KR20090029581A - Wall finish material and method for manufacturing thereof - Google Patents

Abstract

Finishing material and the manufacturing method thereof are provided that the installation in the place exposed to the external environment is possible since the enough mechanical strength is held and durability is improved. A finishing material(100) comprises a reinforcement plate layer(110) for protecting the bending, a secondary jewelry class thin film layer(120) and an adhesive resin layer(130). The reinforcement plate layer for preventing the bending is made of one out of glass, building stone, and double sided etching glass.

Description

Finish Material and Method for Manufacturing

The present invention relates to a method for producing a finishing material and a method for manufacturing the same, and more particularly, a finishing material manufactured by using a semiprecious material such as quartz, marble, crystal, wood fossil, ore into a thin plate and using the same, and a method of manufacturing the same. It relates to a finish produced by.

In general, the finishing material refers to the interior and exterior materials of the building to be built on the interior or exterior walls or floors of the building. In the broadest sense, the finished material is the finished material on the outside of all household goods used in daily life.

Such a finishing material, as well as having the required mechanical properties such as corrosion resistance, durability, as well as aesthetic properties that can be visually beautiful need to be excellent. The exterior design is of utmost importance to every household item that is visible and tactile in everyday life.

Recently, semiprecious gems such as quartz, marble, crystal, wood fossil and ore have been preferred as finishing materials. These natural or artificial mineral materials are excellent in strength in terms of durability, and also have excellent characteristics in terms of aesthetics such as color change according to the irradiation angle of the light and produce beautiful and refined images. Therefore, the demand for finishing materials using semi-precious materials is increasing.

However, there are some problems in using these semi-precious materials as a finishing material for general buildings. First of all, it was difficult to process semiprecious materials into thin plates in the prior art, so semiprecious materials used for finishing materials are a little thicker, and semiprecious materials are expensive because semiprecious materials are expensive. If used as a finishing material, the unit price will be high. Therefore, the price competitiveness of finishing materials using semi-precious stones is inevitably lowered, making it difficult to commercialize them.

One of the ways to utilize semi-precious stones may be a method of processing the semi-precious materials into thin sheets. For this purpose, the semiprecious materials should be processed into thin plates firstly. Next, if the semiprecious materials processed into thin sheets are used as finishing materials, the unit cost can be lowered, but the mechanical strength of the finishing materials themselves will be weak, resulting in deflection. This may occur, and if it is severe, there is a high possibility of being easily damaged by external stimulus such as external force and impact, so it should have sufficient mechanical strength.

As described above, in the case of finishing materials of general buildings using semi-precious materials, it is necessary to develop finishing materials having sufficient mechanical strength and manufacturing methods of such finishing materials while reducing manufacturing costs.

Therefore, an object of the present invention, by processing a semi-precious material such as quartz, marble, crystal, wood fossil, ore into a thin plate applied to the finishing material, it is possible to reduce the manufacturing cost, and to maintain the durability by maintaining sufficient mechanical strength It is to provide a finish and a method of manufacturing the finish that can be improved.

The above object, according to the present invention, the reinforcing plate layer for preventing bending; A semi-precious thin plate layer disposed on at least one surface of the reinforcing plate layer for preventing warpage because at least one of crystal, crystal, wood fossil, and natural mineral is processed into a thin plate having a predetermined thickness; And an adhesive resin layer applied between the quasi-jewelry thin plate layer and the anti-warp reinforcing plate layer such that the semi-precious thin plate layer is adhered to the anti-bending reinforcement plate layer. .

The semi-precious thin plate layer may be prepared by arranging one kind of semi-precious stone thin plate or several kinds of semi-precious thin plate side by side with the reinforcing plate layer for preventing bending.

The semi-precious thin plate may be cut into a thin plate of 1 mm to 5 mm by a predetermined thin plate processing machine.

The bending prevention reinforcing plate layer may be provided by any one selected from glass, stone, and double-sided etching glass.

The adhesive resin layer may be provided by at least one selected from ultraviolet irradiation curable resin and natural reaction curable resin.

The semi-precious thin plate layer is disposed on one surface of the anti-bending reinforcing plate layer, the finish may further include an additional coating layer is further applied to the other surface of the anti-bending reinforcing plate layer facing the semi-precious stone thin plate layer.

The additional coating layer may be provided by at least one selected from adhesive resin and fiber glass.

The semi-precious thin sheet layer may be disposed to be symmetrical to both sides of the anti-bending reinforcing plate layer on the basis of the anti-bending reinforcing plate layer.

At least one of quartz, crystal, wood fossil, and natural minerals is processed into a thin plate having a predetermined thickness, and the plurality of semi-precious thin plate layers are arranged in a plurality of layers; And an adhesive resin layer applied between the plurality of semi-precious thin plate layers to adhere the plurality of semi-precious thin plate layers to each other.

The semi-precious thin plates may be alternately disposed so that the clearances between the semi-precious thin plates forming the plurality of semi-precious thin plates are not coincident with each other along the thickness direction.

Providing a bending prevention reinforcing plate layer; Forming a semi-precipitate thin layer by arranging a semi-precipitate thin plate processed by at least one of crystals, crystals, wood fossils, and natural minerals into a thin plate having a predetermined thickness on at least one surface of the reinforcing plate preventing layer; And forming an adhesive resin layer between the quasi-jewelry thin plate layer and the anti-warp reinforcing plate layer such that the semi-precious thin plate layer is adhered to the warpage reinforcing plate layer.

The method may further include polishing the exposed surface of the semi-precious thin sheet layer to remove the adhesive resin remaining on the exposed surface of the semi-precious thin sheet layer.

The semi-precious thin sheet is provided by arranging one kind of semi-precipitated thin plate or several kinds of semi-precious thin plates side by side with the reinforcing plate layer for preventing bending, and the semi-precious thin sheet is 1 mm to 5 by a predetermined thin sheet processing machine. It may be prepared by cutting into a thin plate of mm.

The bending prevention reinforcing plate layer may be provided by any one selected from glass, stone, and double-sided etching glass.

The adhesive resin layer may be provided by at least one selected from ultraviolet irradiation curable resin and natural reaction curable resin.

The semi-precious thin plate layer may be disposed on one surface of the anti-bending reinforcing plate layer, and may further include forming an additional coating layer on the other surface of the anti-bending reinforcing plate layer opposite to the semi-precious thin plate layer.

The additional coating layer may be provided by at least one selected from adhesive resin and fiber glass.

The semi-precious thin sheet layer may be disposed to be symmetrical to both sides of the anti-bending reinforcing plate layer on the basis of the anti-bending reinforcing plate layer.

Forming a plurality of semi-precipitate thin layers by arranging the semi-precipitate thin sheets processed by at least one of crystals, crystals, wood fossils, and natural minerals into thin layers; And forming an adhesive resin layer between the plurality of semi-precious thin plate layers so that the plurality of semi-precious thin plate layers are bonded to each other.

In the forming of the plurality of semi-precious thin plate layers, the semi-precious thin plates may be alternately disposed so that the clearances between the semi-precious thin plates forming the plurality of semi-precious thin plate layers do not coincide with each other along the thickness direction. .

According to the present invention, by processing a semi-precious material such as crystal, marble, crystal, wood fossil, ore into a thin plate applied to the finishing material, it is possible to reduce the production cost, and also to have sufficient mechanical strength to improve its durability have.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the embodiments of the present invention, reference should be made to the accompanying drawings which illustrate preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, the present invention will be described in detail by explaining preferred embodiments of the present invention with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

1 is a plan view of a finish according to a first embodiment of the present invention, Figure 2 is a cross-sectional view taken along the line II-II of Figure 1, Figure 3 is a thin plate for processing a semi-precipitate thin plate applied to the finish of Figure 1 4 is a schematic perspective view of a processing machine, FIG. 4 is an enlarged view illustrating main parts of FIG. 3, and FIG. 5 is a flowchart of a manufacturing method for manufacturing the finish of FIG. 1.

Referring to these figures, but mainly referring to Figure 2, the finishing material 100 according to the present embodiment is largely composed of four layers. That is, the finishing material 100 according to the present embodiment, the bending prevention reinforcement plate layer 110, and at least one of the crystal, crystal, wood fossil, natural mineral is processed into a thin plate having a predetermined thickness to prevent the bending prevention reinforcement plate layer ( Between the semi-precious thin plate layer 120 and the semi-precious thin plate layer 120 disposed on one surface of the 110, the semi-precious thin plate layer 120 and the anti-bending reinforcement plate layer 110 to be bonded to the anti-bending reinforcing plate layer 110. The adhesive resin layer 130 to be applied to, and the additional coating layer 140 is further applied to the other surface of the anti-warm reinforcing plate layer 110 facing the semi-precious thin plate layer 120.

The reinforcement board layer 110 for preventing bending is a portion which forms a basic skeleton in the finishing material 100 of the present embodiment. As will be described in detail later, the semi-precious thin plate layer 120 is processed to a thin plate having a thickness of several millimeters in order to improve the price competitiveness of the semi-precious thin plate using the semi-precious stone thin layer 120 to use as a finishing material as it is. In this case, a phenomenon such as bending or deflection in the vertical direction of the plate surface may occur due to its own weight or other external force. This phenomenon lowers the mechanical strength of the semi-precious thin plate 121 itself, and may be easily broken or destroyed. Therefore, in order to reinforce the mechanical strength of the semiprecious thin plate layer 120, the reinforcing plate layer 110 for preventing bending is provided.

As the material of the reinforcing plate layer 110, glass, double-sided etched glass, stone, or the like may be selectively used depending on the application of the finishing material 100 or the purpose of use. When the glass plate 111 is selected as the reinforcing plate 110, it is necessary to selectively transmit the light of a window, a partition, etc., through which light may be transmitted, or other lighting means (not shown) provided in the finishing material 100. It can be used where it is. On the other hand, when using a stone (not shown) as the reinforcing plate 110, it is possible to increase the strength of the finish (100). The finishing material 100 may be installed where the external force is frequently acting, or easily exposed to the external environment. In this embodiment, the glass plate 111 is used as the material of the reinforcing plate layer 110.

The glass plate 111 may have excellent light transmittance. This makes it possible to use the optical properties of light, such as scattering, polarization, diffraction, etc. that the semi-precious thin plate 121 has. That is, by using a light source irradiated using a lighting means (not shown) inside the finishing material 100 to irradiate the light to the finishing material 100 to which the semi-precious stone thin plate 121 is bonded so as to utilize a function as an interior accessory. do. In other words, when using the glass plate 111 of the transparent material, it is possible to double the inherent color and optical properties of the semi-precious thin plate 121 by using the light transmittance. In addition, in the case of using a glass plate (not shown) in which a pretreatment process is applied to the glass plate 111 and then etched, the light is combined with the semiprecious thin plate 121 and the glass plate 111 to deform the optical characteristics. You can also use The function as an interior accessory using the light transmittance of the finishing material 100 will be described in detail later.

As described above, the semi-precious gems 55 (see FIG. 3) may be quartz, crystal, wood fossil, natural mineral, or the like. The semi-precious stone 55 may be more beautiful, refined and beautiful in appearance than other general interior and exterior materials. However, the semi-precious stones 55 are mostly natural minerals collected in a natural state or artificial minerals obtained by having a high cost in artificial production. Therefore, the supply volume is insufficient and the cost of reprocessing is relatively high. As a result, the price of the semi-precious stones 55 is not only expensive but also disadvantageous in terms of the manufacturing cost of the products using the semi-precious stones 55, and thus the use of the semi-precious stones 55 has been restricted.

As part of the scheme for overcoming these problems, in the present invention, the semiprecious stones 55 are sliced into thin semi-precious stone plates 121 having a thin plate shape, and the finishing material 100 having the semiprecious stone thin layer 120 is provided. May be considered. The semi-precious thin plate layer 120 is disposed only on one side of the reinforcing plate layer 110 for preventing bending in this embodiment. Therefore, when the finishing material 100 is used as interior and exterior materials of the building, the semi-precious thin plate layer 120 becomes an exposed surface. The semi-precious thin plate layer 120 may be provided by one kind of semi-precious thin plate 121 or may be provided by a plurality of semi-precious thin plates 121, and the plurality of semi-precious thin plates 121 may be gemstones. All of the semi-precious gems 55 (refer to FIG. 3) may be cut into thin plates 121 of substantially equal thickness and then bonded to each other by an adhesive resin to be described later. For reference, FIG. 1 shows a plurality of semi-precious thin plates 121 having different types and sizes, and all semi-precious thin plates 121 are provided with the same reference numerals for convenience of description.

Conventionally, since the semiprecious material is cut with a saw, it is difficult to process the thin plate as described above. In the present invention, in order to process the thin semi-precipitate thin plates 121 having a thin plate shape from the semiprecious stone 55, as shown in FIG. 3. A processor is used.

First, the method of processing the thin plate 20 will be briefly described. As shown in FIG. 3, a plurality of wires 53 called saws are rotated and rotated in a direction substantially perpendicular to the moving direction of the wires 53. It cuts while passing the semi-precious gem 55. When cutting, a solid slurry (not shown) including an abrasive (not shown) is supplied, and the abrasive (not shown) and the wire 53 work in combination to cut the semi-precious gems 55 which are workpieces.

Looking at the configuration of the thin sheet processing machine 50 used in this embodiment, the thin sheet processing machine 50, the moving support frame 51, three rollers 52 for winding the wire 53, and the roller 52 ) And a slurry supply unit 54 for supplying an abrasive (not shown) to the wire 53, which is integrally wound around the wire 53, and is disposed in the vicinity of the wire 53 and rotates.

Wire 53 used for cutting is made of a metal or fiber material, the diameter of the wire 53 may be formed of 0.16 ~ 0.2 mm. Then, a plurality of rollers 52 which can wind the wire 53 are provided, but three rollers 52 of the sheet processing machine 50 used in this embodiment are provided. The roller 52 is formed with a guide groove (not shown) so as to wind each wire 53 strand at a constant interval. And the roller 52 is connected to the AC servo motor can rotate at a speed of 500 ~ 2000 (meter) per minute. When the wire 53 performs the cutting operation, a slurry (not shown) is supplied as an auxiliary material of the cutting process. A slurry (not shown) flowing out through the slurry supply unit 50 includes an abrasive, which uses a GC cutting abrasive. The slurry (not shown) provided in this embodiment may be in the form of solid granules, or may be in a liquid state.

Through such a configuration, the semiprecious thin plate 121 may be manufactured. First, the semi-precious gems 55 are fixed by the moving support frame 51. Then, as the motor (not shown) is driven to rotate the roller 52, the plurality of wires 53 wound thereon are rotated in one direction. At this time, a slurry (not shown) containing an abrasive is supplied onto the wire 53 from the slurry supply part 50 disposed adjacent to the reciprocating wire 53. The semi-precious stones 55 provided in the ingot shape are moved in the vertical direction, and the fine particles (not shown) in the slurry (not shown) reciprocate together with the wire 53 and the semi-precious stones ( 55) is cut off. The cutting principle is a mechanism similar to the cutting process of general machining.

Through such a process, the semi-precious thin plate 121 can be manufactured in a large amount using a plurality of wires 53 in one cutting process. The semi-precipitate thin plate 121 produced may have a thickness of about 3 mm. Since the thickness of the semi-precious thin plate 121 depends on the diameter of the wire 53 and the arrangement interval, the thickness of the semi-precious thin plate 121 can be adjusted by changing them. In addition, since the size of the semi-precious stones 55 which are gemstones are different, the plate surface area of the semi-precious stone plate 121 to be processed is also formed differently.

On the other hand, as shown in Figure 2, the adhesive resin layer 130 is formed mainly in the lower region adjacent to the semi-precious thin plate 121. As a material which comprises the adhesive resin layer 130, there exist an ultraviolet irradiation hardening resin (UV resin) and a natural reaction hardening type resin. Ultraviolet-ray irradiation hardening resin is a raw material formed in a liquid phase and hardened when an ultraviolet-ray is irradiated. Therefore, it can be rapidly cured using an ultraviolet irradiation device (not shown), and mass production of the product is possible. In contrast, natural reaction curable resins (not shown) are cured in their natural state and require approximately 24 hours or more. There is an advantage that can form a thick resin layer. Both adhesive resins are excellent in transparency and excellent in light transmittance, and because they are liquid, there is an advantage of easy application and can be selectively used as necessary.

There are two types of coating methods for forming the adhesive resin layer 130. First, as shown in FIG. 2, as shown in FIG. 2, the semi-precious thin plate 121 is disposed on the glass plate 111, and then an adhesive resin may be applied. The liquid adhesive resin flows down into the gap between the semi-precious thin plates 121 and penetrates into the space between the semi-precious thin plates 121 and the glass plate 111 to form the adhesive resin layer 130 and the semi-precious stones. The gap between the thin plates 121 is sufficiently filled with adhesive resin to fill the gap. As a result, the semi-precious thin plate layer 120 may be bonded by the adhesive resin layer 130.

On the other hand, after the glass plate 111 is provided, the adhesive resin layer 130 which is disposed in parallel with the plate surface of the semi-precious thin plate 121 may be first formed by applying the adhesive resin to the entire plate surface of the glass plate 111. . Next, the semi-precious thin plate layer 120 is formed while the semi-precious thin plate 121 is disposed on the glass plate 111.

The coating layer may be formed by using the above two adhesive resins and the adhesive resin layer 130 coating method, respectively, or mixed. This is a problem that may depend on the manufacturing conditions, manufacturing time, etc. of the finishing material 100. For example, after the ultraviolet irradiation cured resin is applied to one surface of the glass plate 111, the semi-precious thin plate 121 is placed and fixed and exposed to an ultraviolet irradiation device (not shown) to rapidly expose the adhesive resin layer 130. Form. Next, the gap between the semiprecious stones thin plate 121 is sufficiently coated with a natural reaction curable resin, and the adhesive resin layer 130 may be completed through a curing process for 24 hours.

The adhesive resin layer 130, along with the semi-precious thin plate layer 120 becomes the exposed surface of the finishing material 100, thereby affecting the quality of the product. Therefore, in order to remove the adhesive resin remaining on the exposed surface of the semi-precious thin plate 121 and to planarize the adhesive resin layer 130, a process of polishing the exposed surface of the finishing material 100 is required, which is the finishing material 100 In the production method of will be described later in detail. In addition, when the adhesive resin layer 130 is formed, the quality inspection is performed, and when the finishing treatment of the adhesive resin layer 130 is insufficient, the adhesive resin layer 130 is additionally formed by applying and curing the adhesive resin again. can do.

Thus, by forming the adhesive resin layer 130, not only serves to adhere and fix the semi-precious thin plate 121 on the glass plate 111, but also the plate thickness of the non-uniform finish 100 by placing the semi-precious thin plate 121. By uniformly increasing the quality of the finishing material 100 can also be obtained.

The additional coating layer 140 is formed on the other surface of the anti-warm reinforcing plate layer 110 opposed to the semi-precious thin plate layer 120, which is the glass plate that is the reinforcing plate 111 by the external force is applied to the finish 100. When the 111 is damaged or broken, the glass plate 111 serves to prevent the fragments from being separated. In this case, the additional coating layer 140 may be formed by applying the same adhesive resin as the adhesive resin layer 130.

The role of the additional coating layer 140, in addition to having a resistance to external impact, external force, etc. to facilitate the cutting of the finish 100 produced through the manufacturing method of this embodiment. Due to the manufacturing cost, it is manufactured in a large area, so cutting processing is required for use in general buildings and household goods. In such a cutting process, the glass is prevented from breaking, so that the cutting can proceed smoothly. In addition, by using various similar properties such as thermal strain and thermal expansion coefficient of the adhesive resin layer 130 formed on one surface of the glass plate 111 and the additional coating layer 140 on the other surface, the reinforcement plate layer 110 for preventing warpage 110 The thermal deformation of) can be minimized. That is, by applying the same adhesive resin on one surface and the other surface of the glass plate 111, it is possible to prevent the twist in the thickness direction of the glass plate 111, which occurs in the curing step of the adhesive resin or in the temperature change situation.

As described above, in the present embodiment, the semiprecious gems 55 are processed into the semiprecious gemstone thin plate 121 through a predetermined thin plate processing machine 50, and then placed on the glass plate 111 which is the reinforcing plate 110, and bonded. It is possible to manufacture a finish 100 using the semi-precious stones 55, which can have sufficient mechanical strength to improve its durability.

In addition, the finishing material 100 may have a value as a beautiful interior accessory through the semi-precious stone (55). In particular, during the day when natural light can be irradiated, it may have a unique design value due to its own characteristics (for example, color, color, etc.) of the semi-precious stones 55, and may be provided inside the finishing material 100 at night. Illumination irradiated through the lighting means (not shown) can penetrate the finishing material 100 so that the used illumination and semiprecious stones 55 can act to produce a complex color.

In addition, it can be used as a finishing material 100 of various household goods as well as interior and exterior materials of general buildings. If you use it as an exterior finishing material for table, dresser, sink, etc., you can create a more luxurious design.

A method of manufacturing the finishing material 100 having such a configuration will be described with reference to FIG. 4.

First, to provide a reinforcing plate layer 110 for preventing bending to form a basic skeleton of the finishing material 100 (S11). In this embodiment, since the glass plate 111 is selected, the glass plate 111 is cut to match the width / length of the finishing material 100 to provide a reinforcement plate layer 110 for preventing bending (S11).

Next, the semi-precious thin plate layer 120 is disposed parallel to the anti-bending reinforcing plate layer 110 on one side of the anti-bending reinforcement plate layer 110 processed by the thin plate processing machine 50. To prepare (S12).

The operation of arranging the semiprecious stone thin plate 121 on the glass plate 111 may allow one kind of semiprecious stone thin plate 121 to be disposed on one surface of the glass plate 111, or the various semiprecious stone thin plates 121. It may be arranged on one surface of the glass plate 111. It may only be selected in view of the cosmetic aspect.

When arranging the plurality of semi-precious stones thin plate 121 on the glass plate 111, it is necessary to ensure even clearance between the semi-precious stones thin plate 121 so as not to overlap each other. This is to secure a space for the adhesive resin to penetrate the gap. If the semi-precious thin plate 121 is disposed overlapping, the function of adhering the semi-precious thin plate 121 through the adhesive resin may be deteriorated, and there is a possibility of appearance problems. In addition, there may be a problem that the thickness of the finished material 100 to be manufactured is not constant. Therefore, the semi-precious thin plate 121 is to not overlap each other.

Next, the semiprecious stone thin plate 121 is applied to the adhesive resin to be bonded to the reinforcing plate 110 (S13). Description of the adhesive resin to be applied and the application method is as described above.

Next, a step of polishing the exposed surface of the semi-precious thin plate 121 to remove the adhesive resin remaining on the exposed surface of the semi-precious thin plate 121 (S14). In the step of forming the adhesive resin layer 130, the adhesive resin is not applied to avoid the semi-precious thin plate 121, but is evenly applied to the entire area of the plate surface 100. Therefore, after the adhesive resin has cured, it is necessary to remove the residue of the adhesive resin applied to the entire plate surface area. To this end, a process of polishing the plate surface of the finish 100 is performed.

Finally, in order to form the additional coating layer 140, the adhesive resin is applied to the other side of the anti-bending reinforcement plate layer 110 is provided with a semi-precious thin plate layer 120 (S15). The additional coating layer 140 may apply the adhesive resin having the same components and properties as the adhesive resin used for the adhesive resin layer 130, so that the additional coating layer 140 may function.

As such, according to this embodiment, By processing the semi-precious stones 55 through the predetermined sheet processing machine 50 into the semi-precious stone thin plate 121 and using it for the finishing material 100, the unit cost of the semi-precious stones 55 can be significantly lowered, thus the semi-precious stones 55 It is possible to increase the commercialization possibility of the finishing material 100 using.

In addition, by providing the anti-bending reinforcing plate layer 110 and by adhering the semi-precious stone thin plate 121 thereon, the semi-precious stone thin plate 121 is formed to weaken the mechanical strength of the finishing material 100 itself, the finish 100 may be damaged Allows you to overcome problems

Then, the finishing material 100 may have a value as a beautiful interior accessory through the semi-precious stones (55). In particular, during the day when natural light can be irradiated, it may have a unique design value due to its own characteristics (for example, color, color, etc.) of the semi-precious stones 55, and may be provided inside the finishing material 100 at night. Illumination irradiated through the lighting means (not shown) can penetrate the finishing material 100 so that the lighting and quasi-precious stones 55 used can produce a complex color. In addition, it can be used as a finishing material 100 of various household goods as well as interior and exterior materials of general buildings. If it is used as exterior finishing materials such as tables, dressers, and sinks among the household goods in the room, the design will be more luxurious.

Hereinafter, with reference to the accompanying drawings will be described in detail a finishing material and a manufacturing method according to another embodiment of the present invention.

5 to 7 are schematic cross-sectional views of the finishing materials 200 to 400 according to the second to fourth embodiments of the present invention, respectively. Hereinafter, only the parts different from the first embodiment will be described. However, duplicate descriptions of the same configuration should be avoided.

5 is a schematic cross-sectional view of a finishing material according to a second embodiment of the present invention.

As shown in this figure, the finishing material 200 according to the second embodiment of the present invention is also provided in four layers as in the first embodiment. That is, the finishing material 200 according to the second embodiment includes a reinforcing plate layer 210 for preventing warpage, a semi-precious thin plate layer 220, an adhesive resin layer 230, and an additional coating layer 240. .

In the present embodiment, the additional coating layer 240 is differentiated from the first embodiment. In the first embodiment, the additional coating layer 140 (refer to FIG. 2) is formed by applying the adhesive resin, but in the present embodiment, fiber glass 241 is further added to the additional coating layer 240. In this case, the fiber glass 241 included in the adhesive resin may serve as a skeleton of the additional coating layer 240, thereby basically increasing the strength of the additional coating layer 240. Through this, it may be more robust to external stimuli such as external force, impact, etc., depending on the application of the finishing material 200 used in the actual building, and the glass plate 211 is separated by preventing glass fragments from scattering in case of breakage. Possible accidents can also be relatively safer. In addition, it is possible to prevent deformation such as bending of the finishing material 200, which may occur according to different thermal expansion rates of one surface and the other surface of the glass plate 211.

As another feature, the light may be polarized due to the fiber glass 241 when light is transmitted to the finish 200. The fiber glass 241 may have a light transmittance relatively different from that of the transparent resin. As a result, the light passing through the finish 200 is affected by the structure of the fiber glass 241 disposed on the other surface, so that an effect similar to the polarization of light may be obtained.

In addition, the other surface shape of the finishing material 200 may be generated by an embossing structure, so that bending of the other surface may serve to widen the adhesive area in the process of bonding the finishing material 200. This has the advantage that the adhesion of the finish 200 can be easily.

6 is a schematic cross-sectional view of a finishing material according to a third embodiment of the present invention.

As shown in this figure, the finishing material 300 according to the third embodiment of the present invention is formed so that the semi-precious thin plates 321 and 351 are mutually symmetrical on both sides of the glass plate 311 based on the glass plate 311. . Accordingly, the semi-precious thin plate layers 320 and 350 and the adhesive resin layers 330 and 340 are formed on both sides of the glass plate 311, and the description of each of the layers 320, 330, 340 and 350 is described above. Same as one.

Through this, it can be aesthetically beautiful and has the advantage of increasing the light transmittance relatively. Light may be transmitted through the semi-precipitate thin plates 321 and 351 in duplicate so that the light may have better optical characteristics than the above-described embodiments 100 and 200. The finishing material 300 according to the present embodiment may be used for a portion requiring a semipermeable material such as a window and a partition member for partitioning a space.

7 is a schematic cross-sectional view of a finishing material according to a fourth embodiment of the present invention.

As shown in this figure, the finishing material 400 according to the fourth embodiment of the present invention, unlike the finishing materials 100, 200, and 300 described above, the bending preventing reinforcement plate layer (110, 210, 310) is not used Do not. Instead, the finishing material 400 of this embodiment is made of two layers of semi-precious thin plate layers 420 and 450 are bonded to each other. The finish 400 is provided with two layers of semi-precious thin plate layers 420 and 450, and an adhesive resin layer 430 for adhering them.

In this embodiment, a glass plate (not shown), which is a reinforcing plate (not shown), is omitted. Instead, the semi-precious thin plate 451 is first used as a method for reinforcing and supporting the semi-precious thin plate layers 420 and 450. The jewelry thin plate first layer 450 is disposed and formed. The semi-precious thin plate second layer 420 is formed using the semi-precious thin plate 421, wherein the semi-precious thin plate second layer 420 shields the spaced apart interval area of the semi-precious thin plate first layer 420. Semi-precipitate thin plate 421 is disposed to be. That is, the semi-precious thin plates 421 and 451 are staggered so that the spacing between the semi-precious thin sheets 420 and 450 does not coincide with each other along the thickness direction.

The manufacturing method will be briefly described. After the semiprecious thin plate layer 451 is disposed, the semiprecious thin plate layer 420 is completed by applying the adhesive resin and bonding to complete the semiprecious thin plate layer 450. Place and bond. As a result, it is possible to alleviate the warpage phenomenon that may occur due to the absence of the reinforcing plate (not shown).

Through this, it is possible to prevent the bending, deflection, etc. of the finishing material 400 can perform a relatively higher aesthetic function. In addition, the glass plate (not shown) may be omitted to further increase light transmittance. Therefore, the finish 400 may be used where the light transmittance needs to be given more priority than the mechanical properties of the finish 400.

As described above, the present invention is not limited to the described embodiments, and various modifications and changes can be made without departing from the spirit and scope of the present invention, which will be apparent to those skilled in the art. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

1 is a plan view of a finishing material according to a first embodiment of the present invention.

FIG. 2 is a cross-sectional view taken along the line II-II of FIG. 1.

Figure 3 is a schematic perspective view of a thin plate processing machine for processing a semi-precious stone thin plate applied to the finish of Figure 1;

4 is a flowchart of a manufacturing method for manufacturing the finish of FIG.

5 is a schematic cross-sectional view of a finishing material according to a second embodiment of the present invention.

6 is a schematic cross-sectional view of a finishing material according to a third embodiment of the present invention.

7 is a schematic cross-sectional view of a finishing material according to a fourth embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings *

       50: sheet metal processing machine 52: roller

       53: wire 55: semi-precious stone

110: bending prevention reinforcing plate layer 111: glass plate

       120: semi-precious thin sheet 121: semi-precious thin sheet

       130: adhesive resin layer 140: additional coating layer

       241: Fiber Glass

Claims (20)

Reinforcement plate layer for bending prevention; A semi-precious thin plate layer disposed on at least one surface of the reinforcing plate layer for preventing warpage because at least one of crystal, crystal, wood fossil, and natural mineral is processed into a thin plate having a predetermined thickness; And Finishing material characterized in that it comprises an adhesive resin layer is applied between the semi-precious stone thin plate layer and the anti-bending reinforcement plate layer to be bonded to the semi-precious stone thin plate layer. The method of claim 1, The semiprecious stone thin layer is a finishing material, characterized in that provided by one kind of semi-precious stone thin plate or several kinds of semi-precious stone thin plate arranged side by side with the reinforcing plate layer for preventing bending. The method of claim 2, The semiprecious stone thin plate is finished, characterized in that cut by a predetermined thin plate processing machine to a thin plate of 1 mm to 5 mm. The method of claim 1, The warpage reinforcing plate layer is a finishing material, characterized in that provided by any one selected from glass, stone, double-sided etching glass. The method of claim 1, The adhesive resin layer is a finishing material, characterized in that provided by at least one selected from ultraviolet irradiation curable resin and natural reaction curable resin. The method of claim 1, The semi-precious thin plate layer is disposed on one surface of the bending prevention reinforcement plate layer, The finishing material further comprises an additional coating layer is further applied to the other surface of the anti-bending reinforcing plate layer facing the semi-precious thin plate layer. The method of claim 6, The additional coating layer is a finishing material, characterized in that provided by at least one selected from the adhesive resin (Resin) and fiber glass (Fiber Glass). The method of claim 1, The semi-precious thin sheet layer is a finishing material, characterized in that arranged on both sides of the anti-bending reinforcement plate layer symmetrical with respect to the anti-bending reinforcement plate layer. At least one of quartz, crystal, wood fossil, and natural minerals is processed into a thin plate having a predetermined thickness, and the plurality of semi-precious thin plate layers are arranged in a plurality of layers; And Finishing material, characterized in that the adhesive resin layer is applied between the plurality of semi-precious thin plate layers to adhere the plurality of semi-precious thin plate layers to each other. The method of claim 9, Finishing material characterized in that the semi-precipitate thin plates are alternately arranged so that the play between the semi-precious thin plate forming the plurality of semi-precious thin plate layers do not coincide with each other along the thickness direction. Providing a bending prevention reinforcing plate layer; Forming a semi-precipitate thin layer by arranging a semi-precipitate thin plate processed by at least one of crystals, crystals, wood fossils, and natural minerals into a thin plate having a predetermined thickness on at least one surface of the reinforcing plate preventing layer; And And forming an adhesive resin layer between the quasi-jewelry thin plate layer and the anti-warp reinforcing plate layer such that the semi-precious thin plate layer is adhered to the anti-bending reinforcement plate layer. The method of claim 11, And polishing the exposed surface of the semi-precious thin plate layer to remove the adhesive resin remaining on the exposed surface of the semi-precious thin plate layer. The method of claim 11, The semi-precious thin plate layer is provided by one kind of semi-precious stone thin plate or several types of semi-precious stone thin plate arranged side by side with the reinforcing plate layer for preventing bending, The semiprecious stone thin plate is cut into a thin plate of 1 mm to 5 mm by a predetermined thin plate processing machine, characterized in that the finishing material manufacturing method. The method of claim 11, The bending prevention reinforcement plate layer is a finishing material manufacturing method, characterized in that provided by any one selected from glass, stone, double-sided etching glass. The method of claim 11, The adhesive resin layer is a finishing material manufacturing method characterized in that it is provided by at least one selected from ultraviolet irradiation curable resin and natural reaction curable resin. The method of claim 11, The semi-precious thin plate layer is disposed on one surface of the bending prevention reinforcement plate layer, The method of claim 1, further comprising the step of forming an additional coating layer on the other side of the anti-warm reinforcement plate layer facing the thin plate of semiprecious stones. The method of claim 16, The additional coating layer is a finishing material manufacturing method characterized in that it is provided by at least one selected from the adhesive resin (Resin) and fiber glass (Fiber Glass). The method of claim 11, The quasi-precious thin plate layer is a finishing material manufacturing method, characterized in that arranged on both sides of the anti-warp reinforcement plate layer on the basis of the anti-bending reinforcement plate layer. Forming a plurality of semi-precipitate thin layers by arranging the semi-precipitate thin sheets processed by at least one of crystals, crystals, wood fossils, and natural minerals into thin layers; And And a step of forming an adhesive resin layer between the plurality of semi-precious stones thin layers so that the plurality of semi-precious stones thin layers are bonded to each other. The method of claim 19, In the forming of the plurality of semi-precious thin plate layers, the semi-precious thin plates are alternately arranged so that the clearances between the semi-precious thin plates forming the plurality of semi-precious thin plate layers do not coincide with each other along the thickness direction. Finishing material manufacturing method.

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