JP2016102395A - Roof unit and roof structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a roof unit whose workability and carrying-in performance are improved as compared with the conventional one.SOLUTION: Roof units 1A, 1B, 1C, 1P, 1D, 1E for forming a deck roof of a building 100 comprise: a deck plate 2 composed of a plurality of grooves 2a that are obtained by repeatedly forming a crest part 2b and a trough part 2c and extend in one direction; a heat insulation material 5 arranged above the deck plate 2; a weight board 6 arranged above the heat insulation material 5; and a screw 14 for penetrating from the weight board 6 to the deck plate 2 to make the weight board 6, heat insulation material 5, and deck plate 2 fix each other. The rigidity of the weight board 6 is higher than that of the heat insulation material 5. The heat insulation material 5 is held by the deck plate 2 and the weight board 6.SELECTED DRAWING: Figure 8

Description

  The present invention relates to a roof unit and a roof structure.

  Conventionally, a roof unit that constitutes a roof by being installed in a building frame is known. For example, in Patent Document 1, a corrugated deck plate is installed on a panel frame that has a ladder shape in plan view, a heat insulating board is installed thereon, and a waterproof sheet is further stretched thereon. An integrated roof panel is disclosed.

JP 2003-293508 A

  In the roof panel described in Patent Document 1, a panel frame is essential to support the deck plate and the heat insulating board. Further, the panel frame needs to be a steel frame in order to ensure the out-of-plane rigidity of the roof panel, which increases the weight of the roof panel. As a result, the workability and carry-in performance of the roof panel may be reduced.

  An object of the present invention is to provide a roof unit with improved workability and carry-in performance as compared with the conventional art.

  The present invention is a roof unit that forms a flat roof of a building, and is arranged above a deck plate, a deck plate in which a plurality of grooves extending in one direction are formed by repeatedly forming a mountain portion and a valley portion. A heat insulating material, a holding board disposed above the heat insulating material, and a fixing member that penetrates from the pressing board to the deck plate and fixes the pressing board, the heat insulating material, and the deck plate to each other. It has higher rigidity than the heat insulating material, and the heat insulating material is sandwiched between the deck plate and the holding board.

  In this roof unit, the fixing tool penetrates from the holding board to the deck plate in a state where the holding board and the deck plate sandwich the heat insulating material. In this case, the presser board having a predetermined rigidity and the deck plate are integrated, and the out-of-plane rigidity of the entire roof unit can be improved without adding a conventional steel frame. Therefore, the weight of the roof unit is reduced, and the workability and carryability are improved.

  Moreover, it bridges over the several peak part or several trough part in a deck plate, with respect to at least two or more trough parts of at least two or more peak parts or several trough parts among several peak parts. You may further provide the 1st reinforcement plate fixed. By providing such a first reinforcing plate, the out-of-plane rigidity of the roof unit can be further improved.

  In addition, a trough is formed in the outer edge of the deck plate that is parallel to the direction of the groove. In this trough, a joint to the building frame or another roof unit provided adjacent to the trough is formed. A part may be formed. Since the joining portion is formed in the valley portion of the outer edge of the deck plate, the joining member such as a bolt does not interfere with the heat insulating material provided on the mountain portion side and the workability is improved. Further, the joint portion of the deck plate is joined to the building casing or other roof unit, and the housing and the plurality of roof units are integrated, so that the surface rigidity of the roof is increased.

  In addition, a trough is formed in the outer edge of the deck plate that is parallel to the direction of the groove, and a second reinforcement fixed to the peak so as to be taken out upward of the trough. A plate may be further provided. In addition, a support material that supports the heat insulating material and the pressing board from below may be provided in the valley portion. Even when a load due to walking or the like is applied to the outer edge of the roof unit, it is possible to prevent the end of the presser board or the like from sinking.

  Further, the heat insulating material and the pressing board may be provided so as to recede from at least one side of the outer edge of the deck plate, and a part of the peak portion of the deck plate may be exposed. Since the other member can be joined to the peak while the other member is supported by the exposed peak, the workability can be improved.

  An incombustible material may be disposed between the deck plate and the heat insulating material. A non-combustible material may be disposed on the lower surface of the deck plate. Fire resistance can be improved by arranging non-combustible materials. Moreover, it becomes advantageous also for an intensity | strength improvement by using a board | plate material with higher rigidity than a heat insulating material as a nonflammable material.

  Moreover, the gradient material for forming the water gradient of a land roof may be arrange | positioned under or on the heat insulating material, or the water gradient of a land roof may be formed in a heat insulating material. Moreover, in the roof structure formed by arranging a plurality of such roof units, one ridge-shaped water gradient may be formed over the entire land roof. By forming in this way, rainwater can be drained quickly.

  Further, the water gradient may be formed so as to form a dormitory shape for each roof unit. By forming many valleys with a water gradient in one flat roof, drainage and evaporation of rainwater can be performed efficiently.

  ADVANTAGE OF THE INVENTION According to this invention, compared with the past, the roof unit which was improved in workability and carrying in can be provided.

It is a top view of the roof comprised including the roof unit which concerns on 1st Embodiment. It is sectional drawing along the II-II line | wire of FIG. 1, (a) is an exploded view before assembling a roof unit, (b) is a figure which shows the state which assembled | attached the roof unit. It is an exploded view for demonstrating the junction part of roof units. (A) is sectional drawing which shows the support material arrange | positioned at the edge part of a roof unit, (b) is sectional drawing along the bb line of (a). It is an exploded view for demonstrating the junction part with the building of a parapet unit and a roof unit. It is a top view which shows the gradient of a roof unit. It is sectional drawing of the roof unit which concerns on 2nd Embodiment, (a) is an exploded view before assembling a roof unit, (b) is a figure which shows the state which assembled | attached the roof unit. It is sectional drawing of the roof unit which concerns on 3rd Embodiment, (a) is an exploded view before assembling a roof unit, (b) is a figure which shows the state which assembled | attached the roof unit. It is an exploded view for demonstrating the junction part of a roof unit and a joint part unit. It is an exploded view for demonstrating the junction part of the roof units which concern on 4th Embodiment. It is an exploded view for demonstrating the junction part of the roof units which concern on 5th Embodiment. It is an exploded view for demonstrating the modification of the junction part of roof units. It is an exploded view for demonstrating the modification of the junction part of a roof unit and a joint part unit. It is a top view which shows the modification of the combination of the roof unit in a roof structure. It is a top view which shows the modification of the gradient of a roof unit.

  Embodiments according to the present invention will be specifically described below with reference to the drawings. For convenience, the same reference numerals are given to substantially the same elements, and the description thereof may be omitted.

(First embodiment)
First, the first embodiment will be described. FIG. 1 is a plan view (plan view) of a flat roof configured with a roof unit according to the present embodiment. The steel structure building 100 includes a roof structure 101A that forms a flat roof. The roof structure 101 </ b> A is formed by a plurality of roof units 1 </ b> A in which outer edges B are joined together and a parapet unit 30 surrounding the combined roof unit 1 </ b> A. The roof unit 1A is manufactured in advance in a factory or the like, and is transported from the factory or the like to the site by a truck or the like, and is lifted by a crane or the like and attached to the building. Moreover, although the thing of the same magnitude | size is illustrated as 1 A of roof units, the magnitude | size of 1 A of roof units is suitably changed with the shape and magnitude | size of the roof designed so that it may mention later. Further, the parapet unit 30 has a different planar shape depending on where it is arranged, but the basic configuration is common. Moreover, the building 100 in this embodiment has a predetermined plane module. The planar module means a basic dimension that serves as a design standard in architecture, and the building 100 is configured such that a planar dimension (such as the distance between the centers of adjacent columns) is an integral multiple of the planar module. The

  As shown in FIG. 2, the roof unit 1 </ b> A includes a deck plate 2, a gradient material 3, a heat insulating material 5, a pressing board 6, and a waterproof sheet 7. The deck plate 2 is a steel plate member having a planar size corresponding to the planar module of the building 100. In the deck plate 2, a plurality of grooves 2 a extending in one direction (see groove direction D in FIG. 1) are continuously formed at a constant interval. The groove 2a has a depth of about 75 mm, for example, and is narrower toward the bottom. Thereby, the deck plate 2 exhibits a substantially wave shape in which a peak portion 2b having a trapezoidal shape in a side view and a trough portion 2c having a trapezoidal shape in a side view are repeatedly formed. In the deck plate 2, end portions B1 and B2 parallel to the groove direction D (see FIG. 1) end at the trough portion 2c.

  The gradient material 3 is for giving a predetermined gradient to the upper surface of the roof unit 1A. The gradient material 3 is a plate-like member in which a water gradient of about 1/50 to 1/100 is formed, for example. In the present embodiment, the gradient material 3 is formed of polystyrene foam having a heat insulating function. The gradient material 3 is disposed above the deck plate 2.

  The heat insulating material 5 is for providing the heat insulating performance required for the roof unit 1A. The heat insulating material 5 is a plate-like member having a uniform thickness, for example, phenol foam. In this embodiment, the heat insulating material 5 is provided in two layers. The heat insulating material 5 may be one layer or three or more layers depending on the heat insulating performance required for the roof unit 1A. The heat insulating material 5 is disposed above the deck plate 2, and is disposed on the gradient material 3 in this embodiment. In addition, when the gradient material 3 has desired heat insulation and also functions as a heat insulation material, the heat insulation material 5 may be omitted.

  The holding board 6 is a plate-like member disposed above the heat insulating material 5. The holding board 6 has at least higher rigidity than the heat insulating material 5, and includes, for example, a cement board (calcal board, pulp mixed cement board, slag gypsum board, hard wood piece cement board, fiber mixed slate, etc.), wood, It is made of wood board (plywood, particle board, MDF, OSB, hard board, CLT, laminated wood, resin wood, etc.).

  The waterproof sheet 7 is for imparting waterproof properties to the roof unit 1A, and is disposed in the uppermost layer of the roof unit 1A. The waterproof sheet 7 is a sheet material formed of, for example, polyvinyl chloride. Further, as the material of the waterproof sheet 7, various sheets such as an asphalt sheet, a rubber asphalt sheet, a rubber sheet, a butyl rubber sheet, and an acrylic rubber sheet may be used in addition to polyvinyl chloride. In the following description, as a fixing mode of the waterproof sheet 7, mainly bonding by a whole surface bonding method is exemplified, but for example, a mechanical fixing method (for example, an insulating method, a floating method), a mixed method of bonding and mechanical fixing It may be fixed by, for example. Furthermore, in place of the waterproof sheet 7, urethane film waterproofing may be applied to the upper surface of the pressing board 6.

  Further, in the present embodiment, reinforcing plates 11 and 12 are appropriately disposed between the deck plate 2 and the gradient member 3 on the periphery of the deck plate 2. The reinforcing plate (first reinforcing plate) 11 (see FIG. 1) is a belt-like plate orthogonal to the groove direction D of the deck plate 2. For example, the reinforcing plate 11 is disposed at both ends of the deck plate 2 in the groove direction D. Be placed. The reinforcing plate 11 is bridged over at least the plurality of peak portions 2b, and is fixed to at least two or more peak portions 2b among the plurality of peak portions 2b, thereby suppressing the deck plate from being bent. . The reinforcing plate 11 is made of steel, for example, but may be other metals (iron, stainless steel, aluminum, copper, etc.) besides steel.

  1 to 3, the reinforcing plate (second reinforcing plate) 12 is a belt-like plate extending in the groove direction D, and at the outer edge B parallel to the groove direction D of the deck plate 2, It is provided at the end B1 joined to the other roof unit 1A. The reinforcing plate 12 is fixed to at least the peak portion 2b adjacent to the valley portion 2c of the end portion B1, and extends along the peak portion 2b. In particular, as shown in FIG. 3, the end edge 12 a on the end B <b> 1 side of the reinforcing plate 12 is taken out above the valley 2 c of the outer edge.

  In the roof unit 1A, reinforcing plates 11 and 12 are arranged on the upper surface of the deck plate 2, and a gradient material 3, a heat insulating material 5, a pressing board 6 and a waterproof sheet 7 are sequentially laminated thereon. A screw (fixing tool) 14 is driven into the roof unit 1A from the side of the pressing board 6 with the pressing board 6 to the deck plate 2 being in close contact with each other. The screw 14 is driven through a washer 15 having an L-shaped cross section to prevent head slipping. Thereby, the holding board 6, the heat insulating material 5, the gradient material 3, the reinforcing plates 11 and 12, and the deck plate 2 are fixed integrally. At this time, the heat insulating material 5 and the gradient material 3 are sandwiched between the pressing board 6 and the deck plate 2. The waterproof sheet 7 is bonded to the upper surface of the presser board 6 fixed integrally in this way by an adhesive 7a. The adhesive 7a is preferably a rubber-based adhesive in order to bring the waterproof sheet 7 into close contact with the pressing board 6. For example, neoprene-based, chloroplane-based, nitrile rubber-based and natural rubber-based adhesives are used. The washer used for preventing the screw 14 from falling out is not limited to the L-shaped washer as described above, but is a circular flat washer (same as a washer 32 described later) in plan view. Shape).

  As shown in FIG. 3, in the roof unit 1 </ b> A in the present embodiment, the waterproof sheet 7, the presser board 6, the heat insulating material 5, the gradient material 3, and the deck at the end B <b> 1 on the side joined to the other roof unit 1 </ b> A. The edges of the plate 2 are aligned. At the end B1, as shown in FIG. 4, the support material 16 is disposed in the valley 2c of the deck plate 2. The support member 16 includes an upper surface 16a, an inclined surface 16b, and a bottom surface 16c provided corresponding to the shape of the valley portion 2c, and a side surface 16d orthogonal to the upper surface 16a, the inclined surface 16b, and the bottom surface 16c. The support material 16 is made of, for example, steel, and supports the heat insulating material 5 and the pressing board 6 from below. The support members 16 are arranged at a predetermined interval (for example, about 300 mm) along the groove direction of the valley portion 2c.

  As shown in FIGS. 2 and 3, the deck plates 2 are joined together by the joint plate 17 between the adjacent roof units 1 </ b> A. The deck plate 2 of the roof unit 1A has a valley portion 2c at its end edge. In the valley portion 2c, joint portions 18a are formed at a predetermined pitch along the groove direction D (see FIG. 4B). The joint 18a is made of, for example, a nut that is welded to the deck plate 2 in advance. The joint plate 17 is a plate-shaped steel material formed to have a length substantially the same as the length in the groove direction D of the deck plate 2. Bolt penetrating holes 17a and 17b are formed in the joint plate 17 along the length direction at the same pitch as the joints 18a. The holes 17a and 17b correspond to the two deck plates 2 to be connected. The roof plate 1A is joined to each other by fixing the joint plate 17 to the deck plate 2 in the adjacent roof unit 1A with the bolts 17c and 17d.

  Further, on the upper surface side of the adjacent roof unit 1 </ b> A, the gap generated between the waterproof sheets 7 is closed by the waterproof tape 20 made of the same material as the waterproof sheet 7. As shown in FIG. 3, the joint tape 21 is first bonded to the pressing board 6 of the roof unit 1 </ b> A so that the waterproof sheet 7 is not damaged by the screw 14 or the washer 15. And after covering the edge part of the waterproof sheet 7 on the joint tape 21 from both sides, the waterproof sheet 7 and the waterproof tape 20 are welded. In order to bond the joint tape 21 to the presser board 6, as shown in FIG. 3, the region overlapping the joint tape 21 at the end of the waterproof sheet 7 is the presser board 6 at the time of production in a factory or the like. Must not be glued to.

  As shown in FIGS. 2 and 5, in the roof unit 1 </ b> A, the edge of the deck plate 2 at the end portion B <b> 2 that is not joined to the other roof unit 1 </ b> A (end portion that is joined to the parapet unit 30) B <b> 2. Protrudes from the edges of the waterproof sheet 7, the holding board 6, the heat insulating material 5, and the gradient material 3. In other words, the waterproof sheet 7, the pressing board 6, the heat insulating material 5, and the gradient material 3 are retracted from the deck plate 2. In the illustrated example, the edges of the waterproof sheet 7, the pressing board 6, the heat insulating material 5, and the gradient material 3 are aligned at the center of the peak portion 2 b near the outer edge of the deck plate 2. Thereby, the trough 2c of the outer edge in the deck plate 2 and a part of the peak part 2b near the outer edge are exposed.

  An end B2 of the deck plate 2 is a valley 2c. In the valley portion 2c, joint portions 18b are formed at a predetermined pitch along the groove direction. The joint 18b is, for example, a hole for penetrating bolts. The roof unit 1 </ b> A is joined to the building 100 by joining the hole and the hole 105 a provided in the beam 105 of the building 100 in advance by the bolt 19 a and the nut 19 b. In the present embodiment, since the valley portion 2 c is exposed, the bolt 19 a is inserted from the upper surface side of the deck plate 2 and fastened to the nut 19 b, and the roof unit 1 A can be joined to the beam 105 of the building 100. The roof unit 1 </ b> A may be joined to the beam 105 of the building 100 by inserting the bolt 19 a from the lower surface side of the upper flange of the beam 105 and fastening it with the nut 19 b. The beam 105 to which the roof unit 1A is joined supports the outer wall 110 of the building 100 via an outer wall mounting member (not shown). As shown in FIG. 2, the parapet unit 30 is disposed between the end B <b> 2 of the roof unit 1 </ b> A and the outer wall 110.

  The parapet unit 30 includes a plate 31, a gradient material 3, a heat insulating material 5, a pressing board 6, and a waterproof sheet 7. The gradient material 3, the heat insulating material 5, the pressing board 6, and the waterproof sheet 7 have the same configuration as that of the roof unit 1A. The plate 31 is a plate-like member having a substantially Z shape in a side view, and includes a top surface portion 31a, a bottom surface portion 31b, and a side surface portion 31c that is continuous perpendicularly to the top surface portion 31a and the bottom surface portion 31b. The plate 31 is made of, for example, steel, but other than steel, other metals (iron, stainless steel, aluminum, copper, etc.), wood, wood board (plywood, particle board, MDF, OSB, hard board, CLT) , Laminated wood, resin wood, etc.) and cement-based boards (calcal board, pulp-mixed cement board, slag gypsum board, hard wood piece cement board, fiber-mixed slate board, etc.).

  The parapet unit 30 is formed by sequentially laminating the gradient material 3, the heat insulating material 5, the pressing board 6, and the waterproof sheet 7 on the upper surface of the bottom surface portion 31 b of the plate 31. The upper side of the side surface portion 31 c of the plate 31 and the upper surface portion 31 a of the plate 31 protrude above the holding board 6. From the holding board 6 to the plate 31, the screw 14 is driven through the washer 32 from the holding board 6 side in a close contact state. Thereby, the holding board 6, the heat insulating material 5, the gradient material 3, and the plate 31 are fixed integrally. The waterproof sheet 7 is bonded to the upper surface of the presser board 6 fixed integrally in this way by an adhesive 7a. The waterproof sheet 7 is also bonded to the side surface portion 31 c and the upper surface portion 31 a of the plate 31. A cap 35 is provided between the upper surface portion 31 a of the plate 31 and the waterproof sheet 7.

  The parapet unit 30 is supported by a parapet base 115 which is a Z-shaped metal plate provided on the beam 105 on one side edge side (one end side), and the other side edge side (other end side) is a deck plate of the roof unit 1A. 2 is supported. On one end side of the parapet unit 30, the waterproof sheet 7 and the headboard 35 are disposed so as to overlap the upper surface portion 31 a of the plate 31, and further, a hole is formed so as to penetrate the upper surface portion 31 a, the waterproof sheet 7 and the headboard 35. A portion 36 is formed. A bolt 115 a that is fixed in advance to the upper surface of the parapet base 115 is passed through the hole 36, and further fastened with a nut 115 b, so that the parapet unit 30 is joined to the parapet base 115. The side surface portion 31 c of the plate 31 of the parapet unit 30 is in contact with the inner wall surface of the parapet base 115, and the bottom surface portion 31 b is supported by an angle 116 having an L-shaped cross section fixed to the parapet base 115.

  The other end side of the parapet unit 30 is supported by the exposed peak portion 2b of the deck plate 2 of the roof unit 1A. In this state, the screw 14 is driven so as to penetrate and join from the holding board 6 side in the parapet unit 30 to the deck plate 2 in the roof unit 1A. The gap between the parapet unit 30 and the roof unit 1A is closed by the joint tape 21 and the waterproof tape 20 that are attached from the upper surface side.

  The roof structure 101A is formed by joining the roof unit 1A and the parapet unit 30 as described above. The roof structure 101 </ b> A has a predetermined gradient formed by the gradient material 3. In the present embodiment, for example, as shown in FIG. 6, a ridge-like gradient is formed for each roof unit 1A. In this example, a sloped valley E is formed between adjacent roof units 1A. The rainwater swung to each roof unit 1A flows to the valley E due to the gradient of the roof unit 1A, and further flows to the parapet unit 30 by flowing through the valley E. By the drainage by this flow and the evaporation of rainwater remaining as a water pool in the valley E, the rainwater that has fallen on the roof unit 1A is quickly processed.

(Second Embodiment)
Next, a roof structure 101B according to the second embodiment will be described with reference to FIG. The roof structure 101B according to the present embodiment uses a roof unit 1B different from the roof unit 1A, and uses a roof unit 1P having a parapet portion instead of the parapet unit 30. Different from the structure 101A. Hereinafter, points different from the first embodiment will be mainly described, and the same elements and members will be denoted by the same reference numerals, and detailed description thereof will be omitted.

  The basic configuration of the roof unit 1B is the same as that of the roof unit 1A in the first embodiment. That is, the roof unit 1B is formed by arranging the reinforcing plates 11 and 12 on the upper surface of the deck plate 2, and sequentially laminating the gradient material 3, the heat insulating material 5, the pressing board 6 and the waterproof sheet 7 thereon. Screws 14 are driven from the holding board 6 to the deck plate 2 through a circular washer 32 in plan view from the holding board 6 side in a close contact state.

  In this roof unit 1B, at the end B1 on both sides parallel to the groove direction D (see FIG. 1) of the deck plate 2, the waterproof sheet 7, the pressing board 6, the heat insulating material 5, the gradient material 3, and the edge of the deck plate 2 Is complete. Therefore, in the roof unit 1A in the first embodiment, the support member 16 is provided only in the valley portion 2c on one outer edge. However, in the roof unit 1B of the present embodiment, the valley portion 2c is formed in any outer edge. Support material 16 is provided. Further, a joint portion 18a for joining to the adjacent roof unit 1P is provided in the valley portion 2c of the outer edge parallel to the groove direction D in the deck plate 2.

  Moreover, as mentioned above, in this embodiment, the roof unit 1P provided with the parapet part is used. The basic configuration of the roof unit 1P is the same as that of the roof unit 1A except that the roof unit 1P includes a parapet portion. That is, the roof unit 1P is formed by sequentially laminating the gradient material 3, the heat insulating material 5, the pressing board 6, and the waterproof sheet 7 on the upper surface of the deck plate 2. Unlike the roof unit 1A, the roof unit 1P does not include the reinforcing plates 11 and 12, but includes a plate 41 for forming a parapet portion instead.

  The plate 41 has a shape in which the bottom surface 31b of the plate 31 in the parapet unit 30 according to the first embodiment extends to the end of the roof unit 1P. Therefore, the plate 41 has the two functions of the reinforcing plate 11 and the plate 31. Screws 14 are driven in from the holding board 6 to the deck plate 2 through the washer 32 from the holding board 6 side in close contact. Further, joint portions 18 b are formed at a predetermined pitch along the groove direction D in the trough portion 2 c at the end portion of the deck plate 2 that is joined to the beam 105. In addition, the shape which the bottom part of the plate 41 extended not to the edge part of the roof unit 1P but to the mountain part 2b nearest to the parapet in the roof unit 1P may be sufficient.

  At the end of the roof unit 1P on the side joined to the roof unit 1B, the edges of the waterproof sheet 7, the holding board 6, the heat insulating material 5, the gradient material 3 and the deck plate 2 are aligned. On the other hand, at the opposite end, the waterproof sheet 7, the pressing board 6, the heat insulating material 5, and the gradient material 3 protrude from the deck plate 2 to form a parapet portion. The plate 41 is bent in a substantially Z shape when viewed from the side, and a headboard 35 is provided between the upper surface portion 41 a and the waterproof sheet 7 in the same manner as the parapet unit 30.

  The joining of the roof unit 1B and the roof unit 1P is the same as the joining of the roof units 1A in the first embodiment, and a joint plate 17 is used (see FIG. 3). On the upper surface side of the roof units 1 </ b> B and 1 </ b> P, a gap generated between the waterproof sheets 7 is closed by the joint tape 21 and the waterproof tape 20. Further, the joining of the roof unit 1P and the parapet base 115 is the same as the joining of the parapet unit 30 and the parapet base 115 in the first embodiment (see FIG. 5). The joining of the joint 18b of the deck plate 2 and the beam 105 in the roof unit 1P is different from the first embodiment in that the bolt 19a is fastened from the beam 105 side.

(Third embodiment)
Next, a roof structure 101C according to the third embodiment will be described with reference to FIGS. The roof structure 101C is different from the roof structure 101A according to the first embodiment in that a roof unit 1C different from the roof unit 1A is used, that is, only the fit between the adjacent roof units 1C is the first. This is different from the embodiment. Hereinafter, points different from the first embodiment will be mainly described, and the same elements and members will be denoted by the same reference numerals, and detailed description thereof will be omitted.

  The basic configuration of the roof unit 1C is the same as that of the roof unit 1A in the first embodiment. That is, the roof unit 1C is formed by arranging reinforcing plates 11 and 12 on the upper surface of the deck plate 2 and sequentially laminating the gradient material 3, the heat insulating material 5, the pressing board 6 and the waterproof sheet 7 thereon. Screws 14 are driven in from the side of the pressing board 6 in a state of close contact from the pressing board 6 to the deck plate 2.

  In the roof unit 1C, the end B2 on the side that is not joined to the other adjacent roof unit 1C is joined to the parapet unit 30 similar to that of the first embodiment. The joining of the roof unit 1C and the parapet unit 30 and the joining of the parapet unit 30 and the beam 105 are the same as in the first embodiment.

  On the other hand, the edge of the deck plate 2 protrudes from the edges of the waterproof sheet 7, the pressing board 6, the heat insulating material 5, and the gradient material 3 at the end B <b> 2 on the side to be joined with the other roof unit 1 </ b> C. This configuration is the same as the end B2 on the side joined to the parapet unit 30. Since the roof units 1C are joined together by the joint plate 17, a joint 18a for joining the joint plate 17 is formed at the end B2 on the side joined to the other roof unit 1C. Yes. In the joining of the roof units 1 </ b> C in the illustrated example, since the bolt is inserted from the upper side, the joining portion 18 a is provided on the lower surface of the deck plate 2, for example.

  Adjacent roof units 1 </ b> C are joined together by a joint plate 17 between valleys 2 c of the deck plate 2 as in the first embodiment. And the joint part unit 50 is arrange | positioned above the said junction part. As shown in FIG. 9, in the joint unit 50, the pressing board 6, the heat insulating material 5, and the gradient material 3 are bonded by a double-sided tape (not shown). A waterproof sheet 7 is bonded to the upper surface of the presser board 6 with an adhesive 7a. The joint unit 50 is fixed to the deck plate 2 of the adjacent roof unit 1 </ b> C by screws 14 driven into the holding board 6 side while being placed on the exposed peak 2 b in the roof unit 1 </ b> C. On the upper surface side of the roof unit 1 </ b> C and the joint unit 50, the gap generated between the waterproof sheets 7 is closed by the joint tape 21 and the waterproof tape 20.

(Fourth embodiment)
Next, a roof structure 101D according to the fourth embodiment will be described with reference to FIG. The roof structure 101D is different from the roof structure 101A according to the first embodiment in that a roof unit 1D different from the roof unit 1A is used. However, the accommodation of the roof unit 1D is basically the same as that of the first embodiment. Furthermore, since the roof unit 1D includes the same members and elements as the roof unit 1A, the following description will mainly describe differences from the first embodiment, and the same elements and members will be the same. A detailed description is omitted with reference numerals.

  In the roof unit 1 </ b> D, an incombustible material 51 is disposed between the reinforcing plate 12 and the heat insulating material 5, more specifically, between the reinforcing plate 12 and the gradient material 3. The non-combustible material 51 is, for example, a material that does not burn due to the heat of fire in a normal fire. Includes quasi-incombustible materials certified according to The incombustible material 51 may be an ALC board, a gypsum board, a calcium board, a wood cement board, a wood cement board, a hard wood cement board, or the like. By using the non-combustible material 51, fire resistance can be improved. Further, using a plate material having higher rigidity than the heat insulating material 5 and the gradient material 3 as the non-combustible material 51 is advantageous in improving the strength.

(Fifth embodiment)
Next, a roof structure 101E according to the fifth embodiment will be described with reference to FIG. The roof structure 101E is different from the roof structure 101A according to the first embodiment in that a roof unit 1E different from the roof unit 1A is used and a non-combustible material 52 is disposed on the lower surface of the deck plate 2. Yes. However, the accommodation of the roof unit 1E is basically the same as that in the first embodiment. Furthermore, since the roof unit 1E includes the same members and elements as the roof unit 1A, the following description will mainly describe differences from the first embodiment, and the same elements and members will be the same. A detailed description is omitted with reference numerals.

  In the roof unit 1 </ b> E, an incombustible material 51 is disposed between the reinforcing plate 12 and the heat insulating material 5, more specifically, between the reinforcing plate 12 and the gradient material 3. The incombustible material 51 may be an ALC board, a gypsum board, a calcium board, a wood cement board, a wood cement board, a hard wood cement board, or the like. By using the non-combustible material 51, fire resistance can be improved. Further, using a plate material having higher rigidity than the heat insulating material 5 and the gradient material 3 as the non-combustible material 51 is advantageous in improving the strength.

  A non-combustible material 52 is disposed on the lower surface of the deck plate 2 of the roof unit 1E. Similarly to the non-combustible material 51, the non-combustible material 52 includes a non-combustible material and a semi-incombustible material. The non-combustible material 52 may be an ALC board, a gypsum board, a calcium board, a wood cement board, a wood cement board, a hard wood cement board, or the like. The non-combustible material 52 and the non-combustible material 51 may be the same material plate or may be different material plates.

  The incombustible material 52 is basically fixed to the deck plate 2 in advance at a factory or the like, but may be fixed to the deck plate 2 at a construction site. Moreover, arrangement | positioning of the nonflammable material 52 with respect to the roof unit 1E can be set arbitrarily. For example, after the non-combustible material 52 is disposed in a range where the joint plate 17 is avoided from the lower surface of the deck plate 2 in a factory or the like in advance, the roof units 1E are joined to each other using the joint plate 17 at the construction site, An incombustible material 52 may be further arranged in a range covering the plate 17.

  By using the non-combustible material 52, fire resistance from the indoor side (downward) can be improved. In addition, using a plate material having higher rigidity than the heat insulating material 5 and the gradient material 3 as the non-combustible material 52 is advantageous in improving the strength.

  Moreover, in the roof structure 101E according to the fifth embodiment, the case where both the non-combustible material 51 and the non-combustible material 52 are used is illustrated, but it is also possible to omit the non-combustible material 51 and use only the non-combustible material 52. is there.

  As described above, in the roof units 1A, 1B, 1C, 1P, 1D, and 1E shown in the embodiments, the presser board 6 and the deck plate 2 are sandwiched between the presser board 6 and the deck plate 2 so as to sandwich the heat insulating material 5. Through the screw 14. With such a configuration, the presser board 6 having a predetermined rigidity and the deck plate 2 are integrated, and the out-of-plane rigidity of the entire roof unit is improved without adding a conventional steel frame. Can do. Therefore, the roof units 1A, 1B, 1C, 1P, 1D, and 1E are reduced in weight, and workability and carry-in properties are improved.

  Moreover, in roof unit 1A, 1B, 1C, 1D, 1E, it bridges over the several peak part 2b in the deck plate 2, and is fixed with respect to at least 2 or more peak part 2b among the several peak parts 2b. By providing the reinforcing plate 11, the out-of-plane rigidity can be further improved. Similarly, in the roof unit 1P, by providing the plate 41, the out-of-plane rigidity can be further improved.

  Further, in the roof units 1A, 1B, 1C, 1P, 1D, and 1E, since the joint portions 18a and 18b are formed in the valley portion 2c of the outer edge parallel to the groove direction D among the outer edges of the deck plate 2, the joint portions The bolts or nuts 18a and 18b do not interfere with the heat insulating material 5 provided on the mountain portion 2b side, and workability is improved. Further, the joint portions 18a and 18b of the deck plate 2 are joined to the building housing or other roof units 1A, 1B, 1C and 1P, and the housing and the plurality of roof units are integrated, so that the roof surface rigidity is integrated. Is increased. Thereby, since the horizontal brace of the roof construction surface can be omitted, the workability and cost are improved.

  Further, in the roof units 1A, 1B, 1D, and 1E, the roof is provided by the reinforcing plate 12 that is fixed so as to be taken out above the valley portion 2c formed on the outer edge, and the support member 16 that is provided in the valley portion 2c. Even when a load due to walking or the like is applied to the outer edge of the unit, it is possible to suppress the end of the presser board 6 or the like from sinking.

  Further, in the roof units 1A, 1C, 1D, and 1E, the heat insulating material 5, the pressing board 6 and the like are provided so as to recede from the outer edge on at least one side of the outer edge. By exposing a part of the crest 2b on at least one side of the outer edge of the deck plate 2, other members such as the parapet unit 30 and the joint unit 50 that do not include the deck plate 2 are supported by the exposed crest 2b. However, since other members can be joined to the peak portion 2b, the workability can be improved.

  Further, in the roof units 1A, 1B, 1C, 1P, 1D, and 1E, the slope member 3 forms a ridge-shaped water gradient for each roof unit, so that a water gradient valley 2c is formed in one land roof. Many are formed. Thereby, drainage and evaporation of rainwater can be performed efficiently.

  Further, in the roof units 1A, 1B, 1C, and 1P, no incombustible material is disposed between the deck plate 2 and the heat insulating material 5 or between the deck plate 2 and the gradient material 3. Further, no incombustible material is disposed on the lower surface of the deck plate 2. However, the incombustible material 51 may be disposed between the deck plate 2 and the heat insulating material 5, particularly between the deck plate 2 and the gradient material 3. Further, a non-combustible material 52 may be disposed on the lower surface of the deck plate 2. By arranging the non-combustible materials 51 and 52, fire resistance can be improved. In addition, using non-combustible materials 51 and 52 that are higher in rigidity than the heat insulating material 5 and the gradient material 3 is advantageous in improving the strength. In addition, when the parapet unit 30 and the joint unit 50 are used in the roof structure, as a matter of course, for example, the non-combustible material 52 is also disposed on the lower surface of the gradient material 3 of the parapet unit 30 and the joint unit 50. obtain. Thereby, the fire resistance of the whole roof structure improves.

  As mentioned above, although embodiment of this invention was explained in full detail with reference to drawings, a specific structure is not restricted to this embodiment.

  For example, as shown in FIG. 3, the example in which the gap formed between the waterproof sheets 7 is closed only by the waterproof tape 20 and the joint tape 21 on the upper surface side of the adjacent roof units 1 </ b> A is limited to this. Not. For example, when adjacent roof units 1 </ b> A are joined, a gap may be generated between adjacent heat insulating materials 5. In this case, the heat insulating property and air tightness of the roof can be enhanced by adhering the airtight tape 25 so as to close the gap between the heat insulating materials 5. The airtight tape 25 is bonded to the upper surface of the heat insulating material 5. Therefore, when the airtight tape 25 is used, as shown in FIG. 12, it is necessary to form the pressing board 6 of the roof unit 1 </ b> A by retreating from the heat insulating material 5 in advance. Thereby, since the upper surface of the heat insulating material 5 is exposed, the airtight tape 25 can be bonded to the exposed portion of the heat insulating material 5. In this case, after adhering the airtight tape 25 at the construction site, the pressing board 61 is fixed from above the airtight tape 25. The waterproof sheet 7 and the waterproof tape 20 are welded after the joint tape 21 is bonded from above the presser board 61. The holding board 61 is fixed by driving the screw 14. The screw 14 penetrates to the reinforcing plate 12. The presser board 61 is processed in advance so as to have a size that covers the exposed portion of the heat insulating material 5.

  Further, as shown in FIG. 9, an example is shown in which the gap formed between the waterproof sheets 7 is closed only by the waterproof tape 20 and the joint tape 21 on the upper surface side of the roof unit 1 </ b> C and the joint unit 50. It is not limited to. You may adhere | attach the airtight tape 25 so that the clearance gap between the adjacent heat insulating materials 5 may be block | closed. In this case, for example, as shown in FIG. 13, the pressing board 6 of the roof unit 1 </ b> C is formed in advance so as to recede from the heat insulating material 5. Further, the holding board 62 and the heat insulating material 5 of the joint unit 50 are separated. Thereby, since the upper surface of the heat insulating material 5 of the roof unit 1 </ b> C and the joint unit 50 is exposed, the airtight tape 25 can be bonded to the exposed portion of the heat insulating material 5. The presser board 62 protrudes on the end side as much as the presser board 6 of the roof unit 1C is retracted. In this case, after the airtight tape 25 is bonded at the construction site, the pressing board 62 is fixed with the screws 14 from above the airtight tape 25, and the joint tape 21 and the waterproof tape 20 are further bonded.

  Moreover, in the example shown by FIG. 7, although the roof unit 1P is each joined to the both ends B1 in one roof unit 1B, it is not limited to this. For example, a plurality of roof units 1B may be continuously arranged. The roof structure 101B can be expanded in a direction parallel to the groove direction D by arranging the plurality of roof units 1B so that the end portions B1 are joined to each other. Similarly, in the example shown in FIG. 8, a plurality of roof units 1C may be continuously arranged. In this case, the joint unit 50 is disposed between the adjacent roof units 1C. As described above, the roof structure 101C can be expanded in a direction parallel to the groove direction D by repeatedly arranging the roof unit 1C and the joint unit 50.

  In each of the first to fifth embodiments described above, only one of the roof units 1A to 1E is used. However, the present invention is not limited to this, and a plurality of types of the roof units 1A to 1E are used. Can be used in combination. For example, FIG. 14 is a plan view showing a roof structure 101F formed by combining the roof unit 1A and the roof unit 1B. In this example, a roof unit 1A is disposed at each of the left end and the right end of the drawing, and a parapet unit 30 is disposed around the roof unit 1A. A plurality of roof units 1B are arranged between the left and right roof units 1A. In the illustrated example, two types of roof units 1A having different sizes and two types of roof units 1B having different sizes are used, and the roof unit 1Ba is disposed at a position surrounded by four roof units 1B. Has been. This roof unit 1Ba has the same layer structure as the roof unit 1B. The roof unit 1A and the roof unit 1B are opposed to each other at the end portions B1. Further, the end portions B1 of the roof units 1B face each other (including the relationship between the roof unit 1B and the roof unit 1Ba). For this reason, in the roof structure 101F, by adding the roof unit 1B without requiring a joint unit for connection between the roof units, the roof structure is parallel to the groove direction D (the horizontal direction in the drawing). ) Can be extended.

  Moreover, in FIG. 6, although the example where a ridge-like gradient is formed for every roof unit was shown, it is not limited to this. For example, as shown in FIG. 15, a ridge-like gradient is formed throughout the roof structure 101 of a flat roof (a structure similar to the roof structures 101A to 101E or a combination of different roof units such as the roof structure 101F). It may be formed. In this case, the arrangement of the gradient members 3 in the roof unit 1 (including any one of the roof units 1 </ b> A to 1 </ b> E) varies depending on where the roof unit 1 is arranged in the roof structure 101. The rainwater swung to the roof unit 1 flows to the parapet P as it is according to the gradient, as shown by the arrows. By forming in this way, drainage can be performed quickly.

  Moreover, although the example in which the 1st reinforcement plate 11 is fixed over at least 2 or more peak parts 2b was shown, it is not limited to this. For example, the first reinforcing plate 11 may be fixed across at least two valley portions 2c. In this case, the first reinforcing plate 11 is disposed on the lower surface side of the deck plate 2, and screws are driven from the first reinforcing plate 11 side toward the deck plate 2.

  Moreover, although the example in which the gradient material 3 is arrange | positioned between the deck plate 2 and the heat insulating material 5 was shown, it is not limited to this. For example, the gradient material 3 may be disposed between the heat insulating material 5 and the pressing board 6.

  1A to 1C, 1P, 1D, 1E ... roof unit, 2 ... deck plate, 2a ... groove, 2b ... mountain, 2c ... valley, 3 ... gradient material, 5 ... heat insulating material, 6 ... presser board, 11 ... first DESCRIPTION OF SYMBOLS 1 reinforcement plate, 12 ... 2nd reinforcement plate, 14 ... Screw (fixing tool), 18a, 18b ... Joint part, 51 ... Non-combustible material, 52 ... Non-combustible material, 101 (101A-101E) ... Roof structure.

Claims (11)

A roof unit forming a flat roof of a building,
A deck plate in which crests and troughs are repeatedly formed and a plurality of grooves extending in one direction are formed, a heat insulating material arranged above the deck plate, and a presser arranged above the heat insulating material With the board,
A fixing tool that penetrates from the pressing board to the deck plate, and fixes the pressing board, the heat insulating material, and the deck plate to each other;
The pressing board has higher rigidity than the heat insulating material,
The heat insulating material is a roof unit sandwiched between the deck plate and the pressing board.   Bridged over a plurality of peaks or a plurality of valleys in the deck plate, for at least two or more peaks among the plurality of peaks, or at least two valleys of the plurality of valleys The roof unit according to claim 1, further comprising a first reinforcing plate fixed in place.   Of the outer edges of the deck plate, the valley is formed in the outer edge parallel to the direction of the groove, and the other roof unit provided adjacent to the junction with the building frame in the valley. The roof unit according to claim 1 or 2 in which a joined part to is formed.   Of the outer edges of the deck plate, the valley is formed on the outer edge parallel to the direction of the groove, and the second is fixed to the peak so as to be taken out upward of the valley. The roof unit according to claim 1, further comprising a reinforcing plate.   Of the outer edges of the deck plate, the outer edge parallel to the direction of the groove is formed with the valley, and the valley is provided with a support material for supporting the heat insulating material and the pressing board from below. The roof unit as described in any one of Claims 1-4.   The heat insulating material and the pressing board are provided so as to recede from at least one side of the outer edge of the deck plate, and a part of the peak portion of the deck plate is exposed. The roof unit according to item.   The roof unit according to any one of claims 1 to 6, wherein a non-combustible material is disposed between the deck plate and the heat insulating material.   The roof unit according to any one of claims 1 to 7, wherein a noncombustible material is disposed on a lower surface of the deck plate.   The gradient material for forming the water gradient of a flat roof is arrange | positioned under or on the said heat insulating material, or the water gradient of a flat roof is formed in the said heat insulating material. The roof unit according to item.   The roof unit according to claim 9, wherein the water gradient is shaped so as to form a dormitory shape for each roof unit.   A roof structure in which a plurality of roof units according to claim 9 are arranged to form a single waterfall-like water gradient over the entire land roof.

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