JP7056828B2 - Unit building - Google Patents

Description

The present invention relates to a unit building.

The following Patent Document 1 discloses a technique relating to a unit structure in which a cut surface inclined with respect to a horizontal plane is formed in a roof portion of a unit building. In this prior art, three short-dimensional pillars are used in the roof portion, and two cut surfaces are formed. This makes it possible to comply with the diagonal line regulation on two sides.

Japanese Patent No. 2634716

However, in the above prior art, diagonal beams are three-dimensionally arranged and joined to columns and horizontal beams in order to form a cut surface. Therefore, the joining work between the members becomes difficult.

In consideration of the above problems, it is an object of the present invention to obtain a unit building having a simple structure and capable of complying with two-sided diagonal line regulation.

In order to achieve the above object, the unit building according to the first aspect constitutes the upper part of the building body, has a first cut surface on the first roof portion, and has a lower floor unit arranged on the lower side. A cut unit set back on an elevation surface, a lower floor unit, and a setback portion formed by including the cut unit, and a wall portion provided in the setback portion and forming an indoor space, and a wall portion. A second cut surface provided on the setback portion and connected to the horizontal plane of the wall portion and the first roof portion, and a third cut surface connected to the second cut surface, the wall portion, and the first cut surface. It has a second roof portion configured to include the above.

In the unit building according to the first aspect, the cut unit constituting the upper part of the building body has the first cut surface on the first roof portion and is set back in an elevation with respect to the lower floor unit arranged on the lower side. Has been done. The setback portion formed by including the lower floor unit and the cut unit is provided with a wall portion and a second roof portion, and the wall portion and the second roof portion form an indoor space and the wall portion. The second cut surface is formed by the second roof portion connected to the horizontal plane of the first roof portion.

The second roof portion of the setback portion includes a second cut surface and a third cut surface, and the first cut surface of the first roof portion of the cut unit and the second roof of the setback portion. The second cut surface of the portion is connected by the third cut surface of the second roof portion.

That is, on the roof portion (first roof portion, second roof portion) of this unit building, the first cut surface, the second cut surface, and the third cut surface are formed, and diagonal line regulation is performed on the two surfaces of the unit building. Can be handled.

As a comparative example, for example, when a diagonal beam that joins a column and a horizontal beam is used in order to join the first cut surface of the first roof portion and the second cut surface of the second roof portion to each other, the first Since the cut surface and the second cut surface are three-dimensionally joined, the joining work between the members becomes difficult.

On the other hand, in this embodiment, an indoor space is created by a wall portion and a second roof portion separately in the setback portion separately from the building unit such as the cut unit and the standard unit. That is, in this embodiment, it is possible to join with a so-called roof panel without using the columns and horizontal beams forming the unit, and the diagonal beams for joining the columns and the horizontal beams in three dimensions are unnecessary.

Therefore, in this embodiment, the first cut surface, the second cut surface, and the third cut surface are formed on the roof portions (first roof portion, second roof portion) of the unit building with a simple structure. Workability is good without impairing the productivity of the unit itself.

Here, the "first cut surface" and the "second cut surface" are surfaces formed on the roof portion and inclined with respect to the horizontal plane in order to comply with the diagonal line regulation of the road diagonal line and the northern diagonal line. Further, the "lower floor unit" is a unit constituting the first floor portion when the cut unit is on the second floor, and is a unit constituting the second floor portion when the cut unit is on the third floor. Further, the "elevation surface" may be a surface on the end surface side (short side side) or a surface on the girder surface side (long side side).

In addition, the "standard unit" in this embodiment refers to a whole unit having a substantially box shape in which the cut surface is not provided with respect to the cut unit in which the cut surface is provided on the roof portion of the unit. Therefore, for example, a unit in which some columns are eliminated by providing a reinforcing beam, a unit provided with a bus unit, and the like are also included in the standard unit in this embodiment.

The unit building according to the second aspect is the unit building according to the first aspect, in which the second cut surface of the second roof portion stands up from the first cut surface of the cut unit.

For example, when the borderline of the adjacent land on the north side faces due north, the cut surface of the roof portion set by the restriction by the diagonal line on the north side can be erected by moving away from the borderline of the adjacent land. In addition, when the boundary line of the adjacent land on the north side is inclined with respect to the virtual line connecting east and west, the roof part set by the restriction by the diagonal line on the north side is compared with the case where the boundary line of the adjacent land on the north side faces due north. The cut surface of is able to stand up.

Therefore, in the unit building according to the second aspect, the second cut surface of the second roof portion is erected more than the first cut surface of the cut unit. As a result, the range in which the interior space is compressed by the slanted ceiling can be reduced as compared with the case where the slope of the second cut surface is gentle.

The unit building according to the third aspect is the unit building according to the first aspect or the second aspect, and the wall portion is supported by a canch floor overhanging from the floor portion of the cut unit.

In the unit building according to the third aspect, the wall portion of the setback portion can be assembled to the cut unit at the factory by supporting the wall portion on the canch floor protruding from the floor portion of the cut unit. can. Therefore, it is not necessary to assemble the wall portion of the setback portion together with the floor portion to the setback portion at the site, and the workability at the site is improved accordingly.

The unit building according to the fourth aspect is the unit building according to any one of the first to third aspects, in which a standard unit is provided adjacent to the cut unit, and the wall portion is the cut. A pillar portion that is provided over the unit and the standard unit and is located on the wall portion side and is adjacent to each other between the cut unit and the standard unit is removed.

In the unit building according to the fourth aspect, a standard unit is provided adjacent to the cut unit. The wall portion of the setback portion is provided over the cut unit and the standard unit, and the pillar portion located on the wall portion side and adjacent to the cut unit and the standard unit is removed. .. As a result, it is possible to secure a large interior space without pillars at the corners adjacent to each other of the units subject to the two-way diagonal line regulation.

As described above, the unit building according to this aspect has an excellent effect that the diagonal line regulation on two surfaces can be dealt with with a simple structure.

It is the schematic perspective view which looked at the unit building which concerns on this embodiment from the north side diagonally upper side. It is a schematic perspective view which shows each building unit which constitutes the unit building which concerns on this embodiment. It is a schematic exploded perspective view of the main part of the unit building which concerns on this embodiment. It is a schematic disassembled sectional view corresponding to FIG. 5 which shows the main part of the unit building which concerns on this embodiment. It is a schematic cross-sectional view which shows the state which cut along the 5-5 line of FIG. It is a schematic sectional view corresponding to FIG. 5 which shows the modification (1) of the unit building which concerns on this embodiment. It is a schematic sectional drawing corresponding to FIG. 5 which shows the modification (2) of the unit building which concerns on this embodiment. It is a schematic perspective view corresponding to FIG. 2 which shows the modification (3) of the unit building which concerns on this embodiment. It is a schematic perspective view corresponding to FIG. 2 which shows the modification (4) of the unit building which concerns on this embodiment. It is a schematic perspective view which shows the unit building as a comparative example.

Hereinafter, an embodiment of the unit building according to the present invention will be described with reference to the drawings.
(Structure of unit building)

First, the configuration of the unit building according to the present embodiment will be described.
FIG. 1 shows a schematic perspective view of the unit building 10 according to the present embodiment as viewed from the diagonally upper north side. As shown in FIG. 1, this unit building 10 is, for example, a two-story house, a lower floor unit 12 constituting a first floor portion and forming a living space, and a living space forming a second floor portion. It is configured to include the upper floor unit 14 and the like.

The lower floor unit 12 includes standard units 16 and 18, which are substantially box-shaped, respectively, and the standard unit 16 and the standard unit 18 are adjacent to each other along the end face direction (arrow A direction) of the unit building 10. And are arranged. On the other hand, the upper floor unit 14 includes a cut unit 20 and a standard unit 22. The cut unit 20 and the standard unit 22 have a substantially box shape, and the cut unit 20 has a shape having a cut surface (first cut surface) 21 described later on the girder surface side. The cut unit 20 and the standard unit 22 are arranged adjacent to each other along the end surface direction of the unit building 10.

Further, in the unit building 10, the girder face size is different between the cut unit 20 and the standard unit 22 and the standard units 16 and 18, and the cut unit 20 and the standard unit 22 have a girder face size larger than that of the standard units 16 and 18. Is getting smaller. Therefore, the upper floor unit 14 including the cut unit 20 and the standard unit 22 is set back on the elevation side on the wife side with respect to the lower floor unit 12 including the standard units 16 and 18. (Setback portion 24) It is arranged in a state of being set back.

Here, the configurations of the standard units 16, 18 and 22 will be described.
Since the standard units 16 and 18 and the standard unit 22 have substantially the same basic configuration although the girder size is different, the standard unit 22 will be described as a representative of these. In the standard unit 22, if the member cannot be seen due to the angle of the drawing, other standard units 16 and 18 may be referred to.

FIG. 2 shows a schematic perspective view showing each building unit 11 (standard unit 16, 18, cut unit 20, standard unit 22) constituting the unit building 10. As shown in this figure, the standard unit 22 has pillars 26 having the same length erected at the four corners.

The floor girders 28 (see the standard unit 16) are connected to the lower ends of the columns 26 adjacent to each other along the girder direction (arrow B direction). Although the length of the floor girder 28 in the girder direction of the standard unit 22 and the length of the floor girder 28 in the girder direction of the standard units 16 and 18 are strictly different, they will be described using the same reference numerals for convenience of explanation. .. The ceiling girder 32, which will be described later, is the same as the floor girder 28.

Further, floor girders 30 are connected to the lower ends of adjacent columns 26 along the direction of the wife (direction of arrow A). Further, a plurality of floor beams 29 (see FIG. 5) are bridged between the pair of floor beams 28 facing each other, and the plurality of floor beams 29 are arranged at predetermined intervals.

The "bonding" used in the present embodiment includes not only the case where the members are directly connected by welding or fastening, but also the case where the members are indirectly connected via a metal bracket or the like. ..

On the other hand, ceiling girders 32 are connected to the upper ends of columns 26 adjacent to each other along the girder direction. Further, ceiling girders 34 are connected to the upper ends of columns 26 adjacent to each other along the direction of the wife. A plurality of ceiling beams 36 are bridged between the pair of ceiling beams 32 facing each other, and the plurality of ceiling beams 36 are arranged at predetermined intervals. Further, the standard units 16, 18 and 22 are provided with a floor panel 38 on the lower end side of the pillar 26 and a ceiling panel 39 on the upper end side of the pillar 26.

On the other hand, the cut unit 20 is shorter than the pair of standard pillars 40 arranged on the standard unit 22 side and having the same length as the pillar 26 of the standard unit 22 and the standard pillar 40 erected on the outdoor 42 side. It is configured to include a pair of short pillars 44.

The floor girders 28 are connected to the lower ends of the short columns 44 and the standard columns 40 that are adjacent to each other along the girder direction. Further, floor girders 30 are connected to the lower ends of the short pillars 44 and the standard pillars 40 that are adjacent to each other along the direction of the wife.

On the other hand, the ceiling girder 52 is connected to the upper end portion of the short pillars 44 adjacent to each other along the girder direction, and the ceiling girder 54 is connected to the upper end portion of the standard pillar 40. An intermediate beam 56 is arranged between the ceiling beam 52 and the ceiling beam 54 along the girder direction.

Further, ceiling girders 58 are arranged at the upper ends of the short pillars 44 adjacent to each other along the wife direction and at both ends in the girder direction of the intermediate girders 56, and the ceiling girders 58 are the upper ends of the short pillars 44. It is arranged so as to be inclined upward toward the intermediate beam 56 side from the portion. Further, ceiling girders 60 are arranged at both ends of the intermediate girders 56 adjacent to each other along the end direction in the girder direction and at the upper ends of the standard columns 40, respectively. Further, the ceiling girder 58 and the ceiling girder 60 are connected without passing through the intermediate girder 56.

A plurality of ceiling beams 62 are bridged between the ceiling beams 52 and the intermediate beams 56, and the plurality of ceiling beams 62 are arranged at predetermined intervals. Further, a plurality of ceiling beams 64 are bridged between the intermediate beam 56 and the ceiling beam 54 as in the case of the ceiling beam 62, and the plurality of ceiling beams 64 are arranged at predetermined intervals. ing. Further, the cut unit 20 is provided with a floor panel 38 on the lower end side of the short pillar 44 and the standard pillar 40, and a ceiling panel 68 is provided on the upper end side of the short pillar 44 and the standard pillar 40.

The ceiling panel 68 is configured to include a cut portion 70 and a horizontal portion 72 along the direction of the wife. The horizontal portion 72 is arranged along a substantially horizontal plane and includes ceiling girders 54 and 60 and intermediate girders 56. On the other hand, the cut portion 70 is arranged in an inclined state with respect to the horizontal portion 72, and includes the ceiling girders 52 and 58 and the intermediate girders 56. Then, as shown in FIG. 1, the cut portion 70 forms a cut surface (first cut surface) 21 that stands upright with respect to the horizontal plane in the roof portion 98 of the cut unit 20.

As described above, the cut unit 20 and the standard unit 22 shown in FIG. 2 have a smaller girder surface size than the standard units 16 and 18. Therefore, the upper floor unit 14 is arranged in a state of being set back on the elevation with respect to the lower floor unit 12, and the setback portion 24 is provided on the lower floor unit 12 side.

Here, FIG. 3 shows a schematic exploded perspective view of a main part of the unit building 10. Further, FIG. 5 shows a schematic cross-sectional view showing a state of being cut along the line 5-5 shown in FIG. 1, and FIG. 4 shows a schematic disassembled cross-sectional view corresponding to FIG. ing.

As shown in FIGS. 3 to 5, in the present embodiment, the interior space 80 is formed in the setback portion 24 (setback amount; L1). Therefore, the setback portion 24 is provided with a floor portion 76, a wall portion 74, and a roof portion (second roof portion) 78, and the interior space 80 is provided by the floor portion 76, the wall portion 74, and the roof portion 78. Is being formed.

In the present embodiment, the floor portion 76 can be coupled to the setback portion 24 formed by the lower floor unit 12, and includes the floor panel 96. Then, the wall portion 74 is connected to the floor portion 76.

As shown in FIG. 3, the wall portion 74 has an outer wall portion 84 having a substantially rectangular shape that is substantially flush with the end faces 82 of the standard units 16 and 18, and a girder surface 86 of the standard unit 16 and the cut unit 20. The outer wall portion 88 having a substantially rectangular shape that is substantially flush with each other, and the girder surface 90 of the standard units 18 and 22 and the outer wall portion 92 having a substantially rectangular shape that is substantially flush with each other are included. Further, the wall portion 74 includes an outer wall portion 94 having a substantially triangular shape, which is coupled to the upper end portion of the outer wall portion 92 and is substantially flush with the girder surface 90 of the standard unit 22. The outer wall portion 94 may be integrally formed with the outer wall portion 92.

Further, the roof portion 78 includes a roof panel 104 and a roof panel 110. The roof panel 104 is combined with the horizontal roof panel (horizontal plane) 100 of the roof portion (first roof portion) 98 of the cut unit 20 and the horizontal roof panel 102 of the roof portion 101 of the standard unit 22, and the outer wall of the wall portion 74. It is adapted to be coupled to the upper end portion of the portion 84. On the other hand, the roof panel 110 is connected to the upper end portion of the outer wall portion 88 and is coupled to the roof panel 104 and the inclined roof panel 108 of the cut unit 20. As a result, the cut surface (third cut surface) 111 is formed on the roof portion 78.

In the present embodiment, the roof panel 104 is coupled to the horizontal roof panel 100 and the horizontal roof panel 102, so that the cut surface (second cut surface) 105 is formed in the roof portion 78. The cut surface 105 stands up against a horizontal plane and has substantially the same gradient as the cut surface 21 of the roof portion 98 of the cut unit 20. That is, the unit building 10 is a building in which cut surfaces 21 and 105 are formed on two surfaces (roof portion 98 and roof portion 78) of the building roof 13, respectively, and are subject to diagonal line regulation.

Here, the procedure for assembling the unit building 10 in the present embodiment will be described.
As shown in FIGS. 2 and 4, after the lower floor unit 12 (standard units 16 and 18) is installed on the foundation (not shown), the upper floor unit 14 (cut unit 20) is placed on the lower floor unit 12. , Standard unit 22) is installed. In this state, the upper floor unit 14 is arranged in a state of being set back on the elevation with respect to the lower floor unit 12, and the setback portion 24 is provided on the lower floor unit 12 side.

The floor panel 96 of the setback portion 24 is coupled (installed) to the setback portion 24, that is, the ceiling girders 32 and 34 of the lower floor units 12 (standard units 16 and 18). In the present embodiment, the wall portion 74 is preliminarily integrated with the floor panel 96 of the setback portion 24. Therefore, in a state where the floor panel 96 of the setback portion 24 is installed on the ceiling girders 32 and 34 of the lower floor unit 12, the floor panel 96 and the wall portion 74 of the setback portion 24 are installed on the setback portion 24. It will be done.

The floor panel 96 and the wall portion 74 of the setback portion 24 may be separated from each other. In this case, after the floor panel 96 of the setback portion 24 is connected to the ceiling girders 32 and 34 of the lower floor unit 12, the wall portion 74 is connected to the floor panel 96. The outer wall portions 88 and 92 (see FIG. 3) located on both sleeves of the wall portion 74 are located on the short pillar 44 (see FIG. 2) side of the cut unit 20 and the pillar 26 (see FIG. 2) side of the standard unit 22, respectively. Be combined.

Next, as shown in FIGS. 3 and 4, the roof panel 104 is coupled to the outer wall portion 84 of the wall portion 74, the horizontal roof panel 100, and the horizontal roof panel 102. Then, the outer wall portion 94 is coupled to the upper end portion of the outer wall portion 92 and the girder surface 90 side of the standard unit 22 shown in FIG. Further, the roof panel 110 is coupled to the upper end portion of the outer wall portion 88, the roof panel 104, and the inclined roof panel 108 of the cut unit 20.

Then, as shown in FIG. 4, each joint material (floor joint material 112, roof joint material 114, wall joint material 116, ceiling joint material 118) is assembled to each building unit 11. Specifically, the floor joint 112 is assembled between the floor panel 38 of the upper floor unit 14 and the floor panel 96 of the setback portion 24, and the roof joint 114 is assembled between the horizontal roof panel 100 and the roof panel 104. wear.

Next, on the indoor space 80 side of the roof panel 104, a wall joint 116 is assembled between the roof panel 104 and the outer wall portion 84 of the setback portion 24, and a ceiling joint is attached between the roof panel 104 and the ceiling panel 39. Assemble the material 118. Each exterior material (body difference 120, sheet metal 122) is attached to the exterior side of each building unit 11. Specifically, the body difference 120 is assembled between the upper floor unit 14 and the lower floor unit 12, and the sheet metal 122 is assembled between the roof joint member 114 and the roof panel 104.

(Action and effect of unit building)
Next, the operation and effect of the unit building according to the present embodiment will be described.

As shown in FIG. 3, in the unit building 10 according to the present embodiment, the upper floor unit 14 including the cut unit 20 and the standard unit 22 is the lower unit including the standard units 16 and 18. It is arranged in a state of being set back on an elevation with respect to the floor unit 12.

An interior space 80 is formed by the floor portion 76, the wall portion 74, and the roof portion 78 in the setback portion 24 provided on the lower floor unit 12 side, and the roof panel 104 of the roof portion 78 is used as a roof. A cut surface 105 is formed on the roof portion 78 by being coupled to the horizontal roof panel 100 of the portion 98 and the horizontal roof panel 102 of the roof portion 101.

That is, in the building roof 13 of the unit building 10, the cut surface 21 is formed on the roof portion 98, and the two cut surfaces 105 are formed on the roof portion 78. As described above, the unit building 10 is formed. It is possible to comply with diagonal line regulations on two sides.

Further, in the present embodiment, the cut surface 21 of the roof portion 98 of the cut unit 20 and the cut surface 105 of the roof portion 78 of the setback portion 24 are connected by the cut surface 111 of the roof panel 110.

As a comparative example, for example, as shown in FIG. 10, when a diagonal beam 204 is used to join the roof portion 201 and the roof portion 202 to each other in the unit building 200, the diagonal beam 204 is horizontal with the column 206. Since the beams are arranged three-dimensionally with respect to the beams 208 and 210, the work at the time of joining becomes complicated.

On the other hand, in the present embodiment, as shown in FIG. 3, the interior space is separately provided by the wall portion 74, the roof portion 78, etc. in the setback portion 24 separately from the building unit 11 such as the cut unit 20 and the standard unit 22. I'm making 80. That is, in the present embodiment, the inclined roof panel 108 and the roof panel 104 can be joined via the roof panel 110 shown in FIG. 3 without using the pillar 206 and the horizontal beams 208 and 210 shown in FIG. The diagonal beam 204 for three-dimensionally joining the column 206 and the horizontal beams 208 and 210 shown in FIG. 10 is not required.

Therefore, in the present embodiment, with a simple configuration, it is possible to comply with the diagonal line regulation on the two surfaces of the building roof 13 of the unit building 10, the productivity of the building unit 11 itself is not impaired, and the workability is good.

Further, as described above, since the diagonal beam 204 shown in FIG. 10 is three-dimensionally joined to the columns 206 and the horizontal beams 208 and 210, the stress transmission path becomes complicated in the unit building 200. Therefore, a loss will occur during load transmission.

On the other hand, in the present embodiment shown in FIG. 2, as described above, since the building unit 11 is configured except for the setback portion 24, it is compared with the case where the diagonal beam 204 (see FIG. 10) is used. Therefore, the structural frame is simple, the stress transmission path is simplified, and the stress transmission efficiency in the unit building 10 is improved.

(Modified example of this embodiment)
(1) In the present embodiment, in the building roof 13 of the unit building 10 shown in FIG. 1, the cut surface 105 of the roof portion 78 has substantially the same slope as the cut surface 21 of the roof portion 98, but the unit building. It is not limited to this as long as it is possible to comply with the diagonal line regulation on the two surfaces of the building roof 13 of 10.

For example, in the unit building 10, when the adjacent land boundary line P on the north side faces due north, the slope of the roof panel 104 set by the restriction by the northern diagonal line by moving away from the adjacent land boundary line P is the inclined roof panel. It is possible to stand up more than 108. That is, the slope of the roof panel 104 can be steeper than the slope of the sloped roof panel 108. Further, when the adjacent land boundary line P on the north side has an inclination angle θ with respect to the virtual line Q connecting east and west (when the adjacent land boundary line P on the north side does not face due north), the adjacent land boundary line P is true. Compared to the case of facing north, the slope of the cut surface 105 of the roof panel 104 set by the limitation due to the north diagonal line can be made steeper.

In this case, as shown in FIG. 6, the setback amount L2 can be made smaller than the setback amount L1 shown in FIG. 5 (L2 <L1). By reducing the setback amount L2 in this way, the lengths of the cut unit 20 and the standard unit 22 in the girder direction can be increased. That is, the interior space 124 composed of the cut unit 20 and the standard unit 22 can be widened.

Further, as compared with the case where the slope of the roof panel 104 is gentle (see FIG. 5), the range in which the interior space 124 is pressed by the slanted ceiling can be reduced. Further, as the setback amount L2 becomes smaller, the area of the floor panel 96 of the setback portion 24 also becomes smaller, and the floor panel 96 can be simplified. That is, the wall portion 74 may be connected to the ceiling girders 32 and 34 (see FIG. 2) of the lower floor unit 12, and the floor panel 96 may be a joint material type floor material. Further, by lowering the wall portion 74, the gradient of the inclined roof panel 104 can be made steeper than the gradient of the inclined roof panel 108, and the interior space 124 can be widened.

(2) Contrary to the above, as shown in FIG. 7, the setback amount L3 can be made larger than the setback amount L1 shown in FIG. 5 (L3 <L1). That is, here, in the roof panel 128 of the setback portion 126, the inclined portion 130 and the flat portion 132 may be integrated. In this case, the roof panel 128 can have an arbitrary slope by changing the range of the flat portion 132.

In this way, by providing the flat portion 132 on the roof panel 128 and increasing the setback amount L3, the setback portion 126 can be used as the atrium portion 133 without affecting the standard unit 22 and the cut unit 20. Can be done. Then, a staircase or the like can be provided in the atrium 133. It is also possible to arrange a space with a special structure that partially lowers the floor beams, such as a barrier-free type bathroom. That is, the degree of freedom in design is widened, and the versatility of the unit building 10 is improved.

(3) Further, in the present embodiment, as shown in FIG. 4, the floor portion 76, the wall portion 74, and the roof portion (second roof portion) 78 are provided on the setback portion 24 provided on the lower floor unit 12 side. Is provided, and the interior space 80 is formed by the floor portion 76, the wall portion 74, and the roof portion 78. However, the interior space 80 is not limited to this as long as it can be formed in the setback portion 24.

For example, as shown in FIG. 8, the cut unit 20 and the standard unit 22 may be configured to include the canch floor 134. Note that FIG. 8 shows, as an example, a diagram in which the canch floor 134 is assembled on the cut unit 20 side.

The canch floor 134 becomes the floor portion 136 of the setback portion 24. Here, the floor portion 136 is attached to the cut unit 20 via a bracket 138 coupled to the floor girder 30 of the cut unit 20, and the wall portion 140 is supported by the canch floor 134.

Generally, the canch floor 134 is assembled to the cut unit 20 and the standard unit 22 in the factory. Therefore, when the cut unit 20 and the standard unit 22 are provided with the canch floor 134, the floor portion 136 and the wall portion of the setback portion 24 are provided. The 140 will be assembled in the factory together with the assembly of the cut unit 20 and the standard unit 22. Therefore, at the site, it is not necessary to assemble the floor portion 136 and the wall portion 140 of the setback portion 24 to the cut unit 20 and the standard unit 22, and the workability is improved accordingly.

(4) Further, in the present embodiment, as shown in FIG. 2, the pillar 26 of the standard unit 22 constituting the upper floor unit 14 and the standard pillar 40 of the cut unit 20 are arranged adjacent to each other. , Not limited to this. For example, as shown in FIG. 9, the pillar 26 and the standard pillar 40 on the setback portion 24 side may be removed.

As a result, the standard unit 22 and the cut unit 20 subject to the two-way diagonal line regulation can secure a wide interior space 124 without the pillar 26 and the standard pillar 40 at the corners (A) adjacent to each other. However, in this case, the ceiling beam 34 of the standard unit 22 and the ceiling beam 60 of the cut unit 20 are connected by the reinforcing beam 142.

Although the two-story unit building 10 has been described in the present embodiment, the present invention can also be applied to a three-story or more unit building.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above, and one embodiment and various modifications may be used in combination as appropriate, and the present invention does not deviate from the gist of the present invention. Of course, it is possible to carry out various modifications other than the above within the range.

10 unit building (building body)
11 Building unit 12 Lower floor unit 16 Standard unit 18 Standard unit 20 Cut unit 21 Cut surface (first cut surface)
22 Standard unit 24 Setback part 26 Pillar (pillar part)
38 Floor panel (floor part)
40 Standard pillar (pillar part)
74 Wall 78 Roof (2nd roof)
80 Interior space 98 Roof part (1st roof part)
100 Horizontal roof panel (horizontal plane of the first roof)
105 Cut surface (2nd cut surface, 2nd roof)
111 Cut surface (3rd cut surface, 2nd roof)
124 Interior space 126 Setback part 134 Canch floor 140 Wall part

Claims (4)

A cut unit that constitutes the upper part of the building body, has a first cut surface on the first roof, and is set back on the elevation with respect to the lower floor unit arranged on the lower side.
A setback unit formed by including the lower floor unit and the cut unit,
Equipped with
A wall portion provided in the setback portion and forming an indoor space, and a wall portion.
A second cut surface provided on the setback portion and connected to the horizontal plane of the wall portion and the first roof portion, and a third cut surface connected to the second cut surface, the wall portion, and the first cut surface. The second roof, which is composed of
Have,
The roof panel having the third cut surface is a unit building that is joined to the roof panel having the first cut surface and the roof panel having the second cut surface without using an oblique beam . The unit building according to claim 1, wherein the second cut surface of the second roof portion stands up from the first cut surface of the cut unit. The unit building according to claim 1 or 2, wherein the wall portion is supported by a canch floor protruding from the floor portion of the cut unit. A standard unit is provided adjacent to the cut unit,
Claims 1 to claim that the wall portion is provided over the cut unit and the standard unit, and the pillar portion located on the wall portion side and adjacent to the cut unit and the standard unit is removed. The unit building according to any one of items 3.

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