NO162472B - PROCEDURE TO BE FOUND IS OF A POLYAMIDE FOUNDATION. - Google Patents

Abstract

1. Process for the preparation of compositions consisting of a polyamide matrix in which there is dispersed, in the form of particles whose average diameter is less than 5 micrometres, at least one thermoplastic reinforcing elastomer chosen from the group consisting of : (i) olefinic copolymers derived from an aliphatic alpha-olefin containing from 2 to 6 carbon atoms and from at least one compound belonging to the class of the alpha,beta-unsaturated mono- or dicarboxylic acids containing from 3 to 8 carbon atoms, the lower alkyl esters and the anhydrides derived from these acids ; (ii) olefinic copolymers containing carboxyl and/or carboxylate groups and derived from ethylene and from at least one alpha-olefin having from 3 to 6 carbon atoms ; (iii) olefinic copolymers containing carboxyl and/or carboxylate groups and derived from ethylene, from at least one alpha-olefin having from 3 to 6 carbon atoms and from at least one unconjugated aliphatic diene containing at least 5 carbon atoms ; (IVi) copolyesteramides obtained from (alpha) acid compounds consisting, on the one hand, of 1 to 100 mole % of dimeric fatty acids or their derivatives obtained by polymerization and fractionation of saturated or unsaturated aliphatic monoacids having from 8 to 24 carbon atoms, the content of monofunctional acids in these dimeric acids being less than 1% by weight and preferably less than 0.2% by weight, and their content of acids containing more than 2 functional groups being less than 5% by weight and preferably less than 3% by weight, and, on the other hand, of 99 to 0 mole % of other difunctional acids chosen from diacids, aminoacids, hydroxyacids and their derivatives forming esters or amides (beta) dihydroxy compounds and (gamma) diamino compounds or aminoalcohols or mixtures of diamino compounds and aminoalcohols, it being possible for the compounds (gamma) to be omitted in the case where the acid compounds (alpha) already contain an amino reactant ; (Vi) mixtures of these copolymers with one another in variable proportions ; (VIi) and mixtures of at least one of the copolymers (i) to (IVi) with a polyolefin or copolyolefin which has a flexural modulus lower than 100 Mpa, the said process being characterized in that it comprises the following steps : (a) a masterbatch is first produced by dispersing the elastomer or elastomers in a polyamino-acid obtained either by direct homopolycondensation of omega-aminoalkanoic acids containing a hydrocarbon chain having from 4 to 12 carbon atoms, or by hydrolytic opening and polymerization of the lactams derived from these acids, and (b) this masterbatch is then diluted with a polyamide, intended to be reinforced, chosen from the group consisting of : polyamides produced by polycondensation of saturated aliphatic dicarboxylic acids having from 6 to 12 carbon atoms with saturated aliphatic diprimary diamines having from 6 to 12 carbon atoms ; copolyamides produced from the starting monomers of the abovementioned polyamides, it being additionally possible for the acid component of these copolyamides to consist partly of terephthalic acid and/or isophthalic acid ; and mixtures of these polyamides.

Description

Method for the production of slabs of rapidly solidifying molding compound.

The invention relates to a method for the production of sheets of fast-setting stoping compound such as gypsum, with a single-sided or double-sided coating of fibrous material, such as paper or cardboard.

Boards containing fast-setting stoping compound are known, plaster boards being among the most common. These boards are most often sold with the main rafts coated with cardboard. The currently known machines for the production of cardboard-clad gypsum boards comprise a relatively long, endless belt, the speed of which is adjusted so that the board is solidified and can be handled at the far end of the belt. During production, the lower cardboard is fed forward as an endless strip with folded edges, and the stop compound is poured onto the cardboard and the surface is leveled with a scraper, roller etc., after which the top cardboard is also applied in the form of an endless strip.

The thinnest plates that are normally produced have a thickness of

about. 9 mm and a surface weight in an air-dried state of approx. 9 kg/m o. The cardboard weight in this case is a total of approx. 700 - 800 g/m 2, and each cardboard layer has a thickness of approx. 0.4 mm.

Such thin plasterboards have also been produced without cardboard cladding, as a quantity of fibrous material equal to or greater than the cardboard weight (of the order of 20% of the board's total weight) has been mixed into the plaster mass. However, such a plaster mass cannot advantageously be stopped in endless bands without the mass being slurried in a trough, which contains a rotating cylindrical sieve on the surface of which the mass is deposited, after which it is degassed with the help of a rubber roller or the like against the sieve. When the stop compound on the roller has acquired the desired thickness, which is only achieved after several revolutions of the roller, the stop compound is cut through in the longitudinal direction of the roller, whereby a plate is obtained whose dimensions depend on the circumference and width of the roller.

The disadvantages of this method are, first and foremost, that the layers of stop compound closest to the roll may have already begun to solidify during the cut-off, whereby the plate becomes of poorer quality, as fractures often occur in this half-solidified part of the stop compound when it is removed from the cylinder after cutting and straightened into a plate. In principle and from the point of view of holding strength, the method also entails a deterioration compared to the known cardboard-clad plasterboards in that the paper fibers are not concentrated in the surfaces of the board. As the tangled paper fibers have significantly greater tensile strength than the plaster mass, it is of course an advantage is that the fibers are concentrated in the surface layers, thereby achieving higher bending strength.

However, even the known cardboard-clad plasterboards have certain disadvantages. The adhesion between cardboard and plaster is not always good, and this leads to poorer holding properties. The manufacturer is also referred to the types of cardboard and the colors that are marketed, and a board manufacturer that uses high quality plaster cannot compensate the price calculation by choosing a thinner cardboard. The plate available is not particularly refractory. The cardboard is also very cost-effective compared to the price of the stop compound, normally 2-4 times more expensive than this, calculated per m 2 finished board.

These cardboard-covered sheets of fast-setting stoping compound, e.g. plaster, has advantages over boards without either a cardboard or cardboard substrate or a covering with cardboard or cardboard. These advantages are, above all, that the plate after solidification and possible drying is considerably stiffer and has greater breaking strength. Thereby, the plate's thickness has been reduced, and considerable elasticity has thereby been achieved. This is important when handling on construction sites, etc. With the cardboard covering, the board has also become better suited for spicing.

It has now been shown that the stated disadvantages can be eliminated by a plate which, according to the invention, is produced by placing the stop compound on a wet sheet of fibrous material with a dry matter content of a maximum of 50% and then possibly placing another wet sheet on the surface of the stop compound and that the plate produced in this way is allowed to harden and dry.

The slab's solidification and drying as well as its longitudinal and edge cutting take place in a manner known per se, i.e. e.g. by causing a plasterboard to move until it has solidified sufficiently for longitudinal and edge cutting.

The invention is described in more detail with reference to the drawings, where, Fig. 1 schematically shows, seen from the side, a machine for the production of a plate-containing, fast-setting stoping compound.

Fig. 2 is a view along the line II - II in fig. 1.

Fig. 3 is a section through a plate according to the invention.

Fig. 4 shows schematically from the side another machine for producing a plate according to the invention. Fig. 5 is a section through a machine for producing one plate according to the invention. Fig. 6 finally shows in 6a and 6b in section a plate according to the invention, and in 6c and 6d the same plate seen from above.

The machine according to fig. 1 shows an inlet box 1, from which fibrous material flows out onto a wire 2, which is carried by register rollers 3. The wet sheet formed on the wire 2 is sucked off by a suction box 4. Gypsum is stopped on the wet sheet at 5, and the combined plaster-mass sheet is sucked off at suction boxes 6.

The web of gypsum and fiber mass formed by the first part of the wire is placed at 7 on a wet sheet, which has been shaped on a wire 8. This wet sheet is produced analogously to the underlying wet sheet and is thus sponged onto the gypsum mass at 7. At 9, the composite is transferred sheet (web) to another conveyor belt 10, on which the sheet is during solidification and drying. The web is then cut into suitable lengths after any edge cutting.

In fig. 2 shows how the sheet of gypsum and wet sheet 12 is limited by cover straps 11. The composite sheet 12 rests against the wire 2, which is in turn carried by register rollers 3.

The plate obtained in this way has, on average, the appearance shown in fig. 3, where A and E make up the upper and lower fiber layers, and where B makes up the congealed and possibly dried stoping mass. By modifying the specified manufacturing method somewhat, a plate can also be obtained in principle according to fig. 6. This has been produced in such a way that, after applying a small amount of stop compound to the lower fiber web, an intermediate layer C is applied on top of the stop compound, preferably insulating, consisting of cellulose fibres, wood fibres, sawdust, shavings, bark waste, glass fiber, stone wool , crushed brick, crushed coal, expanded cement, foam rubber, foam plastic or other heat-insulating materials. This layer can cover the entire surface of the newly-stopped mass without interruption, or it can be carried out according to one of the forms in fig. 6b, c and d. According to fig. 6b, the insulating layer is applied at certain intervals in the transverse direction of the plate and according to fig. 6c with similar spaces F in the longitudinal direction. In fig. 6d shows embodiments where openings G, H and I are arranged in the insulation layer. These openings can have different shapes. In these spaces and openings, the later-stopped upper stop compound B penetrates down, and the plate thereby becomes stiffer. In fig. 6, A is the upper fiber layer, B the upper stop compound, C the insulation layer, D the lower stop compound and E the lower fiber layer.

The insulating compound can be applied as an endless band which is possibly divided during the coating or in the form of several endless bands possibly provided with holes or the like. The layer C can also be strung, rolled or laid on top of the stop layer D. When the upper stop compound B is applied, the slab is therefore stiffened by the stop compound penetrating into the spaces F, G, H, J, K etc.

The insulation layer C can also be applied in several layers with intermediate applied stop compound in the same way as the one just mentioned. This results in a better thermal insulation ability for the plate.

The plate obtained in this way (which can be in the form of a belt) can then be further drained of water, possibly through the overlying fiber layer and/or subjected to dewatering and/or pressing to a final thickness between press rollers or press belts, which can be covered with wires, rubber, felt etc.

The wet sheet according to the invention often has a relatively low dry weight compared to the dry weight of the stopping mass and is preferably less than 1/4 of the dry weight of the stopping mass. The plate (plate strip) can be coated with material that increases the appearance, fire resistance, holding strength, etc., and this coating is preferably carried out before the plate has had time to solidify. After the plates are solidified, they are preferably dried in a suitable manner to remove excess water.

The overlying wet sheet can also be formed directly on the stop compound by the fiber suspension e.g. is placed on the stop compound and that the excess water from the fiber suspension is sucked directly through the stop compound and the underlying wet sheet.

A plate according to fig. 6 is preferably produced by stopping the stop compound D on the fiber web E, on which the insulating layer C is applied and then another layer D is stopped which is applied to the fiber web A. However, one can also think of other methods of production, e.g. so that layers A, B and C are formed on one machine and then layers D and E are added which are formed on another machine.

The machine according to fig. 4 can of course in principle produce plates of the same simple structure as the machine according to fig. 1, and the machine according to fig. 1 can also be changed to produce plates of a more complicated structure.

The machine according to fig. 4 consists of two parts for manufacturing the lower resp. upper fiber path. These parts consist of containers 1 in which sieve cylinders 2 are immersed, and the fiber suspension, preferably suspended in water, is supplied via the main line 3 to the inlet 4, and the rotational speed of the e.g. wire-clad cylinder 2 is adapted so that a high level is obtained in the container 1 and a low liquid level in the cylinder. Thereby, a fiber layer is deposited on the surface of the cylinder 2.

The fiber layer is degummed with the help of a felt 6 which is pressed by a roller 5, and the felt can be stretched with the device 8 and washed with the device 7. Felt with an adherent fiber layer is further dewatered in the press 13, and the fiber layer can be further dewatered in one or more presses 14.

The fiber layer can be provided with reinforcing fabric or threads which are unwound from the roll 10 around the cylinder 2, possibly under pretension (whereby the plate becomes stronger). Addition of glue, colour, plaster, cement etc. to further strengthen or improve the fiber layer's properties and binding ability to the stoping compound can be applied from containers 12 via the rudder 11.

The fiber layer 15 is transferred to a conveyor belt, a runway or the like. with rollers 18 and possibly buoyancy devices 17 on which the mass is stopped from the stirrer container 19 via rudder 20 in the manner just mentioned in connection with fig. 1.

The insulation material is then applied, e.g. from a roller 24 over an application roller 25 and any adhesive or other additives are fed into the suspension through the rudder 26.

The upper stoping compound is then applied from the container 19 through the pipes 20. In cases where the stoping compound consists of gypsum suspension, dry gypsum is supplied through the pipe 23 and water through the pipe 22 which is mixed by a fast-moving stirrer driven by the motor 21.

Finally, the upper fiber web 15 which has been produced on a similar machine (consisting of one or more screen cylinders) is applied as the lower fiber layer. The upper fiber layer is applied by the roller 27, and a leveling of the plate's upper side can take place with the help of an optionally pressed ruler 28. The finished plate 29 is transported further on the belt so that the stop compound has time to solidify and become manageable. Any excess water can then be removed by drying, possibly after the plate has been cut into suitable lengths.

Claims (4)

1. Process for the production of sheets of fast-setting stoping compounds, such as gypsum, with a single-sided or double-sided coating of fibrous material, such as paper or cardboard, characterized in that the stopping compound is placed on a wet sheet of fibrous material with a dry matter content of a maximum of 50% and that then, if necessary, another wet sheet is placed on the surface of the stop compound and that the sheet produced in this way is brought to harden and dry. 2. Method as stated in claim 1, characterized in that the fibrous material consists of cellulose pulp. 3. Method as specified in claim 1 or 2, characterized in that the plate for solidification is uncoated with a material which "enhances the appearance, fire resistance, holding strength and the like. 4. Method as specified in any of claims 1-3, characterized in that a reinforcement layer is placed on at least one side of the stoping compound layer.