JP7363011B2 - balcony structure - Google Patents

Description

The present invention relates to balcony structures.

Patent Document 1 describes a waterproof composite covering used for floors of balconies, etc., which includes a heat insulating layer (hereinafter referred to as "insulating material"), a roof board layer, a fiber-reinforced resin layer, and a finishing material layer on a base in this order. A technique is disclosed in which a water gradient is formed in the insulation material for draining water from the floor surface of the balcony. With such a configuration, the prior art improves the waterproof performance such as drainage performance, weather resistance, and water resistance, and the aesthetic appearance such as smoothness on the floor surface of the balcony.

Japanese Patent Application Publication No. 2005-264467

However, in the above-mentioned prior art, as mentioned above, a water gradient is formed in the insulation material for draining water from the floor of the balcony, so it is necessary to process the water gradient in the insulation material itself. Therefore, the cost of the insulation material increases. Furthermore, since a water gradient is formed in the insulation material, the wall thickness of the insulation material differs between the base side and the free end side of the balcony, and there is room for further improvement in the durability of the insulation material.

The present invention takes the above facts into consideration and aims to obtain a balcony structure that can improve the durability of the heat insulating material.

The balcony structure according to the first aspect is fixed to a main frame that constitutes a frame of a floor of a balcony disposed above an indoor space or an inner garage, and a beam member that constitutes a part of the main frame. , a joist forming a water gradient on the floor surface of the balcony; a heat insulating material provided on the upper side of the joist and suppressing heat conduction between the upper side and the lower side of the joist; and the heat insulating material A subflooring material provided on the upper surface side and forming a part of the floor surface of the balcony; and a waterproofing material provided on the upper surface side of the flooring material and waterproofing the floor surface of the balcony. There is.

The balcony structure according to the first aspect includes a main frame that constitutes the framework of the floor of a balcony disposed above an indoor space or an inner garage. Joists that form the water slope of the floor of the balcony are fixed to the beam members that form part of this main frame, and the upper and lower sides of the joists are fixed to the upper surface of the joists. A heat insulating material is provided to suppress heat conduction. In addition, on the top side of the insulation material, a subfloor material that forms part of the floor of the balcony is provided, and on the top side of the subfloor material, there is a waterproof material that waterproofs the balcony floor. It is provided.

That is, in this aspect, the water gradient of the floor surface of the balcony is formed by the joists. In other words, the water gradient is formed by the height of the joists, and the heights of the joists differ between the base side and the free end side of the balcony. In this way, when a water gradient is formed by changing the height of the joist material, unlike when the water gradient is formed by the difference in wall thickness of the insulation material, the height of the joist material affects the durability of the joist material. The impact is small.

In the present invention, a heat insulating material is provided on the upper surface side of the joist material, and the heat insulating material is provided on the lower surface side of the subfloor material. Since balconies are installed outdoors, heat from sunlight increases the temperature of the balcony floor. As a comparative example, for example, if a heat insulating material is provided on the upper surface side of the floor of a balcony, the heat insulating material is vulnerable to heat, so there is a possibility that the heat insulating material will melt.

Therefore, in this aspect, the heat insulating material is provided on the lower surface side of the flooring material. This makes it possible to improve the durability of the heat insulating material, and it becomes possible to maintain suppression of thermal effects between the balcony side and the indoor space or inner garage side.

A balcony structure according to a second aspect is the balcony structure according to the first aspect, in which the heat insulating material is adhered to and integrally formed with the floor substrate.

In the balcony structure according to the second aspect, the heat insulating material is bonded to the subfloor material and is formed integrally with the subfloor material, so compared to a case where the heat insulating material and the subfloor material are provided separately. , work efficiency is high because the insulation material and flooring material can be installed on the top surface of the joists at the same time.

A balcony structure according to a third aspect is the balcony structure according to the first aspect or the second aspect, in which the joists are arranged along a direction perpendicular to the water gradient and are arranged along the direction perpendicular to the water gradient. A plurality of joists are arranged along the water gradient, and the heights of the joists are individually set along the water gradient.

In the balcony structure according to the third aspect, the joists are arranged in a direction perpendicular to the water gradient of the floor surface of the balcony, and are arranged in plurality along the water gradient. Additionally, the height of the joists is set individually along the water gradient.

That is, the height of the joists is set higher on the upstream side of the water gradient than on the downstream side of the water gradient. For example, processing a water gradient on the insulation material itself will incur additional processing costs, but in this embodiment, joists of different heights are simply arranged along the water gradient, so there is no need to process the joists. This can be done at a low cost.

As explained above, the balcony structure according to the present invention has the excellent effect of improving the durability of the heat insulating material.

(A) is a plan view of a building to which the balcony structure according to the present embodiment is applied, (B) is a front view of the building, and (C) is a right side view of the building. It is a top view showing the main frame of the balcony structure concerning this embodiment. A cross-sectional view taken along line AA shown in FIG. 1(A) is shown. FIG. 2 is an enlarged cross-sectional view of the main parts of the balcony structure according to the present embodiment. (A) is a plan view of a building showing a modification of the balcony structure as a reference example , (B) is a front view of the building, and (C) is a right side view of the building. A perspective view of the joist material 82 as seen diagonally from the front side when cut along the BB cross section shown in FIG. 5(A) is shown.

Hereinafter, a balcony structure according to the present embodiment will be explained using the drawings.
(Configuration of balcony structure)

First, the configuration of the balcony structure according to this embodiment will be explained.
For example, FIG. 1(A) shows a plan view of a building 10 to which a balcony structure according to the present embodiment is applied, and FIG. 1(B) shows a front view of the building 10. 1(C) shows a right side view of the building 10. As shown in FIGS. 1A to 1C, the building 10 includes a first floor portion 12 and a second floor portion 14, and a balcony 16 is provided on the second floor portion 14. . Note that below the balcony 16, an indoor space 18 is provided in the first floor portion 12.

In this embodiment, as shown in FIG. 3, the balcony 16 includes a main frame 20 that constitutes a floor 19 of the balcony 16. Note that FIG. 3 shows a cross-sectional view taken along line AA shown in FIG. As shown in FIG. 2, the main frame 20 has a rectangular frame shape when viewed from above, and includes a pair of floor girders 22 and 24 that form the long side and face each other, and a short side that forms the main frame 20. A pair of floor girders 26 and 28 facing each other are provided. Note that FIG. 2 shows a plan view of the main frame 20.

Further, as shown in FIG. 2, the floor beams 26 and 28 on the short side and the floor beams 22 and 24 on the long side are connected to each other, and there is a space between the floor beam 22 and the floor beam 24. A plurality of floor beams 30 are provided along the longitudinal direction of the floor beams 22 and 24 at predetermined intervals. In the following description, the floor beams 22, 24, 26, and 28 are simply referred to as floor beams 32 when the shorter side or the longer side is not distinguished.

The floor beams 22, 24, 26, and 28 are arranged on the ceiling beams 15, 17, etc., which constitute a part of the ceiling section 13 of the first floor section 12 shown in FIG. 3, respectively. In addition, FIG. 3 shows the floor beams 22 and 24 on the long side, and the ceiling beams 15 and 17 on the long side correspond to the floor beams 22 and 24. . Further, the ceiling portion 13 is provided with a ceiling heat insulating material area A in which a heat insulating material 29 such as glass wool is provided. Similarly to the floor beam 32 of the balcony 16, the floor beam 21 of the second floor section 14 is arranged above the ceiling beam 15 of the first floor section 12, etc.

Here, as shown in FIG. 3, channel steel is used for each of the floor beams 32. The floor beam 32 also includes a web portion 34 that forms the central portion of the floor beam 32 and is arranged along the height direction of the building 10, and a web portion 34 that forms the upper portion of the floor beam 32 and extends horizontally from the upper end of the web portion 34. It is configured to include an upper flange portion 36 that overhangs along the direction, and a lower flange portion 38 that constitutes the lower part of the floor girder 32 and overhangs from the lower end of the web portion 34 along the horizontal direction.

On the other hand, the floor beam 30 is made of square steel, and includes a pair of side walls 40 that constitute the central part of the floor beam 30 and are arranged along the height direction of the building 10 and face each other. An upper wall part 42 which constitutes the upper part of the floor beam 30 and connects the upper ends of the pair of side wall parts 40, and a lower wall part 44 which constitutes the lower part of the floor beam 30 and connects the lower ends of the pair of side wall parts 40. There is.

As shown in FIGS. 3 and 4, joists 46 and 48 are fixed to the upper flange portion 36 of the floor beam 32 and the upper wall portion 42 of the floor beam 30, respectively. The joists 46 and 48 are made of, for example, channel steel, and include a web portion 50 that constitutes the center of the joists 46 and 48 and is arranged along the height direction of the building 10; An upper flange part 52 constitutes the upper part of the web parts 46 and 48 and extends horizontally from the upper end of the web part 50; It is configured to include a lower flange portion 54 that projects out. Furthermore, lip portions 56 and 58 extend from the tips of the upper flange portion 52 and the lower flange portion 54 in a direction toward each other. Note that the lip portions 56 and 58 are not necessarily necessary.

Further, in this embodiment, the lower flange portions 54 of the joists 46 and 48 are fixed to the upper flange portion 36 of the floor girder 32 and the upper wall portion 42 of the floor beam 30, respectively. Further, the joist material 46 has a lower dimension in the height direction than the joist material 48, and the height dimension of the joist material 46 is H1, and the height dimension of the joist material 48 is H2 (>H1). . The joist material 46 is arranged closer to the free end portion 16A of the balcony 16 than the joist material 48 is. That is, in this embodiment, the water gradient S of the floor surface 19A of the floor portion 19 of the balcony 16 is formed by the heights of the joists 46 and 48.

Although two joists 46 and 48 are mentioned here for the main frame 20, the joists in this embodiment have heights that vary along the water gradient S of the floor surface 19A of the balcony 16. Therefore, it is not limited to the joists 46 and 48.

Further, a sheet-shaped heat insulating material 60 is provided on the upper surface 52A of the upper flange portion 52 of the joists 46, 48. The heat insulating material 60 is set to suppress heat conduction between the upper side and the lower side of the joists 46 and 48, and is made of, for example, flexible polyethylene foam. There is. Therefore, the heat insulating material 60 is elastically deformed along the shape of the upper surface 52A of the upper flange portion 52 of the joists 46, 48, and comes into close contact with the upper surface 52A of the upper flange portion 52 of the joists 46, 48. It is located in the state.

Further, on the upper surface 60A side of the heat insulating material 60, a subfloor material 62 that constitutes a part of the floor surface 19A of the balcony 16 is provided. For example, plywood or particle board called RBR is used for the flooring material 62. A waterproofing material 64 that waterproofs the floor surface 19A of the balcony 16 is provided on the upper surface 62A side of the flooring material 62, and a DN steel plate is used for the waterproofing material 64, for example.

On the other hand, as shown in FIG. 3, the long side floor beam 22 (free end 16A of the balcony 16) and the short side floor beams 26 and 28 (FIG. A waist wall portion 66 is provided on the outside of the web portion 34 (see 2).

Further, a sash lower frame 70 is provided on the base 16B side of the balcony 16 within the indoor space 68 of the second floor portion 14 of the building 10, and the upper surface 70A of the sash lower frame 70 is the floor surface of the balcony 16. It is set to be at a higher position than 19A. A waterproof rising portion 72 is provided on the indoor space 68 side of the sash lower frame 70. Further, a drainer 74 is provided on the lower side of the sash lower frame 70, so that water that flows down the window etc. that partitions the indoor space 68 and the outdoor space 76 and falls onto the floor surface 19A side of the balcony 16. It is composed of

(Functions and effects of balcony structure)
Next, the functions and effects of the balcony structure according to this embodiment will be explained.

As shown in FIGS. 3 and 4, in this embodiment, the water gradient S of the floor surface 19A of the balcony 16 is formed by the joists 46 and 48. That is, in this embodiment, the water gradient S of the floor surface 19A of the balcony 16 is formed by changing the height dimension (H1) of the joist material 46 and the height dimension (H2) of the joist material 48, respectively.

More specifically, in this embodiment, in forming the water gradient S of the balcony 16, the joists 46 and 48 are arranged along the direction perpendicular to the water gradient S of the floor surface 19A of the balcony 16. At the same time, a plurality of them are arranged along the water gradient S.

Here, the height dimension (H1) of the joist material 48 is formed to be higher than the height dimension (H2) of the joist material 46 (H1<H2). Therefore, the joist material 48 is arranged closer to the root portion 16B of the balcony 16 than the joist material 46, and the upstream side of the water gradient S (the root portion 16B side of the balcony 16) is arranged on the downstream side of the water gradient S (the balcony The height dimension of the joist is set to be higher than the free end 16A side of 16).

As a result, a water gradient S is formed on the floor surface 19A of the floor section 19 of the balcony 16, and water on the floor surface 19A of the balcony 16 flows from the root section 16B side of the balcony 16 toward the free end section 16A side according to the water gradient S. It will be guided along the direction of arrow A (see FIG. 1(A)).

When the water on the floor surface 19A of the balcony 16 reaches the free end 16A side of the balcony 16, the water on the floor surface 19A of the balcony 16 flows along the longitudinal direction of the balcony 16 (in the direction of arrow B, see FIG. 1(A)). You will be guided towards a corner of section 19. A drainage hole 78 (see FIG. 1(A)) is provided in one corner of the floor 19, and water on the floor 19A of the balcony 16 is discharged to the outside of the building 10 through the drainage hole 78. .

As described above, in this embodiment, the water gradient S of the floor surface 19A of the balcony 16 is formed by the joists 46 and 48. In other words, the water gradient S is formed by the height of the joists 46 and 48, and the heights of the joists 46 and 48 differ between the root portion 16B side and the free end portion 16A side of the balcony 16.

In this way, when the water gradient S is formed by changing the height of the joists 46 and 48, unlike the case where the water gradient S is formed by the difference in the wall thickness of the insulation material 60, the height of the joists 46 and 48 is Since the influence on the durability of the joists 46 and 48 is small, the life of the balcony 16 itself is improved as a result.

Further, in this embodiment, a heat insulating material 60 is provided on the upper surface 52A side of the upper flange portion 52 of the joists 46 and 48, and a subfloor material 62 is provided on the upper surface 60A side of the heat insulating material 60. That is, in this embodiment, the heat insulating material 60 is provided on the lower surface 62B side of the underfloor material 62.

Since the balcony 16 is installed outdoors 76, the temperature of the floor 19 of the balcony 16 increases due to heat from sunlight and the like. Therefore, as a comparative example, for example, although not shown, if a heat insulator 60 is provided on the floor surface 19A side of the floor 19 of the balcony 16, the heat insulator 60 is vulnerable to heat, so the heat insulator 60 melts. There is a possibility that

Furthermore, in this embodiment, an indoor space 18 is provided below the balcony 16 in the first floor portion 12 . Therefore, moisture from the indoor space 18 rises toward the floor 19 side of the balcony 16. Generally, the balcony 16 is often installed on the south side of the building 10, and moisture heated by sunlight rises from the indoor space 18 to the balcony 16 side and is mixed with the waterproof material 64 cooled by radiation cooling. In between, dew condensation tends to occur on the lower surface 62B side of the flooring material 62.

Therefore, in this embodiment, as shown in FIGS. 3 and 4, the heat insulating material 60 is provided on the lower surface 62B side of the underfloor material 62. In this way, by providing the heat insulating material 60 on the lower surface 62B side of the subfloor material 62, the durability of the heat insulating material 60 against sunlight can be improved, and the heat insulating material 60 also prevents heat from the indoor space 18. This makes it possible to suppress the conduction of water and to suppress the occurrence of dew condensation on the lower surface 62B side of the underfloor material 62. This makes it possible to maintain suppression of thermal effects between the balcony 16 side and the indoor space 18.

In this embodiment, the lower side of the balcony 16 is the indoor space 18, but there are other cases, for example, although not shown, even if the lower side of the balcony 16 is an inner garage or an alcove, the indoor space 18 can be The same effect can be obtained.

Further, a sheet-like heat insulating material 60 is provided on the upper surface 52A of the upper flange portion 52 of the joists 46, 48, and in this embodiment, a flexible polyethylene foam is used as the heat insulating material 60. There is. Therefore, in the present embodiment, the heat insulating material 60 is elastically deformed along the shape of the upper surface 52A of the upper flange portion 52 of the joist members 46, 48, and the upper surface of the upper flange portion 52 of the joist material 46, 48 It is provided in close contact with 52A.

In this way, by providing the heat insulating material 60 in close contact with the upper surface 52A of the upper flange portion 52 of the joists 46, 48, it is possible to take measures against thermal bridges in the joists 46, 48. Heat conduction can be suppressed between the upper and lower sides of the joists 46 and 48.

Moreover, as a comparative example, for example, although not shown in the drawings, when forming the water gradient S of the balcony 16, it is assumed that the water gradient S is processed into the heat insulating material itself. In this case, additional costs will be incurred for processing the water gradient S into the heat insulating material.

On the other hand, in this embodiment, as described above, in forming the water gradient S of the floor surface 19A of the balcony 16, a plurality of joists 46 are arranged along the direction orthogonal to the water gradient S. , 48 are varied along the water gradient S of the balcony 16. That is, in this embodiment, since the joists 46 and 48 of different heights are simply arranged along the water gradient S, there is no need to process the joists 46 and 48, and this can be done at low cost.

Note that the heat insulating material 60 may be bonded to the subfloor material 62 and formed integrally with the subfloor material 62. As a result, although not shown, the heat insulating material 60 and the floor underlayment material are provided on the upper surface 52A of the upper flange portion 52 of the joists 46 and 48, compared to the case where the insulation material 60 and the underfloor material 62 are provided separately. 62 can be installed at once, improving work efficiency.

Further, in this embodiment, as described above, in forming the water gradient S of the floor surface 19A of the balcony 16, a plurality of joists 46 and 48 are arranged along the direction perpendicular to the water gradient S. Although the height dimension is changed along the water slope S of the balcony 16, it is not limited to this.

For example, FIG. 5(A) shows a plan view of a building 80 as a modified example of the balcony structure as a reference example , and FIG. 5(B) shows a front view of the building 80. (C) shows a right side view of the building 80. Further, FIG. 6 shows a perspective view of the joist 82 when cut along the BB cross section shown in FIG. 5(A) and viewed diagonally from the front side.

The joists 82 shown in FIG. 6 may be arranged so as to be parallel to the water slope S' of the floor surface 86A of the floor 86 of the balcony 84 shown in FIGS. 5(A) to 5(C).

Therefore, as shown in FIGS. 5(A) and 6, the height of the web portion 88 of the joist 82 changes along the longitudinal direction of the joist 82 in accordance with the water gradient S'. In addition, the upstream side of the water gradient S' (the longitudinal center 90 side of the balcony 84) is closer to the web part of the joist material 82 than the downstream side of the water gradient S' (the longitudinal end 92 side of the balcony 84). The height dimension of 88 is set to be high. As a result, the water on the floor surface 86A of the balcony 84 is guided in the direction of arrow C from the central portion 90 in the longitudinal direction of the balcony 84 toward the end portions 92 in accordance with the water gradient S'.

When the water on the floor surface 86A of the balcony 84 reaches the longitudinal end 92 side of the balcony 84, it is guided toward one corner of the floor section 86 of the balcony 84. A drainage hole 94 is provided at each corner of the floor portion 86, and water on the floor surface 86A of the balcony 84 is discharged to the outside of the building 80 through the drainage hole 94.

10 Building 16 Balcony 18 Indoor space 19 Floor 19A Floor surface 20 Main frame 22 Floor beam (beam member)
24 Floor beam (beam member)
26 Floor beam (beam member)
30 Floor beam (beam member)
32 Floor beam (beam member)
46 Joist material 48 Joist material 52A Top surface (Top surface of joist material)
60 Insulating material 60A Top surface (Top surface of heat insulating material)
62 Floor base material 62A Top surface (top surface of floor base material)
62B Bottom surface (bottom surface of flooring material)
64 Waterproofing material 80 Building 82 Joist material 84 Balcony 86 Floor 86A Floor surface S Water gradient S' Water gradient

Claims (3)

A main frame that constitutes the skeleton of the floor of a balcony located above the indoor space or inner garage;
a plurality of joists fixed to a beam member constituting a part of the main frame and set at different heights from each other to form a water gradient on the floor surface of the balcony;
A contact portion that contacts the upper surface of the joist is elastically deformed along the shape of the upper surface and is provided in close contact with the upper surface , and conducts heat between the upper side and the lower side of the joist. Insulation material that suppresses
a subfloor material provided on the upper surface side of the heat insulating material and forming a part of the floor surface of the balcony;
a waterproofing material provided on the upper surface side of the floor base material and waterproofing the floor surface of the balcony;
Balcony structure with. The balcony structure according to claim 1, wherein the heat insulating material is bonded to and integrally formed with the subfloor material. The joists are arranged along a direction perpendicular to the water gradient, and are arranged in plural along the water gradient, and the heights of the joists are individually set along the water gradient. The balcony structure according to claim 1 or claim 2.