KR101306968B1 - Extrusion molding partition wall structure by assembling support-block and constructing method using the same - Google Patents

Abstract

The present invention relates to inter-generational wall structure and construction method using the same, and more specifically, it is possible to block the noise transmitted from the connection by allowing the support block is assembled between the extruded wall panel, the wall panel is supported Since it is firmly fixed by the block, it does not cause any shaking or deformation of the wall after construction, so it can improve durability, and it can be completed by assembling the whole structure. It is about.

Description

Extrusion molding partition wall structure by assembling support-block and constructing method using the same}

The present invention relates to inter-generational wall structure and construction method using the same, and more specifically, it is possible to block the noise transmitted from the connection by allowing the support block is assembled between the extruded wall panel, the wall panel is supported Since it is firmly fixed by the block, it does not cause any shaking or deformation of the wall after construction, so it can improve durability, and it can be completed by assembling the whole structure. It is about.

Inter-generational partition walls (structures) of buildings are presented in various ways. In general, lightweight partitions can be used in the case of a single panel. However, inter-generational partition walls must have a certain strength of the walls. In addition, it is necessary to secure sound insulation performance and secure various physical performances such as the construction of electric facilities such as electrical outlets and resistance to external pressure including nail construction for decoration.

Such intergenerational partition inner wall (structure) is often applied to the drywall panel using a gypsum board shown in FIG. Drywall panel using gypsum board is composed of metal panel to construct the skeleton, glass surface, rock wool, etc., insulation material and a certain air layer, and the surface finish is 10 ~ 12mm gypsum board. It is a wall structure of the form. In addition, ALC (Lightweight Foamed Concrete) and cement composite panels have been used. The most important factors in use are fire resistance and sound insulation performance, which are legal factors. In other words, in order for inter-generational internal partitions to be used as walls, the Ministry of Land, Transport and Maritime Affairs must approve the fire resistance and sound insulation performance of the ball.

On the other hand, extrusion panels (hereinafter referred to as "wall panels") have been proposed as inter-generational partition walls. The wall panel was vacuum-formed during production and had a high heat density because it had a high density of 1.8 g / cm 3. That is, when heat is applied to the surface of the wall panel due to a fire or the like, the air of the internal micropores expands and the air does not escape to the outside and has a characteristic of exploding. Due to this, the fire resistance performance is remarkably deteriorated. In the case of the sound insulation performance, the sound insulation performance of the wall panel itself is excellent, but noise is transmitted to the floor and the ceiling of the connection part of the wall panel and the sound insulation performance is lowered. In addition, the construction is performed by inserting wall panels on both the bottom and the top of the wall panel during construction. In this case, gaps between the upper and lower slabs and the channel may occur to act as a factor of noise transmission.

Such wall panels have been widely used as exterior materials and interior materials of existing buildings. The products are generally 35mm, 50mm, 60mm thick products, the width of the product is produced from a minimum of 450mm to a maximum of 600mm. Wall panels have the advantages of high product density and high water resistance by vacuum forming in the production stage. General product quality is shown in Table 1 below.

Item Performance standard Flexural strength (MPa) More than 14 Density (g / cm3) 1.8 ± 0.2 Absorption rate (%) Within 15 Length change rate (%) Within 0.12

Due to the above characteristics, the water resistance is excellent and the flexural rigidity is higher than the panels of other materials used in the wall structure is used as a toilet, balcony panel material requiring water resistance in addition to the exterior material. In addition, when the wall panel is used as an interior material, as described above, it is difficult to apply because it is difficult to secure fire resistance performance, but when the fire resistance performance of the wall panel is secured by using a fiber or the like and the partial finish is applied to the surface. The stable performance can be secured and the fire resistance can be compensated for.

However, even in the case of constructing inter-wall partition internal walls using wall panels, there has been the following problem because there is no separate core material that can only display insulation between the wall panels and support the load between the wall panels. .

First, there is no core material in the middle between the wall panels, as shown in Figure 2 can damage the panel in the lateral load. That is, when a lateral load acts on one wall panel forming the wall, warpage occurs and deformation occurs to damage the durability of the entire wall. This means that even if the wall panel secures the bending strength of 14 MPa or more, as described above, deformation may occur due to construction defects. Recently, due to the expansion of flat-panel TVs and the like, hanger-type constructions have been frequently installed on the inner wall of the dividers for generations. In this case, as shown in FIG. 3, since a load is transmitted only to one panel panel forming a wall, durability of the entire wall structure such as deformation is reduced.

Second, when the connection between the wall panels is not made a strong connection, the panel shakes, and after construction, deformation occurs due to the absence of core material, which can act as a path of heat transfer in case of fire as well as noise transfer due to gaps and cracks in the connection part. have.

The present invention has not yet used an extruded wall panel as the inter-generation partition inner wall (structure) for the reasons mentioned above, but by using it as a complement to the water resistance and fire resistance, by placing a support block between the wall panel transverse By supplementing the durability against external forces such as directional loads and providing a connection between the solid wall panels, it does not cause shaking even in long-term use, so that there is no cracking of the connection and to provide noise and fireproof performance stability.

Extruded internal partition wall structure by assembling the supporting block according to the present invention relates to an internal partition wall structure that divides generations. The basic configuration of the present invention includes a pair of wall panels facing each other and having a plurality of hollows formed therein. And a support block placed between the pair of wall panels. That is, a pair of wall panels and support blocks formed by extrusion molding support the pair of wall panels by the support blocks, thereby presenting a solid internal partition wall structure to improve durability, and to generate noise after construction. To solve the problem.

In the pair of wall panels, both side ends are configured with fastening protrusions fastened to the grooves and the grooves, respectively, so that connection construction between adjacent wall panels is possible.

In addition, it is reasonable to block the heat transfer between adjacent wall structures so as to form a hollow in the support block, and to block the noise flowing through the connection between the adjacent wall panels.

In addition, at least one inner guide groove is formed to face each other on the opposite surface of the pair of wall panels, and a support is mounted on the inner guide groove so that the insulating material placed between the pair of wall panels is fixed and slipped. It is reasonable to ensure that it is prevented.

On the other hand, the construction method using the extrusion molding internal partition wall structure by the assembly of the present invention comprises the steps of installing a channel on the upper, lower slab; Mounting a support on one wall panel of the pair of wall panels and mounting the heat insulating material on one wall panel by the support, fastening the support block to one wall panel, and fastening the other wall panel to the support block Completing the extrusion-molded inner partition wall structure by assembling the above-mentioned support block by a process; And the step of installing the wall structure of the extrusion-molded inner partition wall by assembling the completed support block in the previous step.

The construction method using the extruded inner partition wall structure by assembling according to the present invention allows the support blocks to be prefabricated between a pair of wall panels, resulting in the following advantages.

First, there is an advantage that the sound blocking performance can be improved by blocking the sound transmitted from the connection by configuring the support block in the connection portion of the wall panel.

Second, since the wall panel is firmly fixed by the support block, there is no shaking or deformation of the wall panel after construction, thereby improving durability of the entire wall structure.

Third, since the wall panel, the support block, and the support can be prefabricated including the heat insulating material, there is an advantage in that construction and disassembly are easy.

1 is a side cross-sectional view showing a conventional internal partition wall structure.
Figure 2 is a side cross-sectional view showing a modified example when a lateral load is applied in the conventional internal partition wall structure.
Figure 3 is a side cross-sectional view showing a modification when the TV is configured on one side in the longitudinal cooling inner partition wall structure.
Figure 4a and Figure 4b is a perspective view showing an embodiment of the extrusion inner partition wall structure by the support block assembly of the present invention.
Figure 5a and Figure 5b is a perspective view showing another embodiment of the extrusion inner partition wall structure by the support block assembly of the present invention.
Figure 6a and Figure 6b is a perspective view showing another embodiment of the extrusion inner partition wall structure by the support block assembly of the present invention.
Figure 7 is a plan view showing an example of the extrusion molding inner partition wall structure is installed by the support block assembly of the present invention.
Figure 8 is a block diagram showing a construction method using the extrusion molding internal partition wall structure by the support block assembly of the present invention.

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

Hereinafter, the configuration and operation of the present invention will be described in more detail with reference to the accompanying drawings. In describing the present invention, terms and words used in the present specification and claims are to be construed in accordance with the principles of the present invention, on the basis that the inventor can properly define the concept of a term in order to best explain his invention It should be construed as meaning and concept consistent with the technical idea of.

Extruded inner partition wall structure 100 by assembling the support block of the present invention relates to an inner partition wall structure that partitions generations, as shown in Figure 4a and a plurality of hollows 111 are opposed to each other as shown in Figure 4a. It is composed of a pair of wall panel 110 is formed, and the support block 120 is disposed between the pair of wall panel 110 to be supported by a support block 120 to assemble a pair of wall panel 110. This improves structural performance and prevents noise.

The pair of wall panel 110 is formed by extrusion molding, it is a structure to prevent the noise by making a sound absorption by configuring a plurality of hollows (111) inside. Thus, the wall panel 110 formed by extrusion molding has been difficult to use as a wall structure partitioning generations due to the lack of fire resistance and sound insulation performance, but recently fire resistant performance due to development of asbestos-free products and development of fire-resistant products. There seems to be no problem in securing. Therefore, it is necessary to supplement the sound insulation performance. In general, wall panels formed by extrusion are high-density products, but the wall panels themselves have excellent sound insulation performance, but they are caused by sound leaking from the connections between the wall panels or damage of the joints caused by structural defects over time. It was relatively difficult to secure sound insulation performance due to the gap. Accordingly, in the present invention, in order to solve this problem, a support block 120 is formed between the pair of wall panels 110 to block noise at the connection between the wall panels 110, and the wall panel 110 is supported by the support block 120. Since it is firmly fixed, the function of noise prevention through deformation prevention after construction is exerted.

As shown in FIG. 4A, both side ends of the pair of wall panels 110 are configured with fastening protrusions 113 fastened to the recesses 112 and the recesses 112, respectively, to connect adjacent wall panels 110. It is configured to be assembled.

As shown in FIGS. 4A and 5A, the recess 112 is configured to cover the height of the entire side end of the wall panel 110 at one side end of the pair of wall panels 110, and the fastening protrusion 113 corresponding thereto. Also to be configured over the entire side height of the wall panel (110). By this configuration is to be fastened by the fitting method between the adjacent wall panel 110.

Meanwhile, when the recess 112 and the fastening protrusion 113 are configured as shown in FIG. 4A, fitting may not be easily performed when bending occurs in the extrusion process, and thus, FIG. 5B illustrates one pair of the wall panels 110. A plurality of fastening protrusions 113a are formed at the side ends, and a plurality of recesses 112a are configured to correspond to each other so that each of the fastening protrusions 113a and the recesses 112a is fastened by a fitting method. do.

Preferably, the support block 120 has a hollow 121 formed therein as shown in FIG. 4A. The hollow block 121 is formed in the support block 120 to block the noise at the connection portion of the wall structure and to block heat transfer between adjacent wall structures. Of course, the number of the hollow 121 can be configured selectively.

In fastening the pair of wall panels 110 and the support blocks 120, as shown in FIG. 4A, the support blocks 120 are formed such that the support protrusions 122 are formed on surfaces facing the pair of wall panels, respectively. In each of the pair of wall panels 110, guide grooves 114 are formed on opposite sides of the pair of wall panels 110 so that the support protrusions 122 slide in the guide grooves 114.

To explain this in more detail, the support protrusion 122 is configured to have a shape in which the width is extended in the end direction, and the guide groove 114 corresponding thereto is also configured in a shape in which the width is extended in the inward direction. The support block 120 is to be fastened between the pair of wall panels 110 by sliding in the guide grooves 114, and can be firmly fixed based on the shape of the support protrusions 122 and the guide grooves 114. To do that.

Meanwhile, in the present invention, the support block 120 shown in FIG. 4A to the support block 120a according to another embodiment is shown. The support block 120a of the present embodiment has the same point of forming the hollow 121a and the supporting protrusion 121a in the interior, but first, each corner portion is formed in a round shape in the shape of the hollow 121a. The outer corners also have a round shape. Thus, the support block 120a of this embodiment prevents stress concentration by treating the hollow 121a and the outer corner (not shown) in a round shape, thereby preventing deterioration of durability of the support block 120a by stress concentration. .

In addition, the support protrusion 122a is also configured in a pair of rim shape to form an inclined gradient on the contrary to enable more rigid fixing in the guide groove 114. In other words, the opening angle of the pair of edges forming the inclined gradient in the support protrusion 122a is greater than the angle of the side facing the pair of edges in the guide groove 114 to press the pair of edges. When inserted into the guide groove 114, and slides to the desired position, the support block 120a can be firmly fixed between the pair of wall panels 110 by the elastic restoring force of the pair of edges.

Thus, the support block 120a of the present embodiment is preferably composed of an elastic material, but the material is not limited as long as it is an elastic material, but a PP resin or an aluminum material may be used.

4A and 6A, the support block 120 has a structure in which one support block 120 is fastened to one guide groove 114, and the support block 120 includes the pair of wall panels 110. It is characterized in that it is formed in the same length (height). In this case, between the wall structure is a structure that is completely blocked by the support block 120 is presented. When using the support block 120 can be expected to block the complete heat transfer between the wall structure.

On the other hand in Figure 6b is shown a support block 120b is fastened to a plurality of guide grooves 114. That is, in the pair of wall panels 110, the plurality of support blocks 120b slide on both sides. The support block 120b has the same shape as the support block 120 shown in FIGS. 4A and 6A, and only a length (height) is configured to be different, and thus, detailed descriptions of the support block 120b will be omitted. The reason for presenting the support block 120b in which a plurality is fastened to one guide groove 114 as described above is large in the case of the support block 120 shown in FIGS. 4A and 6A (compared to the support block 120b). As the support protrusion 122 is formed, the support block 120 is not easy to slide to the pair of wall panels 110 when an error occurs, such as bending, so that the support block can reduce the material cost while reducing the molding cost. (120b).

On the other hand, the space formed by the pair of wall panels 110 and the support block 120 is inserted into the heat insulating material, the slide fastening process of the pair of wall panels 110 and the support block 120, the lower side by the time elapsed Back insulation is pushed to the bottom to prevent the block against the partial insulation effect, and in order to prevent the dysfunction in the insulation and structure, such as deformation of the wall structure by the lower pull of the insulation in the present invention, as shown in Figure 4a, a pair of wall panels One or more inner guide grooves 115 are formed on the opposite surface of the 110, and a support 130 is mounted on the inner guide grooves 115.

To describe this in more detail, the inner guide groove 115 is configured in a shape in which the width thereof increases in the inward direction, and the support 130 is a support frame 131 having a shape opposite to the shape of the inner guide groove 115. And a support pin 132 protruding from the support frame 131, and the support frame 131 slides to the inner guide groove 115 configured at one wall panel 110 to support the support pin 132. This is to be exposed, so that the heat insulating material is inserted into the exposed support pins 132 so as to prevent the lower pull of the heat insulating material. Since the inner guide groove 115 is formed over the entire length direction of the wall panel 110, the support 130 may be mounted on one inner guide groove 115 by selecting the number thereof as necessary. Bar, which can be selectively configured in consideration of the weight of the insulation.

On the other hand Figure 7 shows a plan view showing an example of the extrusion molding inner partition wall structure is installed by the support block assembly of the present invention, the pair of wall panels 110, the support 130 and the like described above are the same configuration Although illustrated, the above-described support block 120 and the support block 120d of another embodiment are presented.

The support block 120d has the same shape as the support block 120 shown in FIG. 4A, but the two support blocks 120 are integrally formed. By this configuration, four fastening protrusions 122c are formed in the support block 120d of the present embodiment, so that one support block can be fastened by one support block 120d between adjacent wall panels 110. Four wall panels 110 are fastened to 120d. As the support block 120d is configured as described above, the construction can be easily and securely fastened, and the noise blocking effect can be doubled by blocking the connection part between adjacent wall panels 110 with a completely closed surface.

In addition, as shown in FIG. 7, one or more inner guide grooves 115 face each other on the opposing surfaces of the pair of wall panels 110, so that the inner guide grooves 115 formed in the one wall panel 110 are formed. The end of the support 130, ie, the support pin 132, which is mounted to slide the support frame 131 so that the support pin 132 is exposed, is formed in the other wall panel 110 while passing through the heat insulating material 140. It is reasonable to be mounted to the inner guide groove 115 to prevent the side slip of the heat insulating material 140.

Meanwhile, the present invention proposes a construction method using an extrusion-molded inner partition wall structure by assembling the supporting block as shown in FIG. 8, in which the construction method of the present invention first installs a channel on the upper and lower slabs (S10). Next, the support 130 is mounted on one wall panel 110 of the pair of wall panels 110, and the heat insulating material 140 is attached to the wall panel 110 by the support 130. By assembling the above-mentioned support block by a mounting process, a process of fastening the support block 120 to one wall panel 110, and a process of fastening the other wall panel 110 to the support block 120. Extrusion molding is partitioned through the step (S20) to complete the wall structure (100). Here, the process of mounting the support 130 to the one wall panel 110 and the heat insulating material 140 to the one wall panel 110 by the support 130, the support block 120 is one wall panel ( The process of fastening to 110 and the process of fastening the other wall panel 110 to the support block 120 may be performed by varying the front and rear according to construction conditions.

Finally, the step of installing the extruded internal partition wall structure 100 by the assembly of the completed support block is installed on the glass (S30).

110: wall panel 111: hollow
112: groove 113: fastening protrusion
114: guide groove 120: support block
122: support protrusion 130: support
131: support frame 132: support pin

Claims (12)

It is composed of a pair of wall panels facing each other and a plurality of hollow walls are formed therein and a support block disposed between the pair of wall panels, the both sides of the pair of wall panels are fastened to the groove and the groove, respectively The fastening protrusion is configured, wherein the groove is formed on the whole side end of the wall panel at one side end of the wall panel, the corresponding fastening protrusion is formed to protrude over the whole side end of the wall panel at the other side end to the groove In the internal partition wall structure for partitioning the generation between connecting the adjacent wall panel by allowing the fastening protrusion is inserted,
One or more inner guide grooves face each other on opposite surfaces of the pair of wall panels, and one or more supports are mounted on the inner guide groove, and the inner guide grooves are configured to have a wider width in the inner direction. The support is composed of a support frame which faces the shape of the inner guide groove and a support pin protruding from the support frame, the support frame is slide-fastened to the inner guide groove and the other end of the support pin facing the end. Inserted into the inner guide groove of the wall panel,
The support block
One or more hollows are formed, and two support protrusions are formed on each side of the wall panel facing each other and face each other, and the pair of wall panels have the support protrusions slide on both sides of the mutually opposing surfaces. Extruded inner partition wall structure by assembling the support block is formed, the guide groove is formed, but the two pairs of wall panel is fastened to the one support block.
delete delete delete delete delete delete delete delete delete delete Installing a channel on the upper and lower slabs; Mounting a support on one wall panel of the pair of wall panels and mounting the heat insulating material on one wall panel by the support, fastening the support block to one wall panel, and fastening the other wall panel to the support block Comprising the step of completing the extrusion-inner partition wall structure by the assembly of the support block of claim 1; Installing an extrusion molding inner partition wall structure by the assembly of the support block completed in the previous step in the channel; Construction method using the extrusion molding inner partition wall structure by the assembly of the support block comprising a.

Images