KR830000975B1 - Inorganic Perforated Fiber Manufacturing Method - Google Patents

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Description

Inorganic Perforated Fiber Manufacturing Method

The present invention relates to a method for producing a small tube body, that is, a porous fiber.

In the related art, metal tube drawing operations for producing a small tube upper body have been expensive. Such manipulations for producing extremely fine (ie having fiber size outer diameters) tube bodies are particularly costly and not technically available. The present invention therefore provides a method for easily and economically producing extremely small metal tubular bodies. This method has also been found to be useful for the production of small tubular bodies of other inorganic materials.

The value of the process of the invention generally varies inversely with the outer diameter of the small tube body. In other words, the smaller the desired small tube body, the more valuable this method. For very small outer diameter tube bodies, the cost of the method of the present invention does not rise obviously per unit length. This is in contrast to the cost of tube stretching operations that typically increase when producing such a small outer diameter.

In the description of the present invention, the following definitions are used.

As used herein, “porous fiber” has a very large length relative to its diameter, and also refers to a continuous channel (in particular generally referred to as a “bore”) in the axial direction without the material forming the fiber. The fiber you have. Such fibers can be provided in virtually any length desired for the intended use.

"Intrinsically inorganic material" refers to a sinterable inorganic material that is substantially free of organic polymeric materials. By "monolthic" is meant that the fiber material has the same composition throughout its structure, and furthermore, its fiber maintains its physical structure due to the presence of sintered particles.

"Porosity" refers to a fiber wall property that, although continuously relatively dense, is very small and often has a passageway that allows the passage of fluid through the fiber wall rather than by curved diffusion.

The method of the present invention essentially provides a process for producing inorganic integral porous fibers (ie, small tubular bodies). Particular preference is given to such perforated fibers comprising a metal. The method for producing such fibers comprises (a) preparing a solution of an organic fiber forming polymer containing a sinterable inorganic material in a uniformly dispersed form, and (b) a solution of the inorganic material containing the same through a porous fiber spinning nozzle. Extrusion molding, (c) forming polymer precursor porous fibers containing inorganic materials, (d) treating the polymer precursor porous fibers to remove organic materials and sintering inorganic materials in the form of perforated fibers. It involves making. The essentially inorganic perforated fiber produced is similar to the polymer precursor perforated fiber but on a reduced scale.

The perforated fibers prepared by the present invention are very useful for a wide range. These perforated fibers make inorganic materials useful in a variety of forms, but can be manufactured economically with very wide variation in physical arrangement. Moreover, it can be seen that most of these fibers are made in large quantities without a lack of flaws and damage.

The perforated fibers produced by the present invention essentially contain inorganic sintered in the form of perforated fibers. Sinterable inorganics contain a very large group of materials. Most preferably the sinterable inorganic material is a metal. Nickel, iron and their nonmetals are particularly useful. Sinterable inorganic materials are ceramics such as aluminum oxide, beta-alumina and the like. Sinterable inorganic materials are cermet conductive alloys or metcers such as ferrous metal / aluminum titanium carbide / nickel and the like.

The prepared pore fiber can have an outer diameter of about 2,000 microns. However, one can also consider fibers with larger outside diameters from 3,000 or 4,000 to less than about 6,000 microns. In general, the most economical perforated fibers have an outer diameter of about 50 to 700 (most preferably 100 to 550 microns) microns. These fibers often have a wall thickness of about 20 to about 300 microns. In general, the fibers have a wall thickness to outer diameter ratio of about 0.5 to about 0.03 (particularly about 0.5 to about 0.1).

The most important thing in the present invention is to produce inorganic perforated fibers that can vary in size and arrangement. The size of the fibers is influenced by uniquely modifying spinnerets known in the synthetic fiber art. The wall thickness of the fibers can be varied over a wide range by varying the state of extrusion and fiber formation. This is the only property for producing the perforated fibers of the present application. Next, the method of the present invention is described in detail.

Preparation of polymer solution containing inorganic

A mixture is prepared in which the inorganics are uniformly dispersed in the polymer solution. The polymer solution is composed of fibrous organic polymer dissolved using an appropriate solvent. Generally, the concentration of organic polymer in the solution is radially anisotropic internal void volume wall structure using dry or wet spinning method when the solution contains inorganic material. It should be faithful enough to produce a porous fiber precursor of polymer having The polymer concentration can be varied in a wide variety of ways, depending on the properties required for the final perforated fiber. Of course, the maximum concentration is limited to the extent that the polymer solution containing the inorganic material is difficult to extrude through the spinneret. The lower limit is therefore the extent to which polymer porous pore precursors do not have sufficient polymer to maintain the wall structure. Usually the polymer concentration ranges from 5 to 35% by weight of the polymer solution. In particular, about 10 to 30% is good, and may be about 15 to 30%.

Preparation of Perforated Fiber Precursors with Polymers According to the Present Invention The nature of the organic polymers used is not critical. For example, polyacrylonitrile is polymerized with acrylonitrile and one or more other polymerizable reactive monomers such as vinyl acetate, methyl methacrylate, urethane and vinyl chloride. Additive polymers and condensation polymers are formed by injection molding, extrusion molding or other methods, and thus are used to produce perforated fibers by dry or wet spinning methods. Suitable representative polymerization preparations that can be used in the process of the present invention include substituted and unsubstituted polymers, which can be used among the following.

Polystyrenes including styrene-containing copolymers such as polysulfones, acrylonitrile-styrene copolymers and styrene-butadiene copolymers and styrene-vinylbenzyl halide copolymers; Polycarbonate; Cellulose polymers (eg, butyric acid cellulose acetate, propionic cellulose, ethyl cellulose, methylcellulose, nitro cellulose, etc.), polyamides and polyimides including arylpolyamides and aryl polyimides; Polyethers, polyarylene oxides such as polyethylene and polyxylene oxide, polyester amide diisocyanates; Polyurethane; Polyesters (including polyarylates) such as polyethylene terephthalate, polyalkyl methacrylate, polyalkyl acrylate, polyphenylene terephthalate, etc.), polysulfide; In addition to the above, polyethylene, polypropylene, poly (butene-1), poly (4-methylpentene-1), polyvinyl (e.g. polyvinyl chloride, polyvinyl fluoride, polyvinylidene chloride polyvinylidene fluoride, polyvinyl Alcohols, polyvinyl esters (e.g. polyvinyl acetate, polypropionate), polyvinylpyridine, polyvinylpyrrolidone, polyvinylether, polyvinylketone, polyvinylaldehyde (e.g. polyvinyl formal, polyvinyl butyral Polymers made of alpha olefin unsaturated monomers such as polyvinylamine, polyvinyl phosphate and polyvinyl sulfate); Polyallyl; Polybenzobenzimidazole; Polyhydrazide; Polyoxadiazoles; Polytriazoles; Polybenzimidazoles; Polycarbodiimide; Polyphosphosazines and the like (included as block intermediate polymers containing repeating units from those listed above, such as those of the acrylonitrile-vinyl bromide-sodium salt of parasulfophenyl metharylyl ether); There are graft polymers and mixed polymers containing any of the foregoing. Representative substituents for producing substituted polymers include halogens such as fluorine, chlorine and bromine, hydroxy groups, lower alkyl groups, lower alkoxy groups, monocyclic aryl groups, lower acyl groups and the like. Furthermore, this treatment is inevitable since the organic polymer has to be treated and removed in the next process. For example, suitable polymers should be easily degraded or reacted and should not be so rapid that they affect organic removal. In addition, these polymers must not react with the minerals to produce reaction products that adversely affect or interfere with the next process. Therefore, it should be economically the cheapest and extremely easy to secure. Polymers and polymers obtained by polymerization of acrylonitrile with one or more neutral monomers can be used in particular in the process according to the invention.

The solvent used to prepare the polymer solution may be any of those conventionally known. For example, solvents such as dimethyl acetamide, dimethylformamide, dimethyl sulfoxide and the like are used in addition to acrylonitrile polymers. Obviously, these solvents should be good solvents for the organic polymers and adapted to the dry or wet spinning methods that will occur in the next process.

In preparing an inorganic polymer solution, the inorganic material is dissolved by adding a polymer in a solvent and then dispersing the inorganic material in the solvent. Any other suitable method of preparing a polymer solution containing an inorganic material may be used. For example, a polymer, an inorganic material and a solvent are mixed together, or an inorganic material is added to disperse and then the polymer and the solvent are mixed. There is this.

It is advisable to disperse the inorganic material in the solvent before adding the polymer. The polymer solution containing the inorganic material is prepared using room temperature or a temperature slightly higher than room temperature. Depending on the solvent, polymer or inorganic material used, it is not necessary to determine whether the temperature will be high or low.

The amount of inorganic material is inversely related to the same general concept previously discussed above with respect to the concentration of the polymer in the polymer solution. The precursors that form the occupied structure have a limited amount of polymer, so the maximum amount is limited to the point where it cannot be maintained at a certain level. The minimum amount added is such that the particles of the inorganic material are so widely dispersed that these particles do not sufficiently melt or bind during sintering and degree. The normal ratio of inorganic material to polymer is in the range of about 3.5 to 15 by weight and preferably about 4 to 12, particularly about 4.5 to 10. Inorganic materials require small particles to be uniformly dispersed throughout the polymer solution. Adequate mixing should be given to ensure uniform dispersion. Even if some of the inorganic material is dissolved, it is not important for achieving the object of the present invention because it helps to uniformly disperse.

The inorganic material mixed into the polymer solution is a sinterable inorganic material. Such materials are those which are suitable as sinterable materials or are unusually important materials which can be converted into the required sinterable inorganic materials. For example, if the fiber required is composed of a metal such as nickel or an alloy thereof, it can be used among metals or metal oxides or other compounds that can be ultimately converted to such metals.

Perforated fibers of inorganic material, which are sinterable (or can be converted to sinterable materials), although the process according to the invention can be particularly used for the production of perforated fibers of metal, such as by reducing metal oxides to metal elements. The present invention is applied to prepare the same. These inorganic materials have been mentioned earlier. For better understanding, only metal compounds that can be reduced to sinterable metals will be described in detail.

Of course, since the reduction temperature should be below the melting point and vaporization temperature of the compound to be reduced and the metal element produced, the metal compound that is excessively sublimed or vaporized below the temperature at which the metal compound reacts with hydrogen or carbon is a metal element having a low temperature (eg, K, Ka, Li, etc.) can be satisfactorily used in accordance with the process according to the present invention without particular attention. (Although it is the practice of the present invention that hydrogen is used to give the atmosphere to reduce the metal compound particles to the metal element, other reducing materials may be used. For example, metal compounds, in particular nickel and iron oxide, may be used instead of the hydrogen reducing atmosphere.) The use of carbon monoxide, in part or in whole, leads to a reduction, apparently trace amounts of residuals in the solvent and components of the polymer can form such a reducing atmosphere. Moreover, the metal compound itself is limited to the material in which the reaction product besides the metal element remains in the reaction zone before or during the sintering of the porous fiber.

The most important metal compound is an oxide, because this compound is the most abundant. It is also due to the fact that it is a by-product of the manufacturing process and that metal is most commonly found among natural ore concentrates. Other usable metal compounds include those belonging to halide series, hydroxide series, carbonate series, oxalate series, acetate series.

Regardless of the inorganic material used, the particle size acts as an important factor in producing the required perforated fibers. The size range of the small particles used to disperse in the polymer solution is usually 15 microns or less, preferably 10 microns or less, but more preferably 5 microns or less. In general, the particle size distribution range of a mixture of these particles varies. Clearly, the smaller the particle size, the more uniform the dispersion. To obtain metal fibers with the required properties, extremely small particles of less than 1 micron should be used. Therefore, this can be made to the required size by grinding or classifying the particle size into fine particles.

In general, the smaller the diameter, the greater the degree of filling, thus eliminating the reaction product, that is, the gas or the space that can exit, which can be considered to greatly eliminate the possibility of cracking and surface problems caused by deaeration. However, the confirmed fact is that using a small particle size produces a defect-free but essentially non-porous dense membrane. In either case, depending on the purpose, the porous properties are not necessarily present when the epidermis is formed on the surface of the perforated fiber using particles having a size of about 1 micron depending on the process applied. The difficulty with using extremely fine metal particles is related to the tendency for various metals to oxidize when exposed to the atmosphere in the form of small particles. For example, when iron particles (less than 40 microns) are exposed to the atmosphere to produce iron oxide particles, exothermic reactions occur. Therefore, these materials are difficult to handle, but they can be handled without special measures so that the oxide particles do not have an airtight protective jacket or react instantly. Oxide particles are by-products of metal processing and therefore inevitable at low prices. The process of the invention is in particular using oxides. For example, iron oxide particles, which are by-products of hydrochloric acid washing, can be easily secured. Other sources of iron oxide particles include dust, rust, mill scale and advanced iron ore from basic oxygen converters. Nickel oxide can also be obtained at a low price.

Metal oxide particles in any shape are used in the present invention. Excellent pore fibers can also be produced using metal oxide particles from the spray drying process of dissolved metal oxides. It is difficult to measure the exact particle size of small particles, especially when the particle size is less than 10 microns in diameter. This measurement is most difficult when the particles have a non-uniform shape.

For example, it is difficult to measure the minimum size of a particle because the majority of particles have relatively long spacing. Particles of elongated length cannot pass through screens of the size of the water that are intended to pass through relatively symmetrical particles. As a result, particle size and particle size distribution measurements vary considerably for a given mass between the known methods and the incidences to be made.

The exact size of relatively small particles should be determined according to the Coulter particle calculation method. This method disperses and suspends the particles in a conductive liquid and flows through the small orifice. Immerse two electrodes on each side of the orifice and pass current through the orifice. The particle size is determined by measuring the change in electrical resistance between the two electrodes as the particle exits through the orifice. Therefore, these measurements are made mainly for particle masses and are not affected by shape.

The method of the present invention has advantages over the active state of the metal before sintering and before the reduction treatment of the metal oxide particles when using the metal compound. Metal particles tend to form thin oxide coatings or thin films, and virtually all metal powders of fine size form such thin films to prevent rapid oxidation or to eliminate the flammability of these materials. Such thin films make particles inactive, making them easier to handle in normal atmosphere. However, these thin films are difficult to reduce and retard sintering. Reducing the metal oxide particles to metal elements according to the method according to the present invention and sintering these metals in a reduced state without exposing the metal to an oxidizing atmosphere results in a porous fiber having excellent properties.

The metal alloy is obtained as an inorganic fiber according to the present invention by mixing and dispersing particles of a metal compound such as a metal oxide in a polymer solution. Such alloys exhibit useful properties with strength, diffusivity and chemical resistance. Examples of such alloys include those produced using nickel and iron oxides.

Another method for producing a porous fiber made of metal by the method of the present invention is to combine metal particles and metal compound fine particles. At this time, the metal particles should be mixed with the metal compound before dispersing in the polymer solution. Reduction and sintering at normal temperature and atmospheric pressure. The sintering temperature should be high enough so that the metal element diffuses into the reduced metal substrate and becomes an alloy.

Therefore, when the diffusion rate of the metal element is slow, the sintering temperature should be raised somewhat. If the sintering of the metal element (temperature or temperature at which the metal element can diffuse into the metal base) is above the melting point of the metal base, it cannot be alloyed. However, in the latter case, since the metal element or its oxide may be diffused, the substrate may be strengthened.

Another case in which metal particles can be used is to add to reduce shrinkage of the sintered fibers. In any sintering process, the metal reduces the outer dimensions because it removes the voids between the particles when the particles melt to form a solid material. When the inorganic material is composed of a metal oxide such as a metal oxide which is first reduced and then sintered by the method of the present invention, the size of the reduced particles is smaller than that of the metal compound particles, thereby forming large voids between the particles. Contractions are noticeable. To reduce shrinkage, metal element particles are added to the metal compound particles and mixed in the polymer solution. For example, nickel particles should be added to nickel oxide by 50% by weight to reduce the shrinkage of the final perforated fiber. The size of the metal element particles should be extremely small because the dispersed particles must quickly and uniformly diffuse into the parent metal. In addition, a well-dispersed sintered fiber can be obtained by mixing a non-reduced (or diffusible) particle size controlled material and a metal compound. Metal reactor particles are sintered at temperatures higher than the sintering temperature of the fibers.

As described above, the sinterable inorganic material may be made of a material that can form a fiber material without chemical treatment, or may be a material that is converted into a required form by chemical treatment.

As fully described above, metal oxides that can be reduced to metal elements refer to materials belonging to the latter. If metal fibers are needed, these oxides should be reduced to metal elements during or before sintering.

Other materials that can be used in the process of the present invention include those that need to be oxidized or can be a material that forms a final porous fiber by performing both oxidation and reduction in parallel. These methods will not be mentioned in detail in metal compounds, but nevertheless oxidizing materials such as aluminum can be used in the present invention. Other inorganic materials obtained by simultaneously oxidizing and reducing can also be used in the present invention. An example of such a material is the simultaneous redox of aluminum or titanium and iron oxide or nickel oxide. The following materials are those that can produce the final fiber without chemical treatment (without oxidation and reduction): metals and ceramics (alumina, β-alumina, glass, mullite, silica, etc.).

Polymer solutions containing inorganic materials may also contain other additives and are easy to process in the next process, especially during the extrusion and fiber forming steps. Wetting agents, such as monopalmitic acid sorbitan and the like, are used to wet the inorganic material with a solvent in the polymer solution.

Plasticizers such as N and N-dimethyl laurylamide are also used to impart flexibility to the fiber precursors made of polymers.

Extrusion of Polymer Solution Containing Inorganic Materials

Various extrusion conditions are used in producing the perforated fibers according to the present invention. The weight percentages of polymers in the solution described previously vary widely but should be sufficient to produce perforated fibers under extrusion and fiber forming conditions. If the inorganic materials, polymers and solvents contain contaminants such as water and particulates, the amount of contaminants should be reduced sufficiently to facilitate extrusion and not adversely affect the next process or the final fiber. If necessary, filtration is used to separate contaminants from the polymer solution. Filtration should be carried out appropriately to remove the particles and to allow the inorganic material to pass therethrough. This filtration method should also be able to separate particles in inorganic materials that are larger than the required particle size. If the amount of gas contained in the polymer solution containing the inorganic material is too large, large voids are formed and unnecessary pores are formed in the polymer porous fiber precursor. Therefore, degassing should be made. Such degassing or filtration is carried out either during or immediately after the preparation of the polymer solution containing the inorganic material, or immediately during or before the compression operation.

The size of the porous fiber spinning nozzle depends on the degree of internal and external diameter of the porous fiber precursor in the final polymer. Radiant nozzles also have a variety of images, such as hexagonal, oblong, and star-shaped. In general, the shape of the spinneret is circular, the outer diameter is about 75 to 6000 microns, the center pin is about 50 to 5900 microns, and there is an injection capillary in the center pin.

The diameter of the injection capillary varies within the limits occupied by the pin. The polymer solution containing the inorganic material is frequently kept in an almost inert atmosphere to avoid contaminating or agglomerating the polymer prior to extrusion, and to avoid the risk of fire, which can be caused by volatile and flammable solvents. A convenient atmosphere is to use dry nitrogen.

The temperature for extruding the polymer solution containing the inorganic material is various. Normally, the temperature is sufficient to prevent unnecessary flocculation or precipitation before extrusion. The general temperature range is about 15 to 100 ° C and generally about 20 to 75 ° C. The extrusion pressure is usually a pressure in a range conventionally used in the fiber spinning method. For example, the extrusion pressure depends on the required extrusion rate, the size of the orifice of the spinning nozzle and the viscosity of the polymer solution containing the inorganic material. Particular attention should be paid to the use of relatively low pressures in accordance with the method according to the invention. This is in contrast to a filling method that requires hundreds of atmospheres to produce well-filled and sintered products.

The pressure used in the present invention usually ranges from about 1 atmosphere to about 5 atmospheres or more.

By extruding fibers through multiple spinning nozzles, composite fibers can be made simultaneously, using the same coagulation bath. Using a large number of spinning nozzles can cause the fiber, a precursor, to be twisted simultaneously during or after production.

Manufacture of polymer perforated fiber precursors

In general, fiber spinning technology is the same as that used in the synthetic fiber industry. These techniques can be advantageously applied to the fiber forming step in the process according to the present invention.

Fibers are manufactured using wet or dry spinning, ie, spinning nozzles are installed in a coagulation bath or away from the coagulation bath. Wet methods are frequently used and are a convenient way.

When solidifying, the spinning fiber is brought into contact with the coagulation bath. In the case of the peripheral outer zone, the spinning fibers are passed through the coagulation bath. In the case of the peripheral inner region, the emulsion (coagulates the polymer in the polymer solution) is allowed to coagulate by injecting into the spinning fiber inner tube. As the fluid, air, isopropanol, water and the like are used.

Essentially a solvent which is insoluble in the polymer is used as the coagulant in the coagulation bath. Coagulants should usually be compatible with the solvents in the polymer solution. The nature of the coagulant used depends on the solvent used in the polymer and, depending on the spinning standard used in the textile industry.

By "coagulant" is meant a medium in which the polymer rapidly adheres. By "commercial coagulant" is meant a medium in which the polymer is slowly deposited. For convenience, water is used as the primary coagulant during the coagulation bath. Other coagulants include ethylene glycol, polyethylene glycol, prepropylene glycol, methanol, ethanol and propanol. Allow at least a sufficient time for the extruded fibers to remain in the coagulation bath so that the fibers are reasonably solidified.

The peripheral outer zone is formed by interaction with the coagulant or by cooling (extruded polymer solution containing inorganic material can be cooled by contacting the gas at a temperature below the gelation temperature of the polymer solution). This allows the cooling gas to move relatively quickly, moving out in a direction parallel to the direction of the perforated fiber, which is additionally filled with steam or nonsolvent vapor).

The passage of the surrounding internal region can achieve a similar method by interacting with the coagulant in the injected fluid or cooling to the temperature of the injected fluid. Gelation is completed in the coagulation bath. The coagulation bath has a coagulation effect in addition to the gel effect.

The temperature range of the coagulation bath is -15 ° to 95 ° C or more, often in the range of 1 to 35 ° C, and sometimes 2 to 25 ° C. The temperature range of the fluid injected into the inner tube of the fiber is generally in the same range.

In preparing the porous fiber precursor of the polymer according to the present invention, a radial anisotropic internal void volume wall structure can be made by varying the composition and the temperature of the fluid injected into the coagulation bath and the inner tube of the fiber. For example, to increase the internal pore volume, the coagulant in either the coagulation bath (for the peripheral external zone) or the fluid injected into the inner tube (for the peripheral internal zone) should be a strong coagulant or a higher coagulant concentration. It must be large. To reduce the internal pore volume, use a corresponding coagulant. Different temperatures will change the rate of solidification.

The wall structure also varies depending on the yield rate of the fiber crimp rate, the amount of fluid injected into the fiber tube, and the elongation conduction. The dense film on the outer surface of the fiber wall is formed by using a coagulant (low concentration) having a very low viscosity in the coagulation bath. A dense film on the inner surface of the fiber wall is formed using a very low coagulant concentration in the fluid injected into the inner tube. The dense membrane inside the fibrous wall is formed by using a coagulant which is strong in the coagulation bath and the fluid injected into the intrafibrous tube.

After coagulation of the fibers, the solvent is removed by washing with a non-solvent that is miscible with the solvent in the coagulation solution or the polymer solution. Perforated fiber precursors are also stored in water or other liquid baths. Extrusion and fiber forming conditions are preferably such that the fibers are not stretched unnecessarily. Even if you do not need diarrhea can stretch about 1 to 5 times. Extrusion and fiber spinning speeds are often set to 5 to 100 meters per minute, even if the fibers are not stretched more than necessary and the residence time in the coagulation bath is sufficient. In general, when stretched, the porous fiber precursor made of polymer is strengthened, and even with a given spinning nozzle, the productivity is increased and the diameter of the fiber is small. Annealing is used to strengthen the porous fiber precursors. Both stretching and annealing are done by passing the fibers through boiling water.

Other, but not limited, considerations for perforated fiber wall structures may be defects in dense films. (Defect refers to the incompleteness of the dense membrane, through which the necessary and unnecessary fluids pass through the membrane under normal operating conditions.) Some systems require extremely high selectivity for economic reasons, while others require mediocre selectivity to compete with other separation technologies. Therefore, in general, care should be taken to minimize defects in the manufacture and handling of perforated fibers, but the number and size of tolerable defects vary depending on the application of the fibers.

Perforated fiber precursors made of polymers containing inorganic materials are stored or wound as precursors in the form of a single filament for the next process or winding. The precursors are flexible and have the appropriate strength so that they can be handled without the risk of damage.

After obtaining the precursor by the method according to the invention and dried by a known method. Although not required, in general, the fibers are dried prior to treatment to remove organic polymers. The drying temperature is about 0 to 90 ℃ degree can be also at room temperature, that is, 15 to 35 ℃, the relative humidity is about 5 to 95 ℃ about 40 to 60 is convenient.

The fiber precursor is made up of a small amount of polymer that acts as a continuous phase carrier for inorganic materials uniformly dispersed in the polymer. In general, the concentration of polymer present in the fiber precursor is 50% or less by weight, sometimes 25% or less, and 5% or less. Of course, the main ingredient in fiber precursors is minerals. Other substances are also present, but usually less than two.

Organic Polymer Removal

Porous fiber precursors made of polymers containing inorganic materials are made and then the fibers are dried or stored as described above or transferred immediately to remove and remove the organic polymer in the fibers. This is possible either by thermal decomposition or by reaction of the organic polymer. In addition, the treatment is carried out in an inert or reducing atmosphere so that the minerals are reduced. This method is not necessary. As mentioned above, reaction products generated from organic polymers may be helpful in other processes. For example, hydrogen and carbon present in the polymer play an excellent role in forming a reducing atmosphere. This atmosphere helps to reduce the metal compound, that is, the metal oxide, to the metal element.

Reducing or oxidizing fibers containing inorganic materials (of course, oxidation or reduction is necessary when the inorganic materials dispersed in the polymer solution take the chemical form necessary for sintering). Proper atmosphere must be established before the fibers are treated at oxidation or reduction temperatures. For example, in the case of reduction, a porous fiber precursor made of a polymer containing a reducing inorganic material is continuously passed through the oven. The atmosphere made of hydrogen moves in the countercurrent direction to make contact. When the fiber first comes into contact with the heat generated in the oven, the remaining volatiles are blown away. As the temperature approaches the reducing temperature, the reducing inorganic metal compound is reduced to become a metal element, and the reaction product is blown away.

It will be appreciated for the purposes of the present invention that the temperature range and the sintering temperature at which polymer removal and reduction or oxidation take place may overlap to some extent. In other words, some sintering proceeds at the temperature at which the polymer is removed and oxidized or reduced. The temperature at which the reducing inorganic material, ie the metal compound is reduced, is known, and this temperature measurement is also ordinary.

If it is an atmosphere which can provide hydrogen, it will become a reducing atmosphere. For example, such an atmosphere is intended to not inhibit the reduction reaction as hydrogen, pyrolyzed hydrocarbons, decomposed ammonia, mixtures of the foregoing, gas mixtures thereof and other gases or vapors. Reactions that occur in the decomposition or oxidation of the polymer promote a reducing atmosphere.

Reducing solids such as carbon are used in conjunction with hydrogen, in which case the reactants (CO and CO ₂₎ ) become gaseous and do not impair the required fiber properties since they do not leave residual elements in the sintered fibers. For example, carbon is necessaryly added to the oxide powder. If residual carbon is a necessary element for the final fiber, carbon is also used when the ultimate product is a steel composition containing carbides. When oxidizing the mineral, it is also possible to use air at a suitable temperature under a suitable atmosphere and pressure. The oxidation temperature is generally known. When making cermets, oxidation and reduction occur simultaneously. The fiber containing the sinterable inorganic material is immediately transferred to the sintering treatment zone and sintered.

Manufacture of inorganic fiber by sintering

"Sintering refers to the process of melting and binding inorganic materials that can be sintered to at least the temperature at which particulate matter forms a single structure. Fibers produced by sintering should have significant strength compared to non-sintered fibers. The sintering should be carried out under conditions that can maintain the valence state at a temperature and time sufficient to become the required valence state or to melt and bind. For example, the sintering temperature of the fibers of nickel-iron alloy is 950-1200 ° C. at 5-15 minutes each, and the fibers of nickel-iron alloy produced under these conditions are excellent. Similarly to the oxidation temperature, the sintering temperature of the inorganic material is known.

Conditions for maintaining organic polymers, oxidizing or reducing inorganic materials, and sintering should be properly maintained to prevent damage to the fiber wall structure and the entire fiber (from the final fiber to the fiber precursor) of about 0.2 to Measured as 0.9 and usually 0.3 to 0.6. In other words, the pore fiber precursor is significantly reduced in size and the final product is transformed into a pore fiber. This is what appears in each of these processes. For example, the length of the fibers is significantly reduced, and the fiber wall structure and the dense membrane of the fibers are also reduced, which remain in a relative relationship with each other. During this process, a device for handling the shrinkage of the fiber should be provided. In particular, it is of utmost importance that these measures are taken just before sintering, as the fibers are quite fragile. At this point, a special circumference should be used to accommodate the shrinkage so that the fibers are not damaged. For example, if the fibers stick to the surface of the conveyor, the fibers break as they shrink.

One way to handle fibers is to pretreat the fiber precursors or cords made of fiber precursors to ensure good handling characteristics, and then supply them with heating using a conveyor belt. In this case, the conveyor belts Made from materials that do not adhere to the fiber even under working conditions. This conveyor belt allows the fibers to move at the rate of discharge of the final fiber as it exits the furnace. The feed rate of the fiber precursor is faster than the final fiber speed. The feed rate of the precursor is adjusted in consideration of the degree of shrinkage.

The main feature of the present invention is that the dense membrane, which is essentially nonporous, can be easily produced. The polymer in the fiber precursor of the polymer is characterized by the present invention in that it is a removable phase as described above. Even if the polymer is removed from the dense membrane of the fiber precursor, the final fiber produced after sintering is usually essentially porous. While it can be expected that the gaps between the particles of the inorganic material will be reduced during the oxidation, reduction and sintering of the inorganic material, it is necessary to form a dense membrane which is essentially non-porous to allow gas-like fluids to pass through by diffusion. to be. This phenomenon occurs throughout the fiber wall structure from which the polymer is removed. It is now confirmed that metal compounds, ie, metal oxides, can be used to convert metal elements.

By the method described above, essentially inorganic, monolithic porous fibers having radially anisotropic inner void volume walls have strength compared to the fiber precursors and fibers from the intermediate stage. The final fiber is flexible enough to store in bobbins, but not as soluble as the fiber precursors. The final fiber can be cut to the required length into a bundle of composite fibers (or made from twisted cotton, etc.). The cylinder length is about 0.2-10 m, and it is 1-5 m in many cases. The size of the bundle depends on the application, but is generally 0.5 to 205 cm in diameter.

The process of the present invention can also produce perforated fibers having aperture walls that can be achieved by treating the material of the walls and the fiber walls that produce aperture walls. That is, the precursor fiber polymer containing nickel oxide can inject ammonia gas at the atmospheric pressure of FIG. Another way to obtain the aperture wall of the fiber is to inject a relatively small amount of excellent specific material which is sintered or lower graded. During the manufacture of such materials, specific materials that are good for polymer solutions containing inorganic materials can finally create aperture walls in the inorganic fibers. The perforated fibers produced from this process are stronger compared to the fibers of the precursor and the fibers that interfere with the processing steps. Finally, the fiber is wound around the bobbin and flexible.

Claims (1)

Preparing an organic fiber forming polymer solution containing a sinterable inorganic material in a uniformly dispersed form, extruding the polymer solution containing inorganic materials through a porous fiber spinning nozzle, and forming a porous porous fiber polymer loaded with inorganic materials The process for producing an inorganic porous fiber, characterized in that the processing of the porous fiber polymer of the precursor to remove the organic polymer, and further sintering the inorganic material produced in the form of the porous fiber.