If reported, it is often highly inaccurate. Thus, to perform this analysis, it was necessary to independently measure the percent substitution by gas chromatography. In the range of weight percent most practical for wallboard, e.g. less than 5 wt%, more preferably less than 3 wt%, even moderate increases in DS dramatically decrease the measured flexural strength index of wallboard compared to lower DS, as shown in Figs. 19 and 20. [0084] For low viscosity grade cellulose ethers, the difference in the measured index of nail pull and flexural strength is often the difference between a decrease compared to no reinforcement in the wallboard and a dramatic increase compared to no reinforcement, as shown in Figs. 19 and 20. Furthermore, commercially available cellulose ethers typically have relatively high values of DS, as compared to the DS associated with the limit in solubility of the cellulose ethers. Thus, it is not surprising that cellulose ethers have been overlooked as an additive for strengthening p-calcium sulfate hemihydrate based wallboard products. Indeed, the most promising cellulose ethers, for example MC with a DS in the range from 1.2 to 1.6, have not been readily available for testing as strengthening additives. [0085] The HPMC nail pull performance correlation exhibits a different relationship with methoxyl substitution percentage, which has a much lower range in commercially available HPMC than in commercially available MC. At low additive levels, decreasing methyl DS does increase the nail pull index; however, at higher additive levels reducing the methyl DS is less effective, according to the correlations. This trend is affected somewhat by the choice of viscosity grade and by hydroxypropyl substitution percentage. However, given the data currently available, the degree of hydroxypropyl substitution does not influence the nail pull index as dramatically as methoxyl substitution in MC. These effects are reflected in the scattered data of Fig. 15. [0086] In another alternative embodiment, a foam may be produced to further reduce the density of the wallboard core. This foam may be produced, for example, using a surfactant and stirring of the water and/or slurry to generate a foam, which may be incorporated into the extruded wallboard core. SPECIFIC EXAMPLES [0087] Control Sample. One hundred grams of ß-calcium sulfate hemihydrate was dry mixed with 0.13g ground gypsum accelerator. The ß- calcium sulfate hemihydrate was then added to 150 g of room-temperature tap water in a 500 mL Waring blender. The slurry was blended at low speed for 15 seconds. The slurry was then immediately poured into an approximately 7" x 2" x 1/2" mold. After about 20 minutes, the sample was removed from the mold and placed in a convection oven at 45 °C in which it was dried for at least 36 hrs. After removal from the oven, the sample was cut to 5" x 2" and massed and dimensioned. This data was used to calculate sample density. The flexural strength was attained using a three-point-bend test similar to the ASTM C473 flexural strength test (method B) for gypsum wallboard. An Instron mechanical testing system with data acquisition software was used to determine mechanical behavior. The flexural failure stress was calculated from the failure load, testing configuration, and sample geometry. The two half samples remaining from the bending test were tested for resistance to nail pull. A nail pull test based on ASTM C473 nail pull test (method B) was used. The resulting sample had a density of 0.63 g/cc, a flexural strength of 242 psi, and a nail pull resistance of 46 lbs. {0088] High Viscosity HPMC Enhancing Agent; Paperless Sample. One hundred grams of ß-calcium sulfate hemihydrate was dry mixed with 0.13 g ground gypsum accelerator and 1 g HPMC (100 kcps purchased from Aldrich Chemical Co.). The dry mixture was then added to 150 g of tap water in a 500 mL Waring blender. The slurry was blended at low speed for 15 seconds. The slurry was then immediately poured into a 7" x 2" x 1/2" mold where it set for about 20 minutes before being removed. The sample was placed in a convection oven at 45 °C for at least 36 hrs. After removal from the oven, the sample was cut to 5" long, massed, and dimensioned. The density was calculated and the sample was tested for flexural strength and nail pull resistance on an Instron mechanical testing system. The sample had a density of 0.46 g/cc, a flexural strength of 299 psi, and a nail pull resistance of 43 lbs. (0089] High Viscosity, RETARDED HEMC Enhancing Agent; Paperless Sample. One hundred grams of P-calcium sulfate hemihydrate was dry mixed with 0.13g ground gypsum and 1g of retarded HEMC (15-20, 5 kcps, purchased from Aidrich Chemical Co.). The dry mixture was then added to 150 g of tap water in a 500 mL Waring blender. The slurry was blended at low speed for 15 seconds. The slurry was then immediately poured into a 7" x 2" x 1/2" mold and, after 20 minutes, removed. The sample was placed in a convection oven at 45 °C for at least 36 hrs. After removal from the oven, the sample was cut to 5" long, massed, and dimensioned. The density was calculated and the sample was tested for flexural strength and nail pull resistance on an Instron mechanical testing system. The resulting sample had a density of 0.63 g/cc, a flexural strength of 545 psi, and a nail pull resistance of 78 lbs. [0090] High Viscosity HPMC Enhancing Agent; Lightweight Wallboard. A papered sample was prepared by mixing 1 kg of P-calcium sulfate hemihydrate with 1.3 g ground gypsum and 10 g of HPMC (22 kcps, purchased from Aldrich Chemical Co.). To a 5 liter Waring blending container was added 1.5 kg of room-temperature tap water, 20 drops of Daxad 19LKN (dispersant) from Dow, and 10 drops of a 40% solution of diethylenetriaminepentaacetic acid sodium salt (retarder). The powder was added to the water and blended on high for 15 seconds. The slurry was then poured into an approximately 12" x 12" x 1/2" mold lined with an envelope made of standard decorative wallboard facing paper. The sample was removed from the mold after 15 minutes and placed in a 45 °C convection oven for 48 hrs. The sample was then removed and cut into 5" x 2" and 9" x 2" specimens, with the long dimension in the direction of the fibers of the paper. These specimens were then massed and measured. The density was calculated and the specimens were tested for flexural strength in the fiber direction and nail pull resistance on an Instron mechanical testing system. The sample had a density of 0.47 g/cc, a flexural strength of 822 psi, and a nail pull resistance of 75 lbs. [0091] MC with 1:1 water:ß-calcium sulfate hemihydrate ratio by weight. 100 parts of P-calcium sulfate hemihydrate was mixed with 9 parts of methyl cellulose (Aldrich, MW 17,000, viscosity grade 25 cps). The mixture was then added to 100 parts of water at room temperature and blended at a high shear setting for approximately 15 seconds. The resulting slurry was highly viscous, failing to pour into the form. A spatula was used to transfer, in small portions, enough slurry to be pressed into a form measuring 2 inches by 5 inches by 0.5 inches. After setting, the mixture was removed from the mold and cured at 45 °C for 2 days. The resulting sample has a density of 0.72 g/cc, a nail pull index of 1.87 (121 lbs.) and flexural strength of 881 lb/in2. [0092] MC with 1:1 water ß-calcium sulfate hemihydrate ratio by weight. 100 parts of P-calcium sulfate hemihydrate was mixed with 9 parts of methyl cellulose (Aldrich, MW 14,000, viscosity grade 15 cps). The mixture was then added to 100 parts of water and blended at high shear setting for approximately 15 seconds. The resulting slurry was highly viscous, failing to pour into the form. A spatula was used to transfer, in small portions, enough slurry to be pressed into a from measuring 2 inches by 5 inches by 0.5 inches. After setting, the mixture was removed from the mold and cured at 45 °C for 2 days. The resulting sample had a density of 0.74 g/cc, a nail pull index of 1.75 (119 lbs.) and flexural strength of 864 lb/in2. [0093] MC with 1:1 water:ß-calcium sulfate hemihydrate ratio by weight. 100 parts of P-calcium sulfate hemihydrate was mixed with 9 parts of methyl cellulose (Aldrich, MW 40,000, viscosity grade 400 cps). The mixture was then added to 100 parts of water and blended at a high shear setting. The viscosity was exceedingly high and mixing was not possible for the desired 15 second duration. The powdered mixture was not fully incorporated into the slurry. The mixture prematurely set and could not be transferred to a form. [0094] MC with 1:1 water: ß-calcium sulfate hemihydrate ratio by weight. A subsequent specimen was prepared by reducing the amount of methyl cellulose by mixing 100 parts of P-calcium sulfate hemihydrate with 5 parts methyl cellulose instead of 9 parts methyl cellulose. The mixture was then added to 100 parts of water and blended at high shear setting for approximately 15 seconds. The resulting slurry was extremely viscous, beginning to set prematurely during mixing and failing to pour into the form. A spatula was used to transfer, in small portions, enough slurry to be pressed into a form measuring 2 inches by 5 inches by 0.5 inches. After setting, the mixture was removed from the mold and cured at 45 °C for 2 days. The resulting sample had a density of 0.73 g/cc, a nail pull index of 1.54 (103 lbs.) and a flexural strength of 766 lbs./in2. [0095] Low Viscosity Grade HPMC with 1:1 water: ß-calcium sulfate hemihydrate ratio by weight. 100 parts of ß-calcium sulfate hemihydrate was mixed with 9 parts of HPMC (Aldrich, MW 10,000, viscosity grade 5 cps). The mixture was then added to 100 parts of water and blended at high shear setting for approximately 15 seconds. The resulting slurry poured directly into a form measuring 2 inches by 5 inches by 0.5 inches. After setting, the mixture was removed from the mold and cured at 45 °C for 2 days. The resulting sample had a density of 0.63 g/cc, a nail pull index of 1.26 (58 lbs.) and a flexural strength of 675 lb/in2. [0096] Low Viscosity Grade HPMC with 1:1 water: ß-calcium sulfate hemihydrate ratio by weight. 100 parts of P-calcium sulfate hemihydrate was mixed with 9 parts of HPMC (Aldrich, MW 10,000, viscosity grade 6 cps). The mixture was then added to 100 parts of water and blended at high shear setting for approximately 15 seconds. The resulting slurry poured directly into a form measuring 2 inches by 5 inches by 0.5 inches. After setting, the mixture was removed from the mold and cured at 45 °C for 2 days. The resulting sample had a density of 0.59 g/cc, a nail pull index of 1.18 (47 lbs.) and a flexural strength of 535 lb/in2. [0097] Moderate Range Viscosity Grade HPMC with a water: ß- calcium sulfate hemihydrate ratio of 1.0 by weight. First, 100 parts of ß-calcium sulfate hemihydrate was mixed with 9 parts of HPMC (Aldrich, MW 12,000, viscosity grade 80-120 cps). The mixture was then added to 100 parts of water and blended at high shear setting for approximately 15 seconds. The resulting slurry was exceedingly viscous, prematurely setting during mixing and failing to pour into the form. A spatula was used to transfer, in small portions, enough slurry to fill a form measuring 2 inches by 5 inches by 0.5 inches. After setting, the mixture was removed from the mold and cured at 45 °C for 2 days. The resulting sample had a density of 0.75 g/cc, a nail pull index of 1.54 (121 lbs.) and a flexural strength of 652 lb/in2. [0098] High viscosity, surface-treated HEMC. A paperless sample was prepared by mixing 1.3 kg of P-calcium sulfate hemihydrate with 1.69 g ball mill ground gypsum (accelerator) and 26 g of retarded HEMC (viscosity grade of 15-20.5 kcps at 2 wt%, purchased from Aldrich Chemical Co.). The liquid components, 1.68 kg room temperature tap water, 26 drops Daxad 19LKN (dispersant) from Dow, and 13 drops 40% solution of diethylenetriaminepentacetic acid sodium salt (retarder), were added to a 5 liter Waring blender. The dry ingredients were added to the water and blended on high for 15 seconds, forming a slurry. The slurry was then poured into an approximately 12" x 12" x 1/2" glass mold with a thin teflon sheet on one face to facilitate removal. The sample was removed from the mold after 15 minutes and placed in a 45°C convection oven for 48 hrs. The sample was then removed and cut into 5" x 2" specimens. These specimens were then weighed and measured. The densities of nine specimens were calculated and the specimens were tested for flexural strength and nail pull resistance on an Instron Mechanical testing system using the methods previously described. The board had an average density of 0.64 g/cc, a flexural strength of 809 psi, and a nail pull resistance of 102 lbs., passing ASTM flexural strength and nail pull requirements. [0099] High viscosity, surface-treated HEMC. A paperless sample was prepared by mixing 100 g of p-calcium sulfate hemihydrate with 0.13 g ball mill ground gypsum (accelerator) and 1 g of retarded HEMC (viscosity grade of 15-20.5 kcps at 2 wt%, purchased from Aldrich Chemical Co.). The mixture was then added to 150 g of water and blended on high for 15 seconds, forming a slurry. The slurry was then poured into an approximately 7" x 2" x 1/2" mold. The sample was removed from the mold after 15 minutes and placed in a 45°C convection oven for 48 hrs. The sample was then removed and cut to 5" x 2". The density of sample was calculated and it was tested for flexural strength and nail pull resistance on an Instron mechanical testing system using the methods previously described. The wallboard specimen had an average density of 0.63 g/cc, a flexural strength of 545 psi, and a nail pull resistance of 78 lbs., passing the ASTM nail pull requirement. [0100] High-viscosity, surface-treated HEMC. A paperless wallboard is prepared using the following procedure. First, 150 g of ß-calcium sulfate hemihydrate is dry mixed with 0.2 g ground gypsum and 3 g of surface-treated (retarded dissolution) HEMC (15-20.5 kcps, purchased from Aldrich Chemical Co.). The dry ingredients are added to 162 g of tap water in a 500mL Waring blender, forming a slurry. The slurry is blended at low speed for 15 seconds. The slurry is then immediately poured into a 7" x 2" x lA" mold and, after 20 minutes, removed. The wallboard specimen is placed in a convection oven at 45 °C for at least 36 hrs for drying. After removal from the oven, the sample is trimmed to 5" long, weighed and dimensioned. A specimen prepared according to this procedure had a density of 0.80 g/cc, a flexural strength of 975 psi, and a nail pull resistance of 180 lbs., exceeding ASTM standards for flexural strength and nail pull resistance for '/i-inch wallboard. [0101] High viscosity, surface-treated HEMC. A paperless wallboard is prepared using the following procedure. First, 150 grams of ß-calcium sulfate hemihydrate is dry mixed with 0.2 g ground gypsum and 3 g of surface-treated HEMC (15-20.5 kcps, purchased from Aldrich Chemical Co.). The dry ingredients are then added to 150 g of tap water in a 500mL Waring blender, forming a slurry. The slurry is blended at low speed for 15 seconds. The slurry is then immediately poured into a 7" x 2" x 14" mold and, after 20 minutes, removed. The wallboard specimen is placed in a convection oven at 45 °C for at least 36 hrs for drying. After removal from the oven, the specimen is cut to 5" long, weighed and dimensioned. A specimen prepared according to the foregoing procedure had a density of 0.85 g/cc, a flexural strength of 989 psi, and a nail pull resistance of 203 lbs., exceeding the ASTM standards for flexural strength and nail pull resistance for 1/2-inch wallboard. [0102] Although the present invention has been described in relation to particular embodiments thereof, many other variations and modifications and other uses will become apparent to those skilled in the art. It is preferred, therefore, that the present invention be limited not by the specific disclosure herein, but only by the appended claims. -34- WE CLAIM: 1. A reinforced wallboard core comprising : water; and dry ingredients, wherein the dry ingredients comprise p-calcium sulfate hemihydrate powder and a powdered additive and the dry ingredients are mixed together and mixed with the water, forming a slurry and hydrating the P-calcium sulfate hemihydrate powder, wherein the powdered additive is of a cellulose ether other than carboxymethyl cellulose, and the cellulose ether is selected to have both a viscosity grade of at least about 100 cps and a molecular weight of at least about 20,000, the average density of the wallboard core being less than 0.8 g/cc, when dried. 2. The wallboard core as claimed in claim 1, wherein the cellulose ether is a hydroxypropyl cellulose, a hydroxyethyl cellulose, a methyl cellulose, a hydroxypropyl methyl cellulose, a ethyl hydroxyethyl cellulose, a ethyl hydroxypropyl cellulose or a hydroxyethyl methyl cellulose. 3. The wallboard core core of claim 1 as claimed in claim 1 wherein the cellulose ether is a .hydroxypropyl methyl cellulose. 4. The wallboard core as claimed in claim 1, wherein the cellulose ether is a hydroxyethyl methyl cellulose. 5. The wallboard core as claimed in claim 1, wherein the cellulose ether is a hydroxyethyl cellulose. -35- 6. The wallboard core as claimed in claim 1, wherein the wallboard core comprises substantially no clay. 7. The wallboard core as claimed in claim 4, wherein the wallboard core comprises substantially no clay. 8. The wallboard core as claimed in claim 1, wherein the cellulose ether is a methyl cellulose. 9. The wallboard core as claimed in claim 8, wherein the methyl cellulose, is selected to have a viscosity grade of at least about 400 cps. 10. The wallboard core as claimed in claim 1, wherein the amount of water to dry ingredients is selected such that the average density of the wallboard core is less than 0.75 g/cc. 11. The wallboard core as claimed in claim 10, wherein the mixing causes dispersion of the powdered additive throughout the ß-calcium sulfate hemihydrate powder, whereby the powdered additive is evenly dispersed in the wallboard core. 12. The wallboard core as claimed in claim 10,wherein the density of the wallboard core is in a range from 0.45 g/cc to 0.7 g/cc. 13. The wallboard core as claimed in claim 1, wherein the percent weight of additive to the P- calcium sulfate hemihydrate powder is at least 0.5 wt %. -36- 14. The wallboard core as claimed in claim 13, wherein the additive is selected, and the amount of additive is selected, such that an addition of additive continuously increases the nail pull resistance of the wallboard core. 15. The wallboard core as claimed in claim 13, wherein the percent weight of additive to the ß- calcium sulfate hemihydrate powder is selected to be no greater than 3 wt %. 16. The wallboard core as claimed in claim 1, wherein the degree of substitution of the cellulose ether is less than 1.8. 17. The wallboard core as claimed in claim 1, wherein the additive is surface treated to delay dissolution. 18. A wallboard core comprising a ß-calcium sulfate hemihydrate powder and an aqueous additive solution, wherein the ß-calcium sulfate hemihydrate powder is mixed with the aqueous solution, forming a slurry and hydrating the ß-calcium sulfate hemihydrate powder, wherein the aqueous additive solution comprises water and an additive dissolved in the water and the additive is of a cellulose ether other than CMC, and the cellulose ether is selected to have both a viscosity grade of at least about 100 cps and a molecular weight of at least about 20,000, the amount of water being selected such that the wallboard core has a density less than 0.8 g/cc. 19. The wallboard core as claimed in claim 18, wherein the cellulose ether is a hydroxyethyl cellulose, a methyl cellulose, a hydroxypropyl methyl cellulose, a ethyl hydroxyethyl cellulose, a ethyl hydroxypropyl cellulose or a hydroxyethyl methyl cellulose, and the cellulose ether is selected to have a viscosity grade of at least about 400 cps. 20. The wallboard core as claimed in claim 18, wherein the cellulose ether is a hydroxypropyl methyl cellulose. 21. The wallboard core as claimed in claim 18, wherein the cellulose ether is a hydroxyethyl methyl cellulose. 22. The wallboard core as claimed in claim 18, wherein the cellulose ether is a hydroxyethyl cellulose. 23. The wallboard core as claimed in claim 18, wherein the wallboard has a density in a range from 0.4 g/cc to 0.7 g/cc. 24. The wallboard core as claimed in claim 18, wherein the wallboard comprises substantially no clay. 25. The wallboard core as claimed in claim 18, wherein the cellulose ether is a methyl cellulose having a viscosity grade of at least about 400 cps. -38- 26. The wallboard core as claimed in claim 25, wherein the methyl cellulose has a molecular weight of at least about 40,000. 27. The wallboard core as claimed in claim 25, wherein the amount of water is selected such that the wallboard core has a density less than 0. 75 g/cc. 28. The wallboard core as claimed in claim 18, wherein the cellulose ether is selected to have a viscosity grade less than about 100, 000 cps. 29. The wallboard core as claimed in claim 18, wherein the percent weight of additive to the ß- calcium sulfate hemihydrate powder is at least 0.5 wt %. 30. The wallboard core as claimed in claim 29, wherein the additive is selected, and the amount of additive is selected, such that an addition of additional additive continuously increases the nail pull resistance of the wallboard core. 31. The wallboard core as claimed in claim 29, wherein the percent weight of additive to the ß- calcium sulfate hemihydrate powder is selected to be no greater than 3 wt %. 32. The wallboard core as claimed in claim 31, wherein the additive is selected, and the amount of additive is selected, such that an addition of additional additive continuously increases the nail pull resistance of the wallboard core. 33. A wallboard comprising the wallboard core as claimed in claim 1 and at least one face sheet. 34. The wallboard as claimed in claim 33, wherein the at least one face sheet is paper. 35. The wallboard as claimed in claim 34, wherein the paper is fiber reinforced. 36. The wallboard as claimed in claim 33, wherein the at least one face sheet is a polymer layer. 37. The wallboard as claimed in claim 36, wherein the polymer layer is formed in situ. 38. The wallboard as claimed in claim 33, wherein the at least one face sheet is decorative. 39. A process for making a wallboard core comprising: mixing together a P-calcium sulfate hemihydrate powder and a powdered additive, until the powdered additive is dispersed throughout the p-calcium sulfate hemihydrate powder, wherein the powdered additive is a cellulose ether other than carboxymethyl cellulose and the cellulose ether has a molecular weight of at least about 20,000 and a viscosity grade of at least about 200 cps; adding the mixture of the P-calcium sulfate hemihydrate powder and the powdered additive with an amount of water such that the resulting wallboard core has a density less than 0.8 g/cc; forming a slurry by mixing the mixture of the ß- calcium sulfate hemihydrate powder and the powdered additive with the water; extruding the slurry; shaping the extrudate into an elongated sheet; and allowing the slurry to set, wherein at least a portion of the p-calcium sulfate hemihydrate powder is hydrated. 40. The process as claimed in claim 39. wherein the steps of adding, forming and extruding are continuous. 41. A process for making a wallboard core comprising: dissolving an additive in water to form an aqueous solution, wherein the additive is a cellulose ether other than carboxymethyl cellulose and the cellulose ether has a molecular weight of at least about 20,000 and a viscosity grade of at least about 200 cps; adding an amount of dry ingredients to an amount of the aqueous solution such that the resulting wallboard has a density less than 0.8 g/cc, wherein the dry ingredients include a p-calcium sulfate hemihydrate powder; forming a slurry by mixing the mixture of the P-calcium sulfate hemihydrate powder and the powdered additive with the water; extruding the slurry; shaping the extrudate into an elongated sheet; and allowing the slurry to set, wherein at least a portion of the ß- calcium sulfate hemihydrate powder is hydrated. 42. The process as claimed in claim 41, wherein the steps of adding, forming and extruding are continuous. 43. The wallboard core as claimed in claim 1, wherein the cellulose ether is selected to have both a viscosity grade of at least about 400 cps and a molecular weight of at least about 40,000. 44. The wallboard core as claimed in claim 43, wherein the percent weight of cellulose ether to ß- calcium sulfate hemihydrate is at least 0.5 wl %. 45. The wallboard core as claimed in claim 44, wherein the percent weight fraction of cellulose ether to p-calcium sulfate hemihydrate is less than 3 wt %. -41- 46. The wallboard as claimed in claim 33, wherein the at least one face sheet is a glass mat. 47. The wallboard as claimed in claim 33, wherein the density of the wallboard is in a range from 0.45 g/cc to 0.7 g/cc. 48. The wallboard core as claimed in claim 1, comprising a fiber reinforcement, wherein the fiber reinforcement is mixed with the dry ingredients. 49. The wallboard core as claimed in claim 48, wherein the fiber reinforcement is a cellulose fiber. 50. The wallboard core as claimed in claim 48, wherein the fiber reinforcement is one of a glass fiber, a polymer fiber and a carbon fiber. 51. The wallboard core as claimed in claim 48, wherein the fiber reinforcement is one of a polyester fiber and a nylon fiber. 52. The wallboard core as claimed in claim 48, wherein the fiber reinforcement has an elongated axis and the elongated axis is oriented in the direction of extrusion. 53. The wallboard core as claimed in claim 1, wherein the surface of the wallboard core resists the development of mold, showing no signs of mold growth after 24 days of exposure to mold spores within an environment maintained at 90% humidity and a temperature of 32° C. 54. The wallboard as claimed in claim 33, wherein the surface of the wallboard resists the development of mold, showing no signs of mold growth after 24 days of exposure to mold spores within an environment maintained at 90% humidity and a temperature of 32° C. 55. A reinforced wallboard core comprising : water; and dry ingredients, wherein the dry ingredients comprise ß-calcium sulfate hemihydrate powder and a powdered additive and the dry ingredients are mixed together and mixed with the water, forming a slurry and hydrating the ß- calcium sulfate hemihydrate powder, wherein the powdered additive is of a methyl cellulose, having a degree of substitution in a range from 1.2 to 1.6, the average density of the wallboard core being less than 0.8 g/cc. when dried. A reinforced wallboard core is prepared from a slurry comprising a mixture of ß-calcium sulfate hemihydrate, a cellulose ether additive other than CMC and an amount of water that is sufficient to form a slurry and resulting in a wallboard density of less than 0.8 g/cc. The ß-calcium sulfate hemihydrate is hydrated by the water forming a wallboard core reinforced by the cellulose ether additive. The cellulose ether, having a molecular weight of at least about 20,000 and a viscosity grade of at least 100 cps, is selected to give the reinforced wallboard core improved nail pull resistance and greater flexural strength than unreinforced wallboard of the same density. The reinforced wallboard core may be used for reduced-paper wallboard and / or for lightweight wallboard, for example.

Full Text

REINFORCED WALLBOARD
RELATED APPLICATION
[0001] This application claims the benefit of U.S. Provisional
Application No. 60/425,924, filed November 12,2002, the entire disclosure of
which is incorporated by reference herein.
FIELD OF THE INVENTION
(0002] The field of the invention is wallboards for use in construction,
including paper-covered wallboard, paperless wallboard, sheathing board,
moisture resistant board, type-X board, insulation board, shaft liner, soffit board,
backing board, core board, ceiling board, gypsum glass mat board and a method
of manufacturing such wallboards.
BACKGROUND OF THE INVENTION
[0003] A modified cellulose, also referred to herein as a cellulose
derivative, is used in plaster and joint compounds as a thickener (or to modify the
rheology in some way) and to improve the workability of gypsum-based
compounds. Cellulose ethers have been known to improve some other
properties, including the consistency, adhesion and water retention of gypsum-
based joint compounds and tile adhesives. However, some of these properties,
specifically thickening, are not considered beneficial for the production of
wallboard. Wallboard is formed from a slurry that is continuously mixed and fed
onto a belt. Thus, it is desirable for the slurry used to make wallboard to be
thinner than a plaster.
[0004] Typically, a small amount, e.g. less than 0.25 wt%, of cellulose
ethers is added to the dry ingredients of plaster or joint compound, which may be
limestone-based rather than gypsum-based, prior to mixing with water. This
tends to improve the strength of the plaster or joint compound somewhat, as well

as providing the desired thickening. However, additions of cellulose ethers
greater than 0.25 wt%, particularly at high viscosity grade (the viscosity of an
aqueous solution of the cellulose ether measured at a 2 wt% concentration of the
cellulose ether in water), tend to reduce the strength of gypsum-based products.
See Udo Ludwig and N.B. Singh, Il Cemento, v.1 (1979) 39-50, and Felix Brandt
and Dirk Basbach, Journal of Crystal Growth, v.233 (2001) 837-845, reporting
that the addition of high viscosity grades of cellulose ethers, for example methyl
cellulose, adversely affects the development of gypsum crystals and strength.
Thus, larger additions of cellulose ethers are usually avoided in commercial
plasters.
[0005] Wallboard, which is used herein to also designate such
products as sheathing board, moisture resistant board, type-X board, insulation
board, shaft liner, soffit board, backing board, core board, ceiling board, gypsum
glass mat board, and paperless wallboard, is typically prepared by mixing
dehydrated inorganic materials such as calcined gypsum or stucco with water and
pouring the resulting slurry into molds, forms or sheets where it hydrates,
hardens and dries. Calcined gypsum powder (calcium sulfate hemihydrate and/or
calcium sulfate anhydrite) is usually mixed with water and less than 1 wt% of a
variety of additives, for example accelerants. Dissolution of the calcined gypsum
powder in the water and a resulting hydration reaction causes crystallization of
gypsum crystals (calcium sulfate dihydrate) forming the wallboard core.
Application of multi-ply face sheets is usually integrated with the formation of
the wallboard core. This is often followed by mild heating to drive off the
remaining free (unreacted) water to yield a dry product, having face sheets
adhered to gypsum core.
[0006] Lukevich et al. (WO 99/54265) discloses a method to produce
formed gypsum products by extrusion of an a-gypsum paste (using a-calcium
sulfate hemihydrate). It is known that a-gypsum is slow setting and drying;
therefore, Lukevich et al. prepares an extrudable paste using a nearly
stoichiometric combination of a-gypsum plaster and water; however, addition of
a clay rheology modifier and a methyl cellulose binder are added to reduce
friability (page 1, paragraph 4). The resulting composition is an extrudable paste
having near stoichiometric composition of water and a-gypsum and not a slurry.
[0007] Thus, Lukevich et al. teaches away from using P-calcium
sulfate hemihydrate, which requires an excess of water over and above the
stoichiometric limits taught by Lukevich, to form a slurry that can be extruded
and requiring a step of drying (page 1, paragraph 3). Additionally, the extrusion
of the nearly dry, non-fluid paste, containing clay as a rheology modifier and a
cellulose ether as a binder, results in a plaster product with a much greater
density and vastly different microstructure than a wallboard core prepared using
a slurry of p-calcium sulfate hemihydrate and water.
[0008] Morris et al., U.S. Pat. No. 5,482,551, which issued January 9,
1996, disclose a gypsum-based, extruded construction material with a high
modulus of rupture and a method of extrusion processing of the construction
material. Morris et al. teach a formulation having a low fraction of water to dry
ingredients, including gypsum, clay, perlite, a powdered ethyl cellulose
binder/rheology aid and fiberized cellulose paper, such that the mixture is a
crumbly, semi-dry extrudable composition that maximizes the wet modulus of
rupture. Morris et al. teach that an extruded wall panel must have a high enough
wet strength to be self supporting.
[0009] However, the extruded construction material of Morris et al.,
like that of Lukevich, is too dense to be used commercially as wallboard. Even
with substantial inclusions of lightweight perlite (16% by weight of the dry
ingredients) and near the maximum ratio of water:gypsum allowed by Morris et
al. (0.8), the density of the product was still 54.8 pcf (0.88 g/cc). Typical
densities were about 69 pcf (1.1 g/cc). These densities are unacceptable for
production of commercial wallboard, because the added weight of the wallboard
adds significantly to higher transportation, handling, and installation costs
compared to conventional wallboard.
[0010] Gypsum-based wallboard is used primarily as inexpensive and
easily formable coverings with adequate compressive strength, nail pull
resistance, flexural strength and good fire resistance. However, even
conventional gypsum-based wallboard products are heavy compared to other
modern building materials, and this extra weight adds to the cost of production,
delivery, installation and disposal of gypsum-based construction materials
compared to competing products. Thus, it is desirable to retain the beneficial
qualities of gypsum-based wallboard while reducing the overall cost of installed
wallboard sheets by reducing the weight of gypsum-based wallboard.
[0011] Also, strength of conventional wallboard is related primarily to
the strength of the facing paper, typically an oriented fiber, multi-ply facing
paper that is applied to the gypsum-based slurry, which forms the core of the
wallboard, during a continuous forming process. For a 1/2 inch wallboard with a
density of about 0.6 g/cc, approximately one-half of the nail pull resistance and
two-thirds of the flexural strength are supplied by the paper face sheets, which
also account for 40% of the manufacturing costs. The core is usually
exceptionally poor at handling tensile loads of any kind.
[0012] Others have reduced the weight of the core further by adding
porosity and/or a low-density, expanded filler (e.g. perlite) into the conventional
material. Adding such porosity or filler decreases the density of the core, but
also reduces the strength of the wallboard. The strength of gypsum sheets
decreases dramatically with density. For example, a dramatic decrease of the
nail-pull resistance with density of 1/2-inch gypsum wallboard, both papered and
non-papered, can be seen in Fig. 3.
{0013] Typically, the rate of loss in strength is not merely proportional
with the reduction in density, but instead the strength-to-weight ratio of the
wallboard core decreases with the addition of porosity and/or low-density filler,
such as perlite, compared to that of a fully dense gypsum wallboard core. The
resulting flexural strength of the wallboard may be acceptable, so long as the
strength of the multiply facing is sufficient to offset any weakening of the core,
and the reduced core density does not cause the failure mode to change from
tensile failure of the facing to crushing of the core. However, nail pull resistance
of the wallboard is reduced by addition of such porosity, because increasing
porosity rapidly reduces the resistance of the core to crushing and densification.
Therefore, the nail pull resistance of the wallboard, which depends greatly on the
nail pull resistance of the core, becomes the limiting criterion for wallboard with
low-density cores covered by face sheets. For paperless wallboard core, the
flexural strength may be the limiting failure criterion, because unreinforced
gypsum wallboard cores have little, if any, resistance to the tensile load
components in the flexural strength test.
[0014] Another way of compensating for the introduction of lower
density substitutes (e.g., expanded perlite or air voids) for part of the set gypsum
matrix is to increase the strength of the set gypsum above normal levels in order
to maintain overall core strength. A number of additives, such as cellulosic
particles and fibers, have been included to further improve the mechanical
properties of cementitious products. More expensive glass fibers are used in
place of wood in applications where high fire resistance is required, such as the
shaft liner for elevators. However, conventional fibers, particularly glass, do not
adhere well to the gypsum matrix and decrease the workability of the gypsum
slurry, thus limiting possible improvements to the core strength. Glass fibers are
also brittle and can be easily dislodged during board handling, installation, or
demolition to cause irritation of the skin or respiratory tract.
{0015] More recently, there has been increasing interest in improving
the strength and wear resistance of construction materials by incorporating
polymers and/or starches into the core material, although starches are not
generally considered strength enhancers. Cementitious composites containing
water-dispersible polymers having modest improvement in strength-to-weight
have been found by adding latex or other strengthening polymers to the
cementitious materials.
[0016] However, several unique challenges have thus far restricted the
commercialization of polymer reinforced cementitious products to relatively
expensive niche products. For example, the nail pull resistance may decrease
with the addition of some organic additives or an increase in nail pull resistance
may require concentrations of polymers greater than 5 wt%, which can lead to
problems such as inflammability, reduced extinguishability, commercially
unacceptable cost of the wallboard, and mold susceptibility. Therefore, there is a
longstanding and unresolved need for an additive that can increase both the nail
pull resistance and the flexural strength of wallboard core, allowing the core
density to be reduced.
[0017] Cellulose is a polysaccharide composed of individual
anhydroglucose units which are linked through a glycosidic bond (Figure 16).
The number V of anhydroglucose units in the polymer chain is defined as the
degree of polymerisation. Typically, production of cellulose ethers (CE's)
involves replacing some of the hydroxyl hydrogen groups of cellulose with a
substituent group, for example a methyl group, an ethyl group, a carboxymethyl
group, a hydroxyehthyl group, a hydroxypropyl group, or some combination
thereof. For example, a hydroxyethyl methyl cellulose (HEMC) may be
produced by replacing some of the groups of cellulose with hydroxyethyl groups
and methyl groups. Likewise, a hydroxypropyl methyl cellulose (HPMC) may
be produced with hydroxypropyl and methyl groups replacing some of the
hydroxyl groups of the cellulose.
[00181 The number of substituted hydroxyl groups per anhydroglucose
unit is expressed as the degree of substitution (DS). The DS can vary between 0
and 3. As with all polymer reactions, this reaction does not occur uniformly
along the polymer chain. The reported degree of substitution is therefore a mean
degree of substitution over the whole polymer chain. Alternatively, molar
substitution (MS) may be used to report the number of moles of substituent
groups, such as a hydroxypropyl group, per mole of anhydroglucose. Often,
manufacturers follow a convention whereby one of the substituents is reported by
DS and the other by MS, where the substituent reported by MS may replace a
hydroxyl group or may attach to another substituent in a chain. The DS is not
always reported, and we have found that the value reported is often inaccurate or
given as a broad range, as shown in Table I.
[0019] In another alternative, the weight percent of substituents is
reported. Weight percent of substituents may be directly related to DS and MS.
For example, the following equations show the conversion for HPMC:
[0020] Cellulose ethers are conventionally differentiated by type of
substituent and the viscosity of an aqueous solution of the cellulose ether. For
example methyl cellulose (MC), ethyl cellulose (EC), carboxymethyl cellulose
(CMC), hydroxyethyl cellulose (HEC), ethyl hydroxyethyl cellulose (EHEC),
ethyl hydroxypropyl cellulose (EHPC) and hydroxypropyl cellulose (HPC) are
named for the type of substituent group used to replace the hydroxyl group in
cellulose. The viscosity of an aqueous solution including a cellulose ether is an
important characteristic for its typical use as a thickener; therefore, cellulose
ethers are also differentiated by viscosity, which depends on the degree of
polymerization (directly related to the measured molecular weight), and the type
and degree of substitution of substituent groups. As the molecular weight
increases, the viscosity of an aqueous solution of the cellulose ether increases
also. However, the effect of the degree of substitution depends on the particular
type of substituent group, which may also effect the solubility of the cellulose
ether.
[00211 Manufacturers characterize the effect of a particular cellulose
ether on the viscosity by reporting the measured viscosity of a 2 wt% aqueous
solution of the cellulose ether. Herein, we refer to this 2 wt% viscosity as the
viscosity grade of the particular cellulose ether. Typically, the viscosity grade is
measured by one of two techniques: Brookfield and Ubbelohde. Often, the
measured viscosity grade differs between the two techniques. For example,
results using both techniques are shown in Table I for some cellulose ethers.
[0022] Cellulose ethers are not typically used in wallboard products,
but may be used at low molecular weights (low viscosity) and low concentrations
to provide proper water retention, pumpabiliry and/or increase mixing blade life.
SUMMARY OF THE INVENTION
[0023] A wallboard core comprises water, P-calcium sulfate
hemihydrate and an additive, which are mixed together to form the wallboard
core. Herein, the term wallboard is used to also designate such products as
sheathing board, moisture resistant board, type-X board, insulation board, shaft
liner, soffit board, backing board, core board, ceiling board, gypsum glass mat
board, and paperless wallboard, which may be used to finish walls and ceilings in
the construction industry.
[0024] Upon mixing with the water, the P-calcium sulfate hemihydrate
may dissolve or partially dissolve in the water and hydrates, over time, forming
gypsum crystals. The additive is selected from one or more cellulose ethers
having, for example, a molecular weight of at least 20,000 and a viscosity grade
of at least 100 cps, such as HPC, HEC, MC, HPMC, EHEC, EHPC and HEMC,
without limiting in any way to those listed here, increasing both the nail pull
resistance and flexural strength of the wallboard core. Preferably, the weight
percent of cellulose ether to P-calcium sulfate hemihydrate is selected to be less
than 5 wt%, more preferably less than 3 wt%, whereby the cellulose ether has a
negligible effect on the inflamability and extinguishability of the wallboard.
Even more preferably, the weight percent is selected from 0.5 wt%, alternatively
from 0.5 - 3 wt%, for cellulose ethers that show a continuously increasing nail
pull resistance from 0.5 wt% to 3 wt%, which greatly simplifies the mixing
process. Alternatively, a cellulose ether with a low degree of substitution (DS) is
chosen.
[0025] The increased nail pull resistance and flexural strength
imparted to the reinforced wallboard core makes it possible to reduce or
eliminate the costly and heavy multi-ply paper surfaces of the wallboard. The
multi-ply paper facing can also increase the undesirable mold susceptibility of
wallboard by feeding mold growth after absorbing water from the surrounding
environment. Thus, a mold resistant wallboard may be fabricated using a
reduced paper wallboard core that is strengthened by a cellulose ether additive.
Although paper is a cellulose, cellulose derivatives, such as cellulose ethers, do
not tend to feed mold growth when added to the wallboard core, as shown by
mold resistance tests of specimen maintained at 32 degrees C in an incubator
with 90% humidity and in the presence of mold spores. In an alternative
embodiment, a skim layer is added to at least one surface provides even greater
mold resistance. There is a longstanding and unresolved need for low cost
wallboard having such mold resistance.
[0026] A lightweight wallboard, for example with a conventional
multi-ply facing sheet or sheets, may be fabricated by reducing the density of the
wallboard core without sacrificing the nail pull resistance of the wallboard. For
example, the density may be reduced below 0.75 g/cc using a lightweight filler or
by introducing porosity into the core in the form of voids or air bubbles while
maintaining the flexural strength and nail pull resistance of the wallboard.
[0027] Addition of an excess amount of water to the slurry, over and
above the stoichiometric amount of water needed to hydrate the powdered dry
ingredients, reduces the density of the wallboard core. It is believed, without
being limiting in any way, that the excess water forms droplets in the wallboard
core that, after drying, remain in the wallboard core as pores. A general,
empirical correlation has been found for predicting the wallboard density in g/cc
(p) with the water to powdered dry ingredient ratio (W:P), if foaming is
negligible: p = 0.8324(W:P)-07629. The addition of foaming, whether by rapid
stirring or addition of a foaming agent, may further reduce the density by
introducing porosity into the wallboard core in addition to the amount introduced
by the excess water.
[0028] By adding additional water to the slurry, viscosity of the slurry
is reduced. Thus, a slurry containing substantially no clay may be extruded in a
continuous extrusion process, forming lightweight, reinforced wallboard. By
substantially no clay, it is meant that no clay is added to the dry ingredients as a
rheology modifier. Of course, clay may be present as an impurity in the dry
ingredients or the water at a level that does not significantly affect the rheology
of the extrusion process.
[0029] One method of producing the wallboard core mixes dry
ingredients comprising ß-calcium sulfate hemihydrate powder and a powdered
additive selected from cellulose ethers other than CMC, the cellulose ether being
selected to have a degree of substitution (DS) that is soluble in water (e.g. from
1.2 to 2.4 for MC). For commercially available cellulose ethers, having a range
of DS from 1.6 to 1.9, for example, a viscosity grade of at least about 100 cps
and a molecular weight of at least about 20,000 MW is preferred.
[0030] For a high degree of substitution (DS), e.g. greater than 1.8 for
methyl cellulose (MC), a higher viscosity grade (e.g. at least about 200 cps) is
preferred. Surprisingly, a higher DS is associated with a lower nail pull
resistance for cellulose ethers, such as MC. Thus, a low DS (e.g. in a range from
1.2 to 1.8 for MC) is preferred, because a lower viscosity grade cellulose ether
may be selected or a lower fraction of the cellulose ether additive may be added,
while still achieving the same nail pull resistance. By lowering the viscosity
grade, the slurry becomes easier to mix, given the same amount of water. By
lowering the amount of water, the wallboard dries quicker, given the same slurry
viscosity. By lowering the fraction of cellulose additive in the slurry, the
manufacturing cost of the wallboard is decreased.
[0031] Thus, a range of DS from 1.2 to 1.6 for MC is even more
preferred, for example. Although MC is not available commercially in this range,
the surprising and unexpected correlations for such low DS cellulose ethers,
providing greatly enhanced flexural strength and nail pull resistance, the low cost
of manufacturing such cellulose ethers, and the high volumes of MC to be used
in reinforced wallboard manufacture is expected to drive the development of
commercial grades of MC in this Tange of DS.
10032] In another embodiment, it is preferable to select a viscosity
grade of at least about 400 cps. Surprisingly, by selecting a cellulose ether
greater than this viscosity grade, the nail pull resistance of the resulting
wallboard core increases significantly compared to unreinforced wallboard core
for additions of from 0.5 wt% to 3 wt% of all cellulose ethers tested, except for
CMC, so long as the cellulose ether is well dispersed throughout the p-calcium
sulfate hemihydrate prior to adding to water, even at relatively high DS. At low
DS, the correlations show that nail pull index and flexural strength index are
dramatically increased compared to any conventional wallboard.
[0033] An amount of water may be selected to form a slurry with the
dry ingredients that results in a finished wallboard core density of 0.75 g/cc after
extrusion, setting and drying in an oven at 45 oC until the density remains
constant. In addition, many other additives, including other cellulose ethers may
be added to tailor the properties of the wallboard core without diminishing the
nail pull resistance and strength of the wallboard core.
[0034] In one embodiment, these dry ingredients may be well mixed to
thoroughly disperse the additive throughout the P-calcium sulfate hemihydrate
powder. Then, the dry ingredients are added to and mixed with the water, poured
onto a form, formed into a sheet, allowed to set, dried and trimmed. The amount
of water selected will always be in excess of the amount needed for extrusion and
for the amount of water required for a stoichiometric combination of the p-
calcium sulfate hemihydrate and water to form gypsum. Preferably, the amount
of water is selected to produce a wallboard core with a density less than 0.8 g/cc,
more preferably less than 0.75 g/cc, even more preferably in a range from 0.45
g/cc to 0.7 g/cc for lightweight wallboard.
[0035] By a "slurry," it is meant that the mixture of dry ingredients
and water forms a homogeneous fluid that can be well mixed, dissolving at least
a portion of the P-calcium sulfate hemihydrate in the water prior to extruding the
slurry. The amount of water required depends, for example, on the amount of ß-
calcium sulfate hemihydrate, the amount of additive and other dry ingredients, as
well as the temperature and the type of additive or additives included in the
slurry. The amount of water used significantly alters the microstructure of the
wallboard core, for example by affecting the amount of porosity, the extent of
dissolution of the P-calcium sulfate hemihydrate, the rate of hydration and the
morphology of the gypsum crystals, which in turn affects the nail pull resistance
and flexural strength of the wallboard. A foam may be added to the slurry,
instead of adding additional water, in order to reduce the density to a preferred
range for a specific application. For example, a foaming agent, such as a
surfactant or chemically active foaming agent, may be added in the water and/or
the slurry to cause foam during stirring of the water and/or slurry. Adding a
foam may result in a shorter drying time and/or a more preferable distribution of
the porosity than a process that would produce a wallboard with an equivalent
density by merely increasing the amount of water. Alternatively, a low density
filler may be added.
[0036] The process may be a continuous process, whereby the dry
ingredients are mixed, added to the water, blended into a slurry and the slurry is
poured onto a moving surface to form the wallboard core. A form may both
contain the slurry and form the two edges of the wallboard, while one or more
rolls or restrictions spread and flatten the free surface of the slurry, whereby an
elongated, continuous sheet is formed. Following forming of the continuous
wallboard core, the end of the elongated sheet of slurry, after being allowed to set
at least partially, is cut into lengths from the rest of the elongated, continuous
sheet. Then, the wallboard is trimmed if necessary and dried. Alternatively, one
or more facing sheets may be added during the process on one or both sides of
the wallboard core.
[0037] Another method of producing the wall board mixes a
strengthening additive with the water before mixing with the powdered P-
calcium sulfate hemihydrate. In this method, the additive, whether dry, paste, gel
or liquid, is at least partially dissolved in the water. Then, the dry ingredients,
including the ß-calcium sulfate hemihydrate and optionally other dry additional
additives, are added to and mixed with the aqueous solution to form a slurry.
The slurry is then processed as before.
[0038] One or more paper layers may be adhered to one or both sides
of the wallboard core or facing sheets, for example for decorative purposes
and/or to impart improved strength. The paper may have fibers, which may be
oriented to strengthen the wallboard in a preferred direction. Alternatively, no
paper layers may be added or a non-paper layer may be adhered to one or both
sides of the wallboard core. In yet another alternative, a second additive may be
included in the dry ingredients that segregates to one or both surfaces of the
wallboard, forming an in situ surface layer on the wallboard.
[0039] "At least about" 100 cps means that cellulose ether should be
selected from cellulose ethers having a viscosity grade of about 100 cps or
greater, and "about" 100 cps should be understood to take into consideration
normal variations in commercial measurements of the viscosity grade, based for
example on the use of different measurement techniques. For example, differing
selection of shear rate for measuring viscosity grade may cause variations in the
measured value. A. variation of as much as 30% from the viscosity grade
reported by manufacturers is to be expected at low viscosity grades up to 1000
cps. Viscosity grades greater than about 1000 cps show an even greater variation
in the viscosity grade.
[0040] "At least about" 20,000 MW means that cellulose ether should
be selected from cellulose ethers having a molecular weight of "about" 20,000 or
greater. It should be understood that the mean value of the molecular weight for
a specific type of commercial cellulose ether with a specific degree of
substitution may be 20,000, but that variations between batches and variations
within a batch allow for significant commercial variances in the mean and
standard deviation from the mean of the molecular weight. Typically, the mean
molecular weight may vary by as much as 20% from the manufacturer's
specification. The standard deviation within a batch depends, for example, on
manufacturing tolerances, the process chosen to manufacture a particular
cellulose ether, and the variations already present in the raw cellulose prior to
substitution.
[0041] A nail pull index and flexural strength index are presented
herein that normalize the measurements of nail pull resistance and flexural
strength for wallboard and ceiling board specimens having a spectrum of board
weights by comparing the strength measurements to the strength of specimens
prepared without a strengthening additive at the same wallboard weight and
thickness. For example, the nail pull resistance versus board weight for
conventional wallboard is shown in Fig. 3 for specimens with and without paper.
The nail putt index, as shown in Fig. 5 for some embodiments, is a comparative
measure nail pull resistance of a reinforced specimen to a conventional specimen
at the same density (board weight). Therefore, a nail pull index of 1.0 means that
a reinforced wallboard specimen has the same nail pull resistance as a specimen
prepared conventionally without reinforcing additions.
/ACCOMPANYING
BRIEF DESCRIPTION OF THF/DRAWINGS
[0042] Fig. 1 shows the improvement in nail pull resistance of several
embodiments of the present invention at a concentration of 1g of additive / 100 g
ß-calcium sulfate hemihydrate.
[0043} Fig. 2 shows the improvement in flexural strength of the same
embodiments as shown in Fig. 1.
[0044] Fig. 3 shows the nail pull resistance versus board weight of
wallboard specimens prepared according to the prior art.
[0045] Fig. 4 shows a minimum board weight to satisfy ASTM
Standard C473-95 for a Vz inch thick wallboard versus nail pull index for papered
and non-papered wallboard.
[0046] Fig. 5 shows the nail pull index versus weight fraction for
several embodiments of the present invention.
[0047] Fig. 6 shows the nail pull index versus weight fraction for
several low viscosity cellulose ethers.
[0048] Fig. 7 shows the nail pull index versus viscosity grade for
HPMC at a weight fraction of lg of HPMC per 100 g ß-calcium sulfate
hemihydrate with and without a paper backing.
[0049] Fig. 8 shows the minimum board weight versus viscosity grade
for HPMC at a weight fraction of lg of HPMC per 100 g p-calcium sulfate
hemihydrate with and without a paper backing.
[0050] Fig. 9 shows the nail pull index versus patty diameter (an
indicator of the viscosity that decreases with increasing viscosity) for HPMC.
[0051] Fig. 10 shows the nail pull index versus weight fraction for
several embodiments of the present invention having treated surfaces to delay
dissolution.
[0052] Fig. 11 shows the nail pull index versus weight fraction for
four alternative embodiments comprising a paperless wallboard and a HPMC
strengthening additive.
[0053] Fig. 12 shows the flexural strength index versus weight fraction
for the same four embodiments as shown in Fig. 11.
[0054] Fig. 13 shows the nail pull index versus weight fraction for two
alternative embodiments of a HEC reinforced wallboard or ceiling board.
[0055] 4 Fig. 14 shows the data and a correlation for the nail pull
index versus viscosity grade for another embodiment comprising a paperless
MC-reinforced wallboard.
[0056] 5 Fig. 15 shows the data and a correlation for the nail pull
index versus viscosity grade for another embodiment comprising a paperless
HPMC-reinforced wallboard.
[0057] Fig. 16 shows the chemical formula for cellulose.
[0058] Fig. 17 shows the chemical formula of a methyl cellulose.
[0059] Fig. 18 shows the chemical formula of a hydroxypropyl methyl
cellulose.
|0060] Figs. 19 and 20, based on a correlation with data, show
graphically the calculated effect of percent substitution of methyl groups in
methyl cellulose on the nail pull index and flexural strength index for various
viscosity grades and weight percent additions of methyl cellulose.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0061] A reinforced wallboard and/or ceiling board comprises a
calcium sulfate hemihydrate, a reinforcing additive and water. The calcium
sulfate hemihydrate is preferably ß-calcium sulfate hemihydrate and may be
produced by calcining gypsum, for example. The reinforcing additive is
dispersable in water and may be produced and used in various forms, such as
aqueous solutions, granules and powders. For example, one reinforcing additive
is a cellulose ether. Cellulose ethers may be used with a wide variety of
substituent groups. For example, HPC, HEC, MC, HPMC, EHEC, EHPC and
HEMC may be used as the reinforcing additive.
[0062] In one embodiment, dry ß- calcium sulfate hemihydrate
powder and powdered HPMC are mixed together, dispersing the powdered
HPMC additive throughout the P-calcium sulfate hemihydrate powder. The dry
ingredients are then added to water, including an excess of water beyond that
required to hydrate the ß-calcium sulfate hemihydrate stoichiometrically,
forming a slurry by stirring of the powder/water mixture. For example, the
amount of water used is selected such that the finished wallboard has a density
less than 0.8 g/cc, more preferably less than 0.75 g/cc. Then, the slurry is
extruded through a die or a form or a series of dies and forms. The extruded
slurry is then fed onto a belt into a continuous sheet. The slurry is allowed to
harden, which is also referred to as setting and is a result of the P-calcium sulfate
hemihydrate at least partially dissolving and hydrating, forming calcium sulfate
dihydrate crystals, referred to herein as gypsum crystals.
[0063] Then, the setting wallboard or wallboard specimen is dried.
Air drying or drying in a furnace evaporates the excess water that has not reacted
during hydration, but that is required to form a slurry. Excess water also tends to
increase the amount of porosity dried wallboard core, because the evaporation of
the excess water leaves behind porous microstructure. The sheets may then be
trimmed, sized, weighed and tested.
[0064] Tests include measuring the nail pull resistance, flexural
strength, humidified deflection, mold resistance, and inflamability, for example
using ASTM standard test procedures. Mold resistance is defined as showing no
signs of mold growth on a wallboard or wallboard core surface after 24 days of
exposure to mold spores within an environment maintained at 90% humidity and
a temperature of 32 °C.
[0065] Preferably, the cellulose ethers used as additives to the
wallboard slurry have a high molecular weight, which is associated with a high
viscosity grade. Surprisingly, both nail pull resistance and flexural strength are
greatly increased for specific cellulose ethers at particular molecular weights and
viscosity grades, as shown in Figs. 1 and 2. Also, it is very surprising that both
nail pull index and flexural strength index increase rapidly with increasing
molecular weight and viscosity grade for some cellulose ethers, for example as
shown in Figs. 7 and 15. This contradicts the earlier expectations of others in the
field that relied on data from specimens prepared using stucco slurries using
relatively low molecular weight additives, slurries of CMC, which do not show
increasing nail pull resistance with weight fractions above about 0.25 wt%, and
slurries prepared using processing methods that did not effectively disperse the
cellulose ether powders. Furthermore, the present invention contradicts those
references that indicated that high viscosity grades would weaken the gypsum
crystal strength.
[0066] Specimens of high molecular weight and high viscosity grade
HPMC reinforced wallboard and HEMC reinforced wallboard have the greatest
value of nail pull index of those tested, as shown in Fig. 1. Other embodiments
show greatly improved nail pull index, as well, especially using high viscosity
grade cellulose ethers.
[0067] However, the results for low molecular weight cellulose ethers
was disappointing, as shown in Fig. 6 and 14. As concentration of the cellulose
ethers increased, the nail pull resistance decreased for low molecular weight
cellulose ethers. Degradation of important properties with continued addition of
an additive is highly disfavored in commercial processing, especially for an
additive with a low overall weight fraction compared to other ingredients.
[0068] During a mixing process, increasing the weight fraction of the
additive in the mixture is accomplished by merely adding more of the additive to
a batch or continuous stream of the mixture. However, it is problematic to dilute
the weight fraction of additive once too much additive is mixed with the base
material, because it requires mixing large quantities of the base material, in this
case ß-calcium sulfate hemihydrate, into a mixture of additive and base material
to dilute the weight fraction of additive. Thus, it is desirable for a robust mixing
process to be able to allow an excess of additive without adversely affecting the
properties of the finished product. Therefore, using an additive that continuously
improves the properties of the product even with an inadvertent addition of
excess additive is preferred. Even though the low molecular weight additives
initially increase the nail pull resistance up to 0.25 wt%, the sharp decrease in
properties with continued addition over a percent weight of 0.25 wt% makes
them impractical for use in many commercial processes.
[0069] Fig. 5 shows that for high molecular weight and high viscosity
HPMC, HEMC, and HEC, the nail pull resistance increases logarithmically with
the weight fraction of additive. This is a highly desirable trend, making for a
robust and forgiving manufacturing process. 400 cps MC shows a linear increase
in nail pull resistance with weight fraction of additive, which is also desirable.
[0070] CMC is one of the most commonly used cellulose ethers, but,
in the absence of other cellulose ethers, CMC greatly retards setting time and
reduces nail pull resistance and flexural strength compared to unreinforced
specimens. As mentioned previously CMC does not increase the strength of
wallboard at the concentrations, high molecular weights and viscosities that are
effective for the other cellulose ethers. It is believed, without being limiting in
any way, that other cellulose ethers tend to have molecular interactions via
hydrogen bonding. Thus, it is believed that the high molecular weight molecules
tend to be immobilized and do not segregate to the drying surfaces of the
wallboard, as some other soluble polymers do. Therefore, high molecular weight
molecules, having substantial hydrogen bonding interactions, remain dispersed
throughout the wallboard core and reinforce the matrix of hydrated gypsum
crystals.
[0071] A surface treatment may coat the cellulose ethers to delay the
onset of dissolution, which would be expected to improve dispersion of the
cellulose ethers in water. However, it is believed that, in practice, the delay in
dissolution caused by the surface treatment results in incomplete dissolution of
the surface treated cellulose ethers. Iodine stain tests showed that cellulose
ethers that were surface treated did not disperse evenly throughout the wallboard
specimen, especially for HEC surface-treated powders, while both untreated
cellulose ethers and surface treated cellulose ethers that were pre-dissolved
showed complete and even dispersion throughout the wallboard. One method of
improving dispersion of untreated and surface-treated powdered cellulose ethers
was to pre-mix the dry cellulose ethers until the powders were well dispersed
with the dry ß-calcium sulfate hemihydrate before adding the mixture to water.
Thereby, the agglomeration of the cellulose ethers was reduced and dissolution
occurred more readily than for agglomerated particles.
[00721 The nail pull index of surface treated cellulose ethers was less
than the nail pull index of either pre-dissolved, surface treated cellulose ethers or
untreated cellulose ethers, as shown in Figs. 1 and 2, and as shown against
weight fraction, for example in Fig. 11 for HPMC with a viscosity grade of
45,000 cps (45 kcps) and in Fig. 13 for HEC with a molecular weight of 1.3
million (1.3M).
[0073] The ftexural strength is not affected as greatly by incomplete
dissolution, as shown versus weight fraction in Fig. 12 for HPMC at 45 kcps. It
is believed that the difference between the effects in nail pull index and flexural
strength index is due to the fact that nail pull index is sensitive to crushing of the
specimen core, while the flexural strength index is less sensitive to crushing of
the specimen of the core (distributed stresses).
[0074] Fig. 8 shows the minimum board weight projected for meeting
ASTM standards versus viscosity grade of wallboard specimens prepared with a
weight percent of HPMC additive to ß-calcium sulfate hemihydrate of 1 wt%.
As the viscosity grade increases the minimum board weight that is required to
pass ASTM standards decreases. It should be understood that any additional
reinforcements, such as fiber reinforcements, that are added to the slurry can also
increase the strength, particularly the flexural strength, of the wallboard. This
would also tend to reduce the minimum board weight required to pass ASTM
standards. For example, it is common practice to incorporate cellulose fibers into
the wallboard core. Other fiber reinforcements, such as glass, polymer and
carbon fibers, may also be added to increase the flexural strength of the
wallboard core. In one specific embodiment, short polyester fibers or nylon
fibers or both are mixed into the dry ingredients prior to adding the dry
ingredients to water to increase the flexural strength. Longer fibers can be
introduced during extrusion to provide the core with oriented strengthening along
the longitudinal direction of the wallboard.
{00751 Slurry viscosity is a major concern in high speed wallboard
production. Increased viscosity can lead to increased mixing and pumping
demands, clogged machinery, and problems with board formation. Slurry
viscosity is of even greater importance when selecting a CE additive because the
primary purpose of CEs in conventional plaster formulations is to thicken the
mixture.
[00761 In order to fully hydrate the P-calcium sulfate hemihydrate and
prepare a slurry that can be mixed and extruded, a greater amount of water is
used than is used for plaster compounds, which use hydration of a-calcium
sulfate hemihydrate to form gypsum. It is known that the amount of water added
to the slurry has a profound effect on the quality and microstructure of the
resulting wallboard. It is believed, without limiting the invention in any way,
that addition of too little water prevents adequate mixing of the slurry, while too
much water causes undesired porosity in the wallboard core. There can be a
dramatic increase in viscosity with the addition of CEs, especially in
formulations with elevated levels of high viscosity CE, which can make it
difficult to adequately mix the dry ingredients and the water. Furthermore, an
increase in viscosity can prevent the slurry from being poured into a form. One
simple test that can be used to determine slurry viscosity is a "patty test" in which
some amount of slurry is poured from a designated height and the resulting patty
diameter is recorded. Furthermore, the rheology of wallboard slurry is a function
of time, humidity and temperature.
[0077} In general, the patty size increases inversely with an increase in
the viscosity grade of a cellulose ether. As expected, the patty diameter increases
with decreasing viscosity grade for HPMC In fact, patty diameter increases
logarithmically with the inverse of viscosity grade; therefore, the nail pull index
increases proportionally with the inverse of patty size, as shown in Fig. 9.
[0078] In one embodiment, a slurry was formed by mixing p-calcium
sulfate hemihydrate with less than 5 wt% of a powdered cellulose ether, such that
the cellulose ether was evenly dispersed throughout the mixture. The mixture
was then mixed with an amount of water to form a slurry, such that the wallboard
core had a density of less than 0.8 g/cc upon drying. In an alternative
embodiment, the cellulose ether was selected to have a molecular weight of at
least 20,000 and a viscosity grade of at least 100 cps, and both the nail pull
resistance and flexural strength were improved compared to unreinforced
wallboard. In another embodiment, the amount of powdered cellulose ether was
limited to a range of 0.5 wt% to 3 wt%, and the measured nail pull index
continuously increased with addition of powdered cellulose ether.
[0079] In yet another embodiment, the DS is limited to a range
between 1.2 and 2.4 for a MC. In an alternative embodiment, the DS is limited to
a range from 1.6 and 1.9 for a MC, having a viscosity grade of at least 10 cps,
producing wallboard with improved nail pull index for viscosity grades of at least
100 cps, as shown in Figs. 14 and 15, for example. Fig. 14 shows a graph of nail
pull index versus MC viscosity grade with 0.25,0.5,1.0, and 2.0 wt% of MC
mixed with powdered p-calcium sulfate hemihydrate. The darker lines and point
are the values calculated using a correlation, which is discussed elsewhere, while
the lighter lines are the experimental values. Fig. 15 is a similar graph for HPMC
mixed with powdered ß-calcium sulfate hemihydrate. In another alternative
embodiment, a DS range from 1,2 to 1.6 for a MC, greatly increases the flexural
strength index and increases the nail pull index for MC additions at a weight
percent of 0.25 and 0.5 wt%, as shown in Fig. 19, which is based on the
correlation used in Fig. 14. Fig. 20 shows that this trend applies also to higher
weight percent additions of MC. This shows that increasing nail pull resistance
occurs for wallboard processed using a MC with low DS, high viscosity grade
and high molecular weight, high weight percent or a combination of these.
[0080] It is believed, without being limiting in any way, that
hydrogen-bonding interactions immobilize the cellulose ether molecules, and the
degree of hydrogen bonding is affected by molecular weight and is reflected in
the viscosity grade. It is also affected by the degree of substitution. Thus, degree
of substitution, viscosity grade and molecular weight of the cellulose ether are
critical factors in selecting a specific cellulose ether as a strengthening additive,
because it is believed that the strength of the wallboard depends on the
distribution of cellulose ether molecules in the wallboard core and bonding
interactions among the molecules. Furthermore, it is believed that the effect of
bonding interactions depends on both the degree of substitution and the weight
percent of the addition.
[0081] The percent substitution of specific cellulose ethers, which
were used as reinforcing additives, were analyzed in accordance with standard
test method ASTM D 3876, which is incorporated by reference herein in its
entirety. ASTM D 3876 determines methoxyl and hydroxypropyl substitution in
cellulose ether products by gas chromatography. The resolved substitution
percentages of the various cellulose ethers, along with the viscosity grades taken
from the literature, were compared to the mechanical testing results to determine
the effect of the degree of substitution on flexural strength and nail pull
resistance. Based on these empirical measurements, correlations were developed
that relate the nail pull index and the flexural strength index to cellulose ether
substitution pattern. The following regression models established the best
correlation:

These empirical correlations are useful in defining the effect of each of the
weight percentage of cellulose ether (f), the degree or percent of substitution of
the methyl (M) and hydoxypropyl (H) groups, and the viscosity grade (y) on the
nail pull index and flexural strength index of wallboard core reinforced by MC
and HPMC.
[0082] Specifically, there is a correlation of the amount of cellulose
ether additive in the wallboard core and the nail pull index and flexural strength
index. As expected, the nail pull resistance increases with increasing weight
percent of additive. There is also a correlation with viscosity grade.
Surprisingly, the data shows that increasing viscosity grade increases the nail pull
index for HPMC and MC, which was not reflected in the literature or in some of
the Taw data, for example, as shown in Fig. 14 for MC.
[0083] Finally, there is a very surprising and unexpected correlation
with the percent substitution. Specifically, the nail pull index increases with
decreasing degree of substitution (DS), as show in Figs. 19 and 20 for MC, for
example. This unexpected and surprisingly strong correlation is sufficient to
cause the dramatic dip in the nail pull index versus viscosity grade curve as
shown in Fig. 14, for example. In Fig. 14, the commercially available MC had a
percent substitution of methyl groups of 34%. Furthermore, this effect has gone
unnoticed by others, which has probably discouraged others from adding
cellulose ethers to wallboard as a strengthening additive. Specifically, the DS is
often not reported for commercial cellulose ethers. If reported, it is often highly
inaccurate. Thus, to perform this analysis, it was necessary to independently
measure the percent substitution by gas chromatography. In the range of weight
percent most practical for wallboard, e.g. less than 5 wt%, more preferably less
than 3 wt%, even moderate increases in DS dramatically decrease the measured
flexural strength index of wallboard compared to lower DS, as shown in Figs. 19
and 20.
[0084] For low viscosity grade cellulose ethers, the difference in the
measured index of nail pull and flexural strength is often the difference between
a decrease compared to no reinforcement in the wallboard and a dramatic
increase compared to no reinforcement, as shown in Figs. 19 and 20.
Furthermore, commercially available cellulose ethers typically have relatively
high values of DS, as compared to the DS associated with the limit in solubility
of the cellulose ethers. Thus, it is not surprising that cellulose ethers have been
overlooked as an additive for strengthening p-calcium sulfate hemihydrate based
wallboard products. Indeed, the most promising cellulose ethers, for example
MC with a DS in the range from 1.2 to 1.6, have not been readily available for
testing as strengthening additives.
[0085] The HPMC nail pull performance correlation exhibits a
different relationship with methoxyl substitution percentage, which has a much
lower range in commercially available HPMC than in commercially available
MC. At low additive levels, decreasing methyl DS does increase the nail pull
index; however, at higher additive levels reducing the methyl DS is less effective,
according to the correlations. This trend is affected somewhat by the choice of
viscosity grade and by hydroxypropyl substitution percentage. However, given
the data currently available, the degree of hydroxypropyl substitution does not
influence the nail pull index as dramatically as methoxyl substitution in MC.
These effects are reflected in the scattered data of Fig. 15.
[0086] In another alternative embodiment, a foam may be produced to
further reduce the density of the wallboard core. This foam may be produced, for
example, using a surfactant and stirring of the water and/or slurry to generate a
foam, which may be incorporated into the extruded wallboard core.
SPECIFIC EXAMPLES
[0087] Control Sample. One hundred grams of ß-calcium sulfate
hemihydrate was dry mixed with 0.13g ground gypsum accelerator. The ß-
calcium sulfate hemihydrate was then added to 150 g of room-temperature tap
water in a 500 mL Waring blender. The slurry was blended at low speed for 15
seconds. The slurry was then immediately poured into an approximately 7" x 2" x
1/2" mold. After about 20 minutes, the sample was removed from the mold and
placed in a convection oven at 45 °C in which it was dried for at least 36 hrs.
After removal from the oven, the sample was cut to 5" x 2" and massed and
dimensioned. This data was used to calculate sample density. The flexural
strength was attained using a three-point-bend test similar to the ASTM C473
flexural strength test (method B) for gypsum wallboard. An Instron mechanical
testing system with data acquisition software was used to determine mechanical
behavior. The flexural failure stress was calculated from the failure load, testing
configuration, and sample geometry. The two half samples remaining from the
bending test were tested for resistance to nail pull. A nail pull test based on
ASTM C473 nail pull test (method B) was used. The resulting sample had a
density of 0.63 g/cc, a flexural strength of 242 psi, and a nail pull resistance of 46
lbs.
{0088] High Viscosity HPMC Enhancing Agent; Paperless Sample.
One hundred grams of ß-calcium sulfate hemihydrate was dry mixed with 0.13 g
ground gypsum accelerator and 1 g HPMC (100 kcps purchased from Aldrich
Chemical Co.). The dry mixture was then added to 150 g of tap water in a 500
mL Waring blender. The slurry was blended at low speed for 15 seconds. The
slurry was then immediately poured into a 7" x 2" x 1/2" mold where it set for
about 20 minutes before being removed. The sample was placed in a convection
oven at 45 °C for at least 36 hrs. After removal from the oven, the sample was
cut to 5" long, massed, and dimensioned. The density was calculated and the
sample was tested for flexural strength and nail pull resistance on an Instron
mechanical testing system. The sample had a density of 0.46 g/cc, a flexural
strength of 299 psi, and a nail pull resistance of 43 lbs.
(0089] High Viscosity, RETARDED HEMC Enhancing Agent;
Paperless Sample. One hundred grams of P-calcium sulfate hemihydrate was dry
mixed with 0.13g ground gypsum and 1g of retarded HEMC (15-20, 5 kcps,
purchased from Aidrich Chemical Co.). The dry mixture was then added to 150 g
of tap water in a 500 mL Waring blender. The slurry was blended at low speed
for 15 seconds. The slurry was then immediately poured into a 7" x 2" x 1/2" mold
and, after 20 minutes, removed. The sample was placed in a convection oven at
45 °C for at least 36 hrs. After removal from the oven, the sample was cut to 5"
long, massed, and dimensioned. The density was calculated and the sample was
tested for flexural strength and nail pull resistance on an Instron mechanical
testing system. The resulting sample had a density of 0.63 g/cc, a flexural
strength of 545 psi, and a nail pull resistance of 78 lbs.
[0090] High Viscosity HPMC Enhancing Agent; Lightweight
Wallboard. A papered sample was prepared by mixing 1 kg of P-calcium sulfate
hemihydrate with 1.3 g ground gypsum and 10 g of HPMC (22 kcps, purchased
from Aldrich Chemical Co.). To a 5 liter Waring blending container was added
1.5 kg of room-temperature tap water, 20 drops of Daxad 19LKN (dispersant)
from Dow, and 10 drops of a 40% solution of diethylenetriaminepentaacetic acid
sodium salt (retarder). The powder was added to the water and blended on high
for 15 seconds. The slurry was then poured into an approximately 12" x 12" x 1/2"
mold lined with an envelope made of standard decorative wallboard facing paper.
The sample was removed from the mold after 15 minutes and placed in a 45 °C
convection oven for 48 hrs. The sample was then removed and cut into 5" x 2"
and 9" x 2" specimens, with the long dimension in the direction of the fibers of
the paper. These specimens were then massed and measured. The density was
calculated and the specimens were tested for flexural strength in the fiber
direction and nail pull resistance on an Instron mechanical testing system. The
sample had a density of 0.47 g/cc, a flexural strength of 822 psi, and a nail pull
resistance of 75 lbs.
[0091] MC with 1:1 water:ß-calcium sulfate hemihydrate ratio by
weight. 100 parts of P-calcium sulfate hemihydrate was mixed with 9 parts of
methyl cellulose (Aldrich, MW 17,000, viscosity grade 25 cps). The mixture was
then added to 100 parts of water at room temperature and blended at a high shear
setting for approximately 15 seconds. The resulting slurry was highly viscous,
failing to pour into the form. A spatula was used to transfer, in small portions,
enough slurry to be pressed into a form measuring 2 inches by 5 inches by 0.5
inches. After setting, the mixture was removed from the mold and cured at 45 °C
for 2 days. The resulting sample has a density of 0.72 g/cc, a nail pull index of
1.87 (121 lbs.) and flexural strength of 881 lb/in2.
[0092] MC with 1:1 water ß-calcium sulfate hemihydrate ratio by
weight. 100 parts of P-calcium sulfate hemihydrate was mixed with 9 parts of
methyl cellulose (Aldrich, MW 14,000, viscosity grade 15 cps). The mixture was
then added to 100 parts of water and blended at high shear setting for
approximately 15 seconds. The resulting slurry was highly viscous, failing to
pour into the form. A spatula was used to transfer, in small portions, enough
slurry to be pressed into a from measuring 2 inches by 5 inches by 0.5 inches.
After setting, the mixture was removed from the mold and cured at 45 °C for 2
days. The resulting sample had a density of 0.74 g/cc, a nail pull index of 1.75
(119 lbs.) and flexural strength of 864 lb/in2.
[0093] MC with 1:1 water:ß-calcium sulfate hemihydrate ratio by
weight. 100 parts of P-calcium sulfate hemihydrate was mixed with 9 parts of
methyl cellulose (Aldrich, MW 40,000, viscosity grade 400 cps). The mixture
was then added to 100 parts of water and blended at a high shear setting. The
viscosity was exceedingly high and mixing was not possible for the desired 15
second duration. The powdered mixture was not fully incorporated into the
slurry. The mixture prematurely set and could not be transferred to a form.
[0094] MC with 1:1 water: ß-calcium sulfate hemihydrate ratio by
weight. A subsequent specimen was prepared by reducing the amount of methyl
cellulose by mixing 100 parts of P-calcium sulfate hemihydrate with 5 parts
methyl cellulose instead of 9 parts methyl cellulose. The mixture was then added
to 100 parts of water and blended at high shear setting for approximately 15
seconds. The resulting slurry was extremely viscous, beginning to set
prematurely during mixing and failing to pour into the form. A spatula was used
to transfer, in small portions, enough slurry to be pressed into a form measuring 2
inches by 5 inches by 0.5 inches. After setting, the mixture was removed from
the mold and cured at 45 °C for 2 days. The resulting sample had a density of
0.73 g/cc, a nail pull index of 1.54 (103 lbs.) and a flexural strength of 766
lbs./in2.
[0095] Low Viscosity Grade HPMC with 1:1 water: ß-calcium sulfate
hemihydrate ratio by weight. 100 parts of ß-calcium sulfate hemihydrate was
mixed with 9 parts of HPMC (Aldrich, MW 10,000, viscosity grade 5 cps). The
mixture was then added to 100 parts of water and blended at high shear setting
for approximately 15 seconds. The resulting slurry poured directly into a form
measuring 2 inches by 5 inches by 0.5 inches. After setting, the mixture was
removed from the mold and cured at 45 °C for 2 days. The resulting sample had
a density of 0.63 g/cc, a nail pull index of 1.26 (58 lbs.) and a flexural strength of
675 lb/in2.
[0096] Low Viscosity Grade HPMC with 1:1 water: ß-calcium sulfate
hemihydrate ratio by weight. 100 parts of P-calcium sulfate hemihydrate was
mixed with 9 parts of HPMC (Aldrich, MW 10,000, viscosity grade 6 cps). The
mixture was then added to 100 parts of water and blended at high shear setting
for approximately 15 seconds. The resulting slurry poured directly into a form
measuring 2 inches by 5 inches by 0.5 inches. After setting, the mixture was
removed from the mold and cured at 45 °C for 2 days. The resulting sample had
a density of 0.59 g/cc, a nail pull index of 1.18 (47 lbs.) and a flexural strength of
535 lb/in2.
[0097] Moderate Range Viscosity Grade HPMC with a water: ß-
calcium sulfate hemihydrate ratio of 1.0 by weight. First, 100 parts of ß-calcium
sulfate hemihydrate was mixed with 9 parts of HPMC (Aldrich, MW 12,000,
viscosity grade 80-120 cps). The mixture was then added to 100 parts of water
and blended at high shear setting for approximately 15 seconds. The resulting
slurry was exceedingly viscous, prematurely setting during mixing and failing to
pour into the form. A spatula was used to transfer, in small portions, enough
slurry to fill a form measuring 2 inches by 5 inches by 0.5 inches. After setting,
the mixture was removed from the mold and cured at 45 °C for 2 days. The
resulting sample had a density of 0.75 g/cc, a nail pull index of 1.54 (121 lbs.)
and a flexural strength of 652 lb/in2.
[0098] High viscosity, surface-treated HEMC. A paperless sample
was prepared by mixing 1.3 kg of P-calcium sulfate hemihydrate with 1.69 g ball
mill ground gypsum (accelerator) and 26 g of retarded HEMC (viscosity grade of
15-20.5 kcps at 2 wt%, purchased from Aldrich Chemical Co.). The liquid
components, 1.68 kg room temperature tap water, 26 drops Daxad 19LKN
(dispersant) from Dow, and 13 drops 40% solution of
diethylenetriaminepentacetic acid sodium salt (retarder), were added to a 5 liter
Waring blender. The dry ingredients were added to the water and blended on
high for 15 seconds, forming a slurry. The slurry was then poured into an
approximately 12" x 12" x 1/2" glass mold with a thin teflon sheet on one face to
facilitate removal. The sample was removed from the mold after 15 minutes and
placed in a 45°C convection oven for 48 hrs. The sample was then removed and
cut into 5" x 2" specimens. These specimens were then weighed and measured.
The densities of nine specimens were calculated and the specimens were tested
for flexural strength and nail pull resistance on an Instron Mechanical testing
system using the methods previously described. The board had an average
density of 0.64 g/cc, a flexural strength of 809 psi, and a nail pull resistance of
102 lbs., passing ASTM flexural strength and nail pull requirements.
[0099] High viscosity, surface-treated HEMC. A paperless sample
was prepared by mixing 100 g of p-calcium sulfate hemihydrate with 0.13 g ball
mill ground gypsum (accelerator) and 1 g of retarded HEMC (viscosity grade of
15-20.5 kcps at 2 wt%, purchased from Aldrich Chemical Co.). The mixture was
then added to 150 g of water and blended on high for 15 seconds, forming a
slurry. The slurry was then poured into an approximately 7" x 2" x 1/2" mold.
The sample was removed from the mold after 15 minutes and placed in a 45°C
convection oven for 48 hrs. The sample was then removed and cut to 5" x 2".
The density of sample was calculated and it was tested for flexural strength and
nail pull resistance on an Instron mechanical testing system using the methods
previously described. The wallboard specimen had an average density of 0.63
g/cc, a flexural strength of 545 psi, and a nail pull resistance of 78 lbs., passing
the ASTM nail pull requirement.
[0100] High-viscosity, surface-treated HEMC. A paperless wallboard
is prepared using the following procedure. First, 150 g of ß-calcium sulfate
hemihydrate is dry mixed with 0.2 g ground gypsum and 3 g of surface-treated
(retarded dissolution) HEMC (15-20.5 kcps, purchased from Aldrich Chemical
Co.). The dry ingredients are added to 162 g of tap water in a 500mL Waring
blender, forming a slurry. The slurry is blended at low speed for 15 seconds. The
slurry is then immediately poured into a 7" x 2" x lA" mold and, after 20 minutes,
removed. The wallboard specimen is placed in a convection oven at 45 °C for at
least 36 hrs for drying. After removal from the oven, the sample is trimmed to 5"
long, weighed and dimensioned. A specimen prepared according to this
procedure had a density of 0.80 g/cc, a flexural strength of 975 psi, and a nail
pull resistance of 180 lbs., exceeding ASTM standards for flexural strength and
nail pull resistance for '/i-inch wallboard.
[0101] High viscosity, surface-treated HEMC. A paperless wallboard
is prepared using the following procedure. First, 150 grams of ß-calcium sulfate
hemihydrate is dry mixed with 0.2 g ground gypsum and 3 g of surface-treated
HEMC (15-20.5 kcps, purchased from Aldrich Chemical Co.). The dry
ingredients are then added to 150 g of tap water in a 500mL Waring blender,
forming a slurry. The slurry is blended at low speed for 15 seconds. The slurry is
then immediately poured into a 7" x 2" x 14" mold and, after 20 minutes,
removed. The wallboard specimen is placed in a convection oven at 45 °C for at
least 36 hrs for drying. After removal from the oven, the specimen is cut to 5"
long, weighed and dimensioned. A specimen prepared according to the foregoing
procedure had a density of 0.85 g/cc, a flexural strength of 989 psi, and a nail
pull resistance of 203 lbs., exceeding the ASTM standards for flexural strength
and nail pull resistance for 1/2-inch wallboard.
[0102] Although the present invention has been described in relation
to particular embodiments thereof, many other variations and modifications and
other uses will become apparent to those skilled in the art. It is preferred,
therefore, that the present invention be limited not by the specific disclosure
herein, but only by the appended claims.
-34-
WE CLAIM:
1. A reinforced wallboard core comprising : water; and dry ingredients, wherein
the dry ingredients comprise p-calcium sulfate hemihydrate powder and a powdered
additive and the dry ingredients are mixed together and mixed with the water, forming
a slurry and hydrating the P-calcium sulfate hemihydrate powder, wherein the
powdered additive is of a cellulose ether other than carboxymethyl cellulose, and the
cellulose ether is selected to have both a viscosity grade of at least about 100 cps and a
molecular weight of at least about 20,000, the average density of the wallboard core
being less than 0.8 g/cc, when dried.
2. The wallboard core as claimed in claim 1, wherein the cellulose ether is a
hydroxypropyl cellulose, a hydroxyethyl cellulose, a methyl cellulose, a
hydroxypropyl methyl cellulose, a ethyl hydroxyethyl cellulose, a ethyl hydroxypropyl
cellulose or a hydroxyethyl methyl cellulose.
3. The wallboard core core of claim 1 as claimed in claim 1 wherein the cellulose
ether is a .hydroxypropyl methyl cellulose.
4. The wallboard core as claimed in claim 1, wherein the cellulose ether is a
hydroxyethyl methyl cellulose.
5. The wallboard core as claimed in claim 1, wherein the cellulose ether is a
hydroxyethyl cellulose.
-35-
6. The wallboard core as claimed in claim 1, wherein the wallboard core comprises substantially
no clay.
7. The wallboard core as claimed in claim 4, wherein the wallboard core comprises substantially
no clay.
8. The wallboard core as claimed in claim 1, wherein the cellulose ether is a methyl cellulose.
9. The wallboard core as claimed in claim 8, wherein the methyl cellulose, is selected to have a
viscosity grade of at least about 400 cps.
10. The wallboard core as claimed in claim 1, wherein the amount of water to dry ingredients is
selected such that the average density of the wallboard core is less than 0.75 g/cc.
11. The wallboard core as claimed in claim 10, wherein the mixing causes dispersion of the
powdered additive throughout the ß-calcium sulfate hemihydrate powder, whereby the powdered
additive is evenly dispersed in the wallboard core.
12. The wallboard core as claimed in claim 10,wherein the density of the wallboard core is in a
range from 0.45 g/cc to 0.7 g/cc.
13. The wallboard core as claimed in claim 1, wherein the percent weight of additive to the P-
calcium sulfate hemihydrate powder is at least 0.5 wt %.
-36-
14. The wallboard core as claimed in claim 13, wherein the additive is selected, and the amount
of additive is selected, such that an addition of additive continuously increases the nail pull resistance
of the wallboard core.
15. The wallboard core as claimed in claim 13, wherein the percent weight of additive to the ß-
calcium sulfate hemihydrate powder is selected to be no greater than 3 wt %.
16. The wallboard core as claimed in claim 1, wherein the degree of substitution of the cellulose
ether is less than 1.8.
17. The wallboard core as claimed in claim 1, wherein the additive is surface treated to delay
dissolution.
18. A wallboard core comprising a ß-calcium sulfate hemihydrate powder and an aqueous
additive solution, wherein the ß-calcium sulfate hemihydrate powder is mixed with the aqueous
solution, forming a slurry and hydrating the ß-calcium sulfate hemihydrate powder, wherein the
aqueous additive solution comprises water and an additive dissolved in the water and the additive is
of a cellulose ether other than CMC, and the cellulose ether is selected to have both a viscosity grade
of at least about 100 cps and a molecular weight of at least about 20,000, the amount of water being
selected such that the wallboard core has a density less than 0.8 g/cc.

19. The wallboard core as claimed in claim 18, wherein the cellulose ether is a hydroxyethyl
cellulose, a methyl cellulose, a hydroxypropyl methyl cellulose, a ethyl hydroxyethyl cellulose, a
ethyl hydroxypropyl cellulose or a hydroxyethyl methyl cellulose, and the cellulose ether is selected
to have a viscosity grade of at least about 400 cps.
20. The wallboard core as claimed in claim 18, wherein the cellulose ether is a hydroxypropyl
methyl cellulose.
21. The wallboard core as claimed in claim 18, wherein the cellulose ether is a hydroxyethyl
methyl cellulose.
22. The wallboard core as claimed in claim 18, wherein the cellulose ether is a hydroxyethyl
cellulose.
23. The wallboard core as claimed in claim 18, wherein the wallboard has a density in a range
from 0.4 g/cc to 0.7 g/cc.
24. The wallboard core as claimed in claim 18, wherein the wallboard comprises substantially no
clay.
25. The wallboard core as claimed in claim 18, wherein the cellulose ether is a methyl cellulose
having a viscosity grade of at least about 400 cps.
-38-
26. The wallboard core as claimed in claim 25, wherein the methyl cellulose has a molecular
weight of at least about 40,000.
27. The wallboard core as claimed in claim 25, wherein the amount of water is selected such that
the wallboard core has a density less than 0. 75 g/cc.
28. The wallboard core as claimed in claim 18, wherein the cellulose ether is selected to have a
viscosity grade less than about 100, 000 cps.
29. The wallboard core as claimed in claim 18, wherein the percent weight of additive to the ß-
calcium sulfate hemihydrate powder is at least 0.5 wt %.
30. The wallboard core as claimed in claim 29, wherein the additive is selected, and the amount
of additive is selected, such that an addition of additional additive continuously increases the nail pull
resistance of the wallboard core.
31. The wallboard core as claimed in claim 29, wherein the percent weight of additive to the ß-
calcium sulfate hemihydrate powder is selected to be no greater than 3 wt %.
32. The wallboard core as claimed in claim 31, wherein the additive is selected, and the amount
of additive is selected, such that an addition of additional additive continuously increases the nail pull
resistance of the wallboard core.

33. A wallboard comprising the wallboard core as claimed in claim 1 and at least one face sheet.
34. The wallboard as claimed in claim 33, wherein the at least one face sheet is paper.
35. The wallboard as claimed in claim 34, wherein the paper is fiber reinforced.
36. The wallboard as claimed in claim 33, wherein the at least one face sheet is a polymer layer.
37. The wallboard as claimed in claim 36, wherein the polymer layer is formed in situ.
38. The wallboard as claimed in claim 33, wherein the at least one face sheet is decorative.
39. A process for making a wallboard core comprising: mixing together a P-calcium sulfate
hemihydrate powder and a powdered additive, until the powdered additive is dispersed throughout
the p-calcium sulfate hemihydrate powder, wherein the powdered additive is a cellulose ether other
than carboxymethyl cellulose and the cellulose ether has a molecular weight of at least about 20,000
and a viscosity grade of at least about 200 cps; adding the mixture of the P-calcium sulfate
hemihydrate powder and the powdered additive with an amount of water such that the resulting
wallboard core has a density less than 0.8 g/cc; forming a slurry by mixing the mixture of the ß-
calcium sulfate hemihydrate powder and the powdered additive with the water; extruding the slurry;
shaping the extrudate into an elongated sheet; and allowing the slurry to set, wherein at least a
portion of the p-calcium sulfate hemihydrate powder is hydrated.

40. The process as claimed in claim 39. wherein the steps of adding, forming and extruding are
continuous.
41. A process for making a wallboard core comprising: dissolving an additive in water to form an
aqueous solution, wherein the additive is a cellulose ether other than carboxymethyl cellulose and the
cellulose ether has a molecular weight of at least about 20,000 and a viscosity grade of at least about
200 cps; adding an amount of dry ingredients to an amount of the aqueous solution such that the
resulting wallboard has a density less than 0.8 g/cc, wherein the dry ingredients include a p-calcium
sulfate hemihydrate powder; forming a slurry by mixing the mixture of the P-calcium sulfate
hemihydrate powder and the powdered additive with the water; extruding the slurry; shaping the
extrudate into an elongated sheet; and allowing the slurry to set, wherein at least a portion of the ß-
calcium sulfate hemihydrate powder is hydrated.
42. The process as claimed in claim 41, wherein the steps of adding, forming and extruding are
continuous.
43. The wallboard core as claimed in claim 1, wherein the cellulose ether is selected to have both
a viscosity grade of at least about 400 cps and a molecular weight of at least about 40,000.
44. The wallboard core as claimed in claim 43, wherein the percent weight of cellulose ether to ß-
calcium sulfate hemihydrate is at least 0.5 wl %.
45. The wallboard core as claimed in claim 44, wherein the percent weight fraction of cellulose
ether to p-calcium sulfate hemihydrate is less than 3 wt %.
-41-
46. The wallboard as claimed in claim 33, wherein the at least one face sheet is a glass mat.
47. The wallboard as claimed in claim 33, wherein the density of the wallboard is in a range from
0.45 g/cc to 0.7 g/cc.
48. The wallboard core as claimed in claim 1, comprising a fiber reinforcement, wherein the fiber
reinforcement is mixed with the dry ingredients.
49. The wallboard core as claimed in claim 48, wherein the fiber reinforcement is a cellulose
fiber.
50. The wallboard core as claimed in claim 48, wherein the fiber reinforcement is one of a glass
fiber, a polymer fiber and a carbon fiber.
51. The wallboard core as claimed in claim 48, wherein the fiber reinforcement is one of a
polyester fiber and a nylon fiber.
52. The wallboard core as claimed in claim 48, wherein the fiber reinforcement has an elongated
axis and the elongated axis is oriented in the direction of extrusion.
53. The wallboard core as claimed in claim 1, wherein the surface of the wallboard core resists
the development of mold, showing no signs of mold growth after 24 days of exposure to mold spores
within an environment maintained at 90% humidity and a temperature of 32° C.

54. The wallboard as claimed in claim 33, wherein the surface of the wallboard resists the
development of mold, showing no signs of mold growth after 24 days of exposure to mold spores
within an environment maintained at 90% humidity and a temperature of 32° C.
55. A reinforced wallboard core comprising : water; and dry ingredients, wherein the dry
ingredients comprise ß-calcium sulfate hemihydrate powder and a powdered additive and the dry
ingredients are mixed together and mixed with the water, forming a slurry and hydrating the ß-
calcium sulfate hemihydrate powder, wherein the powdered additive is of a methyl cellulose, having
a degree of substitution in a range from 1.2 to 1.6, the average density of the wallboard core being
less than 0.8 g/cc. when dried.
A reinforced wallboard core is prepared from a slurry comprising a mixture of ß-calcium
sulfate hemihydrate, a cellulose ether additive other than CMC and an amount of water that is
sufficient to form a slurry and resulting in a wallboard density of less than 0.8 g/cc. The ß-calcium
sulfate hemihydrate is hydrated by the water forming a wallboard core reinforced by the cellulose
ether additive. The cellulose ether, having a molecular weight of at least about 20,000 and a viscosity
grade of at least 100 cps, is selected to give the reinforced wallboard core improved nail pull
resistance and greater flexural strength than unreinforced wallboard of the same density. The
reinforced wallboard core may be used for reduced-paper wallboard and / or for lightweight
wallboard, for example.

Documents:

1073-kolnp-2005-granted-abstract.pdf

1073-kolnp-2005-granted-assignment.pdf

1073-kolnp-2005-granted-claims.pdf

1073-kolnp-2005-granted-correspondence.pdf

1073-kolnp-2005-granted-description (complete).pdf

1073-kolnp-2005-granted-drawings.pdf

1073-kolnp-2005-granted-examination report.pdf

1073-kolnp-2005-granted-form 1.pdf

1073-kolnp-2005-granted-form 18.pdf

1073-kolnp-2005-granted-form 3.pdf

1073-kolnp-2005-granted-form 5.pdf

1073-kolnp-2005-granted-gpa.pdf

1073-kolnp-2005-granted-reply to examination report.pdf

1073-kolnp-2005-granted-specification.pdf

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Patent Number

223773

Indian Patent Application Number

01073/KOLNP/2005

PG Journal Number

39/2008

Publication Date

26-Sep-2008

Grant Date

23-Sep-2008

Date of Filing

06-Jun-2005

Name of Patentee

INNOVATIVE CONSTRUCTION AND BUILDING MATERIALS

Applicant Address

5764 SHELLMOUND STREET, EMERYVILLE, CA

Inventors:

#	Inventor's Name	Inventor's Address
1	TAGGE, CHRISTOPHER D	731 CHESTNUT STREET, #109, SAN CARLOS, CA 94070
2	POLLOCK, JACOB, FREAS	1622 WOOLSEY STREET, BERKELEY, CA 94703
3	TORRES, LENNARD	682 CONCORD PLACE, PLEASANTON, CA 94566
4	SOANE, DAVID, S.	109 KING AVENUE, PIEDMONT, CA 94610

PCT International Classification Number

C04B

PCT International Application Number

PCT/US2003/033496

PCT International Filing date

2003-10-31

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	10/351,675	2003-01-23	U.S.A.
2	60/425,924	2002-11-12	U.S.A.
3	10/446,571	2003-05-27	U.S.A.