KR100762943B1 - Sectional floorings with coupling member and assembling method thereof - Google Patents

Abstract

Sectional flooring is provided to prevent the formation of a gap or a step between floorings by coupling two floorings tightly using an elastic coupler and to heighten durability of floorings by assembling floorings without cracks. Sectional flooring(500) includes plural floorings(10,20,30), each having a coupling structure at a pair of longitudinal sides(2) and a pair of transverse sides(4), to be coupled with each other, and an elastic coupler(40) placed between the transverse sides of adjacent floorings and unified with the coupling structure of the transverse side. The coupler includes a base portion formed in the appointed width and thickness, a pair of side hooks formed at right angles to the base portion or bent toward cantilever hooks at the appointed angle to resist the stress applied in the longitudinal direction of the first and second floorings(10,20), and a pair of cantilever hooks fastened to the coupling structure of the first and second floorings to assemble the floorings firmly and to resist the stress applied in the thickness direction of the first and second floorings to prevent a joint of the floorings from getting loose or being stepped.

Description

Prefabricated flooring using joining tool and assembly method thereof {SECTIONAL FLOORINGS WITH COUPLING MEMBER AND ASSEMBLING METHOD THEREOF}

1 is a plan view of a prefabricated flooring according to an embodiment of the present invention.

FIG. 2 is a partial cross-sectional view of the prefabricated flooring material having a section cut along the line I-I of FIG. 1.

3 is a partial cross-sectional view of the assembled flooring material showing the disassembled state of the first flooring material, the second flooring material and the coupler shown in FIG.

Figure 4 is an enlarged cross-sectional view of the coupler in the prefabricated flooring according to an embodiment of the present invention.

FIG. 5 is a partial cross-sectional view of the assembled flooring material showing a cross section taken along the line II-II of FIG. 1.

6 is a partial cross-sectional view of the first floor and the third floor showing the assembly process in the longitudinal side of the floor.

7 is a partial cross-sectional view of the first flooring material and the second flooring material showing the assembling process in the widthwise side surface of the flooring material.

8 is a partial cross-sectional view of the first flooring material and the second flooring material showing a first modification of the coupling structure of the cross-section in the width direction.

9 is a partial cross-sectional view of the first flooring material and the second flooring material showing a second modification of the coupling structure of the cross-section in the width direction.

10 is a partial cross-sectional view of the first flooring material and the second flooring material showing a third modification of the coupling structure of the cross-section in the width direction.

11 is a partial cross-sectional view of the first flooring material and the second flooring material showing a fourth modification of the coupling structure of the cross section in the width direction.

The present invention relates to a prefabricated flooring, and more particularly, to a prefabricated flooring material and a method of assembling the flooring material and the method of assembling the two neighboring flooring to each other firmly using an elastic coupler.

In general, prefabricated flooring is completed by assembling the individual floorings manufactured to a certain standard on the building floor. Conventional individual floorings are rectangular, in particular rectangular with a pair of long sides and a pair of short sides, each side of the floor is formed with a coupling structure for assembly with other flooring.

Conventionally, a protrusion is formed on one of two neighboring floors, and a groove is formed on the other to bond the floorings using a combination structure of the projections and the grooves, and then, by applying an adhesive to the bottom of the flooring to fix the floorings on the building floor. Method was used. However, this method is difficult to dismantle the flooring, it is pointed out that the use of epoxy-based adhesives that are harmful to the human body.

Also, in the related art, the above-described adhesive is applied to the side of the flooring having the protrusions and the grooves, and a method of simultaneously using the mechanical bonding of the protrusions and the grooves and the adhesive strength of the adhesive is used. This method is usually called suspension, and the construction and removal of flooring materials has a relatively convenient advantage. However, this method also has a problem that when the adhesive is frozen or stored for a long time after use, the bonding strength between floors falls, and gaps or steps are generated between floors at areas where the adhesive is not properly applied.

Therefore, in recent years, as another configuration of the suspension method, a method of joining the flooring material by forming a locking member having a locking function on the side of the flooring material without using an adhesive has been proposed. In connection with this method, U.S. Patent No. 4,426,820 and JP-A-3-169967 disclose prefabricated flooring materials having fastening members on the side.

However, in the suspension method using fastening members, wood plywood, medium density fiber boards, and high density fiber boards, which are mainly used as core materials of flooring materials, are contracted under floor heating conditions due to the characteristics of the material. A gap may occur between them.

In addition, the aforementioned wood plywood, medium-density fiber board, high-density fiber board, etc. are less elastic than synthetic resin material, so that when the floors are fastened to each other in a snap-in method, the parts of the fastening member are concentrated. Cracking can easily occur.

Therefore, the present invention is to solve the above problems, an object of the present invention is to increase the bonding strength between the flooring material and the prefabricated flooring material that can prevent the gap or step between the flooring even when the flooring shrinks under floor heating conditions and It is to provide a method of assembly thereof.

It is another object of the present invention to provide a prefabricated flooring material and a method for assembling the flooring material, which can increase durability of the flooring material by preventing damage such as cracking at a fastening part during assembly of the flooring material.

In order to achieve the above object, the present invention,

A plurality of floorings which are assembled to each other by forming a joining structure on the longitudinal side and the widthwise side and using wood as a core material, and two floorings provided below the width side of the flooring and neighboring along the longitudinal direction of the flooring. It includes a coupler of elastic material for bonding the,

A base portion in which the coupler is positioned over two neighboring floorings, and a pair of sides protruding from both end portions of the base portion toward the upper surfaces of the floorings and fitted to the widthwise side of the floorings to support stress along the longitudinal direction of the floorings; The hook and the locking projection protruding toward the upper surfaces of the flooring materials at a predetermined distance from each other at the center of the base portion and the locking jaw and the inclined portion below the locking projection are formed to support the stress along the thickness direction of the flooring materials. Including a pair of cantilever hooks,

The locking jaw has an upper surface consisting of an inclined surface in which a lead angle θ _L is defined with respect to a vertical line along the thickness direction of the flooring material, and a return angle θ with respect to a horizontal plane parallel to the longitudinal direction of the flooring material or a horizontal line parallel to this longitudinal direction. _R ) provides a prefabricated flooring comprising a bottom consisting of a sloped surface defined.

The lead angle θ _L may be set to 5 to 45 °, and the return angle θ _R may be set to 60 ° or less.

The flooring material is projected toward the bottom of the flooring material from one side of the first concave portion accommodating the side hooks and the first concave portion facing the outer side of the flooring material at a lower side facing the coupling hole among the widthwise side surfaces, and fitted between the side hook and the cantilever hook. The cantilever hook is formed by a fastening protrusion, a second recess provided on the side of the fastening protrusion facing toward the outside of the flooring material to receive the locking jaw of the cantilever hook, and an inclined surface corresponding to the inclined portion of the cantilever hook below the second recess. It may include a protrusion for guiding the.

The prefabricated flooring may form a cavity between the floorings and the engagement surface of the coupler to accommodate thermal expansion of the floorings and the coupler. In particular, the cavity width between the floorings and the coupling in the cantilever hook on the upper surface of the base and the cantilever hook may be set to 0.05 to 0.20mm, and the cavity width between the floorings and the coupling in the outer side of the side hook is 0.05 to 0.50mm. It can be set to.

The floorings may form an upper portion of the width side that does not face the coupling hole in a vertical plane, and the vertical surfaces of two neighboring floorings may contact each other.

Any one of the flooring material in the longitudinal side, the upper locking projection protruding toward the neighboring flooring, the intermediate locking projection protruding from the lower portion of the upper projection toward the bottom surface of the flooring, and towards the interior of the flooring A fourth recess is formed on one side of the intermediate locking jaw, and the other one of the flooring materials has a fifth recess for accommodating the upper locking jaw, and the sixth recess for accommodating the intermediate locking jaw, in the longitudinal side. And a lower locking jaw protruding from the sixth recess toward the outside of the flooring material and fitted to the fourth recess.

In addition, the present invention, in order to achieve the above object,

In the prefabricated flooring having the above-described structure, when the floorings are referred to as the first flooring material, the second flooring material, and the third flooring material, respectively, the second flooring material and the coupler are assembled, and the upper locking jaw of the first flooring material is formed of the third flooring material. After inserting into the fifth recess, the longitudinal side surfaces of the first floor material and the third floor material are assembled by rotating the first floor material downward, and the first floor material is connected to the coupler by pressing the first floor material downward. Provided is a method of assembling prefabricated flooring comprising the steps of assembling the widthwise side of the first flooring material and the second flooring material.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

1 is a plan view of a prefabricated flooring according to an embodiment of the present invention.

Referring to FIG. 1, the prefabricated flooring material 500 according to the present embodiment includes a pair of longitudinal side surfaces 2 and a pair of widthwise side surfaces 4 and a longitudinal side surface 2 and a widthwise side surface ( 4) is provided between the plurality of flooring (10,20,30) and the widthwise side surface (4) of the two neighboring flooring (10,20) to form a respective coupling structure in the width direction side (4) It comprises a coupler 40 in combination with the provided coupling structure to couple the flooring (10, 20) to each other.

The floorings 10, 20, and 30 are made of wood as a core material and are rectangular boards having a predetermined thickness and area, and are made of wood plywood, high density fiberboard (HDF), or medium density fiberboard. Fiberboard; MDF) and the like. In addition, the floorings 10, 20, and 30 may form a surface layer (not shown) reinforced with an impregnated paper or a coating layer on the surface thereof.

Coupler 40 is made of a material similar to or better than the flooring (10, 20, 30) and is provided on the side surface (4) in the width direction of the flooring (10, 20). The two bottoms 10, 20 are thereby interconnected at the lateral side 4 via the coupler 40.

The coupling structure provided on the side surface in the width direction of the first flooring material 10 and the second flooring material 20 will be described with reference to FIGS. 2, 3, and 4, and the first flooring material 10 and FIG. The coupling structure provided in the longitudinal side surface of the 3rd flooring material 30 is demonstrated.

FIG. 2 is a partial cross-sectional view of the prefabricated flooring material cut along the line II of FIG. 1, and FIG. 3 is a partial cross-sectional view of the prefabricated flooring material showing the disassembled state of the first flooring material, the second flooring material, and the fitting shown in FIG. 2. 4 is an enlarged cross-sectional view of the coupling tool.

2 to 4, the coupler 40 includes a base part 41 having a predetermined width and thickness, and a first floor material 10 and a second floor material 20 at both ends of the base part 41. A pair of side hooks 42 protruding from the base portion 41 toward the top surface of the base plate, and the top surfaces of the first floor material 10 and the second floor material 20 at the center of the base portion 41. And a pair of cantilever hooks 43 protruding from the base portion 41 and positioned at a predetermined distance from each other.

The height H ₁ of the cantilever hook 43 measured based on the upper surface of the base portion 41 is greater than the height H ₂ of the side hook 42, and the pair of side hooks 42 and the pair The cantilever hook 43 is symmetrical with respect to an imaginary vertical line (shown in dashed lines) passing through the center of the coupler 40 with reference to FIG. 3.

The bottom surface of the base portion 41 is parallel to the bottom surfaces of the first floor material 10 and the second floor material 20 on the building floor on which the prefabricated floor material is installed. The coupler 40 has a total height (H _T , see FIG. 2) smaller than the thickness (T, see FIG. 2) of the first and second floors 10 and 20, so that the assembled floor is viewed from above. The sphere 40 is not visible.

The side hook 42 may be formed at right angles to the base portion 41 or bent at a predetermined angle toward the cantilever hook 43. The side hook 42 counters the stress (mainly tensile force) applied along the longitudinal direction (horizontal direction of the drawing in FIGS. 2 to 4) of the first flooring material 10 and the second flooring material 20.

The cantilever hook 43 has a locking jaw 431 at the top toward the upper surfaces of the two flooring materials 10 and 20, and is farther from the base portion 41 between the base portion 41 and the locking jaw 431. The inclined portion 432 that becomes narrower is formed. When the cantilever hook 43 is viewed in cross section, the inner surface toward the center of the coupling hole 40 is formed in a straight line, and the locking jaw 431 and the inclined portion 432 are formed on the outer surface toward the side hook 42. .

The space provided between the pair of cantilever hooks 43 provides a free space required when one cantilever hook 43 is bent toward the center of the coupler 40 when assembling the coupler 40 and the neighboring cantilever hook. Do not interfere with (43).

In particular, the locking jaw 431 of the cantilever hook 43 is formed with an inclined surface whose upper portion defines a predetermined lead angle (θ _L , see FIG. 4) with respect to a vertical line along the thickness direction of the flooring (10, 20), The lower portion thereof may be formed as a horizontal plane parallel to the longitudinal direction of the flooring 10 or 20 or an inclined surface in which a predetermined return angle (θ _R , see FIG. 4) is defined with respect to the horizontal line parallel to the longitudinal direction.

In the upper part of the locking step 431 in which the lead angle θ _L is defined, the bottom material 10 and 20 moves the locking step 431 from the top to the bottom in the process of assembling the flooring 10 and 20 and the coupling hole 40. When the pressing force is applied, the cantilever hook 43 guides the movement of the cantilever hook 43 such that the cantilever hook 43 is bent toward the center of the engaging tool 40 rather than the outward direction of the engaging tool 40 toward the side hook 42. Play a role.

The cantilever hook 43 is locked to the coupling structure provided in the first flooring material 10 and the second flooring material 20 to assemble the two flooring materials 10 and 20 firmly, and the thickness direction of the two flooring materials 10 and 20. (2 to 4 in the vertical direction of the drawing) against the stress applied along the joints of the two flooring (10, 20) so as not to lift or stepped. The maximum width (H _O) of the cantilever hook 43 may be formed smaller than the width (W) of the side hook 42.

The first bottom member 10 and the second floor member 20 are formed in the lower portion facing the coupling hole 40 in the width direction side, the first recesses 11 and 21 for accommodating the side hooks 42 and the flooring material ( 10, 20 The fastening protrusion 12 which protrudes toward the bottom of the bottom 10, 20 from one side of the first concave portion 11, 21 facing outward and is fitted between the side hook 42 and the cantilever hook 43. 22 and second recesses 13 and 23 provided on the side of the fastening protrusions 12 and 22 facing the bottoms 10 and 20 and receiving the locking jaws 431 of the cantilever hook 43. .

At this time, the protrusions 14 and 24 corresponding to the inclined portion 432 of the cantilever hook 43 are formed on the side surfaces of the fastening protrusions 12 and 22 where the second recesses 13 and 23 are formed. That is, the protrusions 14 and 24 form one surface toward the coupler 40 as an inclined surface corresponding to the inclined portion 432. The inclined surfaces of the projections 14 and 24 cantilever the hooks 431 of the above-described cantilever hooks 43 and the cantilever hooks 43 when the bottom members 10 and 20 and the coupling holes 40 are assembled. It serves to guide the movement of the cantilever hook 43 to be bent toward the center.

In addition, the first flooring material 10 and the second flooring material 20 are provided at the upper part not facing the coupling hole 40 in the width direction side, and the stop protrusion 15 on any one flooring material (for example, the first flooring material 10). ) And a third concave portion 25 for receiving the stop projections 15 in the other flooring material (eg, the second flooring material 20) to form the first flooring material 10 and the second flooring material 20. When assembling, stopper function.

The stopper function is when the bottom surface 10, 20 is constructed is uneven or when the floor material (10, 20) is installed on a soft material such as styrofoam, the assembly of the floor material (10, 20) and the coupler (40) It helps to make things go well.

FIG. 5 is a partial cross-sectional view of the assembled flooring material showing a cross section taken along the line II-II of FIG. 1.

Referring to FIG. 4, the first flooring material 10 includes an upper locking jaw 16 protruding toward the third flooring material 30 from a longitudinal side thereof, and a first flooring material 10 below the upper locking jaw 16. The intermediate locking projection 17 protruding toward the bottom surface of the first bottom member 10 and the fourth recessed portion 18 provided on one side of the intermediate locking projection 17 toward the inside.

In addition, the third flooring material 30 includes a fifth recess 31 for accommodating the upper locking jaw 16 of the first flooring material 10 from the side in the longitudinal direction, and an intermediate locking projection 17 of the first flooring material 10. The 6th recessed part 32 which accommodates the recess, and the lower part which protrudes from the 6th recessed part 32 toward the outer side of the 3rd flooring material 30, and fits into the 4th recessed part 18 of the 1st flooring material 10. FIG. The jaw 33 is formed.

Next, the assembly process of the above-described prefabricated flooring materials will be described with reference to FIGS. 6 and 7.

6 is a partial cross-sectional view of the first flooring material and the third flooring material showing the assembly process in the longitudinal side, Figure 7 is a partial cross-sectional view of the first flooring material and the second flooring material showing the assembly process in the widthwise side.

First, referring to FIG. 6, the upper locking jaw 16 of the first flooring material 10 is inserted at an angle toward the fifth recess 31 of the third flooring material 30 at a lengthwise side thereof, and then the first flooring material ( 10) rotate downward. Then, the upper locking jaw 16 and the intermediate locking jaw 17 of the first flooring material 10 are fitted into the fifth recessed part 31 and the sixth recessed part 32 of the third flooring material 30, respectively. The flooring 10 and the third flooring 30 are assembled to each other.

Here, when the first floor 10 is rotated in the downward direction, the first floor 10 is placed on the coupler 40 engaged with the second floor 20 in the width direction side and then a force is applied to the first floor ( 10) is pressed down in a snap-in manner and assembled with the second flooring 20.

Referring to FIG. 7, as the first flooring material 10 moves downward, the first flooring material including the upper part of the locking jaw 431 and the inclined surface of the cantilever hook 43 formed of the inclined surface in which the lead angle θ _L is defined. 10 of the cantilever hook 43 of the coupler 40 is easily bent toward the center of the coupler 40 while the protrusions 14 of the 10 contact with each other and slide. Subsequently, as the cantilever hook 43 is restored according to the movement of the first flooring material 10, the locking jaw 431 of the cantilever hook 43 enters and locks into the second recess 13 of the first flooring material 10. .

After fastening, the side hooks 42 of the coupling holes 40 are fitted into the first recesses 11 of the first flooring material 10, and the fastening protrusions 12 of the first flooring material 10 are the side hooks 42. It is sandwiched between the cantilever hook 43 and the first bottom member 10 and the coupling sphere 40 is firmly assembled. In this case, the width P of the fastening protrusion 12 is preferably about 3.0 mm or more so that the fastening protrusion 12 is not damaged by the stress generated when the flooring contracts.

In addition, the lead angle θ _L of the cantilever hook 43 locking jaw 431 is preferably 5 to 45 °. When the lead angle θ _L is less than 5 ° or more than 45 °, the guide effect due to sliding with the protrusion 14 of the first flooring material 10 is insufficient, and thus it is difficult to smoothly guide the movement of the cantilever hook 43. . In addition, the return angle θ _R may not be easily disassembled when the first bottom member 10 and the coupling member 40 are easily disassembled in consideration of the coefficient of friction of the contact surface between the fastening protrusion 12 and the coupling member 40 of the first floor member 10. It may be set to a range below 60 °.

In addition, the inclined portion 432 of the lower locking jaw 431 in the cantilever hook 43 allows the cantilever hook 43 to bend elastically when combined with the flooring material, wherein the cantilever toward the base portion 41 is provided. If the lower width of the hook 43 is H _O and the lower width of the locking jaw 431 is H _L , when the ratio of H _O and H _L satisfies the condition of approximately 2: 1, the cantilever hook 43 The warping can be made easier.

Thus, the prefabricated flooring material 500 according to the present embodiment is assembled by the insertion rotation method in the longitudinal side surface 2, and using the coupling hole 40 in the widthwise side surface 4 as well as the flooring material 10 from top to bottom. By adopting a method of assembling by pressing, less interference from neighboring coupling sites can be facilitated construction.

In the above-described structure, the coupler 40 may be formed of a material having a modulus of elasticity of 1 to 4 GPa, and preferably have a modulus similar to that of the high density fiber board and the medium density fiber board. When the coupler 40 has an elastic modulus of 1 GPa or less, the flooring material does not resist the stress to shrink when floor heating is easily bent, and thus the coupling force of the fastening portion is weakened.

The coupler 40 may be manufactured by an extrusion method or an injection method, and an injection method capable of manufacturing an error range of 0.05 mm or less may be effectively applied.

8 is a partial cross-sectional view of the first flooring material and the second flooring material showing a first modification of the coupling structure of the cross-section in the width direction.

Referring to FIG. 8, in the present modification, the flooring materials 10A and 20A are provided between the fastening surfaces of the first flooring member 10A and the coupling tool 40 and between the fastening surfaces of the second flooring member 20A and the coupling tool 40. And a cavity 50 for accommodating thermal expansion of the coupler 40 is formed.

The cavity 50 is a flooring material that may occur due to the thermal expansion of the coupling member 40 and the resilience due to the interference of the cantilever hook 43 in the state in which the flooring (10A, 20A) and the coupling hole 40 is assembled (10A, 20A) acts as a buffer to reduce the occurrence of gaps on the surface, reducing the frictional force between the flooring (10A, 20A) and the coupler 40 to assemble or disassemble the flooring (10A, 20A) and the coupler (40) When working, it increases work efficiency.

In consideration of the material of the coupler 40 and the flooring material 10A, 20A, and the heating conditions of the building floor, the flooring material 10A, 20A of the upper part of the base part 41 and the cantilever hook 43 of the coupler 40 are considered. The width (a) of the cavity 50 between the coupler 40 and the coupler 40 is preferably 0.05 to 0.20 mm, and the cavity 50 between the bottom member 10A, 20A and the coupler 40 at the outer side of the side hook 42. ) The width b is preferably 0.05 to 0.50 mm.

9 is a partial cross-sectional view of the first flooring material and the second flooring material showing a second modification of the coupling structure of the cross-section in the width direction.

Referring to FIG. 9, in the present modified example, the first flooring material 10B and the second flooring material 20B form an upper surface of the widthwise side surface not facing the coupling hole 40 in a vertical plane so that the first flooring material without a stopper function ( The upper portion of the side of 10B and the upper portion of the side of the second flooring material 20B are in contact with each other. Except for this structure, the rest of the structure has the same bonding structure as in the above-described embodiment.

10 is a partial cross-sectional view of the first flooring material and the second flooring material showing a third modification of the coupling structure of the cross-section in the width direction.

Referring to FIG. 10, in the present modified example, the first flooring material 10C and the second flooring material 20C have protrusions 19 and grooves 26 formed on the upper side of the widthwise side not facing the coupling hole 40. To form a locking structure. That is, the first floor 10C forms the projection 19 toward the second floor 20C, and the second floor 20C forms the groove 26 accommodating the projection 18. Therefore, when the first flooring material 10C moves downward and is fitted to the coupling hole 40, the projections 19 are fastened to the grooves 26 so that the thickness directions of the flooring materials 10C and 20C (see FIG. 10 in the drawing). Effectively limit the movement in the vertical direction).

11 is a partial cross-sectional view of the first flooring material and the second flooring material showing a fourth modification of the coupling structure of the cross section in the width direction.

Referring to FIG. 11, in the present modification, the bottom of the fastening protrusion 12 of the first flooring material 10D and the bottom of the fastening protrusion 22 of the second flooring material 20D toward the base portion 41 of the coupler 40 is provided. A glue pocket 51 is formed.

Therefore, when the adhesive is applied to the upper surface of the base portion 41 of the coupler 40, and the first bottom member 10D and the second bottom member 20D are bonded together, the adhesive is trapped in the glue pocket 51 and the bottom member is stuck by the adhesive. Do not lift (10D, 20D) or step. In the present modified example using the adhesive and the glue pocket 51, mechanical bonding force and adhesive force by the adhesive can be secured at the same time.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to the range of.

Thus, the prefabricated flooring material according to the present invention combines the side surfaces in the width direction of the flooring material by using the coupling tool having the above-described structure and material properties, thereby increasing the bonding strength between flooring materials even when the flooring shrinks during floor heating. It is possible to suppress the occurrence of gaps and steps in between. In addition, the prefabricated flooring according to the present invention can increase durability of the flooring because damage such as cracking does not occur at the fastening site during the assembly process.

Claims (17)

A plurality of flooring materials (10,20,30) which form a joining structure on the longitudinal side surface (2) and the widthwise side surface (4), are assembled with each other, and use wood material as a core material; It is provided on the bottom side in the width direction side 4 of the flooring material includes a coupler 40 made of an elastic material for joining two adjacent flooring (10, 20) along the longitudinal direction of the flooring, The coupling sphere 40, A base portion 41 positioned over the two adjacent flooring materials; A pair of side hooks protruding toward upper surfaces of the flooring materials 10 and 20 at both end portions of the base part 41 and fitted to the widthwise side surfaces 4 of the flooring material to support stress in the longitudinal direction of the flooring material ( 42); And A locking jaw 431 and a locking protrusion protruding toward the upper surfaces of the flooring materials 10 and 20 at a predetermined distance from each other at the center of the base part 41, and locked to the widthwise side surfaces 4 of the flooring materials. It comprises a pair of cantilever hooks 43 to form the inclined portion 432 of the lower jaw 431 to support the stress in the thickness direction of the flooring material, The locking jaw 431 is an upper surface consisting of an inclined surface defined by the lead angle θ _L with respect to a vertical line in the thickness direction of the flooring materials 10 and 20, a horizontal plane parallel to the length direction of the flooring material, or the longitudinal direction thereof. And a bottom consisting of an inclined plane with a return angle θ _R defined for a horizontal line parallel to First concave portions formed at positions where the bottoms 10 and 20 respectively receive the pair of side hooks 42 at a lower portion of the widthwise side surface 4 facing the coupler 40. Prefabricated flooring comprising 11,21). The method of claim 1, The prefabricated flooring material having the lead angle θ _L of 5 to 45 ° and the return angle θ _R of 60 ° or less. The method of claim 1, The locking jaw 431 and the inclined portion 432 are provided on an outer surface of the cantilever hook 43 facing the side hook 42, and the inclined portion 432 is far from the base portion 41. Prefabricated flooring with a narrower width. The method of claim 3, A prefabricated flooring material having a ratio of a bottom width H _O of the cantilever hook 43 facing the base portion 41 and a bottom width H _L of the locking jaw 431 satisfying a condition of about 2: 1. The method of claim 1, The fastening protrusion 12 which protrudes toward the bottom of the flooring material from one side of the first recesses 11 and 21 facing the flooring materials 10 and 20 and is fitted between the side hook 42 and the cantilever hook 43. 22); Second recesses 13 and 23 provided on side surfaces of the fastening protrusions 12 and 22 toward the outside of the flooring material 10 and 20 to accommodate the locking jaw 431 of the cantilever hook 43; And Further comprising protrusions 14 and 24 formed in an inclined surface corresponding to the inclined portion 432 of the cantilever hook 43 below the second concave portion 13 and 23 to guide the movement of the cantilever hook 43. Prefabricated flooring. The method of claim 5, Prefabricated flooring material having a fastening protrusion (12, 22) has a width of 3.0mm or more along the longitudinal direction of the flooring material (10,20). The method of claim 5, Prefabricated flooring material forming a cavity 50 for accommodating thermal expansion of the floorings 10 and 20 and the coupling tool 40 between the floorings 10 and 20 and the coupling surface of the coupling tool 40. . The method of claim 7, wherein The width (a) of the cavity 50 between the bottoms 10 and 20 and the coupler 40 at the upper surface of the base portion 41 and the cantilever hook 43 of the coupler 40 is 0.05 to 0.20 mm. Prefabricated flooring material having a width (b) of 0.05 to 0.50 mm between the floorings (10, 20) and the coupling hole (40) on the outer surface of the side hook (42). The method of claim 5, Prefabricated flooring material in which the flooring material (10, 20) is formed in the vertical surface of the upper surface of the side surface (4) that does not face the coupler (40), the vertical surface of the two neighboring flooring material is in contact with each other. The method of claim 5, At the top of the flooring (10, 20) does not face the coupling hole 40 of the width side surface (4), Prefabricated flooring having a stopper function by forming a stop projection (15) in one of the two neighboring flooring, and forming a third recess (25) for receiving the stop projection (15) in the other flooring. The method of claim 5, At the top of the flooring (10, 20) does not face the coupling hole 40 of the width side surface (4), Prefabricated flooring having a locking function by forming a projection (19) in one of the two neighboring flooring, and forming a groove (26) for receiving the projection (19) in the other flooring. The method of claim 5, Prefabricated flooring to form a glue pocket (51) at the bottom of the fastening projections (12, 22) toward the base portion (41) of the coupler 40 is the bottom (10, 20). The method of claim 5, One of the floorings 10 is in the longitudinal side (2), An upper locking jaw 16 protruding toward the adjacent flooring material, an intermediate locking jaw 17 protruding from the lower portion of the upper locking jaw 16 toward the bottom of the flooring material, and an intermediate locking jaw facing the inside of the flooring material ( To form a fourth recessed portion 18 provided on one side of 17), On the other side of the flooring material 30 in the longitudinal side, The fifth recess 31 accommodating the upper locking jaw 16, the sixth recess 32 accommodating the intermediate locking jaw 17, and the outside of the flooring material from the sixth recess 32. Prefabricated flooring protruding toward the bottom to form a lower locking step (33) fitted in the fourth recess (18). The method of claim 1, The flooring material (10, 20, 30) is a prefabricated flooring formed of any one of wood plywood, high density fiber board and medium density fiber board. The method of claim 1, Prefabricated flooring material is formed with an elastic material having a modulus of elasticity of 1 to 4 GPa. In the assembling method of the prefabricated floor covering according to claim 13, When the flooring (10, 20, 30) is referred to as the first flooring material 10, the second flooring material 20 and the third flooring material 30, respectively, Assembling the second flooring material (20) and the coupler (40); The first flooring material by rotating the first flooring material 10 downwardly after inserting the upper locking jaw 16 of the first flooring material 10 into the fifth recess 31 of the third flooring material 30. Assembling the longitudinal side surfaces 2 of the 10 and the third flooring 30; By pressing the first flooring material 10 downward, the first flooring material 10 is assembled to the coupler 40 to form a widthwise side surface of the first flooring material 10 and the second flooring material 20. 4) assembling the prefabricated flooring comprising the steps of assembling. The method of claim 16, When assembling the first flooring material 10 and the coupler 40, While the protrusion 14 of the first flooring material 10 and the upper portion of the locking jaw 431 of the cantilever hook 43 abut against each other, the protrusion 14 may move the cantilever hook 43 to the coupling hole 40. ) Method of assembling the prefabricated flooring material to bend toward the center.

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