JP2009138444A - Roof structure and roof construction method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a new roof structure for insulating heat radiation by using a sheet, and to provide a roof construction method. <P>SOLUTION: The roof structure 100 is set up by laying the sheet 1 on rafters 2, and setting roofing boards 21 (roof materials 11) on the sheet 1. Thus the operator can lay the sheet 1 from above the rafters 2, and therefore working efficiency is improved. Further thanks to the improved working efficiency, standardized laying of the sheet 1 is achieved without variations among individual operators, which leads to positive implementation of designed performance. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a structure of a roof of a building such as a house or a facility, and particularly relates to a technique for suppressing an increase in the temperature of a hut by using a sheet material.

  Conventionally, in the roof structure of a building such as a house or facility, particularly during the summer day, by suppressing the transfer of heat from the outer surface of the roof to the attic, the temperature increase in the attic, and consequently the temperature in the room, is increased. Attempts have been made to suppress and improve cooling efficiency, and there are documents that disclose this (for example, see Patent Documents 1 to 4).

  Regarding how heat is transmitted from the roof to the ceiling, there are three possible modes: conduction, convection, and radiation (radiation). Among these, as a countermeasure against radiation, Patent Document 1 discloses a flexible sheet in the back of the hut. We have proposed a structure that blocks radiant heat (radiant heat) by arranging This structure is known as a heat shield structure.

  In addition, as disclosed in Patent Document 1, in this type of heat shield structure, the sheet is disposed so as to face the inside (the back of the hut) of a roof material such as a field plate, The construction was performed from the indoor side after the field board was attached to the rafter. For example, in the example illustrated in FIG. 10, after the field plate 62 is attached to the rafter 61, the sheet 63 is attached to the rafter 61 with the staples 64 while the sheet 63 is attached to the lower surface of the rafter 61 from below. Construction is performed according to the procedure of stretching.

  However, in such work on the lower surface of the rafter 61, the operator needs to work with his hand facing upwards, which increases the burden on the worker. In particular, since the work is performed at a high place in the back of the hut, workability is poor from the viewpoint of securing a scaffold. In addition, this requires a lot of work time, which is considered to be one of the harmful effects of shortening the construction period and construction cost.

  In addition, since the workability is poor as described above, it is considered that the operator arbitrarily determines the fixing position of the sheet and the arrangement of the staples depending on the situation at the site. If this is the case, the sheet will be strongly stretched between adjacent rafters and the tension will be excessive, increasing the possibility of tearing, etc., and conversely, the tension is weak and the air flow will cause undulations. Can occur. Further, if the staples are improperly arranged, the sheet is drooped, and there is a concern that a large gap is formed between the sheet and the rafter. If such a problem occurs, design performance cannot be exhibited.

  Furthermore, if the operator arbitrarily fixes the sheet, there is a concern that a problem such as waste of the sheet occurs such that the sheet becomes insufficient or is left over. In particular, considering that workability is poor, the possibility of this problem occurring is extremely high.

And what has been described above can be considered as an adverse effect of standardization of sheet construction.
Japanese Patent No. 3552712 JP 2006-249732 A

  Therefore, the present invention is to solve the above-mentioned problems with a novel structure and construction method for a roof structure that uses a sheet to block heat radiation.

  The problems to be solved by the present invention are as described above. Next, means for solving the problems will be described.

That is, as described in claim 1,
A roof structure is provided in which a sheet is laid on a rafter and a roofing material is installed on the sheet.

Moreover, as described in claim 2,
The sheet has a function of blocking radiant heat.

Moreover, as described in claim 3,
A ventilation layer is formed between the sheet and the roof material, and ventilation is performed via the ventilation layer.

Moreover, as described in claim 4,
The sheets are arranged side by side in the longitudinal direction of the rafters, and a gap is secured between the sheets, and ventilation between the gap and the back of the hut is secured. .

Moreover, as described in claim 5,
The sheet is provided with an index for aligning the rafter, and the sheet is laid with the index aligned with the rafter.

Moreover, as described in claim 6,
The sheet is fixed to the rafter using a fixing member, and the sheet is provided with an index for use in alignment of the fixing member with respect to the sheet. It is supposed to be placed at the location of the index.

Moreover, as described in claim 7,
The fixing member has an overlap margin with a side surface of the rafter, and the sheet is disposed downward by the overlap margin by the fixing member, and the ventilation layer is formed between the sheet and the roofing material. It is supposed to be.

Further, as described in claim 8,
The fixing member is constituted by a substantially “U” -shaped sheet metal member, and is fitted to the rafter with the sheet interposed therebetween.

Further, as described in claim 9,
The roof is constructed by laying a sheet on a rafter and installing a roofing material on the sheet.

Moreover, as described in claim 10,
The sheet has a function of blocking radiant heat.

Further, as described in claim 11,
After fixing a certain sheet to the rafter, the roofing material is installed on the certain sheet, the roofing material is used as a scaffold, and the next sheet is attached next to the certain sheet. The roof construction method.

Moreover, as described in claim 12,
The roof construction method is to form a ventilation layer between the sheet and the roof material.

Moreover, as described in claim 13,
The roof construction method secures a gap between the certain sheet and the next sheet.

Further, as described in claim 14,
The sheet is laid by matching an index provided on the sheet with the rafter.

Moreover, as described in claim 15,
The sheet is fixed to the rafter using a fixing member, and the fixing member is arranged according to an index provided on the sheet.

Further, as described in claim 16,
The fixing member has an overlap margin with a side surface of the rafter, and the sheet is disposed downward by the overlap margin by the fixing member, and the ventilation layer is formed between the sheet and the roofing material. It is supposed to be.

Moreover, as described in claim 17,
The fixing member is constituted by a substantially “U” -shaped sheet metal member, and is fitted to the rafter with the sheet interposed therebetween.

  As effects of the present invention, the following effects can be obtained.

  In other words, according to the first aspect of the present invention, the operator can provide a sheet from the upper side of the rafter, and the workability can be improved. In addition, by improving workability, uniform sheet construction that does not vary due to individual differences among workers is realized, and design performance can be reliably realized.

  Moreover, in invention of Claim 2, the thermal-insulation structure which interrupts | blocks the radiant heat transmitted from a roof material to a hut back with a sheet | seat is realizable.

  Moreover, in invention of Claim 3, it becomes possible to implement the ventilation in the back side of a roof material.

  In the invention according to claim 4, it becomes possible to send the air in the back of the hut into the ventilation layer, and to ventilate the back of the hut (back ventilation).

  In the invention described in claim 5, in the alignment of the sheet with respect to the rafters, the work can be standardized and the workability can be improved. In addition, by improving workability, uniform sheet construction that does not vary due to individual differences among workers is realized, and design performance can be reliably realized. In addition, it is possible to reliably prevent the occurrence of a wasteful use of sheets such as a shortage of sheets or a surplus.

  In the invention according to claim 6, in the alignment of the fixing member with respect to the sheet, the work can be standardized and the workability can be improved. In addition, by improving workability, uniform sheet construction that does not vary due to individual differences among workers is realized, and design performance can be reliably realized.

  In the invention according to claim 7, the ventilation layer can have a prescribed cross-sectional shape defined by an overlap margin, and the ventilation layer can be configured with certainty.

  In the invention according to claim 8, the fixing member can be easily fixed to the rafter.

  In the invention according to claim 9, the operator can provide a sheet from the upper side of the rafter, and the workability can be improved. In addition, by improving workability, uniform sheet construction that does not vary due to individual differences among workers is realized, and design performance can be reliably realized.

  Moreover, in invention of Claim 10, the thermal-insulation structure which interrupts | blocks the radiant heat transmitted from a roof material to a hut back with a sheet | seat is realizable.

  In the invention according to claim 11, it is possible to perform the work of laying the sheet from the upper side of the rafters using the roofing material as a scaffold, and the work is less burdensome and can be completed in a short work time. be able to. Further, in relation to seat laying work, it is possible to significantly reduce the work load of assembling / removing the scaffold as compared with the conventional art.

  In the invention according to claim 12, ventilation on the back side of the roofing material can be performed.

  In the invention described in claim 13, the air in the back of the hut can be sent into the ventilation layer, and ventilation of the back of the hut (back of the back of the hut) can be performed.

  In the invention according to the fourteenth aspect, it is possible to standardize the work on the rafters of the sheet, and it is possible to achieve excellent workability. In addition, by improving workability, uniform sheet construction that does not vary due to individual differences among workers is realized, and design performance can be reliably realized. In addition, it is possible to reliably prevent the occurrence of a wasteful use of sheets such as a shortage of sheets or a surplus.

  In the invention described in claim 15, in the alignment of the fixing member with respect to the sheet, standardization of work can be achieved, and workability can be improved. In addition, by improving workability, uniform sheet construction that does not vary due to individual differences among workers is realized, and design performance can be reliably realized.

  In the invention according to claim 16, the ventilation layer can have a prescribed cross-sectional shape defined by an overlap margin, and the ventilation layer can be configured with certainty.

  In the invention according to claim 17, the fixing member can be easily fixed to the rafter.

Next, embodiments of the invention will be described.
FIG. 1 is a schematic diagram of a roof structure 100 to which a heat shield structure 50 according to this embodiment is applied.
In this roof structure, the sheet 1 is arranged on the indoor side of the roofing material 11, and the heat rise from the roofing material 11 is blocked by the sheet 1, thereby increasing the temperature of the roof 12 and the temperature of the ceiling 13. The cooling efficiency (summer season) in the indoor space 14 is improved.

  In addition, the sheet 1 used in the present embodiment is a so-called well-known heat shield sheet, and a sheet having a function specialized for heat shield is suitable for blocking radiation heat. Further, it is more preferable to have a moisture permeability / waterproof function that allows moisture to pass but does not allow water to permeate. However, even if the function of blocking the radiant heat is not particularly required, any sheet having a function of substantially blocking the radiant heat may be used, and the applicable sheet selectivity is wide.

As shown in FIG. 1, a ventilation layer 15 serving as an air passage is formed between the roof material 11 and the sheet 1, and air taken from the eaves 16 is ventilated through the ventilation layer 15. The attic ventilation (eave sky ventilation, building ventilation) that is discharged from the mouth 17 is realized.
Hereinafter, the details of the heat shield structure will be described using examples.

  FIG. 2 shows the heat shield structure 50 as viewed from above the roof, and the air 18 passes through the ventilation layer 15 formed between the field plates 21 and 21A and the sheets 1 and 1A constituting the roofing material 11. It is shown that ventilation takes place.

  As shown in FIG. 3, the sheet 1 is laid in a direction orthogonal to the longitudinal direction of the rafter 2. Further, as shown in FIG. 2, the sheets 1 and 1 </ b> A are arranged in parallel in the longitudinal direction of the rafter 2.

  In addition, as shown in FIG. 2, ventilation is performed by sending air in the cabin 12 into the ventilation layer 15 so as to secure a gap 4 between the sheets 1 and 1A. .

  Further, as shown in FIG. 2, each sheet 1, 1 </ b> A is installed so as to cover the rafter 2 so as to straddle a plurality of rafters 2. And each sheet | seat 1 * 1A is fixed to each rafter 2 using the fixing tools 5 * 5 and the staples 6 * 6 (U-shaped needle-shaped member).

  Further, as shown in FIG. 4, indicators 7 and 7 are provided on the upper surface of the sheet 1 at a predetermined interval L in the longitudinal direction. Then, the sheet 1 is placed on the rafters 2 and 2 so that the indexes 7 and 7 are aligned with the corners 2a of the rafters 2 and 2, respectively. And after covering the sheet | seat 1 on each rafters 2 * 2, the sheet | seat 1 is fixed with respect to each rafters 2 * 2 from the upper surface 1a side of the sheet | seat 1 using the fixing tools 5 * 5 and the staples 6 * 6. .

  Further, as shown in FIG. 5, the field board 21 is disposed on the sheet 1 fixed to the rafters 2 and 2. And between the sheet | seat 1 and the field board 21, it is supposed that the ventilation layer 15 * 15 will be formed, and this ventilation layer 15 * 15 will be arrange | positioned between each rafters 2.2. Yes.

Further, as shown in FIG. 5, in order to secure the ventilation layers 15 and 15, the fixture 5 shown in FIGS. 6A and 7 is used.
As shown in FIGS. 6A and 7, in this embodiment, the fixture 5 is a sheet metal having a substantially “U” -shaped cross section so as to be fitted to the rafter 2 across the sheet 1. It is comprised with the member. The substantially “U” shape is formed by a plane component 5a having substantially the same width as the rafter 2 and side component parts 5b and 5c which are respectively suspended downward from both sides of the plane component 5a. It is going to be done. In addition, although the structure of the fixing tool 5 by such a sheet-metal member is suitable from a viewpoint of manufacturing cost, if it exhibits a function equivalent to that described in the present specification, for the structure, It is not limited.

  Further, as shown in FIGS. 6A and 7, in the fixture 5, the side surface constituent portions 5 b and 5 c have an overlap margin D with the side surfaces 2 b and 2 c of the rafter 2, and the overlap margin D The presence of the sheet 1 allows the sheet 1 to be expanded laterally from the side surfaces 2b and 2c of the rafter 2 at a position lower than the upper surface 2e of the rafter 2 by the overlap margin D. Thereby, the ventilation layer 15 is formed between the extension line 2f of the upper surface 2e of the rafter 2 and the sheet 1, and the dimension in the height direction of the range facing the rafter 2 in the ventilation layer 15 is a constant dimension. Overlap allowance D is assumed.

  Further, as shown in FIGS. 4 and 5, in this embodiment, fixing of the sheet 1 to the rafter 2 by the fixing tool 5 is performed every other rafter 2, that is, the sheet 1 by using the staple 6. The fixing to the rafter 2 and the fixing of the sheet 1 to the rafter 2 by using the fixing tool 5 are alternately performed. As a result, as shown in FIG. 5, the rafter 2 to which the sheet 1 is fixed by the staple 6 is arranged between the rafter 2 to which the sheet 1 is fixed by the fixing tool 5. About the location fixed by the tool 5, the space | interval (overlap allowance D) is ensured between the sheet | seat 1 and the field board 21, and the ventilation layer 15 is comprised reliably. Although it is possible to fix the sheet 1 to all the rafters 2 using the fixing tools 5, if every other fixing tool 5 is used for the rafters 2, the use of the fixing tools 5 Cost reduction can be achieved.

  Further, as shown in FIGS. 6A and 7, in the fixture 5, the side surface constituent parts 5 b and 5 c are provided with a return part 5 m having a wedge shape that engages with the side surfaces 2 b and 2 c of the rafter 2.・ 5n is provided. The return portions 5m and 5n are simply configured by forming an inverted V-shaped notch in the middle in the vertical direction of the side surface constituting portions 5b and 5c and bending the portion in the notch inward. be able to. By providing such return parts 5m and 5n, the fixing parts 5 are prevented from falling off the rafters 2 by the return parts 5m and 5n after the fixing tool 5 is fitted to the rafters 2 with the sheet 1 interposed therebetween. The sheet 1 can be securely fixed to the rafter 2.

  Further, as shown in FIGS. 6A and 7, in order to ensure the engagement between the return portions 5 m and 5 n and the rafter 2, the portions where the return portions 5 m and 5 n are arranged in the side surface constituting portions 5 b and 5 c. It is preferable that the interval W1 between 5u and 5v be substantially equal to or less than the width dimension W2 of the rafter 2. According to this, when the fixing tool 5 is fitted to the rafter 2 with the sheet 1 sandwiched therebetween, the side surface constituting parts 5b and 5c are slightly bent and opened, and after the fitting, the elasticity corresponding to the deformation of the bending. The returning portions 5m and 5n can be pressed (press-fitted) into the side surfaces 2b and 2c of the rafter 2 by the return stress. And the fitting state with respect to the rafter 2 of the fixing tool 5 is reliably maintained by this, and as a result, fixation with respect to the rafter 2 of the sheet | seat 1 can be ensured.

  Further, as shown in FIGS. 6A and 7, due to the configuration of the fixture 5 described above, for example, the fixture 5 is fixed to the rafter 2 covered with the sheet 1. By stepping on the planar component 5a of the fixture 5 from above while aligning the positions, the fixture 5 can be fitted to the rafter 2 with the sheet 1 interposed therebetween. Thus, it becomes possible to implement the fixing tool 5 to the rafter 2 without using a tool.

  Further, as shown in FIGS. 6 (a) and 6 (b), the lower end portions of the side surface constituent portions 5b and 5c are secured so that the interval W3 between the lower end portions 5w and 5x is wider than the width dimension W2 of the rafter 2. By bending the portions 5w and 5x outward, a temporary fitting state is configured so that the rafter 2 is sandwiched between the lower end portions 5w and 5x (the state shown in FIG. 6B). By stepping on from this state, it is possible to completely fit, and the workability can be improved. The fixing of the sheet 1 to the rafter 2 with the staple 6 shown in FIG. 4 can be performed using a known tool.

  Further, as shown in FIG. 4, the sheet 1 having a predetermined length is placed between the rafters 8 </ b> A and 8 </ b> B by performing alignment with the rafters 2 using the indices 7 and 7 of the sheet 1 as a guide. Can be placed. Thereby, as shown in FIG. 5, the cross-sectional shape of each ventilation layer 15 and 15 can be made into a substantially symmetrical shape on both sides of the rafter 2. Furthermore, it can be set as the state to which the substantially same tension | tensile_strength was provided in the site | part of the sheet | seat 1 arrange | positioned between each rafter 8A * 8B. In this way, a uniform cross-sectional shape can be obtained in the ventilation layer 15, and the accuracy of ventilation design can be improved. In addition, excessive tension is not applied to the sheet 1, and it is possible to prevent problems such as tearing, and problems that the tension is too weak and the sheet 1 undulates due to the flow of air.

  Further, as shown in FIG. 4, it is desirable that the indices 7 and 7 of the sheet 1 are provided in advance on the surface of the sheet 1 by printing or the like. According to this, the sheet 1 can be laid without requiring work such as measuring at the construction site. Moreover, it is good also as providing the parameter | index 9,9 also about the location which arrange | positions the fixing tool 5 and the staple 6. FIG. According to this, the positions of the fixing tool 5 and the staple 6 with respect to the sheet 1 in the longitudinal direction of the rafter 2 can be made uniform. The indicators 9 and 9 are provided at a total of three positions, for example, at both ends and the center position, so that the fixing positions of the sheet 1 are provided in an even arrangement in the width direction of the sheet 1 (longitudinal direction of the rafter 2). Is possible. In addition, about the space | interval L of the parameter | index 7 * 7 for position alignment with the rafter 2, it considers and considers the space | interval (for example, 1 scale 5 dimensions) of the rafter 2.

  In addition, as described above, the sheet has the indices 7 and 7 for use in alignment with the rafter 2 and the indices 9 and 9 for use in alignment of the fixing member (fixing tool 5 and staple 6) with respect to the sheet 1. By using 1, it is possible to standardize the construction of the sheet 1 on the rafter 2. As a result, uniform construction of the sheet 1 that does not vary due to individual differences among workers is realized, and design performance can be reliably realized. In addition, this standardization improves workability and shortens the work time. In addition, it is possible to reliably prevent the occurrence of a wasteful use of sheets such as a shortage of sheets or a surplus.

  Further, as shown in FIG. 2, the side end 1 s of the sheet 1 arranged on the side closest to the girder 3 is fixed to the girder 3 in relation to the fixing of the sheet 1 to the rafter 2. This fixing is performed using staples 6 in this embodiment. Further, with respect to the fixing to the girder 3, by forming a cut 1k in the longitudinal direction of the rafter 2 from the side end 1s on the side close to the girder 3 in the sheet 1, the contact between the girder 3 and the side end 1s. It is possible to secure a large area, and it is possible to prevent a large gap from being generated between the sheet 1 and the beam 3. In addition, it is possible to prevent a problem that the side end portion 1s of the sheet 1 is lifted up by the outside air flowing into the ventilation layer 15 from the eaves ceiling 16. In addition, it is good also as providing the parameter | index of the arrangement | positioning of the staple 6, and the formation location of the cut 1k in this side edge part 1s by printing etc. Further, the cut 1k may be provided in advance to reduce the number of man-hours at the construction site.

  Further, as shown in FIG. 8A, as a form of laying the sheet in the vicinity of the purlin 31, a gap 4A is secured between the sheets 1C and 1D laid on the rafters 2 and 2 to be attached together. In particular, the air in the cabin 12 can be released to the cabin ventilation port 17 through the gap 4A. Further, as shown in FIG. 8B, for fixing the sheet 1E to the corner tree 32, in order to secure the ventilation layer 15, the sheet 1E is loosened with the staple 6 against the inclined surface 32a of the corner tree 32. Fixing can be performed. Further, as shown in FIG. 8C, the sheet 1F is fixed to the valley 33 as well on the inclined surface 33a of the valley 33 with the sheet 1F loosened in order to secure the ventilation layer 15. The staple 6 can be fixed.

The heat insulation structure is as described above. Next, the construction procedure of the heat insulation structure will be described.
First, as shown in FIG. 3, the sheet 1 is laid on the part of the beam 3. Thus, the sheet 1 appears on the rafters 2 and 2 at the time of construction. Then, as shown in FIG. 2, the side end 1 s of the sheet 1 is fixed to the beam 3 with staples 6. In addition, the sheet 1 is fixed to the rafter 2 by the fixing tool 5 or the staple 6 at the intermediate portion 1 b in the width direction of the sheet 1 and the side end portion 1 c on the opposite side of the beam 3. In the present embodiment, the fixing of the sheet 1 to the rafter 2 is performed by alternately fixing by the fixing tool 5 and fixing by the staple 6.

  Next, as shown in FIG. 2, the base plate 21 is installed from the top of the sheet 1. By installing the field board 21, a scaffold can be secured (the field board 21 can be used as a scaffold), and the next sheet 1A can be laid next to the sheet 1. Here, a gap 4 is secured in the longitudinal direction of the rafter 2 between the already laid sheet 1 and the next laid sheet 1A. Thereby, it becomes possible to send the air of the shed 12 into the ventilation layer 15, and to ventilate the shed 12 (shed ventilation).

  Then, as shown in FIG. 2, the sheet 1 is fixed to the rafter 2 by the fixture 5 or the staple 6 at a total of three locations in the longitudinal direction of the rafter 2 for the sheet 1 </ b> A. In the present embodiment, the fixing of the sheet 1 to the rafter 2 is performed by alternately fixing by the fixing tool 5 and fixing by the staple 6.

  Further, as shown in FIG. 2, after the seat 1A is fixed, a scaffold for laying the next seat 1B can be secured by installing the field board 21A. By repeating such an operation, it is possible to install the sheet 1 as a whole at a necessary location.

  As described above, as shown in FIG. 2, the heat shield structure 50 is constructed by repeating the laying of the sheet 1 and the installation of the field board 21 in the order from the side of the girder 3 toward the purlin (not shown). It is what. And in this construction, it becomes possible to carry out the work of laying the sheet 1 from the upper side of the rafter 2, and the burden on the operator is small, and the work can be completed in a short working time.

  In addition, as shown in FIG. 2, after the field board 21 is installed, it is possible to lay the sheet 1 </ b> A in the next row by using the field board 21 as a scaffold. In relation to the above, compared to the prior art, the work load of assembling / removing the scaffold can be greatly reduced. In relation to this, for example, in the case of the construction of a heat shield structure in which a sheet is attached to the lower side of a conventional rafter, the construction date of installation of the field plate and the construction date of installation of the sheet are set to different days, It was necessary to secure workers on the construction date for each. However, according to the construction of this embodiment in which the sheet is laid on the upper side of the rafter, it is possible to complete the sheet laying work in a short time. It is possible to complete the installation of the seat and the installation of the field board in one day. That is, the construction date can be shortened by one day. For example, it is possible to incorporate a sheet laying operation as one of the operations of the upper building.

The above is the configuration of this embodiment.
That is, as shown in FIG. 2, a roof structure is provided in which a sheet 1 is laid on a rafter 2 and a field board 21 (roof material 11) is installed on the sheet 1.

  Thereby, the operator can provide the sheet | seat 1 from the upper side of the rafter 2, and can make it excellent in workability | operativity. Further, by improving the workability, uniform construction of the sheet 1 that does not cause variations due to individual differences among workers is realized, and design performance can be reliably realized.

  Further, as shown in FIG. 2, the sheet 1 has a function of blocking radiant heat.

  Thereby, the thermal insulation structure 50 which interrupts | blocks the radiant heat transmitted from a field board (roofing material 11) to the cabin back 12 with the sheet | seat 1 is realizable.

  Further, as shown in FIG. 2, a ventilation layer 15 is formed between the sheet 1 and the field plate 21, and ventilation is performed through the ventilation layer 15.

  Thereby, it becomes possible to implement the ventilation in the back side of the field board 21 (roof material 11).

  In addition, as shown in FIG. 2, the sheets 1 and 1A are juxtaposed in the longitudinal direction of the rafter 2, and a gap 4 is secured between the sheets 1 and 1A, and the gap 4 and the hut are arranged. The ventilation between the back 12 is ensured.

  Thereby, it becomes possible to send the air in the shed 12 into the ventilation layer 15, and to ventilate the shed 12 (shed ventilation).

  Further, as shown in FIGS. 2 and 4, the sheets 1 and 1A are provided with indexes 7 and 7 for alignment with the rafter 2, and the sheets 1 and 1A have the indexes 7 and 7 as rafters. 2 is to be laid and aligned.

  Thereby, in the position alignment with respect to the rafter 2 of the sheet | seat 1, a work can be standardized and it can be excellent in workability | operativity. Further, by improving the workability, uniform construction of the sheet 1 that does not cause variations due to individual differences among workers is realized, and design performance can be reliably realized. Furthermore, it is possible to reliably prevent the occurrence of a wasteful use of the sheet 1 such as the sheet 1 being insufficient or remaining.

  As shown in FIGS. 2 and 4, the sheets 1 and 1A are fixed to the rafters 2 using fixing members (fixing tool 5 and staple 6). Indexes 9 and 9 are provided for use in aligning the fixing member with respect to the sheet 1, and the fixing members are arranged at the positions of the indicators 9 and 9.

  Thereby, in the positioning of the fixing member (fixing tool 5 and staple 6) with respect to the sheet 1, the work can be standardized and the workability can be improved. Further, by improving the workability, uniform construction of the sheet 1 that does not cause variations due to individual differences among workers is realized, and design performance can be reliably realized.

  As shown in FIGS. 2 and 6A, the fixing member (fixing tool 5) has an overlap margin D with the side surfaces 2b and 2c of the rafter 2, and the sheet 1 is fixed to the fixing member (fixing). By the tool 5), it is arranged downward by the overlap margin D, and the ventilation layer 15 is formed between the sheet 1 and the base plate 21 (roof material 11).

  Thereby, the said ventilation layer 15 can have a regular cross-sectional shape defined by the overlap margin D, and it becomes possible to comprise the ventilation layer 15 reliably.

  Further, as shown in FIGS. 6A and 7, the fixing member (fixing tool 5) is configured by a substantially “U” -shaped sheet metal member and is fitted to the rafter 2 with the sheet 1 interposed therebetween. It is supposed to be worn.

  Thereby, a fixing member (fixing tool 5) can be easily fixed to the rafter 2.

Moreover, the above example can be defined as a construction method.
That is, as shown in FIG. 2, the roof construction method is such that the sheet 1 is laid on the rafter 2 and the field board 21 (roof material 11) is installed on the sheet 1.

  Thereby, the operator can provide the sheet | seat 1 from the upper side of the rafter 2, and can make it excellent in workability | operativity. Further, by improving the workability, uniform construction of the sheet 1 that does not cause variations due to individual differences among workers is realized, and design performance can be reliably realized.

  Further, as shown in FIG. 2, the sheet 1 has a function of blocking radiant heat.

  Thereby, the thermal insulation structure 50 which interrupts | blocks the radiant heat transmitted from a field board (roofing material 11) to the cabin back 12 with the sheet | seat 1 is realizable.

  Further, as shown in FIG. 2, after fixing a certain sheet 1 to the rafter 2, a field board 21 (roofing material 11) is installed on the certain sheet 1, and the field board 21 (roofing material 11) is used as a scaffold. It is used as a roof construction method in which the next sheet 1A is attached next to the certain sheet 1.

  Thereby, it becomes possible to carry out the work of laying the sheet 1 from the upper side of the rafter 2 using the field board 21 (roof material 11) as a scaffold, and the work is less burdensome and can be completed in a short work time. Can do. Further, in relation to the laying work of the seat 1, the work load of assembling / removing the scaffold can be greatly reduced as compared with the conventional one.

  Moreover, as shown in FIG. 2, it is set as the roof construction method which forms the ventilation layer 15 between the said sheet | seat 1 and the field board 21 (roof material 11).

  Thereby, it becomes possible to implement the ventilation in the back side of the field board 21 (roof material 11).

  In addition, as shown in FIG. 2, the roof construction method is to secure a gap 4 between the certain sheet 1 and the next sheet 1A.

  Thereby, it becomes possible to send the air in the shed 12 into the ventilation layer 15, and to ventilate the shed 12 (shed ventilation).

  As shown in FIGS. 2 and 4, the sheets 1, 1 </ b> A are laid by aligning the indices 7, 7 provided on the sheets 1, 1 </ b> A with the rafters 2.

  Thereby, standardization of work on the rafter 2 of the sheet 1 can be achieved, and workability can be improved. Further, by improving the workability, uniform construction of the sheet 1 that does not cause variations due to individual differences among workers is realized, and design performance can be reliably realized. Furthermore, it is possible to reliably prevent the occurrence of a wasteful use of the sheet 1 such as the sheet 1 being insufficient or remaining.

  Further, as shown in FIGS. 2 and 4, the sheets 1 and 1A are fixed to the rafter 2 using fixing members (fixing tool 5, staple 6), and the fixing member is the sheet. 1 is arranged in accordance with the indices 9 and 9 provided in 1.

  Thereby, in the positioning of the fixing member (fixing tool 5 and staple 6) with respect to the sheet 1, the work can be standardized and the workability can be improved. Further, by improving the workability, uniform construction of the sheet 1 that does not cause variations due to individual differences among workers is realized, and design performance can be reliably realized.

  As shown in FIGS. 2 and 6A, the fixing member (fixing tool 5) has an overlap margin D with the side surfaces 2b and 2c of the rafter 2, and the sheet 1 is fixed to the fixing member (fixing). By the tool 5), it is arranged downward by the overlap margin D, and the ventilation layer 15 is formed between the sheet 1 and the base plate 21 (roof material 11).

  Thereby, the said ventilation layer 15 can have a regular cross-sectional shape defined by the overlap margin D, and it becomes possible to comprise the ventilation layer 15 reliably.

  Further, as shown in FIGS. 6A and 7, the fixing member (fixing tool 5) is configured by a substantially “U” -shaped sheet metal member and is fitted to the rafter 2 with the sheet 1 interposed therebetween. It is supposed to be worn.

  Thereby, a fixing member (fixing tool 5) can be easily fixed to the rafter 2.

  As shown in FIG. 9, in Example 2, with respect to the formation of the air-permeable layer 15A, a member (for example, foams 25 and 25) having a prescribed thickness is provided between the sheets 1 and 1A and the base plates 21 and 21A. By interposing, the ventilation layer 15A having a prescribed thickness is configured.

  As shown in FIG. 9, in Example 2, the sheets 1 and 1A are fixed to the rafters 2 by using staples 6, and the ventilation layer 15A is formed by a foam 25 having a specified thickness. At 25, a distance is secured between each sheet 1 · 1A and the base plate 21 · 21A. About another structure, it is possible to apply the structure similar to the above-mentioned Example 1. FIG.

  Here, about the foams 25 and 25, the heat insulating material utilized in a ceiling or a wall can be diverted, for example. Moreover, it becomes possible to suppress the increase in the weight of a roof to the minimum by setting it as the foam 25 * 25. Further, since the foams 25 and 25 are lightweight, the work of bonding to the sheets 1 and 1A can be easily performed. As for the arrangement of the foams 25 and 25, it is preferable that an index of the arrangement is provided in advance on the sheets 1 and 1A by printing or the like. In addition, it is not specifically limited to a foam, If it is a member which has regular thickness, it can apply to implementation of a present Example.

  Although the present invention has been described with reference to the most practical and preferred embodiments and examples at the present time, the present invention is not limited to the embodiments and implementations disclosed herein. The present invention is not limited to the examples and can be appropriately changed without departing from the gist or the idea of the invention that can be read from the claims and the entire specification. A building opening device with such a change is also applicable to the present invention. It should be understood as encompassed within the technical scope.

  INDUSTRIAL APPLICABILITY The present invention can be widely applied to a roof structure of a house or facility, and is an effective technique for suppressing the temperature change of the back of the hut due to radiant heat and improving the cooling efficiency.

The figure shown about the example of the roof structure which concerns on embodiment of this invention. The figure shown about the thermal-insulation structure which concerns on Example 1 of this invention. The figure shown about the heat insulation structure in the vicinity of a girder. The figure explaining the position alignment with respect to the rafter of a sheet | seat. The figure explaining the ventilation layer formed between a field plate and a sheet | seat. (A) is a figure shown about attachment of the fixing tool with respect to a rafter. (B) is a figure shown about the example which makes a fixing tool a temporary fitting state with respect to a rafter. The perspective view shown about the structure of a fixing tool. (A) is a figure shown about the structure of the sheet | seat in the vicinity of a purlin. (B) is a figure shown about the fixing method of the sheet | seat with respect to a corner tree. (C) is a figure shown about the fixing method of the sheet | seat with respect to Tani. The figure shown about the heat insulation structure which concerns on Example 2 of this invention. The figure shown about the installation method with respect to the rafter of the conventional sheet | seat.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Sheet 1A Sheet 2 Rafter 3 Girder 4 Gap 5 Fixture 6 Staple 11 Roofing material 12 Hut back 14 Indoor space 15 Ventilation layer 16 Eaves top 18 Air 21 Field plate 21A Field plate

Claims (17)

  A roof structure in which a sheet is laid on a rafter and a roofing material is installed on the sheet. The sheet has a function of blocking radiant heat,
The roof structure according to claim 1. A ventilation layer is formed between the sheet and the roof material, and ventilation is performed through the ventilation layer.
The roof structure according to claim 1 or 2, characterized by the above-mentioned. The sheets are arranged side by side in the longitudinal direction of the rafters, and a gap is secured between the sheets, and ventilation between the gap and the back of the hut is secured.
The roof structure according to any one of claims 1 to 3, wherein The sheet is provided with an index for alignment with the rafter, and the sheet is laid with the index aligned with the rafter.
The roof structure according to any one of claims 1 to 4, characterized by the above. The sheet is fixed to the rafter using a fixing member, and the sheet is provided with an index for use in alignment of the fixing member with respect to the sheet. Placed at the indicator,
The roof structure according to any one of claims 1 to 5, characterized by the above. The fixing member has an overlap margin with a side surface of the rafter, and the sheet is disposed downward by the overlap margin by the fixing member, and the ventilation layer is formed between the sheet and the roofing material. Suppose that
The roof structure according to claim 6. The fixing member is configured by a substantially “U” -shaped sheet metal member, and is fitted to the rafters with the sheet interposed therebetween.
The roof structure according to claim 7.   A roof construction method in which a sheet is laid on a rafter and a roofing material is installed on the sheet. The sheet has a function of blocking radiation heat.
The roof construction method according to claim 9. After fixing a certain sheet to the rafter, the roofing material is installed on the certain sheet, the roofing material is used as a scaffold, and the next sheet is attached next to the certain sheet. ,
The roof construction method according to claim 9 or 10, characterized by the above. Forming a ventilation layer between the sheet and the roofing material;
The roof construction method according to any one of claims 9 to 11, wherein the roof construction method is provided. Ensuring a gap between the certain sheet and the next sheet;
The roof construction method according to claim 11 or 12, characterized in that The sheet is laid by matching an index provided on the sheet with the rafter.
The roof construction method according to any one of claims 9 to 13, wherein the roof construction method is provided. The sheet is fixed to the rafter using a fixing member, and the fixing member is arranged according to an index provided on the sheet.
The roof construction method according to any one of claims 9 to 13, wherein the roof construction method is provided. The fixing member has an overlap margin with a side surface of the rafter, and the sheet is disposed downward by the overlap margin by the fixing member, and the ventilation layer is formed between the sheet and the roofing material. The
The roof construction method according to claim 15. The fixing member is configured by a substantially “U” -shaped sheet metal member, and is fitted to the rafters with the sheet interposed therebetween.
The roof construction method according to claim 16.

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