JP2019135369A - Method for fixing an outdoor structure, structure for fixing an outdoor structure, and tool - Google Patents

Abstract

To provide a method for fixing an outdoor structure capable of reducing water leakage to building materials constituting a building.SOLUTION: This method for fixing a structure to be installed on the outdoor side of a building comprises a step of forming a lower hole 11 in a roofing material 6 which is an exterior material covering a sheathing board 4 constituting a building material constituting a building, a step of forming a gap 14 around the lower hole 11 between the exterior material and the building material, a step of filling the gap 14 with a sealing material 15, and a step of fastening the wooden screw 8, which is a fixing tool, which is passed through the fitting metal 10 and the lower hole 11.SELECTED DRAWING: Figure 6

Description

  The present invention relates to an outdoor structure fixing method for fixing a structure installed on the outdoor side of a building, an outdoor structure fixing structure, and a tool.

  A structure installed on the outdoor side of a building includes a solar cell module installed on the roof of a house. A solar cell module may be fixed to a field board, which is a building material that constitutes a roof, with wood screws passed through the mounting bracket of the solar cell module. The wood screw penetrates the roofing material, which is an exterior material covering the roof, and the waterproof sheet laid on the surface of the field plate, and is tightened to the field plate.

  Patent Document 1 discloses a method for fixing a solar cell module by tightening a wood screw around which a sealing material is wound to a base plate in order to prevent leakage of water into a building material due to the entry of rainwater from a hole through which the wood screw is passed. It is disclosed. The wood screw that has penetrated the waterproof sheet is tightened into the base plate, so that the sealing material pushed back by the base plate around the wood screw accumulates around the hole formed in the waterproof sheet. Thereby, it seals with the sealing material which the hole formed in the waterproof sheet accumulated.

JP2013-190031A

  In the technique of Patent Document 1, in a roof in which a part of a plurality of roofing materials are overlapped and covered with a roofing material, a sealing material is utilized using a space formed between the roofing material and the waterproof sheet. Can be deposited. Since the space to be formed is a space having a height equivalent to the thickness of the roofing material, when the roofing material is a metal plate having a thickness of about 0.4 mm, the space to be formed becomes small. In this case, the sealing material cannot be deposited between the roofing material and the waterproof sheet, and it becomes difficult to prevent water leakage from the hole through which the wood screw is passed to the building material. When the hole through which the wood screw is passed is formed in the metal roof material, a protrusion called “burr” may be generated around the hole of the metal roof material. The protrusions prevent the entry of the sealing material between the roofing material and the waterproof sheet by the protrusions, thus preventing leakage due to rainwater entering between the roofing material and the waterproof sheet. It becomes difficult.

  This invention is made | formed in view of the above, Comprising: It aims at obtaining the fixing method of the outdoor structure which can reduce the water leak to the building material which comprises a building.

  In order to solve the above-described problems and achieve the object, an outdoor structure fixing method according to the present invention is a method of fixing a structure installed on the outdoor side of a building. The outdoor structure fixing method according to the present invention forms a gap around the pilot hole between the step of forming the pilot hole in the exterior material covering the building material constituting the building and the exterior material and the building material. A process, a process of filling a gap with a sealing material, and a process of tightening a fixing tool passed through a structure and a pilot hole into a building material.

  ADVANTAGE OF THE INVENTION According to this invention, there exists an effect that the water leak to the building material which comprises a building can be reduced.

The figure which shows the fixation structure of the outdoor structure concerning Embodiment 1 of this invention. The figure explaining the 1st process of the fixing method of the outdoor structure concerning Embodiment 1. FIG. The figure explaining the 2nd process of the fixing method of the outdoor structure concerning Embodiment 1. FIG. The figure explaining the 3rd process of the fixing method of the outdoor structure concerning Embodiment 1. FIG. The figure which shows the state by which the rubber sheet and the attachment metal fitting were mounted in the structure shown in FIG. The figure explaining the 4th process of the fixing method of the outdoor structure concerning Embodiment 1. FIG. The figure which shows the state in which the pilot hole was formed by the fixing method of the outdoor structure concerning Embodiment 2. FIG. The figure which shows the state by which the sealing material was filled to the mounting bracket by the fixing method of the outdoor structure concerning Embodiment 2. FIG. FIG. 7 is an enlarged view of the pilot hole shown in FIG. 7 and its surrounding portion and the wood screw including the tip. The 1st figure which shows the state in which the wood screw is tightened by the fixing method of the outdoor structure concerning Embodiment 2. 2nd figure which shows the state in which the wood screw is tightened by the fixing method of the outdoor structure concerning Embodiment 2. FIG. The figure which shows the state by which the wood screw was tightened by the fixing method of the outdoor structure concerning Embodiment 2. The figure which shows the principal part side surface of the wood screw used in the fixing method of the outdoor structure concerning the modification of Embodiment 2. FIG. The figure which shows the state with which the sealing material was filled with the fixing method of the outdoor structure concerning Embodiment 3. FIG. The figure which shows the state by which the wood screw was tightened by the fixing method of the outdoor structure concerning Embodiment 3. The figure which shows the state with which the sealing material was filled with the fixing method of the outdoor structure concerning Embodiment 4. FIG. The figure which shows the state by which the wood screw was tightened by the fixing method of the outdoor structure concerning Embodiment 4. FIG. The figure which shows the state with which the sealing material was filled with the fixing method of the outdoor structure concerning Embodiment 5. FIG. The figure which shows the injector which is an example of the tool used in the fixing method of the outdoor structure concerning Embodiment 5. FIG. The figure which shows the state by which the injection device shown in FIG. 19 is placed on the roofing material The figure which shows the state with which the sealing material was filled with the fixing method of the outdoor structure concerning Embodiment 6. FIG. The figure which shows the state by which the wood screw was tightened by the fixing method of the outdoor structure concerning Embodiment 6. FIG.

  The outdoor structure fixing method, outdoor structure fixing structure, and tool according to embodiments of the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a diagram illustrating an outdoor structure fixing structure 1 according to a first embodiment of the present invention. The fixing structure 1 according to the first embodiment is a structure for fixing a structure installed on the outdoor side of a building. In the first embodiment, the building is a general wooden house, and the structure is the solar cell module 2. The solar cell module 2 is installed on the roof 3 of the house. The roof 3 is inclined with respect to the horizontal plane. The structure includes a mounting bracket 10 for mounting the solar cell module 2 to the roof 3. FIG. 1 shows a cross section including a roof 3, a solar cell module 2 installed on the roof 3, a mounting bracket 10, and a fixing structure 1. In FIG. 1, hatching indicating a cross section is omitted. In FIG. 1, the lower side from the roof 3 is indoor, and the upper side from the roof 3 is outdoor.

  The roof 3 includes a field plate 4 that is a building material constituting the roof 3, a waterproof sheet 5 for preventing rainwater from entering the indoor side, and a plurality of roofs that are exterior materials that cover the field plate 4 together with the waterproof sheet 5. It has the lumber 6. The field board 4 is a structural plywood formed by laminating a plurality of plate-like woods, and is a base material on which the waterproof sheet 5 and the roofing material 6 are placed.

  The waterproof sheet 5 covers the outdoor side surface of the base plate 4. The waterproof sheet 5 is a waterproof sheet. One example of the waterproof sheet 5 is asphalt roofing in which a synthetic fiber nonwoven fabric is impregnated with asphalt. An adhesive layer made of an adhesive material is provided on the surface of the waterproof sheet 5 on the base plate 4 side. The waterproof sheet 5 is bonded to the base plate 4 with an adhesive layer. In FIG. 1, illustration of the adhesive layer is omitted.

  The roofing material 6 provided on the waterproof sheet 5 is a metal plate having a thickness of about 0.4 mm. The metal plate is a stainless steel plate, a stainless steel plate, or a Galvalume steel plate (registered trademark). The metal plate is manufactured by rolling or other techniques. The plurality of roofing materials 6 are placed on the waterproof sheet 5 in a state in which the roofing materials 6 adjacent to each other are partially overlapped. The surface on the outdoor side of the roofing material 6 is an installation surface on which the solar cell module 2 is installed. In addition, metal plates other than a tin plate, a stainless steel plate, and a galvalume steel plate may be used for a metal plate. The thickness of the roofing material 6 may be less than 0.4 mm or greater than 0.4 mm.

  The mounting bracket 10 is a component that is fixed to the installation surface and supports the solar cell module 2 on the installation surface. A rubber sheet 7 is sandwiched between the flange portion 10 a of the mounting bracket 10 and the roofing material 6. The rubber sheet 7 is a sheet made of an elastic body and may have adhesiveness. In Embodiment 1, butyl rubber which is an elastic body and has adhesiveness is used for the rubber sheet 7. When the rubber sheet 7 having adhesiveness is used, the mounting bracket 10 is bonded to the roofing material 6 by the rubber sheet 7. An elastic body other than butyl rubber may be used for the rubber sheet 7.

  The wood screw 8 and a sealing material to be described later constitute the fixing structure 1. The wood screw 8 is a fixing tool used for fastening wood. The wood screw 8 is passed through a hole provided in the flange portion 10 a of the mounting bracket 10 and the roofing material 6, penetrates the rubber sheet 7 and the waterproof sheet 5, and is fastened to the base plate 4. The rubber sheet 7 has a function of preventing rainwater from entering a hole provided in the roofing material 6. The gap 9 may be generated at a place where the roofing materials 6 are overlapped. Rainwater can enter between the roofing material 6 and the waterproof sheet 5 through the gap 9. The fixing structure 1 according to the first embodiment prevents water leakage to the field board 4 due to rainwater entering between the roofing material 6 and the waterproof sheet 5. Details of the water leakage prevention function of the fixed structure 1 will be described later.

  Next, with reference to FIG. 2 to FIG. 6, the fixing method of the outdoor structure according to the first embodiment of the present invention will be described. FIG. 2 is a diagram for explaining a first step of the outdoor structure fixing method according to the first embodiment. The first step is a step of forming the pilot holes 11 in the roofing material 6. The pilot hole 11 is formed using a drill 20 that is a cutting tool. The drill 20 is attached to the power tool body. The power tool main body drives the drill 20 to rotate. In addition, illustration of the electric tool main body is abbreviate | omitted in FIG. In FIG. 2, the cross section of the part in which the prepared hole 11 is formed in the roof 3 and the side surface of the drill 20 are shown. Moreover, the cross section of the jig | tool 21 mentioned later is shown. Among the parts constituting the jig 21, the rotor 22 and the stator 23 are hatched, and the bearing 24 and the push screw 25 are not hatched.

  Normally, the waterproof sheet 5 and the base plate 4 can be perforated by tightening the wood screws 8, but the roofing material 6 which is a metal plate cannot be perforated by tightening the wood screws 8. 20 is used to form a pilot hole 11 in the roofing material 6. Following the perforation of the roofing material 6, holes are also formed in the waterproof sheet 5. In addition, when the tip 20a of the drill 20 reaches the base plate 4, the base plate 4 is formed with a recess 13 serving as a guide when the wood screw 8 is tightened.

  A jig 21 which is a tool for adjusting the cutting depth is attached to the drill 20. By mounting the jig 21, the power tool stops drilling at a desired depth. The jig 21 includes a stator 23 and a cylindrical rotor 22 supported by the stator 23 via a bearing 24. The rotor 22 is fixed to the drill 20 by tightening a push screw 25 provided in the rotor 22 in a state where the drill 20 is passed through the center of the rotor 22. The length between the tip 20a of the drill 20 and the tip 26 of the stator 23 is adjusted to be the same as the depth from the outdoor side surface of the roofing material 6 to the deepest part where the drilling is stopped. The end surface 27 of the stator 23 including the tip 26 and directed toward the roof 3 is a surface perpendicular to the rotation axis AX so as to protrude toward the side to which the tip 20a is directed as the drill 20 moves away from the rotation axis AX. It is inclined with respect to. The tip 26 corresponds to a ridge line between the outer peripheral surface 28 and the end surface 27 of the stator 23. The tip 26 is formed along a circle having a diameter larger than the diameter of the pilot hole 11.

  Drilling of the roofing material 6 is started by attaching the jig 21 to the drill 20, bringing the tip 20 a into contact with the roofing material 6 and rotating the drill 20. By drilling using the drill 20, the pilot hole 11 is formed in the roofing material 6. When the roofing material 6 is pushed by the drill 20 during drilling, the outer edge of the pilot hole 11 is plastically deformed so as to bend in the depth direction in which the drill 20 is advanced. Thereby, the burr | flash 12 which is a processus | protrusion protruded indoors is formed in the outer edge of the prepared hole 11 among the roofing materials 6. FIG. While the drill 20 is pressed down, the burr 12 is in close contact with the waterproof sheet 5.

  When drilling by the drill 20 proceeds to the roof plate 6 and the waterproof sheet 5 to the base plate 4, the tip 26 of the stator 23 is pressed against the roofing member 6, and the drill 20 is further lowered. It is suppressed. At this time, since the frictional force between the stator 23 and the rotor 22 via the bearing 24 is extremely lower than the frictional force between the tip 26 and the roofing material 6, the rotor 22 rotates with the drill 20 while being fixed. The child 23 stays on the roofing material 6 without rotating.

  By pressing the jig 21 against the roof 3 in a state where the stator 23 remains on the roofing material 6 without rotating, the tip 26 of the stator 23 moves around the pilot hole 11 in the roofing material 6. Press. By the pressing by the tip 26, the periphery of the pilot hole 11 in the roofing material 6 is plastically deformed so as to be turned up to the outdoor side. Since the end face 27 is provided on the stator 23, the end face 27 instead of the end face 27 is in contact with the roofing material 6 at the end face perpendicular to the outer peripheral surface 28. The contact area with is small. By reducing the contact area between the stator 23 and the roofing material 6, the pressure applied from the stator 23 to the roofing material 6 can be increased.

  FIG. 3 is a diagram illustrating a second step of the outdoor structure fixing method according to the first embodiment. The second step is a step of forming a gap 14 around the pilot hole 11 between the roofing material 6 and the base plate 4. FIG. 3 shows a state where the drill 20 shown in FIG. 2 is pulled out from the roof 3. FIG. 3 shows a cross section of a portion of the roof 3 where the pilot hole 11 is formed.

  When the depression of the drill 20 is stopped, a gap 14 is formed between the roofing material 6 and the waterproof sheet 5 due to plastic deformation around the pilot hole 11 by the jig 21 described above. Due to the formation of the gap 14, the burr 12 is separated from the waterproof sheet 5 to the outdoor side. Thus, in Embodiment 1, the space | gap 14 is formed by pressing the stator 23 against the roofing material 6. FIG.

  FIG. 4 is a diagram illustrating a third step of the outdoor structure fixing method according to the first embodiment. The third step is a step of filling the gap 14 with the sealing material 15. FIG. 3 shows a cross section of the injection nozzle 30 and a cross section of the roof 3.

  After the tip of the injection nozzle 30 is aligned with the pilot hole 11, the paste-like sealing material 15 is injected from the injection nozzle 30 into the pilot hole 11. A synthetic resin or the like is used for the sealing material 15. The sealing material 15 enters the gap 14 through the pilot hole 11 and fills the gap 14, and also fills the recess 13 of the base plate 4. The sealing material 15 filled in the roof 3 is cured.

  FIG. 5 is a diagram illustrating a state where the rubber sheet 7 and the mounting bracket 10 are placed on the configuration illustrated in FIG. 4. In FIG. 5, each cross section of the rubber sheet 7, the mounting bracket 10, and the roof 3 is shown. The arrow A shown in FIG. 5 represents the 1st direction which is the advancing direction of the wood screw 8 when the wood screw 8 is tightened at the process mentioned later. Arrow B represents a second direction which is the opposite direction to the first direction.

  The rubber sheet 7 is disposed so as to cover a region including the pilot hole 11 and the periphery of the pilot hole 11. The mounting bracket 10 is provided with a hole 16 into which the wood screw 8 is inserted. The mounting bracket 10 is placed on the rubber sheet 7 with the hole 16 aligned with the position of the pilot hole 11 on the second direction side. The mounting bracket 10 is placed with a rubber sheet 7 as an intervening part interposed between the roofing material 6 in which the pilot hole 11 is formed. In addition, when the rubber sheet 7 which has adhesiveness is used, the attachment metal fitting 10 is affixed on the roofing material 6 with the rubber sheet 7.

  FIG. 6 is a diagram for explaining a fourth step of the outdoor structure fixing method according to the first embodiment. The fourth step is a step of tightening the wood screw 8 passed through the hole 16 and the prepared hole 11 provided in the mounting bracket 10 to the base plate 4. In FIG. 6, each cross section of the rubber sheet 7, the mounting bracket 10, and the roof 3 and the side surface of the wood screw 8 are shown.

  The wood screw 8 tightened from the hole 16 of the mounting bracket 10 pierces the rubber sheet 7 by pressing the tip 8 a against the rubber sheet 7 and penetrates the rubber sheet 7. The wood screw 8 passes through the sealing material 15 filled in the hole of the pilot hole 11 and the waterproof sheet 5 by tightening after passing through the rubber sheet 7, and the tip 8 a is inserted into the recess 13 of the base plate 4. To reach. The wood screw 8 is tightened to the base plate 4 after the tip 8 a reaches the recess 13 and penetrates the base plate 4. As the tightening of the wood screw 8 on the base plate 4 proceeds, the thrust of the wood screw 8 increases. The mounting bracket 10, the rubber sheet 7, and the roofing material 6 are pressed against the head 8 b of the wood screw 8, and the mounting bracket 10 that supports the solar cell module 2 is fixed to the base plate 4. In the fourth step, the wood screw 8 does not have to be tightened until it penetrates the base plate 4, and the tightening is finished before the tip 8 a reaches the indoor side surface of the base plate 4. May be.

  FIG. 1 shows a state in which the mounting bracket 10 is fixed by two wood screws 8. By fixing each wood screw 8 to the base plate 4 through the first to fourth steps, the fixing of the mounting bracket 10 to the roof 3 is completed. The number of wood screws 8 for fixing the mounting bracket 10 is not limited to two and is arbitrary.

  Here, the function of preventing water leakage by the fixing structure 1 according to the first embodiment will be described. When rainwater that has passed through the gap 9 shown in FIG. 1 enters the wood screw 8 between the roofing material 6 and the waterproof sheet 5, the sealing material 15 filled in the gap 14 is made of the wood screw 8. Blocks rainwater from entering. Since the entrance of rainwater is blocked by the sealing material 15, the fixing structure 1 can reduce leakage due to rainwater entering the indoor side of the field board 4 through the wood screws 8.

  The fixed structure 1 can be formed on the roof 3 by work from the outdoor side of the roof 3, and does not require work from the indoor side of the roof 3, that is, from the attic. According to the first embodiment, water leakage can be reduced by an easy operation as compared with a case where injection of material or attachment of a reinforcing material is required from the attic.

  According to the first embodiment, the fixing structure 1 includes the wood screw 8 by filling the gap 14 formed between the roofing material 6 and the waterproof sheet 5 around the wood screw 8 with the sealing material 15. It is possible to reduce the ingress of rainwater from the surroundings to the indoor side of the field board 4. Thereby, there exists an effect that the water leakage to the building material which comprises a building can be reduced.

Embodiment 2. FIG.
Next, with reference to FIGS. 7-12, the fixing method of the outdoor structure concerning Embodiment 2 of this invention is demonstrated. In the second embodiment, the roofing material 6 is pushed up to form a space by tightening the wood screw 8 passed through the seal material 15 filled in the mounting bracket 10 and the space 15 is filled with the seal material 15. In the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the configuration different from the first embodiment will be mainly described.

  FIG. 7 is a diagram illustrating a state in which the pilot hole 11 is formed by the outdoor structure fixing method according to the second embodiment. In FIG. 7, while showing the cross section of the part in which the pilot hole 11 is formed among the roofs 3, the drill 20 used for formation of the pilot hole 11 is shown with the broken line. Also in the second embodiment, similarly to the first embodiment, the pilot hole 11 may be formed by adjusting the cutting depth by the jig 21 shown in FIG. In the second embodiment, since the gap 14 is not formed by pressing the jig 21, the jig 21 may not be able to increase the pressure applied to the roofing material 6. The jig 21 used in the second embodiment is a general jig including an end surface perpendicular to the rotation axis AX instead of the end surface 27 inclined with respect to the surface perpendicular to the rotation axis AX. Also good.

  By drilling with the drill 20, burrs 12, which are protrusions protruding indoors, are formed on the outer edge of the prepared hole 11 in the roofing material 6. The burr 12 is in close contact with the waterproof sheet 5. Further, portions of the roofing material 6 other than the burr 12 are slightly lifted from the waterproof sheet 5 to the outdoor side.

  FIG. 8 is a view showing a state in which the mounting member 10 is filled with the sealing material 15 by the outdoor structure fixing method according to the second embodiment. In FIG. 8, each cross section of the rubber sheet 7, the mounting bracket 10, the roof 3, and the injection nozzle 30 is shown.

  The rubber sheet 7 is disposed so as to cover a region including the pilot hole 11 and the periphery of the pilot hole 11. The mounting bracket 10 is placed via a rubber sheet 7 on the roofing material 6 in which the pilot holes 11 are formed. The mounting bracket 10 is placed with the hole 16 aligned with the position of the pilot hole 11 on the second direction side.

  After the rubber sheet 7 and the mounting bracket 10 are arranged, the tip of the injection nozzle 30 is aligned with the hole 16, and the paste-like sealing material 15 is injected from the injection nozzle 30 into the hole 16. The sealing material 15 is filled in a space in the hole 16 with the rubber sheet 7 as a bottom. When the sealing material 15 is filled, the wood screw 8 passed through the sealing material 15 filled in the hole 16 is tightened before the sealing material 15 is cured.

  FIG. 9 is an enlarged view of the pilot hole 11 shown in FIG. 7 and its surrounding portion and the portion of the wood screw 8 including the tip 8a. The wood screw 8 includes a shaft portion 32 and a screw thread 33 formed in a spiral shape on the side surface of the shaft portion 32. The shaft portion 32 has a straight portion 32a and a tapered portion 32b. The straight portion 32a is a cylindrical portion having a constant diameter. The tapered portion 32b is a portion that is tapered from the straight portion 32a side toward the distal end 8a. FIG. 9 shows a side surface of a part of the straight portion 32 a and the tapered portion 32 b of the wood screw 8.

  Of the thread 33 formed on the shaft portion 32, the diameter D2 of the portion 33a that is directed to the front side of the drawing in FIG. 9 and is closest to the tip 8a is smaller than the diameter D1 of the pilot hole 11. . The diameter of the thread 33 gradually increases from the tip 8a toward the straight portion 32a and becomes constant at the straight portion 32a. The nominal diameter D4, which is the outer diameter of the wood screw 8, is the diameter of the portion 33c formed in the straight portion 32a of the screw thread 33. The thread 33 formed in the tapered portion 32b includes a portion 33b having a diameter D3 larger than the diameter D1 of the pilot hole 11 and smaller than the nominal diameter D4. Further, the diameter D5 of the tapered portion 32b at the position where the portion 33b is formed is smaller than the diameter D1 of the prepared hole 11.

  FIG. 10 is a first diagram illustrating a state in which the wood screws 8 are tightened by the outdoor structure fixing method according to the second embodiment. FIG. 10 shows a state in which the tip 8 a of the wood screw 8 enters the field board 4 by tightening the wood screw 8.

  The wood screw 8 tightened from the hole 16 filled with the sealing material 15 breaks through the rubber sheet 7 by pressing the tip 8 a against the rubber sheet 7 and penetrates the rubber sheet 7. The wood screw 8 is passed through the hole 11 and the waterproof sheet 5 by tightening after passing through the rubber sheet 7, and allows the tip 8 a to reach the recess 13 of the base plate 4. The wood screw 8 is tightened to the base plate 4 after the tip 8 a reaches the recess 13.

  The nominal diameter D4 shown in FIG. 9 is the same as or slightly larger than the inner diameter D6 of the hole 16 shown in FIG. “Slightly larger than the inner diameter D6” means that the wood screw 8 is large enough to be tightened into the hole 16 due to deformation of the screw thread 33 or the hole 16 during tightening. Since the nominal diameter D4 is the same as or slightly larger than the inner diameter D6, the thread 33 and the wall of the hole 16 are in contact with each other without a gap. For this reason, the leakage of the sealing material 15 in the second direction when the wood screw 8 is tightened is suppressed. The sealing material 15 in the hole 16 is pushed out from the hole 16 in the first direction as the wood screw 8 is tightened.

  A material harder than the material of the mounting bracket 10 may be used as the material of the wood screw 8. When aluminum is used as the material of the mounting bracket 10, iron, which is a material harder than aluminum, may be used as the material of the wood screw 8. By making the material of the wood screw 8 harder than the material of the mounting bracket 10, the wood screw 8 can be tightened while the inner wall of the hole 16 is being shaved by the thread 33 when the nominal diameter D4 is larger than the inside diameter D6. . Even when the distance between the pilot holes 11 and the distance between the holes 16 in the plurality of pilot holes 11 are shifted, the hole 16 is formed by the screw thread 33 by making the material harder than the material of the mounting bracket 10. The wood screw 8 can be tightened while shaving the inner wall.

  FIG. 11 is a second diagram illustrating a state in which the wood screw 8 is tightened by the outdoor structure fixing method according to the second embodiment. FIG. 11 shows a state in which the wood screw 8 is being tightened to the indoor side of the field board 4 as compared to the state shown in FIG.

  When a portion 33 a having a diameter D 2 smaller than the diameter D 1 shown in FIG. 9 of the screw thread 33 passes through the pilot hole 11, the wood screw 8 is tightened without contacting the wall surface of the pilot hole 11. On the other hand, after the portion 33b having a diameter D3 larger than the diameter D1 passes through the pilot hole 11, the wood screw 8 is tightened while being in contact with the pilot hole 11. By tightening the wood screw 8 in contact with the pilot hole 11, the wood screw 8 pushes the roofing material 6 in the second direction as it advances in the first direction. The roofing material 6 is pushed up in the second direction around the pilot hole 11 by tightening the wood screw 8. Thus, in the second embodiment, the roofing material 6 is pushed up in the second direction by tightening the wood screws 8, and the gap 34 is formed around the pilot hole 11 between the roofing material 6 and the waterproof sheet 5. Form.

  Further, when the portion 33b having the diameter D3 passes through the pilot hole 11, the leakage of the sealing material 15 from the pilot hole 11 in the first direction is suppressed, and the sealing material 15 from the hole 16 is lowered. By being pushed into the hole 11, the sealing material 15 is compressed in the pilot hole 11. After the portion 33b passes through the pilot hole 11, when a portion having a diameter D5 other than the portion 33b of the thread 33 in the tapered portion 32b shown in FIG. The compressed sealing material 15 is pushed out to the gap 34 through between the tapered portion 32 b and the prepared hole 11. As described above, in the second embodiment, the sealing material 15 is filled into the gap 34 by the extrusion of the sealing material 15 accompanying the tightening of the wood screw 8.

  FIG. 12 is a diagram illustrating a state in which the wood screw 8 is tightened by the outdoor structure fixing method according to the second embodiment. The wood screw 8 is tightened to the base plate 4 from the state shown in FIG. The mounting bracket 10, the rubber sheet 7, the roofing material 6 and the waterproof sheet 5 are pressed between the head 8 b of the wood screw 8 and the field board 4, so that the roofing material 6 and the waterproof sheet 5 are The space 34 shown in FIG. 11 is closed with the sealing material 15 filled in between. The wood screw 8 does not have to be tightened until it penetrates the field board 4, and the tightening may be finished before the tip 8 a reaches the indoor side surface of the field board 4.

  The sealing material 15 filled between the roofing material 6 and the waterproof sheet 5 enters between the roofing material 6 and the waterproof sheet 5 and blocks rainwater entering toward the wood screws 8. Since the entrance of rainwater is blocked by the sealing material 15, the fixing structure 1 can reduce the entrance of rainwater from the periphery of the wood screw 8 to the indoor side of the field board 4.

  FIG. 13 is a diagram illustrating a side surface of a main part of the wood screw 35 used in the fixing method of the outdoor structure according to the modification of the second embodiment. A slit 36 is formed in the shaft portion 32 of the wood screw 35. In FIG. 13, a part of the straight portion 32a and the tapered portion 32b of the wood screw 35 are shown with the slit 36 facing the front. The slit 36 is a groove having a shape in which the thread 33 and the shaft portion 32 in the taper portion 32b are notched in a straight line between the portion 33a and the straight portion 32a.

  Similar to the wood screw 8 shown in FIG. 11, when the wood screw 35 is tightened from the hole 16 filled with the seal material 15, the seal material 15 is pushed out to the gap 34 through the slit 36. Also in the modification of the second embodiment, the sealing material 15 can be filled into the gap 34 by pushing out the sealing material 15 with the tightening of the wood screw 35.

  According to the second embodiment, the fixing structure 1 includes the sealing material 15 filled between the roofing material 6 and the waterproof sheet 5 around the wood screws 8 and 35. It is possible to reduce the intrusion of rainwater to the indoor side of the field board 4 from the inside. Thereby, there exists an effect that the water leakage to the building material which comprises a building can be reduced.

Embodiment 3 FIG.
Next, with reference to FIG. 14 and FIG. 15, the fixing method of the outdoor structure concerning Embodiment 3 of this invention is demonstrated. In the third embodiment, the gap is formed by lifting the roofing material 6 from the field board 4. In the third embodiment, the same components as those in the first and second embodiments are denoted by the same reference numerals, and the configuration different from the first and second embodiments will be mainly described.

  FIG. 14 is a diagram illustrating a state in which the sealing material 15 is filled by the outdoor structure fixing method according to the third embodiment. In FIG. 14, each cross section of the rubber sheet 7, the mounting bracket 10, the roof 3, and the injection nozzle 30 is shown. Prior to the filling of the sealing material 15, the roofing material 6 is formed with the pilot holes 11 by the same method as in the second embodiment. A hole 37 is provided in the rubber sheet 7. The rubber sheet 7 is placed on the roofing material 6 with the hole 37 aligned with the position of the pilot hole 11 on the second direction side. The mounting bracket 10 is placed on the rubber sheet 7 with the hole 16 aligned with the position of the hole 37 on the second direction side. The mounting bracket 10 is placed with a rubber sheet 7 as an intervening part interposed between the roofing material 6 in which the pilot hole 11 is formed.

  In the third embodiment, the rubber sheet 7 is a sheet made of an elastic body and has adhesiveness. For the rubber sheet 7, butyl rubber which is an elastic body and has adhesiveness is used. The mounting bracket 10 is bonded to the roofing material 6 by the rubber sheet 7. The pilot hole 11, the hole 37 of the rubber sheet 7, and the hole 16 of the mounting bracket 10 may be formed using a drill after the rubber sheet 7 and the mounting bracket 10 are placed on the roof 3. good.

  The mounting bracket 10 is lifted in the second direction after the rubber sheet 7 and the mounting bracket 10 are placed with the holes 16 and 37 aligned with the positions of the pilot holes 11 on the second direction side. Since the mounting bracket 10 is bonded to the roofing material 6 by the rubber sheet 7, the rubber sheet 7 and the roofing material 6 are lifted in the second direction together with the mounting bracket 10. When the roofing material 6 is lifted in the second direction with respect to the waterproof sheet 5, a gap 38 is formed between the roofing material 6 and the waterproof sheet 5. Thus, in Embodiment 3, the roofing material 6 is lifted from the base plate 4 and the waterproof sheet 5 together with the mounting bracket 10 and the rubber sheet 7 to form the gap 38.

  In a state where the gap 38 is formed by lifting the mounting bracket 10, the paste-like sealing material 15 is injected from the injection nozzle 30 into the hole 16. The seal material 15 enters the hole 37, the pilot hole 11, and the recess 13 from the hole 16 and enters the gap 38 from the pilot hole 11. After the sealing material 15 enters the gap 38, the lifting of the mounting bracket 10 is finished. By completing the lifting of the mounting bracket 10, the gap 38 is closed while the sealing material 15 is filled between the roofing material 6 and the waterproof sheet 5. The sealing material 15 filled in the holes 37 and 16 and the roof 3 is cured.

  FIG. 15 is a diagram illustrating a state in which the wood screw 8 is tightened by the outdoor structure fixing method according to the third embodiment. The wood screw 8 tightened from the hole 16 of the mounting bracket 10 passes through the hole 37 and the pilot hole 11 and is tightened to the base plate 4.

  The sealing material 15 filled between the roofing material 6 and the waterproof sheet 5 enters between the roofing material 6 and the waterproof sheet 5 and blocks rainwater entering toward the wood screws 8. Since the entrance of rainwater is blocked by the sealing material 15, the fixing structure 1 can reduce the entrance of rainwater from the periphery of the wood screw 8 to the indoor side of the field board 4. Thereby, also in Embodiment 3, there exists an effect that the fixed structure 1 can reduce the water leak to the building material which comprises a building.

Embodiment 4 FIG.
Next, with reference to FIG. 16 and FIG. 17, the fixing method of the outdoor structure concerning Embodiment 4 of this invention is demonstrated. In Embodiment 4, the roofing material 6 is lifted from the field board 4 by the suction force of the dust collector to form a gap. In the fourth embodiment, the same components as those in the first to third embodiments are denoted by the same reference numerals, and configurations different from those in the first to third embodiments are mainly described.

  FIG. 16 is a diagram illustrating a state in which the sealing material 15 is filled by the outdoor structure fixing method according to the fourth embodiment. The dust collector 40 is a device that sucks dust from the duct 41. The injection nozzle 30 used in the fourth embodiment is integrated with the duct 41. The injection nozzle 30 and the duct 41 constitute a tool used in the outdoor structure fixing method according to the fourth embodiment. In FIG. 16, each cross section of the roof 3, the injection nozzle 30, and the dust collector 40 is shown. Prior to the filling of the sealing material 15, the roofing material 6 is formed with the pilot holes 11 by the same method as in the second embodiment.

  The duct 41 of the dust collector 40 surrounds the periphery of the injection nozzle 30 and is arranged concentrically with the injection nozzle 30. The dust collector 40 is used for removing chips generated when the roofing material 6 and the field board 4 are drilled in a state where the injection of the sealing material 15 by the injection nozzle 30 is stopped.

  After the tip of the injection nozzle 30 is aligned with the pilot hole 11, suction by the dust collector 40 is started, whereby the portion around the pilot hole 11 in the roofing material 6 is drawn to the duct 41. The roofing material 6 is lifted in the second direction by the portion around the pilot hole 11 being drawn to the duct 41. When the roofing material 6 is lifted in the second direction with respect to the waterproof sheet 5, a gap 42 is formed between the roofing material 6 and the waterproof sheet 5. Thus, in Embodiment 4, the roofing material 6 is lifted from the field board 4 and the waterproof sheet 5 by the suction force of the dust collector 40 to form the gap 42.

  In a state where the gap 42 is formed by the suction force of the dust collector 40, the paste-like sealing material 15 is injected from the injection nozzle 30 into the pilot hole 11. The sealing material 15 enters the recess 13 from the pilot hole 11 and enters the gap 42 from the pilot hole 11. As described above, in the fourth embodiment, the injection nozzle 30 injects the sealing material 15 together with the suction from the duct 41 by the dust collector 40, thereby causing the sealing material 15 to enter the gap 42.

  After the sealing material 15 enters the gap 42, the suction by the dust collector 40 is stopped, whereby the lifting of the roofing material 6 in the second direction is released. By releasing the lifting of the roofing material 6, the gap 42 is closed in a state where the sealing material 15 is filled between the roofing material 6 and the waterproof sheet 5. The sealing material 15 filled in the roof 3 is cured.

  FIG. 17 is a diagram illustrating a state in which the wood screw 8 is tightened by the outdoor structure fixing method according to the fourth embodiment. The rubber sheet 7 and the mounting bracket 10 are arranged in the same manner as in the first embodiment after the injection of the sealing material 15 is finished. The wood screw 8 tightened from the hole 16 of the mounting bracket 10 passes through the rubber sheet 7 and the sealing material 15 and is tightened to the field board 4.

  The sealing material 15 filled between the roofing material 6 and the waterproof sheet 5 enters between the roofing material 6 and the waterproof sheet 5 and blocks rainwater entering toward the wood screws 8. Since the entrance of rainwater is blocked by the sealing material 15, the fixing structure 1 can reduce the entrance of rainwater from the periphery of the wood screw 8 to the indoor side of the field board 4. Thereby, also in Embodiment 4, fixed structure 1 has an effect that water leakage to building materials which constitute a building can be reduced.

  In the fourth embodiment, the injection nozzle 30 is integrated with the duct 41, so that when the removal of chips by the perforation of the roofing material 6 and the field board 4 and the injection of the sealing material 15 are performed alternately, the injection nozzle 30 30 and the duct 41 may not be changed. For this reason, compared with the case where the injection nozzle 30 and the duct 41 need to be replaced, workability can be improved.

  In the first to fourth embodiments, the roofing material 6 is not limited to a metal plate, and may be a plate material made of a material other than a metal material. The roofing material 6 may be a plate material having such a hardness that it cannot be perforated by tightening the wood screws 8, and may be a resin plate or the like.

Embodiment 5. FIG.
Next, with reference to FIGS. 18-20, the fixing method of the outdoor structure concerning Embodiment 5 of this invention is demonstrated. In Embodiment 5, the roofing material 6 is lifted from the field board 4 by the magnetic force of a permanent magnet to form a gap. In the fifth embodiment, the same components as those in the first to fourth embodiments are denoted by the same reference numerals, and different configurations from the first to fourth embodiments will be mainly described.

  FIG. 18 is a diagram illustrating a state in which the sealing material 15 is filled by the outdoor structure fixing method according to the fifth embodiment. A permanent magnet 51 is attached to the injection nozzle 30 used in the fifth embodiment. The permanent magnet 51 is disposed so as to surround an end of the injection nozzle 30 on the side from which the sealing material 15 flows out. In the fifth embodiment, the roofing material 6 is mainly composed of iron which is a magnetic material. The roofing material 6 may be mainly composed of a magnetic material other than iron.

  By aligning the tip of the injection nozzle 30 with the pilot hole 11, the roofing material 6 is attracted to the permanent magnet 51 and lifted in the second direction. When the roofing material 6 is lifted in the second direction with respect to the waterproof sheet 5, a gap 52 is formed between the roofing material 6 and the waterproof sheet 5. Thus, in Embodiment 5, the roofing material 6 is lifted from the field board 4 and the waterproof sheet 5 by the magnetic force to form the gap 52.

  In a state where the gap 52 is formed by the magnetic force of the permanent magnet 51, the paste-like sealing material 15 is injected from the injection nozzle 30 into the prepared hole 11. The sealing material 15 enters the recess 13 from the pilot hole 11 and enters the gap 52 from the pilot hole 11. As described above, in the fifth embodiment, the roofing material 6 is attracted to the permanent magnet 51 by the magnetic force of the permanent magnet 51 and the injection nozzle 30 injects the sealing material 15 to cause the sealing material 15 to enter the gap 52.

  After the sealing material 15 enters the gap 52, the lifting of the roofing material 6 in the second direction is released by pulling the permanent magnet 51 together with the injection nozzle 30 from the roofing material 6. By releasing the lifting of the roofing material 6, the gap 52 is closed in a state where the sealing material 15 is filled between the roofing material 6 and the waterproof sheet 5. The sealing material 15 is hardened in a state in which the roof 3 is filled.

  As in the case of the fourth embodiment shown in FIG. 17, after the injection of the sealing material 15 is finished, the rubber sheet 7 and the mounting bracket 10 are arranged. The wood screw 8 tightened from the hole 16 of the mounting bracket 10 passes through the rubber sheet 7 and is tightened to the base plate 4. Also in the fifth embodiment, the fixed structure 1 has an effect that water leakage to the building materials constituting the building can be reduced.

  Next, an injector that is a tool including the injection nozzle 30 will be described. FIG. 19 is a diagram illustrating an injector 50 which is an example of a tool used in the method for fixing an outdoor structure according to the fifth embodiment. The injector 50 is a tool used in the outdoor structure fixing method according to the fifth embodiment. The injector 50 includes the injection nozzle 30 and the permanent magnet 51 shown in FIG. 18, a cylindrical sealing material container 56 in which the sealing material 15 is stored, and a rolling prevention portion 53 for preventing the injector 50 from rolling. Prepare. In addition, the center position of each part which comprises the injector 50 is located on the centerline N shown in FIG.

  The rolling prevention unit 53 is fixed to the injection nozzle 30 in contact with the permanent magnet 51. The rolling prevention part 53 is a component formed with iron as a main component. The component of the rolling prevention part 53 may contain a magnetic material other than iron. The rolling prevention portion 53 includes a plate portion 54 that forms a rectangular outer edge, and a side portion 55 that stands vertically from the outer edge of the plate portion 54. Note that the outer edge of the plate portion 54 may be a polygon other than a rectangle.

  FIG. 20 is a view showing a state where the injector 50 shown in FIG. 19 is placed on the roofing material 6. In FIG. 20, the injector 50 is in a state where the end of the sealing material container 56 opposite to the end where the injection nozzle 30 is provided is directed forward. A length p between the side portion 55 and the center line N on each side of the rectangular shape of the plate portion 54 is longer than a length r between the outer surface of the sealing material container 56 and the center line N. In the sealing material container 56 having a cylindrical shape, the length r is a radius of the cylindrical shape.

  If the tool is configured only by the sealing material container 56 and the injection nozzle 30, the outer surface of the sealing material container 56 comes into contact with the surface of the roofing material 6 so that the tool can be easily placed on the roofing material 6. It will roll. On the roof 3 inclined with respect to the horizontal plane, the tool starts to roll easily due to the action of gravity, and continues to roll unless it is stationary. In the fifth embodiment, the rolling prevention portion 53 that satisfies p> r is provided for the side portion 55 on each side of the rectangle, so that the injector 50 is placed on the roofing material 6. The surface of the side portion 55 is in contact with the surface of the roofing material 6 and remains on the roofing material 6.

  Moreover, since the rolling prevention part 53 is magnetized by contact with the permanent magnet 51, it is attracted to the roofing material 6 whose main component is a magnetic material. The surface of the side portion 55 is in contact with the surface of the roofing material 6, and the rolling prevention portion 53 is attracted to the roofing material 6 by magnetic force, so that the injector 50 rolls on the roofing material 6. Can be reduced. The injector 50 can reduce rolling on the surface of the roofing material 6 that is inclined with respect to the horizontal plane by the adsorption of the rolling prevention portion 53 to the roofing material 6. By reducing the rolling of the injector 50 on the roofing material 6, it is possible to prevent the injector 50 from falling from the roof 3.

  In addition, the rolling prevention part 53 should just satisfy p> r about the side part 55 in at least 1 side among the rectangles which the outer edge of the board part 54 makes. Since the injector 50 can remain on the roofing material 6 when the side portion 55 satisfying p> r is in contact with the roofing material 6, the injector 50 on the roofing material 6. Can reduce the situation of rolling. Even when the outer edge of the plate part 54 forms a polygon other than a rectangle, the rolling prevention part 53 satisfies p> r for the side part 55 on at least one side, so that the injector 50 on the roofing material 6 can be obtained. Can be prevented from rolling. The outer edge of the board part 54 should just contain at least 1 straight line. The rolling prevention part 53 can prevent the injector 50 from rolling on the roofing material 6 by satisfying p> r for the side part 55 in the straight line. In addition, the rolling prevention part 53 is not restricted to what consists of the board part 54 and the side part 55, What is necessary is just to make the shape which can suppress the rolling of the injector 50 including the part which satisfies p> r.

  In order to fix the structure in the entire roof 3, the sealing material 15 stored in a plurality of sealing material containers 56 may be required. According to the fifth embodiment, since the injector 50 placed on the roof 3 can be prevented from falling, a plurality of injectors 50 are placed on the roof 3 and the sealing material 15 in the sealing material container 56 is placed. It is possible to continue the work on the roof 3 by changing the injector 50 every time there is no more. In this case, a plurality of sealing material containers 56 are prepared on the ground or the like, and the sealing material container 56 needs to be taken to the ground every time the sealing material 15 is insufficient in the work on the roof 3. The workability can be improved.

Embodiment 6 FIG.
Next, with reference to FIG. 21 and FIG. 22, the fixing method of the outdoor structure concerning Embodiment 6 of this invention is demonstrated. In the sixth embodiment, a gap is formed between the base plate 4 and the waterproof sheet. In the sixth embodiment, the same components as those in the first to fifth embodiments are denoted by the same reference numerals, and the configuration different from the first to fifth embodiments will be mainly described.

  FIG. 21 is a diagram illustrating a state in which the sealing material 15 is filled by the outdoor structure fixing method according to the sixth embodiment. In Embodiments 1 to 5, the waterproof sheet 5 is bonded to the field board 4 by an adhesive layer provided on the surface of the waterproof sheet 5 on the field board 4 side. In contrast, the adhesive sheet is not provided on the waterproof sheet 61 of the sixth embodiment. The waterproof sheet 61 is the same as the waterproof sheet 5 of Embodiments 1 to 5 except that the waterproof sheet 61 does not have an adhesive layer for adhesion to the base plate 4.

  When forming the pilot hole 11 with the drill 20 shown in FIG. 2, the asphalt of the waterproof sheet 61 is melted due to the temperature rise around the pilot hole 11 due to friction between the drill 20 and the roofing material 6, and the The waterproof sheet 61 may adhere around.

  In the sixth embodiment, as in the fifth embodiment, the roofing material 6 is lifted from the base plate 4 by the magnetic force of the permanent magnet 51, so that the portion of the waterproof sheet 61 adhered to the periphery of the pilot hole 11 is the roof. It is lifted together with the lumber 6. A portion of the waterproof sheet 61 bonded to the periphery of the lower hole 11 is lifted from the field plate 4 in the second direction, and a portion of the waterproof sheet 61 bonded to the periphery of the lower hole 11 is the field plate 4. Stay on top. Thus, in Embodiment 6, the air gap 62 is formed between the field board 4 and the waterproof sheet 61 by lifting the waterproof sheet 61 together with the roofing material 6 from the field board 4.

  In a state where the gap 62 is formed by lifting the roofing material 6 and the waterproof sheet 61, the paste-like sealing material 15 is injected from the injection nozzle 30 into the pilot hole 11. The sealing material 15 enters the recess 13 and the gap 62 from the pilot hole 11. After the sealing material 15 enters the space 62, the lifting of the roofing material 6 is released, so that the space 15 is filled with the sealing material 15 between the waterproof sheet 61 and the base plate 4. 62 is closed. The sealing material 15 filled in the roof 3 is cured. In the sixth embodiment, instead of lifting the roofing material 6 by a method using the same magnetic force as in the fifth embodiment, the roofing material 6 is lifted by the same method as any one of the first to fourth embodiments. Thus, the gap 62 may be formed.

  FIG. 22 is a diagram illustrating a state in which the wood screw 8 is tightened by the outdoor structure fixing method according to the sixth embodiment. The rubber sheet 7 and the mounting bracket 10 are arranged in the same manner as in the first embodiment after the injection of the sealing material 15 is finished. The wood screw 8 tightened from the hole 16 of the mounting bracket 10 passes through the rubber sheet 7 and the sealing material 15 and is tightened to the field board 4.

  Here, the function of preventing water leakage by the fixing structure 1 according to the sixth embodiment will be described. When rainwater that has passed through the gap 9 shown in FIG. 1 travels between the roofing material 6 and the waterproof sheet 61 and enters the wood screw 8, it is filled between the waterproof sheet 61 and the base plate 4. The sealing material 15 blocks rainwater from entering the wood screw 8 from the waterproof sheet 61 to the base plate 4. Since the entrance of rainwater is blocked by the sealing material 15, the fixing structure 1 can reduce leakage due to rainwater entering the indoor side of the field board 4 through the wood screws 8.

  According to the sixth embodiment, the fixing structure 1 is configured such that the sealing material 15 is filled between the waterproof sheet 61 and the field board 4 around the wood screw 8, so that rainwater to the indoor side of the field board 4 can be obtained. Allow entry to be reduced. Thereby, there exists an effect that the water leakage to the building material which comprises a building can be reduced.

  The solar cell module 2 shown in FIG. 1 is subjected to a force in the direction of rising from the roof 3 by the action of wind. When the force is applied, the solar cell module 2 vibrates, so that a fine gap may be generated between the wood screw 8 and the base plate 4. When rainwater enters the field board 4 by being transmitted through the wood screw 8, since the gap is generated, water leakage to the indoor side increases, so that the wood screw 8 needs to be tightened. The tightening of the wood screw 8 involves installing a scaffold for the operator to go up to the roof 3 and removing the solar cell module 2, so that the maintenance cost increases as the frequency of the tightening increases. It becomes.

  According to the fixing method and the fixing structure 1 of the outdoor structure according to the first to sixth embodiments, since the rainwater can be blocked by the sealing material 15 due to the wood screw 8, the sealing material 15 can prevent water leakage. Therefore, the frequency of retightening the wood screw 8 can be reduced. Maintenance costs can be reduced by reducing the frequency of retightening. When the solar cell module 2 is installed on the roof 3 that is inclined with respect to the horizontal plane, compared to the case where the solar cell module 2 is installed on the roof 3 parallel to the horizontal plane, it is easy to receive a force in the direction of lifting from the roof 3. Maintenance costs can be effectively reduced.

  The outdoor structure fixing method according to the first to sixth embodiments and the building to which the fixing structure 1 is applied may be a building including an exterior material capable of fixing the structure, and is a building other than a general house. It may be a thing. In addition to the solar cell module 2, the structure installed on the outdoor side of the building may be a structure such as an antenna that receives radio waves. It is assumed that the structure is mainly a heavy object that needs to be firmly fixed to the building. The fixed structure 1 may be a structure that fixes a structure to a roof parallel to the horizontal plane, in addition to the roof 3 inclined with respect to the horizontal plane. The fixed structure 1 may be one that fixes the structure to the outer wall of the building other than the roof of the building. The exterior material may be an outer wall material of a building.

  The configuration described in the above embodiment shows an example of the contents of the present invention, and can be combined with another known technique, and can be combined with other configurations without departing from the gist of the present invention. It is also possible to omit or change the part.

  DESCRIPTION OF SYMBOLS 1 Fixed structure, 2 Solar cell module, 3 Roof, 4 Base plate, 5,61 Waterproof sheet, 6 Roofing material, 7 Rubber sheet, 8,35 Wood screw, 8a, 20a, 26 Tip, 8b Head, 9 Crevice 10, mounting bracket, 10a flange, 11 pilot hole, 12 burr, 13 recess, 14, 34, 38, 42, 52, 62 gap, 15 sealing material, 16, 37 holes, 20 drill, 21 jig, 22 rotations Child, 23 stator, 24 bearing, 25 push screw, 27 end face, 28 outer peripheral surface, 30 injection nozzle, 32 shaft part, 32a straight part, 32b taper part, 33 thread, 33a, 33b, 33c part, 36 slit, 40 dust collector, 41 duct, 50 injector, 51 permanent magnet, 53 rolling prevention part, 54 plate part, 55 side part, 56 seal material container.

Claims (14)

A method of fixing a structure installed on the outdoor side of a building,
Forming a pilot hole in an exterior material covering the building material constituting the building;
Between the exterior material and the building material, forming a gap around the pilot hole;
Filling the gap with a sealing material;
Tightening the fixing member passed through the structure and the pilot hole to the building material;
The fixing method of the outdoor structure characterized by including.   The method for fixing an outdoor structure according to claim 1, wherein a waterproof sheet is provided between the exterior material and the building material, and the gap is formed between the exterior material and the sheet. .   2. The outdoor structure fixing method according to claim 1, wherein a waterproof sheet is provided between the exterior material and the building material, and the gap is formed between the building material and the sheet.   The gap is formed by pressing a tip of a jig attached to a cutting tool used for forming the prepared hole against the periphery of the prepared hole in the exterior material. The fixing method of the outdoor structure as described in any one of 3. Filling the structure placed on the exterior material in which the pilot hole is formed with the sealing material,
By tightening the fixing tool passed through the sealing material filled in the structure, the exterior material is pushed up in a direction opposite to the advancing direction of the fixing tool by the tightening to form the gap, The method for fixing an outdoor structure according to any one of claims 1 to 3, wherein the sealing material is filled into the gap by pushing out the sealing material accompanying the tightening. Place the structure with an interposition part having adhesiveness between the exterior material in which the pilot hole is formed,
The outdoor structure fixing method according to any one of claims 1 to 3, wherein the gap is formed by lifting the exterior material from the building material together with the structure and the interposition part.   The outdoor structure fixing method according to any one of claims 1 to 3, wherein the gap is formed by lifting the exterior material from the building material by a suction force of a dust collector.   An injection nozzle for injecting the seal material is integrated with a duct connected to the dust collector, and the injection nozzle injects the seal material together with suction from the duct by the dust collector, so that the seal material is injected into the gap. The method for fixing an outdoor structure according to claim 7, further comprising:   The outdoor structure fixing method according to any one of claims 1 to 3, wherein the gap is formed by lifting the exterior material from the building material by a magnetic force.   A permanent magnet is attached to an injection nozzle for injecting the seal material, and the exterior material is attracted to the permanent magnet by the magnetic force of the permanent magnet, and the seal is injected into the gap by the injection nozzle injecting the seal material. The method for fixing an outdoor structure according to claim 9, wherein a material is inserted. A structure for fixing a structure installed on the outdoor side of a building,
The exterior material covering the construction material constituting the building, the sheet having waterproofness provided between the exterior material and the construction material, and the structure are passed through and tightened to the construction material. A fixing tool,
Between the exterior material and the sheet or between the building material and the sheet, a sealing material filled around the fixing tool,
A structure for fixing an outdoor structure, comprising: It is a tool used in the fixing method of the outdoor structure of Claim 4,
The tool is the jig having the tip provided along a circle having a diameter larger than the diameter of the pilot hole formed in the exterior material. A tool used in the method for fixing an outdoor structure according to claim 8,
The injection nozzle;
The duct surrounding the periphery of the injection nozzle;
A tool comprising: It is a tool used in the fixing method of the outdoor structure according to claim 10,
The injection nozzle;
The permanent magnet;
A sealing material container in which the sealing material is stored;
A component that is fixed to the injection nozzle in contact with the permanent magnet and includes a magnetic material as a component;
The component has a plate portion having an outer edge including a straight line, and a side portion raised from the plate portion,
The tool is characterized in that a length between the side portion and the center line of the tool in the straight line is longer than a length between an outer surface of the sealing material container and the center line.

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