JP6595376B2 - Joinery - Google Patents

Description

  The present invention relates to a fitting such as a modified sash.

  A fitting such as a remodeled sash formed by arranging a new fitting unit in an opening made by removing a shoji from a fitting made of an existing frame and a shoji is already well known. Such joinery consists of the remaining existing frame or a reference frame made of a base material attached to the existing frame, a new frame provided inside the reference frame, and a gap between the reference frame and the new frame. And a spacer inserted for adjustment and holding.

Japanese Patent No. 5323964 Japanese Patent Laying-Open No. 2015-94171

  Since fittings such as refurbished sashes are often deformed or deteriorated due to secular changes in existing frames and frames, a plurality of spacers are used in an overlapping manner. Depending on the material of the spacer, a thin resin is used in order to avoid contact corrosion of dissimilar metals. However, when a fire occurs, the spacer itself may ignite, or ignition from the fire source may occur. In addition, the spacer melts and disappears due to the heat of the flame, and a gap may be formed between the reference frame and the new frame as a path for the flame. When the spacer disappears in this manner, the new frame is thermally deformed and the gap increases.

  On the other hand, depending on the material of the spacer, in the case of steel, stainless steel, aluminum or the like, there is a possibility that dissimilar metal contact corrosion occurs due to the material of the member that contacts the spacer.

  This invention is made | formed in view of this subject, The place made into the objective is to improve the fireproof performance of joinery, preventing the different metal contact corrosion of a spacer.

In order to achieve such an object, the joinery of the present invention includes an existing frame or a reference frame made of a base material attached to the existing frame;
A new frame provided inside the reference frame;
A spacer inserted in a gap between the reference frame and the new frame,
The spacer is
A reference frame side end spacer made of a material that is in contact with the reference frame and the adjacent spacer in a state sandwiched between the reference frame and the adjacent spacer and does not corrode different metals when contacting the reference frame and the adjacent spacer; ,
A new frame side end spacer made of a material that does not corrode different metals when contacting the new frame and the adjacent spacer, in contact with the new frame and the adjacent spacer in a state sandwiched between the new frame and the adjacent spacer; ,
It is a joinery characterized by comprising a metal central part spacer positioned between the reference frame side end spacer and the new frame side end spacer.

  According to such a joinery, since the reference frame side end spacer and the new frame side end spacer are made of a material that does not corrode different metal contacts, it is possible to prevent the different metal contact corrosion of the spacers. In addition, since the central spacer is made of metal, it is possible to improve the fireproof performance of the joinery.

Such joinery,
Having a fixture for fixing the reference frame and the new frame through the spacer;
It is desirable to provide other restraint locations in addition to the restraint locations of the reference frame and the new frame by the fixture.

  According to such a joinery, the relative freedom of movement of the reference frame and the new frame can be reduced. Therefore, complex deformations such as warping and twisting are less likely to occur in the joinery, and it is possible to suppress the generation of gaps that serve as passages for flames.

Such joinery,
A connecting bracket for connecting the existing frame or the base material and the new frame;
It is desirable that the other restraint portion is a restraint portion between the reference frame and the new frame by the connecting metal fitting.

  According to such a joinery, the relative freedom of movement of the reference frame and the newly installed frame can be reduced by attaching the connecting fitting. Therefore, complex deformations such as warping and twisting are less likely to occur in the joinery, and it is possible to suppress the generation of gaps that serve as passages for flames.

Such joinery,
There is another fixture different from the fixture that fixes the reference frame and the new frame via the spacer,
It is desirable that the other restraint portion is a restraint portion between the reference frame and the new frame by the other fixture.

  According to such a joinery, the relative freedom of movement of the reference frame and the new frame can be reduced by attaching another fixing tool. Therefore, complex deformations such as warping and twisting are less likely to occur in the joinery, and it is possible to suppress the generation of gaps that serve as passages for flames.

Such joinery,
The spacer has a notch;
It is desirable that the fixing tool and the other fixing tool pass through the notch.

  According to such a joinery, the spacer mounting process during construction is simplified.

Such joinery,
The spacer includes a notch and a hole,
The fixture passes through the notch;
It is desirable that the other fixing tool penetrates the hole.

  According to such a joinery, it is possible to prevent the spacer from dropping even if thermal deformation occurs.

Such joinery,
Engagement portions provided on the existing frame or the base material and the new frame, respectively, which engage with each other when the members provided with the engagement portions are thermally expanded in the event of a fire With
It is desirable that the other restraint location is a restraint location between the reference frame and the new frame by the engaging portion.

  According to such a joinery, the relative freedom of movement of the reference frame and the new frame can be reduced by installing the engaging portion. Therefore, complex deformations such as warping and twisting are less likely to occur in the joinery, and it is possible to suppress the generation of gaps that serve as passages for flames.

Further, the joinery of the present invention is a metal reference frame made of an existing frame or a base material attached to the existing frame,
A new metal frame provided inside the reference frame;
A spacer inserted in a gap between the reference frame and the new frame,
The spacer includes a resin spacer that contacts one of the reference frame and the new frame, and a metal spacer that contacts the other frame,
The metal spacer is a joinery having the same material as the other frame.

  According to such a joinery, although the other frame and the metal spacer are in contact with each other, since both are made of the same material, it is possible to prevent the occurrence of different metal contact corrosion. Moreover, since not all the spacers are made of resin, but part of them are metal spacers, it is possible to improve the fireproof performance of the joinery.

  ADVANTAGE OF THE INVENTION According to this invention, the fireproof performance of joinery can be improved, preventing the different metal contact corrosion of a spacer.

It is a longitudinal cross-sectional view of the sliding window 1. It is a cross-sectional view of the sliding window 1. It is sectional drawing which showed the structure of the spacer 30 which concerns on 1st embodiment, and its periphery. It is the top view which showed the spacer 30 which concerns on 1st embodiment. It is a 1st explanatory sectional view for explaining a problem of a conventional example. It is a 2nd explanatory sectional view for explaining a problem of a conventional example. It is a 3rd explanatory sectional view for demonstrating the problem of a prior art example. It is a 4th explanatory sectional view for explaining a problem of a conventional example. FIG. 5 is a cross-sectional view showing a state in which a gap is filled by thermal expansion of a new vertical frame 21 after disappearance of a base material side end spacer 32 and a new vertical frame side end spacer 33. It is sectional drawing which showed the structure of the spacer 30 which concerns on 2nd embodiment, and its periphery. It is the top view which showed the spacer 30 which concerns on 2nd embodiment. It is sectional drawing which showed the structure of the spacer 30 which concerns on 3rd embodiment, and its periphery. It is sectional drawing which showed the structure of the spacer 30 which concerns on the modification of 3rd embodiment, and its periphery. It is the top view which showed the spacer 30 which concerns on the modification of 3rd embodiment. It is sectional drawing which showed the structure of the spacer 30 which concerns on 4th embodiment, and its periphery.

=== About the sliding window 1 according to the present embodiment ===
A fitting according to the present embodiment (in this embodiment, the sliding window 1) will be described with reference to FIGS.

  In the following description, when the sliding window 1 attached to a building or the like is viewed from the indoor side, the vertical direction is the vertical direction, the horizontal direction is the horizontal direction, and the indoor / outdoor direction. The depth direction is shown as the prospective direction. Even if it is each part of the sliding window 1 and each member constituting the sliding window 1 is in a single state, it is attached to a building or the like in the vertical direction, the horizontal direction, or the prospective direction. The direction will be specified and described.

  The sliding window 1 is a modified sash, and includes an existing frame body 70 (corresponding to an existing frame), a base material 74, and a refurbishing window unit 10. The window unit for refurbishment 10 is a new unit that is introduced by removing an existing sliding shoji, and has a new frame 20 (corresponding to a new frame), a spacer 30, and a new shoji 60.

  The sliding window 1 according to the present embodiment is repaired as follows. First, the existing sliding shoji is removed from the existing sliding window. Next, the new frame body 20 is installed inside the remaining existing frame body 70 or a member made of a base material 74 attached to the existing frame body 70 (this member is referred to as a reference frame for convenience). At this time, the spacer 30 is inserted into a necessary portion of the gap between the reference frame and the new frame body 20, and the reference frame and the new frame body 20 are fixed with screws as an example of a fixture through the spacer 30. Finally, the new shoji 60 is installed on the new frame 20.

  In this embodiment, since the new frame 20 is installed after the base material 74 is attached to the existing frame 70, the reference frame is the base material 74. However, the new frame body 20 may be installed without attaching the base material 74 (in this case, the reference frame is the existing frame body 70).

  The existing frame body 70 is an existing non-ferrous metal (aluminum alloy) frame body of a sliding window, and includes left and right existing vertical frames 71, an existing upper frame 72, and an existing lower frame 73. And the existing frame 70 forms these 4 frame bodies in the shape of a rectangle, and forms the opening as a whole. The existing vertical frame 71 is a long member extending in the vertical direction, and the existing upper frame 72 and the existing lower frame 73 are long members extending in the left-right direction.

  The base material 74 is a metal auxiliary metal fitting for attaching the new frame body 20 to the existing frame body 70. In the present embodiment, the base material 74 is made of an aluminum alloy, but is not limited thereto, and may be made of steel, for example. The base material 74 is positioned on the inner side of the existing frame body 70 and is screwed onto the existing frame body 70 (specifically, the left and right existing vertical frames 71, the existing upper frame 72, and the existing lower frame 73). Not shown in Fig. 1 and Fig. 2. The existing vertical frame 71 is fixed with reference to Fig. 3). The base material 74 is located between the existing frame body 70 and the new frame body 20.

  The new frame body 20 is a nonferrous metal (aluminum alloy) frame body of the window unit 10 for refurbishment, and includes a left and right new vertical frame 21, a new upper frame 22, and a new lower frame 23. The new frame body 20 is housed in the opening described above, with these four frame bodies framed in a rectangular shape. The new vertical frame 21 is a long member extending in the vertical direction, and the new upper frame 22 and the new lower frame 23 are long members extending in the left-right direction.

  Therefore, as shown in FIG. 2, the newly installed vertical frame 21 is provided inside the existing vertical frame 71 (or the base material 74 screwed to the existing vertical frame 71) in the left-right direction, as shown in FIG. The new upper frame 22 is provided on the inner side (in other words, the lower side) in the vertical direction of the existing upper frame 72 (or the base material 74 screwed to the existing upper frame 72). It is provided on the inner side (in other words, the upper side) of the existing lower frame 73 in the vertical direction. That is, the new frame 20 is provided inside the reference frame.

  The spacer 30 is for adjusting the new frame body 20 (and the new shoji 60 attached to the new frame body 20) to be installed at a desired position. The spacer 30 is a thin plate that is inserted into the gap between the reference frame (in this embodiment, the base material 74) and the new frame 20, and may be short or long. More specifically, the spacer 30 is provided between the base material 74 screwed to the existing vertical frame 71 and the new vertical frame 21 and between the base material 74 screwed to the existing upper frame 72 and the new upper frame. 22, respectively. The spacer 30 will be described in detail later.

  The new shoji 60 is a member accommodated in the opening formed by the new frame 20, and includes an outer shoji 60a and an inner shoji 60b. The new shoji 60 is provided to be slidable with respect to the new frame 20. The new shoji 60 includes a housing 62 and a multi-layer glass 64.

=== Regarding Configuration Example of Spacer 30 and its Periphery According to this Embodiment ===
Next, a configuration example of the spacer 30 according to the present embodiment and the periphery thereof will be described.

  In this section, the spacer 30 positioned between the base material 74 screwed to the existing vertical frame 71 and the new vertical frame 21 and the surrounding configuration will be described. Since the spacer 30 positioned between the base material 74 screwed to the existing upper frame 72 and the new upper frame 22 and the configuration around it are provided with the same configuration, the description thereof is omitted.

  In the following, four configuration examples (first embodiment to fourth embodiment) will be described. The spacer 30 and its peripheral configuration described in FIGS. 1 and 2 correspond to the second embodiment among these embodiments.

<<< Example of Configuration According to First Embodiment >>>
First, a configuration example of the spacer 30 and its surroundings according to the first embodiment will be described with reference to FIGS.

  As described above, the base material 74 is fixed to the existing vertical frame 71 with screws (referred to as base material fixing screws 76) in a state of being located inside the existing vertical frame 71. The base material 74 and the newly provided vertical frame 21 are opposed to each other in the left-right direction. The spacer 30 is inserted between the base material 74 and the newly installed vertical frame 21 (gap) so that the out-of-plane direction of the spacer 30 (in other words, the normal direction) is along the left-right direction. In the present embodiment, three or more (specifically, five) spacers 30 are inserted.

  As shown in FIG. 4, the spacer 30 is a rectangular member and includes a notch 31. The notch 31 is provided so that its longitudinal direction is along the long side direction of the spacer 30. One end of the cutout 31 in the longitudinal direction reaches the short side to form an opening 31a, while the other end does not reach the short side and forms a dead end 31b. And the spacer 30 is provided between the base material 74 and the newly provided vertical frame 21 (gap) so that the long side direction (longitudinal direction of the notch 31) of the spacer 30 may follow a prospective direction.

  Further, the base material 74 and the newly provided vertical frame 21 are fixed by screws (referred to as through screws 36) as an example of a fixing tool via the spacer 30, and the base material 74 and the newly provided vertical frame 21 are secured by the through screws 36. Is restrained. The through screw 36 is attached to the base material 74 and the new vertical frame 21 so that the longitudinal direction thereof is along the direction from the base material 74 toward the new vertical frame 21 (that is, the left-right direction). Further, the through screw 36 fixes the base material 74 and the newly provided vertical frame 21 in a state of passing through the notch 31 described above. The through screw 36 according to the present embodiment is located at the dead end portion 31 b of the notch 31.

  Further, on the indoor side, a cover material 68 (that is, a design material) is provided between the newly installed vertical frame 21 and the existing vertical frame 71. The cover material 68 plays a role of covering the gap between the newly installed vertical frame 21 and the existing vertical frame 71 to make the spacer 30 and the like invisible from the indoor side.

  The cover material 68 also serves as a support member that supports an airtight material 69 that is a resin seal material. That is, the cover material 68 is formed with an airtight material support portion 68a, and the airtight material 69 is supported by the airtight material support portion 68a. The hermetic material 69 is in contact with both the cover material 68 and the existing vertical frame 71.

  Further, the airtight material 69 is provided not only on the indoor side but also on the outdoor side. In other words, the new vertical frame 21 is formed with an airtight material support portion 21a, and the airtight material 69 is supported by the airtight material support portion 21a. The hermetic material 69 is in contact with both the newly installed vertical frame 21 and the existing vertical frame 71.

  Meanwhile, in the sliding window 1 according to the conventional example, a resin spacer is provided as the spacer 30. However, the sliding window 1 has the following problems.

  In other words, since the spacer 30 is made of resin, when a fire occurs, the spacer 30 itself may ignite or fire from the fire source to the spacer 30 may occur. Further, as shown in FIG. 5, the spacer 30 melts and disappears due to the heat of the flame, and a gap (see the arrow shown in FIG. 5) is formed between the base material 74 and the newly installed vertical frame 21. (In addition, as shown in FIG. 5, the airtight material 69 melts and disappears in the event of a fire).

  In addition, such a gap may occur between the newly installed vertical frame 21 and the housing 62 of the newly installed shoji 60. That is, when a fire occurs, thermal expansion occurs in the components of the sliding window 1 due to the heat of the flame, but the degree of thermal expansion of the newly installed vertical frame 21 and the casing 62 may differ depending on the position of the flame. Arise. When the degree of thermal elongation of the new vertical frame 21 is larger than that of the housing 62, the new vertical frame 21 is larger toward the base material 74 than the housing 62 as shown in FIG. It moves, and the clearance gap (refer the arrow shown in FIG. 6) used as the passage of a flame will arise between the newly provided vertical frame 21 and the housing 62. FIG.

  Further, when the spacer 30 disappears and a gap as shown in FIG. 5 is generated between the base material 74 and the new vertical frame 21, the base material 74 and the new vertical frame 21 become relatively easy to move (the movement The degree of freedom increases). When the thermal expansion of the constituent member occurs, the degree of thermal expansion differs from place to place due to the position of the flame or the like (for example, a fire occurs indoors and the indoor side member is more For example, the thermal expansion is larger than that of the outdoor member), and various forms of relative movement occur.

  For example, as shown in FIG. 7, first, a phenomenon in which the newly installed vertical frame 21 moves relative to the base material 74 relative to the outdoor side in the central portion in the vertical direction (ie, the central portion swells more than the upper and lower portions). Vertical warping) occurs. Subsequently, as shown in FIG. 8, a side warp occurs in which the newly formed portion including the newly installed vertical frame 21 and the newly installed shoji 60 swells at the center in the left-right direction. And the clearance gap used as the passage of a flame as shown by the arrow arises.

  As shown in this example, when the spacer 30 disappears, a complex deformation such as warping or twisting may occur in the sliding window 1 due to the increase in the degree of freedom described above. Then, a gap is generated, and the gap becomes a passage for the flame.

  In contrast, in the sliding window 1 according to the present embodiment, as shown in FIG. 3, when three or more spacers 30 are inserted, the three or more spacers 30 are connected to the base material 74. A base material side edge spacer 32 (reference) made of a material that contacts the base material 74 and the adjacent spacer while being sandwiched between adjacent spacers and does not corrode different metals when contacting the base material 74 and the adjacent spacer. Frame side edge spacer), and the new vertical frame 21 and the adjacent spacer in contact with the new vertical frame 21 and the adjacent spacer while being sandwiched between the new vertical frame 21 and the adjacent spacer. New vertical frame side end spacer 33 (corresponding to the new frame side end spacer) made of a material that does not corrode different metals, and between the base material side end spacer 32 and the new vertical frame side end spacer 33 Metal central spacer 34 (in this embodiment, are provided three) includes a, a.

  That is, in the present embodiment, the central portion (intermediate layer) of the three or more spacers 30 (the spacer 30 other than the spacers 30 located at both ends) is made of metal (in the present embodiment, Stainless steel spacer (center spacer 34). On the other hand, the spacers 30 located at both ends are made of a material that does not corrode with different metals due to the material of the member that contacts the spacer 30 on both sides (the base material side end spacer 32, the new vertical frame side end). Part spacer 33).

  In the present embodiment, the members that are in contact with the base material side end spacer 32 are all made of metal (the base material 74 is made of an aluminum alloy, and the adjacent spacer is the central part spacer 34, so it is made of stainless steel). For this reason, the base material side end spacer 32 is made of resin. Similarly, the members in contact with the new vertical frame side end spacer 33 are all made of metal (since the new vertical frame 21 is made of aluminum alloy and the adjacent spacer is the central spacer 34, it is made of stainless steel). The newly installed vertical frame side end spacer 33 is made of resin.

  Thus, in the present embodiment, since the central spacer 34 is made of metal instead of resin, ignition and ignition of the spacer 30 can be appropriately suppressed.

  In addition, it is difficult for the spacer 30 to disappear due to melting, and it is possible to appropriately suppress the occurrence of a gap (gap as indicated by an arrow in FIGS. 5, 6, and 8) that becomes a path for the flame. Become. For example, as in the present embodiment, the spacers 30 other than the center spacer 34 are made of resin, and even if the resin spacer 30 disappears due to melting, if the metal center spacer 34 remains, The gap formed between the base material 74 and the newly installed vertical frame 21 is small compared to the conventional example. Therefore, as shown in FIG. 9, it can be expected that the gap is filled (eliminated) by the thermal extension of the newly installed vertical frame 21.

  On the other hand, the two end spacers located at both ends are made of a material that does not corrode different metals (in this embodiment, a resin spacer). It becomes possible to do.

  Thus, according to the present embodiment, it is possible to improve the fireproof performance of the sliding window 1 while preventing the different metal contact corrosion of the spacer 30.

<<< Examples of Configurations According to Second to Fourth Embodiments >>>
Next, 2nd thru | or 4th embodiment is described using FIG. 10 thru | or FIG. As in the first embodiment, the second to fourth embodiments include a base material side end spacer 32, a new vertical frame side end spacer 33, and a center portion spacer 34. However, the number of restraint points (constraint points) is different from the first embodiment.

  That is, in the first embodiment, as shown in FIG. 3, the reference frame (base material 74) and the new vertical frame 21 are fixed by the through screw 36 via the spacer 30, and the reference frame (base material 74) and the new vertical frame 21 are newly installed. The vertical frame 21 was restrained only by the through screw 36. That is, with respect to the reference frame (base material 74) and the newly installed vertical frame 21 that face each other via the spacer 30, the through screw 36 was the only restraint point.

  On the other hand, in the second to fourth embodiments, for the reference frame (base material 74) and the newly provided vertical frame 21 that are opposed to each other with the spacer 30 therebetween, other constrained portions other than the constrained portion by the through screw 36 are provided. I have.

  As already described, when the spacer 30 disappears and a gap is generated between the base material 74 and the newly installed vertical frame 21, the base material 74 and the existing vertical frame 71 are relatively easily moved (the degree of freedom of movement is large). Become). Then, due to the increase in the degree of freedom, compound deformation such as warping and twisting may occur in the sliding window 1 (see FIGS. 7 and 8). Then, a gap is generated, and the gap becomes a passage for the flame.

In the second to fourth embodiments, in addition to the change of the material of the spacer 30, countermeasures against the occurrence of such a problem are further strengthened. That is, the degree of freedom of movement can be reduced by providing other constraining locations in addition to the constraining location by the through screw 36. Therefore, complex deformation such as warping and twisting is unlikely to occur in the sliding window 1, and it is possible to suppress the generation of a gap that becomes a path for the flame.
Each embodiment will be specifically described below.

<About the second embodiment>
In the sliding window 1 according to the second embodiment, as shown in FIG. 10, the existing vertical frame 71 or the base material 74 (the existing vertical frame 71 in the present embodiment) and the new vertical frame 21 are connected. A connecting bracket 40 is provided. And the restraint location of the base material 74 and the newly provided vertical frame 21 by the said connection metal fitting 40 is said other restraint location (namely, 2nd restraint location). That is, since the newly installed vertical frame 21 is connected to the existing vertical frame 71 by the connecting bracket 40 and the base material 74 is attached to the existing vertical frame 71, the new vertical frame 21 and the base material 74 are restrained.

  The connecting metal fitting 40 is a bending member having an L shape in a cross section. Further, on the indoor side, the connection fitting 40 has one end fixed to the new vertical frame 21 and the other end fixed to the existing vertical frame 71 with screws. In addition, the said connection metal fitting 40 is a member provided in the up-down direction continuously from the upper end part of the newly installed vertical frame 21 (existing vertical frame 71) to a lower end part.

  The material and function of the spacer 30 according to the second embodiment are the same as those of the first embodiment, but the length of the spacer 30 in the prospective direction is the first in terms of securing a space for providing the connection fitting 40. It is shorter than the embodiment (see FIG. 3 and FIG. 10 for comparison). In other words, as is clear by comparing FIG. 4 and FIG. 11, in the second embodiment, the length of the spacer 30 in the longitudinal direction of the notch 31 is shorter than that in the first embodiment. In the second embodiment, unlike the first embodiment, the longitudinal direction of the notch 31 is along the short side direction of the spacer 30.

  According to the second embodiment, the degree of freedom of movement described above can be reduced by attaching the connecting fitting 40. Therefore, complex deformations such as warping and twisting are less likely to occur in the joinery, and it is possible to suppress the generation of gaps that serve as passages for flames. Further, the connecting bracket 40 is provided continuously in the vertical direction from the upper end portion to the lower end portion of the new vertical frame 21 (existing vertical frame 71), so that the space between the new vertical frame 21 and the existing vertical frame 71 is provided. It also plays a role of closing the gap (flame passage).

<About the third embodiment>
In the sliding window 1 according to the third embodiment, as shown in FIG. 12, another fixing different from the through screw 36 that fixes the reference frame (base material 74) and the newly installed vertical frame 21 via the spacer 30 is provided. A tool (in the present embodiment, a screw, referred to as a second through screw 42) is provided. And the restraint location of the base material 74 and the newly provided vertical frame 21 by the second through screw 42 is the other restraint location (that is, the second restraint location).

  That is, the base material 74 and the new vertical frame 21 are fixed by the through screw 36 and the second through screw 42 via the spacer 30, and the base material 74 and the new vertical frame 42 are connected by the through screw 36 and the second through screw 42. 21 is restrained. The penetrating screw 36 and the second penetrating screw 42 are attached to the base material 74 and the new vertical frame 21 so that the longitudinal direction thereof is along the direction from the base material 74 toward the new vertical frame 21 (that is, the left-right direction). ing. Further, the through screw 36 and the second through screw 42 are provided so that the base material 74 and the new vertical frame 21 are fixed in a state in which the above-described notch 31 is penetrated at different locations, and are arranged in the expected direction. It has been.

  According to the third embodiment, the degree of freedom of movement described above can be reduced by attaching the second through screw 42. Therefore, complex deformation such as warping and twisting is unlikely to occur in the sliding window 1, and it is possible to suppress the generation of a gap that becomes a path for the flame.

<Modification of Third Embodiment>
In the modification of the third embodiment, as in the third embodiment, another fixing device (second device) different from the through screw 36 that fixes the reference frame (base material 74) and the newly installed vertical frame 21 via the spacer 30 is used. A through screw 42) is provided, and the restraint location of the base material 74 and the newly provided vertical frame 21 by the second through screw 42 is the other restraint location (that is, the second restraint location).

  However, in the third embodiment, the second through screw 42 penetrates the notch 31 like the through screw 36, whereas in the modified example, as shown in FIGS. While the screw 36 passes through the notch 31, the second through screw 42 passes through the hole 44 provided in the spacer 30.

  That is, the spacer 30 is provided with the notch 31 and the hole 44 so as to be aligned in the long side direction, as shown in FIG. The through screw 36 and the second through screw 42 fix the base material 74 and the newly installed vertical frame 21 with the through screw 36 passing through the notch 31 and the second through screw 42 passing through the hole 44, respectively. They are arranged in line in the prospective direction.

  Also in this modification, the degree of freedom of movement described above can be reduced by attaching the second through screw 42 as in the third embodiment. Therefore, complex deformation such as warping and twisting is unlikely to occur in the sliding window 1, and it is possible to suppress the generation of a gap that becomes a path for the flame.

  Further, when the third embodiment is compared with the modified example, the modified example is different from the configuration in which the second through screw 42 penetrates the hole 44 instead of the notch 31 to the second through screw 42. There is an advantage in that an additional function for preventing the spacer 30 from falling can be provided. That is, in the third embodiment, when complex deformation such as warping or twisting occurs in the sliding window 1, the spacer 30 may fall due to the deformation, but in the modification, thermal deformation is caused. Even if it occurs, it is possible to reliably prevent such a fall.

  On the other hand, since the third embodiment does not require the hole 44 to be formed in the spacer 30, it has an advantage that the mounting process of the spacer 30 during construction is simplified.

<About the fourth embodiment>
As shown in FIG. 15, the sliding window 1 according to the fourth embodiment is provided in each of the existing vertical frame 71 or the base material 74 (the existing vertical frame 71 in the present embodiment) and the new vertical frame 21. The engagement portion 50 is a member that is provided with the engagement portion 50 (in this embodiment, at least one of the existing vertical frame 71 and the new vertical frame 21) is thermally expanded in the event of a fire. And engaging portions 50 that engage with each other. And the restraint location of the base material 74 and the newly provided vertical frame 21 by the said engaging part 50 is said other restraint location (namely, 2nd restraint location). That is, since the engaging part 50 of the new vertical frame 21 and the engaging part 50 of the existing vertical frame 71 are engaged, and the base material 74 is attached to the existing vertical frame 71, the new vertical frame 21 and the base material 74 are It is restrained.

  In the present embodiment, as the engaging portion 50 of the new vertical frame 21, a new vertical frame protrusion 51 (fin portion) that protrudes from the main body of the new vertical frame 21 toward the existing vertical frame 71 (base material 74) in the left-right direction. ). Further, as the engaging portion 50 of the existing vertical frame 71, an existing vertical frame protruding portion 52 that protrudes from the main body of the existing vertical frame 71 in the left-right direction toward the new vertical frame 21 is provided. The new vertical frame protrusion 51 is located on the indoor side (inside) in the prospective direction with respect to the existing vertical frame protrusion 52, and in the state shown in FIG. 15, the new vertical frame protrusion 51 and the existing vertical frame protrusion 52 are provided. Are partially overlapping (overlapping) in the left-right direction.

  That is, FIG. 15 shows an example of a situation when a fire has occurred, unlike FIGS. 10, 12, and 13. In FIG. 15, the resin spacer 30 disappears and the thermal extension of the newly installed vertical frame 21 occurs. Then, when such thermal elongation occurs, the above-described overlap occurs due to the new vertical frame protrusion 51 moving toward the existing vertical frame 71, and the overlap portion becomes the engagement portion 50. (Conversely, the overlap does not occur during normal times before a fire breaks out.) Then, the base material 74 and the newly installed vertical frame 21 are restrained by the engaging portion 50. As described above, “restraint” is a concept that includes not only an example in which restraint is normally performed as in the second embodiment and the third embodiment, but also an example in which restraint is performed only after a fire occurs. .

  According to the fourth embodiment, the degree of freedom of movement described above can be reduced by installing the engaging portion 50, so that complex deformation such as warping and twisting is unlikely to occur in the sliding window 1. For example, when the vertical warp as shown in FIG. 7 is to occur, the newly installed vertical frame protrusion 51 and the existing vertical frame protrusion 52 physically interfere with each other at the overlap portion, and the vertical warp is caused. To prevent the occurrence of For this reason, it is possible to suppress the generation of a gap that becomes a passage of flame.

=== Other Embodiments ===
The above-described embodiments are for facilitating the understanding of the present invention, and are not intended to limit the present invention. The present invention can be modified and improved without departing from the gist thereof, and it goes without saying that the present invention includes equivalents thereof.

  In the above-described embodiment, the sliding window 1 has been described as an example of the window. However, the window is not limited to this, and any window may be used. For example, a sliding window, an opening window, or a FIX window may be used.

  Moreover, in the said embodiment, although demonstrated taking the screw as an example as a fixing tool, it is not limited to this. For example, nails, bolts, rivets and the like may be used.

  In the above embodiment, the spacer 30 is inserted into the gap between the metal reference frame (base material 74) and the new metal frame (new vertical frame 21), and the resin reference frame is used as the spacer 30. The side edge spacer (base material side edge spacer 32), the resin-made new frame side edge spacer (newly installed vertical frame side edge spacer 33), and the metal center spacer 34 were provided. Either the resin reference frame side end spacer (base material side end spacer 32) or the resin new frame side end spacer (new vertical frame side end spacer 33) is used as the metal spacer 34. Such a form may be sufficient. However, the metal spacer 30 has the same material as the frame (reference frame or new frame) in contact with the spacer 30.

  That is, the form is not a sequence of resin → metal → resin, but a sequence of resin → metal or metal → resin. It is the same as the above embodiment in that resin spacers and metal spacers are mixed.

  In other words, the spacer 30 inserted in the gap between the metal reference frame (base material 74) and the new metal frame (new vertical frame 21) is connected to the reference frame (base material 74) and the new frame (new vertical frame). The resin spacer 30 that contacts one of the frames 21) and the metal spacer 30 that contacts the other frame are provided. The metal spacer 30 has the same material as the other frame.

  According to this form, the same effect as the above-mentioned embodiment arises. That is, since the spacers 50 are not entirely made of resin but are partially replaced with metal spacers 30, it is possible to appropriately suppress the firing and ignition of the spacers 30. In addition, it is possible to appropriately suppress the occurrence of a gap (gap as indicated by an arrow in FIGS. 5, 6, and 8) that becomes a path for the flame.

  Further, unlike the above embodiment, the metal reference frame or new frame (that is, the other frame) and the metal spacer 30 are in contact with each other, but both are made of the same material. It is possible to prevent the contact corrosion of dissimilar metals.

  Thus, also in the said form, it becomes possible to improve the fireproof performance of joinery, preventing the different metal contact corrosion of the spacer 30. FIG.

DESCRIPTION OF SYMBOLS 1 Sliding window 20 New frame, 21 New vertical frame 30 Spacer, 31 Notch 32 Base material side edge spacer 33 New vertical frame side edge spacer 34 Center spacer 36 Through screw, 40 Connecting bracket,
42 Second penetration screw, 44 Hole 50 Engagement part, 51 New vertical frame protrusion, 52 Existing vertical frame protrusion 60 New shoji, 62 Housing 70 Existing frame, 71 Existing vertical frame, 74 Base material

Claims (8)

A reference frame made of an existing frame or a base material attached to the existing frame;
A new frame provided inside the reference frame;
A spacer inserted in a gap between the reference frame and the new frame,
The spacer is
A reference frame side end spacer made of a material that is in contact with the reference frame and the adjacent spacer in a state sandwiched between the reference frame and the adjacent spacer and does not corrode different metals when contacting the reference frame and the adjacent spacer; ,
A new frame side end spacer made of a material that does not corrode different metals when contacting the new frame and the adjacent spacer, in contact with the new frame and the adjacent spacer in a state sandwiched between the new frame and the adjacent spacer; ,
A joinery comprising a metal central spacer positioned between the reference frame side end spacer and the new frame side end spacer. The joinery according to claim 1,
Having a fixture for fixing the reference frame and the new frame through the spacer;
A joinery comprising other restraint locations in addition to the restraint locations of the reference frame and the new frame by the fixture. The joinery according to claim 2,
A connecting bracket for connecting the existing frame or the base material and the new frame;
The other restraint place is a join place of the reference frame and the newly installed frame by the connecting metal fitting. The joinery according to claim 2,
There is another fixture different from the fixture that fixes the reference frame and the new frame via the spacer,
The other restraint location is a restraint location between the reference frame and the new frame by the other fixture. The joinery according to claim 4,
The spacer has a notch;
The said fixture and the said other fixture have penetrated the said notch, The fitting characterized by the above-mentioned. The joinery according to claim 4,
The spacer includes a notch and a hole,
The fixture passes through the notch;
The other fixture is penetrating through the hole. The joinery according to claim 2,
Engagement portions provided on the existing frame or the base material and the new frame, respectively, which engage with each other when the members provided with the engagement portions are thermally expanded in the event of a fire With
The other restraint place is a join place between the reference frame and the new frame by the engaging portion. A metal reference frame made of an existing frame or a base material attached to the existing frame; and
A new metal frame provided inside the reference frame;
A spacer inserted in a gap between the reference frame and the new frame,
The spacer includes a resin spacer that contacts one of the reference frame and the new frame, and a metal spacer that contacts the other frame,
The metal spacer has the same material as that of the other frame.

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