KR101365486B1 - earthquake-resistance assembling exterior block unit manufacturing method - Google Patents

Abstract

The present invention is for finishing the outer wall,
A six-sided exterior block body 620; A plurality of exterior block body protrusions 622 protruding from the exterior block body 620; A lower end of the outer block body 620 is embedded in the upper end of the outer block body 620, the clasp 610 protruding from the center; A finishing material 630 installed below the exterior block body 620; And a sealing agent 640 installed at the edge of the finishing material 630 to protrude toward the side of the lower edge of the exterior block body 620 or to be aligned with the bottom edge of the exterior block body 620 at the bottom edge. Consists of including
The sealing agent 640 is installed in contact with the sealing agent 640 of the seismic assembly block unit 600 for seismic installation is installed adjacent to the waterproof function, the clasp 610 is the top of the ring-shaped wall block hook portion 618 is formed and the wall block locking portion 618 is fixed to the contact portion inclined surface 114 of the block outer plate 110 is installed adjacent, the outer block body projection 622 is the block outer plate 110 and Provides an earthquake-proof assembly block unit 600, characterized in that to form a drainage channel spaced apart from the outer block body 620.

Description

Earthquake-resistance assembling exterior block unit manufacturing method

The present invention relates to a prefabricated exterior block unit for earthquake resistance, which is constructed by a dry method using a ready-made member in constructing a finishing material on a wall, so that even unskilled persons can maintain a predetermined quality and have excellent seismic performance.

Finishing walls is essential in buildings.

Existing wall finishing materials are to be attached to the finishing materials after the construction of the wall as a structure, after attaching a separate frame or angle to the wall construction, attach the finishing materials, such as stone and fill the gap between the finishing materials with the sealing material. do.

Since the conventional method requires a separate process such as installing a frame on the wall, it takes a lot of time and a difference in quality occurs according to the skill of the skilled workers, and it is difficult to provide seismic performance due to weakness such as lateral pressure.

Therefore, in the construction of the finishing material on the wall by using the ready-made member to be constructed by the dry method, even the unskilled person can maintain a predetermined quality, it is urgent to develop a prefabricated exterior block unit for earthquake resistance excellent in seismic performance.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems of the related art. The purpose is as follows.

First, to provide a seismic prefabricated exterior block unit for reducing the air in the construction of the wall finishing material because the construction of the ready-made member dry.

Second, to provide a seismic prefabricated exterior block unit that can be applied to buildings of various planes and elevations by using a modular member.

Third, to provide a shockproof prefabricated exterior block unit having an excellent seismic performance by providing the main body with an elastic body to cope with the impact such as lateral pressure.

Fourth, to provide a prefabricated exterior block unit for earthquake resistance that can be easily installed in a predetermined quality even unskilled workers.

In order to solve the above technical problem, the present invention is to finish the outer wall,

A six-sided exterior block body 620; A plurality of exterior block body protrusions 622 protruding from the exterior block body 620; A lower end of the outer block body 620 is embedded in the upper end of the outer block body 620, the clasp 610 protruding from the center; A finishing material 630 installed below the exterior block body 620; And a sealing agent 640 installed at the edge of the finishing material 630 to protrude toward the side of the lower edge of the exterior block body 620 or to be aligned with the bottom edge of the exterior block body 620 at the bottom edge. Consists of including

The sealing agent 640 is installed in contact with the sealing agent 640 of the seismic assembly block unit 600 for seismic installation is installed adjacent to the waterproof function, the clasp 610 is the top of the ring-shaped wall block hook portion 618 is formed and the wall block locking portion 618 is fixed to the contact portion inclined surface 114 of the block outer plate 110 is installed adjacent, the outer block body projection 622 is the block outer plate 110 and Provides an earthquake-proof assembly block unit 600, characterized in that to form a drainage channel spaced apart from the outer block body 620.

According to the present invention, the following effects are expected.

First, since the prefabricated member is constructed dry, it provides a seismic assembly block unit for reducing the air in the construction of the wall finishing material.

Second, it provides a seismic prefabricated exterior block unit that can be applied to buildings of various planes and elevations by using a modular member.

Third, to provide a shockproof prefabricated exterior block unit having an excellent seismic performance by providing the main body with an elastic body to cope with the impact such as lateral pressure.

Fourth, the present invention provides a seismic assembly block unit that can be easily installed in a predetermined quality even for unskilled workers.

1 is a plan view and a perspective view of a wall block of the prefabricated block unit for earthquake resistance.
2 is a plan view and a perspective view of a wall block for a corner;
3 is a front view and a perspective view of a first embodiment of a core block body.
4 is a front view and a perspective view of another embodiment of the core block body.
5 is a perspective view of the leaf spring.
6 is a perspective view and a cross-sectional view of the core block.
7 is a perspective view of the core block body used in the second embodiment of the core block.
8 is a perspective view of a leaf spring used in the second embodiment of the core block body.
9 is a perspective view of a second embodiment of a core block.
10 is a cross-sectional view and a perspective view of a wall structure using the prefabricated block unit for earthquake resistance.
11 is a perspective view of the core core.
12 is a conceptual diagram showing the action of the leaf spring end of the leaf spring and the center of the leaf spring.
13 is a perspective view of a core piercing connector for connecting a plurality of core pontoons.
14 is a perspective view showing a state in which the core pontoon connecting rod is coupled to the core pontoon.
15 is a front view, a perspective view and a rear perspective view of the prefabricated exterior block unit for earthquake resistance.
16 is a cross-sectional view showing a method of manufacturing a seismic assembled outer block unit.
17 is a perspective view of a clasp used in a seismic assembly block unit for earthquake resistance.
18 is a combination of an exterior block body and an exterior block body protrusion used in a seismic assembled exterior block unit.
19 is a perspective view of a sealing agent used in the prefabricated exterior block unit for earthquake resistance.
20 is a cross-sectional view illustrating a state in which the seismic assembly block unit is installed on a wall block.
21 is a front view, a side view and a rear perspective view of a second embodiment of the prefabricated exterior block unit for earthquake resistance.
Fig. 22 is a side view and a perspective view of a clasp used in the second embodiment of the prefabricated exterior block unit for earthquake resistance.
23 is another embodiment of a core block.
24 is a construction conceptual view to which another embodiment of the core block is applied.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1. Seismic Assembly Unit

Prefabricated block unit for earthquake resistance of the present invention is to build a wall having a dry earthquake-resistant performance by stacking blocks,

A plurality of inner blocks of the block 110 and the semi-hollowed blocks 132 are formed by connecting the two outer blocks of the plate 110 and the two outer blocks of plate 110 integrally and vertically. A plurality of wall blocks 100, including 120; And, a plurality of core block 200 having an elastic body on the outside; , ≪ / RTI >

The plurality of wall blocks 100 are stacked horizontally and vertically, and several layers are stacked with clogged joints. The anti-hollow portions 132 of the wall blocks 100 are horizontally adjacent semi-hollow portions 132 of the wall blocks 100. ) To form a coupling hollow portion 130` of the same shape and size as the block hollow portion 130, and the core block 200 is vertically penetrated and connected to the block hollow portion 130 and the coupling hollow portion ( 130`) and the elastic body supports the inner wall of the block hollow portion 130 and the coupling hollow portion 130` using elastic force, and thus has a seismic performance corresponding to the lateral pressure acting on the finished wall. do.

1 is a plan view and a perspective view of a wall block of the prefabricated block unit for earthquake resistance. Specifically, Figure 1 (a) is a plan view of the wall block of the prefabricated block unit for earthquake resistance, Figure 1 (b) is a perspective view of the wall block of the prefabricated block unit for earthquake resistance.

2 is a plan view and a perspective view of a wall block for a corner; Specifically, FIG. 2 (a) is a plan view of a corner wall block, and FIG. 2 (b) is a perspective view of a corner wall block.

Adjacent block contact portions 112 are formed at both ends of the block outer plate 110 of the wall block 100 to be in contact with the adjacent wall block 100, and the contact portion inclined surface inclined downward from the adjacent block contact portion 112. 114 is formed. The contact part slope 114 is caught by the wall block locking portion 618 of the clasp 610 to be described later.

The corner wall block 100 ′ is to be installed at the corner of the wall and changes the position of the adjacent block contact portion 112 of the wall block 100.

6 is a perspective view and a cross-sectional view of the core block, Figure 3 is a front view and a perspective view of a first embodiment of the core block body, Figure 4 is a front view and a perspective view of another embodiment of the core block body. And Figure 5 is a perspective view of the leaf spring.

The core block 200,

A plurality of plates composed of two core block inserting portions 234, a block hollow portion contacting portion 232, and a leaf spring contact portion 236 bent at one end of the core block inserting portion 234 in a U-shape folded plate. A spring 230; And a plurality of leaf spring inserting parts 220 horizontally penetrating in a hexahedral shape so that the core block inserting parts 234 of the two leaf springs 230 are symmetrically inserted into the leaf spring inserting parts 220. It is configured to include; a core block body (210).

In this case, the leaf spring 230 is used as the elastic body, and the two leaf spring contact portions 236 symmetrically inserted into and contact the inner surface of the leaf spring inserting portion 220 exchange elasticity with each other and the outer core block body 210. It is preferable to change the elastic force of the block hollow portion contact portion 232 exposed to. Because the block hollow portion 130 and the coupling hollow portion 130` are vertically penetrated and have a certain error, the leaf spring 230 inserted therein is combined with the block hollow portion 130 and the coupling hollow portion 130`. This is to change the elastic force in response to the error when supporting the inner wall of the c) by using the elastic force.

10 is a cross-sectional view and a perspective view of a wall structure using the prefabricated block unit for earthquake resistance.

FIG. 7 is a perspective view of a core block body used in the second embodiment of the core block, FIG. 8 is a perspective view of a leaf spring used in the second embodiment of the core block body, and FIG. 9 is a perspective view of the second embodiment of the core block. Perspective view.

The second embodiment 200` of the core block 200 is,

A core block body 210 'having a plurality of leaf spring engaging portions 220' formed on a front surface and a rear surface thereof in a hexahedral shape as a whole; And a plurality of leaf springs 230 'installed so that the core block fixing portion 234` is hooked to the leaf spring engaging portion 220' so as to have elasticity. The leaf spring 230 ′ is used.

Figure 11 is a perspective view of the core core, Figure 12 is a conceptual diagram showing the action of the leaf spring end fixing plate and the center of the leaf spring.

The present invention instead of the core block 200,

Square pipe 310 is formed hollow; Four leaf spring end fixing rods 342 are formed at a predetermined interval in a row and four leaf spring end fixing rods 340 fixed to each of the front and rear edges of each of the pipes 310; The plurality of leaf spring center fixing projections 362 are inserted at regular intervals in a row by being inserted so as to slide up and down between the leaf spring end fixing brackets 340 fixed to each of the front and rear edges of the respective pipes 310. Leaf spring center pin (360); And a plurality of core core plate springs 320 that are fitted to the leaf spring end fixing protrusions 342 and the leaf spring center fixing protrusions 362. ,

As shown in FIG. 12, when the plate spring center fixing member 360 is pushed upward, the core abacus spring 320 is bent to have an elastic force.

And, as shown in the partial detail of FIG. 11, the two sides of the angular pipe 310, the elastic core distribution spring 380 having an elastic force between the two core core spring (320) installed on the front and rear; Is installed, the elastic force between the core manifold spring 320 due to the elastic distribution spring 380 can be exchanged.

FIG. 13 is a perspective view of a core piercing connector for connecting a plurality of core piercings, and FIG. 14 is a perspective view showing a state in which a core piercing connecting rod is coupled to a core wick.

As shown in FIG. 13, the core core connecting rod 300 ′ is for extending the length of the core core 300 and the core core plate spring 320 is attached to the front and rear surfaces thereof and the brackets 340 ′ on both sides thereof. Is attached.

FIG. 23 is another embodiment of a core block, and FIG. 24 is a construction conceptual diagram to which another embodiment of the core block is applied.

Another embodiment of the core block is further provided with a plurality of elastic distribution springs (380`) connecting between both ends of the leaf spring 230` installed on the front and rear of the core block body 210`, The elastic force is exchanged between the leaf spring 230 'due to the elastic distribution spring 380, and the leaf spring 230' and the elastic distribution spring 380 'are formed of the wall block 100. The anti-hollow part 132 and the block hollow part 130 is characterized by having a seismic performance by maintaining a distance with the inner wall surface.

The core core 300 ″ shown in FIG. 24 adopts a configuration similar to that of the other embodiment of the core block, and an elastic distribution spring 380 ″ is connected between both ends of the core core plate spring 320 ″. The seismic core springs 320 ″ and the elastic distribution springs 380 ″ are separated from the inner wall surfaces of the semi-hollow portions 132 and the block hollow portions 130 of the wall block 100 by seismic resistance. It is characterized by including the performance.

2. Seismic Assembly Block Unit

FIG. 15 is a front view, a perspective view and a rear perspective view of the seismic assembly block unit for earthquake resistance, and FIG. 17 is a perspective view of a clasp used in the assembly structure block unit for earthquake resistance.

And Figure 18 is a combination of the outer block body and the outer block body projections used in the prefabricated exterior block unit for earthquake resistance, Figure 19 is a perspective view of the sealing agent used in the prefabricated exterior block unit for earthquake resistance, Figure 20 is a prefabricated exterior for earthquake resistance It is sectional drawing which shows the state in which a block unit is installed in the wall block.

Seismic assembly block unit 600 for the present invention is to close the outer wall,

A six-sided exterior block body 620; A plurality of exterior block body protrusions 622 protruding from the exterior block body 620; A lower end of the outer block body 620 is embedded in the upper end of the outer block body 620, the clasp 610 protruding from the center; A finishing material 630 installed below the exterior block body 620; And a sealing agent 640 installed at the edge of the finishing material 630 to protrude toward the side of the lower edge of the exterior block body 620 or to be aligned with the bottom edge of the exterior block body 620 at the bottom edge. Consists of including

The sealing agent 640 is installed in contact with the sealing agent 640 of the seismic assembly block unit 600 for seismic installation is installed adjacent to the waterproof function, the clasp 610 is the top of the ring-shaped wall block hook portion 618 is formed and the wall block locking portion 618 is fixed to the contact portion inclined surface 114 of the block outer plate 110 is installed adjacent, the outer block body projection 622 is the block outer plate 110 and The exterior block body 620 is spaced apart to form a drainage path.

The exterior block body 620 and the exterior block body protrusion 622 are preferably manufactured integrally with urethane in consideration of fabrication convenience and seismic performance. In another embodiment, the exterior block body protrusion 622 may be omitted or cut and used in the field.

The clasp 610 can adjust the separation distance and the tension acting upon the block outer plate 110 coupled to the wall block engaging portion length adjustment unit 616, the bent lower fixing portion 614 is Easy to mount with the finishing material 630 and may be attached to the finishing material 630 in advance in some cases. In addition, the upper leveling unit 612 serves to display the thickness of the exterior block body 620 in advance. And since the clasp 610 has elasticity, it is easy to install with strong adhesion, and has a characteristic of not falling off since it actively responds to its lateral load acting on the outer wall with its own displacement.

The sealant 640 has flexibility and elasticity and waterproof performance, so that the sealant 640 is installed in contact with the sealant 640 of the seismic prefabricated exterior block unit 600 which is adjacently installed. It is equipped with a waterproof function.

Fig. 21 is a front view, a side view and a rear perspective view of a second embodiment of the seismic assembled outer block unit, and Fig. 22 is a side view and a perspective view of the clasp used in the second embodiment of the seismic assembled outer block unit.

In the second embodiment of the seismic assembly block unit of the present invention, as shown in Fig. 21 and the following figure, the clasp 610 has a frame-shaped locking portion 619 at the upper end thereof, so that the frame locking portion ( 619 is characterized in that is fixed to the frame installed on the outer wall.

3. How to Produce Seismic Assembly Block Unit

16 is a cross-sectional view showing a method of manufacturing a seismic assembled outer block unit.

The method for manufacturing a seismic assembly block unit for earthquake resistance according to the present invention includes: (1) a lower mold arrangement step of disposing a lower mold (DM); (2) a sealing agent installation step of installing a sealing agent 640 on the lower edge of the lower mold (DM); (3) a finishing material installation step of installing a finishing material 630 in the sealing agent 640; (4) a clasp installation step of mounting the clasp 610 on the finishing material 630; (5) an upper mold installation step of installing an upper mold UM on the lower mold DM; And, (6) filling the urethane into the upper mold (UM) and the lower mold (DM) to fill the urethane filling step in which the sealing agent 640 and the finishing material 630 are integrally combined with the urethane. It is characterized by.

The (6) urethane filling step refers to a step in which the sealing agent 640 and the finishing material 630 are integrally combined with the urethane by filling the urethane into the upper mold (UM) and the lower mold (DM). The sealing agent 640 is installed to protrude toward the side of the lower edge of the outer block body 620 or the lower edge of the outer block body 620 is installed to match the finish line.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

It is therefore intended that the appended claims cover such modifications and variations as fall within the true scope of the invention.

100: wall block
100`: Wall block for corner
110: block outer plate
112: adjacent block contact
114: contact slope
120: block inner plate
130: block
130`: Combined hollow department
132: Anti-Heavy Studies
200, 200`: core block
210, 210`: core block body
220: leaf spring insertion
220`: leaf spring catching part
230, 230 `: leaf spring
232, 232`: Block hollow contact
234: core block insert
234`: Core Block Security
236: leaf spring contact
300, 300``: core
300`: core deep connecting rod
310: square pipe
320, 320``: core core spring
340: leaf spring end fixing
340 `: bracket
342: plate spring end step protrusion
360: leaf spring center
362: leaf spring center fixing protrusion
380, 380`, 380``: Elastic distribution spring
600: exterior block
610: clasp
612: upper leveling unit
614: lower fixed part
616: wall block locking part length adjustment unit
618: wall block catch
619: Frame locking clip
620: exterior block body
622: external block body projection
630: finish
640: sealing agent
UM: Upper mold
DM: Lower mold

Claims (5)

For finishing exterior walls,
A six-sided exterior block body 620;
A plurality of exterior block body protrusions 622 protruding from the exterior block body 620;
A lower end of the outer block body 620 is embedded in the upper end of the outer block body 620, the clasp 610 protruding from the center;
A finishing material 630 installed below the exterior block body 620; And
A sealing agent 640 installed at the edge of the finishing material 630 and installed to protrude toward the side of the bottom edge of the exterior block body 620 or to be aligned with the bottom edge of the exterior block body 620;
, ≪ / RTI >
The sealing agent 640 is installed in contact with the sealing agent 640 of the seismic assembly block unit 600 for seismic installation is installed adjacent to the waterproof function,
The clasp 610 is fixed to the contact surface inclined surface 114 of the block outer plate 110, the wall block engaging portion 618 is adjacent to the wall block engaging portion 618 is formed adjacent,
The exterior block body protrusion 622 forms a drainage path by separating the block outer plate 110 and the exterior block body 620.
The clasp 610 is a seismic prefabricated exterior block unit 600, characterized in that the upper end of the clip-shaped frame locking portion 619 is formed is fixed to the frame is fixed to the frame installed on the outer wall. As a way to produce,
(1) a lower mold placing step of placing a lower mold (DM);
(2) a sealing agent installation step of installing a sealing agent 640 on the lower edge of the lower mold (DM);
(3) a finishing material installation step of installing a finishing material 630 in the sealing agent 640;
(4) a clasp installation step of mounting the clasp 610 on the finishing material 630;
(5) an upper mold installation step of installing an upper mold UM on the lower mold DM; And
(6) filling the urethane into the upper mold (UM) and the lower mold (DM) to the urethane filling step of the sealing agent 640 and the finishing material 630 is integrally combined with the urethane;
Earthquake-proof assembly type block unit production method characterized in that it comprises a.
delete delete delete delete

Images