KR20030048763A - Plastic surface reforming method - Google Patents

Abstract

PURPOSE: A process for modifying plastic surface is provided to increase the strength of plastic surface, to prevent scratch, to improve thermal stability, and to modify electric and optical properties of plastics. CONSTITUTION: The process for modifying plastic surface comprises forming molten plastics into a desired shape and coating a fine hollow body on the plastic surfaces wherein the fine hollow body is coated in a single layer, has the diameter greater than two times of the surface roughness, and is embedded into the plastics in the depth of greater than 1/3D in which the distance between the hollow bodies is 5D to 15D. The fine hollow body is selected from glasses, metals, ceramics and plastics.

Description

Plastic surface reforming method

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plastic surface modification method for improving the physical properties of plastics formed from polymer materials. In particular, a spherical body having a small diameter is applied to a surface of a plastic to improve abrasion resistance of the plastic surface, It relates to a plastic surface modification method that can be imparted.

Plastics, which are widely used in production sites, are limited by the low physical properties of polymer materials compared to materials such as metals. Typical physical properties of polymer materials include 'low surface strength', 'surface scratches caused by abrasive materials', 'low softening temperatures and flame hazards', and many other restrictions on their use.

Polymers used in construction materials or electronics require abrasion resistance, so it is necessary to modify the surface to facilitate the use of plastics on the job site.However, due to the low thermal stability of the polymer material, it is necessary to apply general surface modification techniques. What is difficult is the reality. Thus, there is a need for surface modification techniques that are easy to apply to polymer surfaces.

Looking at the conventional techniques similar to the technique used in the present invention are as follows.

Abe Hidetoshi has obtained a patent for "Adhesive Coating Film" (US.6015606), which is a technique for fixing a fine spherical elastic body of 10-100㎛ size on the surface of the film with an adhesive and is mainly used for surface decoration. have.

While the above described techniques can improve the decorative properties of the adhesive film within a limited range, spherical elastomers do not increase the strength of the surface and require additives such as adhesives to fix the spherical elastomers on the surface and the surface treatment before coating. There is a disadvantage required.

Ulrich Kempf also obtained a patent for "circuit board paper with microspheres" (US.6042936), which has a fine glass hollow on the paper substrate. It describes how to make a circuit board by mounting a shallow glass microsphere. The paper substrate is made up of 5 to 50% of plastic fiber of 10 to 50 mu m and paper pulp to which a filler of glass hollow body is added.

Mounting the microporous body in the above-described paper substrate has the effect of increasing the insulation properties of the substrate, but the overall cost increases because the microporous body does not increase the surface strength of the substrate and the amount is 5-50% of the substrate weight. And there is a disadvantage of requiring an additive material such as plastic fibers.

In addition, Howard Plummer has applied for a "PCB substrate consisting of inorganic microspheres and reinforced polymer composite resins" in US Patent US Pat. No. 5,162,162, which uses a flame retardant using a microsphere. It describes how to play the role of) and the insulation characteristics.

The PCB substrate according to this patent has high thermal stability, flame retardant and uniform insulating properties, but the microspheres uniformly mounted on the substrate do not increase the strength of the plastic surface. The amount is 25-65% of the total, which increases the cost of the product.

In other words, there is a problem in that general plastics are limited in the use of the product due to the physical properties of the polymer forming the plastic, and even modified plastics do not increase the surface strength, thereby limiting the use of the product.

The present invention has been made in order to solve the above problems of the prior art, by molding a plastic in a molten state to a desired shape and then coating a micro-hollow body on the surface of the plastic to improve the physical properties of the plastic and optical / electrical properties It is an object of the present invention to provide a method of modifying plastic surface that is to be shown.

1 is a detailed cross-sectional view showing a plastic surface modified by the plastic surface modification method of the present invention,

2 is a reference diagram schematically showing a microporous body and an abrasive coated on a surface of a plastic,

Figure 3 is a reference drawing comparing the diameter of the microporous body with the roughness of the plastic surface,

4 is a reference diagram for explaining the relationship between the depth in which the microhollow body is planted and the scratch resistance.

<Explanation of symbols on main parts of the drawings>

50: plastic 60: micro hollow body

70: abrasive grain 70 ': abrasive (critical size)

The present invention for solving the above technical problem is to form a plastic in a molten state to a desired shape and then coating a microporous body on the surface of the plastic, the microporous body is coated with a single layer, the diameter is at least surface roughness It is more than twice, and 1 / 3D or more is planted in plastic, and the distance between hollow bodies is set to be about 5-15D.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

The plastic surface modification method according to the present invention is to mold the plastic in the molten state into a desired shape and then to coat the microporous body 60 on the surface of the plastic 50 as shown in FIG.

At this time, the micro-hollow body 60 is coated with a single layer, the diameter of which is used at least twice the surface roughness, it is determined within the range of about 5-40㎛. In addition, the micro-hollow body 60 is planted in the plastic 50 to a depth of about 1 / 2D to 2 / 3D, the distance between the hollow body 60 should be larger than the diameter of the hollow body 60 and 5- Irregularly distributed within the range of 15D.

Looking at the distribution of the micro-hollow body 60 it is preferable to be distributed non-uniformly, as shown in Figure 2, if the size of the abrasive grains 70 is greater than the critical diameter (Dc), a plurality of abrasive grains 70 necessarily The micro hollow bodies 60 are distributed to be in contact at the same time.

Looking at the relationship between the micro-hollow body 60 and the surface roughness (Rz) as shown in Figure 3 and 4 should be larger than the diameter of the micro-hollow body (60). If the diameter of the micro-hollow body 60 is smaller than the surface roughness Rz, the micro-hollow body 60 is recessed in the surface of the plastic 50 so that the micro-hollow body 60 may not exhibit the advantages of the coating. In addition, in order for the microporous body 60 coated on the surface of the plastic 50 to sufficiently cope with the scratch force Fs, it is planted to a depth of 1 / 2D or more to reduce the height difference Δh1 from the surface of the plastic 50. very important.

The microhollow body 60 may be formed of glass, metal, ceramic, plastic, or the like, and the inside thereof may maintain a vacuum or fill a filler 60 'such as a solid, a liquid, and a gas according to a purpose.

The plastic modified by the plastic surface modification method of the present invention configured as described above will allow the microporous body to protect the plastic from scratches or other environmental factors.

In order to coat the microporous body 60 of a single layer on the surface of the plastic 50, the plastic 50 is first molded. After the plastic 50 is molded, the micro-hollow body 60 is coated to meet the above conditions. In order to coat the micro-hollow body 60 on the plastic 50, a method such as plastic molding, plasma molding, water jet coating, and detonation coating is used. do.

These methods have advantages and disadvantages in terms of cost and uniformity of coating, respectively. The most preferable method in terms of cost and uniformity is that the molten plastic 50 is molded and then solidified in the molding process. Plastic molding method for coating the micro-hollow body 60 on the surface of the plastic (50). As the plastic molding method, extrusion, injection molding, blow molding, heating molding, reaction injection molding, and compression molding may be used. Each coating method is as follows.

First, referring to the method using extrusion, the plastic 50 in the molten state in the extrusion process is molded in a desired shape according to the shape of the die and then cooled. The hollow body 60 is coated on the surface of the plastic 50 molded into the desired shape in the extrusion die, which is preferably coated before the plastic 50 is completely solidified. That is, by connecting the extrusion die and the hollow reservoir, the plastic 50 passes through the extrusion die and passes through the hollow reservoir so that the hollow body 60 is coated on the surface of the plastic 50.

In addition, referring to the method using injection molding, injection molding is one of the most typical methods of molding a thermoplastic resin and molding the plastic 50 by supplying and cooling the plastic 50 in a molten state to a mold having a predetermined shape through a nozzle. In this process, in order to coat the microporous body 60 on the surface of the plastic 50, a work of uniformly spraying the microporous body 60 onto the mold surface is required before the molten plastic is supplied to the mold. Do.

In addition, in the case of using other plastic molding methods such as blow molding, heating molding, reaction injection molding, compression molding, and the like, the micro-hollow body 60 may be formed by a method similar to that used in the extrusion and injection molding processes. ) Can be coated on the surface.

Except for the plastic molding method, there are coating methods such as plasma coating, waterjet coating, and coating by explosion, and the plasma coating is performed on the surface of the object at high speed using a high temperature plasma flame. It is a method of spraying and coating. In this process, the micro-hollow body 60 is heated in a short time, coated on the surface of the plastic 50 at high speed, and then cooled.

Waterjet coating is a method of coating the micro-hollow body 60 on the surface of the plastic 50 by using a high-pressure fluid, since it does not use heat, it is possible to prevent damage to the surface by heat is suitable for the polymer material. In addition, the coating by the explosion is a method using the explosive force of the gas particles (oxygen and acetylene), the micro-hollow body 60 is injected at a high speed by the explosive force so that a strong coating on the surface of the plastic 50 is made. .

The plastic 50 modified by the coating of the micro-hollow body 60 does not scratch the plastic surface, and the flexibility of the plastic 50 is maintained even after the coating. In addition, when the metal or magnetic material is filled in the inside of the micro hollow body 60, the electrical or electromagnetic characteristics of the plastic 50 may be improved, and the color of the plastic 50 may be changed by changing the color of the micro hollow body 60. Optical properties can be improved. When the micro-hollow body 60 is formed of glass, ultraviolet rays can be absorbed and have high thermal stability and flame resistance. In order to coat the microporous body 60 on the surface of the plastic 50, a simple method is used, which does not cause an environmental problem, and the amount of the microporous body 60 is only about 2-15% of the total weight. There is an advantage that does not increase the cost.

The present invention configured as described above may be used in various applications in the future of plastics. In other words, the plastic is prevented from being overheated by heat, and the plastic contact lens, artificial tissue, and medical devices can be applied to the medical field.

Plastic surface modification method according to the present invention configured as described above to increase the surface strength of the plastic to prevent scratches and to have a high thermal stability and to change the electrical and optical properties of the plastic can be applied to various fields There is an advantage.

Claims (6)

After molding the molten plastic into a desired shape and coating a micro-hollow body on the surface of the plastic, The microporous body is coated with a single layer, the diameter of which is at least twice the surface roughness, 1 / 3D or more is planted in the plastic, the distance between the hollow body is about 5-15D, characterized in that the plastic surface modification Way. The method of claim 1, The microporous body is a plastic surface modification method, characterized in that formed of any one of glass, metal, ceramic, plastic. The method of claim 1, The inside of the micro-hollow body plastic surface modification method characterized in that to maintain a vacuum. The method of claim 1, The inside of the micro-hollow body is a plastic surface modification method characterized in that the filling of solids, liquids and gases, etc. in accordance with the required properties of the plastic. The method of claim 1, The micro-hollow body is a plastic surface modification method characterized in that it is planted in plastic to a depth of about 1 / 2D-2 / 3D. The method of claim 1, The micro-hollow body is a plastic surface modification method, characterized in that the irregular coating on the surface of the plastic.