KR102420650B1 - A Structure of Insulator for Preventing Thermal Bridge - Google Patents

Abstract

The present invention relates to a thermal bridge breaker for internal insulation installed at a joint between an external wall and a slab. More specifically, the thermal bridge breaker according to the present invention includes tensile reinforcements which are provided at upper and lower portions of an insulating element to penetrate through the insulating element to resist both ± moments and ± shear forces, thereby securing seismic performance by bearing compression and tension simultaneously even when tension and compression forces act alternately on a tensile-shear element during an earthquake, and increasing shear force by forming a shear element which connects the upper and lower reinforcements inside the insulating element. The thermal bridge breaker includes: an insulating element made of insulation material in a rectangular shape with a predetermined size; a plurality of tensile reinforcements which penetrate upper and lower portions of the insulating element in a width direction, of which both end portions protrude outwardly from each insulating element to a predetermined length, and which are installed at regular or irregular intervals in the insulating element; a horizontally buried reinforcement which is configured at one end of the tensile reinforcement in a horizontal direction and buried in a slab; a settling buried reinforcement which is configured to connect the upper and lower tensile reinforcements to the other end of the tensile reinforcement and are buried in a wall; a shear element which is manufactured integrally with the tensile reinforcement by connecting the pair of tensile reinforcements located at the upper and lower portions and is embedded in the insulating element; and fireproof plates which are formed on upper and lower surface of the insulating element with a predetermined thickness, and are made of a high temperature resistant material or ultra-high performance concrete (UHPC).

Description

A structure of Insulator for Preventing Thermal Bridge consisting of upper and lower tension muscles

The present invention relates to a thermal barrier material for internal insulation installed at a joint between an outer wall and a slab, and more particularly, to both the ± moment and ± shear force by constructing a tensile muscle penetrating the insulating element at the upper and lower portions of the insulating element, respectively. It is a structure that can withstand compression and tension at the same time even when tensile and compressive forces alternately act on tensile-shear elements during earthquakes, so seismic performance can be secured. It relates to a thermal cross-blocking material for internal insulation in which upper and lower tension muscles are configured to increase the shear force by constituting the .

In general, a house is defined as a building that separates the inside from the outside by composing a roof and walls. The walls and roof of such a house are usually made of a slab formed by pouring concrete.

The wall of such a house is completed through many processes such as rebar assembly, formwork installation, concrete pouring, exterior finishing, insulating material attachment, and interior finishing.

In this process, an insulator is used so that internal heat does not escape to the outside or heat does not enter from the outside. In this case, the insulation is usually attached to the inside (inner wall) or outside (outer wall) of the building to block heat.

However, in the structure where the wall and the slab are connected, the insulating material is broken, and in the place where the insulating material is cut off, a lot of heat escapes along the slab or reinforcing bar. This phenomenon is called a thermal bridge phenomenon.

As the background technology of the present invention, there is Patent Registration No. 1462800 "thermal bridge blocking device using discontinuous reinforcing bars" (Patent Document 1). In the background art, the heat insulating material 10 and the tensile module 20 disposed at the upper and lower portions in the width direction of the heat insulating material 10 to resist tensile force in the moment direction and the slab for the balcony vertical load bear the compressive force It is composed of a compression module 30 and a truss-type inclined shear muscle 40 that interconnects the tension module 20 and the compression module 30 .

However, in the conventional thermal bridge blocking device using discontinuous reinforcing bars, the truss-type inclined shear reinforcing bars 40 that interconnect the tension module 20 and the compression module 30 still connect the inner and outer tensile reinforcing bars 23 of the wall. There is a problem that there is a thermal bridge phenomenon in which the internal heat still escapes to the outside through the tensile reinforcing bar, and the compression module 30 is continuously disposed, and the shear reinforcing bar 40 passes through the cover between the compression module and the shear. Since the muscle 40 is coupled, the coupling between the shear muscle and the compression module is weak, and the shear muscle 40 is cut at the position where the shear muscle 40 and the compression module are coupled to achieve thermal cross-blocking. If (40) is cut in the middle, there is an effect of thermal cross-blocking, but there is a problem in that the shear force is weakened because the bonding force between the shear muscle and the compression module is weakened.

Patent Registration No. 1462800 "Thermal Bridge Breaker Using Discontinuous Rebar"

The present invention is to solve the above problems, and it can resist both ±moment and ±shear force, so that when an earthquake occurs, tensile force and compressive force alternately act on tensile-shear elements. An object of the present invention is to provide a thermal insulation barrier material capable of increasing shear force while securing seismic performance, and increasing compressive strength while increasing thermal insulation properties.

The present invention provides a heat-insulating material for internal insulation installed at a joint between an outer wall and a slab, comprising: a heat-insulating element made of a heat-insulating material in a rectangular parallelepiped shape of a predetermined size; a tension muscle which penetrates the upper part and the lower part of the insulating element in the width direction, respectively, so that both ends protrude a predetermined length to the outside of the insulating element, and a plurality of tension muscles are installed in the insulating element at equal or unequal intervals; a horizontal embedding muscle configured in the horizontal direction at one end of the tension muscle and embedded in the slab; A fixation embedding muscle configured to connect the upper and lower tension muscles to the other end of the tension muscle and embedded in the wall; a shear element built into the heat insulating element by connecting a pair of tension muscles located on the upper and lower parts to be integrated with the tension muscle; Including, based on 100 parts by weight of cement, silica fume 24-26, each consisting of a predetermined thickness on the upper and lower surfaces of the insulating element and made of a fireproof material or ultra high performance concrete (UHPC, ultra high performance concrete); parts by weight; 20-60 parts by weight of fine aggregate; 30 to 150 parts by weight of silica beads; And 3 to 4 parts by weight of a fluidizing agent; Compression elements made of ultra high performance concrete (UHPC, ultra high performance concrete) made by mixing with water so that the water-cement ratio is 28% (cement weight ratio) is the tensile force of the insulating element An object of the present invention is to provide a thermal cross-blocking material for internal insulation comprising upper and lower tension muscles, characterized in that they are selectively disposed in the width direction of the insulation element between the tension muscles.

In addition, an object of the present invention is to provide a thermal barrier material for internal insulation comprising upper and lower tension muscles, characterized in that one end in the longitudinal direction of the heat insulating element has a protrusion formed by protruding a central portion, and a corresponding concave portion is formed at the other end thereof.

In addition, the shear element is an internal insulation comprising upper and lower tensile muscles, characterized in that the vertical muscles are configured to be spaced apart from each other while connecting the upper and lower tensile muscles, and shear auxiliary muscles connecting them to each other between the vertical muscles. We would like to provide a thermal barrier material for

In addition, an object of the present invention is to provide a thermal cross-blocking material for internal insulation comprising upper and lower tensile muscles, characterized in that the shear element is formed to cross the upper and lower tensile muscles in the central portion to connect them in an X shape.

In addition, it is an object of the present invention to provide a thermal cross-blocking material for internal insulation comprising upper and lower tensile muscles, characterized in that the tension reinforcing bar is made of stainless steel, the horizontal buried reinforcing bars and anchored reinforcing bars are formed of reinforcing bars, and the shear element is made of stainless steel or reinforcing bars.

In addition, it is an object of the present invention to provide a thermal cross-blocking material for internal insulation comprising upper and lower tension muscles, characterized in that the anchored buried muscles are formed in a ⊃ shape and both ends are respectively connected to the upper and lower tensile muscles.

In addition, the anchorage anchor muscle is cut in the central part, and is composed of an upper anchorage muscle and a lower anchorage muscle. want to

Another object of the present invention is to provide a thermal barrier material for internal insulation comprising upper and lower tension muscles, characterized in that the lower surface of the compression element is positioned on the lower surface of the insulating element.

In addition, the compression element is configured such that all surfaces except the lower surface are curved, and the ends of the curved surface of the compression element are configured to protrude from both ends of the heat insulating element 10 in the width direction. An object of the present invention is to provide a thermal cross-blocking material for thermal insulation.

In addition, the fire resistant plate made of ultra high performance concrete (UHPC, ultra high performance concrete), based on 100 parts by weight of cement, 24 to 26 parts by weight of silica fume; 20-60 parts by weight of fine aggregate; 30 to 150 parts by weight of silica beads; and 3 to 4 parts by weight of a fluidizing agent, and to provide a heat cross-blocking material for internal insulation comprising upper and lower tension muscles, characterized in that it is mixed with water so that the water-cement ratio is 28% (cement weight ratio).

In addition, an object of the present invention is to provide a thermal cross-blocking material for internal insulation comprising upper and lower tension muscles, characterized in that the silica beads have a spherical shape.

In addition, an object of the present invention is to provide a thermal cross-blocking material for internal insulation comprising upper and lower tension muscles, characterized in that the silica beads have a size of 4 to 7 μm.

In addition, an object of the present invention is to provide a thermal cross-blocking material for internal insulation comprising upper and lower tension muscles, characterized in that the fine aggregate is silica sand.

The heat cross-blocking material for internal insulation comprising the upper and lower tensile muscles of the present invention can resist both ± moment and ± shear force by constructing tensile muscles penetrating the heat insulating element at the upper and lower portions of the insulating element, respectively, so that the tensile and compressive forces in the event of an earthquake are reduced. Seismic performance can be secured by a structure that can withstand compression and tension at the same time even when alternately acting on tensile-shear elements. Horizontal reinforcing reinforcing bars and anchoring reinforcing bars are configured on one side and the other end, respectively, so that they can be connected to reinforcing bars in structures such as slabs and walls. It can be made by mixing silica beads with the ultra high performance concrete (UHPC) composition of the fireproof plate and compression element to block radiant heat, thereby increasing the thermal insulation and at the same time increasing the compressive strength. It has a useful effect.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical spirit of the present invention together with the detailed description of the present invention, so the present invention is limited to the matters described in the accompanying drawings It should not be construed as being limited.
1 is a perspective view of a thermal cross-blocking material for internal insulation comprising upper and lower tension muscles of the present invention.
2 is a plan cross-sectional view of the thermal cross-blocking material for internal insulation comprising upper and lower tension muscles of the present invention.
3 is a perspective view showing various embodiments of the tension muscle and shear element of the present invention.
4 is a cross-sectional view taken along lines AA and BB of FIG. 2 .
5 and 6 are cross-sectional views illustrating an embodiment in which the heat cross-blocking material for internal insulation including upper and lower tension muscles of the present invention is constructed.

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention, and the present invention is not limited thereto.

Hereinafter, the technical configuration of the present invention will be described in detail according to a preferred embodiment.

1 is a perspective view of a thermal cross-blocking material for internal insulation comprising upper and lower tension muscles of the present invention, FIG. 2 is a plan cross-sectional view of a thermal cross-blocking material for internal insulation including upper and lower tension muscles of the present invention, and FIGS. 5 and 6 are the present invention It is a cross-sectional view showing an embodiment in which a thermal cross-blocking material for internal insulation comprising upper and lower tension muscles is constructed.

As shown in Figs. 1, 5, and 6, the thermal cross-blocking material for internal insulation comprising the upper and lower tension muscles of the present invention is installed at the joint of the outer wall 2 and the slab 3 to block the thermal bridge.

As shown in FIGS. 1 and 2, the thermal cross-blocking material for internal insulation including the upper and lower tension muscles of the present invention includes a thermal insulation element 10 made of a thermal insulation material in a rectangular parallelepiped shape of a predetermined size, and the thermal insulation element 10 in the width direction. A shearing element 30 built into the thermal insulation element 10 and a shearing element 30 which is integrally manufactured with the tension muscle 20 by connecting the upper and lower tension muscles 20 and the tension muscle 20 which is formed through the It is made to include a fireproof plate 40 configured on the upper and lower surfaces, respectively.

The heat insulating element 10 is made of various known heat insulating materials such as EPS in a rectangular parallelepiped shape of a certain size. is formed so that the corresponding concave portion 12 is formed, so that the protrusion 11 and the concave portion 12 of the adjacent heat insulating element 10 when successively installing the internal insulation heat-blocking material comprising the upper and lower tension muscles of the present invention It is interlocked so that it is not only easy to install, but also can be prevented from being separated by an external force.

A pair of tension muscles 20 are equally spaced or unequal to the heat insulating element 10 so that the upper and lower portions of the insulating element 10 are penetrated in the width direction, respectively, so that both ends protrude to the outside of the insulating element 10 by a predetermined length. Make sure to install multiple at intervals.

In particular, in the present invention, by configuring the tensile reinforcing bars 20 at the upper and lower portions, respectively, the external force acting is reduced by half to the upper and lower reinforcing bars compared to the existing product in which the tensile reinforcing bars are disposed only at the upper portion, so that a greater external force is obtained. It is structurally safe even when a large force acts or instantaneously occurs, and can resist both ±moment and ±shear force. It has a structure that ensures seismic performance.

Such a tension muscle 20 is formed by penetrating the heat insulating element 10 in the width direction. At this time, the shear element is connected to the inside of the heat insulating element 10 to connect a pair of tension muscles 20 located at the upper and lower parts of the insulating element 10 . (30) is configured.

3 is a perspective view illustrating various embodiments of a tension muscle and a shear element according to the present invention, and FIG. 4 is a cross-sectional view taken along lines A-A and B-B of FIG. 2 .

The shear element 30 may have various shapes connecting the pair of upper and lower tension muscles 20, and in particular, as shown in FIGS. 3A and 3B, the shear element 30 includes the upper and lower tension muscles. While connecting the muscles 20, the vertical muscles 310, which are configured to be spaced apart from each other, and the shear auxiliary muscles 320 that connect them to each other between the vertical muscles 310, or as in FIG. 3c, The upper and lower tension muscles 20 are intersected at the center to form an X-shape, so that the shear element 30 is integrated with the tension muscle 20 so that the shear element 30 and the tension muscle 20 are connected in the same vertical plane. It is possible to improve the thermal insulation performance by minimizing the amount of reinforcing bars passing through the thermal insulation element 10 while satisfying the required structural performance in response to both compressive and tensile forces acting alternately by placing it on the top.

The residual element 30 and the tension muscle 20 may be integrated by various known methods such as welding.

In addition, in the present invention, a horizontal buried muscle 210 configured in the horizontal direction at one end of the tension muscle 20 and embedded in the slab 2 , and an upper and lower tension muscle 20 are installed at the other end of the tension muscle 20 . A reinforcing bar 220 that is configured to be connected and embedded in the wall 3 is configured, and as shown in FIGS. 5 and 6, the reinforcing bars 21 that are reinforced in structures such as the slab 3 and the wall 2 It can be connected to (31) so that it is easy to set up, and additional reinforcing bars are not required during construction, so it is economical and can improve the convenience of construction.

Since the anchorage embedding muscle 220 is embedded in the wall 2, as in FIGS. 3a, 3c and 5, it is formed in a ⊃ shape so that both ends are connected to the upper and lower tension muscles 20, respectively. This can be facilitated, and as shown in FIGS. 3B and 6 , the anchoring root 220 is divided into a ⊃-shaped central part cut, and consists of an upper anchoring muscle 221 and a lower anchoring muscle 222, The outer end of the upper anchorage reinforcing bar 221 is configured to extend a certain length vertically downward, so that it can be connected to the reinforcing bar 21 reinforced on the wall 2 so that it is easy to fix and no additional reinforcing bars are required during construction.

At this time, the tension muscle 20, the shear element 30, the horizontal buried muscle 210, and the anchored embedded muscle 220 may be integrally manufactured as shown in FIG. 3, and the tension muscle 20 and the shear element (30), the horizontal embedding muscle 210 and the anchoring embedded muscle 220 may be made of the same material or optionally different materials. In particular, the tension muscle 20 is made of stainless steel, the horizontal embedding muscle 210, The anchorage buried reinforcing bar 220 is formed of reinforcing bars made of iron, and the shear element 30 may be made of stainless steel or reinforcing bars.

The horizontal embedding muscle 210 and the anchoring muscle 220 are made of the same material, and the horizontal embedding muscle 210 and the anchoring embedded muscle 220 and the tensioning muscle 20 are made of different materials. It can increase the blocking effect and safety at the same time.

At this time, the material of the horizontal buried reinforcing bar 210 and the anchoring buried reinforcing bar 220 may be made of reinforcing bar, and the material of the tension reinforcing bar 20 and the shear element 30 is preferably stainless steel.

However, even if the material of the shear element 30 is reinforcing bars, the thermal cross-blocking effect can be maintained as it is, and . By installing a tensile reinforcing bar 20 made of stainless steel, which has significantly lower thermal conductivity than reinforcing bars, through the heat insulating element 10 and connecting them with reinforcing bars provided in the slab, the thermal bridge phenomenon is blocked and reduced, and at the same time, it is installed in the inner upper and lower parts of the heat insulating element 10 The shear force can be strengthened by providing the shear element 30 in the tension muscle 20 .

The fire-resistant plate 40 is configured to have a predetermined thickness on the upper and lower surfaces of the insulating element 10, respectively. In particular, such a fire-resistant plate 40 is made of ultra high performance concrete (UHPC, ultra high performance concrete). Thus, while strengthening the structural performance, it is possible to block fire and to protect the insulating element 10 from physical impact.

In the present invention, the compression element 50 made of ultra high performance concrete (UHPC, ultra high performance concrete) is selectively used between the tension muscle 20 and the tension muscle 20 of the insulation element 10, the insulation element 10 is disposed in the width direction of the insulated element 10 and the lower surface of the compression element 50 is positioned on the lower surface of the heat insulating element 10, so that the thermal insulation performance is improved by the internal heat insulating material comprising the upper and lower tension muscles of the present invention. At the same time, it is possible to increase the structural performance.

Since the tension muscle 20 and the shear element 30 are on the same vertical line, the compression element 50 is configured or optional, respectively, between the tension muscle 20 and the tension muscle 20 of the insulating element 10 . By configuring the compression element 50 to be spaced apart from the tension muscle 20 and the shear element 30 by a certain distance, workability can be improved.

Such a compression element 50 may have various shapes, and all surfaces except the lower surface are formed in a curved shape, so that the cross section and volume of the compression element are designed to be minimized within the condition of structurally and safely resisting the compressive force. In particular, as shown in FIG. 1, the curved end of the compression element 50 is configured to protrude from both ends of the heat insulating element 10 in the width direction, so that the protruding portion transmits the compressive force. Since the force is evenly spread after the concentrated stress is generated on the surface, the shape of both surfaces where the stress is concentrated can be optimized.

In the present invention, the fireproof plate 40 and the compression element 50 are made of ultra high performance concrete (UHPC) to enhance structural performance. Although UHPC with excellent strength is used, it is difficult to satisfy both thermal insulation and structural performance in the past because of poor thermal insulation properties.

Therefore, in the present invention, the fireproof plate 40 and the compression element 50 are made by mixing silica beads with an ultra high performance concrete (UHPC) composition to block radiant heat, thereby increasing the thermal insulation properties and at the same time. Compressive strength can be increased.

To this end, based on 100 parts by weight of cement, 24 to 26 parts by weight of silica fume, 20 to 60 parts by weight of fine aggregate, and 30 to 150 parts by weight of silica beads are mixed with water so that the water-cement ratio is 28% (cement weight ratio). make it happen

In the ultra-high performance concrete composition, cement and silica fume are used as binders. When silica fume is mixed in less than 24 parts by weight, the workability deteriorates and when it is mixed in excess of 26 parts by weight, the amount of water required to secure fluidity increases and the proportion of voids remaining after final hardening also increases. Based on 100 parts by weight, it is preferable to mix 24 to 26 parts by weight of silica fume.

In the present invention, coarse aggregate is not included, only fine aggregate is included, and fine aggregate is inexpensive and hard among mineral materials, so any conventionally generally used can be used.

Although these fine aggregates do not chemically react with water, they occupy a portion of the concrete volume, and the aggregate itself contributes to hardening the concrete.

In particular, in the present invention, it is possible to use silica sand (size of about 0.8 to 0.2 mm) as a fine aggregate.

When the fine aggregate is mixed with less than 20 parts by weight based on 100 parts by weight of cement, the strength is lowered, and when mixed with more than 60 parts by weight, there is a high possibility of bonding such as cracks, so 20 to 60 parts by weight based on 100 parts by weight of cement Mixing is preferred.

Silica beads are made in a small round shape of slica gel containing SiO ₂ as a main component.

The silica beads are dispersed to increase the compressive force as the packing density is increased. When the amount is less than 30 parts by weight based on 100 parts by weight of cement, it is difficult to lower the thermal conductivity, and when mixed with more than 150 parts by weight, the strength is lowered. Therefore, it is preferable to mix 30 to 150 parts by weight of silica beads with respect to 100 parts by weight of cement.

In particular, in the present invention, the structural shape and size of the added silica bead is very important because it is necessary to simultaneously satisfy thermal insulation and increase in compressive strength.

Therefore, in the present invention, the silica beads can be formed in a spherical shape, which is a structure capable of uniformly distributing the compressive force, and the compressive force can be increased by dispersing with the added silica sand to increase the packing density.

Such spherical silica beads may have a size of 1 to 10 μm, preferably a diameter of 4 to 7 μm. When it is less than 4 μm or exceeds 7 μm, the packing density is lowered and the compressive strength is lowered, so the spherical silica beads are preferably formed in a size of 4 to 7 μm.

<Experimental Example 1>

As shown in Table 1, in the comparative example, silicon beads were not mixed, and in all examples, silica beads were mixed in the range of 30 to 150 parts by weight with respect to 100 parts by weight of cement, and in all of the comparative examples and examples, 100 parts by weight of cement Based on parts, 3.4 parts by weight of a fluidizing agent was additionally mixed, and in both Comparative Examples and Examples, the weight ratio of water to cement was fixed at 28%, and compressive strength and thermal conductivity tests were performed on the compositions of Comparative Examples and Examples.

Unit: wt% division W/C C sci-fi SS SP SB AG comparative example 28.0 37.0 9.3 40.7 13.0 - - Example 1 28.0 46.5 11.6 11.6 - 30.2 - Example 2 28.0 45.7 11.4 25.1 - 16.0 1.8 Example 3 28.0 45.7 11.4 25.1 - 29.7 1.8 Example 4 28.0 37.0 9.3 - - 53.7 -

In the mixing ratio of Table 1, in both Comparative Examples and Examples, 3.4 parts by weight of a fluidizing agent was further mixed based on 100 parts by weight of cement.

where, W/C: water-cement ratio

C : Cement , SF : silica fume , SS : silica sand

SP : silica powder, SB : silica bead , AG : aerogel

* The above figures represent the addition ratio of each admixture to the total admixture.

* About 1 part by weight of steel fiber can be added based on the weight of cement. In this case, the fiber length is about 10 to 14 mm.

In both Comparative Examples and Examples, 3.4 parts by weight of a fluidizing agent was additionally mixed based on 100 parts by weight of cement. 3 to 4 parts by weight of the fluidizing agent may be additionally mixed based on 100 parts by weight of cement.

The fluidizing agent is added to improve the mixing property, and various known fluidizing agents can be used. When the amount is less than 3 parts by weight, the fluidity enhancing effect is weak, so a large amount of mixed water is used, causing a decrease in compressive strength, 4 When used in excess of parts by weight, it is preferable to additionally mix 3 to 4 parts by weight based on 100 parts by weight of cement because it not only has no great effect on improving fluidity but also causes material separation.

As shown in Table 1, in the comparative example, silicon beads were not mixed, and in all examples, silica beads were mixed in the range of 30 to 150 parts by weight with respect to 100 parts by weight of cement, The weight ratio was fixed at 28%.

As shown in Table 1, compressive strength and thermal conductivity were measured for the compositions of Comparative Examples and Examples, and the results are shown in Table 2.

division Compressive strength (MPa) Thermal conductivity (W/m.K) comparative example 186.0 1.39 Example 1 187.29 0.89 Example 2 107.39 0.79 Example 3 110.59 0.64 Example 4 208.96 0.77

As shown in Table 2, in the comparative example in which silica beads were not mixed, the compressive strength was 186.0 MPa and the thermal conductivity was 1.39, and it can be seen that all the examples in which silica beads were mixed showed lower thermal conductivity than the comparative example. In Examples 2 and 3, the compressive strength was slightly lower than that of Comparative Examples, but, unlike Examples 2 and 3, Example 1 in which the mixing ratio of silica sand was reduced exhibited substantially the same compressive strength as that of Comparative Example, The compressive strength in Example 4, in which the mixing ratio of silica beads was increased except for silica sand, was 208.96 MPa, which was significantly higher than that of Comparative Example.

Therefore, it can be seen that by mixing silica beads to block radiant heat, the thermal insulation properties are increased while at the same time the compressive strength is increased, so that the thermal insulation performance and the structural performance, including the thermal insulation material, can be satisfied at the same time.

7 and 8, the insulation structure 1 of the present invention has discontinuous insulation such as the junction between the wall 2 and the roof slab 3 or the junction between the wall 2 and the floor slab 3, as shown in FIGS. 7 and 8. The insulator 5 and the insulation element 10 of the installed building are continuously constructed on the pet site, so that the insulation of the building is constructed without interruption, thereby performing two roles of the structure and the heat insulator.

As described above, the heat cross-blocking material for internal insulation comprising the upper and lower tensile muscles of the present invention can resist both ± moment and ± shear force by constructing tensile muscles penetrating the insulating element at the upper and lower portions of the insulating element, respectively, so that the tensile force in the event of an earthquake Seismic performance can be secured with a structure that can withstand compression and tension at the same time even when compressive and compressive forces are alternately applied to tensile-shear elements. Horizontal reinforcing reinforcing bars and anchoring reinforcing bars are configured on one side and the other end of the tension reinforcing bar, respectively, so that they can be connected to reinforcing bars in structures such as slabs and walls. By mixing silica beads with a fireproof plate and compression element in an ultra high performance concrete (UHPC) composition to block radiant heat, it is possible to increase the thermal insulation properties and at the same time increase the compressive strength. It has a very useful effect.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art can make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by the invention of such variations and modifications, but only by the claims appended hereto.

10: insulation element
20: tension muscle
210: horizontal embedding muscle
220: sessile reclaimed root
30: shear element
40: fireproof plate
50: compression element

Claims (13)

In the heat cross-blocking material for internal insulation installed at the joint of the outer wall (2) and the slab (3),
a heat insulating element 10 made of a heat insulating material in a rectangular parallelepiped shape of a certain size;
A pair is formed so as to penetrate the upper and lower portions of the heat insulating element 10 in the width direction, respectively, so that both ends protrude to the outside of the heat insulating element 10 by a predetermined length, and a plurality of the heat insulating elements 10 are provided at equal or unequal intervals. a tension muscle 20 to be installed;
a horizontal embedding muscle 210 configured in the horizontal direction at one end of the tension muscle 20 and embedded in the slab 2;
a fixation embedding muscle 220 configured to connect the upper and lower tension muscles 20 to the other end of the tension muscle 20 and embedded in the wall 3;
a shear element 30 built into the heat insulating element 10 and manufactured integrally with the tension muscle 20 by connecting a pair of tension muscles 20 located at the upper and lower portions;
A fireproof plate 40 composed of a predetermined thickness on the upper surface and the lower surface of the insulating element 10, respectively, and made of a fireproof material or ultra high performance concrete (UHPC, ultra high performance concrete); includes;
Based on 100 parts by weight of cement, 24 to 26 parts by weight of silica fume; 20-60 parts by weight of fine aggregate; 30 to 150 parts by weight of silica beads; And 3 to 4 parts by weight of a fluidizing agent; Compression element 50 made of ultra high performance concrete (UHPC, ultra high performance concrete) made by mixing with water so that the water-cement ratio is 28% (cement weight ratio) is an insulating element (10) A thermal cross-blocking material for internal insulation comprising upper and lower tensile muscles, characterized in that the upper and lower tensile muscles are selectively disposed between the tensile muscles (20) and the tensile muscles (20) in the width direction of the heat insulating element (10). The method according to claim 1,
One end in the longitudinal direction of the heat insulating element 10 has a central portion protruding to form a protrusion 11, and a concave portion 12 corresponding thereto is formed at the other end. barrier material. The method according to claim 1,
The shear element 30 connects the upper and lower tension muscles 20 while facing each other and spaced apart from each other by a vertical muscle 310 and,
Between the vertical muscles (310), a thermal cross-blocking material for internal insulation composed of upper and lower tension muscles, characterized in that it consists of shear auxiliary muscles (320) connecting them to each other. The method according to claim 1,
The shear element 30 is a thermal cross-blocking material for internal insulation comprising upper and lower tensile muscles, characterized in that the upper and lower tensile muscles 20 are intersected at the central portion to connect them in an X shape. The method according to claim 1,
The tension reinforcing bar 20 is made of stainless steel, the horizontal buried reinforcing bars 210 and the anchored buried reinforcing bars 220 are formed of reinforcing bars, and the shear element 30 is made of stainless steel or reinforcing bars. Thermal cross-cutting material for heat insulation. The method according to claim 1,
The anchorage buried muscle 220 is formed in a ⊃ shape, and both ends are respectively connected to the upper and lower tensile muscles 20, respectively. 7. The method of claim 6,
The central part of the anchorage buried muscle 220 is cut,
A heat cross-blocking material for internal insulation composed of an upper anchorage muscle 221 and a lower anchorage muscle 222, and the outer end of the upper anchorage muscle 221 is configured to extend a predetermined length vertically downward. The method according to claim 1,
A thermal barrier material for internal insulation comprising upper and lower tension muscles, characterized in that the lower surface of the compression element (50) is positioned on the lower surface of the insulating element (10). 9. The method of claim 8,
The compression element 50 allows all surfaces except the lower surface to be formed in a curve,
A heat cross-blocking material for internal insulation comprising upper and lower tension muscles, characterized in that the curved end of the compression element (50) protrudes from both ends of the heat insulating element (10) in the width direction. The method according to claim 1,
Fireproof plate 40 made of ultra high performance concrete (UHPC, ultra high performance concrete),
Based on 100 parts by weight of cement,
Silica fume 24-26 parts by weight;
20-60 parts by weight of fine aggregate;
30 to 150 parts by weight of silica beads; and
3 to 4 parts by weight of a fluidizing agent; and a heat cross-blocking material for internal insulation comprising upper and lower tension muscles, characterized in that it is mixed with water so that the water-cement ratio is 28% (cement weight ratio). 11. The method of claim 1 or 10,
Silica bead is a heat cross-blocking material for internal insulation composed of upper and lower tension muscles, characterized in that it has a spherical shape. 12. The method of claim 11,
Silica bead is a thermal cross-blocking material for internal insulation composed of upper and lower tension muscles, characterized in that the size is 4-7㎛. 11. The method of claim 1 or 10,
A heat cross-blocking material for internal insulation composed of upper and lower tension muscles, characterized in that the fine aggregate is silica sand.

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