EXTRUSION COATED NON-TWISTED YARN

Information

  • Patent Application
  • 20150344362
  • Publication Number
    20150344362
  • Date Filed
    August 10, 2015
    9 years ago
  • Date Published
    December 03, 2015
    9 years ago
Abstract
The present invention provides a non-twisted yarn and an extrusion coated reinforcement yarn and their methods of manufacture, by coating non-twisted glass filaments with a sizing composition and combining the filaments together side-by-side to provide a sized non-twisted yarn, wherein the sizing composition becomes ductile in a molten thermoplastic resin to free the non-twisted glass filaments for radially inward movement while in the molten thermoplastic resin to provide the non-twisted yarn with an essentially round cross-section suitable for extrusion coating with the molten thermoplastic resin.
Description
FIELD OF THE INVENTION

The invention relates to a yarn suitable for extrusion coating and a method of making the same. Further, the invention relates to an extrusion coated yarn and a method of making the same.


BACKGROUND

U.S. Pat. No. 6,254,817 discloses an extrusion coated reinforcement yarn. The reinforcement yarn is made with glass fibers possessing a high elastic modulus. A continuous, thin protective coating of a thermoplastic resin material protects the glass fibers from contact with moisture and alkali environments.


The extrusion-coated reinforcement yarn can be used to make a mesh reinforcement sheet. In turn, the mesh is used to reinforce a cementitious matrix, such as cementitious gypsum, stucco or portland cement. Alternatively, an individual extrusion-coated reinforcement yarn itself can be used to reinforce a cementitious matrix.


An extrusion coated reinforcement yarn is manufactured by making glass filaments, and combining the glass filaments to make the yarn. Typically, the glass filaments are twisted to form a twisted yarn. Then the twisted yarn is co-extruded with a molten thermoplastic resin material. The co-extrusion process is required to produce a uniformly distributed, thin extrusion coating continuously over the surface of the yarn.


U.S. Pat. No. 5,451,355 discloses a cross-head tip and extrusion die assembly for co-extruding a twisted yarn with a molten thermoplastic resin material. The yarn is continuously fed to a cross-head tip of the assembly. The molten resin material is continuously supplied by an extrusion apparatus to a chamber in the cross-head tip, wherein the resin material uniformly distributes about the yarn prior to co-extrusion. Co-extrusion is performed by passage of the yarn and the molten resin material through a round co-extrusion die of the assembly.


Twisted yarn is manufactured with individual glass filaments. For example, 200-1200 glass filaments are manufactured by drawing molten glass through a platinum alloy bushing that may contain up to several hundred orifices. The bushing produces continuous, drawn glass filaments that solidify as they emerge from its orifices. The filaments emerging from the bushing are continuously sized with a fluent sizing composition, then gathered into a strand and wound into intermediate forming package (cake) for further processing steps.


Extrusion coating of a twisted yarn is reasonably common. A twisting process is performed during yarn manufacturing. After appropriate temperature and humidity conditioning the strands of the forming cakes are continuously twisted on a ring twister in Z-twist or S-twist directions, which produces a round twisted yarn. Extrusion coating of a twisted yarn is reasonably common.


This round yarn is extrusion coated by passing continuously through a round co-extrusion die, a die having a round extrusion orifice. While the round yarn passes continuously through the round extrusion orifice, the round yarn will self-center concentrically in the round extrusion orifice. This enables the round extrusion die to uniformly distribute extrusion pressure surrounding the round yarn. As a result, the co-extruded molten thermoplastic resin material distributes uniformly over the surface of the round yarn. Such uniform pressure distribution enables formation of a uniform, thin coating of thermoplastic material continuously over the surface of the round yarn. Extrusion coating of a round yarn can be done at speeds >300 m./min., which produces a high quality yarn with a round shape.


A twisting process and associated manufacturing equipment has been required to produce a round yarn, which is suitable for extrusion coating. It would be desirable to eliminate the twisting process by producing non-twisted yarn for extrusion coating. However, non-twisted yarn possesses an asymmetrical cross section that has been unsuitable for extrusion coating. The asymmetrical cross section transported through a co-extrusion die produces uneven pressure distribution of the molten thermoplastic resin around the yarn. As a result, extrusion coating of such yarns is difficult due to the asymmetric and unstable resin flow patterns that occur in the die during extrusion. Consequently, the co-extrusion die has difficulty applying a uniformly thin coating continuously on the surface of the yarn. As a result of this asymmetric resin flow, the yarn possesses a resin coating that is asymmetric around the yarn. The thermoplastic resin tends to be thicker in places and thinner in other places, and can possess undesired voids. This lack of roundness and lack of centering of such a yarn is unacceptable.


It would be desirable to produce a non-twisted yarn suitable for extrusion coating. Further, it would be advantageous to provide an extrusion coated reinforcement yarn that is non-twisted and yet has a uniformly thin coating of the thermoplastic resin, and a method of manufacturing the same.


SUMMARY OF THE INVENTION

The present invention provides a method of manufacturing a non-twisted yarn, by sizing non-twisted glass filaments with a sizing composition and combining the filaments together side-by-side to provide a sized non-twisted yarn, wherein the sizing composition becomes ductile in a molten thermoplastic resin to free the non-twisted glass filaments for movement laterally of their lengths within the molten thermoplastic resin and provide the non-twisted yarn with an essentially round cross-section suitable for extrusion coating.


The present invention provides a method of making an extrusion coated reinforcement yarn as follows: coating non-twisted glass filaments with a sizing composition and combining the filaments together side-by-side to provide a sized non-twisted yarn; distributing a molten thermoplastic resin around the sized non-twisted yarn prior to coextrusion, wherein the sizing composition becomes ductile in the molten thermoplastic resin to free the glass filaments for movement within the molten thermoplastic resin; and coextruding the yarn and the resin to move the glass filaments laterally of their lengths within the molten thermoplastic resin and provide the yarn with an essentially round cross-section, wherein the yarn is non-twisted and is coated with a uniformly thin coating of the thermoplastic resin.





BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the invention will now be described by way of example with reference to the accompanying drawings.



FIG. 1 is a schematic view of apparatus for manufacture of continuous non-twisted glass filaments and a continuous non-twisted yarn, and a cross-head extrusion tip and die assembly for manufacture of an extrusion coated glass yarn.



FIG. 2 is a schematic view of extrusion apparatus having the cross-head extrusion tip and die assembly of FIG. 1.



FIG. 3 discloses cross-sections of extrusion coated yarns having TD37 sizing.



FIG. 4 discloses cross-sections of extrusion coated yarns having 5251 sizing.





DETAILED DESCRIPTION


FIG. 1 is a schematic diagram of an apparatus 100 to manufacture continuous non-twisted glass filaments 102 and a continuous non-twisted yarn 104 suitable for manufacturing an extrusion coated reinforcement yarn 106. FIG. 1 discloses a glass composition 108 supplied to a furnace 110 for heating the glass composition 108 to provide molten glass 112. Depending on the composition 108, the glass 112 comprises E-glass, D glass, R glass, C glass, or AR glass. AR glass itself is alkali resistant, and relies on an extrusion coating 122 for additional protection.


The molten glass 112 exits the furnace 110 through a bushing or forming die 114. The molten glass 112 is drawn through numerous miniature orifices of the bushing or forming die 114 to produce drawn glass filaments 102 numbering from 800 to 1200. The glass filaments 102 leaving the bushing or forming die 114 solidify sufficiently to increase their tensile modulus.


A sizing (size) applicator 116 applies an adherent sizing (size) composition 118 onto the filaments 102, preferably by leaching. Before the sizing has an opportunity to dry, the sizing coated (sized) filaments 102 are gathered together side-by-side without twisting and without interlocking to one another. After applying the sizing the filaments gathered together into a strand are wound on a sleeve placed on the take up device (winder) to build the forming package (cakes). The cakes are then dried and cured in an oven to remove the excess of water and allows the film formation of the sizing necessary for further processing operations. The adherent sizing composition 118 is dried to bind the filaments 102 together and form a sizing coated (sized) non-twisted yarn 104. After forming, the cakes contain excess water and are dried, and especially when unwound, the cakes must be dry.


The sizing (size) composition 118 adheres to the filaments 102 to create a bond between the glass and an extrusion coating 122 to be applied onto the non-twisted yarn 104. The sizing composition 118 adheres to the filaments 102, and the filaments 102 adhere to one another side-by-side to provide a sized non-twisted yarn 104. A sized yarn 104 refers to the yarn having filaments 102 with the sizing composition 118 coating the filaments 102 and adhering them to one another. A non-twisted yarn 104 refers to the filaments 102 thereof having zero twist, i.e. being non-twisted and non-interlocked together, and adhered together by the adherent sizing composition 118.


Preferably, the sizing composition 118 becomes less adherent in a molten thermoplastic resin including but not limited to polyethylene, isotactic or syndio polypropylene, polyester, ethylene-propylene copolymers of other olefin fibers, nylon, polyvinyl chloride, copolymer of polybutylene and propylene, ethylene propylene rubber (EPR), thermoplastic polyolefin rubber (TBR), polyvinylidene chloride (SARAN.®.) or ethylene-propylene diene monomer (EPDM).



FIG. 1 discloses a co-extrusion apparatus 119 having a cross-head extruder tip 124 and die assembly 126 for impregnation and continuous coating of the non-twisted yarn 104 with a molten thermoplastic resin 122. The sized yarn 104 is continuously cross-fed to the cross-head extruder tip 124. The sized yarn 104 is transported through a cross head passage 128, then concentrically through a die head cavity 130 in the die assembly 126, and extruded through an outlet orifice 132 of the die assembly 126. FIG. 1 discloses the sized yarn 104 directly transported to the cross-head extruder tip 124 and die assembly 126 after application of the sizing composition 118. Alternatively, the sized yarn 104 is reeled into a continuous coil and packaged in a cake package for shipping and handling. The sized yarn 104 in a cake package is known as a cake yarn. The cake yarn is payed-out, i.e., un-reeled from the cake package and continuously cross-fed to the cross-head extruder tip 124. The cake yarn is transported through a cross head passage 128, then concentrically through a die head cavity 130 in the die assembly 126, and extruded through an outlet orifice 132 of the die assembly 126.


The cross head passage 128 extends through a frusta-conical end 134 of the cross-head extruder tip 124, where the passage 128 is surrounded by a concentric chamber 136 filled with the molten thermoplastic resin 122 under pressure. The molten thermoplastic resin 122 under pressure fills the chamber 136 and surrounds the concentric cross-head end 134. The chamber 136 communicates with a feed duct 138 into which is continuously fed the molten thermoplastic resin 122 under pressure from an extruder 200, FIG. 2. The extruder 200 has an input hopper 202 into which is continuously supplied meltable pellets of thermoplastic resin 122, which are heated and driven under pressure of a drive screw in the extruder 200 to the feed duct 138. A motor 204 is provided to turn the screw drive. The cross-head end 134 and the metal material surrounding the chamber 136 are at an elevated melting temperature of the molten thermoplastic resin 122 to maintain continuous melt flow. Following coextrusion, the extrusion coated reinforcement yarn 106 is transported through a cooling device 206 downstream from the die assembly 126. The cooling device 206 has a series of nozzles 208 for spraying cooling water into the interior of the cooling device 206. Further details of the apparatus 100 are described in U.S. Pat. No. 5,451,355.


By means of this specific internal structure, when the yarn 104 in the die head cavity 130 comes into contact with the molten thermoplastic resin 122 under pressure, the latter distributes uniform radial pressure on the entire periphery of the yarn 104 as soon as contact is established. As a result, all the filaments 102 in the yarn 104 are subjected to the same pressure.


The sizing composition 118 temporarily holds the filaments 102 together, while the yarn 104 is transported through the cross-head 124. As the yarn 104 is transported along the die head cavity 130, the sizing composition on the filaments 102 is contacted by the surrounding molten thermoplastic resin 122. The sizing composition 118 on the filaments 102 softens by immersion in the heat and chemical composition of the molten thermoplastic resin 122 under pressure. Thereby the sizing composition 118 is rendered ductile and loses its tensile strength. The filaments 102 that are held by the ductile sizing composition 118 are free to move by deforming the ductile sizing composition 118. The sizing composition 118 is rendered ductile, which frees the filaments 102 to move under radial pressure applied thereto by the molten thermoplastic resin 122 surrounding the yarn 104 and the filaments 102. As a result, the sizing composition 118 becomes ductile in the molten thermoplastic resin 122 to free the non-twisted glass filaments 102 for movement radially inward of the yarn 1-4, while within the molten thermoplastic resin 122 under pressure, to provide the non-twisted yarn 104 with an essentially round cross-section. As the cavity 130 progressively narrows in a direction toward the round outlet orifice 132, the corresponding unit pressure increases radially inward on the non-twisted glass filaments 102 to move them radially inward to form the yarn 104 with a circular or round cross-section. The yarn 104 having freed glass filaments 102 and the molten thermoplastic resin 122 are co-extruded by transport through the round outlet orifice 132. The molten thermoplastic resin 122 is transported under pressure, while the yarn 104 is transported by pulling tension, for example.


The outlet orifice 132 is machined with a round orifice to distribute uniform pressure of the molten thermoplastic resin 122 over the surface of the yarn 104, and is dimensioned to apply a uniformly thin coating of thermoplastic resin 122 surrounding a non-twisted yarn 104. The yarn 104 has essentially a round cross-section obtained by moving the freed glass filaments 102 under radial pressure applied by the molten thermoplastic resin 122 itself under pressure. Upon exiting from the outlet orifice 132 is an extrusion coated reinforcement yarn 104, The yarn 104 being non-twisted and having non-twisted glass filaments 102. The non-twisted glass fibers 102 are gathered together to provide the yarn 104 with an essentially round cross-section. The resin forms a uniformly distributed, thin extrusion coating 122 on the yarn 104. According to an embodiment of the invention, the surface of the sized yarn 104 can be heated prior to being cross-fed to the co-extrusion apparatus 119. The surface of the sized yarn 104 is heated to the melt temperature or slightly above the melt temperature of either one of, the sizing composition, the sizing composition including a film former composition or the molten thermoplastic resin 122.



FIG. 1 discloses the sized yarn 104, alternatively a cake yarn, transported continuously through a pre-heater oven 140. The non-twisted yarn is manufactured at a greater production speed compared to twisted yarn. As an advantageous result, the greater production speed enables performance of extrusion coating of the non-twisted yarn at a corresponding greater production speed. An embodiment of the invention advantageously uses untwisted yarns at high production speed. Twisted yarns can be used by a process step of untwisting the twisted yarns at high production speed.


EXAMPLE

Cake yarns of non-twisted E glass filaments 33 tex (9 micron filaments) were produced using the apparatus of FIGS. 1 and 2, and were coated with different non-adhesive sizing compositions: Part Numbers: T61 (stach oil binder); 5339 (starch free sizing composed of a modified maleic anhydride propylene as film former and an amino silane); 5251 (starch oil sizing with adhesion promoters for coating with PVC plastisol); TD37 (starch free sizing with film former having a melting point of about 40-50° C., which are commercially available from Vetrotex France S. A., Chambery, France. The filaments were combined together, side by side without twisting and without interlocking to provide a non-twisted sized yarn. The sized yarn had random cross section dimensions provided by the side-by-side filaments.


Different samples of the sized yarn were co-extruded with a thermoplastic resin composition of filled PVC resin, according to the following manufacturing parameters, as follows:


cake yarn: 33 tex (9 micron filaments)


sizing composition types for respective samples: T61(average sizing content applied on the filaments: 1.00%); 5339 (Sizing content applied on the filaments in a range of 0.4% to 1.00%); 5251(average sizing content applied on the filament: 0.85%); TD37 sizing TD37 includes a film former composition and has a melt temperature range of 40° C.-50° C. (average sizing content applied on the filaments: 0.60%). Other film former compositions are available with different melt temperature ranges, for example, a preferred melt temperature range of 30° C.-140° C. and most preferred melt temperature range of 40° C.-60° C. The TD37 sizing has a melt temperature within the most preferred melt temperature range.


coating composition: filled PVC resin


DPU for respective samples: 140%; 170%; 230%


co-extrusion speed range: 800-1000 m/min.


tooling temperature range: 187.8 DC-193.3° C. (370-380° F.)


extruder pressure: 1900-2000 psi


pre-heater oven temperature for respective samples: ambient; 320° C. (600° F.)); 540° C. (1000° F.)); 700° C. (1300° F.). The surface of the glass yarn is heated to a melt temperature or slightly higher than the melt temperature of either one of the sizing composition, the sizing composition including the melt former composition or the extrusion coating prior to the extrusion process steps.



FIG. 3 discloses roundness of yarn cross-section and roundness of resin coating TD37 produced at different DPU values of the Example and different preheater temperatures of the Example. Sizing TD37 contains a film former having a melt temperature range of 40° C.-50° C. The cross-sections indicate roundness of yarn cross-section improves with heating to temperature values above 540° C. (1000° F.). The cross-sections indicate roundness of the resin coating improves with higher DPU values.



FIG. 4 discloses roundness of yarn cross-section and roundness of resin coating 5251 produced at different DPU values and different preheater temperatures. The cross-sections indicate roundness of yarn cross-section improves with heating to temperature values above 540° C. (1000° F.). The cross-sections indicate roundness of the resin coating improves with higher DPU values. The temperatures in FIG. 4 are the temperature settings of the preheater. When the yarn is moving at 800-1000 m/min, the residence time in the preheater is 0.1 to 0.09 seconds. Due to the residence time, the preheater temperature must be set quite high to actually achieve a temperature that allows the size to melt. If the preheater was longer or the yarn was moving slower, the temperature setting of the preheater would have to be reduced. The unexpected result is accomplished by a balanced adjustment of yarn speed through the preheater, preheater length, size melting temperature, and preheater temperature to achieve the following:


1.) melted size, sizing, that frees up the glass filaments of the cake yarn so that they are free to move (round-up) under the pressure of the crosshead.


2.) a warm yarn that allows the resin in the crosshead to penetrate and adhere better to outer surfaces of filaments at an outer edge or outer surface of the yarn bundle.


This description of the exemplary embodiments is intended to be read in connection with the accompanying drawings, which are to be considered part of the entire written description. In the description, relative terms such as “lower,” “upper,” “horizontal,” “vertical,”, “above,” “below,” “up,” “down,” “top” and “bottom” as well as derivative thereof (e.g., “horizontally,” “downwardly,” “upwardly,” etc.) should be construed to refer to the orientation as then described or as shown in the drawing under discussion. These relative terms are for convenience of description and do not require that the apparatus be constructed or operated in a particular orientation. Terms concerning attachments, coupling and the like, such as “connected” and “interconnected,” refer to a relationship wherein structures are secured or attached to one another either directly or indirectly through intervening structures, as well as both movable or rigid attachments or relationships, unless expressly described otherwise.


Patents and patent applications referred to herein are hereby incorporated by reference in their entireties. Although the invention has been described in terms of exemplary embodiments, it is not limited thereto. Rather, the appended claims should be construed broadly, to include other variants and embodiments of the invention, which may be made by those skilled in the art without departing from the scope and range of equivalents of the invention.

Claims
  • 1. An extrusion coated reinforcement yarn comprising: non-twisted glass filaments, the glass filaments adhered with a sizing composition to form an individual non-twisted yarn strand; anda uniformly distributed thin, thermoplastic resin extrusion coating directly in contact with and surrounding the individual non-twisted yarn strand, wherein the thermoplastic resin penetrates and adhere to the outer surface of the yarn to form the extrusion coated reinforcement yarn, the thermoplastic resin comprising a polyethylene, an isotactic propylene, a syndiotactic polypropylene, a polyester, an ethylene-propylene copolymer, nylon, polyvinyl chloride, a copolymer of polybutylene and propylene, an ethylene propylene rubber, a thermoplastic polyolefin, a polyvinylidene chloride, or ethylene-propylene diene monomer (EPDM), wherein the extrusion coated reinforcement yarn has an essentially round cross-section.
  • 2. The extrusion coated reinforcement yarn of claim 1, wherein the sizing composition is softened and rendered ductile in a molten thermoplastic resin to free the filaments for radially inward movement within the individual non-twisted yarn strand to provide the extrusion coated reinforcement yarn with the essentially round cross-section.
  • 3. The extrusion coated reinforcement yarn of claim 1, wherein the sizing composition has a melting point of about 40° C. to 50° C.
  • 4. The extrusion coated reinforcement yarn of claim 1, wherein the sizing composition is starch free.
  • 5. The extrusion coated reinforcement yarn of claim 1, wherein the sizing composition includes a film former composition.
  • 6. The extrusion coated reinforcement yarn of claim 5, wherein the film former composition has a melt temperature of 30° C. to 140° C., or a melt temperature of 40° C. to 60° C.
  • 7. The extrusion coated reinforcement yarn of claim 1, wherein the non-twisted glass filaments number from 800 to 1200.
  • 8. The extrusion coated reinforcement yarn of claim 1, wherein the individual non-twisted yarn strand is 33 tex.
  • 9. The extrusion coated reinforcement yarn of claim 1, wherein the non-twisted glass filaments are 9 micron filaments.
  • 10. The extrusion coated reinforcement yarn of claim 1, wherein the non-twisted glass filaments are not interlocked.
  • 11. The extrusion coated reinforcement yarn of claim 1, wherein the sizing composition provides a bond between the glass filaments and the extrusion coating.
  • 12. The extrusion coated reinforcement yarn of claim 1, wherein the glass filaments comprise E-glass, D glass, R glass, C glass, or AR glass.
  • 13. The extrusion coated reinforcement yarn of claim 1, wherein the sizing is present on the glass filaments in a range of 0.4% to 1.00%.
  • 14. The extrusion coated reinforcement yarn of claim 1, wherein the extrusion coated reinforcement yarn reinforces a cementitious matrix.
  • 15. The extrusion coated reinforcement yarn of claim 14, wherein the cementitious matrix is gypsum, stucco, or Portland cement.
  • 16. The extrusion coated reinforcement yarn of claim 1, wherein the extrusion coated reinforcement yarn is used in a mesh reinforcement sheet.
  • 17. An extrusion coated reinforcement yarn to reinforce a cementitious matrix, the extrusion coated reinforcement yarn comprising: non-twisted glass filaments, the glass filaments adhered with a sizing composition to form an individual non-twisted yarn strand; anda uniformly distributed thin, thermoplastic resin extrusion coating directly in contact with and surrounding the individual non-twisted yarn strand, wherein the thermoplastic resin penetrates and adhere to the outer surface of the yarn to form the extrusion coated reinforcement yarn, the thermoplastic resin comprising a polyethylene, an isotactic propylene, a syndiotactic polypropylene, a polyester, an ethylene-propylene copolymer, nylon, polyvinyl chloride, a copolymer of polybutylene and propylene, an ethylene propylene rubber, a thermoplastic polyolefin, a polyvinylidene chloride, or ethylene-propylene diene monomer (EPDM), wherein the extrusion coated reinforcement yarn has an essentially round cross-section.
  • 18. The extrusion coated reinforcement yarn of claim 17, wherein the sizing composition is softened and rendered ductile in a molten thermoplastic resin to free the filaments for radially inward movement within the individual non-twisted yarn strand to provide the extrusion coated reinforcement yarn with the essentially round cross-section.
  • 19. The extrusion coated reinforcement yarn of claim 17, wherein the sizing composition is starch free.
  • 20. The extrusion coated reinforcement yarn of claim 17, wherein the sizing composition includes a film former composition.
CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. patent application Ser. No. 12/792,957, filed Jun. 3, 2010, entitled “Extrusion Coated Non-Twisted Yarn” naming Inventors Nancy E. Brown, Armel Kerbat and Eric Daniel which in turn claims priority from U.S. Provisional Patent Application Ser. No. 61/225,965 filed on Jul. 16, 2009, entitled “Extrusion Coated Non-Twisted Yarn” naming inventors Nancy E. Brown, Armel Kerbat and Eric Daniel, which are all incorporated by reference herein in their entirety.

Provisional Applications (1)
Number Date Country
61225965 Jul 2009 US
Continuations (1)
Number Date Country
Parent 12792957 Jun 2010 US
Child 14822400 US