DE825377C - Material with high tensile strength and method of manufacture - Google Patents

Description

High tensile strength material and process for its manufacture The invention has the production of a material for constructive and structural purposes should be used. It consists of two main components, i. the carrier of strength and 2. the inorganic binder.

Thread-shaped glass, i.e. glass wool or glass silk, is used as the part that gives the building material the desired high tensile strength. It is known that fine glass threads have extremely high strengths. According to various studies, the tensile strength of the individual thread depends on its diameter. Since the strength of the new material is practically only due to the strength of the glass threads, it is sufficient to limit the strength calculation to that of the glass portion. The strength of the glass threads is the same according to an approximation formula that is sufficiently accurate for thread diameters over 0.05 mm oF = tensile strength in kg / mm2, D = thread diameter in u.

For a diameter of io, u results in a tensile strength of around Zoo kg / mm2, for 5 lc even around 300 kg / mm2.

In the subject matter of the invention, it is to be regarded as particularly surprising that that as the thread thickness decreases, the thread length can also decrease, so that the high Strength of the fabric does not depend on the fact that the threads, such as. B. a steel reinforcement, at least are continuous in the tension zone, but also short threads, e.g. B. staple fibers, can be used, the length of which can be down to 1 to 5o mm, depending on the thread thickness be. These glass threads, if made of the same material, can have the same strength in all Directions are required to be distributed evenly and in a disorderly manner. Your length depends on the one hand on the processing method, on the other hand on the adhesion, which increases with the length of the thread, is determined.

If special surface strengths or linear strengths are required, the glass fibers can also be stored in the form of bundles or fabrics (glass silk). The strength of the fabric is determined by the amount of glass threads that absorb the load. If the proportion of the glass filament volume in the total volume of the body, called f, is known, the strength can be calculated if A is known as the proportion of the total amount of fibers that is effective in the axial direction under consideration. The strength of the fabric is now calculated from the strength op of the glass thread, the volume ratio f and the number of axes according to the following formula QTh = A'f'QB The theoretically highest possible degree of filling f with a circular thread cross-section and three-axis glass distribution is f = 3 7r / 16, with a uniaxial distribution f = 7c / 4; With the currently known thinnest threads of 5, uo and 312 kg / mm2 tensile strength, the material strength is calculated as oTh = 61 kg / mm2 for triaxial fabric, oTh = 245 kg / mm2 for uniaxial fabric. It goes without saying that the more dense the binder, the better its function as a force transmitter between the individual glass fibers. The exact effect of compression tests on concrete showed that the compressive strength increases when the cement content is reduced, because the strength of the aggregate is several times the strength of the cement that has set.

This knowledge can also be transferred to the substance according to the present invention. With this in mind, too, it is advisable to make the proportion of glass fibers as high as possible, i.e. to approach the limit calculated above of around 65% for a random arrangement or around 750 % for a uniaxial distribution. However, this succeeds only imperfectly with commercially available binders up to the limit of 35% in the case of a random arrangement or only 20% in the case of a uniaxial arrangement.

It is advisable to use binders whose fineness is of the order of magnitude corresponds to the thread thickness. the higher the proportion of thread in the mass, the higher must be the degree of comminution of the binder. With the highest proportion of thread the particle diameter should be at least one order of magnitude smaller than the thickness of the fibers lie. For this purpose, special sifting processes and grinding methods are sometimes used such as B. Use of colloid mills may be required. The increase in the mixing water causes a reduction in the glass volume part f, but also an unfavorable one Change in the chemical bond of the cement, so that when you get frothy-loose The structure of the substance desires, according to the invention, not by adding a larger one Amount of water, but by adding an inert one that does not react with the cement Liquid that should be as volatile as possible in order to be recovered quickly to be able to be achieved. The liquid that evaporates during drying leaves behind then finely distributed bubbles in the cement mass.

Suitable liquids are solvents such as. B. alcohol, Ether, acetone, chloroform, etc. are in question. Such liquids can already be the fine grinding of the binders are used as dispersants, so that the binder suspended in the dispersing liquid after the addition of the The fibers can be added directly to the mixing water. Should a pore formation are avoided, the mixture is expediently compacted and optionally sucked the dispersant.

On the other hand, a porous product can also pass through in a known manner Admixture of gas generators such as aluminum, zinc, magnesium or peroxides, hypochlorites u. The like., Or by adding a foamy porous substance, z. B. from urea-containing Synthetic resin. This results in fabrics that have high strength with nailability and low heat conduction.

The above-mentioned phenomenon of increasing the strength of the glass fiber when the diameter is reduced it can be concluded that essentially the outermost layers of the glass thread carry, which is why the inner parts are omitted can be. This leads to a hollow filament that is lighter in weight increased tensile strength connects, because now is also inside the thread a surface. Such capillary threads can be pulled out in a known manner can be made from appropriate tubes. The ratio of the hollow core to the thread thickness should be the smaller, the smaller the thread thickness, z. B. at a Thread thicknesses of 1 mm are between 40 and 60 ° jo, with o, ooi mm thickness 5 to 10 ° / o. The admixture of such capillary threads in materials is of fundamental importance and can also be used for binders other than inorganic, e.g. B. plastics, application Find. For the practical manufacture of such glass thread binder fabrics it will prove expedient to apply the tightest thread arrangement only to those places of the entire body where the highest stresses occur. We come like this according to the invention to bodies with varying embedment density, which also Can alternate bundles and tissues with masses of homogeneous thread distribution.

It is also possible to use other parts made of metals and the like, be it to local increase in strength, be it as composite or protective pieces, to store or to store. To achieve special effects can also other substances, such as fillers or colors, are mixed in. The dyeing of the fabric but according to the invention it can also be done in that the glass itself is colored. Both colored glass melts can be spun into threads, but also undyed glass threads by external coloring, e.g. B. by metallization, use.

When choosing the binder is also the increased reactivity (due to the extraordinarily enlarged surface of the fine glass threads) of the glass to consider. From this point of view are among those known in construction Binders such as cement, gypsum, magnesia, anhydrite, lime, etc. to select those which react as little as possible with the glass substance in question. For example an expansion cement is used, which consists of a mixture of Portland cement and molten cement and plaster of paris. Furthermore, the glass fibers can be made of a material the chemical composition of which is as close as possible to the respective binder, so z. B. high aluminum oxide content in gypsum, low lime content in cement, owns. Furthermore, the reaction between fiber and binder can be directed in such a way that that only a thin surface adhesive layer reacts and the implementation then comes to a standstill comes. This can be done, for example, by after-treatment with carbonic acid or by Achieve removal of the limescale solution that is still in liquid form. The bodies can artificially dried and then with oils, fats, hydrocarbons or Like. To be soaked. In individual cases, fluation can also be considered.

Highly polymerized silicones can also be used as binders. Sand, brick dust, wood flour or wood wool, metal powder, e.g. B. iron, zinc and the like, and their oxides. To enclose as much as possible To achieve the fibers through the binder, it is essential for the method according to the Invention essential that the mixed mass by z. B. pressing, shaking, tamping, Vibrating, ultrasonic treatment and / or centrifuging is compressed.

The production of bodies from the material described is done z. B. by pouring and then setting the mass.

Exemplary embodiment: For processing by casting in a closed Steel molds are used: 100 parts by weight of cement, 5 parts by weight of fiber tape (not woven) A "= 0.75 (proportion of fibers lying in the axial direction = 75%), 45 parts by weight of water.

The binding agent and the glass fiber tape are mixed with the mixing water pulled through the mash. The soaked tape is inserted into the mold and this closed under slight pressure.

Another path that has also been taken in previous attempts is that a thin sliver (Schüller G. m. b. H. Coburg) on a was wound up in a drum running in cement slurry. The fiber has the ability to partly to let cement penetrate from the outside in excess and partly to the inside to squeeze off this excess by winding up the next layers. Still is it is necessary for the production of bodies with higher percentages of glass that Squeeze out the wound fiber tape, otherwise a maximum of 3% filling level of the volume of the room is achieved. By a clean winding and by thin slurry as well Squeezing out the strand succeeds in reaching a filling level of up to 12%.

The mixture can be made at the point of use, but it is It is also possible to send the dry substance premixed and only after adding it of water to set. This water can also be in the form of injected Steam can be added. Before setting, the mass can be pressed, pressed, Shaking, stamping, vibrating, brought into a denser form by ultrasound treatment will. Inhomogeneous distributions within the mass are preferably achieved by spinning and vibration achieved.

To increase the fatigue strength as well as greater resistance To protect against corrosion and weathering is expediently the The mass is molded in highly polished forms or in mirror glass forms.

There are three ways to increase strength: i. the Increase in the degree of filling, 2. the reduction in the elementary thread thickness and 3. the improvement of slip fiber mixing.

The last point is to be achieved through three methods. Spool namely, as described above, the sliver on a drum, then remains the winding of the same onto the drum, the tape relative to its surroundings at rest. The slip in the belt can therefore almost no longer enter the Bundles or emergence from the same are brought. Because the mechanical influence by squeezing, etc., is only a makeshift, another method of spooling was used prepared.

A specially shaped rubber belt is folded so that he like a Möbius strip, the inside and outside are swapped around when revolving around two rolls. If you wind a sliver soaked with slurry between the double-lying belts, then the wound strand is turned from the inside out in the case of the one roll another role from the outside to the inside. The centrifugal force occurring on the rollers flings off superfluous slurry and embeds the fibers.

The centrifugal force used in the Möbius belt can also be used accordingly Another suggestion can be used by means of a centrifuge. In this Centrifuge can introduce the glass wool in a slurry, with this is forced radially outward by its greater specific weight, whereby the slip only remains in the cavities formed by the fibers. In contrast to drum and Möbius belts, where only endless yarns or spun slivers can be processed, disordered glass wool can also be used in such a centrifuge be mixed with slip. It is important to ensure that the glass wool is in loosest form; if possible in individual Threads, is introduced, otherwise the formation of interfaces between the individual lumps of wool will reduce the strength of the body.

The processing of wool alone is also modified Form of the manufacturing process of blown glass wool possible, whereby the glass wool, which falls in a vertical shaft on a conveyor belt, at the same time as sprayed Slurry is mixed. The superfluous seepage could then be sucked off the belt will.

The deformation results in a fairly homogeneous product, which may not be desirable for various products. So will z. B. the edge and abrasion resistance must sometimes be very high, during the Kern would not have to absorb any significant loads. In such cases a Compensation for loose materials is done by impregnating cement slurry takes place by means of vacuum and subsequent high pressure. After partial removal the air trapped in the material sucks the sludge into the body or becomes additionally pressed into the body by the external pressure. It then arise in the outermost layers very dense accumulations of binding agent, which provide the necessary edge and abrasion resistance as well as the desired dimensional accuracy. Of course are Impregnation with other agents, such as wax, paints, varnishes, etc., is also possible.

Special reinforcement bodies can also be made from the material described for reinforced concrete as a replacement for steel inserts. These rods can then into the tension zones without any special measures against being pulled out by the load be inserted. Their rough, mineral surface combines with the surrounding area Concrete becomes an inseparable unit.

Claims (16)

PATENT CLAIMS: i. Material with high tensile strength, in particular for structural purposes, consisting of glass fibers with mineral binders, characterized in that the fibers for the most part have a strength of less than o, oi mm own. 2. Fabric according to claim i, characterized in that the used Glass threads are not solid but are designed as capillaries. 3. Fabric according to claim i and 2, characterized in that air or gas bubbles are contained in the substance. 4. Fabric according to claim i to 3, characterized in that the force transmission body, such as reinforcing iron, tie rods, pressure plates, bearing eyes, connecting and connecting pieces, are embedded. 5. Fabric according to claim i to 4, characterized in that the Glass threads, admixtures, gas bubbles, etc. in locally different concentrations z. B. close to the surface, loosely inside, are arranged. 6. fabric after Claim i l> is @, characterized in that inlaid glass silk fabric on d ^ r Surface of the manufactured body lie while the body is made of a mixture von Bind _, - ordered medium and disordered threads, so that z. B. by washing up the surface of the fiberglass is exposed. 7. Fabric according to claim i to 6, characterized characterized in that the glass threads are colored in their mass, stolen on the surface or are etched or metallized. B. Process for the production of a material according to claims i to 7, characterized in that the What # er turned on the Mass containing glass fibers before setting by pressing, pressing, vibrating, Stamping, shaking, ultrasonic treatment and; 'or centrifuging is compacted. G. Method according to claim 8, characterized in that the binding agent is mixed with the mixing water stirred and the glass fiber pulled through the binder paste in the form of a ribbon, placed in a mold and allowed to harden in this under pressure. ok procedure according to claim 8, characterized in that binding agent is used, its Fineness corresponds to the order of magnitude of the thread thickness, or is less than this. ii. Method according to Claims 8 to 10, characterized in that the mixture contains up to 35 °, 70 ° with a random arrangement of the glass fibers, up to 20 ° in the case of a uniaxial arrangement. 12. The method according to claim 8 to ii, characterized in that that the Anrnachwasser with the binder non-reactive liquids such. B. alcohol, ether, acetone, chloroform can be added, which are used in drying will. 13. The method according to claim 8 to 12, characterized in that glass fibers with a composition adapted to the particular binder, e.g. B. with high-cm _1lu:, iiniumol5-d content for gypsum, low lime content for cement. 14. The method according to claim 8 to 13, characterized in that the fibers with be completely enveloped in a binder, de, @ sen grain size adapted to the fiber thickness is. 15. The method according to claim 8 to 14, characterized in that one in the Binder-containing component that attacks the fiber is rendered harmless is by z. B. Lime excess saturated with carbonic acid or calcium solution removed will. 16. The method according to claim 8 to 15, characterized by the VeI-wen <hung of expanding cement.