JP2018031259A - Composite fittings - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide composite fittings, made of metal and resin, that have high heat insulation properties and moisture condensation resistance by suppressing indoor and outdoor heat conduction more.SOLUTION: A longitudinal slide window 1 has a sliding door 3, provided with a metallic doorframe and a resin doorframe, housed in a frame body 2 provided with a metallic frame and a resin frame. A metallic upper frame 8 of the frame body 2 is divided into an outer metallic upper frame 8a and an inner metallic upper frame 8b, which are coupled together through a bridge material 37. A resin upper frame 13 provided at a position opposed to the bridge material 37 has a plurality of air chambers 39a of different sizes formed in vertical and right-left directions with a lattice-shaped part 40 of resin. The lattice-shaped part 40 is provided with a plurality of projection parts 40a on the side of the bridge material 37, and also provided with a plurality of air chambers 42 in a recessed shape opposite the metallic upper frame 8. The sliding door 2 is so constituted that upper and lower, and right and left doorframes mounted with a glass body 31 constitute a hidden doorframe overlapping with the right and left resin vertical frames, and the resin upper frame 13 and a resin lower frame 14 on an indoor side thereof.SELECTED DRAWING: Figure 1

Description

  TECHNICAL FIELD The present invention relates to various composite fittings such as a composite type squeezed window, a door, and a sliding shoji provided with a frame having a metal frame and a resin frame and a shoji having a metal cage and a resin cage.

2. Description of the Related Art Conventionally, as a composite fitting including a frame body in which a metal such as aluminum and a resin are joined and a shoji, a composite extended window described in Patent Document 1 has been proposed. In this horizontal type composite window, a metal frame is formed on the outdoor side of the window frame forming the opening, and a resin frame is formed on the indoor side. And the shoji attached to a window frame so that opening and closing is possible, the metal cage | basket is formed in the outdoor side, and the resin cage | basket is formed in the indoor side. This shoji has multi-layer glass fitted in a box that is assembled into a quadrangle by upper and lower ridges and left and right vertical folds.
In such an open window or the like, the heat insulation is improved by covering the metal frame with a resin frame when viewed from the indoor side, and the aesthetics are improved by preventing the metal such as aluminum from being seen from the room.

  Moreover, in the composite sliding window described in Patent Document 2, the upper and lower frames and the left and right vertical frames of a frame framed in a quadrangle that houses a shoji are connected to the outdoor metal frame portion and the indoor metal frame. Each was divided into parts, and these were connected and arranged via a resin bridge material. As a result, the outdoor metal frame part and the indoor metal frame part are thermally insulated by the bridge material, the heat transfer between the indoor and the outdoor by the metal frame is blocked by the bridge material, and the heat insulation inside and outside is set high. Yes.

JP 2002-194938 A JP 2012-31590 A

However, for example, as shown in the cross-sectional views of the upper portion of the window shown in FIGS. 5 and 6, when the bridge material is not provided in the composite type window 100 described above, the metal upper frame 102 such as an aluminum material of the frame body 101 is formed. If it is installed to extend from the outdoor side to the indoor side, the metal upper frame 102 transmits the outdoor cool air to the indoor side, and the surface temperature of the resin frame 103 exposed to the indoor side may be lowered to cause dew condensation. there were. 5-8, the arrow has shown the moving direction of heat.
Further, like the composite type window 100 shown in FIG. 7, the indoor side portion of the shoji 104 is configured by the resin frame 103 in order to prevent the metal frame 102 from transmitting cold air from the outdoor side to the indoor side. However, heat transfer often occurs from the outdoor side to the indoor side through the heel portion of the shoji 104, and there is a disadvantage that the indoor side exposed surface of the resin frame 103 is cooled to cause condensation. In this case, there is a risk of warping and the quality may become unstable.

On the other hand, as shown in FIG. 8, in a window 100 formed only of metal, a resin-made bridge member 106 is provided in a frame 101, and an outdoor metal frame 102a and an indoor metal frame 102b of a metal upper frame are provided. Are separated and connected via the bridge member 106, heat transfer such as cold air of the metal upper frame is blocked by the bridge member 106. In this case, heat transfer occurs in the space region outside the bridge member 106, and the phenomenon that the indoor metal frame 102b is cooled by the movement of the low-temperature air occurs, or the heat transfer is performed by the heat transfer in the space region inside and outside the room. Sometimes dropped.
Therefore, it is possible to obtain sufficient heat insulation simply by separating and arranging the outdoor metal frame portion 102a and the indoor metal frame portion 102b through the resin bridge member 106 and suppressing the heat transfer of the metal frame 102. There wasn't. And especially in cold districts, joinery is required to have high heat insulation properties, but composite joinery with such high heat insulation properties has not been provided for metal and resin composite joinery.

  The present invention has been made in view of such a problem, and in a composite joinery made of a metal and a resin, it is possible to further suppress heat conduction indoors and outdoors and obtain high heat insulation and dew proofing. It aims at providing the composite joinery made.

  The composite joinery according to the present invention includes an opening frame provided with a metal frame formed on the outdoor side and a resin frame formed on the indoor side, a metal fence that can be attached to the opening frame and formed on the outdoor side, and the indoor side. The resin frame of the opening frame body is divided into at least one of the resin upper frame and the resin lower frame by a resin in one or both of the vertical direction and the horizontal direction. A first air chamber is formed, and the resin frame has an outdoor side end surface facing the indoor side end surface of the resin bowl, a second packing protruding in a direction along the outdoor side end surface, and an outdoor side from the outdoor side end surface A first air layer comprising a projecting piece projecting to the outside and forming the first air layer on the outdoor side of the first air chamber in the resin frame.

  According to the present invention, since the plurality of first air chambers partitioned by the resin in one or both of the up and down direction and the left and right direction are formed in the resin frame of the opening frame body, by arranging the plurality of air chambers, It is possible to improve heat insulation by reducing heat transfer between the indoor side and the dew-proofing property on the indoor side exposed surface.

Moreover, it is preferable that the protruding piece provided on the resin lower frame is a first packing, and the protruding piece provided on the resin upper frame is a rib.

  The metal frame is preferably divided into an outer metal frame and an inner metal frame, and the outer metal frame and the inner metal frame are preferably connected via a resin bridge member.

  By connecting the outer metal frame and the inner metal frame of the metal frame via a resin bridge material, the heat transfer between the outdoor side and the indoor side can be reduced by the bridge material, and the heat insulation can be improved. In addition, the dew-proofing property on the exposed surface of the resin frame on the indoor side can be improved.

Also, a plurality of protrusions are provided on at least one of the first air chamber, the resin upper frame, and the resin lower frame at a position facing at least one of the outer metal frame, the bridge member, and the inner metal frame of the metal frame. It is preferable to provide a recessed second air chamber formed by
According to the present invention, the heat transfer between the outer metal frame and the inner metal frame of the metal frame can be interrupted by the bridge material to reduce the heat transfer, and at least the outer metal frame, the bridge material, and the inner metal frame. By providing a plurality of first air chambers partitioned in one or both of the vertical direction and the left and right direction, and a concave second air chamber at a position facing either, in a region outside the metal frame Since heat transfer can be cut off and heat transfer is reduced, the heat insulation can be improved by the metal frame and the resin frame.

  Moreover, it is preferable that the resin frame is provided with a concealed ridge structure formed by forming a plurality of first air chambers that overlap with the metal ridge and the resin ridge of the shoji.

  According to the present invention, by adopting a concealed scissor structure, a conventional concealed concealment in which a mere frame is overlapped by overlapping a metal scissor of a shoji and a resin scissors on a plurality of first air chambers of the resin frame of the frame. The heat insulating property of the shoji can be further enhanced than the bag.

Further, the projection provided on the resin frame is provided at a position facing the bridge member so as to separate the outdoor side from the indoor side.
Thereby, since the second air chamber can be divided into the outdoor side and the indoor side by the protrusion and the bridge member, the movement of air, for example, the movement of cold air, can be reduced between the outdoor side and the indoor side.

  According to the composite joinery of the present invention, the resin frame of the opening frame body is provided with a plurality of first air chambers in at least one of the upper and lower directions and the left and right directions in at least one of the resin upper frame and the resin lower frame. By the plurality of first air chambers formed in the above, heat transfer between the outdoors and the indoors can be reduced, and the heat insulation performance and dew proofing can be improved.

It is a principal part longitudinal cross-sectional view of the vertical extension window by embodiment of this invention. It is a principal part horizontal sectional view of the vertical extension window shown in FIG. FIG. 3 is an enlarged cross-sectional view of a lower frame portion of the vertical extension window shown in FIG. 1. FIG. 2 is an enlarged cross-sectional view of an upper frame portion of a vertical extending window shown in FIG. 1. It is a principal part longitudinal cross-sectional view of one composite type window which is not provided with the bridge | bridging material in a prior art example. It is a principal part longitudinal cross-sectional view of the other composite type window which is not provided with the bridge | bridging material in a prior art example. It is a principal part longitudinal cross-sectional view of the further another composite type window which is not provided with the bridge | bridging material in a prior art example. It is a principal part longitudinal cross-sectional view of the composite type window provided with the bridge | bridging material in a prior art example.

Hereinafter, a vertical extending window as an example of a composite joinery according to an embodiment of the present invention will be described with reference to FIGS. 1 to 4.
1 and FIG. 2, the vertical window 1 rotates a shoji 3 housed in a frame 2 attached to a building opening formed in the building frame around the vertical shaft on the suspension side. It can be opened to the outside. The vertical extending window 1 is a composite type made of a metal such as aluminum and a resin, and is provided with a composite frame 2 having a rectangular frame shape and a composite type shoji 3 housed in the frame 2 so as to be opened and closed. Has been.

The frame 2 forms an opening frame composed of a metal frame 4 made of aluminum alloy or the like provided on the outdoor side and a resin frame 5 made of synthetic resin provided on the indoor side. The metal frame 4 is formed of left and right metal vertical frames 6 and 7, a metal upper frame 8, and a metal lower frame 9. The resin frame 5 includes left and right resin vertical frames 11 and 12 formed on the indoor side of the left and right metal vertical frames 6 and 7, a resin upper frame 13 formed on the indoor side of the metal upper frame 8, and a metal lower frame 9. It is comprised with the resin lower frame 14 formed inside.
Further, caps 22a and 22b to be attached to the screen door rails are mounted on the inner surfaces of the resin upper frame 13 and the resin lower frame 14 facing each other, and an air layer 45 is formed on the caps 22a and 22b.

  Moreover, the shoji 3 is comprised by the metal cage | basket 16 which consists of metals, such as an aluminum alloy provided in the outdoor side, and the resin-made resin cage | baskets 17 provided in the indoor side. The metal rod 16 is formed of left and right metal vertical rods 18 and 19, a metal upper rod 20 and a metal lower rod 21. The resin rod 17 includes left and right resin vertical rods 23 and 24 formed on the indoor side of the left and right metal vertical rods 18 and 19, a resin upper rod 25 formed on the indoor side of the metal upper rod 20, and the metal lower rod 21. It is comprised with the resin lower collar 26 formed inside. A glass body 31 made of, for example, double-layer glass is fitted inside the metal cage 16 and the resin cage 17 that are framed in a quadrilateral shape of the shoji 3.

  The shoji 3 of the vertical window 1 is placed in a closed state by contacting the left and right resin vertical frames 11, 12, the resin upper frame 13, and the resin lower frame 14 of the frame 2, and only on the outdoor side. It can be opened. Further, in the shoji 3, a gremon handle 34 is provided as a main lock at the longitudinal center of the metal vertical rod 18 on the door tip side, and the gremon handle 34 is provided on the metal upper frame 8 and the metal lower frame 9 on the door tip side. A receiving portion that can be engaged with the locking component is provided (not shown). A sub-block 36 is installed on the prospective surface of the lower part of the resin vertical rod 23.

  Further, in the lower frame portion of the frame body 2 shown in FIG. 3, a fitting recess 30 is formed on the outdoor side end surface 14 a of the resin lower frame 14 of the frame body 2, and the first packing 32 </ b> A is formed in the fitting recess 30. One end is fitted and the other end protrudes to the outdoor side. The first packing 32A has, for example, a substantially U shape, and a locking portion such as a protrusion for locking the tip of the first packing 32A may be provided on the end surface 26a of the resin lower collar 26. Further, a second packing 33A is formed so as to protrude further below the first packing 32A on the outdoor side end surface 14a of the resin lower frame 14, and in the example shown in the drawing, the second packing 33A is substantially downward. It has a bent or curved shape.

  In the closed state in which the shoji 3 is housed in the frame 2, the tip of the first packing 32A is in contact with the indoor side end face 26a of the resin lower rod 26 of the shoji 3, and the tip of the second packing 33A is the end face. 26a (see FIG. 3) or slightly spaced (see FIG. 1). In this case, the first packing 32 is strongly pressed against the end surface 26a of the resin lower collar 26, and the second packing 33A is set to be relatively lightly abutted against the end surface 26a of the resin lower collar 26 or separated at a minute interval. All of them are almost closed.

  Thus, an air layer 35A that forms a sealed space is formed by the resin lower frame 14, the resin lower collar 26, and the first and second packings 32A and 33A of the frame 2 in a longitudinal sectional view. The air layer 35A can insulate the frame 2 and the shoji 3 from heat, prevent heat such as outdoor cold air from being transmitted to the indoor side, and improve heat insulation and dew proofing. In addition, in the state in which the shoji 3 is closed to the frame 2, the resin lower rod 26 of the shoji 3 comes into contact with the first and second packings 32A and 33A, so that airtightness can be secured and the opening / closing operation of the shoji 3 is affected. Don't give.

Further, the heat insulating air layer is formed not only between the resin lower frame 14 and the resin lower collar 26 but also between the resin upper frame 13 and the resin upper collar 25 as shown in FIG. In this case, the rib 32B is formed below the outdoor side end face 13a of the resin upper frame 13, and the packing 33B is formed above the rib 32B at an interval. Therefore, an air layer 35B in a sealed space is formed by the outdoor side end face 13a of the resin upper frame 13, the rib 32B, and the packing 33B.
Similarly, the first packing 32C and 32D are respectively formed on the outdoor side end faces 11a and 12a of the left and right resin vertical frames 11 and 12, and the second packings 33C and 33D are formed at intervals inside thereof. The left and right resin vertical frames 11, 12 and the end surfaces 11a, 12a, 23a, 24a of the resin vertical rods 23, 24, and the first and second packings 32C, 32D, 33C, 33D, the air layer 35C in the sealed space, 35D is formed.

The first packing 32C, 32D, the second packing 33C, 33D, and the air layers 35C, 35D in the sealed space have the same configuration as the first packing 32A, the second packing 33A, and the air layer 35A described above. The air layer 35B can adopt the same configuration.
Therefore, the air layers 35 </ b> A to 35 </ b> D in the sealed space are formed in a frame shape forming each side of the quadrangle between the quadrangular frame-shaped resin frame 5 of the frame body 2 and the quadrangular frame-shaped resin rod 17 of the shoji 3.

  In the figure, each of the first packings 32A, 32C, 32D described above is formed in a substantially U shape, and the second packings 33A, 33C, 33D are formed in a substantially U shape or a J shape. The first and second packings can adopt any shape. In the closed state of the shoji 3 with respect to the frame 2, the first packing 32A, 32C, 32D strongly abuts against the resin cage 17, and the second packing 33A, 33C, 33D is weakly abutted against the resin cage 17 or spaced apart at a small interval. It only has to be. The first packing 32A, 32C, 32D, the second packing 33A, 33C, 33D, and the packing 33B are made of a synthetic resin such as PVC (polyvinyl chloride) or an elastic material such as rubber.

Next, in the upper frame part of the frame 2 shown in FIG. 4, the metal upper frame 8 of the metal frame 4 is separated from the outer metal upper frame 8a on the outdoor side and the inner metal upper frame 8b on the indoor side on the upper side. Moreover, they are connected with a resin bridge member 37 interposed therebetween. Therefore, heat such as outdoor low temperature transmitted to the outer metal upper frame 8a is blocked by the bridge member 37 and is not transmitted to the inner metal upper frame 8b. The bridge member 37 may have any shape, but is formed to have a wide width so that heat is not transferred between the outer metal upper frame 8a and the inner metal upper frame 8b.
In the example shown in FIG. 4, the bridge member 37 has a substantially polygonal frame shape having a hollow portion 37a inside, for example, a hexagonal cross-sectional frame shape, and ends of the outer metal upper frame 8a and the inner metal upper frame 8b at both ends thereof. Convex parts 37b and 37c which fit into concave parts 38a and 38b formed in the part. Also, the outer metal lower frame 9a on the outdoor side and the inner metal lower frame 9b on the indoor side are separated from each other and connected with the bridge member 15 made of resin interposed between the metal lower frame 9 shown in FIG. The metal frames separated from the bridge members 37 and 15 are not provided in the left and right vertical frames, but may be provided. Further, the lattice-like portion 40 in which the plurality of air chambers 39 a are formed may be provided also on the left and right vertical frames of the frame body 2.

  Moreover, the resin upper frame 13 formed on the indoor side of the inner metal upper frame 8b forms a lattice-like portion 40 that partitions the air chambers 39a (first air chambers) having a plurality of square cross sections that are different in size, and is partitioned by the resin. The plurality of air chambers 39a thus formed constitute a heat-insulating sealed space. The lattice-shaped portion 40 of the resin upper frame 13 is formed in a region facing at least one of the outer metal upper frame 8a, the bridge member 37, and the inner metal upper frame 8b on the indoor side, and here, the shoji 3 Rather than the indoor side. In particular, by installing the air chamber 39a at a position facing the bridge member 37, the heat transfer heat insulation is further enhanced.

  The air chambers 39a partitioned by the lattice-like portion 40 are formed in various sizes, but the air chambers 39a may be arranged in the vertical and horizontal directions in the same size. The portions 40 are formed in a lattice shape having the same dimensions. In addition, the lattice-like portions 40 are configured so that the air chambers 39a are arranged in the vertical and horizontal directions, but may be formed only in the vertical direction or in the horizontal direction. Even in these cases, the heat insulation can be enhanced by the plurality of air chambers 39a. Thus, in the space between the shoji 3 and the outer metal upper frame 8a of the metal upper frame 8, the bridge member 37, and the inner metal upper frame 8b, a plurality of air chambers 39a partitioned by the lattice portion 40 are installed. Therefore, it is possible to reduce the transfer of heat through this space.

Further, the lattice-like portion 40 of the resin upper frame 13 is formed by projecting a plurality of protrusions 40a protruding above the air chamber 39a on the surface facing the outer metal upper frame 8a, the bridge member 37 and the inner metal upper frame 8b. The air chamber 42 (second air chamber) capable of storing air in the recesses between the outer metal upper frame 8a, the bridge member 37, the inner metal upper frame 8b, and the plurality of protrusions 40a of the lattice-shaped portion 40. Is formed. The protrusion 40a of the air chamber 42 may have a gap between the outer metal upper frame 8a, the bridge member 37, and the inner metal upper frame 8b, or may be sealed.
Also by the air chamber 42, the plurality of protrusions 40a are arranged at predetermined intervals in a region facing the outer metal upper frame 8a, the bridge member 37, or the inner metal upper frame 8b, so that heat is generated between the outdoors and the indoors. It is possible to suppress the movement of the material and improve the heat insulation performance.
In particular, one or more (two in the figure) protrusions 40a are provided at positions facing the bridge member 37, and these protrusions 40a make the air chamber 42 an outdoor air chamber 42 and an indoor air chamber 42. It is divided into. As a result, a plurality of air chambers 42 are formed between the bridge member 37 that blocks the movement of heat and the protrusions 40a, so that the movement of air can be suppressed between the outdoor side and the indoor side. Moving to the indoor side can be suppressed.
Furthermore, as described above, the air layer 35B is also formed on the outdoor side of the lattice-like portion 40 of the resin upper frame 13, and this also suppresses the movement of heat indoors and outdoors, so that the heat insulation is improved. . Further, the lattice portion 40 and the plurality of air chambers 39 b are also formed on the resin upper collar 25 and the resin lower collar 26.

Further, in the present embodiment, the lattice-like portion 40 including the large and small air chambers 39 a described above is also formed on the resin lower frame 14. The lattice-shaped portion 40 of the resin lower frame 14 is formed by projecting a plurality of protrusions 40b protruding below the air chamber 39a on the surface facing the outer metal lower frame 9a, the bridge member 15 and the inner metal lower frame 9b. An air chamber 44 (second air chamber) capable of storing air is provided in the recesses between the outer metal lower frame 9a, the bridge member 15 and the inner metal lower frame 9b, and the plurality of protrusions 40b of the lattice-shaped portion 40. Is formed. The protrusion 40b of the air chamber 44 may have a gap between the outer metal lower frame 9a, the bridge member 15, and the inner metal lower frame 9b, or may be sealed.
Also with this air chamber 44, heat is transferred between the outdoors and indoors by arranging a plurality of protrusions 40b at predetermined intervals in a region facing the outer metal lower frame 9a, the bridge member 15 or the inner metal lower frame 9b. It is possible to further improve the heat insulation performance.
Further, the protrusion 40 b is provided at a position facing the bridge member 15, thereby dividing the air chamber 44 into an outdoor air chamber 44 and an indoor air chamber 44 by the protrusion 40 b. As a result, a plurality of air chambers 44 are formed between the bridge member 15 that blocks the movement of heat and the protrusions 40b, and air movement can be reduced between the outdoor side and the indoor side, for example, from the outdoor side to the indoor side. The movement of cold air can be suppressed.

  Further, as shown in FIG. 1, the upper saddle (metal upper cage 20 and resin upper cage 25) and lower cage (metal lower cage 21 and resin lower cage 26) are placed on the frame 2 on the indoor side. It has a structure hidden behind a frame (metal upper frame 8 and resin upper frame 13) and a lower frame (metal lower frame 9 and resin lower frame 14). Similarly, as shown in FIG. 2, the vertical fence (metal vertical fence 18 and resin vertical fence 23) on the door end side of the shoji 3 and the vertical fence (metal vertical fence 19 and resin vertical fence 24) on the hanging side are: On the indoor side, the frame 2 has a configuration hidden behind the vertical frame (metal vertical frame 6 and resin vertical frame 11) on the door end side and the vertical frame (metal vertical frame 7 and resin vertical frame 12) on the hanging side. ing. Therefore, the shoji 3 of the vertical window 1 according to the present embodiment constitutes a hidden fence in which the upper, lower, left, and right eyelids are hidden indoors by the frame 2. Therefore, the movement of heat is reduced by the frame 2 in the upper, lower, left and right folds of the shoji 3.

The vertical window 1 according to the present embodiment has the above-described configuration, and the operation thereof will be described next. As shown in FIGS. 1 and 2, the main lock gremon handle 34 provided on the metal vertical rod 18 on the door-end side with the shoji 3 placed in the frame 2 is operated in the vertical window 1 according to the present embodiment. Thus, the lock portion is engaged with the receiving portion. In this state, even when the outdoor temperature is low, the glass body 31 of the shoji 3 has a high heat insulating property and cold air because a plurality of (three in FIG. 3) laminated glass are arranged with an air layer in between. It is difficult for the heat to move from the outside to the indoor side.
Further, the left and right vertical fences and the upper and lower fences of the shoji 3 are hidden fences that overlap the left and right vertical frames and the upper and lower frames of the frame 2 as viewed from the indoor side.

  In addition, in FIGS. 3 and 4, the upper and lower frames of the frame body 2 are respectively arranged with upper and lower and left and right air chambers 39 a partitioned by a lattice-like portion 40 on the resin upper frame 13 and the resin lower frame 14. ing. Further, an air layer 35A is installed between the resin lower rod 26 and the resin lower frame 14, and an air layer 35B is also installed on the outdoor side of the resin upper frame 13. Therefore, heat transfer such as cold air that can move through the upper and lower side of the shoji 3 is reduced by the plurality of air chambers 39 and the air layers 35A and 35B, respectively, and the heat insulation performance can be improved.

In addition, a resin vertical frame 11 on the door end side and a resin vertical frame 12 on the hanging side are disposed on the left and right vertical fence portions of the shoji 3, and further, the resin vertical frames 23 and 24 and the resin vertical frames 11 and 12 are provided. Since the air layers 35C and 35D are respectively installed between the two, the heat transfer to the indoor side of the cold air passing through the left and right side of the shoji 3 is prevented, and the heat insulation performance can be improved.
1 and 3, a lattice-like portion 40 of the resin lower frame 14 is installed on the indoor side of the metal lower frame 9 of the frame body 2, and is formed by a plurality of large and small air chambers 39 a formed by the lattice-like portion 40. It is insulated and heat transfer from the outdoor side of the frame 2 to the indoor side can be reduced.
Further, in the lower frame portion of the frame body 2, the outer metal lower frame 9 a and the inner metal lower frame 9 b in the metal lower frame 9 are separated by the bridge member 15, so that they are transmitted to the outer metal upper frame 9 a. Heat such as outdoor cold air is divided by the bridge member 15 and is not transmitted to the inner metal lower frame 9b. Moreover, the lattice-like portion 40 of the resin lower frame 14 is installed at a position facing the bridge member 15, the outer metal lower frame 9 a and the inner metal lower frame 9 b, and is insulated by a plurality of large and small air chambers 39 a formed by the lattice-like portion 40. Therefore, it is possible to reduce the heat transfer of cold air or the like from the outdoor side to the indoor side.
Further, a concave air chamber 44 is also disposed between the bridge member 15, the outer metal lower frame 9 a and the inner metal lower frame 9 b, and the protrusions 40 b of the lattice-like part 40, and is partitioned by the protrusions 40 b. The air chamber 44 can reduce heat transfer from the outdoor side to the indoor side.

  1 and 4, in the upper frame portion of the frame body 2, the outer metal upper frame 8a and the inner metal upper frame 8b in the metal upper frame 8 are separated by the bridge member 37. Heat such as outdoor cold air transmitted to the upper frame 8a is divided by the bridge member 37 and is not transmitted to the inner metal upper frame 8b. Moreover, the lattice-like portion 40 of the resin upper frame 13 is installed at a position facing the bridge member 37, the outer metal upper frame 8a, and the inner metal upper frame 8b, and is insulated by a plurality of large and small air chambers 39a formed by the lattice-like portion 40. Therefore, it is possible to reduce the heat transfer of cold air or the like from the outdoor side to the indoor side.

  Further, a recessed air chamber 42 is also disposed between the bridge member 37, the outer metal upper frame 8a and the inner metal upper frame 8b, and the protrusions 40a of the lattice-like part 40, and is partitioned by the protrusions 40a. Heat transfer from the outdoor side to the indoor side by the air chamber 42 can be reduced.

As described above, according to the vertical extending window 1 according to the present embodiment, the bridge members 37 and 15 are installed between the outer metal upper and lower frames 8a and 9a and the inner metal upper and lower frames 8b and 9b, and the metal upper and lower frames 8, 9 is provided with a plurality of air chambers 39a partitioned by a lattice-like portion 40 on the resin upper frame 13 and the resin lower frame 14 provided on the indoor side of the metal upper frame 8 and the metal lower frame 9, respectively. Even in a space region close to the metal upper frame 8 and the metal lower frame 9, heat transfer from the outdoor side to the indoor side can be reduced.
Further, in the upper and lower frames of the frame body 2, a plurality of protrusions 40 a and 40 b are provided between the outer metal upper and lower frames 8 a and 9 a, the bridge members 37 and 15, and the lattice-shaped portion 40 facing the inner metal upper and lower frames 8 b and 9 b. Since the plurality of formed concave air chambers 42 and 44 are provided, it is possible to further reduce the heat transfer of cold air from the outdoor side to the indoor side and the heat transfer of warm air from the indoor side to the outdoor side.

  Moreover, when viewed from the indoor side of the vertical window 1, the left and right resin vertical rods 23, 24, the resin upper rod 25 and the resin lower rod 26 of the shoji 3 are hidden inside the left and right vertical frames and the upper and lower frames of the frame 2. Further, air is formed between the left and right resin vertical rods 23 and 24 and the resin upper and lower rods 25 and 26 of the shoji 3 and the left and right resin vertical frames 11 and 12 and the resin upper and lower frames 13 and 14 of the frame 2. Since the layers 35A to 35D are respectively provided, heat transfer such as cold air from the outdoor side to the indoor side and warm air transfer from the indoor side to the outdoor side can be reduced, and heat transfer between the outdoor side and the indoor side can be reduced. Can be reduced.

Therefore, in the frame 2 and the shoji 3 of the vertical window 1, the heat insulation between the outdoors and the indoors and the dew proofing of the exposed surface on the indoor side can be greatly improved.
In particular, composite furniture such as various windows and doors, including a vertical vertical window 1 made of a metal such as aluminum and a resin, is not used in cold districts and the like, and high heat insulation is required. However, in the composite joinery such as the vertical window 1 according to the present embodiment, heat transfer inside and outside is sufficiently suppressed, and high heat insulation and dew proofing properties equivalent to those of resin joinery etc. can be exhibited. Can be used effectively even in cold regions.

The composite joinery according to the present invention is not limited to the vertical extending window 1 according to the above-described embodiment, and can be appropriately changed or replaced without departing from the gist of the present invention.
Hereinafter, modifications of the present invention will be described, but the same or similar components or members described in the above-described embodiment will be described using the same reference numerals.

  For example, in the embodiment described above, (1) the outer metal upper and lower frames 8a and 9a divided by the bridge members 37 and 15 and the inner metal upper and lower frames 8b and 9b are connected to the metal upper and lower frames 8 and 9 of the frame body 2, (2) A plurality of air chambers 39a and 39b further partitioned by the lattice-like portion 40, and (3) the bridge members 37 and 15, the outer metal upper and lower frames 8a and 9a or the inner metal upper and lower frames 8b and 9b and the lattice-like portion 40. All three sets of the concave air chambers 42 and 44 provided between the two are provided, but the present invention is not limited to such a configuration.

  For example, (2) only a plurality of air chambers 39a and 39b partitioned by the grid portion 40 may be provided, or (3) a resin upper and lower frame facing the metal upper and lower frames 8 and 9 without the bridge members 37 and 15. Protruding portions 40 a and 40 b may be provided on 13 and 14, and only the recessed air chambers 42 and 44 may be provided between the metal upper and lower frames 8 and 9. Alternatively, a combination of (1) and (2), a combination of (1) and (3), or a combination of (2) and (3) may be provided.

  In the above-described embodiment, the first packing 32A to 32D and the second packing 33A to 33D are used for heat insulation between the resin frame on the four sides of the frame 2 and the shoji 3 and the resin frame and the resin basket. Although the layers 35 </ b> A to 35 </ b> D are formed, it is not always necessary to form an air layer on all sides, and may be formed only on a part of the sides. In that case, it is preferable to form an air layer 35 </ b> A between the lower resin lower frame 14 and the lower resin lid 26, which is easy to transmit cold air from the ground and has a relatively low temperature.

  Further, when the air layers 35A to 35D are formed by the first packing 32A, 32C, 32D and the second packings 33A, 33C, 33D, and the packing 33B, the first packing is used instead of the configuration in which one air layer 35A to 35D is provided. 32A, 32C, 32D or / and the second packing 33A, 33C, 33D, packing 33B may be formed into a shape having an air layer composed of a hollow portion, so that two to three air layers may be formed. In this case, the heat insulation is further improved.

  Moreover, although the composite joinery provided with the metal and the resin according to the present invention is used for the vertical extension window 1 as an embodiment, it is not limited to this, and the horizontal extension window, the sliding window, the sliding door, etc. Needless to say, it can be used in composite joinery such as various windows and doors.

DESCRIPTION OF SYMBOLS 1 Vertical extension window 2 Frame 3 Shoji 4 Metal frame 5 Resin frame 6, 7 Metal vertical frame 8 Metal upper frame 8a Outer metal upper frame 8b Inner metal upper frame 9 Metal lower frame 13 Resin upper frames 13a, 14a Outdoor side end surface ,End face
14 Resin lower frame 15, 37 Bridge member 16 Metal rod 17 Resin rod 18, 19 Metal vertical rod 23, 24 Resin vertical rod 25 Resin upper rod 26 Resin lower rod 25 a, 26 a Indoor side end face, end face 31 Glass bodies 32 A, 32 B, 32C, 32D First packing 33A, 33B, 33C, 33D Second packing 35A, 35B, 35C, 35D Air layers 39a, 39b Air chamber (first air chamber)
40 Lattice-like portions 40a, 40b Protruding portions 42, 44 Air chamber (second air chamber)

Claims (6)

An open frame body comprising a metal frame formed on the outdoor side and a resin frame formed on the indoor side;
A shoji equipped with a metal cage that can be attached to the opening frame and formed on the outdoor side and a resin cage formed on the indoor side,
The resin frame of the opening frame body forms a plurality of first air chambers partitioned by resin in one or both of the vertical direction and the horizontal direction in at least one of the resin upper frame and the resin lower frame,
The resin frame includes an outdoor side end surface facing the indoor side end surface of the resin bowl, a second packing protruding in a direction along the outdoor side end surface, and a protruding piece protruding outward from the outdoor side end surface. Forming a first air layer,
The composite joinery characterized in that the first air layer is disposed on the outdoor side of the first air chamber in the resin frame.   The composite fitting according to claim 1, wherein the protruding piece provided on the resin lower frame is a first packing, and the protruding piece provided on the resin upper frame is a rib.   The composite according to claim 1 or 2, wherein the metal frame is divided into an outer metal frame and an inner metal frame, and the outer metal frame and the inner metal frame are connected via a resin bridge member. Joinery. In a position facing at least one of the outer metal frame, the bridge member, and the inner metal frame of the metal frame,
The first air chamber;
A recessed second air chamber formed by providing a plurality of protrusions on at least one of the resin upper frame and the resin lower frame;
The composite joinery according to claim 1 or 2 provided with.   5. The composite joinery according to claim 1, wherein the resin frame includes a hidden ridge structure formed by forming the plurality of first air chambers overlapping the metal ridge and the resin ridge of the shoji.   The composite fitting according to claim 4, wherein the protrusion provided on the resin frame is provided at a position facing the bridge member so as to separate the outdoor side from the indoor side.

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