DE4325267A1 - Producing of thermal insulation from glass fibres - Google Patents

Abstract

Glass or mineral fibres are produced for insulating materials from liquid glass which is pressed through a number of perforations in a revolving plate. Before or while the fibres are cooled they are sprayed with a (6-8%) silicone binder substance which renders them hydrophobic and with a long chain type starch. They are finally dried and formed into sheets or rollers. An emulsion of silicone resin, silicone oil, a dust-laying agent and the starch (polysaccharides) is produced, this is atomised at 18-200 deg.C and then sprayed on the glass fibres. The emulsion pref. contains another resin, silane catalyst and epoxy, methylone or polyester or similar.

Description

The invention relates to a method for manufacturing of glass fibers or mineral fibers for insulation materials made from liquid glass are produced by a variety of Openings of a rotary plate is pressed, whereupon the glass fibers before or when cooling with a water repellent and a binder (6 to 8%) made of silicone and a long-chain starch sprayed and then drying and shaping to be subjected to plates or rolls according to patent (patent registration P 42 22 444.6).

In the production of insulation materials, the liquid Glass pushed through the openings of a rotary plate, that rotates at high speed. The correspond Correspondingly fine glass fibers are then rinsed off with water and sprayed with a binder so that the individual Glass fibers are then folded into mats or rolls can be and remain in this shape, if they leave the drying oven. It is known a binder made essentially of vinyl resin and silicone use, the end products then through the resin get intense yellow color. The disadvantage here is that the resin during later processing or during Use as insulation can partially escape, causing environmental problems arise. From the European patent 129 227 a binder is known which consists of starch, other substances such as silicone are added become. This product is used as a binder for paper, Insulating material, plastic, textiles etc. used. Out US Pat. No. 5,006,140 is finally known to the glass fibers after spraying with water with a binder spray mixture of starch and silicone. Here is one obviously proceeded in the same way as when using it of vinyl resin by using about 4 to 4.5% binder sprayed onto the glass fibers. There is one white fiberglass mat that is rolled up and processed which, however, has areas where it is partially  or collapses completely and especially unsatisfied has spatial densities. The liquid starch which is sprayed onto the glass fibers with the silicone tends to form lumps, so that in addition spraying is complicated by the nozzles. Finally it comes down to medium life to precipitate, so that the bandage medium mixture can no longer be used at all. According to Main patent will use a long chain starch as starch det heated to 50 to 60 ° C and at this temperature is held until spraying. By even order stirring prevents the formation of lumps, so that a flawless processing is ensured. By adding ent speaking high amounts of binder, namely 6 to 8%, a consistently processable glass wool is produced, so that this method now also for the production of Insulation materials is suitable. The insulation mats produced or rollers can after the curing process, d. H. after this Leave the drying oven stored and then later ver be working. The disadvantage is that due to the use upcoming organic products the service life of such Insulation materials are limited. Nor is it possible to recycle tes material because the fibers produced are not can be integrated evenly throughout.

The invention is therefore based on the object the known method of applying the binder to optimize and the life of such fibers to ensure when using recycling material.

The object is achieved in that made of silicone resin, silicone oil, a dust binder and the Starch (polysaccharides) creates an emulsion and this then atomized at a temperature of 18 to 200 ° C and is sprayed onto the glass fibers passed by.

The process in turn results in an advantageous environment friendly insulation mat or corresponding  Insulation rolls, using the evenly prepared and always the same dosed emulsion constant formation of the corresponding fibers secured, so that now recycled material is used can be. The correspondingly sprayed and Glass fibers prepared for solidification can be due to the treatment according to the invention over the entire width and length are compressed evenly so that they are the Properties intended for use as insulation fully meet. Silicone resin, silicone oil and the like Dust binders are mixed with the starch works and kept at temperature and then with one corresponding temperature to the flowing or sprayed glass fibers. Because these glass fibers the spray nozzles from all sides are directed towards the fiberglass strand and a corresponding temperature the even distribution ensuring the emulsion on the fiber is another one Processing of glass fibers into mats and plates and rolls possible without problems. The drying temperature is 180 to 220 ° C and is in the appropriately trained dry maintenance furnace, in order to solidify the mats or to ensure roles.

An expedient embodiment of the invention provides that the emulsion of silicone resin, dust binder, starch, Synthetic resin and silane made as a catalyst and then is sprayed onto the glass fibers. Because of the silane given the possibility of organic and inorganic substances to connect so effectively that a uniform Resin-silane emulsion is formed, which then ver works, d. H. can be sprayed onto the glass fibers. The use of synthetic resin has the advantage that higher stand times are achieved because the organic parts of the Binder correspondingly lower or by use are stabilized with synthetic resin.  

It is particularly useful if the synthetic resin Starch partially or completely replacing epoxy, methylon, polyester Resin or synthetic resins with the same or a similar effect are used become. One can be made of this material particularly well Generate moderate emulsion, in addition to the epoxy and the associated hardener the emulsion in connection with Polydimethylsiloxanes, methylpolysiloxanes or silicon methyl resin emulsions for simultaneous waterproofing and binding Should be used. With complete replacement of the Starch with epoxy resin is not only very stable Produced lized, yet flexible glass fiber fabric, but also a particularly long service life Product. This product is just for use ideal as insulation because it is influenced by tempera ture, moisture or other is not possible. Also outgassing or the like is not possible, so that such Insulation material is particularly environmentally friendly. Purely theoretically it is possible to use such insulation material after use by simply washing with water to remove dust or the like, reinsert, d. H. so to recycle. This makes environmental friendliness even more emphasized.

To form the glass wool correspondingly produced To be able to give mats or rolls and the desired one She sees being able to maintain spatial density exactly Invention before that the glass fibers as known per se End of the chute summarized and between endless link belts with simultaneous hardening on the pre seen bulk density pressed and then cut off of the supernatant are lined laterally. Usually will the hemming is done after leaving the tunnel oven, during the shaping, if necessary, by warmed endless links belts is made to prevent the mats from sticking to the to avoid individual links of the ligaments. Conveniently the curing and shaping is carried out in combination.  

To the use of the insulation material in particular in the form of plates, especially for plates lower spatial density, the invention provides that the glass fiber mat has a thin glass fleece on all or all sides applied, preferably glued. This glass fleece maintains the shape of the mats disadvantageously without their effect to influence. It facilitates both storage and also the later processing.

The amount of binder applied is also when using epoxy resin approx. 6 to 10%. It is the use of waste glass is possible because in particular that Epoxy resin in combination with the silicone as an optimal Binder works. To vary the proportion of waste glass and the respective to be able to adapt to your needs accordingly the invention that 6 to 9 wt .-% epoxy resin, 0.5 to 4 wt .-% silicone and a dust binder are mixed and that the proportions increase with increasing proportion of used glass to get voted. Ultimately, when using up to 10% by weight epoxy resin, the use of 100% waste glass is possible. Because of the better adhesive effect of the epoxy resin in contrast to the phenolic resin according to the previously known Procedure or procedure according to the main patent with starch an insulating material made from 100% waste glass or recycled material be used. This is an important one for the environment Step taken because it has not been possible to date, the total together with the amount of waste glass to be reached also 100% recycle. It is particularly advantageous that from such Recycled material now produces a high quality end product can also guarantee a long service life So don't be recycling again in the foreseeable future product arises.

Where, for some reason, still recycling the correspondingly made materials from glass fibers is necessary, the invention provides that the glass fiber recovered after intended use, at 850  1000 ° C transferred into the glass melt and back to glass fibers is processed. The glass material is in circulation used several times, the binder proportions, i.e. H. Epoxy resin and silicone as well as dust binder through the Heating process neutralized up to 1000 ° C or harmless be made. Then there is an optical fiber available, which in turn are then processed with a Provide binder and reprocessed and used can be.

Where, for some reason, contamination of the glass fibers have occurred, in particular, for example Through use in construction, it can be beneficial if the glass fiber is recovered after the intended use, transferred to the glass melt at 850 to 1400 ° C and removed cools and is disposed of as a glass block or crushed material. Here it is also possible to use this crushed material or the glass blocks re-use elsewhere, for example in Road construction. Due to the high temperature influence on the glass all possible pollutants from the glass fiber dissolved, so that a glass melt or a material is available that another Processing at least a proper disposal can be supplied, especially at correspondingly lower Temperatures pollutants easily into the glass melt involved and then harmless and environmentally friendly be deposited.

The invention is characterized in that a ver better process is created over the glass fibers made partly or entirely from waste glass which are then processed into insulation material, which as not only the usual good insulation properties points, but also easily due to its service life can be used in the long term. A release from Parts of the binder are excluded. Is also one Influence by moisture is not possible because that  Material through which silicone is hydrophobic. The correspond Glass fiber insulation mats made from waste glass are suitable for a wide variety of uses the manufacturing process gives the opportunity to share of waste glass, the spatial density and other properties of the glass fibers to vary. Due to the temperature dependency is made of appropriate glass fibers existing moldings also advantageous as insulation Stoves, ovens, etc. use subject to high temperatures command.

Further details and advantages of the invention counter stand out from the following description the associated drawing, in which a preferred embodiment Example with the necessary details and Items is shown. Show it:

Fig. 1 shows a plant for the production of glass fibers in a schematic representation.

Fig. 1 shows first of all a glass melt in which the glass for the system ( 1 ) is melted. The liquid container is designated by ( 2 ), from which the liquid glass can emerge through an outlet opening ( 3 ) in the form of a uniform glass jet ( 4 ).

This glass beam (4) impinges on a rotating plate (5) which is provided on the outer edge with openings (6). By the rotating rotation plate ( 5 ), the liquid glass is pressed through the narrow openings ( 6 ) and leaves the rotation plate ( 5 ) as a single fiber, with the gas burner ( 7 ) ensuring the necessary temperature in this area and early cooling is prevented.

At a distance from the rotary plate ( 5 ) is arranged a glass fiber ribbon ( 8 ) surrounding feed ring ( 9 ).

About this feed ring ( 9 ) water is sprayed through appropriate nozzles on the glass fiber ribbon ( 8 ).

A further feed ring ( 10 ) is provided at a distance from the feed ring ( 9 ), via which the binder component silicone can be sprayed onto the glass fiber ribbon ( 8 ). Close behind is the feed ring ( 11 ), over which the starch binder component is sprayed. The individual feed rings ( 10 , 11 ) are equipped with nozzles ( 13 , 14 ) through which the respective binding agent component can be discharged uniformly, the nozzles ( 14 ) having a larger diameter than the nozzles ( 13 ) in order to ensure a uniform discharge to ensure the binding medium component starch.

Behind the feed rings ( 9 , 10 , 11 ), a white feed ring ( 12 ) can be provided, for example to be able to apply a further binder component, for example vinyl.

Fig. 1 shows an arrangement in which a cover ( 20 ) is provided between the feed rings ( 9 ) for the water and the feed ring ( 10 ) for the silicone, in order to rule out any influence by water in this way. ( 15 ) denotes the feed line, via which the starch is sprayed onto the glass fiber mat or glass fiber ribbon ( 8 ).

In addition to the feed rings ( 10 , 11 , 12 ), a feed ring ( 25 ) for dust binding agents is provided, so that all important components can be sprayed separately onto the glass fiber ribbon ( 8 ) in this embodiment. According to the method described above, however, it is provided centrally to mix the individual components together to form an emulsion, in order to then spray this emulsion evenly onto the ribbon of glass fibers ( 8 ) via the feed ring ( 26 ). In this case 1, the area is shown in FIG. See provided, where the glass fibers together already again, it being ensured by the annular ring in that the single optical fiber can be also produces really sprayed from all sides with the emulsion.

To prepare the emulsion, a mixing container ( 29 ) is used, which has a mixing rod ( 30 ) which can be rotated at such a speed that a uniform emulsion results. The mixing container ( 29 ) is supplied from the tanks ( 31 , 32 , 33 ) silicone, epoxy resin and dust binder medium.

The emulsion product leaving the mixing container ( 29 ) is pressed by the pump ( 34 ) to the feed ring ( 26 ), which is equipped with corresponding nozzles, not shown here in detail. It can be the nozzles ( 13 , 14 ), which have a corresponding connec tion to the feed ring ( 26 ). The inclination of the nozzles can be changed so that the uniformity of the application of the emulsion is ensured.

The glass fiber ribbon ( 8 ) is fed via the feed rollers ( 36 , 37 ) to an endless link belt ( 35 ) in order to obtain the shape of the uniformly dense glass fiber mat ( 16 ). The endless link belt ( 35 ) is only hinted at here, with a supply of glass fleece ( 39 ) generally being arranged on this endless link belt behind the tunnel furnace (not shown here). This glass fleece ( 39 ) is pulled off the stacking rollers ( 40 ) and brought over the guide roller ( 41 ) evenly close to the glass fiber mat ( 16 ). Adhesive nozzles ( 43 ), which are supplied via the adhesive tank ( 42 ), are arranged in front of the guide rollers ( 41 ), so that the very thin glass fleece ( 39 ) can be securely attached.

Methylon is particularly suitable here because it has epoxy Harz u. a. be mixed and because it has a good glass thread tet. Because of epoxy and / or methylon resins Binder can be used in the selection of raw materials be more generous, d. H. it can also be larger Amounts of waste glass are absorbed without this the properties of the finished glass thread or glass wool to change. Treated or bonded accordingly with methylon resin Glass fibers are particularly good against acids and other chemicals microorganisms completely resistant.

All mentioned features, including those of the drawings alone to be extracted, alone and in combination, are invented considered essential.

Claims (8)

1 . Process for the production of glass fibers or mineral fibers for insulating materials, which are produced from liquid glass which is pressed through a plurality of openings of a rotary actuator, whereupon the glass fibers are exposed to a hydrophobizing agent and a binder (6 to 8%) before or during cooling Sprayed silicone and a long-chain starch and then subjected to drying and shaping into sheets or rolls according to the patent (patent application P 42 22 444.6), characterized in that an emulsion is produced from silicone resin, silicone oil, a dust binder and the starch (polysaccharides) and this is then atomized at a temperature of 18 to 200 ° C and sprayed onto the glass fibers passed. 2. The method according to claim 1, characterized, that the emulsion of silicone resin, dust binder, starch, Synthetic resin and silane made as a catalyst and then is sprayed onto the glass fibers. 3. The method according to claim 2, characterized, that the synthetic resin partially or completely replaces the starch Epoxy, methylon, polyester resin or the same or similar acting synthetic resins are used. 4. The method according to claim 1 to claim 3, characterized, that the glass fibers are combined at the end of the chute and between endless link belts with simultaneous off harden to the intended bulk density and then be trimmed laterally by cutting off the excess.   5. The method according to claim 1 to claim 4, characterized, that a thin or multi-sided on the glass fiber mat Glass fleece applied, preferably glued. 6. The method according to claim 3, characterized, that 6 to 9 wt .-% epoxy resin, 0.5 to 4 wt .-% silicone and a dust binder are mixed and that the proportions can be chosen larger with increasing proportion of used glass. 7. The method according to claim 1 to claim 6, characterized, that the glass fiber back after intended use won, transferred to the glass melt at 850 to 1000 ° C and processed back into glass fiber. 8. The method according to claim 1 to claim 6, characterized, that the glass fiber back after intended use won, transferred to the glass melt at 850 to 1400 ° C and cooled and disposed of as a glass block or crushed material.