KR101719297B1 - wall insulation system assembly having seismic vibration-absorbing panels - Google Patents

Abstract

The present invention provides a wall insulation system assembly having an anti-earthquake panel for absorbing vibration comprises: a plurality of insulation frames including an upper frame disposed on a front side when being installed in a wall, a lower frame disposed on a rear side when being installed in the wall, a lattice rebar bend in a zigzag shape and lengthily extended between the upper and lower frames, and a frame insulation material filled between the upper and lower frames, vertical installed in the wall, and installed by being mutually apart from each other; an insulation material filled between the insulation frames by lattice filling; a plurality of horizontal member horizontally installed at joint intervals in order to intersect the plurality of insulation frames in the front of the insulation frame; a horizontal member fixation plate combined with the horizontal member in upper and lower parts of the horizontal member, and combining and fixating the horizontal member to the insulation frame; and the anti-earthquake panel for absorbing vibration installed in the front of the insulation frame and the horizontal member in upper, lower, left, and right directions to finish the wall, and inclined within a constant range to relieve or absorb vibration occurring in a building when the vibration occurs in the building by an earthquake. Thereby, horizontal and vertical vibration occurring in the building by the earthquake can be simultaneously absorbed, and a heat bridge in the frame, heat bridge effect in a fastener, breakage of the insulation material, or problem of a weak part can be solved.

Description

FIELD OF THE INVENTION [0001] The present invention relates to wall insulation system assemblies having seismic vibration-

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a wall insulation system assembly having a vibration-absorbing seismic panel, and more particularly, To a wall insulation system assembly.

The contents described in this section merely provide background information on the present embodiment and do not constitute the prior art.

In general, drywall construction using metal frame as a frame is performed by 1) arranging metal frame on the wall horizontally and vertically in consideration of the designed pattern by welding or bolt assembly method (metal fastener To fix to the structure); 2) inserting and installing the insulation between the frames using a grating method; 3) fix and attach factory finished panels to each joint location with screws or dedicated brackets; 4) In case of joint-joint system or open-joint system without jointing, use metal foil or waterproof cloth between frame and finish before attaching finish panel After waterproofing, interior and exterior panel installation works.

If there is a concrete structural wall, attach the insulation to the wall first, install the metal frame in the same way as above (1), and apply as in 3) ~ 4) above. At this time, in order to fix and install the metal frame on the wall, the fastener part is separated from the heat insulator, the fastener is installed, and the urethane foam is filled to secure the heat insulation performance.

The method of inserting and inserting the insulation material between the metal frame frames is a method of inserting and installing the insulator between the metal frames because the insulation is cut off due to the metal frame having a thermal conductivity about 1000 times higher than that of general insulation. Resulting in significant energy loss. Even when the heat insulating material is first attached to the wall and the metal frame is installed, the heat energy is conducted to the metal fastener portion having a high thermal conductivity, the heat insulating material is removed around the fastener, and the portion filled with the urethane foam is difficult to exhibit the same heat insulating performance as the original heat insulating material There is a problem that a path of a thermal bridge is formed and a large amount of energy loss is generated there. In such a building, significant heat loss and dew condensation occur in proportion to the large and small spacing of each piping structure according to the finishing dimensions of the panel (the dividing dimension of the joint). In addition, most of the process is carried out in the field. At this time, in the process of cutting and processing the pipes directly, the part of the body is damaged by the cutting machine in the process of welding, and the risk of electric shock and fire is very high. It occurs frequently.

The closed-joint system is a sealing waterproofing method to prevent inflow of rainwater, and adopts a method of caulking sealant of an organic chemical into a joint between each finishing panel. In this case, when the dust or contaminants in the gaps between the joints are not completely removed, the sealant is peeled off from the finishing material and is leaked or exposed to the outside air, which causes contamination, discoloration, deterioration, Causing a problem that the appearance is disturbed by discoloring or causing discoloration, and leakage is caused to the severely deteriorated part. Also, since the internal and external materials are stored in the sunlight, the heated air or heat is transferred to the room through convection or conduction without rapidly dissipating heat, thereby deteriorating the heat insulation performance.

In order to overcome the problems of such a closed joint system, an open-joint system may be employed. This open joint system is not a method of simply exposing joints, but rather a scientific method based on the theory of equipotential pressure. It is a structure that dissipates heat to the air even when the joint is opened and the internal and external materials are stored. It is advantageous in securing performance.

Therefore, it is essential to install a waterproof layer between the insulation and the finishing material so as to prevent rainwater from entering the inside of the system, and to secure airtight performance so as to prevent the inflow of hot or cold air. In addition, the incoming rainwater must have a structure capable of natural drainage. However, such a method also has considerable problems in waterproofing, and it requires careful planning and delicate construction management from the design stage in order to completely solve the problem.

An example of a wall finishing structure according to such an open joint system is disclosed in Korean Patent Registration No. 10-0374995 (registered on Feb. 21, 2003, hereinafter referred to as "Patent Document 1").

Nevertheless, the reality is that it is difficult to solve the leakage problem. Despite the many advantages of the open joint system, the closed joint system which is caulked to the sealant is mainly applied. As a result, significant cost of building maintenance and management costs have been incurred to clean the contaminated walls and repair the leak, or to replace the failed sealant due to deterioration.

On the other hand, Korea has been recognized as a relatively safe area from earthquakes. Recently, earthquake occurrence frequency is increasing. Therefore, there is an increasing interest in earthquake resistance repair method in concrete facilities including existing general buildings.

However, in existing buildings and facilities, not only the earthquake considerations are insufficient, but also seismic performance is weak due to deterioration damage or strength deterioration. In case of unexpected earthquake, not only direct damage due to breakage or collapse but also reconstruction There is also a problem in that socio-economic losses are incurred.

Korean Patent Registration No. 10-0374995 (registered on Feb. 21, 2003)

It is an object of the present invention to provide a method and apparatus capable of simultaneously absorbing horizontal vibration and vertical vibration generated in a building due to an earthquake and at the same time to prevent thermal bridges, And an object of the present invention is to provide a wall insulation system assembly having a vibration absorption seismic panel capable of solving the problem.

In addition, it is possible to prevent twisting or distortion of the finishing panel and to secure the merits of the internal and external insulation of the building sufficiently, and to simplify manufacturing and installation so as to simplify and reduce cost, shorten the air, improve energy efficiency of building, And to provide a wall insulation system assembly having a vibration-absorbing seismic panel that can be provided as an environmentally friendly method that is very advantageous in terms of cost reduction.

It is another object of the present invention to provide a wall insulation system assembly having a vibration absorption seismic panel that absorbs vibration caused by an earthquake and improves watertightness by using a packing so that the side frame and the finishing panel are spaced apart from each other.

In order to achieve the above object, a wall thermal insulation system assembly with a vibration absorption seismic panel according to the present invention comprises: an upper frame disposed forwardly when installed on a wall; a lower frame disposed rearwardly when installed on a wall; And a frame insulator which is folded in a zigzag form between the lower frames and extends between the upper frame and the lower frame and a frame insulator which is filled between the upper frame and the lower frame, A heat insulating frame; A heat insulating material filled in the space between the heat insulating frames by a grid; A plurality of horizontal members arranged horizontally at an interval of an interval to cross the plurality of heat insulating frames at the front of the heat insulating frame; A horizontal fixing plate coupled to the horizontal member at the upper and lower portions of the horizontal member and coupling and fixing the horizontal member to the heat insulating frame; And a wall mounted on the front side of the heat insulating frame and the horizontal member to close the wall. When vibration occurs in the building due to an earthquake, the wall tilts within a predetermined range to alleviate vibrations generated in the building, And an anti-vibration panel for vibration absorption.

The vibration absorption seismic panel may include a side frame provided to the heat insulating frame and the horizontal member so as to form a quadrangular shape and a side frame which is inserted into the side frame so as to be slidable in the longitudinal direction of the side frame, A corner frame which is fastened and fixed and which supports the side frames so as to be fixed to the heat insulating frame and the horizontal member and the corner parts of the other side frames which are positioned orthogonally to the side frames, And a finishing panel which is fitted into the packing groove formed in the corner frame and absorbs vibration generated in the building, and a finishing panel which is in close contact with the outer surface of the packing and fastened to the side frame and finishes the finishing .

The moving member includes a hook which is slidably inserted into an insertion groove formed in the side frame, a support which is connected to the hook and is inserted into a cut formed on the side frame and supports the hook, And a fastening fixture fastened and fixed to the heat insulating frame and the horizontal member by bolts or screws.

The wall heat insulation system assembly with the vibration absorption seismic panel according to the present invention comprises an upper bracket provided on the vibration absorption seismic panel and fixing the vibration absorption seismic panel to the horizontal member, A bottom bracket installed at a lower portion of the seismic panel for fixing the vibration-absorbing seismic panel to the horizontal member, and two adjustment plates coupling the upper bracket or the lower bracket to the horizontal member.

According to the present invention, it is possible to simultaneously absorb horizontal vibration and vertical vibration generated in a building due to an earthquake, and at the same time to solve problems such as thermal bridges in frames generated by existing methods, thermal bridge phenomenon in fasteners, It is possible to provide a wall insulation system assembly having a vibration-absorbing seismic panel that can solve the problem.

In addition, it is possible to prevent twisting or distortion of the finishing panel and to secure the merits of the internal and external insulation of the building sufficiently, and to simplify manufacturing and installation so as to simplify and reduce cost, shorten the air, improve energy efficiency of building, It is possible to provide a wall insulation system assembly having a vibration-absorbing seismic panel that can be provided as an environment-friendly method that is very advantageous for saving.

It is also possible to provide a wall insulation system assembly having a vibration absorption seismic panel that absorbs vibration caused by an earthquake and improves watertightness by using a packing so that the side frame and the finishing panel are spaced apart from each other.

1 is an exploded perspective view showing a process of installing a wall insulation system assembly having a vibration absorption seismic panel according to the present invention,
Fig. 2 is a side view showing the construction of a wall insulation system assembly with the vibration-damping seismic panel of Fig. 1 in a side view,
FIG. 3 is a front view and a side view of the horizontal fixing plate of FIG. 2,
4 is a bottom view, front view, and side view of the upper bracket of FIG. 2;
Fig. 5 is a front view and a side view of the lower bracket of Fig. 2,
FIG. 6 is a front view and a side view of the adjustment plate of FIG. 2;
Figure 7 is a side view of the horizontal member of Figure 2,
Fig. 8 is an assembly sectional view and assembly side view of the heat insulating frame of Fig. 2, Fig.
9 is an enlarged exploded perspective view showing a process of installing a vibration absorption seismic panel in front of a heat insulating frame and a horizontal member according to the present invention,
10 is an exploded perspective view of a vibration-absorbing seismic panel according to the present invention,
11 is a side sectional view of a vibration-absorbing seismic panel according to the present invention,
Fig. 12 is an enlarged sectional view showing a part of the vibration-absorbing seismic panel of Fig. 11,
13 is a partially exploded perspective view showing a process of installing a movable member on a side frame of a vibration-absorbing seismic panel according to the present invention;
14 is a view illustrating a process of absorbing or alleviating vibration generated in a building as the movable member tilts in the vibration-absorbing seismic panel according to the present invention,
Fig. 15 is a rear view showing a rear surface of a vibration-absorbing seismic panel according to another embodiment of the present invention, Fig.
16 is a side view showing the configuration of a vibration-absorbing seismic panel according to another embodiment of the present invention.

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

As shown in FIGS. 1 and 2, the wall heat insulating system assembly with the vibration-absorbing seismic panel according to the present invention is an open joint system, and includes a plurality of heat insulating frames 100, a heat insulating material 200, Includes a plurality of horizontal members (300), a horizontal member fixing plate (400), and a vibration absorption seismic panel (500).

As shown in FIGS. 2 and 8, the heat insulating frame 100 includes an upper frame 110, which is provided as a long elongated member and disposed in front of the wall 10 including the concrete wall, A lattice bar 130 bent in a zigzag form and extending long between the upper frame 110 and the lower frame 120, A frame insulator 140 filled between the upper frame 110 and the lower frame 120. The frame insulator 140 is vertically installed in the wall 10 through the fastener 20, And are provided in a plurality of spaced apart from each other.

The heat insulating frame 100 according to the present invention does not require welding in the field, and it can prevent the opening and closing phenomenon by the existing steel square pipe to improve the cooling and heating energy efficiency. In the upper frame 110, It is possible to construct the wall insulation system assembly using the improved off-joint system by connecting the horizontal member 300 and the like to the heat-insulating frame 100.

8A, the cross section of the upper frame 110 is formed by vertically bending and extending both ends of the inner horizontal portion 112 to form an inner vertical portion 114, and an inner vertical portion 114 Each of the inner vertical portions 114 is bent and extended vertically in the direction opposite to each other to form the middle horizontal portion 115. The middle horizontal portion 115 has a curved portion 116 having a U-shape and a curved portion 116 having a U-shape, the curved portion 116 having an outer horizontal portion 118 .

The outer horizontal portion 118 is bent and extended vertically in the direction of the inner horizontal portion 112 at the end portion to form an outer vertical portion 119. The outer vertical portion 119 includes an intermediate horizontal portion 115, (112).

The inner horizontal portion 112, the inner vertical portion 114, the intermediate horizontal portion 115 and the 'U' -shaped bent portion 116 are used to insert the T-shaped bolt 30 (see FIG. 2) The bolt groove 111 is formed in consideration of the size of the inserted T-shaped bolt 30 so that the head portion of the T-shaped bolt 30 can be accommodated.

The inner vertical portion 114 and the outer horizontal portion 118 function to secure the position of the lattice reinforcing bar 130 when the heat insulating frame 100 is coupled and to facilitate the welding.

8, a cross section of the lower frame 120 is formed such that both ends of the first upper horizontal portion 121 are vertically bent to form a joint portion 123, and the joint portion 123 is elongated And is bent and extended vertically in a direction away from the first upper horizontal portion 121 to form a second upper horizontal portion 125. [ The second upper horizontal portion 125 is bent and extended vertically in the direction away from the first upper horizontal portion 121 at the end portion to form the lower vertical portion 127.

The lower horizontal portion 129 is bent and extended perpendicularly to the first upper horizontal portion 121 at an end of the lower vertical portion 127 to form a lower horizontal portion 129, (125).

8 (b), the lower vertical portion 127 of the lower frame 120 includes a slot hole 127a for engaging with the fastener 20 using a bolt (not shown) And the slot holes 127a are formed at regular intervals along the longitudinal direction of the lower frame 120. [

The length between the outer vertical portions 119 of the upper frame 110 is the same as the length between the lower vertical portions 127 of the lower frame 120. The length of the inner horizontal portion 112 of the upper frame 110 is shorter than the length of the first upper horizontal portion 121 of the lower frame 120 so that the lattice reinforcing bars 130 are arranged in a trapezoidal shape in the heat insulating frame 100 do.

Accordingly, the lattice reinforcing bars 130 are more effective in an external force acting in the transverse direction, as compared with the case where the lattice reinforcing bars 130 are arranged in parallel with each other, so that the structure is improved in response to buckling of the frame.

The lattice bar 130 is a reinforcing bar that is continuously bent in a zigzag form as shown in Figs. The upper frame 110 and the lower frame 120 are formed such that a part of the bent portions of the pair of lattice bars 130 is positioned at a corner portion between the inner vertical portion 114 of the upper frame 110 and the middle horizontal portion 115 And the other of the bent portions of the lattice reinforcing bar 130 is welded and joined to the first horizontal portion 121 of the first upper horizontal portion 121 of the lower frame 120. [ And is welded and joined to both ends and the second upper horizontal portion 125.

The remaining portion of the frame 110 between the upper frame 110 and the lower frame 120 except for the lattice reinforcement 130 is filled with the frame insulating material 140.

1, the fastener 20 is composed of a frame coupling plate 21 and a wall coupling plate 23, and the frame coupling plate 21 and the wall coupling The plate 23 is preferably vertically connected in the form of an 'L' character.

The frame engaging plate 21 includes two fastener slot holes 21a and the fastener slot hole 21a of the frame engaging plate 21 is engaged with the slot hole 127a of the lower frame 120, The interval between the two fastener slot holes 21a of the lower frame 21 is formed to be equal to the interval between the slot holes 127a of the lower frame 120. [

The wall coupling plate 23 includes a set anchor groove 23a and attaches the set anchor to the wall body 10 through the set anchor groove 23a to thereby fasten the fastener 20 to the wall body 10.

The heat insulating frame 100 is coupled to the wall 10 by a fastener 20, as shown in Fig. When the heat insulating frame 100 is vertically coupled to the wall 10, the heat insulating material 200 is interposed between the heat insulating frames 100 to complete the heat insulating wall.

In order to prevent water or moisture from penetrating into the inside of the heat insulating wall, the moisture permeable and waterproof paper (40) is provided on the heat insulating wall using an adhesive means such as double-sided adhesive tape.

The heat insulating material (200) is filled in the space between the heat insulating frames (100) by a grid.

As shown in Fig. 2, the wall insulation system assembly with the vibration-absorbing seismic panel according to the present invention is characterized in that a complete watertight layer and airtightness are formed between the heat-insulating frame 100 and the vibration- The horizontal member 400, and the upper bracket 600, the lower bracket 700, and the adjustment plate (not shown) to have a performance that secures the structural safety against external force and secures seismic performance and follow- 800).

As shown in FIG. 1, the horizontal member 300 includes a plurality of longitudinally arranged members horizontally installed at a gap distance across a plurality of heat-insulating frames 100 at the front of the heat-insulating frame 100 2, two horizontal fixing plates 400 are used to fix the horizontal member 300 to the heat insulating frame 100 and the horizontal fixing plate 400 is fixed by using the T-shaped bolts 30 Is fixed to the heat insulating frame (100). At this time, the head portion of the T-shaped bolt 30 is fitted into the bolt groove 111 of the upper frame 110 of the heat insulating frame 100.

2 and 3, the horizontal fixture plate 400 is coupled to the horizontal member 300 at the upper and lower portions of the horizontal member 300 and is used to couple and fix the horizontal member 300 to the heat insulating frame 100 The horizontal fixing plate 400 includes a horizontal coupling unit 420 for coupling the horizontal coupling unit 410 and the wall coupling unit 410 including the fixing plate slot hole 411 for coupling with the heat insulating frame 100 .

The wall coupling portion 410 is a rectangular plate and includes a fixing plate slot hole 411 at the center thereof. The horizontal coupling portion 420 is vertically bent at the end of the wall coupling portion 410, And is perpendicular to the direction of approaching the wall engaging portion 410. The wall engaging portion 410 is formed with a stepped portion that is perpendicular to the wall engaging portion 410, That is, since the horizontal recombination unit 420 has a bent shape in the form of a 'C', it is not easily separated when it is combined with the horizontal member 300.

1 and 9, the vibration-absorbing seismic panel 500 is installed in the upper, lower, left, and right directions in front of the heat insulating frame 100 and the horizontal member 300 to close the wall 10, When the vibration is generated in the building, it is inclined within a certain range to mitigate the vibration generated in the building or to absorb the vibration.

Accordingly, it is possible to simultaneously absorb the horizontal vibration and the vertical vibration generated in the building due to the earthquake, and at the same time, solve the problem of thermal bridge in the frame generated in the existing method, thermal bridge of the fastener, It is possible to provide a wall insulation system assembly having a vibration-absorbing seismic panel that can be used.

2, the wall heat insulating system assembly with the vibration-absorbing seismic panel according to the present invention is installed on the upper part of the vibration-absorbing seismic panel 500 and includes the vibration-absorbing seismic panel 500 as the horizontal member 300 A lower bracket 700 for fixing the vibration absorption seismic panel 500 to the horizontal member 300 and a lower bracket 600 for fixing the vibration absorption seismic panel 500 to the horizontal member 300, It is preferable to further include two adjustment plates 800 for coupling the bracket 600 or the lower bracket 700 with the horizontal member 300.

Accordingly, the vibration absorption seismic panel 500 can be fixed to the horizontal member 300 by the adjustment plate 800, the upper bracket 600, and the lower bracket 700.

9, on one side of the heat insulating frame 100 according to the present invention, a heat insulating material 200, which is provided to extend to a portion where the heat insulating material 200 is accommodated and is closed by the vibration absorption seismic panel 500, The heat insulating material fixing unit 900 includes an elastic pressing member 910 including an elastic member such as a spring and protruding toward the heat insulating material 200 do.

Accordingly, when the heat insulating material 200 is filled with lattice between the heat insulating frames 100 and is finished by the vibration absorption seismic panel 500, the heat insulating material fixing portion 900 having the elastic pressing member 910 fixes the heat insulating material 200 are brought into close contact with the vibration-damping seismic resistant panel 500, thereby maximizing the effect of heat insulation and vibration absorption.

The upper bracket 600 is a bracket connected to the upper portion of the vibration absorption seismic panel 500 as shown in Figs. 2 and 4, Coupled with the combined adjustment plate (800).

More specifically, the upper bracket 600 includes a first panel coupling plate 610 and a first tuning plate joint 620. The first panel coupling plate 610 includes a vibration absorbing panel 500, And the first panel coupling plate 610 includes the first bracket slot hole 611 because the first panel coupling plate 610 is coupled using the anchor bolt 50. [

The first adjustment plate coupling portion 620 protrudes from the first bracket slot 611 of the first panel coupling plate 610. The first adjustment plate coupling portion 620 is protruded from the other surface of the first panel coupling plate 610, And is protruded at a predetermined distance from one end far away from the first panel coupling plate 610 and protruded perpendicularly to the first panel coupling plate 610 and has a shape of 'a' bent in the direction of the first bracket slot hole 611, The adjustment plate 620 includes two bracket bolt holes 621 for engagement with the adjustment plate 800 and is coupled using hexagonal bolts 60. [

The adjustment plate receiving portion 630 is formed on the other surface of the first panel coupling plate 610 at a position adjacent to the first adjusting plate coupling portion 620 and the adjusting plate receiving portion 630 has a stable contact portion And is formed to be lower than other portions of the other surface of the first panel coupling plate 610 so as to be seated.

The lower bracket 700 is a bracket connected to the lower portion of the vibration absorption seismic panel 500 as shown in Figs. 2 and 5, and is coupled to the upper region of the horizontal member 300 in the upper region of the horizontal member 300, Coupled with the adjustment plate (800).

More specifically, the lower bracket 700 includes a second panel coupling plate 710 and a second adjusted plate coupling portion 720, and the second panel coupling plate 710 includes a vibration absorption seismic panel 500, And the second panel coupling plate 710 includes the second bracket slot hole 711 because the second panel coupling plate 710 is coupled using the anchor bolt 50.

The second brackets 700 are spaced apart from the second bracket slot 711 by a predetermined distance so that the second brackets 720 are projected. 3 protrusion 831 and is bent in a direction opposite to that of the second bracket slot hole 711 to have a shape of 'A'.

The lower bracket 700 is located below the vibration absorption seismic panel 500 and is fitted to the adjustment plate 800. Unlike the upper bracket 600, the lower bracket 700 does not include bolt holes.

2 and 6, the adjustment plate 800 is a member for finely adjusting the installation height and the projection depth of the vibration-absorbing seismic panel 500. The horizontal member 300 and the vibration-absorbing seismic panel 500 The upper bracket coupling portion 820 and the lower bracket coupling portion 830. The horizontal rejoinder plate 810 and the lower bracket coupling portion 830 are connected to each other by a bolt, .

The horizontal re-combination plate 810 includes a regulating plate slot hole 811 through which the bolts 70 pass because the plate is in contact with the horizontal member 300 on one side and engages with the horizontal member 300 through the bolts.

The upper bracket engaging portion 820 and the lower bracket engaging portion 830 are formed at both ends of the horizontal re-combination plate 810 so that the regulating plate 800 is aligned with the horizontal re- combination plate 810 The lower bracket coupling portion 830 is formed and the upper bracket coupling portion 820 is formed in the opposite direction.

The upper bracket coupling portion 820 includes a first protrusion 821 protruding vertically in the other surface direction at the end of the horizontal recombination plate 810 and a second protrusion 821 protruding vertically in the other surface direction at a portion spaced apart from the end portion by the diameter of the head portion of the bolt The second projecting portion 823 forms a bolt connecting groove 825 having a shape of '?'.

The bolt fastening groove 825 in the form of └┘ serves as a nut when the adjusting plate 800 is engaged with the upper bracket 600 and the hexagonal bolt 60 and is inserted into the bracket bolt hole 621, and bolts are turned to adjust tightening and loosening, so that the height of the vibration-absorbing seismic panel (500) is finely adjusted so as to be precisely aligned with the joint.

The lower bracket coupling portion 830 includes a third projection 831 extending from the end of the horizontal recombination plate 810 in an opposite direction to the upper bracket coupling portion 820, And a fourth protrusion 833 extending in a portion spaced apart by a thickness 720. [

The lower bracket engaging portion 830 has a longer length of the fourth projection 833 than the third projection 831 to stably fix the lower bracket 700. [

As shown in Figs. 2 and 7, the horizontal member 300 is one of members for an open joint system which is horizontally installed at an interval between joints to the heat insulating wall, and the cross section is provided so as to extend long.

The cross section of the horizontal member 300 includes a reference vertical portion 310, a first connection portion 320, and a second connection portion 330. One surface of the reference vertical part 310 is flat as a surface to be fixed to the heat insulating wall and the first connection part 320 and the second connection part 330 at both ends of the reference vertical part 310 are flattened on the reference vertical part 310 .

Each of the first connection part 320 and the second connection part 330 includes a fixed plate fitting part 341, an adjustment plate fitting part 343 and a fixing part 345. The fixed plate coupling portion 341 is a portion that engages with the horizontal recombination portion 420 of the horizontal plate 400 and the first connection portion 320 and the second connection portion 330 are formed on opposite sides of the surfaces facing each other .

Shaped grooves are formed inwardly to accommodate the horizontal recombination unit 420 of the horizontal fixture plate 400 at a portion where the end of the reference vertical portion 310 starts to protrude. The 'a' shaped groove corresponds to the size and shape of the horizontal recombination unit 420 of the horizontal member fixing plate 400.

Therefore, the horizontal member 300 is horizontally inserted between the two horizontal fixing plates 400 fixed to the heat insulating frame 100 in advance. When the horizontal member 300 and the horizontal member fixing plate 400 are coupled to each other, the reference vertical portion 310 and the wall coupling portion 410 of the horizontal member fixing plate 400 are brought into contact with the heat insulating frame 100 to form a flat surface.

The adjustment and alignment unit 343 is a portion of the adjustment plate 800 which is engaged with the horizontal re-combination plate 810. The first and second connection units 320 and 330 are formed on the surfaces facing each other, 310 at a distance from the fixed judging portion 341. Since the horizontal member 300 and the adjustment plate 800 are coupled using the bolts 70 and the nuts 75, the adjustment plate-fitting portion 343 is formed with a groove having a 'T' shape inward, Lt; / RTI >

The fixing portion 345 abuts against the third projection 831 of the adjusting plate 800 so that the adjusting plate 800 is coupled to the horizontal member 300 and then the second projection 823 or the fourth projection 833 And the position where the fixing portion 345 protrudes from the adjustment judging portion 343 is a position where the first connecting portion 320 and the second connecting portion 320 protrude And may be different according to the second connection portion 330.

When the horizontal member 300 and the adjustment plate 800 are in contact with each other, the horizontal member 300 and the adjustment plate 800 are not engaged with each other. The upper bracket 600 and the lower bracket 700 are also provided with projections and depressions such as threads on the portions where the anchor bolts 50 are tightened so that the upper and lower brackets 600 and 700 are slid with respect to the vibration- .

9 to 14, the vibration absorption seismic panel 500 includes a side frame 510 installed in the heat insulating frame 100 and the horizontal member 300 so as to have a rectangular shape, And the side frame 510 is fixed to the heat insulating frame 100 and the horizontal member 300 so as to be slidable in the longitudinal direction of the heat insulating frame 100 and the horizontal member 300 A corner frame 530 for allowing corner portions of the movable member 520 and the other side frame 510 positioned at right angles to the side frame 510 to be connected to each other and a side frame 510 and a corner frame 530 A packing 540 fitted to the packing groove 513 formed in the packing 540 and absorbing vibration generated in the building; And a deadline finish panel 550.

Accordingly, it is possible to prevent twisting or distortion of the finishing panel 550, and to sufficiently secure the merits of the internal and external insulation methods of the building, and to simplify manufacturing and installation so as to be simple and simple, It is possible to provide a wall insulation system assembly having a vibration absorption seismic panel that can be provided as an environmentally friendly method that is very advantageous in terms of cost reduction, maintenance, and maintenance cost reduction.

The side frame 510 is disposed between the heat insulating wall and the finishing panel 550 and is fixed to the upper and lower sides of the finishing panel 550 by bolts and nuts respectively to form a square shape. . The side frame 510 may be integrally formed with the guide rail 511, the packing groove 513, the extending portion 515, and the fitting groove 517.

The guide rail 511 includes an insertion groove 511a formed in the longitudinal direction so that the hook portion 521 formed in the moving member 520 is inserted and slidable and a cutout portion 511a formed by cutting the middle of the insertion groove 511a A first supporting portion 511c formed on the outer side of the side frame 510 and a second supporting portion 511d formed on the inner side of the side frame 510 opposite to the first supporting portion 511c.

The insertion groove 511a allows the hooking portion 521 formed in the moving member 520 to be inserted and allows the hooking portion 521 to move back and forth or upward and downward, The hook portion 521 may be formed larger than the hook portion 521.

As described above, when the insertion groove 511a is formed larger than the hooking portion 521 formed on the shifting member 520, the vibration generated in the building due to an earthquake or the like is mitigated.

The vibration generated in the building is transmitted to the side frame 510 through the moving member 520 and the vibration generated in the side frame 510 is transmitted to the side frame 510 through the moving member 520. [ The vibration of the finishing panel 550 is transmitted to the finishing panel 550 which is fastened and fixed to the finishing panel 550. In order to alleviate the vibration of the finishing panel 550, May be formed larger than the hook portion (521) formed on the member (520).

For example, when vibration is generated in the building due to an earthquake or the like while the moving member 520 is fixed to the heat insulating wall, the rubber packing 511e may be inserted into the insertion groove 511a. The hook portion 521 formed on the side frame 510 moves to reduce the friction between the moving member 520 and the side frame 510 and the vibration generated by the friction between the moving member 520 and the side frame 510, (511e) can absorb. The use of such a rubber packing 511e has an advantage that noise generated by the friction between the moving member 520 and the side frame 510 can be blocked.

Meanwhile, the width between the both ends of the cutout portion 511b may be formed to be within the range of 1.5 to 2 times the thickness of the moving member 520 inserted between the cutouts 511b. In the present invention, when the gap between the both ends of the incision portion 511b is formed to be less than the lower limit range, the movable member 520 is hard to move due to the vibration, and when the movable member 520 May be released to the cutout 511b.

The first support portion 511c is formed by extending from the outer side of the side frame 510 in the direction of the heat insulating wall and the heat insulating frame 100 and includes a moving member inclined outwardly of the side frame 510 520, respectively.

That is, as shown in FIG. 14 (b), the moving member 520, which is inclined by a certain angle due to the building vibration, is bent or broken by the pressure of the support table 523 formed on the moving member 520 by external force In order to prevent breakage of the moving member 520, the front surface of the fastening and fixing part 525 formed on the moving member 520 is supported by the first supporting part 511c.

The second support portion 511d is formed to extend from the inner side surface of the side frame 510 toward the heat insulating frame 100 and includes a moving member 520 inclined toward the inner side of the side frame 100 by vibration of the building Lt; / RTI >

That is, as shown in FIG. 14C, the other side of the fastening portion 525 formed on the moving member 520, which is inclined by a certain angle due to the vibration of the building, is supported so that the moving member 520 To be bent or broken by the pressure.

The packing groove 513 is formed on the front surface of the side frame 510 to have a predetermined depth in the longitudinal direction. The packing 540 is inserted and fixed in the packing groove 513, and a pair of protrusions And the protrusion 513a prevents the packing 540 inserted into the packing groove 513 from being released to the outside.

The extension portion 515 is formed to extend in the inner direction of the side frame 510 at the outer wall of the packing groove 513 and a fastening hole 515a is formed so that the finish panel 550 can be fastened and fixed with bolts and nuts .

The fitting groove 517 may be formed between the guide rail 511 and the packing groove 513 in the shape of a letter and inserted in the corner frame 530 so that the fastening bar 533 is inserted .

That is, the side frames 510 may be formed so as to be connected to each other by the corner frame 530.

In addition, a fixing piece 517a may be formed to prevent the corner frame 530 fitted into the fitting groove 517 from being detached from the outside.

The moving member 520 includes a hook portion 521 slidably inserted into the insertion groove 511a formed in the guide rail 511 of the side frame 510 and a hook portion 521 connected to the hook portion 521, A support base 523 which is inserted into the cutout 511b formed in the heat insulating frame 100 and the horizontal member 300 and which is fixed to the heat insulating frame 100 and the horizontal member 300 by bolts or screws, And a fixing portion 525.

Accordingly, the movable member 520 is inserted into the guide rail 511 formed on the side frame 510 to be slid along the guide rail 511 so as to be adjustable in position, so that the side frame 510 is fixed to the heat insulating wall can do.

In addition, in the present invention, the moving member 520 may absorb vibration transmitted to the finishing panel 550 due to vibration of the building, or may mitigate vibration.

For example, when vibration occurs in a building due to vibrations occurring in an earthquake or a nearby construction site, the movable member 520 can be moved within a certain range or can be inclined within a certain range to absorb vibration generated in the building Or relaxed.

On the other hand, the moving member 520 may be formed to be inclined at an angle of 8 ° to 12 ° with respect to the center of the insertion groove 511a formed in the guide rail 511, but in the present invention, 520 are inclined at an angle of 10 DEG.

That is, in the present invention, when the inclination of the movable member 520 is formed to be lower than the above lower limit range, there is no effect due to the effect of mitigating the vibration generated in the building or absorbing the vibration, The moving member 520 may be severely shaken and damaged.

The corner frame 530 is disposed between the side frame 510 and the other side frame 510. The corner frame 530 includes a finishing panel 550 fastened to the side frame 510, May be provided to prevent the side frame 510 from twisting or twisting. The corner frame 530 includes a body 531 formed to close between the side frames 510 and the other side frame 510 disposed orthogonally to the side frames 510, And a fastening bar 533 formed on the side frame 510 and fixed to the fitting groove 517 formed in the side frame 510. A packing groove 513 may be formed in the front surface of the corner frame 530 so that the packing groove 513 formed in the corner frame 530 is formed to be connected to the packing groove 513 formed in the side frame 510 .

The packing 540 is made of a synthetic resin material having water tightness and flame resistance and is fitted and fixed in a packing groove 513 formed in the side frame 510 and the corner frame 530. The packing 540 is made of a finishing panel 550 And the side frame 510 may collide with each other to prevent the finish panel 550 from being damaged.

That is, the packing 540 may be formed to be larger than the depth of the packing groove 513 and protrude from the outer surface of the side frame 510 so as to be spaced apart from the side frame 510 by a predetermined distance .

As described above, if the packing 540 is used at a predetermined distance between the side frame 510 and the finishing panel 550, it is possible to absorb vibration generated by an earthquake or the like to prevent the finishing panel 550 from being deformed There is an advantage to be able to do.

For example, when the side frame 510 fixed by the moving member 520 is moved by vibration, the finishing panel 550 may be moved in the same manner to cause deformation, which prevents deformation of the finishing panel 550 When one side frame 510 of the four side frames 510 is distorted and deformed, the finishing panel 550 (see FIG. 5) Is not deformed by the packing 540 due to twist or distortion.

The finishing panel 550 is made of a metal such as a steel plate or aluminum, fastened to the side frame 510 by bolts, nuts, or the like, and is provided for finishing the outside of the heat insulating wall.

16, the finishing panel 550 of the vibration-damping vibration-isolating panel 500 according to the present invention includes a superanno-silicon nitride coating layer (not shown) coated with a synthetic organic compound component of silicon and nitrogen on the front outer surface 551 are preferably formed.

Accordingly, it is possible to effectively prevent the heat insulating wall, which is finished by the vibration absorption seismic panel 500 according to the present invention, from being contaminated by the external contaminants by the ultra-nanosized silicon nitride coating layer 551, It is possible to reduce the maintenance cost and achieve ultra-high nano density, so that it is less influenced by the temperature of the outside air and can further improve the heat insulating property and does not include the six heavy metals such as nickel, chromium, cadmium and lead Therefore, environment-friendly conditions can be met.

15, the vibration-absorbing seismic isolation panel 500 according to the present invention is provided so as to be closed by the finishing panel 550 at the front but filled with the panel insulation block 560 at the rear open part A vibration absorbing means 570 is provided between the side frame 510 and the panel insulating block 560 so that the panel insulating block 560 is fixed to the side of the vibration absorbing seismic panel 500 by the vibration absorbing means 570 And is supported so as to be resiliently supported therein.

Accordingly, the heat insulation performance of the vibration-damping seismic isolation panel 500 according to the present invention can be further improved by the panel insulation block 560 and the vibration absorption means 570, and the vibration damping and absorption performance Can be increased.

According to the present invention, by using the packing 540 so as to be spaced apart from the side frame 510 and the finishing panel 550, it is possible to absorb the vibration due to the earthquake and to improve the water- It is possible to provide a wall insulation system assembly with a panel.

While the invention has been described in connection with what is presently considered to be practical exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

100: heat insulating frame 110: upper frame
120: Lower frame 130: Lattice bar
140: Frame insulation 200: Insulation
300: horizontal material 400: horizontal material fixing plate
500: vibration-absorbing seismic panel 510: side frame
520: moving member 521:
523: Support base 525:
530: Corner frame 540: Packing
550: Finishing panel 600: Upper bracket
700: lower bracket 800: regulating plate

Claims (4)

A lower frame disposed rearwardly when installed on the wall, a lattice reinforcing bar extending in a zigzag form and extending between the upper frame and the lower frame, A plurality of heat insulating frames made of a frame insulating material filled between the lower frames and installed perpendicularly to the walls and arranged to be spaced apart from each other;
A heat insulating material filled in the space between the heat insulating frames by a grid;
A plurality of horizontal members arranged horizontally at an interval of an interval to cross the plurality of heat insulating frames at the front of the heat insulating frame;
A horizontal fixing plate coupled to the horizontal member at the upper and lower portions of the horizontal member and coupling and fixing the horizontal member to the heat insulating frame; And
The wall is installed in the upper, lower, left, and right directions in front of the heat insulating frame and the horizontal member. When the vibration occurs in the building due to an earthquake, it is inclined within a certain range to alleviate vibration generated in the building, An anti-vibration panel for vibration absorption;
/ RTI >
The vibration absorption seismic panel according to claim 1, wherein the vibration absorption seismic panel comprises: a side frame provided on the heat insulating frame and the horizontal member so as to form a quadrangular shape; A corner frame for connecting corners of another side frame which is positioned orthogonally to the side frames, a corner frame for supporting the side frames so that the side frames are fixed to the heat insulating frame and the horizontal member, A packing which is fitted in a packing groove formed in the corner frame and absorbs vibration generated in the building; and a finishing panel which is tightly fixed to the outer surface of the packing and fastened to the side frame and finishes the wall,
The moving member includes a hook which is slidably inserted into an insertion groove formed in the side frame, a support which is connected to the hook and is inserted into a cut formed on the side frame and supports the hook, And a fastening fixing part fastened and fixed to the heat insulating frame and the horizontal member with bolts or screws,
An upper bracket installed on the vibration absorption seismic panel for fixing the vibration absorption seismic panel to the horizontal member,
A lower bracket installed below the vibration-absorbing seismic panel for fixing the vibration-absorbing seismic panel to the horizontal member,
Further comprising two adjustment plates for coupling the upper bracket or the lower bracket and the horizontal member,
And a heat insulating material fixing part which is provided at one side of the heat insulating frame and extends to a portion where the heat insulating material is accommodated and fixes the position of the heat insulating material finishing by the vibration absorption seismic panel, And an elastic pressing member which is provided so as to protrude toward the heat insulating material.


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