JP4547183B2 - Multi-story building dwelling structure - Google Patents

Description

  The present invention relates to a dwelling unit structure of a multi-layer building in which a floor of each dwelling unit in a multi-layer building such as a skeleton infill house has a double floor structure.

In multi-story buildings such as apartment buildings, in each dwelling unit space, it is inevitable that construction noises when performing various constructions, living sounds when living, and vibrations during these constructions and livings may occur.
Among the housing complexes, the skeleton infill housing (hereinafter referred to as SI housing) is a housing complex in which the skeleton portion and the infill portion are separated, and the skeleton portion is constructed of concrete.

Technologies related to SI housing are described in Patent Literature 1 (Japanese Patent Laid-Open No. 2002-21348), Patent Literature 2 (Japanese Patent Laid-Open No. 2002-174042), Patent Literature 3 (Japanese Patent Laid-Open No. 2003-343096), and the like. .
In SI houses, if the skeleton part and the infill part are contracted separately, the completion time of the infill part may be different. As a result, the sound of the dwelling unit that has already been occupying the construction of the infill part in another dwelling unit will be heard.
JP 2002-21348 A JP 2002-174042 A JP 2003-343096 A

In a conventional SI house dwelling unit structure, the floor structure of the entire dwelling unit is a single floor structure consisting of only a frame floor (floor slab), and the outer wall is directly fixed to the frame floor. And the indoor space of the whole dwelling unit is formed by the frame floor, the door boundary wall, the outer wall, and the frame floor of the upper floor. For this reason, the construction sound in one dwelling unit becomes a solid propagation sound and propagates to other dwelling units, which may cause complaints about sound and vibration, which is a major impediment to the spread of SI houses.
In SI houses, one of the advantages is that the infill part can be designed freely. However, if the floor plan is different between the upper and lower floor units, the living sound between the upper and lower floor units can be reduced. Propagation problems arise.
There are various sounds such as door and sash opening / closing sounds, water sounds in bathrooms, washrooms, toilets, and floor impact sounds. Restrictions will be placed, and the original free design of SI houses will be hindered.
Even in apartment buildings other than SI houses, construction noises generated during renovation work, various living sounds and vibrations are often transmitted to other dwelling units, and complaints about sounds and vibrations often occur.

  The present invention has been made to solve such problems, and can prevent various construction sounds, living sounds, and vibrations generated in the indoor space of one dwelling unit from propagating between the dwelling units on the upper and lower floors. It aims at providing the dwelling unit structure of a multilayer building.

In order to achieve the above-described object, the multi-story building dwelling structure according to the present invention is a multi-story building dwelling structure in which a plurality of dwelling units are arranged, and one dwelling unit is partitioned by a fixed wall to form a dwelling unit indoor space. A double floor structure with a concrete upper floor laid on a concrete frame floor on each floor via a floor clearance of a predetermined height is connected to the exterior passageway through the doorway. The fixed wall is formed as a wall in which the legs are joined to the frame floor, and a wall having a predetermined horizontal dimension is formed between the side surface of the fixed wall and the end surface of the upper floor.・ By forming a floor clearance and forming a floor clearance between the cabinet floor and the upper floor over the entire plan view of the indoor space of one dwelling unit, a sound insulation structure between the upper and lower floor dwelling units is constructed, and the outside passage is shared In the hallway This common corridor also has a double floor structure in which a concrete upper floor is laid on a concrete frame floor with a clearance on the floor of a predetermined height, and a slit is formed in the upper floor. The upper floor is separated into the dwelling room interior side and the common corridor side by this slit .
Moreover, the dwelling unit structure of a multilayer building according to the present invention is a dwelling unit structure of a multi-layer building in which a plurality of dwelling units are arranged, wherein one dwelling unit is partitioned by a boundary wall to form a dwelling unit indoor space, A double floor structure in which a concrete upper floor is laid on the concrete frame floor of each floor with a clearance on the floor with a predetermined height dimension in plan view of the indoor space of a single dwelling unit. Formed throughout, the boundary wall of one dwelling unit is equipped with a mounting wall and a fixed wall, and the mounting wall is mounted with its legs mounted on the upper surface of the upper floor and is a wall body provided with an entrance / exit Formed, a floor clearance is formed between the upper floor under the legs of the mounting wall and the chassis floor, and the fixed wall is formed as a wall body in which the legs are joined to the chassis floor. Wall / floor with a predetermined horizontal dimension between the floor and the end face Forming a clearance, by forming a floor clearance between the skeleton floor and upper floor throughout the plan view one dwelling unit interior, it constitutes a sound insulation structure between upper and lower floors of the dwelling unit, the residential unit outside passage shared hallway Yes, this common corridor also has a double floor structure in which a concrete upper floor is laid on the concrete frame floor with a clearance on the floor of a predetermined height, and a slit is formed in the upper floor The upper floor is separated into the dwelling room interior side and the common corridor side by this slit .
Upper floors, reinforced concrete floor structure which is pouring in situ construction, or is not preferable for a floor structure which is integrally spread a plurality of floor panels made of precast reinforced concrete.
It is preferable to dispose a cushioning material for floor clearance in the floor clearance in the double floor structure.

Since the dwelling unit structure of the multi-layer building according to the present invention is configured as described above, various construction sounds, living sounds, and vibrations generated in the indoor space of one dwelling unit can be prevented from propagating between the dwelling units on the upper and lower floors. . Moreover, since the slit is provided in the upper floor, it is possible to prevent the walking sound and vibration in the common hallway from propagating into the dwelling unit through the upper floor.

First, an embodiment according to the present invention will be described with reference to FIGS.
FIG. 1 is a schematic diagram showing a basic dwelling unit structure of a multi-layer building according to the present invention. 1A is a side cross-sectional view showing a part of a multi-layered building, and FIGS. 1B and 1C are cross-sectional views taken along line BB and CC, respectively, in FIG. 1A. It is.
As shown in FIG. 1, the multi-layer building 101 has a dwelling unit structure in which a plurality of dwelling units 10 are arranged. The one dwelling unit 10 is partitioned by a fixed wall 119 to form an indoor space 31 of the one dwelling unit 10, and is connected to the outside dwelling passage 11 through an entrance 33.
The wall around the single-dwelling unit 10 having a substantially quadrangular shape in plan view is divided into a wall 3 facing the exterior passage 11, a door boundary wall 9, and an outer wall 4 facing the balcony 12. It is configured as a wall 119.
In one dwelling unit 10, a double floor structure 24 is formed over the entire plan view of the one dwelling unit indoor space 31. The double floor structure 24 is a structure in which a concrete upper floor 23 is laid on a concrete frame floor 20 of each floor via a floor clearance CL having a predetermined height h.

The fixed wall 119 is formed as a wall body in which the leg portion 119 a is joined to the frame floor 20. A wall / floor clearance S2 having predetermined horizontal dimensions d1, d2, and d3 is formed between the side surface of the fixed wall 119 and the end surface of the upper floor 23. A floor clearance CL is formed between the housing floor 20 and the upper floor 23 over the entire plan view of the indoor space 31 of one dwelling unit. Thus, the sound insulation structure between the dwelling units 10 on the upper and lower floors is configured.
Thereby, the purpose of preventing various construction sounds, daily life sounds and vibrations generated in the indoor space 31 of one dwelling unit 10 from propagating between the dwelling units 10 on the upper and lower floors is realized.

FIG. 2 is a schematic diagram showing a progressive dwelling unit structure of a multi-layer building according to the present invention. 2A is a side cross-sectional view showing a part of a multi-layer building, and FIGS. 2B and 2C are cross-sectional views taken along line BB and CC, respectively, in FIG. 2A. It is. 3 is a cross-sectional view taken along the line III-III in FIG. 2C, FIG. 4 is an enlarged cross-sectional view of the IV portion in FIG. 2A, and FIGS. 5A and 5B are a modification of FIG. It is a figure which shows a modification, respectively, and is a figure equivalent to FIG.
As shown in FIGS. 2 to 5, the multi-layer building 201, 201 a, 201 b has a dwelling unit structure in which a plurality of dwelling units 10 are arranged. One dwelling unit 10 is partitioned by a boundary wall 202 to form an indoor space 31 of the one dwelling unit 10 having a quadrangular shape in plan view, and is connected to the outside dwelling passage 11 through an entrance 33.
In one dwelling unit 10, the double floor structure 24 is formed over the entire plan view of the one dwelling unit indoor space 31. The double floor structure 24 is a structure in which a concrete upper floor 23 is laid on a concrete frame floor 20 of each floor via a floor clearance CL having a predetermined height (see FIG. 2).

The one dwelling unit 10 divides the periphery of the substantially rectangular shape in plan view by the boundary wall 202 to form a one dwelling unit indoor space 31. The boundary wall 202 is divided into a wall 3 facing the exterior exterior passage 11, a door wall 9, and an outer wall 4 facing the balcony 12 from the planar arrangement.
The wall 3 facing the exterior doorway passage 11 is configured as a placement wall 30, and the door wall 9 and the outer wall 4 are configured as a fixed wall 219. That is, the boundary wall 202 of one dwelling unit 10 includes the placement wall 30 and the fixed wall 219. (See FIG. 2 (B)).
The mounting wall 30 is formed as a wall body that is attached with the leg portions 30 a mounted on the upper surface of the upper floor 23 and provided with an entrance 33. A floor clearance CL is formed between the upper floor 23 below the leg portion 30a of the mounting wall 30 and the chassis floor 20 (see FIGS. 2A and 4).

The mounting wall 30 facing the outdoor passage 11 is provided with entrances 33 such as a front door and a doorway, but between the upper floor 23 below the leg portion 30 a of the mounting wall 30 and the frame floor 20. Since the clearance CL on the floor is formed, it is possible to prevent the door door and window opening / closing noise at the entrance / exit 33 provided on the mounting wall 30 from being transmitted to the frame floor 20.
Since the leg portion 30a of the mounting wall 30 facing the out-of-dwelling passage 11 is mounted on the upper surface of the upper floor 23, it is within the range where the upper floor 23 is mounted (reference numeral L1 in FIG. 4). The planar position of the mounting wall 30 can be freely set within the range shown in FIG.
Conventionally, a free plan house has only been able to freely set and change the position of the partition wall that partitions the rooms in one dwelling unit. However, in the present invention, the boundary wall 202 that partitions the periphery of the one dwelling unit 10 is provided. By configuring as the mounting wall 30, the degree of freedom for setting and changing the planar position of the mounting wall 30 is improved.
Since the mounting wall 30 is attached between the upper floor 23 and the upper floor 20 (or beam), a dry structure such as a reinforced concrete PCa plate or ALC plate is preferable.

The fixed wall 219 is formed as a wall body in which the leg portion 219a is joined to the frame floor 20, and a wall / floor clearance of predetermined horizontal dimensions d1 and d2 is provided between the side surface of the fixed wall 219 and the end surface of the upper floor 23. S2 is formed (see FIGS. 2C and 3). By forming a floor clearance CL between the housing floor 20 and the upper floor 23 over the entire plan view of the indoor space 31 of one dwelling unit, a sound insulation structure between the dwelling units 10 on the upper and lower floors is configured.
Since the fixed wall 219 is configured as a wall body integrated with the frame floor 20, it may be either a cast-in-place or a seismic wall structure such as a Pca reinforced concrete wall or steel wall, or a non-seismic wall structure by a lightweight dry structure.
Thereby, the purpose of preventing various construction sounds, daily life sounds and vibrations generated in the indoor space 31 of one dwelling unit 10 from propagating between the dwelling units 10 on the upper and lower floors is realized.

As shown in FIG. 1 to FIG. 5, the upper floor 23 is a floor structure made of reinforced concrete that has been laid in the field, or a floor structure that is integrated with a plurality of floor panels made of PCa (precast reinforced concrete). is there. Thus, since the upper floor 23 is a heavy floor structure, even if an impact is generated by dropping something on the upper floor 23, the impact sound hardly propagates to the dwelling units on the lower floor.
A buffer material for floor clearance is disposed in the floor clearance CL in the double floor structure 24. As a result, even if various construction sounds, living sounds, and vibrations are generated in the indoor space 31 of the single dwelling unit, these sounds and vibrations are generated by the double floor structure 24 in the lower part (floor part) and the upper part (ceiling part). Since it is absorbed by the heavy floor structure 24, it does not propagate to the lower floor dwelling unit 10 and the upper floor dwelling unit 10.

The passage outside the dwelling is a common hallway, and also in this common hallway 11, a double floor structure in which a concrete upper floor 23a is laid on a concrete frame floor 20 via a floor clearance CL of a predetermined height. 24 is formed.
A slit S1 is formed between the upper floor 23 and the upper floor 23a of one dwelling unit 10 so as to extend in the direction of the line. The upper floor is shared with the upper floor 23 on the indoor side of the dwelling unit 10 by the slit S1. It is separated into an upper floor 23a on the corridor 11 side.
That is, the slit S1 between the upper floor 23 of the one dwelling unit 10 and the upper floor 23a of the common hallway 11 is formed in a shape that penetrates the cross-sectional thickness direction of the upper floors 23, 23a with a predetermined width. The slit S1 extends in the longitudinal direction of the common hallway 11 over the entire length in the longitudinal direction of the mounting wall 30 (see FIGS. 2C and 4).
Walking sounds, vibrations, and the like in the shared hallway 11 are blocked by the slit S1, and therefore do not propagate from the upper floor 23a of the shared hallway 11 to the upper floor 23 in the dwelling unit 10.

In the modification shown in FIG. 5A, the upper floor 23 of the dwelling unit 10 extends from the outer surface of the mounting wall 30 to the common hallway 11 side by a predetermined horizontal dimension L1, and is shared with the slit S1 as a boundary. The upper floor 23a on the corridor 11 side is disposed lower than the upper floor 23 on the indoor side of the dwelling unit 10 by a height dimension h1.
In the other modification shown in FIG. 5B, the floor structure of the shared hallway 11 is configured by only the frame floor 20 without providing the upper floor, and the upper floor 23 of the dwelling unit 10 is substantially the same as the outer surface of the mounting wall 30. The case where it is flush is shown. The upper floor 23a on the shared hallway 11 side may be a light dry structure floor such as a wooden structure.

In the following embodiments shown in FIGS. 6 to 18, an SI house is shown as an example of a multi-layer building, but the dwelling unit structure of the multi-layer building in the present invention is also applicable to an apartment house other than the SI house.
Moreover, as a multi-layered building, in addition to a housing complex, an office building (including an office building considering use change to a housing complex), a hotel, or the like may be used. Multi-story buildings are not only flat plate-like buildings but also rectangular and layered buildings, center-core type buildings with lifting equipment arranged in the center core, or shapes with hollow spaces inside (Ro-shaped, C-shaped) It may be a building.
The dwelling unit structure according to the present invention is preferably applied to all the units of the multi-layer building, but may be applied to some dwelling units (preferably, a plurality of dwelling units adjacent vertically).

Embodiments according to the present invention will be described below with reference to FIGS.
FIGS. 6 to 18 are diagrams showing an embodiment of the present invention. FIG. 6 is a schematic explanatory view of a skeleton infill house as a multi-layer building. FIG. 7 is a reference of a plate-like plane multi-layer building shown in FIG. FIG. 8 is a plan view of the floor, and FIG. 8 is a side sectional view taken along line VIII-VIII in FIG. 9 is an enlarged side sectional view of FIG. 8, FIG. 10 is an enlarged side sectional view of FIG. 9, FIG. 11 is a sectional view taken along line XI-XI in FIG. 10, and FIG. 12 is a sectional view taken along line XII-XII in FIG. It is.
FIG. 13 shows a modification of the mounting wall structure of one dwelling unit, and corresponds to a front sectional view taken along line XIII-XIII in FIG. FIG. 14 is a plan cross-sectional view according to a modified example of the upper floor, corresponding to FIG.

As shown in FIG. 6, there is an SI house (skeleton infill house) in one of the multi-layer buildings 1 such as an apartment house. This SI house is a house in which the skeleton portion S and the infill portion I are separated.
The skeleton portion S includes a structural frame such as a pillar, a beam, and a frame and shared facilities, and is a basic, joint, and durable portion. Therefore, the skeleton portion S is made with an emphasis on long-term durability.
On the other hand, the infill part I is composed of the interior of the dwelling unit and the equipment in the dwelling unit, and has a strong personality and is a terminal, individual, and expendable part. Therefore, the infill portion I is made with emphasis on variability so that it can be freely changed in response to various needs corresponding to the lives and social conditions of the resident.

In SI houses, the skeleton part S and the infill part I are clearly separated, so even if the infill part I becomes obsolete or difficult to use, it can be dealt with by replacing only the infill part I. Can be used as is.
When constructing an SI house (multi-layer building 1), as shown in FIG. 6A, first, the skeleton portion S is completed. Next, as shown in FIG. 6B, the infill portion I is designed and constructed sequentially from the dwelling unit where the purchaser is determined.
Therefore, when the construction of the infill portion I is performed, there are many cases where a resident lives in another dwelling unit in which the infill portion I has already been completed. Thus, the construction of the infill portion I is sequentially performed, and when the construction of the infill portion I of all the dwelling units is completed as shown in FIG. 6C, the entire SI house is completed.

In this way, in the SI house, even if the infill part I of all the dwelling units is not completed, it is possible to move into the dwelling units where the infill part I has been completed, and there are skeleton-type dwelling units and relocated dwelling units. , Will be mixed in the same building 1.
For this reason, there are many cases where the construction of the infill portion I is carried out at a dwelling unit immediately above or below the dwelling unit. In such a case, it is necessary to prevent the construction sound and vibration generated in the construction of the infill portion I from propagating to other dwelling units on the upper and lower floors where the dwelling has been completed and to maintain a good living environment.
In addition, in the case of SI houses or other apartment houses, the construction noise that occurs during renovation after residence, the living noise that occurs when the apartment is already inhabited, and the vibration during the construction and living are It is necessary to prevent propagation to other dwelling units and to maintain a good living environment.

Next, the dwelling unit structure of the multi-layer building 1,301 that keeps the living environment favorable will be described. In this embodiment, an SI house is shown as an example of the multi-layer building 1,301.
As shown in FIGS. 7 to 14, the multi-layer building 1 is a plate-shaped apartment house, and each floor (reference floor) is a plate-like planar shape that is narrow in the direction between the beams (Y direction) and slender in the cross direction (X direction). I am doing.
Each floor of the multi-story building 1 has a single corridor system in which a plurality of dwelling units 10 are arranged along a common corridor 11 that extends in the direction of the line and constitutes a passage outside the dwelling unit, and a balcony 12 is attached to the opposite side of the common corridor 11. It is a plate-like planar shape. Each floor above the second floor of the multi-layer building 1 has a predetermined floor height H.
A plurality of pillars 5 are respectively arranged with arbitrary span lengths in the direction of the traverse along the inner edge portions of the common hallway 11 and the balcony 12 of the multi-layer building 1. The pillar 13 on the shared corridor 11 side and the pillar 13 on the balcony 12 side are arranged to face each other with a predetermined span length L apart.
The multi-story building 1 has a span direction of 8 spans, and a cross-beam direction orthogonal to the cross row direction is 1 span (span between opposing columns 13 and 13).

A first ramen structure 15 a is disposed between the shared hallway 11 and the dwelling unit 10, and a second ramen structure 15 b is disposed between the balcony 12 and the dwelling unit 10. The two ramen structures 15a and 15b extend in the column direction and are arranged in parallel and facing each other.
A plurality of beams (inner beams) 16 facing the beam-to-beam direction are fixed to the two ramen structures 15a and 15b. The two ramen structures 15 a and 15 b and the plurality of beams 16 constitute a frame structure 14 of the multi-layer building 1. The frame structure 14 may have a plurality of wall surface structures arranged in the beam-to-beam direction and fixed to the beam 16.
Here, “framework structure” means a frame that combines a wire such as a column or a beam and a surface member (a surface member such as a door wall 9 or a wall brace that also has a function of a seismic wall), and is integrated with this frame. The secondary structural member is a structure that can resist external forces such as seismic force in structural design.

In the first frame structure 15a, the frame frame frame is composed of a plurality of columns made of PCa and outer peripheral beams 17 as a plurality of beams made of PCa installed in the horizontal direction. Similarly, in the second frame structure 15b, the frame structure in the direction of spar is composed of a plurality of columns 13 and a plurality of outer peripheral beams 17 installed in the horizontal direction.
In addition, the structure which has arrange | positioned the 1st frame structure 15a on the outer side of the common corridor 11, and has arrange | positioned the 2nd frame structure 15b on the outer side of the balcony 12 may be sufficient.

The frame surface 18 in the beam direction connecting the column 13 of the first frame structure 15a and the column 13 of the second frame structure 15b opposite to the column 13 has a predetermined span length L and is in the row direction. A plurality (9 in this case) are formed at an arbitrary span length.
The frame surface 18 in the beam direction is a surface orthogonal to the frame surface in the beam running direction, and is configured as a virtual vertical surface passing through the horizontal axis connecting the two opposite pillars 13. The frame surface in the column direction is an imaginary vertical plane on which the first ramen structure 15a and the second ramen structure 15b are respectively arranged.
By arranging the beam 16, the door wall 9, columns (if necessary) and the like on the frame surface 18 in the beam direction, a structure in the beam direction of the frame structure 14 is configured.
In this embodiment, the case where the skeleton portion is composed of a frame structure has been described. However, the skeleton portion may be replaced with other known structural types such as a vibration control structure, a seismic isolation structure, a wall structure, a steel structure. It may be configured with such as.

A plurality of dwelling units 10 are arranged in the multi-layer building 1. That is, each floor of the multi-layer building 1 is provided with a placement wall 30 that is the outer wall 3 on the shared corridor 11 side and a placement wall 30 that is the outer wall 4 on the balcony 12 side in the crossing direction. By providing a fixed wall 19 that is the door wall 9 and partitioning the internal space, a dwelling unit structure is formed in which a plurality of (8 in this case) dwelling units 10 are formed.
By partitioning the periphery of one dwelling unit 10 with the boundary wall 2, an indoor space 31 of the one dwelling unit 10 is formed, and is connected to the common hallway 11 via the entrance 33.
Concrete floors (that is, floor slabs) 20 are placed on the floor of each floor of the multi-layer building 1. The frame floor 20 is formed integrally with the pillar 13, the outer peripheral beam 17, the fixed wall 19, and the like.
The frame floor 20 is placed up to the dwelling unit 10 and the common hallway 11 and the balcony 12 on both sides thereof. On each outer edge portion of the common hallway 11 and the balcony 12, a rising portion 21 rises upward and is integrally formed with the frame floor 20.
The concrete frame floor 20 is generally a cast-in-place reinforced concrete or PCa frame floor having a predetermined frame floor thickness (slab thickness). However, a steel floor deck plate and a cast-in-place concrete are used. A synthetic enclosure floor may be used.
The multi-layer building 1 is supported by the foundation structure 25. The foundation structure 25 is constructed on the lowest floor of the frame structure 14. The foundation structure portion 25 is constructed with a predetermined span length L and connects opposite foundations 26 with foundation beams 27, and the foundation 26 is supported by a pile 26a (see FIG. 8).

As a dwelling unit structure of the multi-layer building 1, a double floor structure 24 in which a concrete upper floor 23 is laid on a concrete frame floor 20 of each floor via a floor clearance CL of a predetermined height is used. It is formed over the entire plan view of the dwelling unit indoor space 31.
In this embodiment, the floor clearance cushioning material 22 is disposed on the floor clearance CL on the reinforced concrete frame 20 of the dwelling unit 10 in each floor, and the concrete upper floor 23 is disposed on the floor clearance cushioning material 22. The entire unit is constructed as a double floor structure 24.
The upper floor 23 and the fixed wall 19 are structurally interrupted. The fixed wall 19 is formed as a reinforced concrete wall, but may be a dry structure wall.

The boundary wall 2 of the single dwelling unit 10 includes a fixed wall 19 including a door boundary wall 9 and a placement wall 30. The mounting wall 30 is formed as a wall body that is attached with the leg portions 30 a mounted on the upper surface of the upper floor 23 and provided with an entrance 33. A floor clearance CL is formed between the upper floor 23 below the leg portion 30 a of the mounting wall 30 and the frame floor 20. The mounting wall 30 is mounted on the upper floor 23 in a state of being separated from the housing floor 20. The placement wall 30 is arranged as an outer wall on the shared hallway 11 side and an outer wall on the balcony 12 side.
In addition, although the mounting wall 30 has shown the case where it forms the flat plate shape facing the direction (namely, row direction) orthogonal to the fixed wall 19, it has a 1 or several bending part and mounts it. A bent shape or the like in which a part of the wall 30 is a wall surface in the column direction may be used.

Immediately below the mounting wall 30 is an upper floor 23 and a floor clearance CL, and the load of the mounting wall 30 is supported by the upper floor 23. The upper floor 23 is a heavy concrete floor slab having sufficient strength to support the mounting wall 30.
The fixed wall 19 is formed as a wall body whose legs are joined to the frame floor 20, and a wall / floor clearance S 2 having a predetermined horizontal dimension is formed between the side surface of the fixed wall and the end surface of the upper floor 23. (See FIG. 11).
Thus, the floor clearance CL is formed between the housing floor 20 and the upper floor 23 over the entire plan view of the indoor space 31 of one dwelling unit, and the sound insulation structure between the dwelling units 10 on the upper and lower floors is configured. Thereby, it is possible to prevent various construction sounds, living sounds, and vibrations generated in the indoor space 31 of the one dwelling unit 10 from propagating between the dwelling units 10 on the upper and lower floors (see FIG. 11).

More specifically, the upper floor 23 of one dwelling unit (for example, one dwelling unit on the nth floor), the mounting wall 30, the fixed wall 19, and the frame floor 20 on the upper floor (for example, n + 1th floor) An indoor space 31 for the entire dwelling unit is formed.
The concrete upper floor 23 is formed as a reinforced concrete floor structure (so-called wet floor structure) or a PCa floor slab placed in the field construction, but is a dry structure board such as an ALC board. But you can.
As a modification of the present embodiment, the upper floor 23 may be a floor structure (so-called dry floor structure) in which a plurality of PCa floor panels 23 are spread and integrated (see FIG. 14). In this modification, the floor panels are connected and integrated by connecting reinforcing bars (not shown), and the entire upper floor 23 is integrated by pouring mortar or the like into the joint. If floor panels are used, construction work is simplified because there is no need for on-site work for placing concrete.

As described above, in the dwelling unit structure of the multi-layer building 1, the floor structure of the entire dwelling unit is the double floor structure 24, and the upper floor 23 and the fixed wall 19 in the beam direction are structurally blocked, and the beam is crossed. The mounting walls 30 on the shared corridor 11 side and the balcony 12 side in the direction are not fixed directly to the housing floor 20 but are placed on the upper floor 23 apart from the housing floor 20, and the upper floor 23 and the mounting wall 30. The interior space 31 of the entire dwelling unit is formed by the upper floor 20.
Accordingly, various construction sounds, living sounds, and vibrations generated in the indoor space 31 of one dwelling unit 10 (for example, the nth floor dwelling unit 10) are transferred to other dwelling units (n + 1 floor dwelling unit 10, n-1 floor dwelling unit). 10) and the like can be prevented.
For example, the construction of the infill part in the SI house (and the renovation work in the SI house or the general apartment house) can be freely performed at any time for each dwelling unit 10 without causing trouble to other dwelling units.

The mounting wall 30 on the shared corridor 11 side is provided with an entrance 33 and a window such as an entrance and a doorway, and the mounting wall 30 on the balcony 12 side is provided with a window. The leg portion 30 a of the mounting wall 30 is fixed to the upper surface of the upper floor 23, and the upper end portion 30 b of the mounting wall 30 is attached to the outer circumferential beam 17.
The leg 30a of the mounting wall 30 may not be fixed to the upper floor 23, and the upper end 30b is attached to a beam other than the outer peripheral beam 17 or the upper floor 20 of the frame. It may be the case.

The upper floor 23 is disposed substantially parallel to the upper part of the housing floor 20, and a floor clearance CL extends between the housing floor 20 and the upper floor 23 in the horizontal direction. The floor clearance CL is provided with a floor clearance cushioning material 22.
Vertical loads such as people, furniture, and partition walls act on the upper surface of the upper floor 23, and these vertical loads are transmitted to and supported by the frame floor 20 via the floor clearance cushioning material 22.
The on-floor clearance cushioning material 22 includes, for example, a high-elasticity polystyrene foam 22a that exhibits excellent vibration-proofing performance, and a plurality of vibration-proofing rubbers 22b that are arranged in a scattered manner to support the load on the upper floor 23. Has been.
Note that glass wool, rock wool, polyolefin foam, anti-vibration rubber, or a combination of these may be used instead of the highly elastic polystyrene foam 22a.
The on-floor clearance cushioning material 22 is formed in a board shape and is light and strong. Since the on-floor clearance cushioning material 22 may be spread on the frame floor 20, the construction is simple and the construction period is shortened. The cushioning material 22 for clearance on the floor is excellent in soundproofing and vibration-proofing properties and has high reliability because it has almost no creep.

The common hallway 11 also forms a double floor structure 24 in which a concrete upper floor 23a is laid on a concrete frame floor 20 via a floor clearance CL of a predetermined height.
A slit S1 is formed between the upper floor 23 and the upper floor 23a, and the upper floor is divided into an upper floor 23 on the indoor side of the dwelling unit 10 and an upper floor 23a on the shared corridor 11 side by the slit S1. It is separated.
In the present embodiment, an upper floor 23b is provided on the balcony 12 in addition to the shared corridor 11, and a slit S1 is formed in the upper floor 23b so as to extend in the direction of the line. The upper floor is separated into the upper floor 23 on the indoor side of the dwelling unit 10 and the upper floor 23b on the balcony 12 side by the slit S1.
Since this slit S1 is provided, it is possible to prevent the walking sound and vibration in the common hallway 11 and the balcony 12 and the sound of gardening on the balcony 12 from propagating into the dwelling unit 10 through the upper floor 23. it can.
The floor clearance CL below the mounting wall 30 is provided with a water stop member 32 extending in the direction of the line (see FIG. 10). The water stop member 32 blocks water between the outside of the dwelling unit and the inside of the dwelling unit to stop the water.
Even if rain falls on the common corridor 11 or the balcony 12, even if it enters the clearance CL on the floor below the slit S1 through the slit S1, the rain is stopped by the water-stopping member 32. No, it is discharged to a drain outlet (not shown) outside the dwelling unit. Note that the slit S1 may not be provided.

Since a wall / floor clearance S2 is formed between the upper floor 23 and the fixed wall 19 and between the upper floor 23 and the pillar 13 in the horizontal direction in a plan view, they are structurally cut off and sound or Vibration propagation is blocked (see FIGS. 11 and 13).
The wall / floor clearance S2 is filled with, for example, a highly elastic polystyrene foam, glass wool, rock wool, polystyrene foam, polyolefin foam, rubber, or a wall / floor clearance cushioning material combining them.

Taking the n-floor one dwelling unit 10 as an example, an upper floor 23 dedicated to the dwelling unit 10, a placement wall 30 placed on the upper floor 23, and the placement wall 30 via the outer beam 17 ( Alternatively, the structure (n-th floor structure Bn) including the upper floor (n + 1 floor) frame floor 20 (directly attached) is unitized so as to form the indoor space 31 of the entire dwelling unit 10. (See FIGS. 9 and 10). Further, the upper floor 23 on the nth floor is structurally cut off from the frame floor 20 directly below, the fixed wall 19 and the pillar 13 on the nth floor, respectively.
Moreover, the structural body Bn is also connected to a similar structural body (that is, the structural body Bn + 1 on the (n + 1) th floor) on the upper floor (n + 1 floor) via the floor clearance CL on the upper floor. Are structurally blocked.
As a result, the heavy object composed of the structure Bn of the n-floor one dwelling unit 10 is equivalent to the similar structure in the other dwelling units 10 in the lower floor (n-1 floor) (that is, the n-1 floor structure Bn-1). ) And the structure Bn + 1 in the other dwelling unit 10 on the upper floor (n + 1 floor), the floor clearance CL on the n floor and the floor clearance CL on the n + 1 floor are secured, as if floating. It is in a state.

Therefore, even if various construction sounds, living sounds, and vibrations are generated in the indoor space 31 formed by the n-th floor structure Bn, these sounds and vibrations are below the n-th floor structure Bn (the floor portion). ) In the double floor structure 24 of the above-mentioned double floor structure 24 and the cushioning material 22 for clearance on the floor, and the floor clearance CL and the cushion material 22 for clearance on the floor in the double floor structure 24 in the upper part (ceiling part). It does not propagate to other dwelling units 10 on the lower floor (n-1 floor) and other dwelling units 10 on the upper floor (n + 1 floor).
Since the upper floor 23 is a heavy concrete floor slab, even if an object is dropped on the upper floor 23 and an impact is generated, the impact sound hardly propagates to the dwelling unit 10 on the lower floor.
Further, the space between the upper floor 23 and the fixed wall 19 and the space between the upper floor 23 and the pillar 13 are structurally blocked. Since the outer beam 17 and the column 13 are heavy objects, sound and vibration are almost absorbed. Therefore, sound and vibration hardly propagate to the other dwelling units 10 through the fixed wall 19, the outer peripheral beam 17, the pillar 13, and the like.

In the modification shown in FIG. 13, the leg 30 a of the mounting wall 30 is fixed to the upper surface of the upper floor 23. The upper end 30b of the mounting wall 30 is supported by the upper floor 20. An interior wall 42 is provided in parallel with the fixed wall 19. In addition, the code | symbol 44 is an interior ceiling board and the code | symbol 41 is a vibration-proof rubber.
Thereby, since the mounting wall 30 is structurally interrupted from the fixed wall 19 and the upper floor 20, it is possible to more effectively prevent the propagation of sound and vibration.
A vertical clearance 23d extending in the vertical direction is formed between the interior wall 42 and the fixed wall 19 to be blocked. The vertical clearance 23d is filled with a vertical clearance cushioning material 43 such as glass wool, rock wool, or a sealing material.
Therefore, it is possible to prevent sound and vibration from propagating from the interior wall 42 to the fixed wall 19, and to prevent sound from leaking from the vertical clearance 23d.

FIG. 15 is a plan view of a reference floor of a multi-layer building 301 of the center core type in which lifting / lowering equipment is arranged on the center core 51 in the center of the building, and corresponds to FIG. 16 is a partially enlarged plan view of the multi-layer building 301 shown in FIG.
As shown in FIGS. 15 and 16, the multi-layer building 301 has a dwelling unit structure in which a plurality of dwelling units 10 are arranged in the same manner as the multi-layer building 201 shown in FIGS. 2 to 4. The one dwelling unit 10 is partitioned by a boundary wall 302 to form an indoor space 31 of the one dwelling unit 10, and is connected to the outside dwelling passage 11 through an entrance 33.

In the boundary wall 302 of the present embodiment, the surrounding walls of the dwelling unit 10 are configured with the wall 3 on the dwelling unit exterior passage 11 side as the placement wall 30 and the door wall 9 and the outer wall 4 as the fixed wall 19, respectively. ing.
In the present embodiment, the flat shape of one dwelling unit 10 is L-shaped, the dwelling exterior passage 11 is a common hallway in the room, so the wall 3 on the dwelling exterior passage 11 side is an inner wall, and the outside of the outer wall 4 has a balcony. Except that the outer wall 4 that is not installed is configured as a fixed wall 19, it is the same as the embodiment described in FIGS. 7 to 14. Therefore, the description which overlaps with the said Example is abbreviate | omitted.

FIG. 17 is a graph showing the propagation data of the floor impact sound according to this embodiment, and the horizontal axis and the vertical axis indicate the frequency and the floor impact sound level, respectively.
The symbol “◯” in FIG. 17 indicates the data of the prior art in which the floor of the dwelling unit has a single floor structure, and the symbol “●” indicates the double floor structure 24 made of concrete in which the floor of the dwelling unit is on-site. The data of a present Example are shown. And the sound when the floor was impacted was measured downstairs.
As a result, as indicated by the curve indicated by the symbol “●”, according to the double floor structure 24 of the present embodiment, it is understood that the propagation of the floor impact sound can be effectively prevented.

FIG. 18 is a graph showing construction sound propagation data according to the present embodiment, and the horizontal axis and the vertical axis indicate frequency and sound pressure level, respectively.
A symbol “□” in FIG. 18 indicates data of the prior art having a single-floor structure similar to that described above, and is a case where a hammer operation is performed. Further, the symbol “Δ” indicates data of the present embodiment having a double floor structure similar to that described above, and the same hammering operation is performed. And the sound of the hammer was measured downstairs.
As a result, as shown by the curve of “Δ”, it can be seen that according to the double floor structure 24 of the present embodiment, the propagation of the sound of the hammer work, which is a typical example of the construction sound, can be effectively prevented. .

In the SI house (multi-layer building 1,301) of this embodiment, the problems of various construction sounds, living sounds and vibrations generated in the indoor space of one dwelling unit can be solved. The original free design is possible without any restriction on the timing of the construction of the infill part, which can greatly contribute to the spread of SI houses.
In the case of SI houses or other apartment houses, it is possible to prevent various construction sounds, living sounds and vibrations from propagating to other dwelling units, so that all the buildings of the multi-layer buildings 1, 101, 201, 201a, 201b, 301 are sounded. It is possible to make a “quiet house” with a good living environment without complaints about vibration and vibration.

Although one embodiment of the present invention (including modifications, the same applies hereinafter) has been described above, the present invention is not limited to the above-described embodiments, and various modifications and additions can be made within the scope of the gist of the present invention. Etc. are possible.
In the drawings, the same reference numerals denote the same or corresponding parts.

  The present invention can be applied to office buildings, hotels, etc., in addition to apartment houses such as the above-mentioned SI houses.

1 to 5 are views showing an embodiment of the present invention, and FIG. 1 is a schematic view showing a basic dwelling unit structure of a multi-layer building according to the present invention. It is the schematic which shows the progressive dwelling unit structure of the multilayer building concerning this invention. It is the III-III sectional view taken on the line of FIG. FIG. 4 is an enlarged cross-sectional view of a portion IV in FIG. FIGS. 5A and 5B are diagrams respectively showing the modified example of FIG. 4 and other modified examples, and are equivalent to FIG. 6 to 18 are diagrams showing an embodiment of the present invention, and FIG. 6 is a schematic explanatory view of a skeleton infill house. It is a standard floor plan view of a multi-layer building. FIG. 7 is a side sectional view taken along line VIII-VIII in FIG. It is side surface sectional drawing to which FIG. 8 was expanded. FIG. 10 is an enlarged side cross-sectional view of FIG. 9. It is the XI-XI sectional view taken on the line of FIG. It is a XII-XII line plane sectional view of Drawing 10. It is the figure which shows the modification of the mounting wall structure of one dwelling unit, and is equivalent to the XIII-XIII line front sectional drawing of FIG. It is a plane sectional view concerning the modification of the upper floor of this example, and is a figure equivalent to FIG. FIG. 7 is a plan view of a reference floor of a center core type multi-layer building, and is a view corresponding to FIG. 7. FIG. 16 is a partially enlarged plan view of the multi-layer building shown in FIG. 15. It is a graph which shows the data of propagation of the floor impact sound regarding a present Example. It is a graph which shows the data of construction sound propagation concerning this example.

Explanation of symbols

1, 101, 201, 201a, 201b, 301 Multi-storied building 2, 202, 302 Boundary wall 3 Wall on the exterior side of the dwelling unit 4 Outer wall (fixed wall)
9 Door wall (fixed wall)
10 dwelling units 11 common hallway
19, 119, 219 Fixed wall 20 Frame floor 22 Floor clearance cushioning material 23 Upper floor 24 Double floor structure 30 Mounting wall 30a Mounting wall leg 31 Single-unit indoor space 33 Entrance / exit 119a, 219a Fixed wall leg CL Clearance on floor S1 Slit S2 Wall / floor clearance

Claims (4)

In the dwelling unit structure of a multi-layer building with multiple dwelling units,
One dwelling unit is partitioned by a fixed wall to form one dwelling unit indoor space, and is connected to a passage outside the dwelling unit through an entrance,
A double floor structure in which a concrete upper floor is laid on a concrete frame floor of each floor via a floor clearance of a predetermined height is formed over the entire plan view of the indoor space of one dwelling unit,
The fixed wall is formed as a wall body whose legs are joined to the frame floor, and a wall / floor clearance having a predetermined horizontal dimension is formed between the side surface of the fixed wall and the end surface of the upper floor,
By forming a floor clearance between the cabinet floor and the upper floor over the entire plan view of the indoor space of one dwelling unit, a sound insulation structure between the upper and lower floor dwelling units is constructed ,
The passage outside the dwelling is a common corridor, and also in this common corridor, a double floor structure in which a concrete upper floor is laid on a concrete frame floor via a floor clearance of a predetermined height is formed.
A multi-storied building dwelling structure characterized in that a slit is formed in the upper floor, and the upper floor is separated into a dwelling room interior side and a common corridor side by this slit . In the dwelling unit structure of a multi-layer building with multiple dwelling units,
One dwelling unit is partitioned by a boundary wall to form one dwelling unit indoor space, and is connected to a passage outside the dwelling unit through an entrance,
A double floor structure in which a concrete upper floor is laid on a concrete frame floor of each floor via a floor clearance of a predetermined height is formed over the entire plan view of the indoor space of one dwelling unit,
The boundary wall of one dwelling unit has a mounting wall and a fixed wall,
The mounting wall is formed as a wall body mounted with its legs mounted on the upper surface of the upper floor and provided with an entrance / exit, and the clearance above the floor between the upper floor and the frame floor under the legs of the mounting wall is provided. Form the
The fixed wall is formed as a wall body whose legs are joined to the frame floor, and a wall / floor clearance having a predetermined horizontal dimension is formed between the side surface of the fixed wall and the end surface of the upper floor,
By forming a floor clearance between the cabinet floor and the upper floor over the entire plan view of the indoor space of one dwelling unit, a sound insulation structure between the upper and lower floor dwelling units is constructed ,
The passage outside the dwelling is a common corridor, and also in this common corridor, a double floor structure in which a concrete upper floor is laid on a concrete frame floor via a floor clearance of a predetermined height is formed.
A multi-storied building dwelling structure characterized in that a slit is formed in the upper floor, and the upper floor is separated into a dwelling room interior side and a common corridor side by this slit .   The upper floor is a floor structure made of reinforced concrete that has been cast on site or a floor structure in which a plurality of floor panels made of precast reinforced concrete are spread and integrated. Multi-story building dwelling structure. The dwelling unit structure of a multilayer building according to claim 1 , 2 or 3 , wherein a cushioning material for floor clearance is arranged in the floor clearance in the double floor structure.

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