JP2003535234A - UV curable super absorbent coating - Google Patents

Abstract

  (57) [Summary] Articles coated with water resistant coatings that absorb water to provide a water resistant effect and desorb water when the coating dries, and methods of providing water and erosion resistance to articles prepared with such coatings It is. The coating comprises applying to the surface of the article a composition comprising a water-swellable polymer and a non-aqueous solution of a liquid UV-curable resin, and curing the coating comprising the superabsorbent polymer upon exposure to an ultraviolet (UV) light source. Is formed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The application of the Invention The present invention relates to a high strength superabsorbent coating capable of rapidly absorbing water, suitable for coating various articles that require a waterproof surface, it is enhanced or molded It includes, but is not limited to, products and reinforcing materials used in the manufacture of such products. In particular, the coating is formed from a non-aqueous composition that includes a water-swellable polymer powder and a liquid UV curable resin. The coating composition further comprises a viscosity modifier. The concept of the invention also relates to an article coated with a superabsorbent coating composition,
Includes methods of applying such coatings, including reinforced and molded products and fiber reinforced materials. The coatings of the present invention clearly show a high level of water uptake and provide excellent spreading and coating capabilities when applied to a substrate.

[0002] deterioration of moisture beneath the exposed the surface of the article to be used in the background outdoor environments invention takes place by penetration is a well known problem. This degradation includes oxidative degradation caused by the reaction of water to the surface of the reinforcing fibers in which these articles are used and water-induced erosion. In the marine environment, for example, problems especially with flooding are compounded by the salinity of the environment. The presence of salt in such an aqueous environment promotes oxidative degradation. In non-salt water environments, such as those with high atmospheric humidity, water resistant coatings are necessary to protect the surfaces of constructs and devices from moisture induced degradation. Articles affected by the aforementioned degradation include items having a high humidity and a surface exposed to humidity. Such examples include reinforced rods and cables, such as fiber optic or telecommunications cables. These telecommunication cables are often used in situations where they are buried underground or submerged for long periods of time. Such protection from water loss is critical to the integrity of the construction of these cables and the success of their intended function. The telecommunications cable can include, for example, a core that includes a glass rod that acts as a stiffening or stiffening member. This rod contributes to the rigidity of the cable. If water soaks into contact with the cable core components, erosion or chemical degradation of the cable infrastructure will occur.

In order to combat this problem of loss of waterlogging, several strategies have been devised to make cables and other reinforced articles water resistant and to be sensitive inside from contact with water and water vapor in the surrounding environment. Attempts have been made to protect the surface. Techniques for making these water repellent articles have included wrapping the article in a protective facing material and sealing the surface to be protected. Closure techniques include chemically treating the surface layer of the article to withstand water absorption and applying a water repellent coating. The technique of covering the surface with a protective armor material is conventional. For example, using a wrap or tape made of an impermeable polymer with water block capability, or treating the encapsulating material with an emulsion or solution of the water block polymer. The packaging process does not require application of chemical compounds or surface treatment of the article. Rather, protection comes from the area covered by the exterior material.

The coatings traditionally used to repel water were made of a substrate that was insoluble and impermeable to water, thus providing a physical barrier to moisture ingress. Such barrier coatings have included materials such as grease and gels. In the case of cables, for example, these coatings are applied by extrusion under pressure. However, there are certain drawbacks with this type of coating. Greases and gels are difficult to handle due to their slippage and give the coated articles an unpleasant sensation. This is an important factor to be taken into account in the manufacturing process, especially as it affects the ease of handling the cables in the connecting operation. Greases and gels also resist changes in viscosity at low or high temperatures. These changes in viscosity are
Freeze / thaw operations and thus the stability of the coating will be affected. Thus, degraded performance at these points affects the stable performance of the cable. More recently, grease-free, water resistant dry coatings have been devised, which themselves have some water absorption capacity. This ability to absorb water allows the coating to absorb moisture that comes into contact with the article, preventing direct contact with sensitive surfaces. The absorbent component of these dry water block coatings is a dry, granulated, superabsorbent polymer that swells and absorbs upon contact with water. Superabsorbent polymers are usually characterized in terms of their expansion coefficient, expansion capacity and gel strength. Traditional uses of these dry superabsorbent polymers have primarily included personal hygiene product articles, food packaging articles and chemical spill cleaning compositions, although recent experiments have shown that Included is the use of these dry polymers to form coatings for other articles such as reinforced cables. For example,
Hargar, US Pat. No. 5,689,601, discloses a dry water block coating of reinforced fiber articles using milled or granulated water soluble dry blocking components in one or more thin layers of an exterior polymer. Is disclosed. This packaging limits the degree of water absorption achieved by the particulate polymer and thus the swelling capacity of the coating.

In general, either dry or liquid coatings of reinforced fibers, strands and articles, such as cables made from fibrous material, are applied to the surface of the fibrous material and then, if at all, Cure before further processing. In general, the meaning of applying the coating depends on whether a liquid coating is used or a solid particulate coating is applied. In the case of dry coating, coating processes using granulated water blocking agents include several time-consuming and labor-intensive steps that are directly related to the use of granulated or ground polymer. These steps require that one or more treatments with the binder resin be made, and that the milled resin be crushed at the location of the powder coating using equipment such as a fluidized bed.
Including the need to apply more than one species. Alternatively, a liquid coating containing an absorbent polymer can be used. A drawback of aqueous coatings is the time required to set and cure after applying the coating. Conventional coating processes that require heating devices such as ovens and air dryers require additional process time. This has the consequence of increasing process costs. In the prior art, there is a need for waterblock coating compositions for application to reinforced articles or reinforced materials that have a high capacity for water absorption and a concomitant rapid expansion rate. Moreover, it is desirable that such coatings be capable of fast and effective curing without expensive and time consuming steps.

SUMMARY OF THE INVENTION Currently, surprisingly, non-aqueous, containing a high absorbency of the water-blocking coatings, non-aqueous liquid UV curable resin and water-swellable polymer having excellent water-swelling capacity and faster expansion It has been discovered that it can be formed from the coating composition. The coating containing the water-swellable polymer is capable of substantially instantaneous water absorption when exposed to a water environment. In one aspect, the invention includes a method of providing water resistance to a surface of an article,
A) preparing a non-aqueous liquid coating composition comprising a water-swellable polymer and a liquid UV curable resin, b) applying the non-aqueous liquid coating composition to the surface of the article and coated surface And c) exposing the coated surface to UV light to cure the non-aqueous liquid coating composition to provide a coating layer comprising a water-absorbing and water-resistant water-swellable polymer. Forming on the surface of the article.

[0007]

DETAILED DESCRIPTION OF THE INVENTION Embodiments of the Invention The composition of the present invention provides a surface of an article or material that requires a surface resistant to water.
It is suitable for forming water-swellable coatings and thus protects the material underlying the surface treated with the coating. As used herein, the term "article" is specifically intended to include any product or material having a surface requiring a water resistant coating that protects the underlying structure from degradation caused by exposure to moisture. To do. Such articles use molded composite articles, laminates, sheets, reinforced fibrous materials known in the art, and one or more of these materials grouped or interspersed with any type of substrate. Includes products made by. The term also includes articles made using reinforced fiber products such as structural materials or devices. Upon contact of the coated surface of the protected article with water, the coating of the present invention absorbs water and swells in volume. By absorbing water, the coating does not effectively expose it to moisture and protects it from contact with the inner surface of the protected article. As a result, the sensitive inner surface remains dry and protected from degradation by flooding. The coating of the present invention achieves only water-resistant protection by absorbing water and prevents moisture penetration underneath the coating layer.

The water-swellable polymers used in the coatings of the present invention can be selected from polymers that can form non-aqueous solutions used in coating mixtures, and upon curing the loss of the polymer itself as the coating dries. It has an expanded volume and expansion rate that allows it to absorb and subsequently desorb water without. Preferably, such polymers are ground or in particulate form. The water-swellable polymers used in the present invention can be selected, for example, from the group of polymers having the required ability to absorb and desorb large amounts of water. Coatings containing the superabsorbent water-swellable polymers of the present invention absorb significantly greater amounts of water and exhibit swelling rates of up to 75% or more of the dry weight. The desired content of water-swellable polymer in the coating composition is in the range of 5-70%. Preferably, the amount of water-swellable polymer is based on the total weight of the composition.
It is about 44 to 70 mass%. An example of a suitable water-swellable polymer is polyacrylate powder, commercially available under the tradename "AP80HS" from Emerging Technologies. The UV curable resin included in the coating composition of the present invention is suitably a liquid, non-aqueous resin that can be cured rapidly and effectively upon exposure to UV light. Such liquid non-aqueous resins can be selected from UV curable epoxides, polyethers, polyesters, polyurethanes, acrylates and combinations thereof. Preferably, the UV curable resin is a solvent free polyacrylate resin that is typically liquid at room temperature. The resin should be a liquid, however its viscosity will change as a function of temperature. Preferably, the UV curable resin is liquid at ambient temperature or higher. An example of such a resin is polyacrylate, sold under the trade name "500 VINCH" by Zeon Technology. The UV curable resin can be included in the coating composition at a concentration of about 30-95% by weight, based on the total weight of the composition. Preferably, the concentration of UV curable resin is about 35-56% by weight.

The composition used to form the coating of the present invention further comprises one or more photoinitiators to initiate crosslinking of the UV curable resin during the curing process. Examples of photoinitiators are "IRGACURE 651" or "IRGACURE 819", which are commercially available phenyl ketone photoinitiators from Ciba Specialty Chemicals.
Is included. Photoinitiators can be included in the formulation depending on the commercial formulation of the UV curable resin selected. For example, 500 VINCH UV curable resin is sold as a combined formulation containing a UV curable polyacrylate and one or more photoinitiators. The coating composition also comprises one or more additives conventionally known for use in surface coating materials. For example, colorants, viscosity modifiers, surface active agents,
And lubricants can be added to the formulation. The amount of such additives is readily selected by the desired cure of the additives in the composition. The coating composition can be formed by combining a water-swellable polymer powder with a liquid UV curable resin and a photoinitiator. Preferably, the ingredients are
It can be allowed to bind at room temperature. However, the resin can be preheated before being combined with the other ingredients. For example, the resin can be mixed from room temperature to about 66 ° C. (150 ° C.
Can be heated to temperatures up to ° F). The mixture can be blended by any suitable means. In one preferred embodiment, a blend of 50% by weight of water-swellable polymer powder, such as polyacrylate powder, is mixed with 50% water-swellable polymer powder, such as acrylate resin.
% Combined with liquid UV curable resin. The coating formed from this combination was observed to provide maximum water expansion volume.

The coating composition of the present invention can be applied to fibers, rovings, rods, cables and other articles in need of water block protection. Coating composition,
It can be applied to coat these articles by conventional methods, including frosting, dipping, spraying and other known methods. Where the article to be protected is a reinforcing strand or roving, the composition is suitably applied by, but not limited to, means including dip draw dipping followed by passage through a drawing die. Where the coating composition is applied to the reinforcing strands or rovings, the strands or rovings are first sized with a suitable sizing composition that is compatible with the components of the coating composition. A sizing step before the coating is applied is preferred, as it reduces mechanical friction which causes damage to the fiber filaments of the strands or rovings and standing fluff in the mechanical device step.

The water-resistant properties of the coatings of the present invention are obtained by curing a non-aqueous composition by being applied to the surface of an article and then exposed to ultraviolet (UV) light. Curing by exposure to UV light allows for the fast and effective formation of coatings without the need for large energy consuming, equipment requiring long curing times, such as ovens. During the curing process, cross-linking occurs between polymer chains, whereby the coating containing the polymer forms a solidified layer, which absorbs water in contact with the coated surface, thereby lowering the underlying coated article. Protect. Suitably, at least one layer of the coating composition is applied to one or more surfaces of the article to form a coated surface. Next, the coated surface is about 200-
Exposed to UV radiation at a wavelength of 450 nanometers. The frequency of radiation is selected based on the curing requirements of the UV curable resin. For example, where 500 VINCH polyacrylate is used, the preferred frequency for curing the coating is about 350 nanometers. The UV radiation can be provided by a suitable UV light source that provides radiation of the desired frequency. For example, the brand name "FUSION
You can use the light box sold at.

When the coating of the present invention is applied to the surface of a reinforcing fiber strand and cured, the coating exhibits an expanded volume up to an initial dry weight of about 75 wt% water-swellable polymer. Preferably, the swelling volume in this type of application is up to about 40-60% by weight, based on the initial dry weight of the water-swellable polymer. The glass fiber reinforced articles containing the water resistant coatings described herein are suitable for applications where it is desired to form durable, resilient, flexible coatings that are exposed to water and water vapor and have good waterproof properties. Can be used. The following examples are representative and do not limit the scope of the invention.

[0013]

【Example】

An exemplary coating composition was prepared by combining water-swellable polyacrylate polymer powder, AP80HS and 500 VINCH polyacrylate, a non-aqueous liquid UV curable resin in various proportions. The polymer powder and UV curable resin were combined and blended to make a uniform dispersion. "ADVANTEX R25H
The "" or "TYPE-E" glass strands are commercially available presized glass rovings from Owen Corning, which were passed through a bath containing the coating composition to impregnate the strands. After impregnation, the strand was passed through a punch die with the desired orifice size to control the amount of coating composition coated on the surface of the strand. The coated strands were then passed through an array of UV ovens and exposed to UV light for about 0.1-5 seconds to cure. The UV oven UV wavelength was about 365 nanometers.

Example 1 In this example, a coating composition for UV curing was formulated by mixing a blend of superabsorbent polyacrylate and UV acrylate in the proportions listed below. 95% by weight of 500 VINCH UV acrylate manufactured by Zeon Technology and 5% by weight AP 80HS supplied by Emerging Technology Example 2 In this coating composition the same components were combined as follows. 86 wt% 500 VINCH UV acrylate and 14 wt% AP 80HS Example 3 An exemplary coating composition was developed according to the following formulation. 500 VINCH UV Acrylate 75.7 wt% and AP 80HS 24.3 wt% Example 4 In this example, a coating composition for UV curing was formulated according to the following formulation. 500 VINCH UV 64.9 wt% and AP 80HS 35.1 wt% Example 5 In this coating composition the components were combined as follows. 56% by weight of 500 VINCH UV acrylate and 44% by weight of AP 80HS Example 6 In this coating composition the components were combined as follows. 45% by weight of 500 VINCH UV acrylate and 45% by weight of AP 80HS Example 7 In this coating composition the components were combined as follows. 50% by weight 500 VINCH UV acrylate and 50% by weight AP 80HS Example 8 In this coating composition the components were combined as follows. 30% by weight of 500 VINCH UV acrylate and 70% by weight of AP 80HS Example 9 The coatings of Examples 1-8 were examined to determine the swelling capacity of water when applied to the reinforcing fiber material. ADVANTEX R25H Strand and TYPE-E
The glass reinforcing fibers were coated with the coating composition of Examples 1-8. The glass was sized with aminosilane before applying the coating. In each example, the swelling capacity was determined and measured as a percentage swelling overtime calculated based on the total weight of coating and fiber. The results obtained are included in Table 1.

[0015]

[Table 1] ^a Superabsorbent polyacrylate, Emerging Technology ^b UV Acrylate, Zeon Technology ^c Swelling capacity was measured after 1 minute as a percentage change in the mass of the coated strand.

Observations have shown that a significant amount of water absorption is achieved, for example, where the proportion of either the superabsorbent polymer or the UV curable polymer is at a concentration of about 30-70% by weight, respectively. Show. While the invention has been illustrated and illustrated, it will be apparent that the claims are not limited and provide a range consistent with the wording of the claim and its equivalent elements.

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Claims (23)

[Claims] 1. A composition comprising a water-swellable polymer and a liquid UV curable resin is U
An article characterized in that it is at least partially coated with a coating formed by curing upon exposure to V light. 2. The article of claim 1, wherein the coating absorbs water to provide a water resistant effect and desorbs water when dried. 3. The article of claim 1, wherein the water-swellable polymer, after curing, absorbs up to about 75% of its dry weight of water when immersed in an aqueous environment. 4. The article of claim 1, wherein the water-swellable polymer comprises a polyacrylate polymer. 5. The article of claim 1, wherein the liquid UV curable resin comprises an acrylate resin. 6. The article of claim 1 which is a reinforced fiber material. 7. The article of claim 6, further comprising an aminosilane sizing agent under the coating. 8. The article of claim 1, which is a composite article. 9. The article of claim 1 selected from the group consisting of tapes, mats, fabrics, rovings, fiber strands, laminates, sheets, rods and cables. 10. The article of claim 1 selected from the group consisting of molded articles, fabrics, scrims, wood and paper products and structural materials. 11. A non-aqueous coating composition adapted to form a coating that absorbs and desorbs water, the composition comprising a water-swellable polymer and a liquid UV curable resin. 12. The water-swellable polymer is powdery polyacrylate,
The non-aqueous coating composition according to claim 11. 13. The non-aqueous coating composition according to claim 11, wherein the liquid UV curable resin is an acrylate. 14. The non-aqueous coating composition of claim 11, further comprising a photoinitiator. 15. The proportion of water-swellable polymer in the composition is about 30-70.
The non-aqueous coating composition according to claim 11, which is wt.% And the proportion of UV curable resin in the composition is about 30-70 wt.%. 16. A method of providing water resistance to the surface of an article, comprising the steps of: a) preparing a non-aqueous liquid coating composition comprising a water-swellable polymer and a liquid UV curable resin, b). Applying the non-aqueous liquid coating composition to the surface of the article to form a coated surface, and c) exposing the coated surface to UV light to cure the non-aqueous liquid coating composition. And forming a water-absorbing and water-resistant coating layer on the surface of the article. 17. The step of applying the non-aqueous liquid coating composition to the surface of the article comprises contacting the non-aqueous liquid coating composition with the surface of the article to provide a non-aqueous solution over the entire surface of the article. 17. The method of claim 16 including the step of forming a layer of liquid coating. 18. The method of claim 16, wherein the UV light is at a wavelength of about 200-450 nanometers. 19. A reinforced fiber material formed according to the method of claim 16. 20. The reinforcing fiber material according to claim 19, wherein the sizing is applied with an aminosilane before the coating is applied. 21. A composite article formed according to the method of claim 16. 22. A reinforced fiber product formed according to the method of claim 16. 23. An article having at least one surface coated with a water resistant UV curable coating containing a silane, a water-swellable polymer and a liquid UV curable resin.