KR102044655B1 - Multi-layer glued structural cross laminated timber panel for floor member and manufacturing method thereof - Google Patents

Abstract

The present invention relates to a method for manufacturing an integrated plate for a multi-junction structure for the floor, which comprises the steps of: lumbering four surfaces of smallwood to have a predetermined cross-sectional dimension, drying the same to have a predetermined water content, and finishing the same with planning to prevent contraction or distortion during drying to manufacture a plurality of square materials having a predetermined length; manufacturing a core plate by bonding sides of the manufactured square materials; manufacturing a lower structure laminated plate by separately bonding a veneer laminated in an odd number which is three or more to alternately cross a fiber direction of several veneer plates with a surface layer on upper and lower portions of the core plate (110) in a double layer; having a plurality of reinforcing materials separated from each other on an upper portion of the veneer forming the surface layer of the lower structure laminated plate in a width direction to be coupled to the veneer (120); and coupling an upper laminated plate to an upper portion of the reinforcing materials.

Description

Multi-layer glued structural cross laminated timber panel for floor member and manufacturing method

The present invention relates to a multi-joint structural aggregate plate for floors and a method for manufacturing the same, and more particularly, to a multi-junction structural aggregate plate and a method of manufacturing the same that can be used for floor structures in a wooden house.

, 2010년 9,585동 연면적781,000

급기야 현재 10,000동이 넘는 목조주택이 들어서, 목조주택 1만 세대이다. 그리고 근래에 들어 설계도가 다양해지고 많은 건축주들의 개성 있는 집을 지으려는 수요가 생기면서 수평부재인 대들보, 장선 등의 길이인 지간거리가 상당히 길어지는 경향이 있다. 기존의 구조용 목재로서는 그 지간거리를 버텨낼 수 있는 구조적 강도가 갖춰지지 않으면서 공학목재인 집성재의 사용이 많아지고 있는 현실이다.Recently, the timber industry market is continuously expanding due to the increase in the use of timber products and the interest in wooden houses due to the improvement of housing and return to homes, the aging culture of low birth rates. According to the recent trend of wood construction, the number of new buildings in 2006 was 4,203 dong, totaling 365,000.

9,585 dong in 2010, total floor area 781,000

At present, more than 10,000 wooden houses are built, with 10,000 wooden houses. In recent years, as the design is diversified and the demand of many owners to build a unique house tends to be considerably longer. Existing structural timber is a reality that the use of aggregate materials, which are engineering wood, is not equipped with structural strength that can withstand the distance.

As shown in FIG. 1, the aggregate 10 is formed by gluing a lumber end plate or an incineration material having a thickness of about 34 mm in parallel with fibers between adjacent laminas 1 in an adhesive direction using an adhesive in a length, width, or thickness direction. Material. Aggregate was developed in earnest after the development of risinol resin, and operating materials began to spread in the 1960s and structural materials in the 1990s. According to the conditions of use, the aggregates are divided into indoor and outdoor use, and there are straight aggregates, curved aggregates, type I cross-section aggregates, upper cross-sections and hollow cross-sections depending on the shape. According to the load direction, it is divided into horizontal laminated aggregate and vertical laminated aggregate, and in Japanese standard JAS, it is divided into operation, structural, and makeup structure according to the use. The grade of adhesive and the appearance of the operating aggregate are the criteria for classifying the grade, and the structural grade is used as a strength member of the building and is used in important places of the structure, so the performance standard is strict.

Structural cross-section aggregates and the characteristics of the building are structurally laminated with lamina, resulting in a material with less variation in strength. As a result, the lower limit of the intensity distribution rises, so that the allowable stress is about 1.5 times the maximum of the lumber. In addition, the raw material of the lamina has a characteristic of less warping and splitting due to the use of a drying material, and a carbonized layer is formed on the combustion part while the surface is ignited and burned, so that the fire resistance is superior to that of ordinary wood.

On the other hand, there is an alternating aggregate (20, Cross Laminated Timber) as shown in Fig. 2 as a planar engineered wood formed by laminating the lamina (1) orthogonally stacked among the aggregate. Alternating aggregate 20 is an engineered timber with the advantage of being able to construct high-rise wooden building materials. It is a vertically laminated aggregate that has been developed and used in the 2000s in Europe, North America, and Japan. In the United Kingdom and North America, high-level timber constructions are being built using these materials, and the production and scale of the international materials are 475,000m3 as of 2011. Central Europe accounts for about 95% of the total, with production expanding in the UK, Germany and Austria.

However, such a conventional alternating aggregate 20 may cause problems such as twisting and splitting of lamina due to different degrees of shrinkage occurring in each layer when exposed to changes in external conditions such as temperature and humidity. The twisting of the lamina desorbs the adhesive surface between the lamina, and the dry stress caused by the lamina surface and the internal water inclination may cause cracking and splitting on the surface of the alternating aggregate, which may cause deformation by moisture. This can lead to strength degradation which is very unfavorable for use as structural materials.

Therefore, an object of the present invention is to solve the conventional problems and to develop a multi-joint structural aggregate plate for floors that can be used as a floor member in a wooden house.

Method for manufacturing a multi-junction structural aggregate plate for floors according to a preferred embodiment of the present invention to have a small cross-section of the four-necked wood to have a predetermined cross-sectional dimension, and then dried to a predetermined moisture content, in order to remove shrinkage or distortion during drying Manufacturing a plurality of right angle materials (111) having a predetermined length by finishing the planer, and manufacturing the judgment (110) by side-joining the prepared right angle materials (111), and a plurality of veneer end plates in a fiber direction Bonding the plywood (120,130) laminated with three or more odd sheets so as to intersect the upper and lower portions of the umpire 110 in a surface layer and a two layer, respectively, to fabricate the substructure aggregate plate 100; Comparting a plurality of reinforcing materials 410 in the width direction on the top of the plywood 120 to form a surface layer of 100 to couple to the plywood 120, and the top of the plurality of reinforcing materials (410) 420 combined Key is characterized in that it comprises the steps:

In addition, in the manufacturing of the lower structural aggregate plate 100, the right angle member 111 disposed on one side of the referee 110 is bonded to protrude from the front and back layers, disposed on the other side of the opposite referee 110. The right angle member 111 to be joined is characterized in that the bonding to enter more concave than the front and back layer.

In addition, in the step of coupling the reinforcing material 410 to the plywood 120 is made by inserting the coupling member 211 in the lower direction from the top of the reinforcing material 410 to be coupled to the plywood 120, the coupling The lower portion of the member 211 is characterized in that the coupling so as to be arranged inside the corner member 111 of the judgment (110).

In addition, the bottom structure in the multi-junction structural laminate for the floor adjacent to the flooring 111 part protruding from the front and back layer in the judgment 110 of the substructure assembly plate 100 in one floor multi-junction structural laminate. Coupled to the corner member 111 that enters more than the front and back layer in the judgment plate 110 of the aggregation plate 100 is characterized in that the two floors for the multi-junction structural composite plate for parallel bonding.

In addition, the substructure assembly plate 100 is disposed on the plywood 130 to form a two-layer of the substructure assembly plate 100, and coated with an adhesive on the upper surface of the plywood 130 to form the two-layer, then plywood In order to form the referee 110 on the upper side of the 130, after applying an adhesive to the left and right sides of the plurality of right angle member 111, the right angle member 111 is disposed vertically, the angle angle member forming the judgment 110 After applying the adhesive on the upper surface of 111 is characterized in that the plywood 120 to form the surface layer of the lower structural aggregate plate 100 is laminated.

In addition, the lower structural assembly plate 100 is made by a manufacturing apparatus consisting of a lower frame 200 and the upper frame 300 each formed of a steel structure, extending to a predetermined length and arranged side by side A plurality of H-shaped steels 230 are arranged to be parallel to each other and arranged between the hardware members 210 and 220 at a predetermined interval, and a support bracket 235 having a vertical surface is installed on the right side of each H-shaped steel 230. The left side of the H-shaped steel 230 is provided with a support bracket 231 is a screw hole is formed, the support bracket 231 is fastened to the screw hole of the support bracket 231 screw bolt 232 is screwed and tightening bolt On the right end of the 232 is placed a plywood 130 to form a two-layer of the lower structural aggregate plate 100 on a plurality of H-shaped steel 230 of the lower frame 200, the pressure pad 233 is formed, The adhesive is applied to the upper surface of the plywood 130, and then to the upper side of the plywood 130 The adhesive is applied to the left and right sides of the plurality of right angle members 111 forming the judgment 110, and then the right angle members 111 are vertically arranged, but the side surfaces of the right angle members 111 are disposed on the right side of the judgment 110. Is disposed to contact the support bracket 235 of the H-shaped steel 230, and after the adhesive is applied to the upper surface of the right angle member 111 forming the judgment 110 to form the surface layer of the lower structural aggregate plate 100 The upper portion formed by stacking the plywood 120 and a plurality of H-shaped steels 330 are arranged to be parallel to each other at regular intervals between the left and right hardware members 310 and 320 that extend in a predetermined length and are arranged side by side. The frame 300 is disposed on the plywood 120 to form the surface layer, and then the tightening bolts 232 of the H-shaped steels 230 are tightened to a predetermined torque by using a torque wrench to press the pressure pad 233 to the judgment 110. Pressing the right angle member disposed on the left side of the) to the left and right joint at the same time the upper frame 300 and the lower rope Using the captive bolt being the (200) at a predetermined pressure is characterized in that the vertical joint.

In addition, after reaching the predetermined thickness and width by applying left and right pressures to the lower structural assembly plate 100, the nail 110 is added to the upper and lower surfaces of the lower structural assembly plate 100 to add the judgment 110, the table, and the second layer. It is characterized in that for the nailing and dismantling the lower frame 200 and the upper frame 300 to manufacture the lower structural aggregate plate 100.

According to the present invention, there is provided a multi-joint structural aggregate plate for a floor, which can be used as a floor member in a wooden house, and a manufacturing method thereof.

1 is a view of the existing aggregate material, Figure 2 is a view of the existing alternating aggregate material,
Figure 3 is a front view of a multi-joint structural aggregate plate for floors according to the present invention,
Figure 4 is a front view of the lower structural aggregate plate in the present invention,
5 to 7 is a view showing a manufacturing process of a multi-joint structural aggregate plate for floors according to the present invention,
Figure 8 is a view showing the surface of the base plate aggregate in the present invention,
9 is a view showing the back surface of the lower structural aggregate plate in the present invention,
10 is a diagram showing the results of performing a short-term planar bending test of the multi-junction structural laminate for floor according to the present invention.

Hereinafter will be described in detail through the manufacturing method for a multi-junction structural aggregate plate for floors according to the present invention.

Figure 3 is a front view of a multi-junction structural composite board for floors according to the present invention, Figure 4 is a front view of the lower structural aggregate plate in the present invention, Figures 5 to 7 of the multi-junction structural laminate for floors according to the present invention Figure 8 is a view showing the manufacturing process, Figure 8 is a view showing the surface of the substructure assembly plate in the present invention, Figure 9 is a view showing the back surface of the substructure assembly plate in the present invention, Figure 10 is a present invention This is a chart showing the results of the short-term planar bending test of multi-junction structural laminates for floors.

The multi-junction structural composite board for floor according to the present invention has a predetermined cross-sectional dimension by four-sided small-necked wood and then dried up to a predetermined moisture content, and has a certain length by finishing the planer to remove shrinkage or distortion during drying Manufacturing a plurality of corner members 111, side joining the prepared corner members 111 to manufacture the judgment 110, and a plurality of veneer end plates in three or more odd sheets so that the fiber direction crosses Bonding the laminated plywood (120,130) to the top and bottom of the judgment 110 in a surface layer and a two-layer, respectively, to produce a substructure laminated plate 100, and to form a surface layer of the substructured laminated plate 100 Coupling a plurality of reinforcing members 410 on the upper part of the plywood 120 in the width direction to couple the plywood 120 to the upper part of the plurality of reinforcing materials 410. Done including The. Hereinafter, each step will be described in more detail.

Figure 3 shows a multi-joint structural laminate for floor according to the present invention, in the present invention first to fabricate a substructure laminated plate 100 to form a substructure of the multi-joint structural laminate for floor.

Substructure structural plate 100 in the present invention shown in Figure 4 prepares a small timber that is thinning first to prepare the judgment 110. As a thinning timber, a small diameter tree is generally a tree having a diameter of 18 cm or less, and in the present invention, a thinning diameter tree having a diameter of about 120 mm to 140 mm is used. Small tree used in the present invention can be used in all species regardless of species.

Then, after preparing the thinning small-sized timber on both sides around the depth of water to rotate 90 degrees to prepare the remaining two sides to produce a plurality of corners 111 having a cross-sectional dimension of 90mm x 90mm or more. In this case, when the wood is rotated by 90 degrees one by one in order, the small hardwood material has a large amount of immature ghost wood and various growth stresses are present in the interior, which is likely to cause torsion during the sawing process. Especially in the case of larch, the fiber inclination is large and has a spiral tree, so the torsion is more likely to occur. In addition, in the case of thinning timber, once the sanction on one side and the other side to be sanctioned, the productivity is very low.

Therefore, in order to minimize the occurrence of the torsion during the sanction process and increase the productivity, the two sides facing each other at the same time. In addition, the depth of the small diameter wood is produced with a high density, excellent dimensional stability and excellent strength than the edge, mainly around the water depth.

The prepared corner member 111 is dried at a target moisture content of 15% using a separate drying facility. In the present invention, the cross-sectional dimension of the regular angle member 111 is 80mm or more, which is thicker than the thickness of the commonly used dry wood (50mm), so that it is determined that a drying process different from that of general wood is required. The drying process is applied so that it can dry quickly with the least energy.

The drying process applied to the drying of the shell of the present invention is step 1: steaming for 12 hours at 96 ℃ (steaming); Step 2: high temperature drying for 36 hours at 120 ° C. and 90 ° C. wet bulb temperature; Step 3: medium temperature drying for 24 hours at a dry bulb temperature of 100 ° C. and a wet bulb temperature of 70 ° C .; Step 4: low temperature drying for 24 hours at a dry bulb temperature of 80 ° C. and a wet bulb temperature of 60 ° C .; Step 5: It takes 3 days to cure at room temperature.

Therefore, as described above, after the steaming material is steamed for 12 hours at the initial 96 ° C for 12 hours at a predetermined dry / wet bulb temperature, it is dried for a predetermined time through a high temperature, a medium temperature, and a low temperature drying process such as surface splitting and warping. Drying defects are minimized, and the dryness can be dried as quickly as possible with low energy. Through this drying process, the cornerstone 111 is dried to a target moisture content of 15%.

Then, a slight shrinkage or warping may occur when the drying process is performed. To remove this, the dried right angle member 111 is finished with a planer, and the right angle member 111 having a length of 4.8 m and a cross sectional dimension of 90 mm x 90 mm or more is removed. To produce.

In the present invention, the juncture 110 is manufactured by side joining the right angle member 111 manufactured as described above, and in this embodiment, the juncture 110 is formed by side joining two junctures 110 having a width of 0.6 m and a length of 4.8 m. In the plate 100, the size of the judgment 110 was 1.2m in width and 4.8m in length. However, the present invention is not limited thereto and may be manufactured with one referee 110 having a width of 1.2 m.

Then, the plywood 120 and 130 are bonded to the surface layer and the second layer of the manufactured judgment 110, respectively. The species of plywood used as a step of manufacturing the plywood (120, 130) used as the front and back layer is made of domestic materials such as larch, rigi pine, locust, lily, birch, chestnut, pine, cypress, cedar, etc. Radiatapine, Eucalyptus, Meranti, MLH (mixed local hardwood), Poplar, Vietnamese acacia, Radiatapine, Namyangjae mixed species including KERUING, etc.The adhesives used are phenol, melamine, urea and isocyanate. Thermosetting resin and thermoplastic resins such as PVAc, PVA, EVA, PUR, epoxy resin, and hot melt and rubber adhesives.

The plywood manufacturing process consists of the processing of lumber and the increase of the timber, the transversal of the wood, the peeling, the cutting of the single board, the drying, the typesetting, the defect repair of the single board, the application of adhesive, cold pressing, hot pressure, and post-treatment.

When cutting the end plate, the thickness of the end plate should be 0.5mm or more and 5mm or less. After drying the single plate, the single plate moisture content is dried to 5-10% level, and in the case of coniferous plywood, it is dried to 3-8% water content. The moisture content range of single plate suitable for adhesion should be adjusted according to the type of adhesive used. When using urea and melamine resin adhesives, the water content should be maintained at 5 ~ 15% and phenol resin adhesives at water content below 8%.

Then, in the typesetting process, there may be a number of defects such as splitting, knots, thickening or the like that are smaller than predetermined dimensions in the dried single plate. Small defects scattered here and there are rounded off with a patching machine, then buried in other healthy single plates of the same size and shape, and tapered and repaired. The narrow end plates are made of transverse joints into the desired end plates. Lateral joining is a method in which the sides of the end plates are smoothly cut by a veneer jointer to be in close contact with each other and then taped thereon, or directly bonded by applying an adhesive to the sides of the end plates to be joined. After finishing the repair and transverse joining, the single plate shall be combined with the top plate, the judge, and the second plate in consideration of the construction of the single plate according to the specifications of the product.

The number of laminates should be at least 3 ply for plywood (120, 130), the thickness of the plates should be at least 0.5mm and less than 5mm, and the total thickness of the plywood is 2.4mm, 2.7mm, 3.6mm, 4.8mm, 5.2mm, 6mm Including international standard of plywood, 7mm, 7.5mm, 9mm, 11.5mm, 12mm, 15mm, 18mm, 22mm, 24mm, 30mm, 40mm, 50mm.

The juncture 110 is manufactured by side-joining the prepared angler 111 as described above, and the plywood 120 and 130 are bonded to the front and back layers of the umpire 110, and the front and back layers are formed as shown in FIG. 4. One side of the referee 110 to protrude about 40mm more than the plywood (120, 130). Therefore, one side of the judgment 110 protrudes more than the front and back layers, and the other side of the judgment 110 enters further.

8 and 9 illustrate the front and rear surfaces of the substructure assembly plate 100, respectively. In the present embodiment, two plywoods 120 having a width of 1.2 m and a length of 2.4 m in the surface layer are followed in the longitudinal direction. And attached to (110), in the case of a two-layer was prepared by attaching one plywood 130 of width 1.2m, length 2.4m in the center and then attaching plywood 130 of length 1.2m of the same width on both sides, respectively. .

As such, by combining one plywood 130 to a two-layer portion corresponding to a portion to which two plywoods 120 forming the surface layer are joined, resistance to tensile stress acting in the center is improved.

In addition, a separate manufacturing facility was developed and manufactured in order to manufacture the substructure assembly plate 100 of the present invention, and it was applied to manufacture the substructure assembly plate 100 of the present invention.

In the present invention, the manufacturing equipment is made of a lower frame 200 and the upper frame 300, each made of a steel structure. In detail, the lower frame 200 is formed by extending a predetermined length and forming a plurality of H-shaped steels 230 arranged in parallel at regular intervals between the left and right hardware members 210 and 220 arranged side by side. . At the right side of each H-beam 230, a support bracket 235 having a vertical surface formed vertically to support the right side of the judgment 110 is installed, and a support bracket at which a screw hole is formed at the left side of the H-beam 230. 231 is installed, the support bracket 231 is screwed to the screw hole of the support bracket 231 is fastening bolt 232 for screwing the umpire 110 of the lower structural assembly plate 100 from the side screw The pressure pad 233 is formed at the right end of the tightening bolt 232.

The plywood 130 having a thickness of 18 mm is disposed on the H-shaped steel 230 of the lower frame 200 in order to form the back layer of the lower structural assembly plate 100 of the present invention.

Then, an adhesive is applied to the upper surface of the plywood 130. In this invention, the viscosity 24,000-26,000 cps / 25 degreeC, the main component: vinyl acetate resin and the adhesive agent of pH = 4-5 were used.

The adhesive is applied to the upper surface of the plywood 130, and then the adhesive is applied to the left and right sides of the plurality of right angle members 111 forming the judgment 110 on the upper side of the plywood 130, and then the right angle member 111 is vertically The side of the right angle member 111 disposed on the right side of the judgment 110 is disposed so as to contact the support bracket 235 of the H-beam (230). And, the right angle member 111 disposed on the right side of the judgment 110 is disposed so as to protrude about 40mm more than the plywood of the back layer. Then, the right angle member 111 disposed on the left side of the judgment 110 enters about 40 mm more than the plywood 130 of the back layer.

The size of the judgment 110 is approximately equal to the size of the back layer of the plywood to place the right angles to be 1.2m in width, 4.8m in length, and the angle with a width of 90mm or less can be used to match the plywood size.

As such, when the arrangement of the right angle member 111 is completed, an adhesive is applied to an upper surface of the right angle member 111 forming the judgment 110, and then a plywood having a thickness of 18 mm to form a surface layer of the lower structural assembly plate 100 ( 120) are stacked. The plywood 120 of the surface layer is disposed so that the right side of the plywood 120 is about 40mm more than the right angle member 111 disposed on the right side of the judgment 110, and thus, the left side of the plywood 120 is arranged on the left side of the judgment 110. It is about 40mm more protruding than the right angle member 111.

When the lamination is completed in this way, the upper frame 300 is disposed on the upper side of the plywood 120 to form a surface layer. The upper frame 300 is formed by extending a predetermined length and a plurality of H-shaped steels 330 arranged in parallel at regular intervals between the left and right hardware members 310 and 320 which are arranged side by side are welded and It has the same size as the frame 200.

When the arrangement of the upper frame 300 is completed, the step of tightening the tightening bolts 232 of each H-shaped steel 230 to a predetermined torque in the lower frame 200 using a torque wrench and at the same time the upper frame 300 and Using the plurality of tightening bolts along the longitudinal direction of the right angle member 111, the lower frame 200 likewise applies an up and down pressure with a constant torque (pressure) with a torque wrench.

In this way, the left and right and up and down pressure is applied for 2 hours, and then the upper and lower frames 200 and 300 of the manufacturing equipment are dismantled to manufacture the lower structural assembly plate 100.

On the other hand, unlike the above embodiment, after reaching the predetermined desired thickness and width by applying the left and right and up and down pressure as another embodiment, as shown in Figs. ) And a table, two layers can be further nailed in this case, the upper and lower frames can be directly dismantled and cured without the time of compaction to manufacture the substructure aggregate plate 100 of the present invention.

 After manufacturing the lower structural aggregate plate 100, a plurality of reinforcing members 410 in the width direction of the plywood 120 to form the top layer of the lower structural aggregate plate 100, that is, the lower structural aggregate plate 100 Join spaced apart (see Figure 3).

 Each of the reinforcing members 410 is made of a square material of 2 × 4 (38mm × 89mm), 2 × 6 (38mm × 140mm), etc., and the length of the reinforcing material 410 is the same as that of the substructure assembly plate 100. It is coupled along the longitudinal direction (longitudinal direction of the right angle member) of the substructure assembly plate 100, and is spaced apart at intervals of approximately 250mm in the width direction.

The reinforcing material 410 is fixed to the lower structural assembly plate 100 by the coupling member 411, first, punctures the hole at 300 mm intervals along the longitudinal direction of the reinforcing material 410 and 180 mm long as the coupling member 411 Secure with rag screws.

Coupling member 411 is inserted into the lower direction from the top of the reinforcing member 410 through a punched hole to be coupled to the plywood 120 to form the surface layer of the lower structural aggregate plate 100, the coupling member 411 The lower portion is coupled to be disposed inside the right angle member 111 of the judgment (110).

As described above, the reinforcing material 410 is coupled to the upper portion of the lower structural aggregate plate 100, and the upper plywood 420 having a thickness of 18 mm is coupled to the upper part of the plurality of reinforcing materials 410. The upper plywood 420 is fixed to the reinforcement 410 by nails spaced apart at regular intervals. The space below the upper plywood 420 between the reinforcement 410 may be a heat insulator for heat insulation.

In the present invention, a multi-junction structural composite plate for floors is manufactured as described above, and two additional multi-junction structural composite plates for floors are additionally manufactured to be manufactured as a floor member.

At this time, the right angle member 111 of the judgment 110 protruding from the front and back layers from the lower structural assembly plate 100 of one floor of the multi-junction structural laminate for one floor, the lower structural assembly plate of the multi-junction structural laminate for another floor In parallel with the right angle member 111 of the judgment 110 enters concave than the front and back layer at (100). The joint surface may be in parallel with the adhesive or the adhesive. In the present invention, the concave right angle member of the judgment 110 that combines the right angle member 111 of the protruding judgment 110 by forming one side of the judgment 110 more prominent than the front and back layers in the lower structural aggregate plate. It can be fitted into the (111) part and can be connected in parallel without the need for separate T & G (groove and tongue) processing and can be used as a floor member in a wooden house after the parallel connection.

The short-term planar bending test was performed by applying the KS F 2150 to the multi-junction structural aggregate plate for floor according to the present invention as described above in a 1/3 point load method.

The short-term planar flexural test was performed on the lower structural aggregate plate 100 in the present invention as a specimen, the multi-junction structural laminate for floor using 2 × 4 stiffener, and the multi-junction structural laminate for floor using 2 × 6 stiffener in the present invention. The test was carried out and the test results are shown in Table 1 and FIG.

Psalter
Kinds Proportional limit MOE
(GPa) Load (kN) MOR ^{1 )}
(MPa) weight
(kN) sag
(mm) 18.75mm
Deflection limit load 50 mm
Deflection load 100 mm
Deflection load F-CLT 2.49 13.49 8.79 3.25 7.72 15.55 4.28 4TR-F-CLT 3.15 8.74 3.10 5.85 13.15 22.96 7.71 6TR-F-CLT 4.02 8.17 2.59 7.85 17.73 29.54 10.36 ¹⁾ MOR was calculated from the load at the deflection limit of L / 240 (18.75mm).

In each symbol, F-CLT refers to the part of the substructure assembly plate 100 separately, and 4TR-F-CLT refers to the multi-junction structural assembly plate for floors to which 2 × 4 stiffener is applied, and 6TR- F-CLT refers to the flooring laminate for multi-junction structures using 2 × 6 stiffeners.

As shown in Table 1 and FIG. 10, MOR (Modulus Of Rupture) showing bending strength was found to increase in the order of F-CLT <4TR-F-CLT <6TR-F-CLT.

Therefore, when using the multi-junction structural laminate for floor according to the present invention as described above as a floor member it can be expected to use as a stable floor member in a wooden house having improved flexural strength.

As mentioned above, although this invention was demonstrated with reference to the preferred embodiment, this invention is not limited to the specific embodiment mentioned above, Comprising: It is common in the technical field to which this invention pertains without deviating from the summary of this invention claimed in the Claim. Anyone with knowledge will be able to implement a variety of variations.

100: substructure aggregate plate 111: square shell
120, 130: plywood 200: lower frame
210: left side hardware member 220: right side hardware member
230: H section steel 231: support bracket
232: tightening bolt 300: upper frame
410: reinforcement 420: upper plywood

Claims (8)

Making a small diameter wood to four sides to have a certain cross-sectional dimension, and then dried to a predetermined moisture content, and manufacturing a plurality of regular angle material (111) having a predetermined length by finishing the planer to remove the shrinkage or distortion during drying and ,
Manufacturing the umpire 110 by side-joining the prepared angler 111;
Steps for manufacturing the substructure laminated plate 100 by joining the plywood (120,130) laminated in three or more odd sheets so that the fiber direction intersects the veneer end plate in the upper and lower parts of the judgment 110, respectively. Wow,
Coupling a plurality of reinforcing members 410 in the width direction to the plywood 120 at an upper portion of the plywood 120 forming a surface layer of the lower structural aggregate plate 100;
Comprising the step of coupling the upper plywood 420 on top of the plurality of reinforcement 410,
The substructure assembly plate 100 is disposed on the plywood 130 to form a two-layer of the substructure assembly plate 100,
After applying the adhesive on the upper surface of the plywood 130 forming the two-layer, and then applying the adhesive on the left and right sides of the plurality of right angle member 111 to form the judgment 110 on the upper side of the plywood 130 The ashes 111 are arranged vertically,
After applying the adhesive on the upper surface of the angle member 111 forming the judgment 110 is made by laminating the plywood 120 to form the surface layer of the substructure assembly plate 100,
The lower structural assembly plate 100 is made of a manufacturing apparatus consisting of a lower frame 200 and the upper frame 300 each formed of a steel frame structure,
A plurality of H-shaped steels 230 which are formed to extend in a predetermined length and are arranged parallel to each other between the left and right hardware members 210 and 220 which are arranged side by side are joined to each other, and each of the H-shaped steels 230 A support bracket 235 having a vertical surface is installed on the right side, and a support bracket 231 is formed on the left side of the H-shaped steel 230, and a screw hole of the support bracket 231 is provided on the support bracket 231. The fastening bolt 232 is screwed to the right end of the fastening bolt 232 two layers of the lower structural aggregate plate 100 on the plurality of H-shaped steel 230 of the lower frame 200 is formed with a pressure pad 233 Place the plywood 130 to form a,
After applying the adhesive on the upper surface of the plywood 130, and then applying the adhesive on the left and right sides of the plurality of right angle member 111 forming the judgment 110 on the upper side of the plywood 130 and then the right angle member 111 Arranged vertically, the side of the right angle member 111 is disposed on the right side of the judgment 110 is placed in contact with the support bracket 235 of the H-shaped steel 230,
After applying an adhesive to the upper surface of the right angle member 111 forming the judgment 110, and laminated the plywood 120 to form the surface layer of the substructure assembly plate 100,
A surface layer is formed on the upper frame 300 formed by joining a plurality of H-shaped steels 330 which are formed to extend in a predetermined length and are arranged in parallel at a predetermined interval between the left and right hardware members 310 and 320 arranged side by side. Placed on the plywood 120,
Tightening the tightening bolts 232 of the H-shaped steel 230, the pressure pad 233 presses the right angle member disposed on the left side of the judgment 110 to the left and right joint at the same time the upper frame 300 and the lower frame ( Method for manufacturing a multi-junction structural aggregate plate for floors characterized in that the 200 is joined up and down using a fastening bolt. The method of claim 1,
In the manufacturing of the substructure assembly plate 100, the right angle member 111 disposed on one side of the referee 110 is joined to protrude from the front and back layers, and the right angle disposed on the other side of the opposite referee 110. Ash (111) is a method of manufacturing a flooring laminate for multi-junction structures for flooring, characterized in that the bonding so as to enter concave than the front and back layers. The method of claim 1,
In the step of coupling the reinforcing material 410 to the plywood 120 is inserted into the coupling member 411 in the lower direction from the top of the reinforcing material 410 is made by coupling to the plywood 120, the coupling member ( The lower part of the 411 is coupled to be disposed so as to be arranged inside the right angle member (111) of the judgment (110). The method of claim 2,
In one floor of the multi-junction structural aggregate plate, the substructure laminated plate in the multi-junction structural laminate for adjacent floors the part of the angled corner 111 which protrudes from the front and back layer at the judgment 110 of the substructure laminated plate 100 in the floor. Method of manufacturing a multi-joint structural laminate for flooring, characterized in that the two joints for the multi-joint structural laminate for flooring is coupled in parallel to the part of the angled material (111) more than the front and back layer in the judgment 110 of (100). delete delete The method of claim 1,
After reaching the predetermined thickness and width by applying the left and right pressures up and down to the substructure assembly plate 100, nails 121 and 131 are nailed to the upper and lower surfaces of the substructure assembly plate 100 so that the judgment 110, the table, and the second layer are formed. The method of manufacturing a multi-junction structural laminate for flooring, characterized in that for further nailing and dismantling the lower frame 200 and the upper frame 300 to produce a lower structural aggregate plate (100). Claims 1 to 4, the floor multi-joint structural aggregate plate manufactured by the manufacturing method according to any one of claims.

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