GB2035286A - Glass fiber reinforced cements and process for manufacture of same - Google Patents

Abstract

A fiber reinforced cementitious product comprises a cement as a continuous phase and fibres dispersed as reinforcement in the continuous phase, the product including a polyelectrolyte and a finely divided inorganic material having a high surface area present in (a) admixture with the cement, (b) as a size coating on the fibers or (c) both. The fibers are preferably glass but may also be other natural and synthetic inorganic and organic fibres. The inorganic material may be pentonite, fumed silica or diatomaceous earth. The cementitious product may be made by Hatschek, Magniani, or filter press processes.

Description

SPECIFICATION Glass fiber reinforced cements and process for manufacture of same This invention relates to reinforced cements and to compositions for use in the manufacture of reinforced cementitious products.

It is now well known that various fibers can be used in the reinforcement of cementitious products. One of the more well-known reinforced cementitious products is cement reinforced with asbestos fibers. The asbestos fibers are combined with cement in the form of a built-up laminate to provide a reinforced product, such as cement pipes and cement sheets or boards and the like, having good strength characteristics.

In the manufacture of such asbestos fiber reinforced cementitious products, two processes are well-known to those skilled in the art. The first is the so-called Hatschek process for the production of reinforced cementitious pipe and the second is the Magniani process for the production of boards formed of reinforced cement. In both of the processes, asbestos fibers are mixed with a cement slurry to form a pulp, and then the pulp is placed onto a foraminous forming member (a cylinder in the case of the Hatschek process and a flat, usually endless, belt in the Magniani process). Moisture from the slurry is removed by applying suction thereto whereby water is drawn through the foraminous forming member.

The mechanism underlying the effectiveness of asbestos fibers in the manufacture of reinforced cementitious products is not fully understood at the present time. The asbestos reinforcement appears to maintain, to at least some degree, the retention of water as the reinforced cement product is being manufactured to prevent excessive dehydration or dewatering which would cause the cement product to crumble.

It has been hypothesized that the high surface activity of asbestos fibers makes them highly reactive to retain small cement particles along with water to prevent cement from being carried off with the water during dehydration or dewatering on the foraminous support. That high reactivity is accentuated by the fact that the asbestos fibers have a high specific surface arsea (viz., of the order of 10-20 m2/g.). Thus, the highly reactive surfaces of the asbestos fibers are believed to flocculate the cement and retain it to provide a reinforced cement product having good structural strengths.

Various attempts have been made to omit asbestos from such reinforced cementitious products but without success. In the absence of the asbestos fibers dispersed in the cementitious material, the rate at which water is removed so that the cementitious product can be cured is significantly increased. In addition, the green strength of the reinforced cementitious product, before cure, is drastically reduced as a result of excessive dewatering resulting in delamination.

In addition to Hatschek or Magniani processes the invention is suitable for practice in filter press process.

It has been proposed, in French Patent No. 2,317,250, to partially replace asbestos fibers with glass fibers.

Even that technique has not met with any appreciable success. Glass fibers, when combined with cementitious materials in the manufacture of reinforced cementitious products have a tendency to adhere together, remaining in bundles, thereby disturbing the rate at which water can be removed through the foraminous forming member. In general, the presence of glass fibers in such reinforced cement products makes such products, in the hydrated state, too porous and causes the water present in the cement slurry to be removed too rapidly, carrying with it large quantities of the cement itself. Because glass fibers have quite low surface areas (of the order of 0.1-0.2m2/g.), they do not share in the ability of asbestos to retain either cement or water.Thus, it has not been possible, up to the present invention to form, on a Hatschek machine, reinforced cement products containing more than 2% by weight of glass fibers.

It is accordingly an object of this invention to provide a method for producing and to produce glass fiber-reinforced cementitious products.

It is a more specific object of this invention to provide treated glass fibers and a size composition for use in the manufacture of same wherein the size coating on the glass fibers and additives to the cementitious slurry enable the glass fibers to be distributed through a cementitious pulp and thereby regulate the rate at which water is drawn therefrom in the manufacture of glass fiber-reinforced cementitious products.

It is yet another object of the invention to provide an improved process for forming fiber reinforced cementitious products wherein glass fibers are blended with cementitious materials and then formed into a glass fiber reinforced cementitious product.

The concepts of the present invention reside in the discovery that glass fibers can be employed as reinforcement in the manufacture of reinforced cementitious products when cement system includes, as a component of the size on the glass fiber surfaces or as a component of the cement slurry (or both), an inorganic, finely divided particulate material having a high surface area in combination with polyelectrolytes.

It has been unexpectedly found that the presence of the inorganic material and the polyelectrolyte serve to markedly increase the amount of cement particles and water retained by the glass fibers. It is therefore possible to produce, when desired, a glass fiber reinforced cement product containing as much as 30% glass fibers by weight, all without adversely affecting the structural properties of the reinforced product.

In the preferred practice of the invention, glass fibers which may or may not have been previously sized (as in forming) are sized with a size composition containing, as the essential ingredients, the inorganic material and the polyelectrolyte. The glass fibers are then laid down on a foraminous support member with a cement slurry which has also been formulated with the inorganic material and polyeiectrolyte(s). Water is then removed in a conventional manner (as by applying a vacuum to the foraminous support) to effect partial dehydration or dewatering of the glass fiber-cement composite after curing, the result is a fiber reinforced-cement product having high structural strengths.

As the inorganic material, use is preferably made of a finely divided siliceous material having a small particle size, preferably less than 10 microns, and a high specific surface area (i.e.} surface areas greater than 20 m2/g and most preferably in the range of 75-500 m2/g). Best results have been obtained with a specially treated Pentonite known as Altonit.

Good results can also be achieved with fumed silica, diatomaceous earth or like silicas.

The term "polyelectrolyte" includes flocculating agents, such materials which have been found to provide good results are the flocculating agents Hercofloc 900 or Delfloc 50-V, both of which are commercially available. Surfactants and wetting agents may be used together with the polyelectrolytes.

The total amount of inorganic material employed is not critical, and can be varied within relatively wide limits. Best results are usually obtained when the inorganic material employed constitutes from 5 to 50 % by weight, based on the weight of the cement employed, and preferably 10 to 25 % by weight. Similarly, the amount of the polyelectrolyte can be varied usually within the range of 0.01 to 1% by weight based on the weight of the cement employed.

Where, in the preferred embodiment, the inorganic material is present in a size applied to the glass fibers, the size composition is formulated, on a solid basis, to include from 10 to 75 % inorganic material and 1 to 25 % polyelectrolyte. It is sometimes preferred to formulate the size with film-former which is compatible with the polyelectrolyte. Suitable are starches or similar film-formers and/or vinyl resins. One vinyi resin which provides good results is polyvinyl alcohol such as "Mowiol 4.88" from Hoechst AG, Germany.

In addition, the size can be formulated to include other conventional additives such as glass fiber lubricants, wetting agents, etc. Suitable lubricants include Sodamine or Emerlube 7484. The amount of the film-former generally ranges from 5-35 % by weight and the lubricant from 1.0 to 15 %, based on the solids content of the size. The size is applied to the glass fibers in amounts ranging from .1 to 25 % solids by weight based on the weight of the glass fibers. If the fibers are used without additives to the cementitious siurry, the solids of glass sizing will be in the range of 5 to 200 % or more of glass weight.

In the application of the size composition to glass fibers, use can be made of any of a variety of known application techniques. For example, the glass fibers can be passed in contact with a roller wet with one of the size compositions. Alternatively, the size compositions can be sprayed onto the glass fibers.

Glass fibers used in the practice of this invention can be "E" glass fibers, well known to those skilled in the art, such fibers are described in U.S. Patent No. 2,334,961. Preferred glass fibers used in the practice of this invention, however, are alkali resistant glass fibers. Such glass fibers are now well-known to those skilled in the art, and are described in U.S. Patent Nos. 3,840,379,3,861,927 and 3,861,926.

In combining glass fibers treated in accordance with this invention with cementitious material, use can be made of any of a number of cements of the same type employed in the art. Suitable cementitious materials include cement, Portland cement, concrete, mortar, gypsum, hydrous calcium silicate, etc. The treated glass fibers, generally in an amount ranging from 1 to 25 % by weight based upon the weight of the cement are blended with a cement slurry, either with or without the addition of other fibers such as asbestos fibers.

When such other fibers are used, they are generally present in an amount ranging from 1-10% by weight based upon the weight of the cementitious material. The pulp resulting from blending the fibers and the cementitious material is then placed in contact with a foraminous forming member in accordance with the well-known Hatschek or Magniani processes and a vacuum applied to the foraminous member to remove water from the fiber reinforced cementitious product. The product is then cured in accordance with conventional techniques.

The resulting fiber reinforced cementitious product is characterized by high strength, and can be used as various building materials in accordance with well-known principles of the prior art.

Having described the basic concepts of the invention, reference is now made to the following examples which are provided by way of illustration and not by way of limitation, of the practice of this invention in the treatment of glass fibers with the size compositions of this invention and the use of the treated glass fibers in the manufacture of glass fiber-reinforced cementitious products.

Example 1.

This example illustrates the preparation and use of a size composition in accordance with the concepts of this invention.

A size composition is formulated as follows: Parts by weight Polyvinyl alcohol (Mowiol 4.88) 14.0 Altonit 18.0 Lubricant (Emerlube 7484) 4.3 Flocculating agents : Delfloc 50-V 5.0 Hercofloc 900 1.0 The above size composition is combined with water to make up a suspension having a solids content of 2.5 % by weight solids.

The foregoing size composition is applied to glass fibers by roller coating. The resulting fibers coated with the size composition have a gel-like coating on the surfaces thereof, the coating exhibiting good adhesion to the glass fiber surfaces.

Example 2.

This example illustrates the use of glass fibers treated in accordance with the practice of this invention in the manufacture of glass fiber-reinforced cementitious pipe or sheet.

Glass fibers treated in accordance with Example 1 are blended with a cement composition having the following composition: Cement Composition Parts by weight Cement 800 Altonit 140 Hercofloc 900 0.4 Water 8000 The glass fibers, chopped to lengths of about 1/8 to 3 inches, are employed in an amount corresponding to about 10% by weight based upon the weight of the cement. The pulp thus formed is then processed in the known way in a Hatschek machine to form fiber reinforced cement pipes or sheets having good strength characteristics. This may include the use of additional polyelectrolytes.

While the foregoing description is based on the use of glass fibers as reinforcement, it will be understood that the concepts of the present invention lend themselves to the use of other fibers, including natural and synthetic organic and inorganic fibers, such as wool, dacron, nylon, polyester fibers, metal, etc.

The invention may be practiced to allow the use of mineral fibers, particularly glass fibers in paper-making systems and in wet process board and mat systems by improving the processability characteristics of such inorganic fibers.

It will be understood that various changes and modifications can be made in the details of procedure, formulation and use without departing from the spirit of the invention, especially as defined in the following

Claims (21)

claims. CLAIMS

1. A fiber reinforced cementitious product comprising a cement as a continuous phase and fibers dispersed as reinforcement in the continuous phase, with said product including a polyelectrolyte and a finely divided inorganic material having a high surface area present in (a) admixture with the cement, (b) as a size coating on the fibers or (c) both.

2. A product as defined in claim 1 wherein the fibers are glass fibers.

3. A product as defined in claim 1 or claim 2 wherein the inorganic material is a siliceous material having a specific surface area greater than 20 m2/g.

4. A product as defined in any preceding claim wherein the inorganic material comprises one or more of silica, a Pentonite and a diatomaceous earth.

5. A product as defined in any preceding claim wherein the glass fibers are present in an amount up to 30% by weight based on the weight of the cement.

6. A product as defined in any preceding claim wherein the inorganic material is Pentonite.

7. A product as defined in any preceding claim wherein the polyelectrolyte is selected from surfactants, wetting agents and flocculating agents.

8. A product as defined in any preceding claim wherein the polyelectrolyte and the inorganic material are present as size coating on the fibers and wherein the size coating also includes a lubricant.

9. A product as defined in any preceding claim wherein the polyelectrolyte and the inorganic material are present as size coating on the fibers and the size coating also includes a film-forming resin.

10. A product as defined in claim 1 substantially as disclosed herein with reference to Example 2.

11. Glass fibers for use as reinforcement for cementitious materials comprising glass fibers having a size coating thereon, said coating comprising a polyelectrolyte and a finely divided inorganic siliceous material having a specific surface area greater than 20 m2/g.

12. Glass fibers as defined in claim 11 wherein the inorganic material is Pentonite.

13. Glass fibers as defined in claim 11 or claim 12 wherein the size coating also includes a film-forming resin.

14. glass fibers as defined in claim 12 substantially as disclosed herein with reference to Example 1.

15. A process for the manufacture of fiber reinforced cementitious products wherein fibers are mixed with a cementitious material to form a pulp, the pulp is contacted with a foraminous forming member from which water is withdrawn to form a green product and the green product is cured, wherein either the cementitious material or the glass fibers contains a polyelectrolyte and a finely devided inorganic material having a high surface area.

16. A process for the manufacture of glass fiber-reinforced cementitious products wherein glass fibers are mixed with a cementitious material to form a pulp, the pulp is contacted with a foraminous forming member from which water is withdrawn to form a green product and the green product is cured, the improvement comprising mixing glass fibers having a size coating thereon, said coating containing a polyelectrolyte and a finely divided inorganic siliceous material having a surface area greaterthan 20 m2/g, with a cement composition containing cement, said polyeiectrolyte and said inorganic material.

17. A process as defined in claim 15 or claim 16 wherein the fibers are glass fibers.

18. A process as defined in any of claims 15 to 17 whrein the polyelectrolyte is selected from surfactants, wetting agents, and floculating agents.

19. A process as defined in any of claims 15 to 18 wherein the inorganic material is a Pentonite.

20. A process as defined in claim 19 wherein the size coating also includes a film-forming resin.

21. A process as defined in claim 16 substantially as disclosed herein with reference to Example 2.