KR20120008764A - Plate product using natural stone for floor and wall finishing - Google Patents

Abstract

PURPOSE: A finishing board is provided to improve the durability of a background plate and to prevent the deformation of a background plate. CONSTITUTION: A finishing board comprises a natural rock surface plate, a reinforcement plate, and a background plate(100). The natural rock surface plate is formed into the constant size and thickness. The reinforcement plate is formed to be corresponded to the natural rock surface plate and is attached to the natural rock surface plate. The background plate is a lot formed than the natural rock surface plate and is attached to the reinforcement plate.

Description

Plate for Finishing {PLATE PRODUCT USING NATURAL STONE FOR FLOOR AND WALL FINISHING}

The present invention relates to a plate for finishing, and more particularly, to a plate for finishing to enable the use of natural stone plate, such as marble or granite, or ceramic plate of ceramic or magnetic system for finishing on the floor and wall.

Today, natural stone materials such as marble and granite are used in a variety of construction materials. In particular, natural stone is often used as a finishing material for finishing the visible part, that is, the exterior wall, inner wall and floor of the building, in order to decorate the building luxuriously because of the advantage of being a natural material that can provide non-uniform natural beauty. .

Such natural stone is generally constructed in the form of a plate, which is weak in compressive strength, impact strength, and tensile strength, and in the case of a plate, in particular, it is very weak to impact due to brittleness in the material, which is a risk of damage in construction or in use. In consideration of the risk of breakage, but may vary depending on the type, it is generally used in a thickness of at least 10mm to 30mm.

However, although the thickness of about 10 mm to 30 mm can be said to be thin, the density of the natural stone is very high, and thus has a considerable weight. Such a considerable weight may put a structural burden on the building, and therefore, when a finish using natural stone is scheduled, it is necessary to consider the load separately from the design stage and to increase the cost of foundation work.

In addition, the handling for construction or transportation must be careful, and as construction is difficult, requiring careful attention to orderly alignment of the vertical and horizontal in the construction process, the construction cost burden is also considerable.

Due to such a cost burden, natural stone material is not generally used in the construction of a general house, and is mainly applied to high-end constructions with a construction cost.

On the other hand, the present applicant has developed a finishing plate as disclosed in Patent Publication No. 10-2009-0121166 in view of this point.

Such a conventional finishing plate will be described with reference to FIGS. 1 and 2.

As shown in FIG. 1, the finishing plate is cut to a natural stone surface plate 10 of a predetermined thickness cut to a predetermined length and width, and cut to a length and width corresponding to the natural stone surface plate. Reinforcement plate 20 is attached to the lower surface of the), and the base plate 30 is cut to have a length and width larger by a predetermined dimension than the natural stone surface plate 10 is attached to the lower surface of the reinforcing plate 20.

The natural stone surface plate 10, the reinforcing plate 20 and the base plate 30 is integrated in a manner of bonding using a contact portion to the contact portion. Specifically, a hot melt adhesive, particularly a moisture-curable urethane hot melt adhesive, is applied by using a hot melt applicator to about 100 to 150 g, or about 100 to 150 g by using a cold pressure adhesive including vinyl acetate and an isocyanate curing agent. Then, by using a roll press machine or a hydraulic cold press, the pressure is about 3 to 5 kg / cm 2 for 30 to 60 minutes, and the process is left at room temperature for 48 hours to completely cure the adhesive. Will go through.

The natural stone surface plate 10 is made of a natural stone plate, such as marble or granite, is processed to have a thickness of about 3 to 5 mm, length and width may be determined in various dimensions. In addition, the corner of the upper surface is preferably chamfered in order to prevent the occurrence of breakage during handling for transportation or construction.

The reinforcement plate 20 is provided to reinforce the impact strength, the compressive strength, and the tensile strength of the natural stone surface plate 10. An aluminum composite having two aluminum plates attached up and down with a plastic plate such as PE interposed therebetween. It is composed of any one plate selected from a single plate, such as a plate or a glass fiber plate, fiber reinforced cement board (CRC board), magnesium board, urethane foam plate, but in Figure 1 illustrates a single plate. In particular, in the case of an aluminum composite sheet, it is preferable that the plastic sheet and the aluminum sheet are also integrated through a method of adhering to the contact portion using an adhesive. On the other hand, by having such a reinforcing plate 20, the impact strength, compressive strength and tensile strength of the natural stone surface plate 10 is significantly improved, and the floor and wall finishing plate using the finished natural stone is sufficient durability Will have

In addition, the base plate 30 may be formed of a sheet of wood, such as plywood, a high density fiber board, a cut sheet and a synthetic wood, or an injection molded thermoplastic ABS resin or a compression molded thermosetting melamine resin material. The base plate 30 has side receiving portions 31 and end receiving portions 33 having independent shapes on one side of the longitudinal direction and one end of the width direction, respectively, and side protrusions 32 correspondingly coupled to the opposite sides. ) And the end protrusion 34 are formed to protrude. Particularly, the side accommodating part 31 and the end accommodating part 33 are formed as grooves having a shape surrounded by an upper wall, a side wall, and a lower wall, but the upper wall and the lower wall are upper wall removal sections 37 having a predetermined unit dimension from which the upper wall and the lower wall are removed, respectively. ) And the lower wall removal section 38 is formed in a continuous shape alternately. In addition, the base plate 30, except for a predetermined portion of the edge honeysuckle consisting of a plurality of rectangular cross-sectional groove (not shown) or hexagonal cross-sectional groove 35 (hereinafter referred to collectively as "hexagonal cross-sectional groove") that is open to the upper surface side. The comb structure is formed. This is to ensure that the finishing plate of the structure in which the heterogeneous materials are integrated in a flat balance to make the construction work more convenient.

And, the hexagonal cross-sectional groove 35 is formed with a vent hole 36 penetrating the center portion, the vent hole 36 can be arranged in accordance with a predetermined arrangement rule, all hexagonal cross-sectional groove 35 Although each may be provided one at a time, it is preferable that the number is provided in an appropriate number to have an arrangement with a certain interval. Such a vent 36 is to promote the complete curing of the moisture-curable urethane hot melt adhesive used for bonding between the base plate 30 and the reinforcing plate 20, the water vapor in the air through the vent 36 It can be provided to the moisture-curable urethane hot melt adhesive between the base plate 30 and the reinforcing plate 20 to improve the adhesion through the complete curing of the moisture-curable urethane hot melt adhesive.

However, the conventional base plate 30 can integrate heterogeneous materials by a honeycomb structure composed of hexagonal cross-sectional grooves 35 whose top surface is opened, but the honeycomb structure is formed only on the top surface. Since the upper and lower surfaces of the 30 form an asymmetrical structure, the upper surface of the base plate 30 is weaker than the lower surface of the structure 30, so that both ends of the manufactured base plate 30 are cured upward and deformed.

In addition, when the conventional base plate 30 is formed of thermoplastic ABS resin, the base plate 30 of the thermoplastic material is the heat of the pipe for the indoor heating directly acts on the base plate due to the installation characteristics of the finishing plate material There was a problem that the base plate 30 can be easily softened and deformed. In addition, when the conventional base plate 30 is formed of a thermosetting melamine resin, the resin constituting the melamine resin has a large burden on the cost and can not be reused, which may cause environmental problems.

Therefore, the present invention has been made to solve the problems of the prior art as described above, the base plate to enable the use of natural stone plate or ceramic plate such as marble or granite for finishing on the floor and walls in a vertically symmetrical structure By forming the weight of the base plate and the finishing plate light weight, the stable balance by the vertically symmetrical structure prevents deformation of the base plate, and provides a finishing plate that can improve the strength and bonding strength of the base plate. There is a purpose.

In addition, another object of the present invention, by molding the base plate with a thermosetting BMC or SMC material containing glass fibers, the cost of the resin constituting the BMC or SMC is not higher than the conventional melamine resin, additives such as glass fibers This can lower the overall cost, stabilize the properties of the material against heat, and provide an environmentally friendly finishing plate.

The above object is a finishing plate material comprising a natural stone surface plate formed in a predetermined size and thickness, a reinforcing plate formed to correspond to the natural stone surface plate and fixed to the natural stone surface plate, and a base plate attached and fixed to the reinforcement plate In the above, the base plate is achieved by the finishing plate, characterized in that the honeycomb structure is formed in a vertically symmetrical structure in which the cross-sectional grooves open to the upper surface side and the cross-sectional grooves opened to the lower surface side alternately and continuously formed.

In addition, the above object is a finishing plate comprising a ceramic plate formed of a predetermined size and thickness, and a base plate attached to and fixed to the ceramic plate, wherein the base plate is opened to the lower surface side and the cross-sectional groove opening to the upper surface side A honeycomb structure in which cross-sectional grooves are formed repeatedly alternately is also achieved by a finishing plate material characterized by being formed in a vertically symmetrical structure.

In addition, each of the ventilation holes are formed in the cross-sectional grooves of the base plate, and through the upper surface of the cross-sectional grooves open to the lower surface side of the base plate, holes of small diameters are drilled, and the cross-sectional grooves open to the upper surface side of the base plate. The lower surface is preferably a perforated aperture of large diameter, the base plate is preferably formed of a BMC or SMC material containing glass fibers of the thermosetting resin.

According to the finishing plate of the present invention, the base plate has a vertically symmetrical structure by repeatedly forming a cross-sectional groove open to the upper surface side and a cross-sectional groove opened to the lower surface side on the upper and lower surfaces of the base plate, respectively, so that the base plate has a vertically symmetrical structure The strength of the plate is improved, the weight is not only light, but also the structure of the upper and lower parts of the base plate to achieve a stable balance to prevent deformation of the base plate, thereby improving the bonding strength of the base plate.

In addition, according to the present invention, since the base plate is molded from a thermosetting material such as BMC or SMC containing glass fibers, the cost burden is less than that of the conventional melamine resin, and the deformation of the base plate during frequent contact with heat is minimized. It can be effective.

1 is a cross-sectional view in a width direction of a conventional plate for finishing.
Figure 2 is a bottom view showing a base plate of the conventional plate finishing.
Figure 3 is a plan perspective view showing a base plate of the plate for finishing according to the present invention.
Figure 4 is a bottom perspective view showing a base plate of the plate for finishing according to the present invention.
Figure 5 is a cross-sectional view in the width direction showing the base plate according to the present invention.
6 is a cross-sectional view showing an example in which a ceramic plate is installed on the base plate according to the present invention.

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

First, prior to explaining the present invention, the same reference numerals are given to the same parts as in the prior art, and redundant descriptions are omitted.

3 to 5 is a view showing a base plate of the plate for finishing according to the invention.

Finishing plate material of the present invention, the natural stone surface plate 10 is formed in a predetermined size and thickness, the reinforcement plate 20 is formed to correspond to the natural stone surface plate 10 is attached to the natural stone surface plate 10 and fixed It is formed larger than the natural stone surface plate 10 includes a base plate 100 which is fixed to the reinforcement plate 20, and the side receiving part 31 and the end receiving portion on the outer surface of one side of the base plate 100 adjacent to each other A part 33 is formed, and the side protrusion part 32 and the end protrusion part 34 are formed on the outer side of the other side of the base plate 100 corresponding thereto and are coupled to each other.

Here, the side accommodating part 31 and the end accommodating part 33 are formed to have the same length as the upper wall and the lower wall unlike the prior art, but the side accommodating part 31 and the end accommodating part 33 are limited thereto. Make sure it's not.

In particular, the base plate 100 is a rectangular cross-sectional groove 110 (hereinafter referred to as "upper square cross-sectional groove") that is open to the upper surface side on the upper and lower surfaces, respectively, as shown in Figures 3 and 4, A honeycomb structure in which a rectangular cross-sectional groove 120 (hereinafter referred to as "a rectangular cross-sectional groove") opened in a lower surface side in an alternating and repeated manner as shown in FIG. 5 is formed in a vertically symmetrical structure.

That is, the lower surface of the lower surface around the one rectangular cross-sectional groove 110 opened to the upper surface side of the base plate 100 in the form of the lower surface rectangular cross-sectional groove 120 opened toward the lower surface surrounds the upper surface of the rectangular cross-sectional groove 110. Is formed. On the contrary, the upper surface of the lower surface of the rectangular cross-sectional groove 120 is formed in the shape of surrounding the lower surface of the rectangular cross-sectional groove 120, the upper surface of the rectangular cross-sectional groove 110 opened toward the upper surface.

Accordingly, the upper and lower portions of the base plate 100 are formed by a vertical symmetrical structure formed by alternately and repeatedly forming the rectangular cross-sectional grooves 110 and 120 forming the honeycomb structure on the upper and lower surfaces of the base plate 100, respectively. Since the structural balance is stabilized, not only deformation such as bending is prevented, but also the strength of the base plate 100 can be improved and the weight can be reduced.

In addition, the upper and lower rectangular cross-sectional grooves 110 and 120 constituting the honeycomb structure minimize the contact area between the base plate 100 and the reinforcement plate 20 having different thermal expansion coefficients. It is possible to minimize the deformation of the base plate 100 according to the difference.

Meanwhile, in the present exemplary embodiment, the cross-sectional grooves 110 and 120 formed on the upper and lower surfaces of the base plate 100 have been described as an example of a rectangular shape, but may be formed in a hexagonal shape or any other shape.

In addition, each of the upper and lower rectangular cross-sectional grooves 110 and 120 of the base plate 100 are formed with vent holes 130 and 140 penetrating through the center thereof, respectively, the vent holes 130 ( 140 may be arranged according to a predetermined arrangement rule, but may be provided in an appropriate number to have an arrangement form having a certain interval, more preferably the vent holes 130 and 140 are all rectangular cross-sectional groove 110 It is more advantageous in terms of weight saving of the base plate 100 to be provided in each one).

On the other hand, the inner surface of the lower surface rectangular cross-sectional groove 120 having a surface bonded to the reinforcing plate 20 is perforated through a hole 140 of a small diameter, the upper surface of the rectangular cross section (not bonded to the reinforcing plate 20) A large diameter vent hole 130 is drilled on the inner lower surface of the 110.

Here, the small-diameter aperture hole 140 perforated in the rectangular cross-sectional surface groove 120 of the adhesive while minimizing the flow down of the moisture-curable urethane hot melt adhesive used for bonding between the base plate 30 and the reinforcement plate 20 In order to promote the complete curing, through the vent 140 to allow water vapor in the air to be provided to the moisture-curable urethane hot melt adhesive between the base plate 30 and the reinforcing plate 20 to complete the moisture-curable urethane hot melt adhesive It enables to improve adhesion through curing. In addition, the large-diameter aperture hole 130 drilled in the upper rectangular cross-sectional groove 110 has the maximum weight of the base plate 100 within a structural design range that does not affect deformation or deterioration of strength of the base plate 100. The large-diameter aeration hole 130 is to be reduced, so that more water vapor in the air can be provided as a moisture-curable urethane hot melt adhesive between the base plate 100 and the reinforcing plate 20.

Meanwhile, the base plate 100 formed as described above is formed by compression molding a thermosetting material, that is, a fiber reinforced thermosetting compound such as BMC or SMC, thereby providing predetermined rigidity to the base plate 100.

The thermosetting resin used to manufacture the base plate 100 may be molded by a conventional hot press, and the moisture-curable urethane hot melt adhesive between the base plate 100 and the reinforcing plate 20 may be vented. Water vapor in the air through the 130 and 140 may be supplied to generate a urethane reaction, and may be selected by pressing at room temperature with a common cold press.

At this time, the moisture-curable urethane hot melt adhesive penetrates between the base plate 100 and the reinforcing plate 20 to show a very strong adhesive force, and the heat is generated, so the press does not need to apply a separate heat cold press at room temperature (Cold Press) Even pressurization can be achieved completely.

Construction of the plate for finishing with a base plate of the present invention as described above is as follows.

First, a unit finish plate material formed by attaching and fixing the reinforcing plate 20 as an adhesive for moisture curing on the base plate 100 of the present invention, and attaching and fixing the natural plate surface plate 10 on the reinforcing plate 20. Prepare several.

Thereafter, the prepared plurality of finishing plates are continuously constructed based on the horizontal coupling structure between the side accommodating portion 31 and the side protrusion 32 of the base plate 100 provided in each finishing plate. That is, the finishing plate using the natural stone surface plate 10 having the side receiving portion 31 and the side protrusion 32 in which the upper wall removing section 37 and the lower wall removing section 38 are formed is pre-installed on the floor or wall. The side projections 32 of the finishing plate to be post-installed in the side accommodating portion 31 of the finishing plate is continuously constructed in such a way as to be pushed horizontally. Construction of a single sheet of finishing plate by pushing the end projections 34 of the finishing plate to be post-installed into the end receiving portion 33 of the pre-finished finishing plate adjacent to the longitudinal direction following the widthwise coupling as described above. This is the finish. At this time, the method of applying the adhesive on the bottom surface and the wall surface may be used a dry construction method or a wet construction method.

6 is a cross-sectional view illustrating an example in which a ceramic plate is installed on a base plate according to the present invention. Before describing the present embodiment, the same reference numerals are given to the same parts as the above-described embodiment, and overlapping descriptions are omitted. .

Since the base plate according to the present embodiment is the same as the base plate of the above-described embodiment, as shown in FIG. 6, repeated description thereof will be omitted, and only the different ceramic plate materials will be described intensively.

The ceramic plate 40 is formed by compressing a raw material such as quartz, pottery, feldspar, etc. to a raw material of clay to a certain thickness (3-5 mm) and density, and then sintering the substrate at a temperature of 1,200 to 1,300 ° C. and then 1,050 to 1,100. After aging at 占 폚, glaze or the like is used to form a surface-treated pottery and a plate (tile) of ceramic material sintered by firing at a high temperature of 1,300 to 1,500 占 폚.

The ceramic plate 40 formed as described above is subjected to precision cutting and chamfering processing to a predetermined size, and then coated with a moisture-curable urethane hot melt adhesive on the base plate 100, followed by cold pressing the processed ceramic plate 40 as described above. Use to attach.

On the other hand, the finish plate is formed by attaching the ceramic plate 40 as described above to the base plate 100 of the natural stone surface plate 10 and reinforcement plate 20 on the base plate 100 as in the above-described embodiment Since the two-layer structure can be replaced by the one-layer structure of the ceramic plate 40 having a thickness of 3 to 5 mm, it is possible to supply a more efficient and economical product which simplifies the process and reduces the cost. In particular, since the multi-step process such as the adhesion process of the reinforcement plate 20 and the natural stone slicing process and the additional modification of the base plate 100, such as the polishing of the thickness of the reinforcement plate 20, is omitted, as in the above-described embodiment. Is simplified.

In addition, the ceramic plate 40 as described above, as in the conventional natural stone surface plate is not only difficult construction method, but also serious problems of contamination due to the matage (joint), etc., when the floor or wall construction adhesive surface is hard and smooth Although there was a disadvantage that the ceramic plate 40 is dropped even after a small impact on the wash construction, the construction is easy to install by attaching and fixing the ceramic plate 40 on the base plate 100 of the present invention, to increase the adhesive strength after construction And, it has the advantage that the plate of ceramic material can be enlarged in a small size.

In addition, it is possible to reduce the structural burden due to the construction cost and light weight by improved construction properties during floor construction.

Although the present invention has been described in detail only with respect to specific embodiments as described above, it is apparent to those skilled in the art that modifications and changes can be made within the scope of the technical idea of the present invention, and such modifications or changes are patents of the present invention. Will belong to the claims.

10: natural stone surface plate 20: reinforcement plate
30: the base plate 31: side receiving part
32: side protrusion 33: end receiving portion
34: end protrusion 35: section groove
36: vent 37: upper wall removal section
38: lower wall removal section 40: ceramic plate
100: base plate 110,120: section groove
130,140: Aerator

Claims (4)

In the finishing plate comprising a natural stone surface plate formed of a predetermined size and thickness, a reinforcement plate formed to correspond to the natural stone surface plate and fixed to the natural stone surface plate, and a base plate attached to the reinforcement plate,
The base plate is a closing plate, characterized in that the honeycomb structure is formed in a vertically symmetrical structure in which the cross-sectional grooves opened to the upper surface side and the cross-sectional grooves opened to the lower surface side alternately and continuously formed.
In the finishing plate comprising a ceramic plate formed in a predetermined size and thickness, and a base plate attached to the ceramic plate fixed,
The base plate is a closing plate, characterized in that the honeycomb structure is formed in a vertically symmetrical structure in which the cross-sectional grooves opened to the upper surface side and the cross-sectional grooves opened to the lower surface side alternately and continuously formed.
The method according to claim 1 or 2,
Each vent hole is formed in the cross-sectional groove of the base plate, and a small diameter vent hole is drilled in the top surface of the cross-sectional groove opened toward the bottom surface of the base plate, and the bottom of the cross-sectional groove opened toward the top surface of the base plate. Finishing plate, characterized in that the perforated hole of large diameter.
The method according to claim 1 or 2,
The base plate is a finishing plate, characterized in that formed of BMC or SMC material containing glass fibers of the thermosetting material.

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