JP4480179B2 - Exterior wall structure of reinforced concrete exterior heat insulation building and method for constructing exterior wall - Google Patents

Description

  The present invention relates to a horizontal projecting object in which a balcony, a fence, an outer corridor, etc. (hereinafter referred to as a balcony in the present specification) are projected in a cantilever manner on a concrete outer wall from the outer wall of a reinforced concrete exterior heat insulating building, and a lower end. Vertical protrusions such as a balcony sleeve wall, a pouch sleeve wall, a decorative wall projecting from an outer wall (hereinafter referred to as a sleeve wall in the present specification), and applying a vertical stress to the foundation. The present invention relates to an outer wall structure that protrudes and is constructed by being thermally cut off from a concrete building frame, and a construction method thereof, and belongs to the technical field of architecture.

  Reinforced concrete exterior thermal insulation buildings cover the outer surface of the concrete frame with a thermal insulation layer, so that the thermal stress on the concrete frame is reduced by solar radiation, which can prevent cracks in the concrete frame, and the concrete frame is in contact with the air. Therefore, the neutralization of concrete can be suppressed, the corrosion of the steel bars can be suppressed, the durability of the building can be improved, the temperature environment in the building can be suitably maintained, and there is little condensation, It is rated as a high-performance durable building because it can suppress the occurrence of mold and mites and provide an excellent living environment in terms of health.

  However, in the case of an external insulation building in which a reinforced concrete balcony and a reinforced concrete sleeve wall protrude from the outer wall of the building, the reinforced concrete balcony floor slab and the reinforced concrete sleeve wall serve as a thermal bridge to the inside of the concrete building frame. In a reinforced concrete building, the suppression of thermal bridge action from the reinforced concrete balcony floor slab and the concrete frame from the reinforced concrete sleeve wall to the concrete frame is strongly desired. As the reduction means, the conventional example 1 shown in FIG. 11 is used, and as the thermal bridge reducing means of the balcony floor slab and the concrete sleeve wall, the conventional example 2 shown in FIGS. 12 (A) and 12 (B) and FIG. 12 (C). , (D), the conventional method 3 is proposed.

Conventional example 1 shown in FIG. 11 is cited as Conventional Example 1 in Patent Document 1, FIG. 11 (A) is a side view of a balcony, and FIG. 11 (B) is a supporting reinforcing bar unit to be used. FIG. 11C is a side view of the reinforcing bar unit.
As shown in FIGS. 11 (B) and 11 (C), the thermal bridge suppressing means in the balcony floor slab of the conventional example 1 (FIG. 11) is arranged in parallel with a large number of elongated connecting reinforcing bars on top of the heat insulating material. In addition, a reinforcing bar group for compression is arranged at the lower part of the heat insulating material, and the bearing plates at both ends of each compressing reinforcing bar are projected from the heat insulating material, and each lattice bar is arranged in the vicinity of the compressing reinforcing bar, As shown in FIG. 11 (A), a thermal bridge reduction unit in which both side extensions are extended in parallel between the long connecting rebars on the top of the heat insulating material is arranged in the form of a balcony and a housing frame. Then, the concrete balcony is protruded and supported from the dwelling housing by the rebar unit for thermal bridge reduction by concrete placement.

Moreover, FIG. 12 is the thermal bridge suppression means from a balcony floor slab and a concrete sleeve wall, and it was mentioned by nonpatent literature, Comprising: FIG. 12 (A) is a cross-sectional view of the prior art example 2, FIG. 12 (B) is a longitudinal sectional view of Conventional Example 2, FIG. 12 (C) is a transverse sectional view of Conventional Example 3, and FIG. 12 (D) is a longitudinal sectional view of Conventional Example 3.
That is, in the conventional example 2 of FIGS. 12A and 12B, the entire outer periphery of the balcony floor slab and the concrete sleeve wall protruding from the dwelling part is formed on the outer peripheral insulation composite panel, 12 (C) and 12 (D), the concrete outer wall is covered with the composite panel, but the balcony floor slab protruding from the concrete outer wall and The sleeve wall is not covered with heat insulation, and the heat insulation function is reinforced by sticking heat insulation on the inside of the concrete frame, that is, on the inside of the outer wall, where it receives the thermal bridge action from the balcony floor slab and the concrete sleeve wall. To do.
JP 2005-188036 A Published by Hokkaido Outside Insulation Council, “2003 edition, RC exterior insulation method handbook, pages 40-47: Calculation of heat loss coefficient”

In the construction of the reinforced concrete balcony of Conventional Example 1, since many continuous reinforcing bars and compression reinforcing bars are arranged in parallel on the heat insulating material itself, the rebar unit for thermal bridge reduction itself has a complicated shape, and the reinforcing bar unit Cannot be efficiently transported and stored.
Moreover, the protruding parts such as balconies have various sizes and shapes, and the preparation of the corresponding reinforcing bar units is complicated and difficult.
And, at the time of formwork, the reinforcing bars arranged on the side of the housing unit are in the way, and it is difficult to arrange the reinforcing bar unit for fixing the thermal bridge and to fix the reinforcing bar. Reinforcing bar assembly work is difficult and complicated.
In addition, a thermal bridge reducing rebar unit is placed on the boundary surface between the balcony floor slab and the dwelling unit frame, and after the concrete frame is constructed, it becomes an external heat insulation building with a post-pasting method in which heat insulating material is attached to the concrete outer wall. Is bad and not versatile.
Moreover, the thermal bridge reduction technology of Conventional Example 1 cannot be applied to reduce the thermal bridge of the concrete sleeve wall.

  Moreover, in the construction method of the balcony floor slab and the sleeve wall of the reinforced concrete of the conventional example 2, as shown in FIGS. 12 (A) and (B), both the upper and lower sides of the balcony floor slab, the front end surface, and the sleeve wall Since both the side surfaces and the front end surfaces, that is, the outer peripheral surfaces of the balcony floor slab and the sleeve wall are covered with a heat insulating material, the balcony floor slab and the sleeve wall have the same outer heat insulation structure as the outer wall. There is a defect that the thickness of the slab and the sleeve wall becomes large due to the covering heat insulating material, and the composite panel is attached to the balcony floor slab and the sleeve wall, in particular, the attachment of the tip surface, and the balcony floor The workability of attaching the heat insulating material to the upper surface of the slab is poor, and the construction means of Conventional Example 2 is expensive due to the application of the composite panel and the heat insulating material.

  Moreover, in the construction method of the reinforced concrete balcony floor slab and the sleeve wall according to Conventional Example 3, as shown in FIGS. 12C and 12D, the balcony floor slab and the sleeve wall are not covered with the composite panel. Furthermore, unlike the conventional example 2, there is no problem of increasing the thickness, but in order to suppress the thermal bridge between the balcony floor slab and the sleeve wall, a heat insulating reinforcing material is adhered to the inner surface of the concrete frame, and the concrete frame In the heat insulation reinforcement, only about 75% reduction of the thermal bridge can be expected, and the thermal bridge reduction rate is lower than that of the conventional example 2 (FIGS. 12A and 12B).

Moreover, in Conventional Example 3 (FIGS. 12 (C) and 12 (D)), a step due to the heat insulating reinforcing material is generated on the inner surface of the concrete case, and when finishing the interior, the step of the heat insulating reinforcing material is eliminated. It is also necessary to construct a base for attaching the interior material, which increases the number of constructions and costs in terms of interior finishing.
The present invention solves or improves the problems of the conventional examples 1, 2 and 3 at a stroke, and both the reinforced concrete balcony floor slab and the reinforced concrete sleeve wall have a thermal bridge effect on the concrete frame. The present invention provides a technique for rationally constructing a balcony and sleeve wall concrete protruding from an external heat-insulated reinforced concrete building by thermally blocking the concrete from the concrete building.

  The invention of the outer wall structure of a reinforced concrete external heat insulating building of the present application is, for example, as shown in FIG. 1, an outer wall in which a reinforced concrete balcony floor slab SB and a reinforced concrete sleeve wall 5 project from a concrete outer wall W of a reinforced concrete external heat insulating building. The concrete outer wall W has an outer heat insulation by a composite panel 2 in which a heat insulating layer 2B is layered on a layered surface 2S of a molded cement plate 2A in which ventilation grooves G and thick portions 2C are alternately arranged vertically. The balcony floor slab SB is covered and thermally insulated from the outer wall surface Wf by the heat insulating layer 2B of the composite panel 2 on the entire surface of the base end Bb, and fitted to the composite panel 2, the noncombustible heat insulating material 4B of the nonflammable support block 4 The connecting bars 1 and 6 of the connecting bars 1 and 6 are fixed in the concrete frame CF and the other protruding part BP in the balcony floor slab SB. The support frame CF is cantilevered with only the connecting bars 1 and 6, and the side wall Bs is supported by the sleeve wall 5, and the sleeve wall 5 has the base end 5b as a whole in a vertically long heat insulating support panel 3. The heat-insulating layer 3B is thermally shielded from the outer wall surface Wf, and one protrusion AP of the connecting bars 1 and 6 penetrating the non-combustible heat insulating material 40B of the non-combustible support block 40 fitted into the heat-insulating layer 3B is formed into a concrete frame. The other projecting portion BP is fixed in the sleeve wall 5 in the CF so that the concrete frame CF is cantilevered with only the connecting bars 1 and 6, and the lower end is supported by the foundation F, and the sleeve The vertical stress of the wall 5 is transmitted to the foundation F.

In this case, the heat insulating layer 2B of the composite panel 2 and the heat insulating layer 3B of the heat insulating support panel 3 are preferably foamed plastic heat insulating layers, and typically both are foam insulating materials of JISA9511.
The composite panel 2 typically has a heat insulation of an extruded polystyrene foam plate of JISA9511 having a thickness T3 of 75 mm, a width BW of 500 mm, and a height Bh (floor height 1 h) of 2700 mm, as shown in FIG. DECF in which a layer G having a thickness T2 of 25 mm, a width AW of 490 mm, a height Ah of 2700-3 mm, a depth Gd of 13 mm, and a width a1 of 30 mm is scattered vertically on the layer attachment surface 2S. Panel (Mitsubishi Materials Building Materials Co., Ltd., trade name), heat insulation layer 2B protrudes d4 (20mm) at the upper end, d4 '(17mm) enters at the lower end, and in the width direction as shown in Fig. 6 (C) The layer 2B is layered and integrated in a form in which d3 (20 mm) protrudes on the left side 2L and d2 (10 mm) enters on the right side 2R.
And for general walls, it is used without processing, and for balconies, the fitting notch H1 is cut so that only the upper end of the composite panel 2 can be fitted to the nonflammable support block 4. And use.

Moreover, if the nonflammable heat insulating material 4B of the nonflammable support blocks 4 and 40 can hold the connecting bars 1 and 6 and fit into the heat insulating layers 2B and 3B, respectively, in terms of heat insulating function, the heat insulating layers 2B and 3B and It can be integrated to achieve the same function, and the connecting bars 1 and 6 can be provided with a fire resistance function. A lock cell board made of calcium carbonate foam (Fuji Kasei Kogyo Co., Ltd., trade name) or a lock board ( Non-combustible heat insulating material of Nippon Boseki Co., Ltd., trade name) can be used.
In this case, the calcium carbonate foam plate (thermal conductivity: 0.032 kcal / mh ° C., moisture permeability resistance: 26.3 m ² hmmHg / g) is fitted as the non-combustible heat insulating material 4B, 40B in the heat insulating layers 2B, 3B. And the physical property approximate to the heat insulation layers 2B and 3B is exhibited.

  Further, the connecting bars 1 and 6 extend from the supported body side, that is, the balcony B or the sleeve wall 5 side to the support body side, that is, the concrete frame CF side, and support the cantilever to support the supported body. 5B, or a single connecting bar 6 shown in FIG. 8B may be used, but a single balcony B that protrudes horizontally in a cantilevered form may be used. When supported by the connecting bars 6 in the form, the number of connecting bars 6 increases, and the sleeve wall 5 is supported by the foundation F, so that the load on the connecting bars 1 and 6 is reduced. Is for the balcony, which is a truss-shaped Z-strut 1 with a strong support force shown in FIG. 5 (B), and for the sleeve wall, which is shown in FIG. 8 (B). This is a single form connecting rod 6.

Then, the arrangement interval, the muscle diameter, and the number of the connecting bars 1 and 6 in the balcony floor slab SB, the arrangement interval, the muscle diameter, and the number of the connecting bars 1, 6 in the sleeve wall 5 are also calculated. However, from the viewpoint of the work of arranging the formwork, a small number of Z bars 1 should be provided at a large interval for the balcony floor slab SB, and a small number of connecting bars for the sleeve wall. It is preferable to arrange the 6 or Z muscles 1 at large intervals.
In addition, the sleeve wall 5 is rigidly connected to the roof slab RB, the foundation beam FG and the foundation F at the upper and lower ends and the side ends of the balcony floor slab SB at the left and right sides. The bars 1 and 6 prevent the sleeve wall 5 from moving back and forth due to the seismic force, and reduce the stress load of the connecting bars 1 and 6 in the balcony floor slab SB.

Further, since the balcony floor slab SB is supported only by the connecting bars 1 and 6 with respect to the concrete building frame CF, structurally, the balcony floor slab SB in the long side direction of the balcony floor slab SB as shown in FIG. If the upper and lower end stripes 9A and 9B are extended into the sleeve wall 5 and both are rigidly integrated, a part of the load stress of the balcony floor slab SB can be borne by the sleeve wall 5 and the displacement of the balcony can be suppressed. Therefore, in the balcony B having a small distance LA between the center of the sleeve walls 5, it is possible to adopt a single connecting bar 6, and for a balcony floor slab having a large center distance LA between the sleeve walls. In this case, since the stress load from the balcony floor slab SB on the sleeve wall 5 also increases, the Z wall 1 having a large support strength may be adopted for the sleeve wall 5 as well.
And the rigid structure integration with the side end Bs of the balcony B and the sleeve wall 5 also produces the effect which suppresses the concrete crack in both adjacent parts.

In this case, for example, as shown in FIG. 4A, the side edge Bs of the balcony floor slab SB is attached to the sleeve wall 5 with the upper edge 9A and the lower edge 9B in the long side direction of the floor slab SB. The upper end 9C and the lower end 9D in the short side direction of the floor slab SB are fixed in the parapet P at the end of the floor slab SB as shown in FIGS. Then, the auxiliary reinforcement 9E is added and strengthened, and the beam main reinforcement 9F in the parapet P may be fixed in the sleeve wall 5.
In this case, if the barbs 9G are arranged in the parapet P, the beam function of the parapet P is improved, and the support by the sleeve wall 5 of the balcony floor slab SB can be achieved more firmly.

Therefore, in the outer wall structure of the present invention, both the balcony floor slab SB and the sleeve wall 5 of reinforced concrete protruding from the reinforced concrete outer wall W are thermally insulated from the concrete building frame CF by the heat insulating layers 2B and 3B. Since the supporting bridges 1 and 6 are cantilevered only, the hot bridge route from the balcony floor slab SB and the sleeve wall 5 to the concrete frame CF is outside air → the concrete of the balcony floor slab and the sleeve wall → the connecting bars. → Only the route of the concrete frame → the living room, and the thermal bridge action from the outside into the concrete frame CF can be remarkably suppressed.
And since the composite panel 2 which coat | covers the concrete outer wall W with external heat insulation is provided with the groove | channel G which enables the draft ventilation of external air, it is the exterior attached to the surface of a shaping | molding cement board (exterior base material) 2A. Regardless of the physical properties of the material, that is, without being constrained by the attached exterior materials, internal condensation can be suppressed, heat stress due to solar radiation can be suppressed, and energy-saving and excellent living environment can be provided. And

In addition, since the connecting bars 1 and 6 that support the balcony floor slab SB and the concrete sleeve wall 5 are protected by the non-combustible heat insulating materials 4B and 40B and disposed in the heat insulating layers 2B and 3B, the outer wall covering heat insulating layer 2B and Even if 3B burns, the connecting bars 1 and 6 can suppress fire deterioration by the non-combustible heat insulating material, and the balcony B and the sleeve wall 5 become fire resistant.
Further, the reinforced concrete balcony floor slab SB and the sleeve wall 5 are constructed in a front open box shape (rectangular cylinder shape, honeycomb shape) of the balcony floor slab SB as a horizontal protrusion and the sleeve wall 5 as a vertical protrusion. Is thermally shielded by a heat insulating layer and attached to the concrete building frame CF. Therefore, the large load stress of the balcony floor slab SB is caused by the cantilever connecting bars and the sleeve wall 5 supported by the foundation F. The balcony floor slab SB and the sleeve wall 5 have a large degree of freedom in terms of design and construction, and the degree of freedom in designing as a building becomes large.

Further, in the invention of the outer wall structure, as shown in FIG. 1, the base end Bb of the fence slab RB and the base end P′b of the roof parapet P ′ protruding horizontally from the concrete casing CF are insulated from the concrete casing CF. Only the connecting bars 1 and 6 of the non-combustible support blocks 4 and 40 that are thermally shielded by the layers 2B and 3B ′ and fitted to the heat-insulating layers 2B and 3B ′ are used to convert the slab RB and the roof parapet P ′ into the concrete frame CF. It is preferable to provide a protrusion.
In this case, as shown in FIGS. 2 (B) and 2 (C), the straw slab RB may be constructed with the form of the composite panel 2 in the same manner as the balcony floor slab SB, and the roof parapet P ′ is shown in FIG. As shown in C), a heat insulating layer 3B ′ having a necessary connecting reinforcement 6 penetratingly mounted corresponding to the cross-sectional shape of the roof parapet P ′ is placed on and connected to the upper end of the heat insulating layer 3B for the sleeve wall 5 or the sleeve wall 5 The heat insulating support panel 3 may be extended and the necessary connecting bars 6 may be arranged to construct the mold frame.

In addition, as a measure against snow load in a cold region, the kite slab RB employs a Z-strip 1 as a connecting bar based on the structural calculation, and has an arrangement interval larger than the Z-strip 1 on the balcony floor slab SB. What is necessary is just to make support strength large as small.
Therefore, the obtained outer wall structure includes all the concrete structures protruding from the concrete outer wall W surface of the concrete frame CF, including the wall slab RB and the parapet P ′ protruding horizontally from the roof slab RS, and the concrete building frame CF. Becomes a structure that is thermally blocked through the heat insulating layer, and the external thermal bridge action into the concrete building CF can be extremely reduced.

In the invention of the outer wall structure, in the composite panel 2, the heat insulating layer 2B protrudes from the molded cement plate 2A with a large step d4 at the upper end and enters a small step d4 'at the lower end so that the upper and lower phases are connected to each other. At the same time, the rubber plate PR closes the plate-like portion Pd of the molded cement plate 2A at the upper and lower connecting portions, and the non-combustible heat insulating material 4B is fitted into the composite panel 2 in a form that ensures the ventilation function of the groove G. It is preferable.
In this case, as shown in FIG. 6C, if the non-combustible heat insulating material 4B of the non-combustible support block 4 is fitted to the thick portion 2C position of the molded cement plate 2A, interference with the grooves G on both sides is avoided. It becomes fitting and the ventilation function of the groove G can be guaranteed.

As shown in FIG. 10 (B), the composite panel 2 is vertically connected, and the difference between the large step d4 (standard: 20 mm) and the small step d4 ′ (standard: 17 mm) (standard: 3 mm). In order to close the front surface between the plate-like portions Pd of the molded cement plate 2A of the upper and lower panels, that is, between the upper and lower cement plates 2A, by sandwiching the rubber plate PR, The inflow of outside air into the groove G can be prevented, and the through-flowing gas from the lower end (waist drainage) to the upper end (headwood) of the outer wall composite panel 2 can be guaranteed.
The upper and lower cement plates 2A can be connected by the cross joint 7 having the horizontal contact piece 7F having the same thickness as the rubber plate PR.

Therefore, the vertical connection of the panel 2 can guarantee the function of passing the draft ascending air flow from the waist drainage to the headwood by the groove G, and the workability of the connection of the upper and lower panels by using the cross joint 7 is improved.
In addition, even if rainwater enters from the connecting portion of the upper and lower panels, it is possible to prevent rainwater from entering the residential floor slab SA without rising to the heat insulating layer 2B abutting interface of the upper and lower panels.
Further, the non-combustible support block 4 is fitted in such a manner that the non-combustible heat insulating material 4B ensures the ventilation function of the groove G of the molded cement plate 2A as shown in FIG. 7B, for example. Even in the arrangement position, the uniform air permeability of the outer heat insulating coating on the outer wall W can be guaranteed.

Further, in the invention of the outer wall structure, the non-combustible heat insulating material 4B of the non-combustible support block 4 and the non-combustible heat insulating material 40B of the non-combustible support block 40 are both in the fitting notches H1 and H4 of the heat insulating layers 2B and 3B. It is preferable that the fitting is held in an airtight manner.
In this case, in the incombustible support block 4, as shown in FIG. 5 (A), the gap follower sheet 12A is adhered to both side surfaces 4S of the incombustible heat insulating material 4B, and is fitted as shown in FIG. 7 (B). If fitted into the notch H1, the airtight fitting can be fixed by the time-dependent expansion of the gap following sheet 12A. In the non-combustible support block 40, as shown in FIG. If the gap follow-up sheet 12A is wound and pasted and inserted and fitted into the fitting notch H4 as shown in FIG. 9A, the air-tight fit can be secured by the time-dependent expansion of the gap follow-up sheet 12A.
As the gap following sheet 12A, Softlon (trade name) of Sekisui Chemical Co., Ltd. or Ilmond (trade name) of Illbrook (Germany) may be employed.

Then, if the corresponding side dimensions of the non-combustible heat insulating materials 4B and 40B are formed to be slightly small (standard 10 mm small) with respect to the fitting notches H1 and H4, and a standard 2 mm thick gap following sheet 12A is pasted. The non-combustible heat insulating materials 4B and 40B are air-tightly fitted in 1 to 2 hours due to easy insertion work and expansion of the gap following sheet 12A.
Therefore, although the heat insulation layers 2B and 3B that thermally shield the base end Bb of the balcony floor slab SB and the base end 5b of the concrete sleeve wall 5 are fitted with the non-combustible heat insulating materials 4B and 40B that hold the connecting bars 1 and 6, respectively. Since the incombustible heat insulating materials 4B and 40B are airtightly fitted in the fitting notches H1 and H4, the air in the fitting notches H1 and H4 becomes a sealed air heat insulating layer, and the heat insulating function of the heat insulating layers 2B and 3B. There is no loss.

Further, as shown in FIG. 6 (A), the composite panel 2 is provided with a fitting notch H1 having a depth of 4h extending from the upper end to the balcony floor slab lower surface Sd at the position of the thick portion 2C in the center of the width of the molded cement board 2A. As shown in FIG. 7B, the ventilation groove G4 on both side surfaces 4S of the non-combustible heat insulating material 4B fitted in the fitting notch H1 faces the open side surface of the groove G of the molded cement plate 2A. Is preferred.
Since the outer wall structure of the present invention is a breathable outer heat insulating wall that is covered with the composite panel 2, it is necessary to avoid the groove G from being crushed by fitting the non-combustible support block 4 into the composite panel 2.

However, the molded cement plate 2A of the standard composite panel 2 has a thickness T2 of 25 mm, a depth Gd of 13 mm, and a width a1 of 30 mm between the thick portions 2C, as shown in FIG. 6B. If the groove G is scattered between the thick portions 2C, the width a4 of the central thick portion 2C is 40 mm, and the width W4 (standard: 60 mm) of the fitting notch H1 is formed in the central thick portion 2C, the fitting The wearing notch H1 partially cuts the groove G on both sides.
And since the notch H1 for fitting is a minimum incision for fitting the non-combustible heat insulating material 4B, the notch defect of the composite panel 2 is small, and the heat insulating layer 2B of the composite panel 2 is also obtained by placing concrete on the balcony floor slab SB. Is protected by the cement plate 2A and can suppress deterioration of the heat insulation function.

Accordingly, as shown in FIG. 5, the incombustible heat insulating material 4B of the incombustible supporting block 4 is provided with the recessed grooves G4 vertically on both side surfaces 4S of the position facing the groove G, and the incombustible heat insulating material 4B is provided in the fitting notch H1. Are fitted in alignment with each other, the groove G4 of the non-combustible heat insulating material 4B communicates with the formed cement plate groove G partially cut at the fitting notches H1 on both sides, and the groove G is long in the width direction. And demonstrates its original ventilation function.
In other words, even if a commercially available standard size DECF panel (Mitsubishi Materials & Building Materials Co., Ltd., trade name) is used and the notch with the required width (W4) is cut open, the ventilation function of the groove G is lost. In addition, the incombustible support block 4 can be fitted into the composite panel 2, and the composite panel in which the balcony floor slab SB protrudes in a cantilevered form exhibits the original ventilation function.

In addition, as shown in FIG. 5B, the non-combustible support block 4 includes a Z upper upper end 1U and a Z lower end 1D, a central horizontal upper side 1U ′, an intermediate inclined part 1S that slopes down on both sides, and horizontal sides on both sides. It is preferable that the trapezoidal Z truss bar 1M composed of the lower side 1D ′ is fixedly held in an airtight manner by the non-combustible heat insulating material 4B.
In this case, the intermediate inclined portion 1S of the Z truss bar 1M has an inclination angle θ of 45 °, which is the working interface between the tensile stress of the Z bar 1 (corresponding to the Z upper bar) and the compressive stress (corresponding to the Z lower bar). This is preferable because it can effectively cope with the shear stress (45 ° inclined surface action).
In addition, as shown in FIG. 5 (B), airtight fixing and holding of the Z line 1 with the non-combustible heat insulating material 4B is performed by winding the gap follower sheet 12A around the Z line 1 and fitting grooves H2 of the non-combustible heat insulating material 4B. What is necessary is just to carry out integral fitting to H2 'and H3.

Accordingly, in the Z muscle 1, the Z upper end muscle 1U and the Z lower end muscle 1D are integrated while maintaining the necessary stress center distance L15 (standard: 92 mm) in the vertical direction. Compared with the case where the lower end bars of the arm are separately and independently disposed, the support force (in terms of structural calculation: 3.64 times) is much greater. For example, the Z upper end bars 1U and the Z lower end bars 1D have a diameter of 22 mm. If the Z truss bar 1M is an embodiment Z bar having a diameter of 16 mm (FIG. 5B), the arrangement interval of the Z bars 1 is calculated for a balcony floor slab with a sleeve wall center distance LA of 3500 mm to 7000 mm. Incombustible heat insulation at the time of constructing balcony floor slab formwork and sleeve wall formwork, fitting to the composite panel heat insulation layer 2B of the noncombustible support block 4 can be done with a large number of arrangements with a small number of ones at 1000mm intervals. Positioning of the Z-strip protrusions AP, BP from the material 4B, and Haisuji work is simple, and and easy.
And even if the non-combustible heat insulating material 4B penetrates the Z-strip 1 into the fitting groove, the ventilation of the air in the fitting groove is suppressed, and the heat insulation function loss does not occur.
Moreover, since the non-combustible support block 4 is a factory-produced product, it can be supplied to the construction site as a quality-assured, homogeneous product, and there are structural variations and safety due to differences in the construction contractors of balconies and sleeve walls. Variations can be prevented.

  Further, the heat insulating layer 2B of the composite panel 2 that heat-blocks the balcony floor slab SB and the heat-insulating layer 3B that heat-blocks the sleeve wall 5 are both of the same material and the same thickness, and the non-combustible heat insulation of the non-combustible support block 4 It is preferable that the material 4B and the incombustible heat insulating material 40B of the incombustible support block 40 have the same material and the same thickness, and both have the same thickness as the composite panel heat insulating layer 2B.

In this case, in the concrete work for placing concrete, the incombustible support block 4 for holding the connecting bars 1 and 6 and the incombustible support block 40, the notch H1 for fitting the composite panel heat insulating layer 2B, and the heat insulating support panel. Since the fitting and fixing work by hand to the fitting notch H4 of No. 3 is the fitting of the non-combustible heat insulating materials 4B and 40B of the same thickness to the heat insulating layers 2B and 3B of the same thickness, it is a flush fitting. And easy.
And the right-and-left alignment arrangement of the heat insulation layer 2B and the heat insulation support panel 3 of the composite panel 2 is easy, and since the heat insulation covering to the concrete outer wall W can be performed uniformly, the mold work is easy and the concrete outer wall W The composite panel heat insulating layer 2B and the sleeve wall heat insulating layer 3B have the same heat insulating function, resulting in an outer wall structure having a uniform heat insulating coating.

Further, as shown in FIG. 2 (A), the connecting bars 1 and / or the connecting bars 6 are preferably fixed in the concrete frame CF by bending the protrusion AP for fixing in the concrete frame CF. .
In this case, the protrusion AP may be bent sideways or bent downward, and the bending angle is preferably 90 °.
If the protruding portion AP is bent, the bent protruding portion AP can be arranged in the concrete casing CF even within the thickness TW (standard: 180 mm) of the outer wall W as shown in FIG.

  Therefore, the balcony floor slab SB can be provided with a protrusion even in a form that maintains a step difference from the living part floor slab SA, that is, in a state where the linearly extending protruding part AP cannot be fixed in the living part floor slab SA. However, as shown in FIG. 2A, it is possible to attach the outer wall W from an appropriate position, and the projecting positions of the balcony floor slab SB and the concrete sleeve wall 5 can be freely made, and the degree of freedom in design is improved.

  Further, the invention of the construction method of the outer wall uses a breathable composite panel 2 in which a molded plastic board 2A having a ventilation groove G is layered and integrated with a foamed plastic heat insulating layer 2B. In this case, the composite panel 2 is an outer wall formwork, and the balcony floor slab SB projecting wall portion has a height of 4 h that interferes with the composite panel 2 from the upper end to the base end of the balcony floor slab SB. An overhanging cutout H1 is formed to form an outer wall mold, and the Z upper end muscle 1U and the Z lower end line 1D are formed in the fitting cutout H1 of the composite panel 2, and the trapezoidal Z truss bar 1M has a center distance L15 up and down. The non-combustible support block 4 held in a penetrating form with the non-combustible heat insulating material 4B is fitted and fixed to the integrated Z-strip 1 to keep one projecting portion AP of the Z-strip 1 in the concrete frame side formwork. The other protrusion BP is placed in the balcony floor slab formwork In the projecting wall portion of the sleeve wall 5, the heat insulating support panel 3 in which the fitting notch H4 is arranged is provided over the entire height of the sleeve wall base end 5b and the composite panel is insulated. Standing in contact with the layer 2B, the non-flammable support block 40 that has the single connecting bar 6 penetrating and holding the non-combustible heat insulating material 40B is fitted and fixed to the fitting notch H4. , One protrusion AP is placed in the concrete frame form and the other protrusion BP is placed in the sleeve wall form to form a conventional sleeve wall form, and the longitudinal direction in the balcony floor slab SB form The bar arrangements 9A and 9B are fixed in the sleeve wall molds, and then concrete is placed in each mold frame, so that the balcony floor slab SB and the sleeve walls 5 protrude from the concrete outer wall W.

  In this case, as shown in FIG. 6, the composite panel 2 for general walls typically has a heat insulation layer 2B having a thickness T3 of 75 mm, a width BW of 500 mm, and a height of 1 h (standard: 2700 mm). Extrusion method polystyrene foam board of JISA9511, exterior base material (molded cement board) 2A has a thickness T2 of 25 mm, a width AW of 490 mm, a height Ah of 2697 mm with a floor height of 1h-3 mm, FIG. ) Is a DECF panel (Mitsubishi Materials Building Materials Co., Ltd., trade name) in which a groove G having a depth Gd of 13 mm and a width a1 of 30 mm is vertically arranged on the layer attachment surface 2S. 6A, the heat insulating layer 2B is d4 ′ (17 mm) at the lower end, protrudes d4 (20 mm) at the upper end, and d2 (10 mm) at the right side 2R. Enter, d3 (20mm) protruding at 2L on the left side It is a layered dress of the form.

Moreover, as shown in FIG. 6 (B), the composite panel 2 for constructing a balcony floor slab is formed by forming only a fitting notch H1 at the upper end of the composite panel 2 for a general wall. A fitting notch H1 having a depth of 4h (standard: 200 mm) and a width W4 of 60 mm extending from the upper part of the panel 2 to the lower surface Sd of the balcony floor slab SB is formed at the center of the molded cement board 2A as shown in FIG. , An incision is formed in the thick part 2C having a width a4 (standard: 40 mm).
Further, as shown in FIG. 5B, the Z muscle 1 is a truss structure in which the Z upper muscle 1U and the Z lower muscle 1D are integrated with a trapezoidal Z truss 1M while maintaining a sufficient center-to-center distance L15. The support strength is large and a large interval (standard: 500 mm) can be arranged.

The heat insulating support panel 3 arranged on the sleeve wall protruding portion is made of the same material as the heat insulating layer 2B of the composite panel 2, and as shown in FIG. 9B, the thickness T3 is 75 mm, the width W3 is 200 mm, and the height is 3 h. Is connected up and down two 1350mm of 1/2 floor height.
Then, in the construction method of the present invention, the composite panel 2 for a general wall, the composite panel 2 for a balcony, and the heat insulating support panel 3 for a sleeve wall prepared at a factory are arranged on the outer side of the outer wall with a conventional mold framework. Used as a base form for the frame and sleeve wall, and the non-combustible support block 4 and the non-combustible support block 40, which are factory-produced products, are erected, the notch H1 for fitting the composite panel 2, and the heat-insulating support panel 3 erected. Can be placed in the self-contained form in the balcony floor slab formwork, sleeve wall formwork and concrete frame side formwork. As shown in FIG. 4, each formwork can be formed by performing a line work and fixing and arranging the longitudinal upper end bars 9A and the longitudinal lower end bars 9B of the balcony floor slab SB in the sleeve wall formwork.

Then, if conventional concrete is placed in each formwork, the balcony floor slab SB is thermally insulated from the concrete outer wall W by the heat insulating layer 2B, so that the cantilever wall 5 is in a cantilevered form only by the Z-strip 1. Is insulated from the concrete outer wall W by the heat insulating layer 3B of the heat insulating support panel 3 so as to be cantilevered only by the connecting bars 6, and the side edge Bs of the balcony floor slab SB is rigidly formed on the sleeve wall 5. Connected, the sleeve wall 5 itself can be constructed in a form in which normal stress is transmitted to the foundation F.
And, in the balcony floor slab SB that requires a strong support force, the truss structure is formed with the trapezoidal Z truss muscle 1M while maintaining the distance L15 (standard: 92 mm) between the Z upper muscle 1U and the Z lower muscle 1D. Since the Z-strand 1 with strong support is used, the Z-stripe 1 has a large interval (standard: 500 mm) in the balcony floor slab SB, that is, one Z-strand 1 is placed per composite panel. As a result, the workability of the formwork and the bar arrangement work is significantly improved compared to the conventional example 1.

Therefore, according to the construction method of the present invention, workability can be improved by simply assembling the incombustible support block 4 and the incombustible support block 40 as a factory-produced product into a conventional construction method. Well, the novel and high quality outer wall structure of claim 1 can be reasonably implemented.
Since the composite panel 2 has a left-right connection and a vertical connection that are phase-missing connections, the connection work by the abutting contact between the heat insulating layers 2B is easy. Since the layer 2B protrudes upward in the form of a phase gap connection that creates a gap between the cement plates 2A, the upper and lower connection portions are formed between the cement plates 2A of the upper and lower panels 2 by the extension of an elastic sheet such as a rubber plate PR. In this way, the flow of outside air into the groove G group can be prevented, and the draft rising air flow from the lower end to the upper end of the outer wall can be guaranteed, and the connection of the upper and lower panels is adopted by the cross joint 7 as shown in FIG. Makes it easier.
For example, even if rainwater enters from the upper and lower connection portions, the heat insulation layer 2B can be prevented from reaching the upper and lower abutting interfaces, and rainwater intrusion to the living portion side can be prevented.

Moreover, in the invention of the construction method, the non-combustible support block 4 and the non-combustible support block 40 are attached to the outer peripheries 4S and 40S of the non-combustible heat insulating materials 4B and 40B by attaching the gap following sheet 12A to the fitting notch H1. , H4 are preferably fitted and fastened in an airtight manner.
In this case, as shown in FIG. 6, the incombustible support block 4 is fitted into the upper open fitting notch H <b> 1, and therefore, the gap following sheet 12 </ b> A may be adhered to both side surfaces 4 </ b> S. As shown in FIG. 9, since it becomes fitting to the hole-shaped fitting notch H4 of the center part of the heat insulation layer 3B, what is necessary is just to stick the gap | interval tracking sheet | seat 12A on the upper and lower sides and the left and right surfaces.
In addition, the non-combustible support blocks 4 and 40 are arranged in the fitting notches H1 and H4, even when the composite panel 2 and the heat-insulating support panel 3 are installed in a standing state as a mold, in a preparation stage before the standing placement. Construction may be sufficient, and it may be selected according to workability.

In addition, if the dimensions of the non-combustible heat insulating materials 4B and 40B with respect to the fitting notches H1 and H4 are small (standard: 10 mm) and a standard 2 mm-thick gap following sheet 12A is attached, each non-combustible heat insulating material 4B and 40B fits. The alignment and placement work in the wearing notches H1 and H4 is easy, and the non-combustible heat insulating materials 4B and 40B are airtightly fitted and fastened by the time-dependent expansion of the gap following sheet 12A.
The non-combustible heat insulating materials 4B and 40B are air-tightly fitted to the fitting notches H1 and H4, so that the air in the gap between the non-combustible heat insulating materials 4B and 40B and the heat insulating layers 2B and 3B is also an air-insulating layer in a sealed form. Thus, a decrease in the heat insulating function of the heat insulating layers 2B and 3B due to the fitting of the non-combustible support blocks 4 and 40 can be avoided.

In addition, slit grooves 3G and 2G are arranged on the opposite side surfaces of the heat insulating support panel 3 disposed at the base end of the sleeve wall form frame and the composite panel heat insulating layer 2B, and the joining plate 3A is connected to the heat insulating layer 3B. It is preferable that the heat insulating layer 3B of the heat insulating support panel is aligned and abutted with the heat insulating layer 2B of the composite panel by being fitted over the slit groove 3G of the composite panel and the slit groove 2G of the composite panel.
In this case, the bonding plate 3A has a relative positional relationship in the front-rear direction (FIG. 10A) between the heat insulating layer 3B of the heat insulating support panel 3 and the heat insulating layer 2B of the composite panel 2, as shown in FIG. The standard is to use a plastic plate with a thickness of 3 mm, a width of 80 mm, and a height of the floor (standard: 2700 mm). The slits 3G and 2G of the heat insulating layer 3B and the heat insulating layer 2B are The groove width is 3 mm and the depth is 40 mm + α. However, when the joining plate 3A is frictionally held by the slit grooves 3G and 2G, the joining plate 3A is shortened and the heat insulating layers 3B and 2B are appropriately abutted. You may implement by partial insertion in the position.
Therefore, the use of the joining plate 3A facilitates the abutting and alignment arrangement of the heat insulating support panel 3 with respect to the composite panel 2, and the joining plate 3A suppresses the displacement of the heat insulating support panel 3 due to the concrete pressure when placing concrete. There are also advantages.

Further, in the invention of the construction method of the outer wall, the vertical connection of the composite panel 2 is as follows. As shown in FIG. 10 (C), the vertical piece 7W provided with the vertical ventilation groove G7 and the intermediate left and right horizontal contact piece 7F. The vertical piece 7W is inserted into the upper and lower grooves G, the horizontal abutment piece 7F is sandwiched by the cement board thick part 2C of the upper and lower panels, and the molded cement board 2A It is preferable to carry out by sandwiching a rubber plate PR having the same thickness as the horizontal abutting piece 7F on the plate-like portion Pd.
In this case, in the cross joint 7, the cross-sectional shape of the upper and lower vertical pieces 7W approximates the cross-section of the insertion target groove G, and the horizontal abutment piece 7F has a thickness of 3 mm and a width in the front-rear direction 7W. And the same length (standard: 11.8 mm), the left and right lengths may be set to lengths that do not close the left and right grooves G.
The thickness (standard: 3 mm) of the horizontal contact piece 7F is the difference between the large step d4 (standard: 20 mm) at the upper end and the small step d4 ′ (standard: 17 mm) at the lower end (standard: 17 mm). 3mm).

Accordingly, the cross joint 7 is inserted at both ends of the composite panel 2 as shown in FIG. 1 and the lower vertical piece 7W is inserted from the upper end of the groove G of the lower composite panel 2 as shown in FIG. Then, the horizontal abutment piece 7F is placed on the upper end of the cement plate, and the entire length of the plate-like portion Pd (standard: 12 mm) of the cement plate 2A on the front surface of the horizontal abutment piece 7F is the same as that of the horizontal abutment piece 7F. By extending and arranging the butyl rubber plate PR having a thickness and fitting the lower end opening of the groove G of the upper composite panel 2 to the upper vertical piece 7W, the lower side when forming the upper floor formwork The upper and lower connection work of the upper panel 2 with respect to the panel 2 can be easily performed.
And in the connection part of the up-and-down composite panel which employs the cross joint 7, the vertical air flow groove G7 of the cross joint 7 guarantees the up and down flow of the draft air flow in the groove G in which the cross joint 7 is inserted. The

In constructing the sleeve wall formwork, the heat insulating support panel 3 is provided with a separator 10H ', a heat insulating material cone 11A, and an anchor 11B as shown in FIG. It is preferable to use and hold.
In this case, the separator 10H ′, the heat insulating material cone 11A, the anchor 11B, and the like are commonly used posture holding members of the mold frame.
In addition, as shown in FIG. 9, the heat insulating support panel 3 is a plate-like heat insulating layer 3 </ b> B in which a non-combustible support block 40 that is held through the connecting bars 6 is fitted and fixed. It is necessary to hold the heat insulating layer 3B extending up and down by a height of 5 (standard: floor height 1h).

And if the heat insulation support panel 3 is a single piece of floor height, it may be appropriately sandwiched and held. However, as shown in FIG. Should be pinched and retained.
Then, by fixing the projecting portion of the anchor 11B into the outer wall formwork and the projecting portion into the sleeve wall formwork with the reinforcing bar in each formwork, an appropriate position in the upper and lower sides of the heat insulating layer 3B, and the connecting portion Insulating material cone (KP Con) 11A holding and holding J3 can be held in position, and by placing the insulating material cone 11A in the vertical connection portion J3 of each heat insulating layer 3B of each heat insulating support panel, or in an appropriate vertical position, The heat insulating support panel 3 can suppress displacement due to the pressure of the cast concrete in combination with the tight holding of the protrusions AP and BP of the connecting bars 6 in the respective formwork.
Therefore, the vertical connection and position holding work of the heat insulating support panel 3 are facilitated, and the construction of the concrete sleeve wall formwork is facilitated.
In this case, the separator 10H ′ for connecting the heat insulating material cones 11A on both sides is an iron bar, but the heat bridge is blocked by the heat insulating material cones 11A.

Further, in the invention of the construction method, as shown in FIG. 10A, the width W3 of the heat insulating layer 3B of the heat insulating support panel 3 is slightly larger than the sleeve wall thickness T5 (standard: 10 mm). It is preferable that both dimensions 3L and 3R of the heat insulating layer 3B are abutted against the entering surfaces 2L and 2R at the side ends of the heat insulating layer 2B of the composite panel 2 with the provided dimensions.
In this case, the dimension of the projecting portion P3 from the side surface of the sleeve wall 5 on both side surfaces 3L and 3R of the heat insulating layer 3B may be about 10 mm as standard, and the side surface of the composite panel heat insulating layer 2B opposite to the heat insulating layer 3B is as required. The entry surface should be 10mm.
Therefore, as apparent from FIG. 10A, the heat insulating layer 3B of the heat insulating support panel 3 has both side surfaces 3L and 3R abutting against the entering surfaces 2L and 2R of the heat insulating layer 2B of the composite panel 2 because the protruding both side surfaces 3L and 3R abut. , 3R protrusion P3 (standard: 10 mm) is a support form of the composite panel 2 on the molded cement plate 2A, and the abutting contact work of the heat insulating layer 3B to the composite panel 2 is facilitated, and in the work process. The molded cement plate 2A is also used for the pressure displacement action to the heat insulating layer 3B by the concrete pressure generated by the concrete placement in the outer wall formwork, which is performed prior to the concrete placement in the sleeve wall formwork. The counter-supporting action is suitably achieved.

  The outer wall structure of the reinforced concrete external heat insulating building of the present invention is a heat insulating layer in which a reinforced concrete balcony projecting from the outer wall W, a reinforced concrete sleeve wall, etc. are thermally shielded from the concrete outer wall W through the heat insulating layers 2B and 3B. Since it is cantilevered only by the supporting connecting bars 1 and 6 held by the non-combustible heat insulating materials 4B and 40B fitted in 2B and 3B, it can be constructed from the concrete of a protruding attachment (balcony, sleeve wall, etc.) The thermal bridge to the concrete (concrete outer wall, etc.) of the frame CF is blocked by the heat insulating layers 2B and 3B, and there is no need to heat-insulate the outer peripheral surface of the protruding object on the balcony or the sleeve wall as in the past. The thermal bridge action from the object to the concrete frame CF side can be suppressed, and all the supporting connecting bars 1 and 6 are protected by the non-combustible heat insulating materials 4B and 40B. Under strength degradation during fire can be suppressed, the outer wall structure of the energy saving can be obtained conveniently by refractory.

  In addition, the non-combustible support block 4 with the Z bar 1 and the non-combustible support block 40 with the connecting bar 6 that influence the safety and heat insulation of the concrete projecting attachment are factory-produced products. It can be prepared as a homogenous product with sufficient safety guaranteed, can be stored and transported as a product easily, can be deployed to a wide range of construction sites, and is constructed by adopting non-combustible support blocks 4 and 40. The concrete sleeve wall 5 and the concrete balcony B are fireproof and safe.

The concrete structure protruding from the concrete building frame CF cantilever-supports the balcony floor slab SB with only the supporting connecting bars 1 and 6 (typically Z bars 1). The lower end is supported by the foundation F via the foundation beam FG, and the balcony floor slab SB and the sleeve wall 5 are rigidly connected, and the sleeve wall 5, the foundation beam FG, the foundation F, the roof floor slab RS, and the balcony floor slab. SB has a honeycomb shape bonded to a square and has high rigidity.
And since a part of load stress of the balcony floor slab SB is transmitted to the sleeve wall 5 and is transmitted from the sleeve wall 5 to the foundation F, the interval between the connecting bars 1 that support the balcony floor slab SB can be greatly increased. It is possible to facilitate the bar arrangement work of the living section floor slab SA and the balcony floor slab SB.

Further, the balcony floor slab SB and the sleeve wall 5 to be provided with protrusions can determine the thickness T5 of the sleeve wall 5, the arrangement form of the sleeve wall 5, the shape of the connecting reinforcement 6, etc., depending on the distance LA between the centers of the sleeve walls 5. , The structural design becomes easy.
The sleeve wall 5 transmits an axial force to the foundation F via the foundation beam FG, and the wind pressure on the sleeve wall 5 is caused by the rigid connection between the balcony floor slab SB and the sleeve wall 5, and the balcony floor slab SB. Therefore, the connecting bars 6 that connect the concrete frame CF and the sleeve wall 5 have a small load and can be arranged at a large interval.

In addition, according to the construction method of the present invention, the formwork of the reinforced concrete floor slab SB and the reinforced concrete sleeve wall 5 is arranged at an appropriate position of the composite panel 2 standing as an outer wall formwork in a conventional concrete formwork. Because the non-combustible support block 4 and the non-combustible support block 40 are merely fitted and fastened to the fitting notch H1 and the fitting notch H4 arranged at an appropriate position of the heat insulating support panel 3 standing at the base end of the sleeve wall mold. This can be carried out by a simple assembling work of the non-combustible support blocks 4 and 40 in a conventional formwork.
Moreover, since the Z-strands 1 of the non-combustible support block 4 have a strong support force, a small number of them can be arranged at a large interval, and the workability of the non-combustible support block 4 and the arrangement of the bars within the form-frame are improved. good.

And opening of the fitting notch H1 to the composite panel 2, opening of the fitting notch H4 to the heat insulating support panel 3, and the Z-strip 1 are held through, which are necessary for the preparation of the formwork of the concrete floor slab SB and the sleeve wall 5. The non-combustible support block 4 and the non-combustible support block 40 that holds the single connecting bar 6 can be prepared as factory-produced products of homogeneous products, so that they are new, have fire resistance, can suppress thermal bridges, and The outer wall structure of a concrete building that can suppress condensation can be reasonably constructed.
Even if the composite panel 2 is in the contact area of the base end Bb of the balcony floor slab SB, the molded cement board 2A receives the cast concrete of the balcony floor slab and protects the ventilation groove G. Therefore, even if the reinforced concrete outer wall W is in the projecting portion of the balcony floor slab SB, the air permeability is guaranteed.
Therefore, no matter what kind of exterior material is selected as the exterior material attached to the surface of the composite panel 2, that is, the exterior material such as tile or paint attached to the surface of the molded cement board 2A, a breathable outer wall is provided. I can do it.

[External wall structure (Figs. 1 and 2)]
1 is a partially cutaway perspective view of the outer wall structure of the present invention, and FIG. 2A is a cross-sectional view of the outer wall structure of FIG.
As shown in FIG. 1 and FIG. 2A, the concrete outer wall W has a wall thickness (wall thickness) TW of 180 mm, a floor height 1h of 2700 mm, and the outer surface Wf of the outer wall W has a thickness T1 of 100 mm. The composite panel 2 is layered by using a 75 mm thick foamed plastic heat insulating layer 2B and a 25 mm thick molded cement board with ventilation grooves G as an exterior base material 2A. This is a breathable contact-type composite panel having a heat insulation layer 2B having a width BW of 500 mm.

  Further, the balcony floor slab SB and the roof roof slab RB projecting horizontally are notched H1 for fitting the composite panel 2 that covers the concrete outer wall W having a wall thickness TW of 180 mm as the load-bearing wall of the concrete frame CF. In addition, as shown in FIG. 7A, the non-combustible support block 4 having one Z-bar 1 penetratingly held is fitted and integrated, so that each Z-bar 1 is placed on one composite panel 2, that is, at an interval of 500 mm. The balcony floor slab SB is extended from the living section floor slab SA and the roof slab RB is extended from the rooftop floor slab RS by cantilever support, and the balcony floor slab is , Thickness TS is 180mm, Depth LB is 1500mm, Long side tip edge is equipped with Parapet P with both height Ph and width PW 150mm, and the slab RB is a balcony floor slab As shown in FIG. 1, a roof parapet P ′ having a width PW of 150 mm and a height P′h of 300 mm, which is equivalent to SB and continues from the leading edge of the long side to the upper end of the sleeve wall 5, is provided.

  Further, as shown in FIG. 2A, the sleeve walls 5 are arranged such that the center distance LA between the sleeve walls 5 is 6000 mm, the thickness T5 is 180 mm, and the floor height is 1 h (2700 mm). A non-combustible support block 40 that is a sleeve wall and has a depth LB of 1500 mm, which is the same as that of the balcony B and the heel slab RB, and holds one single connecting bar 6 for supporting the concrete sleeve wall, As shown in FIG. 9A, two upper and lower heat insulating support panels 3 having a height of 1/2 floor (1350 mm) are connected. As shown in FIG. 2A, the outer sleeve wall 5 is made of concrete. The heat insulating support panel 3 is brought into contact with the load bearing wall outer wall W on the side surface of the frame CF, and protrudes from the load bearing wall outer wall W via the heat insulation support panel 3. The intermediate sleeve wall 5 includes the heat insulation support panel 3. Abutting on the concrete outer wall W and protruding from the concrete outer wall W, sleeves on both sides The wall 5 is rigidly joined to both sides Bs in the longitudinal direction of the balcony floor slab SB and the heel slab RB, and the lower end of the sleeve wall is rigidly joined to the building foundation F via the foundation beam FG.

[Non-combustible support block 40 (FIG. 8)]
FIG. 8A is an overall perspective view of the incombustible support block 40, and FIG. 8B is an exploded perspective view.
The non-combustible support block 40 is a member that holds the connecting bar 6 in a single form in a penetrating form with a non-combustible heat insulating material 40 </ b> B and is fitted and fixed to the fitting notch H <b> 4 of the heat insulating layer 3 </ b> B of the heat insulating support panel 3.
Therefore, the non-combustible heat insulating material 40B of the non-combustible support block 40 is a material that does not cause a heat-insulating defect in the heat-insulating layer 3B even when embedded in the fitting notch H4 of the heat-insulating layer 3B, that is, the foamed plastic heat-insulating layer 3B of JISA9511. As an approximate material, a lock cell board (trade name) of a calcium carbonate foam plate manufactured by Fuji Chemical Industry Co., Ltd. is adopted.

Rock cell board (trade name) is excellent in cutting processability, and the physical properties are similar to those of a foamed plastic heat insulating plate, and the thermal conductivity is 0.032 kcal / mh ° C. (the foamed plastic type is 0.022 to 0). .037kcal / mh ℃), moisture permeation resistance 26.3m ² hmmHg / g (foam plastic systems, 52.5m ^{2 hmmHg} / g), compressive strength 1.8 kgf / cm ² (foamed plastic system, 0. 5~2.0kgf / cm ^2), weighs (density) 90 kg / ^{m 3} (foam plastic systems 15~45kg / ^{m 3),} locking cell board (trade name) integrated into the heat-insulating layer 3B Even if buried, it exhibits non-flammability and exhibits an approximate heat insulating function together with the heat insulating layer 3B.

  Accordingly, as shown in FIG. 8B, the non-combustible support block 40 is a non-combustible heat insulating material 40B obtained by cutting a calcium carbonate foam plate into a block shape having a height Z40 of 50 mm, a thickness Y40 of 75 mm, and a width X40 of 50 mm. The non-combustible heat insulating material 40B is divided into two equal widths with a width X20 of 25 mm to form a non-combustible heat insulating material piece 40B ', and a symmetrical inner surface 40D of the non-combustible heat insulating material piece 40B' is 900 mm long and 1 mm in diameter 16 mm. A fitting groove H5 slightly larger (standard: 6 mm) than the diameter (16 mm) of the connecting bar for fitting the connecting bar 6 is cut in, and the connecting bar 6 has an outer periphery as shown in FIG. Over the entire length, an epoxy resin paint (fireproof coating primer: SK Kaken Co., Ltd., trade name) with excellent corrosion resistance, adhesion, and heat insulation is applied as a rust preventive paint 1B, corresponding to the center fitting groove H5 In the part, that is, the part buried in the incombustible heat insulating material 40B In addition, fire-resistant paint 1A (SK fireproof coat :( stock) Esuke_kaken, applying the product name).

Next, as shown in FIG. 8B, the gap following sheet 12A is wound around the position where d12 (10 mm) enters from the position LF-LF of the front and rear end face 40F of the incombustible heat insulating material 40B, and the incombustible heat insulating material pieces 40B ′ on both sides are wound. A conventional adhesive is applied to the symmetric inner surface 40D, and the non-combustible heat insulating material pieces 40B 'on both sides are bonded and integrated in a form in which the connecting bars 6 are sandwiched by the fitting grooves H5. After the connecting bars 6 are fixed and integrated in the non-combustible heat insulating material 40B by the expansion, the fire-resistant sealing 13 is filled in the space from the outside of the fitting groove H5 to the gap following sheet 12A of the non-combustible heat insulating material 40B.
And as shown to FIG. 8 (A), the nonflammable heat insulating material 40B is the clearance follower sheet | seat 12A of the state provided with the protection sheet in the front end and the rear end on the upper and lower left and right surfaces facing the inner surface of the fitting notch H1. (20 mm width, 2 mm thickness) is attached, and a double-sided adhesive tape 12B provided with a protective sheet is attached to the center of the lower surface to prepare as a factory product.

[Insulation support panel 3 (FIG. 9)]
As shown in FIG. 2 (A), the heat insulating support panel 3 is a structure in which the concrete sleeve wall 5 is thermally cut off and connected to the concrete outer wall W. FIG. 9 (A) shows the heat insulating support panel 3. It is a perspective view of the state which connected two sheets above and below, and made the floor height 1h.
In the case where the panel 3 is used in a two-sheet connection, the heat insulating layer 3B of each panel is a foamed plastic heat insulating plate (extruded polystyrene foam) of JISA9511 which is the same quality as the heat insulating layer 2B of the composite panel 2. As shown in FIG. 9 (A), the width W3 is 200 mm, which is slightly wider (standard: 20 mm) than the thickness T5 (standard: 180 mm) of the concrete sleeve wall 5, and the thickness T3 is a composite panel heat insulating layer. The height of 3 mm is set to 75 mm, which is the same size as 2B, and 1350 mm, which is 1/2 of the floor height 1 h (2700 mm).

  And in the lower panel 3, it is the position of 150 mm (L5) from the lower end, and in the upper panel 3, it is the position of the thickness TA (200 mm) +150 mm (L5) of the living part floor slab SA from the upper end. In addition, a square fitting notch H4 having a side W4 of 60 mm is perforated so that one non-combustible support block 40 having a length of 900 mm and a 16 mm diameter deformed steel bar can be arranged as the connecting bar 6, and FIG. As shown in FIG. 5, the connecting bar 6 of the lower panel 3 is 150 mm (L5) above the upper surface Sf of the balcony floor slab SB, and the connecting bar 6 of the upper panel 3 is 150 mm (L5) from the lower surface Sd of the balcony floor slab SB. It is located below.

Further, the non-combustible support block 40 may be fitted and fixed to the heat insulating support panel 3 at the stage where the panel 3 is erected in the sleeve wall form or at the preparation stage of the panel 3, but the width (X40) is 50 mm and high. As shown in FIG. 9 (A), a gap following sheet 12A having a thickness of 2 mm is wound around the four circumferential surfaces of the non-combustible heat insulating material 40B having a thickness (Z40) of 50 mm, and the side W4 formed on the heat insulating layer 3B is 60 mm. If the non-combustible heat insulating material 40B is fitted in the fitting notch H4, the non-combustible heat insulating material 4B can be air-tightly fitted and fixed to the heat insulating layer 3B of the heat insulating support panel 3 due to the time-dependent expansion of the gap following sheet 12A.
Further, the protruding portion AP of the connecting bar 6 may be bent at 90 ° for fixing in the outer wall W as shown in FIG.
In addition, at the center of the width of both sides 3L and 3R of the heat insulating layer 3B, as shown in FIG. 9A, a slit with a width of slightly over 3 mm (standard: 3.2 mm) and a depth of over 40 mm (standard: 45 mm) is provided. The groove 3G is disposed.

[Composite panel 2 (Fig. 6)]
The general wall composite panel 2 is a panel used also as the composite panel 2 (processed composite panel 2) employed at the balcony arrangement position, and covers the general wall portion of the concrete outer wall W with a breathable outer heat insulating coating.
That is, as shown in FIG. 6A, the general panel 2 has a width BW of 500 mm, a thickness T3 of 75 mm, and a height 1 h of 2700 mm (standard floor height) as a base material for the exterior. Molded cement board 2A with AW of 490mm, thickness T2 of 25mm and height of 2697mm, heat insulation layer 2B protrudes 20mm (d4) at the upper end, enters 17mm (d4 ') at the lower end, and heat insulation layer in the width direction 2B protrudes 20 mm (d3) on the left side 2L, and is layered and integrated into a shape that enters 10 mm (d2) on the right side 2R. In the upper and lower connecting parts of the composite panel 2, 3 mm (3 mm ( d4-d4 ′) is generated, and a vertical joint of 10 mm (d3-d2) is formed at the left and right connection portions. The top, bottom, left and right can be connected to each other, and the separator insertion holes hs and bolts are in place. An insertion hole hb is arranged. .

And as a heat insulation layer 2B, the extrusion method polystyrene foam of JISA9511 is employ | adopted, and the standard DECF panel (Mitsubishi Material Building Materials Co., Ltd., brand name) is employ | adopted as a shaping | molding cement board 2A.
That is, in the molded cement board 2A, as shown in FIG. 6C, a ventilation groove G having a width a1 of 30 mm and a depth Gd of 13 mm is formed on the layering surface 2S, and the thick portion 2C having a width a2. The thick portions 2C having a width a3 (45 mm) are alternately arranged at both ends in the width direction, and the thick portions 2C having a width a4 (40 mm) are positioned at the center.
As shown in FIG. 6 (C), the groove G group is arranged in a trapezoidal section with two sections on both ends of the formed cement board 2A and two sides on the center thick part 2C having a width of 40 mm (a4). It is a groove.

[Composite panel for balcony 2 (Fig. 6)]
As shown in FIG. 6 (B), the composite panel 2 used for constructing the balcony floor slab SB has only a fitting notch H1 formed at the center of the upper end of the composite panel 2 for general walls.
That is, as shown in FIGS. 6 (B) and 6 (C), the fitting notch H1 is positioned at the center thick portion 2C (width a4: 40 mm) of the molded cement plate 2A from the upper end of the panel with a width W4 (60 mm). Then, a rectangular long groove having a depth of 4 h of 200 mm is cut and prepared.

[Z muscle 1 (FIG. 5B)]
The Z bar 1 is a support steel bar that cantilever-supports the balcony floor slab SB, and the Z bar 1 itself includes a Z upper bar 1U and a Z lower bar 1D, as shown in FIG. A horizontal upper side 1U ′, an intermediate inclined portion 1S on both sides inclined downward at an angle θ of 45 ° from both ends of the horizontal upper side 1U ′, and a horizontal lower side 1D ′ extending outward from the lower end of the intermediate inclined portion are provided. The trapezoidal Z truss bar 1M maintains the stress center distance (distance between the axis of the Z upper bar 1U and the axis of the Z lower bar 1D) L15, the horizontal upper side 1U 'on the lower surface of the Z upper bar 1U, and the horizontal lower side. The portion 1D ′ is brought into contact with the upper surface of the Z lower rebar 1D, and is welded and integrated from both sides.

The Z bar 1 is a member that supports the reinforced concrete balcony floor slab SB in a cantilevered form as a connecting bar of the non-combustible support block 4 that is fitted and fixed to the heat insulating layer 2B of the composite panel 2. The diameter, the length, and the arrangement interval of the Z bars 1 may be determined based on the load structural calculation of the balcony floor slab SB.
That is, the bending moment M is represented by a general formula: M = at × ft × j.
Here, at is the cross-sectional area of the tensile reinforcing bar, ft is the allowable tensile stress degree of the reinforcing bar, and j is the stress center distance of the bending material.
As is apparent from the above general formula, even if a reinforcing bar with the same diameter is adopted, the value of the stress center distance of the steel bar is extremely important for improving the supporting force. Therefore, in the present invention, as shown in FIG. As described above, the intermediate sloping portion 1S of the Z truss bar 1M is secured at a necessary concrete covering thickness under the condition of 45 ° inclination, and the maximum stress center distance L15 is ensured.

In this case, if a steel bar having a diameter of 22 mm is used for the Z upper bar 1U and the Z lower bar 1D, and the Z upper bar 1U and the Z lower bar 1D are fixed and integrated with a distance L14 of 70 mm, the Z upper bar 1U. The center distance L15 of stress between the Z lower end reinforcement 1D can be 92 mm.
And the diameter and length of the steel bars are cantilevered in the form of a vertical plate and cantilevered in the form of a horizontal plate rather than the concrete sleeve wall 5 where the lower end is supported by the foundation F, so safety is more important. 1 is determined from the performance (displacement: 1/400 or less) and economic efficiency applied to a balcony floor slab SB, but the balcony floor slab SB having a depth LB of 1500 mm and a thickness TS of 180 mm in FIG. Table 1 below shows the calculation comparison of diameters 19 mm, 22 mm, and 25 mm of the bar steel used for the Z bar 1 when supported by the bar 1 group.

[Table 1]
Diameter 19mm Diameter 22mm Diameter 25mm
Total length (mm) of Z upper end muscle 1U 1276 1200 1144
Overall length (mm) of Z lower end muscle 1D 793 760 727
Weight (kg / location) 5.0 6.3 7.3
Application price (yen / location) 298 381 475
Strength margin 38% 54% 64%
Displacement of balcony tip (mm) 3.7 2.7 2.0
It is the contact part between the living part floor slab SA and the heat insulating layer 2B, in the center between the sleeve walls 5 on both sides.
Displacement (mm) 0.3 0.3 0.3
Displacement 1/348 1/458 1/580

The Z truss bars 1M are all formed of a deformed steel bar having a diameter of 16 mm in the same form.

  Therefore, the concrete floor slab SB according to the embodiment of the present invention has one Z-strip on one composite panel 2 having a panel width BW of 500 mm in a floor slab SB having a depth LB of 1500 mm and a floor slab thickness TS of 180 mm. In order to arrange the Z bars 1 group at intervals of 500 mm, the Z bars 1 are made of a deformed steel bar having a diameter of 22 mm and a length L10 of 1200 mm as a Z upper end bar 1U as shown in FIG. A deformed steel bar with a length L12 of 760 mm is used as the Z bottom bar 1D, and as a Z truss bar 1M, a steel bar with a diameter of 16 mm, the intermediate inclined part 1S on both sides is inclined 45 °, the trapezoidal height L14 is 70 mm, and the horizontal upper side 1U ′ and horizontal lower side 1D ′ are 80 mm each, the horizontal upper side 1U ′ of the Z truss bar 1M is in contact with the lower surface of the Z upper bar 1U, and the horizontal lower side 1D ′ of the Z truss bar 1M is Z Abutting on the upper surface of the lower end 1D, the Z upper end The distance L14 between the U and Z lower stripes 1D is set to 70 mm, the contact portions are welded from both sides and integrated with the fixing portions ZU and ZD (FIG. 10B), and the Z upper stripe 1U and the Z lower stripe 1D are In the meantime, a Z-strip 1 having a stress center distance L15 of 92 mm is produced.

And, as shown in FIG. 5 (B), the epoxy resin fire coat undercoat material (ESK Kaken Co., Ltd., trade name) excellent in corrosion resistance, adhesion, and heat insulation is provided over the entire length of the Z-strip 1. The rust-preventive coating 1B is applied twice, and a SK fire-resistant coat (SK Co., Ltd., trade name) is further applied as a fire-resistant paint 1A to the portion located in the incombustible heat insulating layer 4B.
As shown in FIG. 7 (A), if the Z streaks 1 are arranged on one of the 500 mm wide composite panels 2 for a balcony, that is, at intervals of 500 mm, the balcony floor slab SB of the embodiment is 58% Safely cantilevered with sufficient strength.

[Non-combustible support block 4 (Fig. 5)]
FIG. 5A is a perspective view of the incombustible support block 4, and FIG. 5B is an exploded perspective view of the incombustible support block 4.
As shown in FIG. 5 (A), the incombustible support block 4 has a thickness Y4 of 100 mm which is the same size as the thickness T1 of the composite panel 2, and a height Z4 of a depth 4h of the fitting notch H1 of the heat insulating layer 2B. A non-combustible heat insulating material 4B having the same size (standard: 200 mm) and a width of X4 (50 mm) facing the heat insulating layer 2B and X3 (40 mm) facing the cement board 2A penetrates and holds one of the Z bars 1. Is.
As the incombustible heat insulating material 4B, a lock cell board (Fuji Kasei Kogyo Co., Ltd., trade name) made of calcium carbonate foam is used.

That is, as shown in FIG. 5 (B), cut out from the lock cell board (trade name), the heat insulating layer 2B facing part is width X4 (50 mm), the molded cement board 2A facing part is width X3 (40 mm), and molded. A block-type non-combustible heat insulating material 4B in which a vent groove G4 is cut out at the portion facing the groove G of the cement board 2A is divided into two in the width direction to form two plane-symmetric non-combustible heat insulating material pieces 4B '. In the cut inner surface 4D of the heat insulating material piece 4B ′, the fitting groove H2 for the Z upper end muscle 1U constituting the Z line 1 and the fitting groove H2 ′ for the horizontal upper side 1U ′ of the Z truss line 1M are symmetrically provided on the cut inner surface 4D. The fitting grooves H3 for the Z lower end bars 1D are formed so that the fitting grooves H2, H2 ', H3 are slightly larger (standard: 6 mm) than the diameters of the respective fitting bars (1U, 1D, 1M).
The vertical position of the fitting grooves H2, H2 ′, H3 in the non-combustible heat insulating material piece 4B ′ may be determined from the balcony floor slab thickness TS (180 mm) and the concrete covering thickness of the Z reinforcement 1, and the Z upper end reinforcement. The upper end of 1U may be 53 mm below the upper end of the incombustible heat insulating material 4B, and the lower end of the Z lower end bar 1D may be 33 mm above the lower end of the incombustible heat insulating material 4B.

In this case, if a table type polystyrene foam cutter is used, desired fitting grooves H2, H2 ', and H3 can be formed smoothly.
Next, in the central part of the Z-strip 1 at two positions before and after the incombustible heat insulating material 4B, that is, the position of the noncombustible heat insulating material 4B at a small distance d12 (standard: 10 mm) from the front surface F4 position LF-LF. A gap follower sheet 12A (Sekisui Chemical Co., Ltd., Softlon (trade name)) having a thickness of 2 mm and a width of 20 mm is wound around the rear surface B4 position LB-LB at a small distance d12 (standard: 10 mm). Apply an adhesive to the inner surface 4D of both non-combustible heat insulating material pieces 4B ', and fit Z-strips 1 into the fitting grooves H2, H2', H3 of the non-combustible heat insulating material pieces 4B 'on both sides to divide the non-combustible heat insulating material. The piece of material 4B ′ is fixedly integrated with one incombustible heat insulating material 4B.

The gap following sheet 12A expands with time in the thickness direction in the integrated non-combustible heat insulating material 4B, fills the gap between the Z stripe 1 and the fitting grooves H2, H2 ′, H3, and the Z stripe 1 Hold.
Next, by filling the fitting grooves H2, H2 ′, H3 of the non-combustible heat insulating material 4B with the fireproof sealing 13 from the front surface F4 side and the rear surface B4 side using a conventional sealing gun, the inner clearance follower sheet 12A and the outer fireproof sealing 13 make the non-combustible support block that elastically holds the Z-strip 1 and air-tightly holds the Z-strip 1 in the non-combustible heat insulating material 4B.
In addition, if a clearance gap arises between the joint surfaces of the nonflammable heat insulating material pieces 4B 'on both sides, the fireproof sealing 13 may be filled in the clearance.

Next, as shown in FIGS. 5 (A) and 7 (B), the incombustible heat insulating material 4B that is fixed and integrated includes the front end of the both sides 4S, the position facing the plate-like portion Pd of the molded cement plate 2A, the heat insulation. A gap following sheet 12A (20 mm width, 2 mm thickness) with a protective sheet is attached to the upper end, front end, and rear end positions of the layer 2B facing portion, and a protective sheet is also provided on the lower surface of the incombustible support block 4. The double-sided adhesive tape 12B is adhered and prepared as a factory product.
Of the width X3 (40 mm) of the incombustible heat insulating material 4B, there is a gap with the width (60 mm) of the fitting notch H1 at the position opposed to the molded cement plate 2A plate-like portion Pd. As in B), the 2 mm-thick gap following sheet 12A may be stacked two times.

[Cross joint 7 (FIG. 10C)]
FIG. 10C is a perspective view of the cruciform joint 7. The cruciform joint 7 is a breathable cruciform joint developed by the present inventor for connecting a breathable heat-insulating composite panel. Japanese Patent Application No. 2005-289892 Use what was disclosed in.
That is, as shown in FIG. 10C, the cruciform joint 7 to be employed includes horizontal contact pieces 7F on both sides for placing between the grooves G at the upper end of the cement plate 2A of the composite panel 2, and the grooves. It is a plastic molded product having a general thickness of 3 mm, which has a cross shape in front view, and is composed of upper and lower vertical pieces 7W to be fitted into G. Inside the vertical piece 7W, there is a ventilation groove G7 penetrating vertically. It is provided.
As for the dimensional relationship, the protruding length of the vertical piece 7W is 50 mm on the upper side and 30 mm on the lower side, and a horizontal abutting piece 7F having a thickness of 3 mm is extended to the left and right, the vertical height is 83 mm, and the vertical piece 7W. The depth thickness 7T of the horizontal abutment piece 7F is 11.8 mm, and the horizontal abutment piece 7F protrudes 20 mm to the left and right.
The upper and lower ends of the vertical piece 7W are tapered in such a manner that the function of the ventilation groove G7 is not lost on the upper and lower ends of both side surfaces 7S in order to facilitate the insertion into the groove G.

[Construction of outer wall structure]
In the general wall portion of the concrete outer wall W, a close-contact type breathable composite panel 2 having a floor height of 1h (2700 mm) is formed with a molded cement board 2A as an outer surface and a step d3 (20 mm) by both side edges. And d2 (10 mm), a concrete frame form is constructed by a conventional method by using a phase-separated connection by contact of the heat insulating layer 2B.
Further, in the protruding portion of the balcony B, the composite panel 2 in FIG. 6B, that is, the height of 4 h (200 mm) that does not interfere with the base end Bb surface of the balcony floor slab SB at the center of the upper panel. A concrete wall formwork was constructed by standing up as a scraped frame with a composite panel 2 in which a depth notch H1 having a width W4 (60 mm) was cut open at a depth, and a balcony floor outward from the formwork The slab formwork is projected horizontally using a conventional method.

In this case, since the heat insulating layer 2B enters d2 (10 mm) on the right side 2R of the composite panel 2, the left side 3L of the sleeve wall heat insulating support panel 3 can be supported.
The side surface of the heat insulating layer 2B that comes into contact with the heat insulating support panel 3 for the sleeve wall receives the heat insulating layer 2B from the exterior base material 2A so as to receive the protruding portion P3 (10 mm) of the heat insulating support panel 3 as necessary. A slit groove 2G is cut into the center of the thickness of the side surface of the composite panel heat insulating layer 2B.
And the composite panel 2 for the balcony formwork set up by the formwork has a fitting width notch H1 having a central width W4 of 60 mm. The width X4 shown in FIG. The non-combustible support block 4 having the gap follower sheet 12A having a thickness of 2 mm is peeled off from the curing paper (protective sheet) of the gap follower sheet 12A on both sides and the cured paper of the double-sided adhesive tape 12B on the lower face. , (B), the incombustible support block 4 is fitted and seated in alignment with the heat insulating layer 2B.
In this case, the gap following sheet 12A has a gap between the incombustible heat insulating material 4B (width X4: 50 mm) in the wide portion and the heat insulating layer 2B in the fitting notch H1 (width W4: 60 mm), and the incombustible heat insulating material 4B in the narrow width portion. The gap between (width X3: 40 mm) and the molded cement plate 2A of the fitting notch H1 is closed by expansion over time.

  Next, the projecting portion AP of the Z line 1 projecting into the living part floor slab form and the projecting part BP of the Z line 1 projecting into the balcony floor slab form from the incombustible support block 4 Then, a conventional spacer (not shown), a heat insulator cone 11A, and an anchor 11B are held in position, and in a conventional manner, vertical stripes 8A, transverse stripes 8B, and width stop stripes 8C are placed in the outer wall formwork. In the balcony floor slab formwork, the long side direction upper end reinforcement 9A, the long side direction lower end reinforcement 9B, the short side direction upper end reinforcement 9C, and the short side direction lower end reinforcement 9D are provided, and the necessary rebars are also provided in the living part floor slab formwork. Arrangement is made, and the protrusions AP and BP of the Z-strip 1 are respectively connected with the reinforcement in the mold and the wire as necessary.

In addition, the concrete sleeve wall form is constructed by projecting from the outer wall form by a conventional method, and the base end in the sleeve wall form is supported in a non-combustible manner by a fitting notch H4 as shown in FIG. 9A. As shown in FIG. 3 (A), the heat insulation support panel 3 fitted with the block 40 and the heat insulation support panel 3 fitted with the non-combustible support block 40 in the fitting notch H4 at the upper end have a height of 3h. Is arranged in a vertically connected form of the heat insulating support panel 3 of 1350 mm, and the heat insulating layer 3B is connected to the composite panel heat insulating layer 2B of the adjacent balcony floor slab form frame and the joining plate 3A as shown in FIG. Align it.
In this case, if the composite panel heat insulation layer 2B on both sides is the entry surface, the protrusions P3 on both ends of the heat insulation layer 3B enter the entry surfaces 2L and 2R of the composite panel heat insulation layer 2B on both sides, and the protrusion P3 is the composite panel. This is preferable because the outer base material 2A is abutted and supported.
At the protruding corner of the outer wall W, as shown in FIG. 10 (A), the contact surface of the heat insulating layer 2B of the composite panel 2 with the heat insulating layer 3B on the inner surface is cut to enter the entrance surface 2L. 3A and the slit groove 2G ′ are arranged, the joining plate 3A can be applied.

In this case, as shown in FIG. 4 and FIG. 10 (A), the KP control provided with the separator 10H ′, which is commonly used from both the front and rear sides, at the upper and lower joints J3 of the heat insulating support panels 3 and at appropriate vertical intervals. (Cone for heat insulating material) 11A sandwiches the heat insulating support panel 3 and fixes it in the reinforcing bar with the anchor 11B so that the joint portion J3 and the appropriate position of each heat insulating support panel 3 can resist concrete pressure.
Then, as shown in FIG. 10A, one protrusion AP of the single connecting bar 6 protruding from the heat insulating support panel 3 is in the concrete frame form and the other protrusion BP is in the sleeve wall form. The position is held by a spacer (not shown), a heat-insulating cone 11A, and an anchor 11B, and necessary reinforcement is placed in the sleeve wall mold by a conventional method.
In this case, as shown in FIG. 4, the longitudinal upper end stripe 9A and the longitudinal lower end stripe 9B in the balcony floor slab form are fixed in the sleeve wall form.

In addition, when forming the sleeve wall 5, the heat insulating support panel 3 of the intermediate sleeve wall 5 is bent at 90 ° laterally at the protrusion AP of the connecting bar 6 and fixed to the tip as shown in FIG. The plate 6C is fixed, and the bent protrusion AP is fixed in the mold of the outer wall W.
Further, the slab RB may be framed in the same manner as the balcony floor slab SB, and the heat insulating layer 3B ′ of the base end P′b of the roof parapet P ′ is also the same as the heat insulating support panel 3 of the sleeve wall 5 Therefore, the necessary connecting bars 6 may be additionally arranged.
In this case, in the heel slab RB, as shown in FIG. 2 (C), if the Z bars 1 are arranged 150 mm (L9) from the concrete surface of the sleeve wall 5 and spaced 300 mm (L8), 420 kg / m ² (snow cover) 1400 mm) load resistance is possible.

  After the necessary reinforcing bar arrangement and fixing in each concrete formwork, if concrete is placed on each outer wall formwork, balcony floor slab formwork and sleeve wall formwork, as shown in FIG. The balcony floor slab SB has a base end Bb thermally insulated from the outer surface Wf of the concrete outer wall by the heat insulating layer 2B of the composite panel 2, and the reinforced concrete sleeve wall 5 has the base end 5b by the heat insulating layer 3B of the heat insulating support panel 3 and the concrete outer wall. The outer wall Wf is cut off from the heat and attached to the lower end, and the lower end is supported by the foundation F. The outer wall of the concrete outer wall W is covered with the heat insulating layer 2B of the air-permeable composite panel 2, and the balcony floor slab An outer wall structure in which the side end Bs of the SB and the side end Ps of the balcony parapet are rigidly joined to the concrete sleeve wall 5 is obtained.

The construction of the concrete balcony floor slab SB on the upper floor may be performed in the same manner as the existing balcony floor slab SB on the lower floor.
Then, when constructing the upper floor balcony floor slab SB, as shown in FIG. 10 (B), each composite panel 2 integrated with the lower floor balcony floor slab SB has two trapezoidal grooves G at the upper left and right sides. 10C, the lower vertical piece 7W of the cross joint 7 is inserted, and the plate-like portion Pd (width: 12 mm) at the upper end of the cement plate 2A has the same width as the plate-like portion Pd. 3mm-thick butyl rubber plate PR is stuck and extended, and the upper panel composite panel 2 is aligned with the lower panel composite panel 2 by fitting the lower end of the groove G to the upper vertical piece 7W of the cross joint 7. Connect up and down.

  In the obtained outer wall structure, the entire exposed surface Wf of the concrete outer wall W is heat-insulated with the breathable composite panel 2, and the outer wall is heat-insulated and the water vapor inside the concrete frame CF is absorbed by the panel 2. It is a high-quality building that is spontaneously discharged through the ventilation groove G group, has no internal condensation, has reduced mold and mites, and has excellent heat-saving and durability due to external insulation.

Projections such as balconies and sleeve walls from the outer wall W are cantilevered by the concrete frame CF with the base end Bb having only the Z-strip 1 group, and the side ends Bs are sleeves. The wall 5 is rigidly connected and integrated, and the sleeve wall 5 is cantilevered by the concrete frame CF with the base end 5b only of the connecting bars 6 and the lower end is integrated with the foundation F 'via the foundation beam FG. Projections with protrusions are in the form of square tubes (honeycomb shape) and form a heat shield with the concrete outer wall W. Therefore, the protrusions from the concrete outer wall W have a uniform thermal bridge effect on the concrete building frame CF and are fireproof. And is firmly supported.
Therefore, according to the present invention, it is possible to construct a reinforced concrete projecting structure from a reinforced concrete exterior heat insulating building with a fireproof and strong support form under the suppression of the thermal bridge action. The protrusion attachment can be freely attached as desired.

[Others]
When the concrete balcony floor slab SB and the concrete sleeve wall 5 are attached to the reinforced concrete building frame CF, the center distance LA between the concrete sleeve walls 5 on both sides supported by the both ends of the balcony floor slab SB, the thickness of the sleeve wall 5 is provided. In the structural calculation based on the length T5, the thickness TS of the balcony floor slab SB, etc., it is determined whether the wall longitudinal bars 8A in the sleeve wall 5 are single reinforcing bars or double reinforcing bars, the shape of the sleeve wall supporting connecting bars, the number, the balcony floor If the distance between the Z bars 1 in the slab and the distance from the sleeve wall side surface 5f, that is, the balcony floor slab side edge Bs, to the balcony supporting Z bars, the balcony floor slabs of various sizes with guaranteed safety are obtained. SB can be constructed.
Table 2 shows the estimated conditions for constructing various sizes of balcony floor slabs SB.

[Table 2]
Center-to-center distance between sleeve walls>3500>5000>6000> 7000
LA (mm) 5000 or less 6000 or less 7000 or less 80000 or less Thickness of sleeve wall 5 T5 1,2 stories 120 Both ends 200
(Mm) 3-5 stories 150 180 Center 180 180
Balcony floor slab SB
Thickness TS (mm) 180 180 200 180
Reinforcement form of sleeve wall 5 Single (single) Double (double) Double (double) Double (double)
Bar arrangement bar arrangement bar arrangement bar arrangement
For floor height of connecting bar 6 For floor height For floor height For floor height
Shape and number 2 in single form 2 in single form 3 Z line 1 3 Z line 1 3
Balcony floor slab SB
Z-strip 1 spacing interval (mm) 1000 1000 1000 500
Balcony from sleeve wall surface 5f
Distance to support Z-strip 1 (mm) 500 500 500 250

When the distance LA between the centers of the sleeve walls 5 is greater than 3500 mm and less than or equal to 5000 mm:
The wall thickness T5 of the sleeve wall 5 is 120 mm in the 1st and 2nd floor buildings, and 150 mm in the 3rd to 5th floors. The bar reinforcement 8A in the sleeve wall 5 is single (single). This is because the burden on the balcony floor slab SB supported by the sleeve wall 5 is reduced because the center-to-center distance LA is short.
Moreover, the reason why the lower limit of the center distance LA between the sleeve walls 5 is set to 3500 mm is that the sleeve walls 5 are installed at the boundary with the adjacent door from the use of the balcony B. .
The thickness TS (180 mm) of the balcony floor slab SB, the shape and number of the connecting bars 6, and the arrangement interval of the Z bars 1 of the balcony floor slab SB may be the same as in the embodiment.

When the distance LA between the centers of the sleeve walls 5 is more than 6000 mm and 7000 mm or less:
(B) The wall thickness T5 of the sleeve walls 5 at both ends becomes as large as 200 mm. This is because the balcony wall slab SB is attached to only one side of the sleeve walls 5 at both ends, and the center distance LA becomes long. This is because the balance has deteriorated.
(B) The thickness TS of the balcony floor slab SB becomes as large as 200 mm. This is because the sectional moment of the horizontal plate (balcony floor slab) is increased by increasing the center distance LA, This is to resist bending and bending.
(C) In the connecting bars, three Z bars 1 or connecting bars 6 that support the balcony floor slab SB are arranged in the floor height 1h (2700 mm), so that the roof floor slab RS and the upper sleeve wall 5 This is because the axial force and the load on the balcony floor slab SB are partly transmitted to the concrete frame CF via the Z bars 1 and the distance between the centers of the sleeve walls 5 is increased.
In addition, the space | interval of the Z reinforcement 1 which supports the reinforcement (double reinforcement) in the sleeve wall 5 and the balcony floor slab SB is the same as that of an Example.

When the distance LA between the centers of the sleeve walls 5 is more than 7000 mm and less than 80000 mm:
(D) The distance between the Z-stripes 1 of the balcony floor slab SB support is reduced (half).
This is because the distance LA between the centers of the sleeve walls 5 is increased, so that most of the load on the balcony floor slab SB is not transmitted to the sleeve walls 5 and only the vicinity (approximately 1700 mm) of the sleeve walls 5 is provided. 5 is transmitted.
(E) In place of the single connecting bar 6, the Z bar 1 supporting the balcony floor slab SB is adopted as the connecting bar.
This is because the distance LA between the centers of the sleeve walls 5 has increased. By adopting three Z bars 1, a part of the load on the balcony floor slab SB and a part of the axial force from above are used. Since it is transmitted to the concrete frame CF, the load on the foundation beam FG and the foundation F is reduced, and the cross-sectional shape and the amount of bar arrangement are reduced.
The upper limit of the distance LA between the centers of the sleeve walls 5 is set to 80000 mm, based on the standards of the Architectural Institute of Japan. For longer buildings, an expanded joint (a structure such as a building is physically separated). This is because, in principle, separate structures are used to control the changes in the housing due to temperature changes and vibrations, or changes due to ground subsidence, etc., and in principle, separate structures are used.

From Table 2 above, if the distance LA between the centers of the sleeve walls 5 is 6000 mm to 80000 mm, the connecting bars for supporting the sleeve walls 5 are preferably the Z bars 1, and in this case, the insulation support panel 3 of the sleeve walls 5 May be fitted with the non-combustible support block 4 shown in FIG.
Further, in the embodiment, the balcony floor slab SB is projected from the living part floor slab SA in a projecting form, but the Z-strip protrusion AP of the heat insulating support panel 4 is bent by 90 ° and fixed in the concrete outer wall W. In this case, the balcony floor slab SB is effective as a coping means when there is a step difference from the residential floor slab SA.

  In the embodiment, the heat insulating support panel 3 has the same thickness T3 as the heat insulating layer 3B (T3) 75 mm of the composite panel 2 as shown in FIG. However, as a modification, the heat insulating layer 3B is prepared with a heat insulating layer plate having a thickness T1 (100 mm) of the composite panel 2 and a width W3 (200 mm), on both sides of the front surface. If an angle notch in the top view is provided over the entire length in the vertical direction, the same depth as the cement plate thickness T2 (25 mm) and the same width as the heat insulating layer protrusion P3 (10 mm) in FIG. The angle notch on the front surface of the heat insulating layer 3B forms the heat insulating layer protrusions P3 on both sides 3L and 3R of the heat insulating layer 3B shown in FIG. 10 (A).

In the composite panel 2 that contacts both sides, the entrance surfaces 2L and 2R of the heat insulating layer 2B abut against the protruding portions P3 on both sides of the heat insulating layer 3B, and the protruding ends of the cement plates 2A of the composite panel 2 on both sides However, it fits into the angle notch and supports the angle notches on both side edges of the heat insulating layer 3B, and the support form is the same as the support by the cement plates 2A at both ends of the heat insulating layer 3B shown in FIG.
Accordingly, it is possible to effectively counteract the pressure displacement action on the heat insulating layer 3B caused by the concrete pressure, which is generated by placing the concrete in the outer wall formwork.
Moreover, since the thickness of the heat insulating layer 3B, that is, the thickness of the heat insulating support panel 3 is the same as the thickness of the composite panel 2 (100 mm), The workability of the parallel contact arrangement is improved from that of FIG.

It is a partially cutaway perspective view of the outer wall structure of the present invention. It is explanatory drawing of the outer wall structure of this invention, Comprising: (A) is a principal part cross-sectional view, (B) is a principal part longitudinal cross-sectional view, (C) is the arrow CC view of (B). BRIEF DESCRIPTION OF THE DRAWINGS It is principal part explanatory drawing of this invention, Comprising: (A) is a longitudinal cross-sectional view of a sleeve wall, (B), (C) is fixing form explanatory drawing of the balcony floor slab muscle to a parapet, respectively. It is relationship explanatory drawing of the sleeve wall of this invention, and a balcony floor slab, Comprising: (A) is a longitudinal cross-sectional view, (B) is the B section enlarged view of (A), (C) is the C section expansion of (A). FIG. It is explanatory drawing of the nonflammable support block 4 used for this invention balcony floor slab, Comprising: (A) is a perspective view, (B) is an exploded perspective view. It is explanatory drawing of the composite panel used for this invention, Comprising: (A) is a partially cutaway side view of the composite panel for general walls, (B) is a partially cutaway perspective view of the composite panel for balcony floor slabs, (C) is It is a top view of (B). It is explanatory drawing which integrated the nonflammable support block 4 with the composite panel for balcony floor slabs of this invention, Comprising: (A) is a partially cutaway perspective view, (B) is a principal part expanded top view of (A). It is explanatory drawing of the nonflammable support block 40 used for the heat insulation support panel for sleeve walls of this invention, Comprising: (A) is a whole perspective view, (B) is a disassembled perspective view. It is explanatory drawing of the heat insulation support panel for sleeve walls of this invention, Comprising: (A) is a perspective view of the state which fitted the nonflammable support block 40, (B) is the heat insulation layer before fitting the nonflammable support block 40. A perspective view and (C) are front views of connecting bars used for the non-combustible support block 40. It is a principal part enlarged view of this invention, Comprising: (A) is a cross-sectional view of a sleeve wall base end part, (B) is a longitudinal cross-sectional view of a balcony floor slab base end part. It is explanatory drawing of the prior art example 1, Comprising: (A) is a balcony longitudinal cross-sectional view, (B) is a reinforcing bar unit front view, (C) is a reinforcing bar unit top view. It is a prior art example, (A) is a cross-sectional view of the prior art example 2, (B) is a vertical cross-sectional view of the prior art example 2, (C) is a cross-sectional view of the prior art example 3, (D) is a prior art. 10 is a longitudinal sectional view of Example 3. FIG.

Explanation of symbols

1 Z-strip (connector)
1A Fireproof paint 1B Rust prevention paint 1D Z lower end 1D 'Horizontal lower side 1M Trapezoid Z truss (Z truss)
1S Intermediate inclined part 1U Z upper end line 1U 'Horizontal upper side part 2 Composite panel (breathable heat insulating composite panel, panel)
2A Molded cement board (cement board, exterior base material)
2B, 3B, 3B 'Heat insulation layer 2C Thick part 2G, 3G Slit groove 2S Layer surface 3 Heat insulation support panel for sleeve wall (heat insulation support panel, support panel)
3A Bonding plate 4 Non-combustible support block for balcony (non-combustible support block)
4B, 40B Incombustible heat insulating material 4B ', 40B' Incombustible heat insulating material pieces 4D, 40D Symmetrical inner surface (inner surface)
4S, 40S Incombustible heat insulating material side surface (side surface, outer periphery)
5 Reinforced concrete sleeve walls (concrete sleeve walls, sleeve walls)
5B Rooftop thermal insulation layer 5b Sleeve wall base end (base end)
6 Single connecting bars (connecting bars)
6C Fixing plate 7 Cross joint 7F Horizontal contact piece 7S Side face 7W Vertical piece 8A Wall vertical line (vertical line)
8B Transverse wall (transverse)
8C, 8C 'width stop

9A Long side upper end bar 9B Long side lower side bar 9C Short side upper side bar 9D Short side lower side bar 9E Auxiliary bar 9F Beam main bar 9G Knee bar 10H 'Separator 11A KP Con (insulation cone)
11B Anchor 12A Gap following sheet 12B Double-sided adhesive tape 13 Fireproof sealing 14A Thermal insulation anchor 14B Bolt 16A Sealing 16B Backup material 40 Nonflammable support block for sleeve wall (nonflammable support block)
A living part
AP, BP Connecting muscle protrusion (protrusion)
B Balcony Bb Balcony base end (base end)
Bs Balcony floor slab side edge (side edge)
CF concrete building frame (concrete frame, frame)
F Foundation FG Foundation beam G Ventilation groove (groove)
G4 Vent groove G7 Vent groove H1, H4 Fitting notches H2, H2 ', H3, H5 Connecting bar fitting groove (fitting groove)
hb Bolt insertion hole hs Separator insertion hole J3 Vertical joint (joint)
LA Center distance between sleeve walls (center distance)
L15 Stress center distance (center-to-center distance)
P, P 'Parapet P'b Parapet base end Pd Plate-shaped part PR Rubber plate (Butyl rubber plate)
P3 Heat insulation layer protrusion (protrusion)
RB Sakai slab RS Roof floor slab SA Residential floor slab SB Balcony floor slab Sd Balcony floor slab bottom surface (floor slab bottom surface)
Sf, Sf 'Concrete floor top (floor slab top)
W Concrete outer wall (outer wall)
Wf Outer wall surface (surface)
ZD, ZU fixed part

Claims (14)

  An outer wall structure in which a reinforced concrete balcony floor slab (SB) and a reinforced concrete sleeve wall (5) protrude from a concrete outer wall (W) of a reinforced concrete outer heat insulating building, and the concrete outer wall (W) Outer insulation coating by composite panel (2) in which insulation layer (2B) is laminated on layering surface (2S) of molded cement board (2A) in which grooves (G) and thick parts (2C) are alternately arranged vertically The balcony floor slab (SB) is fitted to the composite panel (2) by thermally insulating the entire base end (Bb) from the outer wall surface (Wf) by the heat insulating layer (2B) of the composite panel (2). One protrusion (AP) of the connecting bars (1, 6) passing through the non-combustible heat insulating material (4B) of the non-combustible support block (4) is placed in the concrete frame (CF), and the other protrusion (BP) is Fixed in the balcony floor slab (SB) Then, with respect to the concrete frame (CF), only the connecting bars (1, 6) are cantilevered and the side ends (Bs) are supported by the sleeve walls (5), and the sleeve walls (5) The non-combustible support block (40) fitted to the heat insulating layer (3B) by thermally blocking the entire surface of the base end (5b) from the outer wall surface (Wf) by the heat insulating layer (3B) of the vertically long heat insulating support panel (3). ) Of the connecting bars (1, 6) penetrating the non-combustible heat insulating material (40B), one protrusion (AP) in the concrete frame (CF) and the other protrusion (BP) in the sleeve wall (5) To the concrete frame (CF), the connecting bars (1, 6) are used in a cantilevered form, and the lower end is supported by the foundation (F). The outer wall structure of a reinforced concrete exterior heat insulation building that is loaded on the foundation (F).   The base end (Bb) of the firewood slab (RB) and the base end (P'b) of the roof parapet (P ') projecting horizontally from the concrete housing (CF), the concrete housing (CF) and the heat insulation layer (2B, 3B)庇) Thermally shut off at 、) and only the connecting bars (1, 6) of the incombustible support block (4, 40) fitted to the heat insulating layers (2B, 3B '), the slab (RB) and the roof parapet (P The outer wall structure according to claim 1, wherein ') is provided projectingly on the concrete frame (CF).   In the composite panel (2), the heat insulating layer (2B) protrudes from the molded cement plate (2A) at the upper end and protrudes at a large step (d4), and at the lower end, enters a small step (d4 '), and the upper and lower phases are not connected. The rubber plate (PR) closes between the plate-like portions (Pd) of the molded cement plate (2A) at the upper and lower connecting portions, and the non-combustible heat insulating material (4B) ensures the ventilation function of the groove (G). The outer wall structure according to claim 1 or 2, which is fitted in the composite panel (2) in the form.   The non-combustible heat insulating material (4B) of the non-combustible support block (4) and the non-combustible heat insulating material (40B) of the non-combustible support block (40) are both in the fitting notches (H1, H4) of the heat insulating layers (2B, 3B). 4. The outer wall structure according to claim 1, wherein the outer wall structure is fitted and held in an airtight manner.   The composite panel (2) has a fitting notch (H1) having a depth (4h) extending from the upper end to the bottom surface (Sd) of the balcony floor slab at the thick portion (2C) position at the center of the width of the molded cement board (2A). The indented groove (G4) on both sides (4S) of the non-combustible heat insulating material (4B) fitted in the fitting notch (H1) has an open side surface of the groove (G) of the molded cement board (2A). The outer wall structure according to any one of claims 1 to 4, which faces each other.   The non-combustible support block (4) has a Z upper end line (1U) and a Z lower end line (1D), a central horizontal upper side part (1U '), an intermediate inclined part (1S) inclined downward on both sides, and a horizontal lower side on both sides. The trapezoidal Z truss bar (1M) consisting of the part (1D '), and the Z bar (1), which is integrally fixed while maintaining the stress center distance (L15) in the vertical direction, is airtight with the non-combustible heat insulating material (4B). The outer wall structure according to any one of claims 1 to 5, wherein the outer wall structure is fixedly held.   The heat insulation layer (2B) of the composite panel (2) that thermally blocks the balcony floor slab (SB) and the heat insulation layer (3B) that thermally shields the sleeve wall (5) are both the same material and the same thickness. The incombustible heat insulating material (4B) of the incombustible support block (4) and the incombustible heat insulating material (40B) of the incombustible support block (40) are made of the same material and the same thickness, and both are the composite panel heat insulating layer (2B). The outer wall structure according to any one of claims 1 to 6, wherein the outer wall structure has the same thickness.   The connecting bar (1) and / or the connecting bar (6) is fixed in the concrete outer wall (W) by bending the protrusion (AP) for fixing in the concrete frame (CF). 8. The outer wall structure according to any one of 1 to 7.   Using a breathable composite panel (2) in which a molded cement board (2A) having a group of ventilation grooves (G) is layered and integrated with the foamed plastic-based heat insulation layer (2B), In this case, the composite panel (2) is used as an outer wall formwork, and in the balcony floor slab (SB) protruding wall portion, the base end of the balcony floor slab (SB) is projected to the composite panel (2) from the upper end. A fitting notch (H1) over the height (4h) that interferes with the outer wall is formed into an outer wall formwork, and the fitting upper notch (H1) of the composite panel (2) has a Z upper end line (1U) and a Z lower end. Non-combustible support block in which the Z-strip (1) is integrated with the trapezoidal Z-truss (1M) while maintaining the center-to-center distance (L15) with the non-combustible heat insulating material (4B). (4) is fitted and fixed, and one projecting part (AP) of Z-strip (1) is on the side of the concrete frame In the frame, the other protrusion (BP) is placed in the balcony floor slab mold to form a conventional mold, and in the protruding wall of the sleeve wall (5), a fitting notch (H4) The heat-insulating support panel (3) in which is placed is erected in the form of contact with the composite panel heat-insulating layer (2B) over the entire height of the sleeve wall base end (5b). The non-combustible heat insulating material (40B) is fitted with a non-combustible support block (40) through which the single connecting bar (6) is held and fixed, and one protrusion (AP) of the single connecting bar (6) is concreted. In the frame formwork, the other protrusion (BP) is placed in the sleeve wall formwork to form a conventional sleeve wall formwork, and the longitudinal reinforcement in the balcony floor slab (SB) formwork ( 9A, 9B) is fixed in the sleeve wall formwork, and then concrete is placed in each formwork. From the concrete outer wall (W), Barco Over to project the floor slabs (SB) and return panel (5), the outer wall construction method of.   The non-combustible support block (4) and the non-combustible support block (40) are attached to the outer peripheries (4S, 40S) of the non-combustible heat insulating materials (4B, 40B) by attaching the gap following sheet (12A) to the notch (H1 , H4). The method for constructing the outer wall according to claim 9, wherein the outer wall is fitted and fastened in an airtight manner.   Slit grooves (3G, 2G) are arranged on the opposite side surfaces of the heat insulation support panel (3B) and the composite panel heat insulation layer (2B) of the heat insulation support panel (3) arranged at the base end of the sleeve wall formwork, (3A) is fitted over the slit groove (3G) of the heat insulating layer (3B) and the slit groove (2G) of the composite panel, and the heat insulating layer (3B) of the heat insulating support panel is inserted into the heat insulating layer (2B of the composite panel). The method for constructing an outer wall according to claim 9 or 10, wherein the outer wall is aligned and abutted on the outer wall.   The vertical connection of the composite panel (2) is made by using a cross joint (7) having a vertical piece (7W) having an upper and lower ventilation groove (G7) and an intermediate left and right horizontal contact piece (7F). The piece (7W) is inserted into the upper and lower grooves (G), the horizontal contact piece (7F) is sandwiched between the thicker parts (2C) of the upper and lower panels, and the formed cement board (2A) The method for constructing an outer wall according to claim 9, 10, or 11, wherein the rubber plate (PR) having the same thickness as the horizontal abutting piece (7 F) is sandwiched between the shape portion (Pd).   The heat insulating support panel (3) is sandwiched and held at appropriate positions in the sleeve wall form using a separator (10H '), a cone for heat insulating material (11A), and an anchor (11B). The construction method according to any one of the above.   The width (W3) of the heat-insulating layer (3B) of the heat-insulating support panel (3) is set to protrude slightly on both sides from the sleeve wall thickness (T5), and both side surfaces (3L, 3R) of the heat-insulating layer (3B) are composite panels. The construction method according to any one of claims 9 to 13, wherein the abutting surface (2L, 2R) of the side end of the heat insulating layer (2B) of (2) is abutted against and abutted.

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