JP6441019B2 - building - Google Patents

Description

The present invention relates to the building.

  In a building constituting a store such as a convenience store, when a building structure is industrialized, a roof may be constructed by a plurality of roof units installed on the building body. For example, there is a building including a plurality of rectangular parallelepiped roof units arranged along the width direction of a building, and a roof constructed by these roof units (for example, Patent Document 1). In this building, the roof unit manufactured in the factory is transported to the building construction site using a transportation means such as a truck, and is installed on the building main body at the construction site.

  Further, in this building, each roof unit has a truss structure, so that the indoor space of the building can be made large. In the building body, structural parts such as pillars are arranged to face each other along the longitudinal direction of the roof unit, and both end parts of the roof unit are supported by these structural parts. In this configuration, since the roof unit has a truss structure, it is possible to increase the separation distance between the structural portions arranged to face each other. For this reason, for example, in a store, after realizing a sales floor space where there is no structure such as a pillar, it is possible to increase the space of the sales floor space.

JP 2012-207428 A

  However, in the configuration in which the roof unit has a truss structure, there is a concern that the cost burden and work burden when manufacturing the roof unit are large in increasing the indoor space.

  This invention is made | formed in view of the said situation, and makes it the main objective to construct | assemble the roof provided with the several roof unit suitably.

  Hereinafter, means and the like effective for solving the above-described problems will be described while showing functions and effects as necessary. In the following, for easy understanding, the corresponding configuration in the embodiment of the invention is appropriately shown in parentheses, etc., but is not limited to the specific configuration shown in parentheses.

  The roof structure of the building of the first invention is a roof unit (roof unit 31, 36) having a roof surface material (roof surface materials 35, 36) and a roof structure part (roof frames 37, 38) for supporting the roof surface material. 32) is a roof structure of a building provided on the upper side of the building body (building body 12), and the plurality of roof units include a truss structure portion (front side roof) including a truss structure. A truss roof unit (front side roof unit 31) having the frame 37) as the roof structure part, and a non-truss structure part (back side roof frame 38) configured without including the truss structure are the roof structure part. And a panel roof unit (back side roof unit 32) formed in a panel shape, and the panel roof unit is configured such that the non-truss structure part is connected to the truss structure part. And it is characterized in that it is supported by the truss structure.

  According to the first invention, since the truss roof unit is used as the roof unit, the indoor space of the building can be enlarged. Moreover, since the panel roof unit is also used in addition to the truss roof unit, it is possible to reduce the cost burden and work burden when manufacturing the roof unit, compared to a configuration in which only the truss roof unit is used. Therefore, the roof provided with the several roof unit can be constructed | assembled suitably.

  According to a second invention, in the first invention, an overlap portion (overlap portion 71) in which the roof surface materials of the truss roof unit and the panel roof unit are vertically aligned with each other is formed, A connecting portion between the truss structure portion and the non-truss structure portion is covered from above by at least one of the roof surface materials of the truss roof unit and the panel roof unit.

  According to 2nd invention, since the overlap part is formed in the roof, waterproofness can be improved about the connection part of the roof surface material of a truss roof unit, and the roof surface material of a panel roof unit. Moreover, since the connecting portion between the truss structure part and the non-truss structure part is arranged below the roof surface material, when fixing the panel roof unit to the truss roof unit, the non-truss structure part with respect to the truss structure part And the operation of forming the overlapping portion of the roof surface materials can be performed together. For this reason, the work burden at the time of fixing a panel roof unit with respect to a truss roof unit can be reduced.

  In 3rd invention, in 2nd invention, each roof surface material of the said truss roof unit and the said panel roof unit forms the one-way water gradient in the arrangement direction of these truss roof units and panel roof units. Among the truss roof unit and the panel roof unit, the roof surface material on the upstream side of the water gradient is disposed on the upper side of the roof surface material on the downstream side of the water gradient. Thus, the overlap portion is formed.

  According to the third invention, in the overlap portion of the roof surface material, rainwater and the like flow down from the upstream roof surface material toward the downstream roof surface material. It is difficult for water to enter between the materials. Thus, in the arrangement direction of the truss roof unit and the panel roof unit, in the configuration in which one end of the roof is the upper end and the other end is the lower end, the configuration in which the upper end (ridge) is formed in the middle portion of the roof is In contrast, since it is not necessary to provide a “building wrap” or the like, it is possible to reduce the cost burden and work burden when performing waterproofing processing on the roof.

  In 4th invention, in any 1st thru | or 3rd invention, the structure of the said building main body WHEREIN: The connection support part which supports the connection part of the said truss structure part and the said non-truss structure part ( The partition structure portion 21e) is included, and the truss structure portion of the truss structure portion and the non-truss structure portion is connected to the connection support portion.

  According to the fourth invention, since the truss roof unit is supported by the connection support portion, the connection support is provided by connecting the truss structure portion to the connection support portion and then connecting the non-truss structure portion only to the truss structure portion. There is no need to connect to the part. For this reason, compared with the structure with which the non-truss structure part was connected with both the truss structure part and the connection support part, the work burden at the time of installing a panel roof unit can be reduced.

  According to a fifth invention, in the fourth invention, the structure of the building main body includes a pair of opposing structure parts (structure parts 21a and 21b) facing each other with the connection support part interposed therebetween, and the truss In the roof unit, the truss structure part is connected to the first structure part (front side structure part 21a) of the pair of opposing structure parts and the connection support part, so that the first structure part and the connection support are provided. The non-truss structure part is connected to the second structure part (back side outer wall part 15b) and the truss structure part among the pair of opposing structure parts. And supported by the second structure portion and the truss structure portion.

  When a truss roof unit manufactured in a factory is transported to a construction site, it is assumed that the size of the truss roof unit is restricted due to restrictions on transportation such as the size of a truck bed. For example, in a configuration in which a truss roof unit is spanned between a pair of opposing outer wall portions in a building body, the separation distance between the pair of outer wall portions is set according to the size of the truss roof unit. Due to restrictions on unit transportation, the size of the building itself is limited.

  On the other hand, according to the fifth invention, since the connection support portion is disposed between the first structure portion and the second structure portion in the building body, the connection between the first structure portion and the second structure portion. Even if the separation distance is set to a value larger than the length dimension of the truss roof unit, the truss roof unit can be properly installed on the upper side of the building body. In addition, in the configuration in which the truss roof unit is spanned between the first structure portion and the connection support portion, the separation distance between the first structure portion and the connection support portion is made as large as possible using the structural strength of the truss roof unit. Since it can set, a connection support part can be arranged in the position near the 2nd structure part. In this case, since the separation distance between the second structure portion and the connection support portion can be set to a minimum value, even if the panel roof unit does not have a truss structure, the panel roof unit can be connected to the second structure portion and the truss roof. It can be properly installed in the state of being stretched over the unit.

  The truss roof unit and the panel roof unit are both formed in a rectangular shape in plan view, and the truss roof unit has long sides arranged in the direction in which the first structure portion and the connection support portion are arranged. Are arranged side by side in a direction orthogonal to the alignment direction, and the panel roof unit has a short side extending in the alignment direction of the second structure portion and the connection support portion. It is preferable that the plurality of truss roof units are arranged in a state of being spanned.

  According to this configuration, since one panel roof unit is arranged side by side for a plurality of truss roof units, compared to a configuration in which the panel roof unit is individually arranged for each of the truss roof units, The number of panel roof units will be reduced. In this case, since the connection location of panel roof units reduces, the work burden at the time of installing a panel roof unit can be reduced.

  In a sixth invention, in any one of the first to fifth inventions, the truss structure portion includes a pair of upper and lower chord members (upper chord member 55 and lower chord member 56) and a bundle member (bundle) that connects these chord members. The non-truss structure part is connected to the truss structure part by being fixed to the bundle material.

  According to the sixth invention, in the truss structure portion, the bundle member that firmly connects the upper and lower pair of chord members is to be connected to the non-truss structure portion. It can be supported properly. Moreover, since the bundle material is a vertical material extending in the vertical direction, the panel roof unit should be installed at an appropriate height position by an easy operation of setting the connection position of the non-truss structure portion with respect to the bundle material in the vertical direction. Can do. Thereby, the work burden at the time of setting the height position of a panel roof unit can be reduced.

  According to a seventh invention, in the sixth invention, the non-truss structure portion is provided with a horizontal member (horizontal member 61) provided on the lower side of the roof member in a state of projecting laterally from the roof member. ), And the projecting portion (projecting portion 61a) of the horizontal member is connected to the truss structure portion by being fixed to the bundle material.

  According to the seventh invention, the projecting portion of the horizontal member and the bundle member are arranged in a direction intersecting with the arrangement direction of the truss roof unit and the panel roof unit. The truss structure part and the non-truss structure part can be firmly connected in a state of being inserted. Thereby, the support strength of the non-truss structure part by a truss structure part can be raised.

  In addition, it is preferable that the fixing position of the horizontal member with respect to the bundle member is disposed between the fixing position of the upper chord member and the fixing position of the lower chord member with respect to the bundle member. According to this configuration, since the fixing positions of the horizontal member, the upper chord member, and the lower chord member with respect to the bundle member are shifted up and down, the fixing structure of the horizontal member member with respect to the bundle member is separated from the upper chord member and the lower chord member It is hard to be restricted. Further, in connecting the horizontal member to the bundle member, it is not necessary to project the bundle member upward from the upper chord member or to protrude downward from the lower chord member, so that the versatility of the panel roof unit can be improved. . This is because the upper and lower chord materials are fixed to the bundle material and the roof surface material to the bundle material. This is because it is not necessary to change the position.

  In an eighth invention according to any one of the first to seventh inventions, the structure of the building main body is spaced from the connecting portion between the truss structure portion and the non-truss structure portion toward the non-truss structure portion side. A panel support part (back side structure part 21b) that supports the panel roof unit from below is included, and the non-truss structure part is spaced upward from the panel support part. A holding member (spacer member 67) for holding is provided between the non-truss structure part and the panel support part, and the non-truss structure part is connected to the panel support part via the holding member. ing.

  According to the eighth invention, since the non-truss structure part is installed on the panel support part via the holding member, the entire panel roof unit is obtained by using both the truss structure part and the holding member. It can arrange | position in the position spaced apart upward from the building main body. Moreover, in the configuration in which the height position of the non-truss structure portion is held by the truss structure portion and the holding member, the height position of the connecting portion with respect to the truss structure portion and the holding member without changing the configuration of the panel roof unit itself By setting the height dimension, a desired inclination angle (water gradient) can be given to the roof surface material of the panel roof unit. Therefore, the versatility of the panel roof unit can be enhanced.

  According to a ninth aspect, in the eighth aspect, the holding member includes a plurality of vertical members (vertical members 81) provided at predetermined intervals in a direction intersecting the arrangement direction of the truss roof unit and the panel roof unit. ) And cross members (an upper cross member 82 and a lower cross member 83) that are provided extending in the intersecting direction and connect the plurality of vertical members.

  According to the ninth invention, in the holding member, since the supporting strength for supporting the panel roof unit is secured by the plurality of vertical members, the panel roof unit can be properly installed on the upper side of the building body. it can. Moreover, since the plurality of vertical members are connected by the horizontal members, these vertical members can be attached together to the panel support portion. Thereby, the work burden at the time of fixing a panel roof unit with respect to a panel support part can be reduced.

Diagram showing building structure Top view of the building body Exploded perspective view showing the structure of the building Perspective view of roof frame A-A line cross-sectional view of FIG. The figure which shows the structure of a cover member Diagram showing configuration of spacer member The perspective view which shows the installation procedure of a back side roof unit Longitudinal section showing the installation procedure of the back roof unit

  Hereinafter, an embodiment embodying the present invention will be described with reference to the drawings. In this embodiment, the roof structure of the present invention is embodied in a building constructed by a steel frame construction method. FIG. 1 is a diagram illustrating a configuration of the building 10, FIG. 2 is a plan view of the building body 12, and FIG. 3 is an exploded perspective view illustrating the configuration of the building 10. In FIG. 1, (a) shows a perspective view of the building 10, and (b) shows a plan view of the building 10. In FIG. 2, (a) shows the floor plan of the building 10, and (b) shows the arrangement of the columns 27 and 28.

  As shown in FIG. 1A, the building 10 includes a building main body 12 provided on the foundation 11 and a roof 13 provided on the building main body 12. The building body 12 is formed in a rectangular parallelepiped shape, and is installed in a direction in which the longitudinal direction thereof is the width direction of the building 10. In the building body 12, one of the pair of side surfaces extending in the longitudinal direction forms a building front (facade).

  The roof 13 is a flat roof having a single-flow water gradient, and the roof surface is inclined obliquely downward from the front side of the building toward the back side. On the roof surface, the end on the front side of the building is the upper end, the end on the back is the lower end, and water such as rainwater is directed toward the back of the building 10 along the roof. To come down. In FIG. 1A and FIG. 3, the angle of the water gradient is shown larger than the actual angle.

  As shown in FIG. 2A, the building body 12 includes an outer wall 15 surrounding the indoor space of the building 10 and a partition wall 16 that partitions the indoor space. The outer wall 15 and the partition wall 16 have wall materials, such as a gypsum board and an exterior material, and wall bases, such as a stud and a runner, and the wall surface material is supported by the wall base. The outer wall 15 includes a front outer wall portion 15a that forms a facade surface of the building body 12, a rear outer wall portion 15b that forms a rear side surface, and side outer wall portions 15c and 15d that form side surfaces. Both the front outer wall portion 15a and the rear outer wall portion 15b extend in the longitudinal direction of the building 10, and the side outer wall portions 15c and 15d both extend in the short direction of the building 10. The partition wall 16 is provided in parallel with the outer wall portions 15a and 15b between the front outer wall portion 15a and the rear outer wall portion 15b, and is spanned over the side outer wall portions 15c and 15d. The indoor space is divided into front and back. The front outer wall portion 15a and the rear outer wall portion 15b correspond to a pair of opposing wall portions that face each other with the partition wall 16 therebetween.

  The building 10 is used as a medium-sized store such as a convenience store, and an entrance to the store is provided in the front outer wall portion 15a. The building 10 has a sales space 18 for selling products and a backyard space 19 in which the products can be stored. The sales space 18 is a large space without walls and pillars. Yes. In the indoor space, the space on the front side of the partition wall 16 is a sales space 18 and the space on the back side of the partition wall 16 is a backyard space 19. In the sales space 18, a product display shelf, a cashier counter, and the like are installed.

  In the building main body 12, the sales space 18 is larger than the backyard space 19 because the partition wall 16 is disposed at a position closer to the back outer wall portion 15 b. In this case, the depth dimension D1 (for example, 9.2 m) of the sales space 18 is larger than the depth dimension D2 (for example, 2 m) of the backyard space 19.

  As shown in FIG. 1A, FIG. 2B, and FIG. 3, the building body 12 has a building structure 21 that supports the outer wall 15 and the partition wall 16, and this building structure 21 Includes columns 27 and 28 and a ceiling beam 29. The columns 27 and 28 are erected in a state of extending upward from the foundation 11, and are arranged side by side in the inner space of the outer wall 15 and the partition wall 16. In the outer wall 15 and the partition wall 16, the wall base is fixed to the columns 27 and 28 and the ceiling beam 29, and the wall surface material covers the columns 27 and 28.

  Of the columns 27 and 28, the lattice column 27 is configured to include a plurality of column portions and a lattice connecting the column portions, and the inter-column 28 is disposed between the lattice columns 27. . Of the plurality of lattice pillars 27, the lattice pillar 27 a disposed at the outer corner of the building body 12 extends along the rear outer wall 15 b and the side outer wall 15 c. And has a configuration in which it is difficult to bend in both the front-rear direction and the width direction. In the lattice pillar 27a, pillar portions are arranged at the intersection position of the outer wall portions 15a and 15b, the intermediate position of the rear outer wall portion 15b, and the intermediate position of the lateral outer wall portion 15c, and the adjacent pillar portions are latticed. It is connected by.

  The ceiling girder 29 is stretched over a plurality of columns 27 and 28 to connect the upper ends of the columns 27 and 28 to each other. The ceiling girder 29 has a web extending in the vertical direction and a pair of flanges arranged above and below the web, and is formed of H-section steel. The ceiling girder 29 is provided for each of the front side outer wall portion 15 a, the back side outer wall portion 15 b, the side outer wall portions 15 c and 15 d, and the partition wall 16.

  The building structure 21 supports the near-side structure portion 21a supporting the near-side outer wall portion 15a, the back-side structure portion 21b supporting the back-side outer wall portion 15b, and the side outer wall portions 15c and 15d. Side structure parts 21c and 21d, and a partition structure part 21e supporting the partition wall 16 are provided. These structural portions 21 a to 21 e are each configured to include the pillars 27 and 28 and the ceiling beam 29 and are erected on the foundation 11. Moreover, these structural parts 21a-21e are integrated by each ceiling girder 29 being connected. The partition structure part 21e is provided between the near side structure part 21a and the back side structure part 21b. In this case, the near side structure portion 21a and the back side structure portion 21b are opposed to each other with the partition structure portion 21e interposed therebetween.

  As shown in FIG. 1A and FIG. 3, the roof 13 is configured by installing roof units 31 and 32 on the upper side of the building body 12. The roof units 31 and 32 are placed on the building structure 21 and supported by the building structure 21 from below. The roof units 31 and 32 are arranged side by side along the depth direction of the building 10, and among these roof units 31 and 32, the front side roof unit 31 is arranged on the facade side relative to the back side roof unit 32. Yes. The near-side roof unit 31 is disposed above the sales space 18 and the back-side roof unit 32 is disposed above the backyard space 19.

  The near side roof unit 31 is installed on the near side structure 21a and the partition structure 21e. The near-side roof unit 31 is stretched between the near-side structure portion 21a and the partition structure portion 21e, and is directly supported by the near-side structure portion 21a and the partition structure portion 21e. In this case, the near-side roof unit 31 is also spanned between the near-side outer wall portion 15 a and the partition wall 16.

  On the other hand, the back side roof unit 32 is installed on the back side structure part 21b. The back-side roof unit 32 is in a state of being spanned between the near-side roof unit 31 and the back-side structure portion 21b, and is directly supported by the back-side structure portion 21b, and the near-side roof unit 31. It is indirectly supported by the partition structure part 21e via In this case, the back side roof unit 32 is also spanned between the near side roof unit 31 and the back side outer wall part 15b.

  A plurality of front side roof units 31 and back side roof units 32 are provided side by side in the width direction of the building 10. Each of the plurality of front side roof units 31 is formed in a rectangular parallelepiped shape, and is installed in a direction in which each longitudinal direction is the depth direction of the building 10. In this case, the front roof units 31 are arranged in parallel to each other. Each of the plurality of back-side roof units 32 is formed in a rectangular panel shape, and is installed in a direction in which each longitudinal direction is the width direction of the building 10. Each back-side roof unit 32 is in a state of straddling the boundary between adjacent front-side roof units 31 in the building width direction.

  By the way, for both the front side roof unit 31 and the back side roof unit 32, the one arranged at the end in the width direction of the building 10 is also placed on the side structure part 21c, and its side structure. It is also supported by the portion 21c.

  Moreover, in this embodiment, as shown in FIG.1 (b), the seven near side roof units 31 and the two back side roof units 32 are used. While the near side roof unit 31 has the same length dimension (length dimension which can be spanned between the near side structure part 21a and the partition structure part 21e), two back side roofs The units 32 have different length dimensions. One back side roof unit 32 has a length dimension that can be passed over four front side roof units 31, and the other back side roof unit 32 has three front side roof units 31. It has a length dimension that can be passed over.

  Next, the configuration of the front side roof unit 31 and the back side roof unit 32 will be described with reference to FIGS. 1, 3, and 4. FIG. 4 is a perspective view showing the roof frames 37, 38, (a) showing the front side roof frame 37 and (b) showing the back side roof frame 38.

  As shown in FIGS. 1A and 3, the roof units 31 and 32 have roof surface materials 35 and 36 that form roof surfaces, and roof frames 37 and 38 that support these roof surface materials 35 and 36. doing. The roof surface materials 35 and 36 are folded plate materials formed of a metal material, and are placed on the roof frames 37 and 38 with the folds extending along a water gradient. In the front side roof unit 31, the fold of the front side roof surface material 35 extends along the longitudinal direction, and in the back side roof unit 32, the fold of the back side roof surface material 36 extends along the short side direction. Is extended. In this case, the roof surface materials 35 and 36 are installed at the same inclination angle (water gradient).

  The roof frames 37 and 38 are placed on the ceiling beam 29 of the building structure 21 and are fixed to the ceiling beam 29. Of the roof frames 37 and 38, the front roof frame 37 of the front roof unit 31 is fixed to the front structure 21 a and the partition structure 21 e in a state of straddling the sales floor space 18. Here, the front side roof frame 37 has a truss structure, which makes it difficult for an intermediate portion of the front side roof frame 37 to bend downward. For this reason, it is possible to enlarge the sales space 18. The roof frames 37 and 38 constitute a roof structure portion in a state where they are connected to each other.

  On the other hand, the back roof frame 38 of the back roof unit 32 is fixed to the front roof frame 37 and the back structure 21b across the backyard space 19. Here, the back roof frame 38 does not have a truss structure, and the manufacturing cost can be reduced compared to the front roof frame 37 having a truss structure. In addition, the depth dimension D2 of the backyard space 19 is set to a size that hardly causes bending even in the back roof frame 38 that does not have a truss structure.

  The front roof frame 37 corresponds to the truss structure portion, and the front roof unit 31 corresponds to the truss roof unit. The back roof frame 38 corresponds to a non-truss structure part, and the back roof unit 32 corresponds to a panel roof unit. Furthermore, the partition structure part 21e corresponds to a connection support part that supports the truss roof unit, and the back structure part 21b corresponds to a panel support part that supports the panel roof unit. In addition, the near side structure portion 21a and the back side structure portion 21b correspond to a pair of opposing structure portions, the near side structure portion 21a corresponds to the first structure portion, and the back side structure portion 21b corresponds to the second structure portion. Equivalent to.

  As shown to Fig.4 (a), the near side roof frame 37 is formed in the rectangular parallelepiped shape as a whole by combining several steel materials. The front side roof frame 37 has a longitudinal truss 51 extending in the longitudinal direction and a short truss 52 extending in the lateral direction as a flat truss. Each of these trusses 51 and 52 is a parallel string truss, and has a pair of upper and lower string members 55 and 56, and an oblique member 57 and a bundle member 58 that connect these string members 55 and 56. Yes. The string members 55, 56, the diagonal member 57, and the bundle member 58 are all formed of channel steel.

  In the front side roof frame 37, a solid truss is formed by combining the long truss 51 and the short truss 52. A pair of longitudinal trusses 51 are provided side by side in the lateral direction of the front roof frame 37, and these longitudinal trusses 51 extend in parallel in a plan view. Between the pair of longitudinal trusses 51, a plurality of short trusses 52 arranged in the longitudinal direction of the front roof frame 37 are arranged. The short trusses 52 connect the pair of longitudinal trusses 51 to each other. Yes. In the longitudinal truss 51, the bundle members 58 are disposed at both ends thereof, and thus, the bundle members 58 are disposed at the four corners of the near-side roof frame 37.

  In the longitudinal truss 51, the lower chord material 56 of the pair of upper and lower chord materials 55, 56 extends in the horizontal direction, while the upper chord material 55 is inclined with respect to the lower chord material 56 so that the front roof It extends parallel to the face material 35. In the short truss 52, a pair of upper and lower string members 55, 56 both extend in the horizontal direction.

  As shown in FIG.4 (b), the back | inner side roof frame 38 is formed in the rectangular panel shape as a whole. The back roof frame 38 includes a horizontal member 61 formed of a steel material and a structural surface material 62 such as a plywood attached to the horizontal member 61.

  The horizontal member 61 has two channel steels. These channel steels allow the other channel steel to enter the channel of one channel steel with the respective channel portions facing each other. In this state, they are fixed to each other with screws or the like. In this case, the horizontal member 61 is a rectangular tubular long material. A plurality of horizontal members 61 are provided side by side in the longitudinal direction of the back roof frame 38 in a direction extending in the short direction of the back roof frame 38. The horizontal member 61 is installed in accordance with the position of the bundle member 58 arranged at the end of the short side portion of the front side roof frame 37.

  The structural face material 62 is a field board formed in a rectangular shape, and a plurality of structural face materials 62 are provided side by side in the longitudinal direction of the back roof frame 38. Each structural surface material 62 has the same width dimension as that of the near-side roof frame 37 in the longitudinal direction of the back-side roof frame 38, and is provided in a state of being spanned between adjacent horizontal members 61. In this case, the adjacent structural surface materials 62 are connected via the horizontal member 61.

  In the back roof frame 38, the horizontal member 61 protrudes laterally from the structural surface material 62, and the protruding portion 61 a is provided only on one end side in the short side direction of the back roof frame 38, The horizontal member 61 does not protrude on the other end side. In this case, the length dimension of the horizontal member 61 is made larger than the width dimension of the structural surface material 62.

  For example, in the back roof frame 38 spanned by the three front roof frames 37, as shown in the figure, six horizontal members 61 are arranged in accordance with the positions of a total of six bundles 58. . In this case, two horizontal members 61 are arranged in a state in which the side surfaces of the adjacent bundles 58 of adjacent front side roof frames 37 are gathered, and these horizontal members 61 are overlapped. Are integrated by a fixture such as a bolt. Further, in this case, the three structural surface members 62 are in a state of being spanned over the adjacent horizontal members 61 and are indirectly connected through the two integrated horizontal members 61. Has been.

  Moreover, the roof units 31 and 32 have the roof heat insulating materials 64 and 65 provided under the roof surface materials 35 and 36 (refer FIG. 5). The roof heat insulating materials 64 and 65 are formed in a plate shape by a foam heat insulating material such as polystyrene foam, and are provided in a state of being stacked on the lower surfaces of the roof surface materials 35 and 36. The roof heat insulating materials 64 and 65 are disposed between the roof surface materials 35 and 36 and the roof frames 37 and 38, and the roof surface materials 35 and 36 are fixed to the roof frames 37 and 38 with screws or the like. It is fixed to both the roof face materials 35 and 36 and the roof frames 37 and 38.

  Next, the structure of the connection part of the near side roof unit 31 and the back side roof unit 32 is demonstrated, referring FIGS. FIG. 5 is a cross-sectional view taken along line AA in FIG. 1B, FIG. 6 is a diagram showing the configuration of the cover members 72 and 73, and FIG. In FIG. 6, (a) shows a longitudinal sectional view of the vicinity of the connecting portion between the front side roof unit 31 and the back side roof unit 32, and (b) shows a sectional view taken along the line BB of (a). , (B), illustration of the outer cover member 72 is omitted. In FIG. 7, (a) shows an exploded perspective view of the spacer member 67 with respect to the back side structural portion 21b, (b) shows a perspective view of the spacer member 67, and in both (a) and (b), The short truss 52 and the diagonal member 57 are not shown for the front roof frame 37.

  As shown in FIG. 5, in the connecting portion between the near side roof unit 31 and the far side roof unit 32, the protruding portion 61 a of the horizontal member 61 of the far side roof unit 32 becomes the bundle material 58 of the near side roof unit 31. It is connected. In this bundle member 58, the connecting portion with the horizontal member 61 is disposed between the connecting portion with the upper chord member 55 and the connecting portion with the lower chord member 56. Further, the protruding portion 61 a of the horizontal member 61 is arranged side by side with the bundle member 58 in the short direction of the front side roof unit 31, and the side surface portion of the horizontal member 61 is overlapped with the side surface portion of the bundle member 58. In such a state, the side surfaces are connected by a fixing tool such as a bolt.

  In the back side roof unit 32, a horizontal member 61 and a structural surface material 62 are provided in parallel to the back side roof surface material 36, and the horizontal member 61 is an upper chord material of the longitudinal truss 51 of the front side roof unit 31. The angle of inclination is the same as 55. Here, in the configuration in which one end of the horizontal member 61 is connected to the bundle member 58, the other end is placed on the back side structure portion 21 b via the spacer member 67, thereby the back side structure. It arrange | positions in the position spaced apart upward from both the part 21b and the partition structure part 21e. The spacer member 67 will be described later.

  Since the horizontal member 61 is connected to the bundle member 58 on the lower side of the upper chord member 55, a step is formed at the boundary between the upper surfaces of the near side roof frame 37 and the deep side roof frame 38. In this case, the roof heat insulating material 64 of the front side roof unit 31 and the roof heat insulating material 65 of the back side roof unit 32 are vertically separated, and an intermediate heat insulating material 69 is provided in this separated portion. The intermediate heat insulating material 69 is a foam heat insulating material, similarly to the roof heat insulating materials 64 and 65, and is continuously provided on the roof heat insulating materials 64 and 65. In this case, the heat insulating layer of the roof 13 is formed by these heat insulating materials 64, 65, and 69.

  As shown to Fig.6 (a), the overlap part 71 where the near side roof surface material 35 and the back side roof surface material 36 overlapped vertically is formed in the roof 13. As shown in FIG. In the overlap portion 71, the back side roof surface material 36 is in the lower side of the front side roof surface material 35, and a step is formed in the roof surface materials 35 and 36. In the near side roof unit 31, the near side roof surface material 35 protrudes to the back side from the near side roof frame 37 and the roof heat insulating material 64, and in the back side roof unit 32, the back roof frame 38 is horizontally mounted. The material 61 protrudes further to the facade side than the back side roof frame 38, the roof heat insulating material 65, and the structural surface material 62. In this case, the projecting dimension of the front side roof surface material 35 is larger than the projecting dimension of the projecting portion 61 a of the horizontal member 61, and as a result, the overlap portion 71 is formed.

  In the overlap portion 71, there is a concern that water such as rainwater may enter the indoor side from the gap between the front side roof surface material 35 and the back side roof surface material 36. For the portion 71, the outer cover member 72 that covers the separated portion between the front roof member 35 and the rear roof member 36 from the outdoor side, and the roof member 35, 36 inside the outer cover member 72. An inner cover member 73 that closes the separated portion is provided. The outer cover member 72 is provided in a state of being stretched over the upper surface of the front side roof surface material 35 and the upper surface of the back side roof surface material 36, and is fixed to each of the roof surface materials 35 and 36 with screws or the like. ing.

  The inner cover member 73 is provided between the front side roof surface material 35 and the back side roof surface material 36, and is spanned between the lower surface of the front side roof surface material 35 and the upper surface of the back side roof surface material 36. In this state, the roof surface members 35 and 36 are fixed with screws or the like.

  As shown in FIG. 6 (b), in the roof surface materials 35 and 36, a peak portion 75 having a groove portion opened downward and a trough portion 76 having a groove portion opened upward are alternately arranged. Are arranged side by side. The front roof material 35 and the back roof material 36 are arranged such that the mountain portions 75 and the valley portions 76 are arranged vertically, and the lower mountain portion 75 of the mountain portions 75 arranged vertically is the upper side. It arrange | positions so that it may not enter in the groove part of the peak part 75. FIG. In this case, the upper valley portion 76 does not enter the groove portion of the lower valley portion 76 in the valley portions 76 arranged in the vertical direction.

  The inner cover member 73 is provided in the groove portion of each mountain portion 75 of the front side roof surface material 35 and in the groove portion of each valley portion 76 of the back side roof surface material 36. Each inner cover member 73 is formed in a trapezoidal shape in accordance with the shape of each groove portion of the peak portion 75 and the valley portion 76, and is attached to the roof surface materials 35 and 36 in a state where the groove portion is divided into the outdoor side and the indoor side. It has been. In this case, if the size and shape of the peak portion 75 and the valley portion 76 are the same, there is no need to use different inner cover members 73 for the peak portion 75 and the valley portion 76, so when attaching the inner cover member 73 Work burden and cost burden can be reduced.

  Next, the spacer member 67 will be described. As shown in FIG. 7A, the spacer member 67 is a long member extending in the width direction of the back side structure portion 21b, and is provided on the ceiling beam 29 of the back side structure portion 21b. A plurality of spacer members 67 are arranged in series in the width direction of the back-side structure portion 21b, and the adjacent spacer members 67 are connected to each other with their end faces overlapped. In addition, the spacer member 67 is provided between the back side roof frame 38 and the back side structure part 21b, and thereby holds the back side roof frame 38 at a position spaced upward from the back side structure part 21b. It corresponds to a member.

  As shown in FIG. 7B, the spacer member 67 has a plurality of vertical members 81 extending in the vertical direction and a pair of upper and lower horizontal members 82 and 83 that connect the vertical members 81. . The longitudinal member 81 and the transverse members 82 and 83 are both formed of channel steel, and the pair of upper and lower transverse members 82 and 83 are provided with their respective groove portions facing each other. In a state of entering into the groove portions of the members 82 and 83, they are fixed to the cross members 82 and 83 by welding or the like. In this case, the longitudinal member 81 is placed on the inner surface of the web of the lower transverse member 83, and the upper transverse member 82 is placed on the upper end surface of each longitudinal member 81. The vertical members 81 are arranged side by side at predetermined intervals in the longitudinal direction of the horizontal members 82 and 83, and these vertical members 81 serve as a bundle that supports the back-side roof unit 32 from below. In this case, the spacer member 67 can also be referred to as a bundle unit.

  Next, the installation procedure of the back side roof unit 32 is demonstrated, referring FIGS. 6-9. FIG. 8 is a perspective view showing the installation procedure of the back side roof unit 32, and FIG. 9 is a longitudinal sectional view showing the installation procedure of the back side roof unit 32. In FIG. 8, the truss 52 and the diagonal member 57 are not shown for the front roof frame 37.

  First, the roof units 31 and 32 are manufactured in a factory and transported to a building site using a transportation means such as a truck. Here, when the roof units 31 and 32 are loaded on the truck bed, it is necessary to prevent the loading state of the roof units 31 and 32 from exceeding the transportation limit of the Road Traffic Law. For this reason, in designing the size and shape of the roof units 31 and 32, it is necessary to consider transportation restrictions in addition to the size of the building 10. In the present embodiment, since the depth dimension of the building body 12 exceeds the transport limit, the roof 13 is constructed using the back roof unit 32 in addition to the front roof unit 31.

  When transporting the front side roof unit 31, the three front side roof units 31 are loaded on one truck. Here, the rear roof unit 32 has a smaller height than the front roof unit 31 because it does not have a truss structure. For this reason, in the truck bed, a plurality of back-side roof units 32 can be loaded in a space for loading one front-side roof unit 31.

  After transporting the roof units 31 and 32 to the construction site, the front side roof unit 31 is installed on the building body 12 and then the back side roof unit 32 is installed. In the present embodiment, of the two back-side roof units 32, the back-side roof unit 32 that is installed on the L-shaped lattice pillar 27 a in a plan view arranged at the protruding corner portion of the building body 12 is the first. Install in. Thereby, it can suppress that the back side structure part 21b bends in the front-back direction of the building main body 12 in the state which mounted the back side roof unit 32 on the back side structure part 21b.

  After each front-side roof unit 31 is installed, as shown in FIGS. 7A and 9A, the spacer member 67 is installed on the ceiling beam 29 of the back-side structure portion 21b. Thereafter, as shown in FIG. 8 (a), the rear roof unit 32 lifted in the installation direction by a heavy machine such as a crane is lowered from the upper position of the building main body 12 to approach the upper surface of the building main body 12. Go. Then, as shown in FIG. 9B, when the protruding portion 61 a of the horizontal member 61 of the back roof unit 32 reaches a position lower than the front roof material 35, the descent by the heavy machinery is stopped.

  Thereafter, the rear roof unit 32 is slid to the front roof unit 31 side to align the front roof unit 31 with respect to the front roof unit 31, and FIG. 8 (b) and FIG. 9 (c). ), The rear roof unit 32 is placed on the spacer member 67, and the protruding portion 61a of the horizontal member 61 is brought into contact with the bundle member 58. And the back side roof unit 32 is fixed to the back side structural unit 21b and the near side roof unit 31, and after the fixing work is finished, the lifted state of the back side roof unit 32 is released, and the hanger is attached to the back side roof. Remove from unit 32.

  Here, as shown in FIG. 8B, in the pair of longitudinal trusses 51 of the front roof unit 31, the chord members 55 and 56 and the bundle member 58 are arranged with the respective groove portions facing the inside of the truss. The string members 55 and 56 are fixed to the outer side surface (web plate surface) of the bundle member 58. In this case, the adjacent front side roof units 31 are connected by bolts or the like in a state where the chord members 55 and 56 of the respective longitudinal trusses 51 are overlapped with each other on the outer side surfaces (the plate surfaces of the web). The bundle material 58 is separated by the amount of the chord materials 55 and 56.

  The protruding portion 61 a of the horizontal member 61 of the back roof unit 32 is disposed between the string members 55 and 56 and is fixed to the outer surface of the bundle member 58 in the same manner as the string members 55 and 56. In this case, the two horizontal members 61 integrated by the connection are individually fixed to the bundle members 58 in a state of being inserted into the separated portions of the bundle members 58 of the adjacent front side roof units 31. ing.

  Thereafter, as shown in FIG. 6A, the outer cover member 72 and the inner cover member 73 are attached to the overlap portion 71 between the front roof unit 31 and the back roof unit 32.

  According to the embodiment described in detail above, the following excellent effects can be obtained.

  In the front side roof unit 31, the front side roof frame 37 has trusses 51 and 52, so that the ceiling back space (attic space) having a certain height dimension is used as the front side roof surface material 35 and the building body 12. Can be secured between.

  In the roof 13, the back roof frame 38 is connected to the front roof frame 37, so that the back roof frame 38 can be divided into a partition structure without providing a bundle or the like on the partition structure portion 21 e of the building body 12. It can be installed at a position spaced upward from the portion 21e. In this case, since a ceiling back space having a certain height dimension can be secured between the back roof surface material 36 and the building body 12, the ceiling back space (the back of the back yard space 19) can be secured. An air conditioner such as an indoor unit, an air conditioning duct, a ventilation device, and the like can be installed. Therefore, in the roof 13 in which the truss roof unit such as the front side roof unit 31 and the panel roof unit such as the back side roof unit 32 are mixed, it is possible to easily secure the back space of any roof unit.

  By the way, for example, in the configuration in which the back side roof frame 38 is directly mounted on the partition structure part 21e and the back side structure part 21b, the space behind the ceiling cannot be secured between the back side roof face material 36 and the building body 12. Even if it can be secured, the height of the space behind the ceiling becomes very small, making it difficult to install an air conditioner, an air conditioning duct, a ventilator, etc. on the back of the ceiling.

  In the configuration in which the back side roof frame 38 is connected to the front side roof frame 37, the back side roof frame 38 is not directly connected to the partition structure portion 21e. It is not necessary to connect to both the side roof frame 37 and the partition structure part 21e. For this reason, the work burden at the time of installing the back | inner side roof frame 38 can be reduced.

  In the building main body 12, since the partitioning structure part 21e is arranged at a position near the back side structure part 21b between the near side structure part 21a and the back side structure part 21b, the back side roof frame 38 is made of a truss structure. The non-truss structure part which does not have can be made. In particular, the backyard space 19 disposed between the rear structure portion 21b and the partition structure portion 21e does not necessarily have to be a large space unlike the sales space 18, so the depth dimension D2 is set to the rear side. The roof frame 38 can be set to a size that can be accommodated even by a non-truss structure portion.

  In the front side roof frame 37, the bundle material 58 that firmly connects the pair of upper and lower string members 55, 56 is the connection target of the back side roof frame 38. Can be properly supported. Moreover, the back roof frame 38 can set the back roof unit 32 to an appropriate height position by an easy operation of setting the height position of the fixed position with respect to the bundle material 58. Thereby, the work burden at the time of setting the height position of the back side roof unit 32 can be reduced.

  In the back roof frame 38, the projecting portion 61 a of the horizontal member 61 is arranged at a position vertically aligned with the string members 55 and 56 of the front roof frame 37, so that the horizontal member 61 is placed on the front roof frame 37. The near-side roof frame 37 and the back-side roof frame 38 can be firmly connected in a state of entering the side. For example, in a configuration in which the horizontal member 61 does not enter the front roof frame 37 side, the front roof frame 37 and the back roof frame 38 are connected to each other with a bolt or the like so that the connection is made. There is concern that it will be difficult to ensure the strength.

  Since the overlap part 71 is formed in the connection part of the near side roof surface material 35 and the back side roof surface material 36, the waterproof property about the boundary part of the near side roof unit 31 and the back side roof unit 32 is formed. Can be increased. And since the connection part of the near side roof frame 37 and the back side roof frame 38 is arrange | positioned in the downward position of the near side roof surface material 35, when installing the back side roof unit 32, it is a near side roof frame. The operation of aligning the rear roof frame 38 with respect to 37 and the operation of forming the overlap portion 71 with the roof surface materials 35 and 36 can be performed together. For this reason, the work burden at the time of installing the back | inner side roof unit 32 can be reduced.

  In the overlap portion 71, the upstream side roof surface material 35 on the upstream side is disposed on the upper side of the back side roof surface material 36 on the downstream side, so that water such as rain water is interposed between the roof surface materials 35 and 36. It is hard to penetrate. In this case, for example, unlike the configuration in which the connecting portion between the front side roofing material 35 and the backside roofing surface material 36 is the upper end (ridge), Is not necessary. Therefore, it can suppress that the structure of the connection part of the near side roof unit 31 and the back side roof unit 32 becomes complicated.

  Since the back roof frame 38 is installed on the back structure 21b via the spacer member 67, the entire back roof frame 38 can be obtained by using both the front roof frame 37 and the spacer member 67. Can be installed at a position spaced upward from the building structure 21. In this case, since the height position of the back side roof unit 32 depends on the height position of the connecting portion with respect to the near side roof frame 37 and the height dimension of the spacer member 67, the versatility of the back side roof unit 32. Can be increased.

  In the spacer member 67, since the support strength for supporting the back side roof unit 32 is ensured by the plurality of vertical members 81, the back side roof unit 32 can be appropriately fixed to the back side structure portion 21b. Moreover, in the spacer member 67, since the plurality of vertical members 81 are connected by the horizontal members 82 and 83, the plurality of vertical members 81 can be installed together with respect to the back side structure portion 21b. Thereby, the work burden at the time of fixing the spacer member 67 and the back side roof unit 32 with respect to the back side structure part 21b can be reduced.

[Other Embodiments]
The present invention is not limited to the description of the above embodiment, and may be implemented as follows, for example.

  (1) In the above embodiment, the horizontal member 61 of the back roof frame 38 is connected to the bundle member 58 between the upper chord member 55 and the lower chord member 56, but the horizontal member 61 is the upper chord member 55. May be connected to the bundle material 58 on the upper side of the lower chord material 56 or on the lower side of the lower chord material 56. For example, if the horizontal member 61 is connected to the bundle member 58 on the upper side of the upper chord member 55, a configuration in which the rear roof surface member 36 is disposed on the upper side of the front roof member 35 can be easily realized.

  (2) In the above embodiment, the horizontal member 61 of the back roof frame 38 is connected to the bundle member 58 of the front roof frame 37, but the back roof frame 38 and the front roof frame 37 are structural. Any portion of the back roof frame 38 may be fixed to any portion of the near roof frame 37 as long as it is connected to the front roof frame 37. For example, the horizontal member 61 is connected to the upper chord member 55 and the lower chord member 56. In this configuration, since the horizontal member 61 extends in parallel with the string members 55 and 56 in a plan view, an area where the horizontal member 61 and the string members 55 and 56 are in contact with each other can be ensured as much as possible. In this case, the fixing strength between the horizontal member 61 and the string members 55 and 56 can be increased.

  (3) In the above embodiment, the front side roof frame 37 as the truss structure portion has a three-dimensional truss, but the front side roof frame 37 may not have a three-dimensional truss. For example, the short truss 52 may not be provided. Even in this case, the structural strength of the near side roof frame 37 can be appropriately ensured by the longitudinal truss 51 being spanned between the near side structure portion 21a and the partition structure portion 21e. Further, only one longitudinal truss 51 may be provided at an intermediate position in the lateral direction of the front side roof frame 37.

  (4) In the above embodiment, the back roof frame 38 as the non-truss structure portion has the structural surface material 62 and the horizontal member 61, but may have only one of them. Further, the back roof frame 38 may have a connecting member that connects the adjacent horizontal members 61. For example, it is set as the structure formed in the rectangular frame shape by a pair of connecting member connecting a pair of horizontal member 61. FIG. In this configuration, since the frame is formed by the pair of connecting members and the pair of horizontal members 61, the structural strength of the back roof frame 38 can be increased. In this case, even if the back roof frame 38 does not have the structural surface material 62, the structural strength of the back roof frame 38 can be appropriately maintained.

  (5) In the said embodiment, although the back | inner side roof unit 32 was provided in the state straddling the boundary part of the adjacent near side roof unit 31, it may be provided in the state which does not straddle. For example, the front roof unit 31 and the back roof unit 32 are arranged in a one-to-one relationship in the front-rear direction of the building 10. In this configuration, since the number of back-side roof units 32 increases, the number of times of performing a series of installation operations for installing one back-side roof unit 32 increases, while the back-side roof unit 32 is downsized. Therefore, the work burden at the time of installing each back side roof unit 32 will be reduced.

  (6) In the above embodiment, the connecting portion between the horizontal member 61 of the back roof frame 38 and the bundle member 58 of the front roof frame 37 is disposed below the front roof member 35. The connecting portion may be disposed below the overlap portion 71 and the back side roof surface material 36.

  (7) In the above embodiment, in the overlap portion 71, the front side roof surface material 35 and the back side roof surface material 36 are in a state in which the lower mountain portion 75 does not enter the groove portion of the upper mountain portion 75. Although it has been arranged, it may be arranged in a state in which the lower peak 75 enters the groove of the upper peak 75. Further, it may be arranged so that the valley portion 76 is positioned below the peak portion 75.

  (8) In the said embodiment, in the overlap part 71, the near side roof surface material 35 which is a roof surface material of a truss roof unit is arrange | positioned above the back side roof surface material 36 which is a roof surface material of a panel roof unit. However, the roof surface material of the panel roof unit may be disposed on the upper side of the roof surface material of the truss roof unit. In this case, in the water gradient of the roof surface, the roof surface material of the panel roof unit is disposed on the upstream side, and the roof surface material of the truss roof unit is disposed on the downstream side.

  (9) In the above embodiment, the water gradient is the same between the front roof member 35 and the back roof member 36, but the water gradient is different between the front roof member 35 and the back roof member 36. May be different. For example, the back-side roof frame 38 is placed on the back-side structure portion 21b without the spacer member 67, so that the inclination angle of the back-side roof unit 32 itself is increased. In this configuration, the water gradient of the back-side roof surface material 36 is larger than the water gradient of the near-side roof surface material 35. Further, with this configuration, it is possible to reduce the cost burden as much as the spacer member 67 is not used.

  (10) In the above embodiment, the front roof unit 31 corresponds to the truss roof unit, and the back roof unit 32 corresponds to the panel roof unit. However, the back roof unit 32 corresponds to the truss roof unit. The front roof unit 31 may correspond to a panel roof unit. For example, in the configuration in which the partition structure portion 21e is disposed at a position closer to the near-side structure portion 21a, the back-side roof unit 32 preferably has a truss structure, and the near-side roof unit 31 has a truss structure. Preferably not.

  Further, the roof units 31 and 32 may be hung over the structure portion in the width direction of the building 10 instead of being hung over the structure portion in the depth direction of the building 10. For example, the partition structure portion 21e extends in parallel with the side structure portions 21c and 21d, the truss roof unit is spanned between the one side structure portion 21c and the partition structure portion 21e, and the non-truss roof unit is the other. It is set as the structure spanned by the side structure part 21d and the truss roof unit.

  (11) In the above embodiment, the front roof unit 31 as the truss roof unit and the back roof unit 32 as the panel roof unit are arranged in directions orthogonal to each other, but the truss roof unit and the panel roof unit And may be arranged parallel to each other. For example, in a configuration in which a plurality of roof units extending in parallel to each other are spanned between the front side structure portion 21a and the back side structure portion 21b, the roof unit at the intermediate position is a truss roof unit, and the roof unit at the end position is a panel A roof unit.

  In this configuration, the partition structure portion 21e is not provided, and the panel roof unit is installed on the side structure portions 21c and 21d. For this reason, the panel roof unit is supported by the near side structure portion 21a and the back side structure portion 21b via the truss roof unit by being connected to the truss roof unit. In this case, the side structure portions 21c and 21d correspond to a panel support portion that supports the panel roof unit.

  (12) In the above embodiment, the roof frames 37, 38 are placed on the ceiling beam 29, but the roof frames 37, 38 are placed on the columns 27, 28 without the ceiling beam 29. May be. Even in this case, the roof frames 37 and 38 are fixed to the columns 27 and 28, so that the columns 27 and 28 are connected via the roof frames 37 and 38, and the structural strength of the building structure 21. Can be secured appropriately.

  DESCRIPTION OF SYMBOLS 10 ... Building, 21a ... Front side structure part as 1st structure part, 21b ... Back side structure part as 2nd structure part and panel support part, 21e ... Partition structure part as connection support part, 31 ... Truss roof unit Front side roof unit as 32, Back side roof unit as panel roof unit, 35 ... Front side roof surface material, 36 ... Back side roof surface material, 37 ... Front side roof frame as truss structure part, 38 ... Non Back side roof frame as truss structure part, 55 ... upper chord material, 56 ... lower chord material, 58 ... bundle material, 61 ... horizontal member, 61a ... projecting part, 67 ... spacer member as holding member, 71 ... overlap part 81 ... Vertical material, 82 ... Upper cross member, 83 ... Lower cross member.

Claims (8)

Comprising a building body, and a plurality of roof unit was set vignetting on the upper side of the building body,
Wherein the plurality of roof unit is a building having a roof structure for supporting the roof member and the roof member,
The plurality of roof units include
A truss roof unit having a truss structure part including the truss structure as the roof structure part;
A panel roof unit having a non-truss structure part configured without including a truss structure as the roof structure part, and formed into a panel shape;
Is included,
The panel roof unit is supported by the truss structure part by connecting the non-truss structure part to the truss structure part ,
In the structure of the building body,
A panel support portion is provided at a position spaced from the connecting portion between the truss structure portion and the non-truss structure portion toward the non-truss structure portion side, and supports the panel roof unit from below;
A holding member that holds the non-truss structure part at a position spaced upward from the panel support part is provided between the non-truss structure part and the panel support part,
The non-truss structure section, building, characterized in that it is connected to the panel supporting part via the holding member. By forming an overlap portion in which the roof surface materials of the truss roof unit and the panel roof unit are vertically arranged, a connecting portion between the truss structure portion and the non-truss structure portion is the truss roof building according to claim 1, characterized in that is covered from above by at least one of the roof members of the unit and the panel roof unit. Each roof surface material of the truss roof unit and the panel roof unit forms a one-flow water gradient in the direction in which the truss roof unit and the panel roof unit are arranged,
Of the truss roof unit and the panel roof unit, the roof surface material on the upstream side of the water gradient is disposed on the upper side of the roof surface material on the downstream side of the water gradient. in, building according to claim 2, wherein the overlap portion is formed. The structure of the building body includes a connection support part that supports a connection part between the truss structure part and the non-truss structure part,
The connection to the support part, building according to any one of claims 1 to 3, characterized in that the truss structure of the truss structure portion and the non-truss structure section is connected. The structure of the building main body includes a pair of opposing structure portions that face each other with the connection support portion interposed therebetween,
The truss roof unit is supported by the first structure portion and the connection support portion by connecting the truss structure portion to the first structure portion and the connection support portion of the pair of opposing structure portions. And
The panel roof unit is supported by the second structure portion and the truss structure portion by connecting the non-truss structure portion to the second structure portion and the truss structure portion of the pair of opposing structure portions. construction product according to claim 4, characterized in that it is. The truss structure part has a pair of upper and lower string members and a bundle member that connects these string members,
The non-truss structure section, building according to any one of claims 1 to 5, characterized in that it is connected to the truss structure by being secured to the bundle member. The non-truss structure portion has a horizontal member provided on the lower side of the roof surface material in a state of protruding sideways from the roof surface material, and the protruding portion of the horizontal material is the bundle material. construction product according to claim 6, characterized in that it is connected to the truss structure by being secured to. The holding member is
A plurality of vertical members provided at a predetermined interval in a direction intersecting the arrangement direction of the truss roof unit and the panel roof unit;
A cross member provided in a state extending in the intersecting direction and connecting the plurality of vertical members;
Building according to any one of claims 1 to 7, characterized in that it has a.

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