JP2020105734A - Joint structure and joiner - Google Patents

Abstract

To provide a joint structure hardly damaging waterproof property and improving fire resistance.SOLUTION: A joint structure 1 comprises a joint 3, a sealing material 4, a joiner 5, and a refractory material 6. The joint 3 is formed between end faces 21 of adjacent building boards 2. The sealing material 4 is positioned at the joint 3. The joiner 5 backs up the sealing material 4. The refractory material 6 is positioned between the sealing material 4 and the joiner 5, and is configured to foam and expand due to the heat of the fire. The sealing material 4 contacts with the refractory material 6 without being fixed thereto.SELECTED DRAWING: Figure 1

Description

The present invention relates to joint structures and joiners. More specifically, the present invention relates to a joint structure and a joiner having joints formed between end faces of adjacent building boards.

Patent Document 1 describes a joint joiner. The joint joiner is arranged in a joint portion formed between the end faces of the adjacent exterior materials, and serves as a base of the sealing material placed in the joint portion. The sealing material may be cut or peeled off due to the expansion and contraction change of the exterior material after construction, and the waterproof property of the joint portion may be impaired. Therefore, the sealing material is required to be able to absorb and follow the expansion and contraction change of the exterior material after construction, and it is desirable to adhere to the end surface of the exterior material but not to the joint joiner. Therefore, the joint breaker is provided with a bond breaker for preventing the sealing material from adhering.

On the other hand, since the sealing material is made of synthetic resin and easily burns, it has been desired to improve the fire resistance of the joint portion.

JP, 2003-343024, A

The present invention has been made in view of the above reasons, and an object of the present invention is to provide a joint structure and a joiner in which waterproofness is not easily impaired and fire resistance can be improved.

A joint structure according to an aspect of the present invention is a joint formed between end surfaces of adjacent building boards, a sealing material located at the joint, a joiner that backs up the sealing material, the joiner and the sealing material. And a refractory material configured to expand and expand due to heat of fire. The sealing material is in contact with the refractory material without sticking to it.

A joiner according to one embodiment of the present invention is a joiner that backs up a sealing material located at a joint formed between end surfaces of adjacent building boards. A mounting portion for mounting a refractory material configured to be foamed and expanded by heat of fire and configured to contact the sealing material without being fixed.

According to the present invention, there is an advantage that waterproofness is not easily impaired and fire resistance can be improved.

FIG. 1 is a sectional view showing an embodiment of a joint structure according to the present invention. FIG. 2 is a perspective view showing an embodiment of the above. FIG. 3A is a partial perspective view showing a joiner used in the above embodiment. FIG. 3B is a partial perspective view showing a modified example of the above joiner. FIG. 4 is a cross-sectional view showing a refractory material used in the above embodiment. FIG. 5: is sectional drawing which shows operation|movement of one Embodiment same as the above. FIG. 6 is a sectional view showing the operation of the above embodiment. 7A and 7B are cross-sectional views showing a conventional joint structure.

(Embodiment)
FIG. 1 is a sectional view showing a joint structure 1 according to this embodiment. The joint structure 1 includes joints 3 formed between the end faces 21 of adjacent building boards 2, a sealing material 4 arranged on the joints 3, a joiner 5 and a fireproof material 6 that back up the sealing material 4.

FIG. 2 is a perspective view showing the joint structure 1 according to the present embodiment. The joint structure 1 is provided on the outer wall 11 of the building. The outer wall 11 includes a plurality of building boards 2 attached to the outside (outdoor side) of the foundation 9 of the building. The building board 2 on the outer wall 11 is an outer wall material. The building board 2 is attached to the base 9 by a plurality of fasteners 7. The fastener 7 is a fastener that can be attached to the outdoor side of the base 9 by hooking the building board 2. The base 9 is a gypsum board, a plywood, a furring strip or the like attached to the outdoor side of a pillar or the like.

(Building board)
The building board 2 is ceramic siding. Ceramic siding is a plate-shaped finishing material made of cement (hardened cement). The building board 2 has a quadrangular shape when viewed from the front (a shape viewed from the outside), and is a horizontally long rectangle. The building board 2 may have an uneven pattern on the surface, or may have a coating film. The building board 2 has a hook portion 22 at the upper end. The hook portion 22 is a portion that is hooked to the fastener 7 when the building board 2 is attached to the base 9. The building board 2 has a cover portion 23 at the lower end portion. When a plurality of building boards 2 are vertically adjacent to each other and attached to the base 9, the covering portion 23 is located in front of the hook portion 22 and the fastener 7 of the building board 2 located on the lower side. It is a part that hides the part 22 and the fastener 7.

(Joint)
In the joint structure 1 according to this embodiment, the end surface (edge) 21 of the building board 2 is a side end surface of the building board 2. That is, it is a surface that constitutes an end of the building board 2 in the left-right direction. The end surface 21 is a flat surface and is parallel to the thickness direction of the building board 2 (direction orthogonal to both the up-down direction and the left-right direction of the building board 2). Here, “flat” does not mean “flat” in a strict sense, but also includes a case where there is some unevenness. In addition, "parallel" is not strictly parallel, and includes a case where the building board 2 is not orthogonal to the vertical direction and/or the horizontal direction of the building board 2 or to some extent.

In the joint structure 1 according to this embodiment, the joint 3 is a space formed between the end faces 21 of the adjacent building boards 2. That is, the joint 3 is formed by arranging the building boards 2 that are adjacent to each other in the left-right direction with a slight gap (about 10 mm) provided therebetween, without protruding. Therefore, in the building boards 2 that are adjacent to each other in the left-right direction, the end surface 21 of one building board 2 and the end surface 21 of the other building board 2 face each other, and a gap between the facing end surfaces 21 is formed as the joint 3. To be done. The joint 3 is formed substantially straight in the vertical direction.

(Sealing material)
In the joint structure 1 according to the present embodiment, the sealing material 4 is arranged on the joint 3. Here, it is sufficient that a part of the sealing material 4 is arranged in the joint 3, and a part of the sealing material 4 may protrude from the joint 3. The sealing material 4 improves the waterproof property of the joint 3. That is, the sealing material 4 prevents water such as rainwater and condensed water from entering the building board 2 from the outdoor side to the indoor side through the joint 3. Therefore, the sealing material 4 is preferably arranged so as to contact the end face 21 of the building board 2 and close the joint 3. Further, the sealing material 4 is preferably expandable and contractible. That is, the width dimension (the dimension in the left-right direction) of the joint 3 changes as the building board 2 expands and contracts due to a change in temperature or receives a wind and vibrates. Therefore, it is preferable that the sealing material 4 has elasticity so that it can follow the change in the width dimension of the joint 3. As a result, a gap is less likely to be formed between the sealing material 4 and the end surface 21, and the sealing material 4 is less likely to be broken due to expansion and contraction, and the waterproof property of the joint 3 is less likely to be impaired. In addition, it is preferable that the sealing material 4 has good adhesiveness to the end surface 21, good weather resistance and water resistance, and has appropriate elasticity.

The sealing material 4 is made of synthetic resin, and is made of a material selected from the group consisting of silicone resin, modified silicone resin, acrylic resin, polyurethane resin, polysulfide resin, EPDM and butyl rubber. Preferably.

(Joiner)
In the joint structure 1 according to the present embodiment, the joiner 5 backs up the sealing material 4. That is, the joiner 5 supports the sealing material 4 in the joint 3. Usually, the sealing material 4 is put in the joint 3 from the outdoor side of the building board 2, but at this time, in the thickness direction of the building board 2, the sealing material 4 is arranged at a predetermined position in the joint 3, The joiner 5 supports the sealing material 4 from the indoor side.

As shown in FIG. 3A, the joiner 5 is a member that is long in the vertical direction. The joiner 5 includes a support portion 55, a plurality of (a pair of) leg portions 56 projecting from both side ends of the support portion 55 toward the indoor side (rear side), and left and right from a tip (rear end) of each leg portion 56. And a fixing portion 57 protruding in the direction. The interval between the plurality of legs 56 is formed so as to gradually narrow from the outdoor side toward the indoor side. That is, the plurality of leg portions 56 are formed so as to gradually approach each other from the end portion (front end) on the support portion 55 side toward the end portion on the fixed portion 57 side (rear side). The distance between the legs 56 is smaller on the indoor side than on the outdoor side.

The joiner 5 is equipped with a mounting portion 51 for mounting the refractory material 6. In the joint structure 1 according to the present embodiment, the outdoor side surface (front surface) of the support portion 55 is configured as the attachment portion 51. The attachment portion 51 is a surface that constitutes the outermost side of the joiner 5, and the joiner 5 and the building board 2 are arranged so that the attachment portion 51 is located in the joint 3. The mounting portion 51 is a flat surface, but may have some irregularities. As the joiner 5, a bent product of a metal plate such as a steel plate, an extruded product of a metal such as aluminum, a plastic molded product, or the like can be used.

(Refractory material)
In the joint structure 1 according to the present embodiment, the refractory material 6 is located between the joiner 5 and the sealing material 4. That is, the sealing material 4 is backed up by the joiner 5 without directly contacting the joiner 5. That is, the joiner 5 backs up the sealing material 4 via the refractory material 6.

In the joint structure 1 according to the present embodiment, the refractory material 6 is configured to foam and expand due to the heat of fire. That is, when the refractory material 6 is not heated by the heat of fire, it does not foam or expand. That is, when the refractory material 6 is not heated by the heat of the fire, it retains its original shape, and when heated by the heat of the fire, it foams and expands and deforms from the original shape.

The refractory material 6 has a surface that contacts the sealing material 4. That is, the sealing material 4 is applied in a state of being in contact with the surface of the refractory material 6. The sealing material 4 is in contact with the refractory material 6 without being fixed. As a result, the expansion and contraction of the sealing material 4 is less likely to be restricted by the refractory material 6. Here, "fixed" means firmly and firmly attached. Therefore, "non-fixed" means not firmly and firmly attached. That is, “the sealing material 4 does not adhere to the refractory material 6 ”includes a state in which the sealing material 4 is not adhered or fixed to the refractory material 6 at all, and the sealing material 4 partially adheres to the refractory material 6 or It includes a fixed state, and also includes a state in which the sealing material 4 is weakly adhered or fixed to the refractory material 6. That is, if the sealing material 4 is capable of expanding and contracting so as not to come off from the end face 21 while being in contact with the surface of the refractory material 6, it is included in “not fixed” in the present embodiment.

The refractory material 6 includes a non-sticking portion 61 and a foam expanding portion 62. The refractory material 6 may include a base material portion 63 in addition to the non-fixed portion 61 and the foam expansion portion 62. The non-fixed portion 61 constitutes a surface that comes into contact with the sealing material 4. That is, the sealing material 4 is applied in a state of being in contact with the surface of the non-fixed portion 61. The sealing material 4 contacts the non-fixed portion 61 without being fixed. As a result, the expansion and contraction of the sealing material 4 is less likely to be restricted by the non-fixed portion 61.

The foam expansion part 62 is a part which foams and expands when the refractory material 6 is heated by heat of a fire. That is, when the refractory material 6 is heated by the heat of a fire, the foaming/expansion portion 62 foams and expands, and the non-sticking portion 61 and the base material portion 63 hardly foam or expand. The foam expansion part 62 can be expanded by the heat of a fire. That is, the foam expansion section 62 foams when heated by a fire, and increases the volume while forming a large number of voids inside due to the foaming. The expanded refractory material (expansion residue) becomes a foamed expanded body 6a, which does not easily burn against a flame and retains its shape, and further has heat insulation due to the bubbles inside. Therefore, when the foam expander 6a expands at the joint 3, the joint 3 is almost closed by the foam expander 6a, and it becomes difficult for flame, smoke, and heat to pass through the joint 3.

The foam expansion part 62 contains a heat-expandable fire-resistant resin composition. Specifically, the foam expansion part 62 preferably contains a synthetic resin, a polyhydric alcohol, a flame retardant foaming agent, and the like. Examples of the synthetic resin include melamine resin, acrylic resin, alkyd resin, vinyl chloride resin, vinyl acetate resin, urethane resin, epoxy resin, silicone resin, polyester resin, polyolefin/vinyl acetate resin, vinyl acetate/versatic acid vinyl ester copolymer. Examples thereof include polymer resins, vinyl acetate/polyolefin resins, vinyl acetate/versatitic acid/acrylic resins, vinyl acetate/acrylic copolymer resins, acrylic/styrene copolymer resins, and polybutadiene resins. In addition, polyethylene etc. are mentioned as polyolefin. Examples of the polyhydric alcohol include pentaerythritol, dipentaerythritol, tripentaerythritol, polypentaerythritol and the like. As the flame retardant foaming agent, phosphates such as ammonium phosphate, ammonium polyphosphate, melamine phosphate, melamine polyphosphate, aluminum polyphosphate, and magnesium polyphosphate are preferably used, but sulfamate ( Examples thereof include sulfamine ammonium) and borates (ammonium borate). As the heat-expandable fire-resistant resin composition, for example, a foamable ammonium polyphosphate-containing polyethylene resin is used.

The content ratio of the synthetic resin, the polyhydric alcohol, and the flame-retardant foaming agent in the foam expansion section 62 is 10 parts by mass or more and 50 parts by mass or less of the polyhydric alcohol, and the flame-retardant foaming agent is 100 parts by mass of the synthetic resin. It is preferably 50 parts by mass or more and 200 parts by mass or less.

The base material portion 63 has a function of maintaining the shape of the refractory material 6. In particular, the base material portion 63 has a function of holding the foam expansion portion 62. That is, the heat-expandable refractory resin composition forming the foam expansion part 62 is soft and difficult to maintain a specific shape. Further, the heat-expandable refractory resin composition is sticky and has low handleability. Therefore, the base material portion 63 is provided in the refractory material 6 in order to improve the shape maintainability and handleability of the refractory material 6.

The refractory material 6 is formed in a plate shape or a sheet shape. For example, the thickness of the refractory material 6 can be 0.5 mm or more and 3 mm or less, and more preferably 0.6 mm or more and 2.0 mm or less. The refractory material 6 is provided with a layered non-sticking portion 61, a layered foam expansion portion 62 and a layered base material portion 63. The non-fixed portion 61 and the base material portion 63 are provided on both surfaces of the foam expansion portion 62. That is, the foam expansion part 62 is sandwiched between the non-fixed part 61 and the base material part 63. Therefore, one surface of the refractory material 6 is formed by the non-sticking portion 61, and the other one surface of the refractory material 6 is formed by the base material portion 63.

The non-sticking portion 61 and the base material portion 63 have water resistance. Here, the “water resistance” in the present embodiment means that it is not altered by water. For example, the non-fixed portion 61 and the base material portion 63 are hardly dissolved even if water adheres to the surfaces thereof, and their shapes are hardly changed. Further, the non-fixed portion 61 and the base material portion 63 hardly permeate moisture, and hardly pass moisture. Since the non-sticking portion 61 and the base material portion 63 have water resistance, it is possible to reduce the influence of water on the foam expanding portion 62, and to reduce the loss due to the dissolution of the foam expanding portion 62.

The material of the non-fixed portion 61 and the base material portion 63 is preferably a synthetic resin film. Examples of the synthetic resin film include polyethylene terephthalate film (PET film), polyethylene film, polypropylene film and silicone film. Further, the synthetic resin film may be provided with an appropriate reinforcing material such as glass paper, glass non-woven fabric, and glass woven fabric. The non-fixed portion 61 and the base material portion 63 may be made of the same material or different materials. The non-adhered portion 61 is particularly required not to be adhered to the sealing material 4, and thus is preferably a PET film having this property. The base material portion 63 is preferably a PET film having this property, because the adhesiveness to the joiner 5 and the water resistance are taken into consideration.

The refractory material 6 normally has a thickness of about 0.5 to 3 mm (before being expanded by heating), but when heated to 200° C. or higher due to a fire, the volume (particularly in the thickness direction) of the refractory material 10 to 10 Expands about twice.

(Joint structure)
The joint structure 1 according to this embodiment is formed as follows.

First, the joiner 5 is attached to the outdoor side of the base 9. When attaching the joiner 5, the fixing portion 57 is arranged along the outdoor side surface of the base 9, and a fixing tool such as a screw or a nail is driven up to the base 9 so as to penetrate the fixing portion 57. As a result, the support portion 55 and the leg portions 56 of the joiner 5 are in a state of protruding to the outdoor side of the base 9.

Next, the refractory material 6 is attached to the joiner 5. When attaching the refractory material 6, the base material portion 63 of the refractory material 6 is attached to the attachment portion 51 of the joiner 5. An adhesive, a double-sided tape, or the like is used to attach the base material portion 63. The refractory material 6 is attached over substantially the entire length of the joiner 5 in the longitudinal direction. Therefore, the refractory material 6 is attached along the entire surface of the attachment portion 51.

Next, the plurality of fasteners 7 are attached to the outdoor side of the base 9. The fastener 7 is fixed to the base 9 with a fastener such as a screw or a nail. Here, since the joint structure 1 is formed by using the end surface 21 of the building board 2, the side end portion of the building board 2 is arranged near the side of the joiner 5. Therefore, the fasteners 7 are provided at least near the sides of the joiner 5 to attach the side ends of the building board 2.

Next, the plurality of building boards 2 are attached to the outdoor side of the base 9. Each building board 2 is attached by hooking the hook portion 22 on the upper end to the fastener 7 on the upper side. The lower part of each building board 2 is also hooked and attached to the lower fastener 7. The plurality of building boards 2 are sequentially attached from bottom to top. The building boards 2 adjacent to each other in the up-and-down direction can be seen from the front because the hook portions 22 of the building board 2 located on the lower side and the fasteners 7 hooked on the hooks 22 are covered by the covering portion 23 of the building board 2 located on the upper side. Disappear. Further, a ventilation layer 8 is formed between the indoor side surface of the building board 2 and the base 9. The width dimension of the ventilation layer 8 (the distance between the indoor surface of the building board 2 and the outdoor surface of the base 9) is substantially the same as or slightly narrower than the thickness of the fastener 7. The ventilation layer 8 can be formed so as to be continuous from the lower part to the upper part of the outer wall 11.

The building boards 2 adjacent to each other in the left-right direction are arranged such that the end faces 21 thereof face each other in the left-right direction. That is, among the building boards 2 adjacent in the left-right direction, the right end surface 21 of the building board 2 located on the right side and the left end surface 21 of the building board 2 located on the left side are arranged to face each other. The space between the facing end faces 21 is formed as the joint 3. A part of the joiner 5 and the refractory material 6 are arranged in the joint 3. That is, a part of the joiner 5 and the refractory material 6 are arranged between the facing end faces 21. Here, a part of the joiner 5 is the outdoor end of the leg portion 56 and the support portion 55. Therefore, the attachment portion 51, which is the surface of the support portion 55 on the outdoor side, and the refractory material 6 attached to the attachment portion 51 are also arranged in the joint 3. A gap 81 is formed between the end surface 21 of the building board 2 and the joiner 5. The gap 81 is formed between the edge 25 on the indoor side of the end surface 21 of the building board 2 and the outer surface of the leg portion 56 of the joiner 5. Therefore, the joint 3 and the ventilation layer 8 communicate with each other through the gap 81.

Next, the sealing material 4 is placed on the joint 3. In the joint structure 1 according to the present embodiment, the sealing material 4 is arranged on the outdoor side of the refractory material 6. That is, the sealing material 4 is arranged between the opening 31 on the outdoor side of the joint 3 and the surface of the non-fixed portion 61 of the refractory material 6 on the outdoor side. As a result, the sealing material 4 is supported by the joiner 5 via the refractory material 6. A wet type sealing material 4 is used. In this case, a viscous sealing material 4 is injected into the joint 3 from the opening 31 using a sealing gun, and the injected sealing material 4 in the joint 3 is dried and solidified or cured. As a result, the elastic sealing material 4 is arranged on the joint 3.

The sealing material 4 arranged on the joint 3 adheres to the end face 21. The adhesion in this case is due to the self-adhesive force of the sealing material 4. That is, it is an adhesive force generated when the sealing material 4 is dried and solidified or cured after the wet sealing material 4 is injected into the joint 3. When the sealing material 4 adheres to the end surface 21 in this way, the building board 2 expands and contracts due to changes in temperature or vibrates due to wind, so that the width of the joint 3 changes, so that it follows. The sealing material 4 expands and contracts. Therefore, the end surface 21 and the sealing material 4 are less likely to be peeled off, the sealing material 4 is less likely to be damaged such as a crack, and the waterproof property of the joint 3 is less likely to be deteriorated.

On the other hand, the sealing material 4 arranged on the joint 3 does not adhere to the refractory material 6. That is, the sealing material 4 contacts the non-fixed portion 61 of the refractory material 6, but is not fixed. Therefore, even if the width dimension of the joint 3 changes as described above, the sealing material 4 expands and contracts while contacting the non-fixed portion 61. Therefore, the end surface 21 and the sealing material 4 are less likely to be peeled off, the sealing material 4 is less likely to be damaged such as a crack, and the waterproof property of the joint 3 is less likely to be deteriorated. That is, in the joint structure 1 according to this embodiment, the refractory material 6 (the non-fixed portion 61 thereof) functions as a bond breaker.

The joint structure 1 according to the present embodiment secures the waterproofness of the outer wall 11 in a normal time before a fire occurs, similarly to a normal joint. On the other hand, as shown in FIG. 1, when a fire F occurs outside the outer wall 11, the joint structure 1 is heated from the outside by the flame F. In such a situation, the resin sealing material 4 burns and disappears due to the heat of the flame F. Further, the heat of the flame F causes the refractory material 6 to foam and expand. That is, the non-sticking portion 61 and the base material portion 63 of the refractory material 6 burn and disappear with the heat of the flame F, and the foam expanding portion 62 expands while foaming with the heat of the flame F. Here, in addition to the heating by the flame F, the heat generated by the burning of the sealing material 4, the non-sticking portion 61, and the base material portion 63 is also used for the foaming and expansion of the foam expanding portion 62. Combustion of the sealing material 4, the non-fixed portion 61, and the base material portion 63 often occurs closer to the foam expansion portion 62 than to the flame F, so that the foam expansion portion 62 is easily heated.

The heated foam expansion section 62 expands while foaming. At this time, since the foam expansion section 62 is expanded mainly in the thickness direction while being supported by the joiner 5, the joint 3 is filled with the foam expansion body 6a on the outdoor side of the joiner 5. The foam expander 6a is formed by increasing the volume of the foam expander 62 when the foam expander 62 is heated by fire and foams, forming a large number of voids inside. The foamed expandable body (expansion residue) 6a does not easily burn against a flame and retains its shape, and further has thermal insulation due to the bubbles inside. Therefore, when the foam expander 6a is filled in the joints 3, the joints 3 are closed, and it becomes difficult for flames, smoke, and heat to pass through the joints 3.

In addition, as the heating of the foam expansion part 62 progresses, the expansion and expansion of the foam expansion body 6a further progress, and the volume of the foam expansion body 6a may increase. In this case, as shown in FIG. 6, the foam expansion body 6a projects from the opening 31 of the joint 3 to the outdoor side. In addition to this, the expanded foam body 6a penetrates into the outdoor side of the second joint 3 of the building board through the gap 81. As a result, a part of the foam expansion body 6a enters the ventilation layer 8 and the gap 81, and the foam expansion body 6a is arranged from the joint 3 to the ventilation layer 8 (near the periphery of the joiner 5 and the fastener 7). It will be. Therefore, the joint 3 and the gap 81 are closed, flames, smoke, and heat are less likely to enter the ventilation layer 8, and the fire resistance of the joint 3 and its periphery is improved. In particular, when flame, smoke, and heat enter the ventilation layer 8, smoke or the like may spread through the ventilation layer 8. However, the joint structure 1 according to the present embodiment is capable of reducing the spread of such smoke or the like. You can

Further, when the foam expander 6a is formed around the joiner 5 and the fastener 7, it becomes difficult for flame and heat to reach the fastener 7 and the indoor side of the building board 2 by the foam expander 6a. And thermal deformation of the building board 2 is reduced. Therefore, the building board 2 is unlikely to come off the fastener 7 and fall off. In addition, as shown in FIG. 7A, in the case of the joint 3X without the refractory material 6, when heated with the flame F, the sealing material 4 disappears, and then the flame F enters the ventilation layer 8 through the joint 3X, As a result, the fastener 7 and the building board 2 may be deformed, and the building board 2 may come off the fastener 7 and fall off as shown in FIG. 7B.

(Modification)
The embodiment is only one of the various embodiments of the present disclosure. The embodiments can be variously modified according to the design and the like as long as the object of the present disclosure can be achieved.

Although the joint structure 1 included in the outer wall 11 has been described above, the joint structure 1 according to the present embodiment is not limited to this. For example, a partition wall, an inner wall, a fence, a fence, or the like may be included in the joint structure 1.

Although the outer wall 11 in which the plurality of building boards 2 are horizontally stretched has been described above, the joint structure 1 according to the present embodiment is not limited to this, and the plurality of building boards 2 may be vertically stretched.

Although the case where the joint structure 1 is the vertical joint has been described above, the joint structure 1 is not limited to this, and the joint structure 1 according to the present embodiment may be a horizontal joint.

In the above, the ceramic siding was described as the building board 2, but the construction board 2 is not limited to this, and the building board 2 may be metal siding or wood siding in the joint structure 1 according to the present embodiment. Further, the building board 2 may be a combination of ceramic siding material, metal siding material and wood siding material.

In the above description, the case where the mounting portion 51 to which the refractory material 6 is mounted is the outdoor side surface of the supporting portion 55 has been described, but the mounting portion 51 is not limited to this. For example, as shown in FIG. 3B, the outer surface of the joiner 5, that is, the outer surface of the leg portion 56 may be the mounting portion 51. In this case, the refractory material 6 attached to the attachment portion 51 of the leg portion 56 easily faces the ventilation layer 8. Therefore, when the refractory material 6 expands, it easily enters the ventilation layer 8, and the fire resistance of the ventilation layer 8 is easily improved.

In the above description, the refractory material 6 is attached to the attachment portion 51 after the joiner 5 is attached to the base 9, but the invention is not limited to this. For example, the joiner 5 may be attached to the base 9 after attaching the refractory material 6 to the attachment portion 51. Further, the refractory material 6 may be attached to the attachment portion 51 after attaching the fastener 7 to the base 9. Further, the refractory material 6 may be attached to the attachment portion 51 after attaching the building board 2. That is, the refractory material 6 may be attached to the attachment portion 51 before the sealing material 4 is placed on the joint 3.

Although the wet sealing material 4 has been described above, a dry sealing material may be used.

(Summary)
As described above, the joint structure (1) according to the first aspect includes the joint (3), the sealing material (4), the joiner (5), and the refractory material (6). The joint (3) is formed between the end faces (21) of the adjacent building boards (2). The sealing material (4) is located at the joint (3). The joiner (5) backs up the sealing material (4). The refractory material (6) is located between the sealing material (4) and the joiner (5), and is configured to foam and expand due to the heat of fire. The sealing material (4) is in contact with the refractory material (6) without being fixed.

According to this aspect, the expansion and contraction of the sealing material (4) is less likely to be hindered by the refractory material (6), the sealing material (4) is less likely to be peeled off from the end face (21) or cracked, and cracks are less likely to be generated. Water resistance is not impaired, and the fire-resistant material (6) expands and expands in the event of a fire, flames, heat and smoke are less likely to enter the joints (3), spread of fire is reduced, and fire resistance is improved. There is an advantage that it can be achieved.

The joint structure (1) according to the second aspect is the joint structure (1) according to the first aspect, wherein the refractory material (6) includes a non-adhesion portion (61) to which the sealing material (4) does not adhere. The sealing material (4) contacts the non-fixed portion (61).

According to this aspect, it is possible to prevent the sealing material (4) from sticking to the refractory material (6) at the non-adhered portion (61), and the expansion and contraction of the sealing material (4) is hindered by the refractory material (6). The sealing material (4) is less likely to be peeled off or cracked from the end surface (21), and the waterproof property is less likely to be impaired.

The joint structure (1) according to the third aspect is the joint structure (1) according to the second aspect, wherein the non-fixed portion (61) is made of a water-resistant synthetic resin film.

According to this aspect, not only the sealing material (4) does not adhere to the refractory material (6) at the non-adhesion portion (61) but also the water resistance of the refractory material (6) is obtained at the non-adhesion portion (61). And the waterproof property of the joint (3) is improved.

The joint structure (1) according to the fourth aspect is the joint structure (1) according to any one of the first to third aspects, in which the building board (2) is attached to the base (9) by the fasteners (7). A ventilation layer (8) communicating with the joint (3) is formed between the building board (2) and the base (9). The refractory material (6) is configured to foam and expand in the joint (3) by the heat of the fire. A part of the expanded refractory material (6) is configured to enter the ventilation layer (8).

According to this aspect, flames, heat, and smoke are less likely to enter the ventilation layer (8) through the joints (3), and further spread of fire is reduced to improve fire resistance.

The joiner (5) according to the fifth aspect is a joiner (5) that backs up a sealing material (4) arranged in a joint (3) formed between end faces (21) of adjacent building boards (2). is there. A mounting portion (51) for mounting a refractory material (6) configured to be foamed and expanded by heat of fire and to which the sealing material (4) is in contact without being fixed is provided.

According to this aspect, since the sealant (4) is backed up by the joiner (5) in the joint (3), the expansion and contraction of the sealant (4) is less likely to be hindered by the refractory material (6), and the sealant (4) is prevented. ) Is less likely to be peeled off from the end face (21) of the building board (2), cracks are less likely to occur, waterproofness is less likely to be impaired, and the refractory material (6) foams and expands in the event of a fire, and the joint (3 ) Has the advantage that flames, heat, and smoke are less likely to enter, and the spread of fire is reduced and the fire resistance can be improved.

1 Joint Structure 2 Building Board 21 End Face 3 Joint 4 Sealing Material 5 Joiner 6 Fireproof Material 7 Fastener 8 Venting Layer 9 Base

Claims (5)

Joints formed between the end faces of adjacent building boards,
A sealing material located at the joint,
A joiner that backs up the sealing material,
A refractory material that is located between the sealing material and the joiner and is configured to expand and expand by the heat of fire,
Equipped with
The sealing material is in contact with the refractory material without sticking,
Joint structure. In claim 1,
The refractory material includes a non-adhered portion to which the sealing material does not adhere,
The sealing material is in contact with the non-fixed portion,
Joint structure. In claim 2,
The non-sticking portion is composed of a water-resistant synthetic resin film,
Joint structure. In any one of Claims 1-3,
The building board is attached to the base with fasteners, and a ventilation layer communicating with the joint is formed between the building board and the base,
The refractory material is configured to foam and expand due to heat of fire in the joint, and a part of the expanded refractory material is configured to enter the ventilation layer,
Joint structure. A joiner that backs up a sealing material arranged in a joint formed between end faces of adjacent building boards,
A mounting portion for mounting a refractory material configured to foam and expand due to heat of fire, and to which the sealing material is configured to contact without sticking,
Joiner.

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