RU2039137C1 - Method of producing unwoven material - Google Patents

Abstract

FIELD: protection against chemical pollutions. SUBSTANCE: microfibers are pulled away from polymeric melt. Then the microfibers are put down into linen formed continuously at the receiving part of the shell. Solid particles of ion-exchange filler are introduced and the linen got is pulled out to have ion-exchange filler inside. Then the linen is compacted in roller press and ready material is wound. In this case the microfibers pulled out are put down onto the internal surface of the linen being under forming continuously through all its perimeter The linen is compacted in roller press before winding at the temperature of softening of polymeric material. Natural compounds are used as ion-exchange filler or ion-exchange synthetic gums. Polypropylene is used as polymeric material. EFFECT: improved efficiency. 4 cl, 2 dwg

Description

 The invention relates to non-woven materials formed by the aerodynamic method from a polymer melt, in particular to a method for producing non-woven material with ion-exchange filler, and can be used in the manufacture of dust masks or protective masks when cleaning air from radioactive particles and aerosols, as well as for the production of gas masks and other protective equipment for general use.

 A known method of manufacturing a non-woven filter material, in which the fiber-forming polymer material is electrified in the form of a fiber stream in a liquid medium, the spun microfibers are thinned with a high-speed flat gas flow, the microfibers are layered on the outer surface of the technological mandrel, and before laying the still solidified microfibers, solid particles are introduced into the bundle of spun microfibers ion-exchange filler and after laying them in the layered structure of the filter material act the uterine roller (US patent N 3904798, CL D 04 H 1/04, 1973).

 However, the material produced in a known manner has low operational properties due to the high packing density of microfibers, which leads to increased hydraulic resistance of the material when filtering air in respiratory devices, as well as low efficiency of the method due to losses of the ion-exchange filler when introduced into a bundle of spun microfibers laid on the outer surface technological mandrel. Moreover, the lighter the weight of the used particles of the ion-exchange filler, the greater the value of technological losses due to the entrainment of particles by a high-speed gas stream.

 To improve operational properties, there is a known method of manufacturing a nonwoven material, in which a fiber bundle is straightened out from a polymer melt, solid particles of an ion-exchange filler are introduced into the fiber bundle after the fibers have solidified before laying them on the receiving surface, and particles of activated carbon, aluminum oxide, are used as solid particles. and polyethylene is used as the polymeric material (USSR patent N 1142007, class D 04 H 3/00, 1985).

 However, the known method, adopted as a prototype in terms of the number of similar features, is characterized by low efficiency, due to certain losses of the ion-exchange filler in the process of introducing solid particles into a high-speed stream of spinning fibers. In addition, the method is characterized by high consumption of compressed gas necessary for introducing the transported solid particles into the fiber bundle, representing a flat projection in space, which also reduces the efficiency of the known method, and the introduction of solid particles, especially a fine fraction, and laying on the outer surface of the mandrel or the receiving surface leads to technological dustiness of the production atmosphere with these particles and requires additional costs for the implementation of measures to reduce dustiness, h about also reduces the efficiency of the process.

 The purpose of the invention is to increase the efficiency of the method by reducing the loss of ion-exchange filler.

 This goal is achieved by the fact that in the proposed method, according to the invention, the spun microfibers are laid on the inner surface of the stationary technological mandrel along its perimeter at the melting temperature of the polymer material and after laying the microfibers, solid filler particles are introduced onto the inner surface of the continuously formed canvas along its perimeter, and before by winding the finished nonwoven material, the formed canvas with the filler placed inside is pressed in a roller press at a temperature of softening polymer material. In addition, polypropylene is used as the polymeric material, and natural zeolites or synthetic ion-exchange resins, the melting temperature of which exceed the softening temperature of the polymeric material, are used as the ion-exchange filler.

 An introduction to the proposed method of a new significant distinguishing feature, namely, that "spun microfibers are laid on the inner surface of a stationary technological mandrel along its perimeter at the melting temperature of the polymer material", allows you to form the canvas in the form of a continuous sleeve with a given pore size. Moreover, the temperatures indicated in the process determine the self-binding of the spun microfibers into a porous self-supporting structure of the canvas with pore sizes smaller than the size of the introduced particles of the filler, which eliminates its loss.

 The introduction of the second significant distinguishing feature, which consists in the fact that “after laying microfibers, solid filler particles are introduced onto the inner surface of the continuously formed canvas along its perimeter”, in the proposed method, the guaranteed placement of filler particles inside the porous sleeve is ensured, regardless of the varying size of the filler particles and its dispersion, the possibility of dusting of the production atmosphere is excluded, and all fine particles are captured in the process and precipitated on the inner surface of the porous nonwoven web in the form of a sleeve, which causes the occurrence of an unexpected positive effect in comparison with the prototype. In this case, the percentage ratio of injected solid particles and polymer microfibers is controlled by the speed of the extruded molded canvas, which leads to an increase in the efficiency of the method and reduces the loss of ion-exchange filler.

 The introduction of the third significant distinguishing feature, namely: "before winding the finished non-woven material, a molded canvas with an ion-exchange filler is pressed in a roller press at a softening temperature of the polymer material", causes the invention to heat-fix the material in the form of a flat layered canvas with two external hygienic layers of soft polymer microfibers , and also provides the indentation and incorporation of solid particles into the structure of the nonwoven material, which reduces the loss of filler and improves t hygienic properties of the nonwoven fabric. The use of natural zeolites extends the range of adsorbed chemical contaminants and simplifies the process due to their high melting point, and the use of polypropylene allows to obtain superthin, less than 5 microns, polymer microfibers.

 Figure 1 shows a device in vertical projection for carrying out process operations; figure 2 is the same in horizontal projection.

 The method is as follows.

 The granules of the polymer material are placed in the extruder and melted to the pour point of the polymer material, and then squeezed out through the many holes of the ring spinning head 1. At the same time, compressed purified air heated to the melting temperature of the polymer material is fed into the spinning head 1, under the influence of which the ring bundle of microfibers 2 is straightened. The rectified microfibers are laid on the inner surface of the stationary technological mandrel 3. In connection with the use in the process tsevoy head 1, in which the fiber-forming channels arranged circumferentially vypryadaemye microfibers are laid on the perimeter of the mandrel and the process produced a nonwoven fabric as a continuous sleeve. At the same time, in the space between the head surface and the inner surface of the technological mandrel in the enclosed space, the microfibers are cooled to a temperature below the pour point, the microfibers are laid at the melting temperature of the polymer material, at which a self-bonded fibrous canvas is formed.

 After laying the microfibers in a continuously formed canvas in the form of a sleeve that is continuously stretched along the technological mandrel, solid filler particles are introduced using an annular head 4 into which pre-screened solid particles of an ion-exchange filler, for example, natural zeolites or ion-exchange synthetic resins, are fed.

 In this case, the solid particles of the filler are introduced onto the inner surface of the continuously formed canvas in the form of a sleeve along its perimeter with the help of compressed air introduced together with the solid particles. Under the action of air flowing from the head 4, particles in a confined space are deposited inside the sleeve, which eliminates the loss of ion-exchange filler, and the air purified from fine dust enters the production atmosphere through the porous canvas structure, thereby ensuring high environmental friendliness of the proposed method. The percentage of solid particles and microfibers is controlled by the speed of drawing the formed canvas along the technological mandrel.

 The molded canvas with two external hygienic layers of polymer microfibers and a layer of solid particles of ion-exchange filler placed inside is stretched and simultaneously pressed vertically in the roller press 5 at a surface temperature of the rolls equal to the softening temperature of the polymer material. Under the influence of the force of the roller press 5, solid particles are densified and incorporated into the structure of the fibrous canvas, which prevents the loss of filler during operation and improves the filtration characteristics of the resulting non-woven material.

 After pressing, the finished material is continuously fed to the receiving device 8, in which it is wound into a roll, and then packaged in a known manner.

PRI me R. Polypropylene mark 21180-16 heated in a screw extruder type P2-32h25 to a temperature ^of 270 C and then through a plurality of holes of 0.3 mm diameter located in the circular circumference of the head 1, extruded (extruded) into technological mandrel 3. Simultaneously, the head 1 fed purified compressed air heated to a temperature ^of 170 C at a speed of 200 m / s. The resulting microfibers with an average diameter of 3 μm were laid on the inner surface of the mandrel, and then a molded canvas in the form of a sleeve was wound on a receiving device at a speed of 1 m / min. After laying the microfibers in the canvas in the form of a sleeve through the head 4, an air inventory with solid particles with an average size of 10 μm of natural zeolite was applied, which was laid on the inner surface of the formed canvas. Thus obtained non-woven material was pulled and pressed with a gain of 100 kg in a roller press at a temperature of 130 ^about C, and then the finished material was wound into a roll on the receiving device. The resulting material was characterized by a hydraulic resistance of 10 mm aq. column, and the solids content was 45%. At the same time, there was no loss of ion-exchange filler and no dustiness of the atmosphere.

 The resulting material sorbed toluene vapors.

Claims (4)

 1. A METHOD OF PRODUCING A NONWOVEN MATERIAL, in which a microfibre beam is straightened out from a polymer melt, continuously placed on a canvas on the receiving surface of the technological mandrel, solid particles are introduced, the formed canvas is pulled and wound on a receiving device, characterized in that the spun microfibers are laid on the inner surface fixed technological mandrel along its perimeter, after laying microfibers injected solid particles on the inner surface of a continuously formed canvas along its perimeter , and before winding the canvas, it is pressed in a roller press at a softening temperature of the polymer material.  2. The method according to claim 1, characterized in that polypropylene is used as the polymeric material.  3. The method according to claim 1, characterized in that natural zeolites are used as solid particles.  4. The method according to claim 3, characterized in that ion-exchange resins are used as solid particles, the melting temperature of which exceeds the softening temperature of the polymer material.

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