KR102037088B1 - Structure Pannel With Insulation Function Using Structure and Insulation Function Unit - Google Patents

Abstract

The present invention relates to a thermal insulation integrated structure structural panel using a structural reinforcing member, and more specifically, to integrate a structural panel formed of a core material and a low specific gravity ALC produced by mixing the slag which is a by-product generated in the steelmaking process with cement and The present invention relates to a thermal insulation function integrated structural panel using a structural reinforcing member that reinforces a structural reinforcing member to reinforce a heat insulating performance while expressing strength performance.
One preferred embodiment of the present invention is based on 100 parts by weight of starting material consisting of 45 ~ 50wt% Portland cement (OPC), 10wt% quicklime, 30 ~ 35wt% slag, 10wt% anhydrous gypsum, 0.6 parts by weight of aluminum powder, Pore 0.06 parts by weight of Stabilizer to form a blend, 130 parts by weight of mixed water based on 100 parts by weight of the starting material is mixed with the blend to prepare a slurry, curing and drying the core material formed into a plate shape of a predetermined size, and ALC A panel body formed of inner and outer structural panels formed to be bonded to both sides of the core material; A fixing member connecting member configured to penetrate the core material in the thickness direction at the position of the fixing hole of the panel main body 10, an inner fixing member positioned in the perforated fixing hole of the inner structural structural panel and fixed by filling mortar, and the outer structural structural member Consists of an outer fixing unit located in the perforated fixing hole of the panel is fixed by the filling mortar, one end of the anchorage connecting member is connected to the inner fixing unit and the other end is connected to the outer fixing unit to bind the inner and outer structural panels It comprises a; structural reinforcing member configured to include.

Description

Structural panel integrated with insulation function using structural reinforcing member {Structure Pannel With Insulation Function Using Structure and Insulation Function Unit}

The present invention relates to a thermal insulation integrated structure structural panel using a structural reinforcing member, and more specifically, to integrate a structural panel formed of a core material and a low specific gravity ALC produced by mixing the slag which is a by-product generated in the steelmaking process with cement and The present invention relates to a thermal insulation function integrated structural panel using a structural reinforcing member that reinforces a structural reinforcing member to reinforce a heat insulating performance while expressing strength performance.

In general, the panel body is part of the building's outer wall and must be exposed to the external environment to provide resistance to wind pressure and insulation to block heat flow. Exterior wall panels are known to have such insulation and resistance. The outer wall panel uses the insulation made of styrofoam or foam concrete having insulation between the inner and outer panels. In this case, the insulation is relatively weak in strength and should be considered so as not to be resisted during the integral behavior of the inner and outer panels. do.

Background art of the present invention is Republic of Korea Patent Registration No. 0319645 "sandwich type concrete panel". It is provided so that both ends of the iron core embedded therein is exposed to the outside, the surface is a core member for projecting a plurality of shea connector for connection; It is composed of a covering member bonded to the sheath connector and attached to the surface of the core member, and has an advantage of easy connection between the panel, the panel, and the panel and other structures. In the case of the foam member, there was a problem in that the sheer connector could not be used and bonding with the coating member was difficult.

Republic of Korea Patent Registration No. 0319645 "Sandwich type concrete panel"

The present invention is to solve the above problems, by integrating the core panel and the structural panel formed of ALC having a low specific gravity and reinforced with structural reinforcing member to enhance the thermal insulation performance, but also to exhibit excellent strength performance, existing external insulation It is possible to improve the load resistance and lack of adhesion of the exterior finish, which is a limitation of the external finish, and to secure proper resistance against anticipated gravity and wind loads. It is intended to provide a thermal insulation function integrated structural panel using structural reinforcing members that can be secured by the initial strength enhancement and economical by using low-cost raw materials by mixing with cement.

The present invention is usually based on 100 parts by weight of the starting material consisting of 45 ~ 50wt% Portland cement (OPC), 10wt% quicklime, 30 ~ 35wt% slag, 10wt% anhydrous gypsum, 0.6 parts by weight of aluminum powder, 0.06 parts by weight of Pore Stabilizer To form a blend, and mix 130 parts by weight of the mixed water with the blend based on 100 parts by weight of the starting material to prepare a slurry, curing and drying the core material, which is formed in a plate shape of a predetermined size, and formed by ALC, and both sides of the core material. A panel body comprising an inner and outer structural panel bonded to the panel; A fixing member connecting member configured to penetrate the core material in the thickness direction at the position of the fixing hole of the panel main body 10, an inner fixing member positioned in the perforated fixing hole of the inner structural structural panel and fixed by filling mortar, and the outer structural structural member Consists of an outer fixing unit located in the perforated fixing hole of the panel is fixed by the filling mortar, one end of the anchorage connecting member is connected to the inner fixing unit and the other end is connected to the outer fixing unit to bind the inner and outer structural panels The structural reinforcing member configured to include; to provide a thermal insulation function integrated structural panel using a structural reinforcing member comprising a.

In addition, the inner and outer fixing holes 202, 204, the disk having a diameter larger than the inlet side diameter of the fixing hole; A coupling bolt provided on the front surface of the disc; It consists of a plurality of fixing pins protruding by a predetermined length on the back of the disc; The anchorage connecting member has a length corresponding to the width of the core material to provide a heat insulation function integrated structural panel using a structural reinforcing member, characterized in that it is manufactured in the form of a round bar having a screw hole for fastening the coupling bolts at both ends.

In addition, the core member is to provide a thermal insulation function integrated structural panel using a structural reinforcing member, characterized in that the protective tube made of a synthetic resin material or a soft material is inserted into the anchorage connection member is further installed.

In addition, the core material is a heat insulating function using a structural reinforcing member, characterized in that a plurality of shear grooves of a predetermined shape is formed in the entire width direction at regular intervals on both sides, and shear projections corresponding to the shear grooves are formed on the inner and outer structural panels. An integral structural panel is provided.

In addition, the shear groove is made of a trapezoidal cross-sectional shape of the narrow cross section of the outer side and the inner cross section, the shear projection provides a heat insulation function integrated structural panel using a structural reinforcing member, characterized in that made of a trapezoidal cross-sectional shape of the corresponding shape. I would like to.

In addition, the slag in the core is 24.3 wt% SiO ₂ , 40.9 wt% CaO, 12.8 wt% Al ₂ O ₃ , 0.50 wt% Fe ₂ O ₃ , 4.0 wt% SO ₃ , 6.69 wt% MgO An object of the present invention is to provide an integrated structural panel for thermal insulation using structural reinforcing members.

In addition, based on 100 parts by weight of the starting material in the core material, 50.5 parts by weight of SiO ₂ , 29.7 parts by weight of CaO and 1.80 parts by weight of SO ₃ to provide a thermal insulation function integrated structural panel using a structural reinforcing member. I would like to.

Insulation function integrated structural panel using the structural reinforcing member of the present invention integrates the structural panel formed of the core material and ALC having a low specific gravity and reinforces it with the structural reinforcing member so as to enhance the thermal insulation performance while excellent strength performance, and other existing It is possible to improve the problem of lack of load resistance and deterioration of adhesion of exterior finish, which is a limitation of insulation, and to secure proper resistance against anticipated gravity and wind loads, and slag, which is a by-product of the core material in the steelmaking process. By mixing with cement has a very useful effect to secure construction properties through the initial strength enhancement and economics through the use of low-cost raw materials.

The following drawings, which are attached in this specification, illustrate the preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention. It should not be construed as limited.
1 is a perspective view and an exploded perspective view of a heat insulation function integrated structural panel using the structural reinforcing member of the present invention.
2 is a cross-sectional view taken along line AA of FIG. 1A.
Figure 3 is a graph showing the compressive strength of the slag cement replacement content.
Figure 4a is an exploded perspective view of one embodiment of a structural reinforcing member used in the present invention.
4B is a front view of FIG. 4A.
5a to 5d is a manufacturing flow chart of a heat insulation function integrated structural panel using a structural reinforcing member according to the present invention.
6A and 6B are partially exploded perspective and synthetic state diagrams of a heat insulation function integrated structural panel using structural reinforcing members applied to the present invention.

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

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

1 is a perspective view and an exploded perspective view of a heat insulating function integrated structural panel using a structural reinforcing member of the present invention, Figure 2 is a cross-sectional view taken along the line A-A of FIG.

Insulation function integrated structural panel using the structural reinforcing member of the present invention as the inner and outer structural panels 12, 14 bonded to both sides of the core member 16 and the core member 16 of a predetermined size and formed of ALC It consists of a panel body 10 made of, and one or more through-type structural reinforcing member 20 is formed so as to penetrate through the central portion of the panel body 10.

In the present invention, the core material 16 is made of a slag mixed inorganic thermal insulation material by mixing the slag which is a by-product generated in the steelmaking process with cement, thereby improving economic efficiency, improving insulation performance, and strength. Ensure good performance.

Inorganic insulation materials used as core materials of conventional structural panels are powder raw materials such as cement, anhydrous gypsum and quicklime as main raw materials, and powder powder and mixed water are mixed to prepare a slurry, and then aluminum powder is mixed. Aluminum powder is used as a blowing agent in calcium silicate-based inorganic insulation materials. The slurry is foamed by the hydration reaction of the alkaline component. At this time, the aluminum powder is transformed into a hydrate (Al (OH) ₃ ), and hydrogen gas is generated by reaction with calcium hydroxide (Ca (OH ₂ ) generated from quicklime or cement.

2Al + 3Ca (OH) ₂ + 6H ₂ O 3CaO + Al ₂ O ₃ + 6H ₂ O + 3H ₂

Or 2Al + Ca (OH) ₂ + 6H ₂ O Ca (Al (OH) ₄ ) 2 + 3H ₂ + 3H ₂ (Equation 1)

Slurry foaming due to hydrogen gas is cured at the same time as the foaming with the heat of hydration generated in the hydration reaction of the powder raw material. When the cured foam is demoulded through curing for 24 hours, the calcium silicate-based inorganic insulation material is completed.

In particular, the core material 16 used in the present invention is usually based on 100 parts by weight of the starting material consisting of 45 ~ 50wt% Portland cement (OPC), 10wt% quicklime, 30 ~ 35wt% slag, 10wt% anhydrous gypsum, aluminum powder 0.6 Part by weight, 0.06 parts by weight of Pore Stabilizer is mixed to form a mixture, 130 parts by weight of mixed water based on 100 parts by weight of the starting material is mixed with the formulation to prepare a slurry, curing and drying to form a plate shape of a predetermined size.

Departure Raw Material Preparation

For the production of the core material 16 used in the heat insulation function-integrated structural panel using the structural reinforcing member of the present invention, as a starting material for the powder raw material was configured as shown in Table 1.

% SiO ₂ Al ₂ O ₃ Fe ₂ O ₃ CaO MgO SO ₃ Powder level (g / cm ² ) OPC 11.8 5.86 2.83 59.7 4.02 3.55 8,600 Slag 24.3 12.8 0.50 40.9 6.69 4.02 6,300 Anhydrous gypsum 1.7 0.4 0.1 39.3 - 53.1 2,800 Lime stone 1.6 0.3 0.4 90.3 0.8 0.7 4,100

Table 1 is a component analysis table of the starting material used in the present invention, the remainder of the component table is other impurities and moisture.

OPC of the starting material used in the present invention is used to adjust the powder degree to 3,600 g / cm ² by grinding orient type 1 ordinary cement, Slag is adjusted to 6,300 g / cm ² slag used in the manufacture of slag cement in OO ready-mixed concrete And crushed. Anhydrous gypsum from Chemius Korea and quicklime from Baekwang Materials were used. In addition, Pore Stabilizer was used with Wacker PDMS, and AL powder, blowing agent, was used with Y250 from Alco Engineering.

No. 8,600
OPC Slag Lime stone Anhydrous gypsum Water Pore
Stabilizer Al
Powder One 45 35 10 10 130 0.06 0.6 2 50 30 3 55 25 4 60 20 5 65 15 6 70 10

Table 2 shows the mixing conditions of the starting raw materials used in the present invention.

Calcium silicate-based inorganic insulation material used as the core material 16 is demolished through the curing process after pouring the slurryed starting material in the mold. Rapid demolding of the slurry foamed to a hardness suitable for demolding during demolding is also important. Since the slag affects the expression of long-term strength than the initial strength, the slag powder was ground to 6,300 g / cm ² to promote the reaction through the grinding.

Generally, the three powders of the slurry used have a strength of 3,200 g / cm ² when incorporated into mortar after 15 days of curing. In the case of slag-incorporated calcium silicate-based inorganic insulation materials, the hardness of the slurry was found to be twice as high as that of conventional calcium silicate-based inorganic insulation materials. (Slurry mixing 20kgf, existing specimen 10kgf-using ALC slurry hardness tester) After demoulding, measure the specific gravity of compressive strength after curing the specimen under curing conditions of 35 ~ 30 ℃ and relative humidity of 30 ~ 75% for 3 days, 7 days and 15 days. It was.

Calcium silicate that partially replaces slag instead of OPC, compared to OPC, quicklime, and gypsum as a raw material of OPC, quicklime, and gypsum, which are the main raw materials of the core material made of the calcium silicate-based insulating material using slag according to the present invention. In the case of the inorganic insulation material, the following experiments are conducted to find out the characteristics of specific gravity, thermal conductivity, and compressive strength, and to obtain the optimum ratio of slag.

Basic Specimen Fabrication

The mixing experiment of Table 2 is an experiment to replace the OPC slag and a partial content, the goal is to check the strength change according to the replacement amount, and to maintain the thermal conductivity and specific gravity 0.045 W / mK, 0.13 g / cm ³ .

Thermal conductivity measurement

Thermal conductivity (plate heat flow method, HC-074, EKO, Japan) The measurement was performed at 35 ° C. on the upper plate and 15 ° C. on the lower plate according to KS L 9016. The unit of thermal conductivity is expressed in W / mK as a joule of the amount of heat flowing for 1 second through 1m ² of the plate when there is a temperature difference of 1K on both sides having a thickness of 1m. The thermal conductivity specimens were 20 cm x 20 cm x 3 cm.

Specific gravity measurement

The specimen under conditions suitable for the measurement by KS F 2701 was dried at 100 ° C. for 24 hours, and the volume and weight of the specimen were measured and expressed in units of g / cm ³ .

Compressive strength measurement

Compressive strength was measured at a loading rate of 9.8 N / sec using the WooJin Universal Testing Machine WJ-100S according to KS F 2701. The compressive strength was converted into MPa by the value obtained by dividing the load by the circular cross-sectional area (cm 2) of the test piece (kgf /). In order to measure the compressive strength, a specimen dried at 100 or more for 24 hours was used.

Figure 3 is a graph showing the compressive strength of the slag cement replacement content blended under the conditions of Table 2.

3a is a result of measurement after curing, as shown in FIG. 3a, the compressive strength and specific gravity were measured according to KS F 2701. No. 1 to No. As the slag decreases according to the compounding condition of 6, the compressive strength tends to decrease.

With a specific gravity of less dry, depending on curing to cured air dry average 3 days 0.21g / cm ^3, 7 il 0.18g / cm ³ 15 il 0.15 g / cm ³ specific gravity jyeoteuna lowered, the compressive strength was confirmed a tendency increasing with the amount birthday , No. The highest compressive strength was found in 15 days at 50 wt% of ordinary portland cement (OPC) and 30 wt% of slag.

Figure 3b is a graph showing the compressive strength of the slag cement replacement content measured after drying at 80 ℃ 24hr.

3a was prepared and cured in the same manner as in FIG. 3a, but the compressive strength was measured by drying the same specific gravity according to the curing period at 0.13 g / cm ³ . Keeping in mind the cracks caused by drying shrinkage during drying, raised 10 ℃ every 30 hours from 30 ℃ to 80 ℃ and dried at 80 ℃ for 24 hours. Specific gravity was lowered to 0.13 g / cm ³ , but cracks due to dry shrinkage were found on all specimens. The presence and the degree of cracks vary slightly from specimen to specimen, so the reproducibility of the compressive strength is poor. 1 Under the mixing conditions, 6 It was confirmed that the compressive strength was lowered according to the change in the mixing conditions. The 15-day compressive strength was found to be the highest at 45 wt% of ordinary portland cement (OPC) and 35 wt% of slag.

As a preferred embodiment of the core material consisting of a slag-incorporated inorganic insulating material according to the present invention, starting materials of Table 1, such as 8,600 g / cm ² OPC and 6,300 g / cm ² slag, are used.

Mixing conditions were prepared by mixing 100 parts by weight of OPC 50 wt%, slag 30 wt%, quicklime 10 wt%, anhydrous gypsum 10wt%, 130 parts by weight of mixed water and a power drill for 3 minutes to prepare a first slurry, Pore Stabilizer is mixed with 0.06 parts by weight of the powder, followed by secondary mixing. Finally, the mixture of 0.6 parts by weight of Al powder (relative to powder) and proceeding to tertiary mixing completes the slurry of the slag-incorporated calcium silicate-based inorganic insulation material.

The finished slurry is poured into a mold, and the Al powder is foamed and cured within 1 hour by maintaining a relative humidity of 25 to 30 ° C. and 60 to 75%. After curing in the manufacturing conditions for 24 hours, demoulded and used according to the intended use.

As shown in Figs. 1 and 2, the core 16 has a flat plate shape, and the inner and outer structural panels 12 and 14 of the flat plate shape are adhered to both sides.

Figure 4a is an exploded perspective view of an embodiment of a structural reinforcing member used in the present invention, Figure 4b is a front view of Figure 4a, Figures 5a to 5d is a production of a thermal insulation function integrated structural panel using a structural reinforcing member according to the present invention Flowchart.

The penetrating structural reinforcing member 20 is formed to penetrate the core 16 of the panel body 10 in the thickness direction to fix and couple to the structural panels 12 and 14 on both sides, and various known shapes and materials. It may be made of.

In particular, the through type structural reinforcing member 20 is located in the perforated fixing hole 12a of the inner structural structural panel 12, as shown in Figs. 4a and 4b and is fixed by the filling mortar 13 as shown in Fig. 5d. The inner fixing unit 202, the outer fixing unit 14a located in the perforated fixing hole 14a of the outer structural panel 14, and fixed by the filling mortar 15, and the hole of the core 16 ( 16a) is inserted into the fixing unit at the same time, one end is connected to the inner fixing unit 202 and the other end is connected to the outer fixing unit 204 to bond the inner and outer structural panels 12 and 14 to connect the fixing member (206) It can be configured to include.

The inner and outer fixing units 202 and 204 have the same configuration. The inner and outer fixing holes 202 and 204 include a disc 202a having a diameter larger than the inlet diameter of the fixing hole 12a, a coupling bolt 202b provided on the front surface of the disc 202a, and a rear surface of the disc 202a. Is composed of a plurality of fixing pins (202c) protruding by a predetermined length.

The anchorage connector 206 has a length corresponding to the thickness of the core material 16 and is made and manufactured in the form of a round bar having a screw hole 206a to which the coupling bolt 202b is fastened at both ends.

Meanwhile, the core member 16 may further include a protective tube 17 made of a soft material such as a synthetic resin material or a sponge into which the anchorage connecting member 206 is inserted, as shown in FIG. 5D.

6A and 6B are partially exploded perspective and synthetic state diagrams of a heat insulation function integrated structural panel using structural reinforcing members applied to the present invention.

The fixing holes 12a and 14a formed in the inner and outer structural panels 12 and 14 may be any one of a straight hole as shown in FIG. 5A, a stepped hole as shown in FIG. 6A, and a tapered hole as shown in FIG. 6A. .

In addition, the inner and outer structural panels 12 and 14 may be configured to further install the reinforcement (121, 141) as shown in Figure 5a.

Referring to the manufacturing method of the panel body 10 configured as described above is as follows.

First, the inner structural structural panel 12 is disposed on the bottom surface 5 as shown in FIG. 5A. The bottom surface may be the bottom of the manufacturing plant.

Next, as shown in FIG. 5B, after pre-assembling the fixing unit connecting member 206 to the hole 16a of the core 16, the inner fixing unit 202 and the outer fixing unit 204 are fastened to both ends of the fixing unit connecting member 206, respectively. Release.

In this step, the protective tube 17 may be installed on the core 16, and then the fixing unit connecting member 206 may be installed on the protective tube 17.

Next, after filling the mortar 13 in the fixing hole 12a of the inner structural structural panel 12 as shown in FIG. 5C, the inner fixing unit 202 is embedded, and as shown in FIG. 5D, the outer structural structural panel 14 of FIG. The fixing hole 14a is placed in the outer fixing unit 204. At this time, the core material 16 is disposed between the inner structural structural panel 12 and the outer structural structural panel 14.

At this time, the adhesive 18 is applied to both sides of the core material 16 to bond the inner and outer structural panels 12 and 14.

Then, the mortar 15 is filled in the fixing hole 14a to fix the outer fixing unit 204 to the outer structural structural panel 14.

In the panel body 10 constructed and manufactured as described above, the inner structural structural panel 12 and the outer structural structural panel 14 are bound through the through-structure structural reinforcing member 20. At the same time, the core 16 is connected to the anchorage connector 206 of the through-structure reinforcing member 20 is fixedly disposed between the inner and outer structural panels 12 and 14.

Therefore, when the wind load acts on the outer structural structural panel 14 after construction, the panel main body 10 is transmitted to the inner structural structural panel 12 through the through-structure structural reinforcing member 20 to have a resistance to behave integrally. It can effectively resist the bending moment, and in particular, the inner and outer structural structural panels 12, 14 through the through-structure structural reinforcing member 20 can be integrated to act as a single member.

Insulation function integrated structural panel using the structural reinforcing member of the present invention as described above to integrate the structural panel formed of ALC with a low core material and low specific gravity and to reinforce with a structural reinforcing member to enhance the thermal insulation performance, but also excellent strength performance In addition, it is possible to improve the load resistance performance deficiency and adhesion deterioration problem of exterior finish, which is a limitation of the existing external insulation, and to secure proper resistance against anticipated gravity load and wind load. By using the slag as a by-product mixed with cement, there is a very useful effect to secure the constructability through the initial strength enhancement and economic efficiency through the use of low-cost raw materials.

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

10: panel body
12: inner structural panel
12a, 14a: fixing hole
13, 15: filling mortar
14: exterior structural panel
16: heartwood
17: protective tube
20: through structure reinforcing element
202: inner fixing unit
204: outer anchorage
206: anchorage connector

Claims (5)

Based on 100 parts by weight of starting materials consisting of 45 ~ 50wt% of portland cement (OPC), 10wt% of quicklime, 30 ~ 35wt% of slag, and 10wt% of anhydrous gypsum, 0.6 parts by weight of aluminum powder and 0.06 parts by weight of Pore Stabilizer are mixed. To create,
Based on 100 parts by weight of the starting material, 130 parts by weight of the mixed water is mixed with the blend to prepare a slurry, and to cure and dry the core material 16, which is formed in a plate shape having a predetermined size, and formed by ALC, and both sides of the core material 16. A panel body 10 made of inner and outer structural panels 12 and 14 bonded to and formed in a plurality of fixing holes 12a and 14a at the same position;
A fixing unit connecting member 206 formed by penetrating the core 16 in the thickness direction at the positions of the fixing holes 12a and 14a of the panel main body 10, and a perforated fixing hole of the inner structural structural panel 12 ( The inner fixing unit 202 located at 12a and fixed by the filling mortar 13 and the perforated fixing hole 14a of the outer structural panel 14, which is fixed by the filling mortar 15 It consists of an outer fixing unit 204, one end of the fixing unit connecting member 206 is connected to the inner fixing unit 202 and the other end is connected to the outer fixing unit 204 to bind the inner and outer structural panels 12, 14 Structural reinforcing member 20 configured to include a; heat insulation function integrated structural panel using a structural reinforcing member, characterized in that comprises a. The method according to claim 1,
The inner and outer fixing holes 202 and 204 include: a disk 202a having a diameter larger than the diameter of the inlet side of the fixing hole 12a; A coupling bolt 202b provided on the front surface of the disc; It consists of a plurality of fixing pins (202c) protruding by a predetermined length on the back of the disc (202a);
The anchorage connecting member 206 has a length corresponding to the width of the core material 16 and using a structural reinforcing member, characterized in that it is manufactured in the form of a round bar having a screw hole (206a) is fastened to both ends of the coupling bolt 202b Insulation structural panels. The method according to claim 1,
The core member 16 is a heat insulating function integrated structural panel using a structural reinforcing member, characterized in that the protective tube 17 made of a synthetic material or a soft material is inserted into the anchorage connecting member 206 is further installed. delete The method according to claim 1,
Based on 100 parts by weight of starting material from the core material 16,
Insulating function-integrated structural panel using a structural reinforcing member, characterized by further mixing 50.5 parts by weight of SiO ₂ , 29.7 parts by weight of CaO and 1.80 parts by weight of SO ₃ .

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