EP2041037A1 - Method for the production of continuous mineral fibers - Google Patents

Abstract

The invention relates to the technology of producing continuous mineral fiber, made of materials with a particle size of preferably no more than 80 mmm, in a smelting furnace. The melt is channeled into feeders in a processing zone within the distributor channel. The processing zone has an extraction area for the melt for supplying the nozzles of the injector, and the primary continuous fibers are formed within the internal openings of said nozzles. According to the invention, the ratio between the volume of the extraction area for the melt supplied to the nozzles and the internal volume of the feeder is within the range of 0.002 to 0.09, or the ratio between the volume of the extraction area for the melt supplied to the nozzles and the internal volume of the injector filled with melt is within the range of 0.0005 to 0.025, or the ratio between the volume of the extraction area for the melt supplied to the nozzles and the total internal volume of the nozzle openings of the injector is within the range of 0.05 to 2.8.

Description

 Production process for endless mineral fibers

The invention relates to the production of endless mineral fibers, in particular from rock, from mixtures based thereon, from glass-containing industrial and technical waste products.

There is known a method of producing mineral fibers from rock, which involves producing a melt of raw material in a melting furnace, feeding the melt to a processing zone (distribution channel) from which the melt is taken out with a feeding device and supplied to the nozzles (Ukrainian Patent No. 3, 1993, IPC C03B 37/00), wherein the discharge ports of the flow feeder are at a level of 0.8 to 0.2 of the level of the melt in the processing zone.

A disadvantage of this method is that it only defines the procedure for determining an optimum (with regard to the properties of the melt necessary for the production of qualitative primary fibers) removal area in the processing zone (distribution channel). The known method does not match the geometrical dimensions of the removal region with the parameters of the melting furnace in which the preparation of the melt for feeding into the processing zone (distribution channel) takes place, nor with the parameters of the fiber forming system, which is a flow feeder and a nozzle vessel, which are arranged one behind the other and connected to each other. This reduces the overall stability of the fiber production process, but allows the production of endless mineral fibers from viscous and high viscosity melts with an average specific brittleness of at least 0.7 fractions per kg.

There is known a rock mineral fiber manufacturing method which comprises preparing a melt of raw material in a melting furnace, feeding the melt to a processing zone (distribution channel) from which the melt is taken by a feeder and fed to the nozzles (European Patent EP 1380552 , 2002, IPC C03B 37/02), wherein the openings of the flow feeder, through which the removal of the melt takes place and which form the extraction zone for the removal of the melt, are arranged such that the ratio of the height of the melt in the furnace to Height of the removal range for the melt in the range of 1.4 to 50 is located. In addition, according to the known technical solution, the ratio of the melt level in the furnace (the melting tank) to the projection surface of the Entnalimebereichs for the melt to the horizontal plane in the range of 10 to 6000 are. By observing the stated geometric criteria, it is possible to ensure that the melt from the smelting furnace reaches optimal properties for the production of fibers of basalt rock into the distribution channel and the removal area. Although the known method matches the geometrical dimensions of the removal region with the parameters of the melting furnace in which the treatment of the melt for supply to the processing zone (distribution channel) takes place, the known process as before does not provide any connection between the geometry of the removal region for the melt with the parameters of the fiber-forming system, which is a flow feeder and a nozzle vessel arranged one behind the other and connected to each other. This does not make it possible to ensure a high overall stability of the fiber production process, but has made it possible to improve the characteristics of the production of continuous mineral fibers to an average specific brittleness of at least 0.5 fractions per kg and a daily average output of a single unit of up to 170 kg.

A process is known for producing continuous mineral fibers from rock, in particular basalt rock (hereinafter "basalt"), in which milled rock is melted in a melting furnace from which the melt flows into a processing zone (distribution channel) from where flow is fed the melt takes place to the nozzles, where the shaping of the fibers takes place ("Osnovy proizvodstva bazal'tovyh volokon", DD Dzigiris, MF Mahova, Moscow: Teploenergetik, 2002, 416 p.). In this case, as shown in Fig. 3.7 (page 107), the extraction area for taking out the melt for flow supply to the nozzles is formed by an end opening of the flow feeder and openings on the side surface of the flow feeder. The known method defines the function of the flow feeder as follows: "Taking a temperature homogeneous melt and stabilizing its supply to the nozzle feeder for processing into primary fiber" (p. 106).

Starting from the observance of the principle of a continuous melt flow and the applicability of the Poiseuille-Hagen equation for the calculation of the mass flow of the melt in the system flow feeder nozzle vessel, the known technical solution establishes a connection (ratio) between the volume of the flow feeder and the summary Volume of the nozzles and the height of the melting column in the nozzle vessel (in fact, the height of the nozzle vessel) fixed. These calculations were made on the assumption that the ratio of the kinematic viscosity of the melt in the flow feeder to the kinematic viscosity of the melt in the die vessel is 0.6. This ratio between the melt viscosities in the flow feeder and in the nozzle vessel depends primarily on the temperature of the melt itself, which is withdrawn from the processing zone (distribution channel) and the walls of the said devices, which are usually by ohmic heating on passage electric current to be heated. However, taking into account that the working temperatures of the materials from which the flow feeder (nozzle vessel) are produced, are generally limited to a range from 1350 to 1800 ⁰ C, which is close to the melting temperature of the rock, as it is - also in view of the low thermal conductivity and diathermy nature of basalt rock melts - it is not possible to use the flow feeder (the nozzle vessel) for effectively controlling the properties of the melt, in particular for heating the melt to optimum temperatures. As noted above, the only function of the flow feeder is to "stabilize" the melt with optimum properties from the removal area to the nozzle vessel (s) for fiber formation. At the same time, the possibility of a "stabilized" supply undoubtedly determines the relationship between the geometrical dimensions of the zone of the melt removal area (in fact, the volume inside) the flow feeder delimited by the plane of its end opening and the plane connecting the lower and lower edges of the lower openings located on the side surface of the flow feeder and located in the processing zone) and the geometrical dimensions (in fact the volume en) of the flow feeder, the nozzle vessel and the total volume of the inner nozzle opening. Unfortunately, no information about these conditions can be found in the known technical solutions.

The object to be solved by the present invention is to increase the stability and effectiveness of basalt rock melt fiber manufacturing technology, mixtures based thereon, glass-containing industrial and engineering wastes, resulting in a reduction of the average specific brittleness on stripping of the primary yarns and an increase in the specific output of a single production unit.

This object is achieved by the proposed methods of producing mineral fibers from rock, mixtures therefrom, glass-containing industrial and technical waste products, according to which materials having a particle size of preferably not more than 80 mm are melted in a melting furnace and the melt flow feeders in the processing zone ( in the processing zone), in the processing zone a demnalimization area for the melt for flow supply to the nozzles of the nozzle vessel, in the inner openings of the Primärlos Endlosfasem be formed is formed, according to the invention the ratio of the volume of the removal area for the melt flow to the Nozzles to the internal volume of the flow feeder in the range of 0.002 to 0.09, the ratio of the volume of the removal area for the melt to flow to the nozzles to the inner volume of the nozzle vessel, which is filled with melt, in B range from 0.0005 to 0.025 and the ratio of the volume of the melt removal area to the flow rate to the internal volume of the nozzle openings of the nozzle vessel is in the range of 0.05 to 2.8.

The distribution channel is also often called feeder channel or supply line or basin.

The volume in the enthalpy area comprises the internal volume of the opening or openings in the region of the end face of the flow feeder and the internal volume of the openings which are located on the side faces of the flow feeder. The wall thickness of the flow feeder is low, this being selected from a range with a lower limit of 0.1 mm, preferably 0.5 mm, in particular 0.8 mm and an upper limit of 10 mm, preferably 5 mm, in particular 3 mm , Wall thicknesses from a range of max. 1 mm. This results in very small volumes. The total volume of the openings in the side areas of the flow feeder is from a range with a lower limit of 50 mm ³ , preferably 80 mm ³ , in particular 100 mm ³ , and an upper limit of 500 mm ³ , preferably 300 mm, in particular 200 mm. Volumes of 150 mm ³ to 180 mm ³ prove to be particularly advantageous. By contrast, the total volume of the opening or openings in the end region of the flow feeder is from a range with a lower limit of 1000 mm ³ , preferably 1500 mm ³ , in particular 2000 mm, and an upper limit of 10000 mm ³ , preferably 5000 mm ³ , in particular 4000 mm ³ , selected. Volumes of 3200 mm ³ to 3800 mm ^{3 are} advantageous. Even very small deviations of the volumes of a few percent can be of great importance for the quality of the mineral fibers.

The diameter of the end opening or the sum of the end openings of the flow feeder is selected from a range with a lower limit of 1 mm, preferably 5 mm, in particular 10 mm, and an upper limit of 100 mm, preferably 50 mm, in particular 30 mm. The height over which the openings are distributed on the side surfaces of the flow feeder is from a range with a lower limit of 0.5 mm, preferably 2 mm, in particular 5 mm, and an upper limit of 200 mm, preferably 100 mm, in particular 50 mm, selected.

The internal volume of the nozzle openings is limited by the plane in the bottom and front of the nozzle opening.

In general, the nozzle vessel is completely filled with melt to produce and maintain a defined static pressure. However, it is also possible to use a very low static pressure for the production of mineral fibers, the nozzle vessel also only having to be partially filled with melt.

The diameter of the nozzle openings is selected from a range with a lower limit of 0.5 mm, preferably 1 mm, in particular 1.5 mm, and an upper limit of 50 mm, preferably 20 mm, in particular 10 mm. Particularly advantageous are openings with an average diameter in the range of 1 mm to 5 mm.

In this way, the present invention provides optimum ratios of the volume of the melt removal area to the internal volumes of the flow feeder and the nozzle vessel, and also the internal volume of the internal openings of the nozzles of the nozzle vessel.

This gives the process of fiber formation through the nozzles stability and reduces the average specific brittleness of the endless mineral fibers in relation to the previously achieved a value of 0.5 fractions per kg for the entire spectrum of known compositions of basalt rock suitable for the production of mineral fibers. A stable shaping process of the fibers through the nozzles in turn allows an increase in the average daily output of a single unit to at least 170 kg.

At ratios of the volume of the melt removal area which is virtually equal to the volume inside the flow feeder delimited by the plane of the face opening of the flow feeder and the area which the lower edges of those located on the side face of the flow feeder and in the processing zone to the inner volumes of the flow reservoir, the nozzle vessel and the nozzle orifices of less than 0.02, 0.0005 and 0.05 respectively, the amount of melt entering the molding system is not sufficient, and it may come to violations of the principle of continuous flow of the melt, which flows into the inner nozzle openings. This, in turn, obviously leads to an increase in the specific brittleness of the primary fibers and a reduction in the specific production of the fiber-forming system. With ratios of the volume of the melt removal area to the inner volumes of the flow memory, the nozzle vessel and the nozzle orifices of more than 0.09, 0.025 and 2.8, respectively, melt flows at different temperatures into the flow feeder (it is known from the literature, that the temperature of the melt on heating from the surface decreases on average by 15 to 17 ° C every 10 mm) and a viscosity which can not be stabilized with the aid of the heat released from the walls of the flow feeder which leads to Example be heated by passing electrical current (the amount of heat mentioned is limited by the working interval of the materials from which the flow feeder is made). In this way, a melt which does not have the optimum properties flows into the nozzle vessel and the inner openings of the nozzles, which leads to an increase in the specific brittleness of the primary fibers and a reduction in the specific production of the fiber forming system. The possibilities for effective control of the properties of the melt are also limited by the properties of the materials from which the nozzle vessel is made, as described above.

The process is illustrated by the following examples. example 1

Basalt rock giving a viscous melt having the following composition (% by weight): 52.8 to 53.7 SiO ₂ , 0.5 to 0.6 TIO ₂ , 17.3 to 19.7 Al ₂ O ₃ , 9.8 to 10.6 Fe ₂ O ₃ + FeO, 3.1 to 6.3 MgO 7.1 to 8.0 CaO, 2.8 Na ₂ 0, 1.6 K ₂ O, others - 1 , 8, was ground to particle sizes of 10 to 20 mm, mechanically sorted and placed in a smelting furnace where, with the aid of the combustion energy of the gas-air mixture, a temperature of 1450 ± 10 ⁰ C was maintained to produce a homogeneous melt. Subsequently, the melt flowed into the processing zone itself - the distribution channel, on the bottom of which flow feed tubes were arranged, which had openings in the end face as well as on the side face near the end face. The temperature of the melt in the distribution channel was maintained in the range of 1300 to 1350 ⁰ C. In the distribution channel, a removal area was formed, wherein the depth of the distribution channel, the height of the withdrawal area exceeded 3.5 times. With the aid of the flow feeders, the melt was led from the processing zone to the nozzle vessel, where the formation of the fibers took place in the inner nozzle openings. The ratios of the volume of the melt extraction area to the inner volumes of the flow feeder, the nozzle vessel and the nozzle openings were 0.025, 0.006 and 0.45, respectively. Under production conditions, a mean specific brittleness of basalt continuous fibers of 0.45 fractions per kg and a mean output of a single unit of 177 kg per 24 hours was achieved.

Example 2

To justify the claimed limit values set forth in the claims, continuous mineral fibers were prepared under conditions which differed in part from the conditions given for Example 1. Thus, by means of a forced welding of the openings on the side surface of the flow feeder and / or the nozzles of the nozzle vessel and by varying the geometric dimensions of the flow feeder and the nozzle vessel, the ratios of the volume of the removal area for the melt to the inner volumes of the flow feeder, the nozzle vessel and the nozzle openings are varied in the ranges of 0.001 to 0.1, 0.0004 to 0.03, and 0.04 to 3.0, respectively. The results which resulted from the variation of the mentioned parameters are given in Table 1. Table 1. Variants of the production process for endless mineral fibers

Example 3

According to the invention, mineral fibers were produced from Kraftwerksasche, the calcite (CaCO ₃ ) was added, according to the technology described for Example 1.

The ash was composed of the following components (wt%): 43.6 SiO ₂ , 16.2 Al ₂ O ₃ , 1.6 Fe ₂ O ₃ , 5.25 FeO, 0.7 Li ₂ O, 26 , 7 CaO, 3.11 MgO, 0.67 K ₂ O, and 2.17 other ingredients.

From 63% ash according to the stated composition, which was filled with calcite granules, mineral fibers were produced; the average output of a single unit was 160 kg per 24 h.

Example 4

According to the technique described for Example 1, at a temperature of 1300 ± 30 ° C in the melting furnace and 1100 to 1270 ° C in the distribution channel mineral fibers from glass-containing technical waste products (fluorescent tubes) were prepared according to the invention.

The glass-containing technical waste products were composed of the following components (% by weight): 72.0 SiO ₂ , 2.0 Al ₂ O ₃ , <0.01 FeO, 19.5 to 18 (Na ₂ O + K ₂ O), 8.0 (CaO + MgO + BaO), traces of PbO, Sb ₂ O ₃ , As ₂ O ₃ , Cd oxide, Ti and other components.

Under experimental conditions, mineral fibers were produced with a single unit average output of 163 kg per 24 hours.

Claims

Patent claims

A process for the production of mineral fibers from rock, mixtures therefrom, glass-containing industrial and technical waste products, according to which materials having a particle size of preferably not more than 80 mm are melted in a melting furnace and the melt is fed to flow feeders in the processing zone in the distribution channel, the processing zone is formed a melt removal area for feeding the nozzles of the nozzle vessel into whose inner openings the primary endless fibers are formed, characterized in that the removal area for the melt is formed such that the ratio of the volume of the removal area for the melt Melt to the internal volume of the flow feeder is in the range of 0.002 to 0.09.

2. Method of production of mineral fibers from rock, mixtures based thereon, glass-containing industrial and technical waste products, according to which materials with a particle size of preferably not more than 80 mm are melted in a melting furnace and the melt is fed to flow feeders in the processing zone in the distribution channel, in the processing zone is formed a melt removal area for feeding the nozzles of the nozzle vessel into whose inner openings the primary endless fibers are formed, characterized in that the removal area for the melt is formed such that the ratio of the volume of the removal area for the melt Melt to the inner volume of the melt-filled nozzle vessel in the range of 0.0005 to 0.025.

3. Method of production of mineral fibers from rock, mixtures based thereon, glass-containing industrial and technical waste products, according to which materials with a particle size of preferably not more than 80 mm are melted in a melting furnace and the melt is fed to flow feeders in the processing zone in the distribution channel, in the processing zone is formed a melt removal area for feeding the nozzles of the nozzle vessel, in whose inner openings the primary endless fibers are formed, characterized in that the removal area for the melt is formed such that the ratio of the volume of the removal area for the melt to the total inner volume of the nozzle openings of the nozzle vessel is in the range of 0.05 to 2.8.

4. Method of production of mineral fibers from rock, mixtures based thereon, glass-containing industrial and technical waste products, according to which materials with a particle size of preferably not more than 80 mm are melted in a melting furnace and the melt is fed to flow feeders in the processing zone in the distribution channel in that a removal zone for the melt for supplying flow to the nozzles of the nozzle vessel, in the inner openings of which the primary endless fibers are formed, is formed in the processing zone, characterized in that the removal area for the melt is formed such that a) the ratio of the volume b. the ratio of the volume of the melt removal area to the internal volume of the melt-filled die feeder is in the range of 0.0005 to 0.025, c ) there s ratio of the volume of the removal area for the melt to the summary inner volume of the nozzle openings of the nozzle feeder is in the range of 0.05 to 2.8.