JP2020139406A - Composite frame - Google Patents

Abstract

To provide a composite frame and fittings capable of improving airtightness while maintaining heat insulation.SOLUTION: A composite frame 20 is provided at an opening W and is constituted by connecting a metal member 20A and a resin member 20B, and the composite frame 20 features that the metal member 20A has a panel supporting groove 40 for supporting an end of a glass panel 2, the resin member 20B is disposed on the metal member 20A so as to cover the indoor side of the panel support groove 40, and an airtight line A1 for blocking ventilation of the outside air to the indoor side is formed continuously from an indoor side surface of the panel support groove 40 to a prospective surface of the metal member 20A.SELECTED DRAWING: Figure 2

Description

The present invention relates to a composite frame and fittings provided at an opening of a structure.

Conventionally, as a lower frame of a fitting provided in an opening of a structure, for example, the one described in Patent Document 1 has been proposed. This lower frame is a composite member composed of an aluminum lower frame and a resin lower frame, and a drainage guide is provided so as to communicate with the aluminum lower frame and the resin lower frame. Since it has a resin lower frame, it has high heat insulation properties, and the condensed water that has flowed down to the resin lower frame by the drainage guide is drained to the outside via the hollow portion on the indoor side of the aluminum lower frame.

JP-A-11-107648

By the way, in the sash described in Patent Document 1 above, rainwater may infiltrate into the hollow due to the pressure difference between the inside and outside of the hollow of the lower frame. In order to improve the drainage of rainwater that has entered the hollow of the lower frame, it is necessary to provide a large check valve in the drainage guide, but as the check valve becomes larger, the gap around the check valve also increases. It becomes large and the airtightness decreases.
Further, since the indoor side of the frame into which the end portion of the double glazing glass is fitted is made of a resin member, a gap is likely to occur at the joint portion between the resin members, and the edge of the resin member due to thermal expansion and contraction of the resin member. There is a problem that a gap is formed in the portion and the airtightness is lowered.
In particular, in medium- and high-rise buildings such as buildings, since a pressure difference is generated indoors and outdoors, water may be drawn into the indoor side, and high airtightness is desired.

Therefore, the present invention has been made in view of the above circumstances, and provides a composite frame and fittings capable of improving airtightness while maintaining heat insulating properties.

In order to achieve the above object, the present invention employs the following means.
That is, the composite frame according to the present invention is a composite frame provided at an opening and formed by connecting a metal member and a resin member, and the metal member is a panel support that supports an end portion of a glass panel. The resin member has a groove and is arranged on the metal member so as to cover the indoor side of the panel support groove, and is continuous from the indoor side surface of the panel support groove to the prospective surface of the metal member. Therefore, it is characterized in that an airtight line is configured to prevent the outside air from being ventilated to the indoor side.

In the composite frame configured in this way, the resin member is arranged so as to cover the metal member on the indoor side of the panel support groove that supports the end portion of the glass panel, so that the heat insulating property can be ensured.
Further, since an airtight line is formed continuously from the indoor side surface of the panel support groove of the metal member to the prospective surface of the metal member to prevent the ventilation of the outside air to the indoor side, the airtightness can be ensured. ..

Further, the fitting according to the present invention includes the composite frame described above, the glass panel housed in the composite frame, and a sealing material provided on the peripheral edge of the glass panel, and supports the panel. The groove is characterized by having a metal-side pressing portion that presses the sealing material toward the glass panel side.

In the fitting configured in this way, the metal side pressing portion of the panel support groove of the metal member presses the sealing material provided on the peripheral edge of the glass panel toward the glass panel side, so that the outside temperature changes. Even if the resin member heat shrinks, the metal member does not heat shrink, so the airtightness is ensured by blocking the flow of outside air and sound indoors and outdoors between the glass panel and the panel support groove of the metal member that sandwiches the sealing material. can do.

Further, in the fitting according to the present invention, it is preferable that the resin member has a resin-side pressing portion that presses the metal-side pressing portion toward the glass panel side.

In the fitting configured in this way, the resin-side pressing portion of the resin member presses the metal-side pressing portion toward the glass panel side, so that the airtightness between the glass panel and the panel support groove of the metal member sandwiching the sealing material is tight. Can be enhanced.

Further, in the fitting according to the present invention, the metal member has a pair of first engaging portions separated in the vertical direction, and the resin member sandwiches the first engaging portion from the vertical direction. It may have a second engaging portion.

In the fitting configured in this way, since the pair of first engaging portions of the metal member and the pair of second engaging portions of the resin member are engaged, the displacement due to thermal expansion and contraction of the resin member is suppressed. .. Further, since the pair of second engaging portions of the resin member sandwich the pair of first engaging portions of the metal member in the vertical direction, the exposure of the metal member to the indoor side is suppressed.

According to the composite frame and fittings according to the present invention, the airtightness can be improved while maintaining the heat insulating property.

It is a perspective view which looked at the FIX window which concerns on 1st Embodiment of this invention from the indoor side. FIG. 1 is a vertical cross-sectional view taken along the line AA. FIG. 2 is a horizontal cross-sectional view taken along the line BB. It is the C part enlarged view of FIG. It is a perspective view which looked at the lower end part of the FIX window which concerns on 1st Embodiment of this invention from the indoor side. It is a perspective view which looked at the lower end part of the FIX window which concerns on 1st Embodiment of this invention from the outdoor side. FIG. 4 is a cross-sectional view taken along the line DD. It is (a) the perspective view seen from the diagonally upper side, (b) the perspective view seen from the diagonally lower side of the valve provided in the first dew condensation water drain hole of the FIX window according to the first embodiment of the present invention. It is (a) the perspective view seen from diagonally above and (b) the perspective view seen from diagonally below the valve provided in the 2nd dew condensation water drain hole of the FIX window which concerns on 1st Embodiment of this invention. It is a front view which looked at the sliding window which concerns on 2nd Embodiment of this invention from the indoor side. It is a vertical sectional view of the sliding window which concerns on 2nd Embodiment of this invention. It is sectional drawing of the sliding window which concerns on 2nd Embodiment of this invention. It is an enlarged view of part E of FIG. It is a vertical sectional view of the sliding window which concerns on the modification of the 2nd Embodiment of this invention. It is sectional drawing of the sliding window which concerns on the modification of the 2nd Embodiment of this invention.

(First Embodiment)
Hereinafter, as an example of the fittings provided in the opening of the building according to the first embodiment of the present invention, a FIX window (fitting window) will be described with reference to FIGS. 1 to 9.
FIG. 1 is a perspective view of the FIX window according to the first embodiment of the present invention as viewed from the indoor side.
As shown in FIG. 1, the FIX window 100 is provided with a frame body (composite frame) 1 provided in the opening W and formed in a quadrangular frame shape, and a multi-layer such as a pair of glass fitted in the frame body 1. It includes a glass (glass panel) 2 and ridges 5 provided on the left and right sides of the frame 1.
In the following description, the direction along the double glazing 2 that intersects the vertical direction and the vertical direction of the double glazing 2 is referred to as a finding direction. Of the finding directions, the direction toward the center of the double glazing 2 is referred to as the inside of the finding direction, and the opposite direction is referred to as the outside of the finding direction. Further, the thickness direction of the double glazing 2 is referred to as a prospective direction.

The frame body 1 includes an upper frame 10 and a lower frame 20 extending in the horizontal direction, and a vertical frame 30 extending in the vertical direction by connecting both ends of the upper frame 10 and both ends of the lower frame 20, respectively. Have.

FIG. 2 is a vertical cross-sectional view of FIG. 1 cut along AA.
As shown in FIG. 2, the upper frame 10 includes a metal upper frame (metal member) 10A provided on the outdoor side and a resin upper frame (resin member) 10B provided on the indoor side. are doing. The metal upper frame 10A and the resin upper frame 10B are connected to each other.

The lower frame 20 has a metal lower frame (metal member) 20A provided on the outdoor side and a resin resin lower frame (resin member) 20B provided on the indoor side. The metal lower frame 20A and the resin lower frame 20B are connected to each other.

FIG. 3 is a horizontal cross-sectional view of FIG. 2 cut at BB.
As shown in FIG. 3, the vertical frame 30 includes a metal vertical frame (metal member) 30A provided on the outdoor side and a resin vertical frame (resin member) 30B provided on the indoor side. are doing. The metal vertical frame 30A and the resin vertical frame 30B are connected to each other.

The vertical frame 30 is provided with a ridge 5. The ridge 5 holds the indoor side of the double glazing 2 and has a metal ridge (metal member) 50A made of metal and a resin ridge (resin member) 50B made of resin provided on the indoor side of the metal ridge 50A. ing. The metal ridge 50A and the resin ridge 50B are integrally formed.

As shown in FIGS. 2 and 3, the upper frame 10, the lower frame 20, and the vertical frame 30 are each provided with a glass receiving portion 40 having a U-shaped cross section that is recessed so as to be separated from the double glazing 2. There is. A surface clearance (space portion) 40S is provided between the inner and outer surfaces of the double glazing 2 and both side portions of the glass receiving portion 40.

The surface clearance 40S is provided with an elastic material 41 such as a sponge and a sealing material (sealing material) 42. The sealing material 42 has an amorphous shape or a fixed shape, and for example, silicone, modified silicone, urethane, butyl and the like can be adopted.

The double glazing 2 is fitted into the glass receiving portion 40 in a state where the ridge 5 is removed from the vertical frame 30. After that, the ridge 5 is attached to the vertical frame 30, and the elastic material 41 and the sealing material 42 are provided. The outdoor side ends 10Z, 20Z, 50Z of the resin upper frame 10B, the resin lower frame 20B, and the resin ridge 50B support the sealing material 42.

Next, the configurations of the lower frame 20 and the valves (upper cap 60, lower valve 70) provided on the lower frame 20 will be described in detail.
FIG. 4 is an enlarged view of part C of FIG.
As shown in FIG. 4, the metal lower frame 20A is a connecting wall that connects the upper part 110 that supports the resin lower frame 20B, the lower part 120 that extends downward from the upper part 110, and the upper wall part and the lower wall part. It has a unit 130 and.

The upper portion 110 is provided with a side wall portion 111 that projects upward and extends in the finding direction. A pair of side wall portions 111 are provided so as to be separated from each other in the prospective direction. The lower end portion 2Z of the double glazing 2 is arranged between the side wall portions 111.

The side wall portion 111 on the outdoor side is provided with an elastic material locking piece 112 projecting toward the indoor side. A sealing material support wall portion 113 projecting toward the indoor side is provided at the upper end portion of the side wall portion 111.

The side wall portion 111 on the indoor side is provided with an elastic material locking piece 114 projecting toward the outdoor side. A pair of elastic material locking pieces 114 are provided so as to be separated from each other in the vertical direction.

A sealing material support wall portion (metal side pressing portion) 115 extending upward from the end portion of the upper elastic material locking piece 114 is provided.

An engaging piece (first engaging portion) 117 bent toward the indoor side is provided at the upper end of the sealing material support wall portion 115. Further, the side wall portion 111 on the indoor side is provided with an engaging piece (first engaging portion) 118 projecting toward the indoor side.

On the outdoor side of the double glazing 2, the elastic material 41 is sandwiched between the elastic material locking piece 112 of the side wall portion 111, the lower end portion of the sealing material support wall portion 113, and the double glazing 2. Further, the sealing material 42 is sandwiched between the sealing material support wall portion 113, the elastic material 41, and the double glazing 2.

On the indoor side of the double glazing 2, the elastic material 41 is sandwiched between the pair of elastic material locking pieces 114 and the double glazing 2. Further, the sealing material 42 is sandwiched between the sealing material support wall portion 115, the elastic material 41, and the double glazing 2. Further, the sealing material support wall portion 115 of the metal lower frame 20A is pressed by the engaging wall portion 203 of the resin lower frame 20B described later.

In the present embodiment, the portion (bottom portion) 119 sandwiched between the pair of side wall portions 111 in the side wall portion 111 and the upper stage portion 110 constitutes the glass receiving portion (panel support groove) 40.

The lower portion 120 has a first inclined wall portion 121 that gradually decreases downward from the indoor side to the outdoor side of the upper portion 110, and a first inclined wall portion 121 that gradually decreases downward from the end portion of the first inclined wall portion 121 toward the outdoor side. It has a second inclined wall portion 122 and. The first inclined wall portion 121 has a steeper inclination than the second inclined wall portion 122.

The connecting wall portion 130 connects the bottom portion 119 of the upper stage portion 110 and the second inclined wall portion 122. The connecting wall portion 130 is arranged along the vertical direction.

FIG. 5 is a perspective view of the lower end of the FIX window 100 as viewed from the indoor side. In FIG. 5, the description of the double glazing 2 is omitted.
As shown in FIGS. 4 and 5, in the bottom portion 119 of the upper portion 110, a rainwater drainage hole 110H penetrating in the vertical direction and communicating with the outside is provided on the outdoor side of the connecting wall portion 130. Rainwater drainage holes 110H are provided near both ends of the bottom portion 119 in the finding direction.

FIG. 6 is a perspective view of the lower end of the FIX window 100 as viewed from the outdoor side.
As shown in FIGS. 4 and 6, at both ends of the connecting wall portion 130 in the finding direction, final drainage holes 130H penetrating in the prospective direction and communicating with the outside are provided at the lower end portions.

As shown in FIG. 6, fins 31 extending inward in the finding direction are provided on the outdoor side of the metal vertical frame 30A. The fins 31 extend in the vertical direction. In front view, the fins 31 are arranged so as to overlap the final drainage holes 130H provided in the connecting wall portion 130.

As shown in FIGS. 4 and 6, the lower end portion 111Z of the side wall portion 111 extends below the upper portion 110. A drainage space portion 111S is formed between the lower end portion 111Z of the side wall portion 111 and the second inclined wall portion 122.

As shown in FIG. 4, the resin lower frame 20B includes a horizontal plane portion 201 formed along the horizontal plane and an erected vertical facing portion 202 provided so as to intersect in the vertical direction from the outdoor side of the horizontal plane portion 201. , The engaging wall portions (resin side pressing portion, second engaging portion) 203 extending to the outdoor side from the upper and lower ends of the vertical facing portion 202, respectively. Each engaging wall portion 203 engages with the engaging pieces 117 and 118 of the metal lower frame 20A by sandwiching them in the vertical direction.

As shown in FIG. 2, an upward piece 201T extending upward is provided at the indoor end of the horizontal surface portion 201. At the upper end of the upward piece 201T, a lower frame indoor side surface portion 206 extending toward the indoor side is provided.

Further, the resin lower frame 20B has a support wall portion 205 extending downward from the lower surface of the horizontal surface portion 201. A pair of support wall portions 205 are provided so as to be separated from each other in the prospective direction.

The lower end of the support wall portion 205 on the indoor side is engaged with the upward piece 110T extending upward from the indoor side of the upper portion 110 of the metal lower frame 20A. The support wall portion 205 on the outdoor side is supported by the upper stage portion 110. In this way, the resin lower frame 20B is connected to the metal lower frame 20A.

As shown in FIG. 4, in the horizontal surface portion 201 of the resin lower frame 20B, the first dew condensation water drainage hole 201H penetrating in the vertical direction is provided on the outdoor side of the support wall portion 205. An upper cap 60 is provided in the first dew condensation water drain hole 201H.

FIG. 7 is a cross-sectional view of FIG. 4 cut by DD. FIG. 8 is a perspective view of the upper cap 60 as viewed from diagonally above (a) and (b) as viewed from diagonally below.
As shown in FIGS. 4, 7 and 8, the upper cap 60 includes an upper surface portion 61 formed in a rectangular shape in a plan view, and an upright wall portion 62 extending downward from two opposite sides of the upper surface portion 61. have.

The erection wall portion 62 is placed on the horizontal surface portion 201 of the resin lower frame 20B. As a result, a space portion 61S having a height corresponding to the height of the standing wall portion 62 is formed between the upper surface portion 61 and the horizontal surface portion 201.

Further, the upper cap 60 extends downward from the lower surface of the upper surface portion 61, and extends downward from the lower surface of the upper surface portion 61 and the engaging leg portion 63 that engages with the edge portion of the first dew condensation water drain hole 201H of the horizontal surface portion 201. It has a guide wall portion 64 and.

The guide wall portion 64 has a downward triangular shape. The guide wall portion 64 is formed with an inclined wall portion 65 that is inclined obliquely downward.

As shown in FIG. 4, in the upper portion 110 of the metal lower frame 20A, a second dew condensation water drain hole 110J penetrating in the vertical direction is provided on the indoor side of the side wall portion 111. The second dew condensation water drain hole 110J is provided slightly inside the end of the metal lower frame 20A in the finding direction.

The second dew condensation water drainage hole 110J is provided directly below the first dew condensation water drainage hole 201H and in communication with the first dew condensation water drainage hole 201H. The second dew condensation water drainage hole 110J is arranged between the first dew condensation water drainage hole 201H and the height separation corresponding to the height of the support wall portion 205 of the resin lower frame 20B. A lower valve (check valve) 70 is provided in the second dew condensation water drain hole 110J.

As shown in FIG. 6, the lower valve 70 is arranged at a position deviated from the final drain hole 130H of the metal lower frame 20A in the finding direction.

9A and 9B are a perspective view of the lower valve 70 viewed from diagonally above (a) and a perspective view of (b) viewed from diagonally below.
As shown in FIGS. 4, 7 and 9, the lower valve 70 has an upper tubular body 71 arranged above the upper portion 110. The upper tubular body 71 has a bottom portion 72 formed in an annular shape in a plan view, an outer peripheral wall portion 73 erected from the edge of the bottom portion 72, and an inner peripheral wall portion 74 extending downward from a through hole 72H formed in the bottom portion 72. And have.

Further, the lower valve 70 has a lower tubular body 75 arranged in the second dew condensation water drain hole 110J, and a plurality of connecting bodies 76 connecting the upper tubular body 71 and the lower tubular body 75. ing.

A protruding wall portion 77 that protrudes inward in the radial direction is provided on the inner peripheral surface of the lower tubular body 75. At the lower end of the protruding wall portion 77, an inclined wall portion 78 that gradually increases upward as it goes inward in the radial direction is formed.

At the lower end of the lower tubular body 75, a valve hole 75H having a shape that bulges upward and penetrates in the radial direction is formed. The valve holes 75H are formed at three locations separated in the circumferential direction.

The connecting body 76 is placed on the upper portion 110. As a result, a gap 71S is formed between the bottom portion 72 of the upper tubular body 71 and the upper portion 110.

A valve body 80 is provided inside the lower tubular body 75. The valve body 80 has a central plate 81 formed in a circular shape in a plan view, and a valve body 82 protruding outward in the radial direction from the edge portion of the central plate 81.

The valve body 82 has a shape that bulges upward corresponding to the shape of the valve hole 75H. The valve bodies 82 are provided at three locations separated in the circumferential direction.

Normally, the valve body 80 is arranged below the lower tubular body 75, and the valve body 82 is arranged in the valve hole 75H. A space 75S is formed between the inner peripheral surface of the lower tubular body 75 and the upper surface of the central plate 81.

On the other hand, when an upward pressure is received from the outside, the valve body 80 moves upward. As a result, the inner peripheral surface of the lower tubular body 75 and the upper surface of the central plate 81 are sealed. In this way, the valve body 80 functions as a check valve that prevents backflow of rainwater and the like.

Next, the connecting structure of the vertical frame 30 and the ridge 5 will be described.
As shown in FIG. 3, the metal vertical frame 30A is provided with an intermediate surface portion 340 extending in the finding direction in the intermediate portion in the prospective direction. At the inner end of the intermediate surface portion 340 in the finding direction, an engaging claw portion 341 projecting toward the outdoor side is provided. Further, the intermediate surface portion 340 is provided with an engaging projection 342 that projects toward the outdoor side.

On the other hand, at the end of the base portion 510 extending in the finding direction of the metal ridge 50A in the finding direction, a protrusion 511 extending toward the outdoor side is provided. At the tip of the protrusion 511, an engaging piece portion 512 that gradually goes to the outdoor side toward the outside in the finding direction is provided.

The end of the protrusion 511 is engaged with the engaging claw portion 341 of the metal vertical frame 30A. The tip of the engaging piece portion 512 is engaged with the engaging projection 342 of the metal vertical frame 30A. In this way, the metal ridge 50A is connected to the metal vertical frame 30A.

Further, an engaging piece portion 513 extending toward the indoor side is provided at an outer end portion of the base portion 510 of the metal ridge 50A in the finding direction. At the end of the engaging piece portion 513, a bent piece portion 514 that is bent inward in the finding direction is provided.

Further, an engaging piece portion 515 extending toward the indoor side is provided at the inner end portion of the base portion 510 in the finding direction. At the end of the engaging piece 515, a bent piece 516 that is bent outward in the finding direction is provided.

Further, a projecting piece 521 projecting toward the outdoor side is provided at the inner end of the base 510 in the finding direction. A support wall portion (metal side pressing portion) 522 extending along the finding direction is provided at the end of the projecting piece 521.

On the other hand, an engaging claw portion 571 extending outward in the finding direction is provided at an outdoor end portion of the outer surface portion 570 extending in the prospective direction of the resin ridge 50B. The engaging claw portion 571 is engaged with the engaging piece portion 513 and the bent piece portion 514 of the metal ridge 50A.

The outer surface portion 570 of the resin ridge 50B and the inner side surface portion 560 arranged inside the outer surface portion 570 and extending in the prospective direction are connected by a connecting wall portion 583. The connecting wall portion 583 is provided with an engaging piece portion 584 extending toward the outdoor side. At the end of the engaging piece 584, a bent piece 585 that is bent inward in the finding direction is provided. The bent piece portion 585 is engaged with the bent piece portion 516 of the metal ridge 50A.

In this way, the engaging claw portion 571 of the resin ridge 50B and the engaging piece portion 513 and the bent piece portion 514 of the metal ridge 50A are engaged, and the bent piece portion 585 of the resin ridge 50B and the metal ridge 50A are folded. The resin ridge 50B and the metal ridge 50A are connected by engaging with the curved piece portion 516.

Next, the airtight line A1 for blocking the ventilation of the outside air to the indoor side in the FIX window 100 and the heat insulating line A2 for ensuring the heat insulating property will be described.
As shown in FIG. 2, the airtight line A1 is continuously formed along the indoor side surface of the sealing material support wall portion 115 and the upper surface (expected surface) of the metal lower frame 20A. Specifically, an airtight line along the sealing material support wall portion 115, the upper elastic material locking piece 114, the indoor side wall portion 111, the portion indoor side of the side wall portion 111 in the upper stage portion 110, and the upward piece 110T. A1 is configured. A lower valve 70 is provided on the upper portion 110 of the metal lower frame 20A on the airtight line A1.

Further, a heat insulating line A2 is formed along the engaging wall portion 203, the vertical facing portion 202, the horizontal plane portion 201, the upward piece 201T, and the lower frame indoor side surface portion 206 of the resin lower frame 20B.

Further, in the upper frame 10, the airtight line A1 is continuously formed along the indoor side surface and the horizontal plane (expected surface) of the metal upper frame 10A. Further, the heat insulating line A2 is configured along the horizontal plane of the resin upper frame 10B.

Further, as shown in FIG. 3, in the vertical frame 30 and the ridge 5, the airtight line A1 is continuous along the indoor side surface of the metal ridge 50A and the metal vertical frame 30A and the surface (expected surface) extending in the prospective direction. In addition, the heat insulating line A2 is formed along the inner surface of the resin ridge 50B in the finding direction, the indoor side surface, and the inner surface of the resin vertical frame 30B in the finding direction.

As described above, the airtight line A1 and the heat insulating line A2 are provided separately, and the airtight line A1 and the heat insulating line A2 are formed over four circumferences. On the indoor side of the airtight line A1, a heat insulating space surrounded by the airtight line A1 and the heat insulating line A2 is secured over four circumferences.

Next, the structure for holding the end portion of the double glazing 2 will be described.
As shown in FIG. 4, in the lower frame 20, a pair of engaging wall portions 203 of the resin lower frame 20B sandwich the engaging pieces 117 and 118 of the metal lower frame 20A from the vertical direction. In this state, the sealing material support wall portion 115 of the metal lower frame 20A presses the double glazing 2 via the sealing material 42.
Therefore, even if the resin lower frame 20B is expanded and contracted by heat, the engaging wall portion 203 does not come off or shift from the metal lower frame 20A, so that the expansion and contraction displacement of the resin lower frame 20B can be suppressed.
Since the upper frame 10 also has the same configuration, the description thereof will be omitted.

As shown in FIG. 3, in the vertical frame 30 and the ridge 5, as described above, the metal ridge 50A and the resin ridge 50B are connected to each other on the indoor side of the base 510 of the metal ridge 50A from the base 510. The support wall portion 522 provided on the outdoor side presses the double glazing 2 via the sealing material 42.
Therefore, even if the resin ridge 50B is expanded and contracted by heat, the engaging claw portion 571 and the bent piece portion 585 of the resin ridge 50B do not come off or shift from the metal ridge 50A, so that the expansion and contraction displacement of the resin ridge 50B is increased. Can be suppressed.

Next, drainage of rainwater that has entered the glass receiving portion 40 of the metal lower frame 20A of the FIX window 100, dew condensation water that has accumulated on the resin lower frame 20B, and drainage of dew condensation water that has accumulated on the metal lower frame 20A. Will be described.

As shown by the arrow X in FIG. 4, the rainwater that has entered the glass receiving portion 40 falls downward from the rainwater drainage hole 110H at the bottom 119 of the metal lower frame 20A, passes through the drainage space portion 111S, and goes outdoors. It is discharged. This flow path is a rainwater drainage channel X through which rainwater is discharged.

On the other hand, as shown by an arrow Y in FIG. 4, the condensed water collected on the resin lower frame 20B is a space portion 61S formed between the upper surface portion 61 of the upper cap 60 and the horizontal surface portion 201 of the resin lower frame 20B. From, it falls. Since the inclined wall portion 65 (see FIG. 7) of the upper cap 60 is formed so as to be inclined diagonally downward, the dew condensation water easily flows along the inclined wall portion 65.

The dropped dew condensation water passes through the inside of the upper tubular body 71 of the lower valve 70 and falls downward from the through hole 72H of the bottom 72. Condensed water falls below the lower valve 70 from the space 75S formed between the inner peripheral surface of the lower tubular body 75 and the upper surface of the central plate 81.

A continuous passage 110R is formed between the second dew condensation water drainage hole 110J and the final drainage hole 130H. Condensed water moves to the outdoor side along the first inclined wall portion 121 of the resin lower frame 20B, passes through the final drainage hole 130H and the drainage space portion 111S, and is discharged to the outside.
This flow path is the first dew condensation water drainage channel Y through which the dew condensation water collected on the resin lower frame 20B is discharged.

On the other hand, as shown by the arrow Z in FIG. 4, in the unlikely event that dew condensation water collects on the metal lower frame 20A (below the resin lower frame 20B), the dew condensation water is collected on the upper tubular body 71 of the lower valve 70. From the gap 71S formed between the bottom portion 72 of the metal lower frame 20A and the upper portion 110 of the metal lower frame 20A, between the outer peripheral surface of the inner peripheral wall portion 74 and the inner peripheral surface of the lower tubular body 75, and the lower tubular body 75. From the space portion 75S formed between the inner peripheral surface of the center plate 81 and the upper surface of the central plate 81, the water falls below the lower valve 70. The subsequent flow is the same as the flow of the condensed water collected on the resin lower frame 20B. This flow path is the second dew condensation water drainage channel Z from which the dew condensation water collected on the metal lower frame 20A is discharged.

In this way, the first dew condensation water drainage channel Y and the second dew condensation water drainage channel Z are drained without passing through the glass receiving portion 40. In other words, the rainwater drainage channel X, the first dew condensation water drainage channel Y, and the second dew condensation water drainage channel Z are provided independently.

Further, along the line indicated by the broken line P shown in FIG. 4, a water stop line is configured to prevent the ventilation of the outside air to the indoor side and the infiltration of rainwater into the indoor side. The valve body 80 having the check valve function of the lower valve 70 is arranged in the water stop line to prevent rainwater from flowing back to the indoor side.

In the FIX window 100 configured in this way, the metal upper frame 10A, the metal lower frame 20A, the metal vertical frame 30A, and the metal ridge 50A are provided indoors from the glass receiving portion 40 that supports the end portion of the double glazing 2. Since the resin upper frame 10B, the resin lower frame 20B, the resin vertical frame 30B, and the resin ridge 50B are arranged so as to cover the resin, heat insulation can be ensured. Further, since a heat insulating space surrounded by the airtight line A1 and the heat insulating line A2 is secured on the indoor side of the airtight line A1, the heat insulating property can be improved.

Further, the outside air is ventilated from the indoor side surface of the sealing material support wall portion 115 and the metal ridge 50A to the indoor side along the prospective surfaces of the metal upper frame 10A, the metal lower frame 20A, the metal vertical frame 30A, and the metal ridge 50A. Since the airtight line A1 that prevents the above is continuously configured, the airtightness can be ensured. Further, since the lower valve 70 is provided in the airtight line A1, the backflow of rainwater from the lower valve 70 is suppressed. Further, since rainwater does not enter the indoor side of the airtight line A1, the lower valve 70 may have a size suitable for draining the condensed water. That is, the lower valve 70 can be miniaturized, and the gap around the lower valve 70 can be suppressed to be small, so that the airtightness can be improved.

Further, the sealing material support wall portions 115 and 522 of the metal upper frame 10A, the metal lower frame 20A, the metal vertical frame 30A, and the metal ridge 50A form the sealing material 42 provided on the peripheral edge of the double glazing 2 in the double glazing 2. By pressing to the side, even if the resin upper frame 10B, resin lower frame 20B, resin vertical frame 30B, and resin ridge 50B are thermally shrunk due to changes in the outside temperature, the metal upper frame 10A, metal lower frame 20A, and metal vertical frame Since the 30A and the metal ridge 50A do not shrink due to heat, indoors and outdoors between the double glazing 2 and the metal upper frame 10A, the metal lower frame 20A, the metal vertical frame 30A, and the glass receiving portion 40 of the metal ridge 50A sandwiching the sealing material 42. Airtightness can be ensured by blocking the circulation of outside air and sound.

Further, since the engaging wall portion 203 of the resin upper frame 10B and the resin lower frame 20B presses the sealing material support wall portion 115 toward the double glazing 2, the metal upper frame 10A sandwiching the double glazing 2 and the sealing material 42, The airtightness between the metal lower frame 20A and the glass receiving portion 40 can be improved.

Further, since the engaging pieces 117 and 118 of the metal upper frame 10A and the metal lower frame 20A and the pair of engaging wall portions 203 of the resin upper frame 10B and the resin lower frame 20B are engaged with each other, the resin upper frame 10B, Displacement due to thermal expansion and contraction of the resin lower frame 20B is suppressed. Further, since the pair of engaging wall portions 203 of the resin upper frame 10B and the resin lower frame 20B sandwich the engaging pieces 117 and 118 of the metal upper frame 10A and the metal lower frame 20A in the vertical direction, they are on the metal. The exposure of the frame 10A and the metal lower frame 20A to the indoor side is suppressed.

Further, the rainwater that has entered the glass receiving portion 40 is drained to the outside through the drainage space portion 111S from the rainwater drainage hole 110H provided in the glass receiving portion 40 and communicated with the outside. The dew condensation water collected on the resin lower frame 20B is provided in the first dew condensation water drainage hole 201H, the second dew condensation water drainage hole 110J, the communication passage 110R, and the metal lower frame 20A provided in the resin lower frame 20B. The water is drained from the final drainage hole 130H communicated with the outside through the drainage space portion 111S. In the unlikely event that dew condensation water collects on the metal lower frame 20A, the dew condensation water collected on the metal lower frame 20A will be drained from the second dew condensation water drainage hole 110J, the communication passage 110R and the final drainage hole 130H. It passes through 111S and is drained.
In this way, since the rainwater drainage channel X, the first dew condensation water drainage channel Y, and the second dew condensation water drainage channel Z are provided independently, rainwater and dew condensation water are drained while suppressing the backflow of rainwater. be able to.

Further, since the first dew condensation water drainage hole 201H and the second dew condensation water drainage hole 110J are arranged apart from each other in the vertical direction, it is possible to prevent backflow of rainwater. Further, the second dew condensation water drain hole 110J is provided with a valve body 80 that functions as a check valve. Therefore, the backflow of rainwater can be reliably prevented.

Further, the fins 31 provided on the outdoor side of the metal vertical frame 30A and extending inward in the finding direction are arranged so as to overlap the final drain holes 130H provided at the end of the metal lower frame 20A in the finding direction. There is. Therefore, in the front view, the final drainage hole 130H is hidden by the fin 31 and cannot be seen, so that the appearance can be improved.

The composite lower frame according to the present invention is not limited to the FIX window 100 according to the first embodiment described above, and can be appropriately changed or replaced without departing from the gist of the present invention.
Hereinafter, other embodiments and modifications of the present invention will be described, but the same or similar parts and members described in the above-described embodiments will be described with reference to the same reference numerals.

(Second Embodiment)
For example, FIG. 10 is a front view of the sliding window according to the second embodiment of the present invention as viewed from the indoor side. FIG. 11 is a vertical cross-sectional view of the sliding window according to the second embodiment of the present invention. FIG. 12 is a cross-sectional view of the sliding window according to the second embodiment of the present invention. FIG. 13 is an enlarged view of part E of FIG. Note that the frame is not shown in FIG. 10, and the shoji is not shown in FIG.
As shown in FIGS. 10 to 13, in the sliding window 100X, the outer sash 20X and the inner sash 20Y are housed in a frame (not shown).

The outer sash 20X and the inner sash 20Y have an upper stile 91 and a lower stile 92, and a vertical stile 93 extending in the vertical direction by connecting both ends of the upper stile 91 and both ends of the lower stile 92, respectively. It has an upper stile 91, a lower stile 92, and a double glazing 2 housed inside a pair of vertical stiles 93.

In the lower frame 20, an outer rail 131 for traveling the 94 provided under the outer sash 20X is provided on the outdoor side of the metal lower frame 20A. On the indoor side of the metal lower frame 20A, the inner rail 132 is provided at a position one step higher than the outer rail 131. The inner rail 132 supports a door roller (not shown) provided at the lower part of the shoji sash 20Y so as to be able to travel.

In the outer sash 20X, the upper stile 91 has a metal upper stile (metal member) 91A provided on the outdoor side and a resin upper stile (resin member) 91B provided on the indoor side. There is. The metal upper stile 91A and the resin upper stile 91B are connected to each other.

Similarly, the lower stile 92 has a metal lower stile (metal member) 92A provided on the outdoor side and a resin lower stile (resin member) 92B provided on the indoor side. The metal lower stile 92A and the resin lower stile 92B are connected to each other.

Similarly, the vertical stile 93 has a metal vertical stile (metal member) 93A provided on the outdoor side and a resin vertical stile (resin member) 93B provided on the indoor side. The metal vertical frame 93A and the resin vertical frame 93B are connected to each other.

Further, also in the inner sash 20Y, the upper stile 91, the lower stile 92, and the left and right vertical stiles 93 have the same configuration as the outer sash 20X, and the description thereof will be omitted using the same reference numerals.

The side ends of the four sides of the double glazing 2 are continuously surrounded by a glazing channel (sealing material) 43 having a substantially U-shaped cross section over the entire circumference.

The glazing channel 43 has a base portion 43a that abuts on the end surface of the double glazing 2 and a rising portion 43b that abuts on both side edges.

A flat surface portion 45, two fin portions 44 extending from the flat surface portion 45 on the double glazing 2 side, and a tip fin portion 46 provided at the tip end portion of the flat surface portion 45 are formed on both rising portions 43b. There is. At the other end of the tip fin portion 46, a protrusion 46a projecting to the opposite side of the flat surface portion 24 is formed.

The fin portions 44 and the tip fin portions 46 airtightly seal both side portions of the double glazing 2 indoors and outdoors and the glazing channel 43.

In the metal upper stile 91A, the metal lower stile 92A, and the metal vertical stile 93A, a glass receiving portion 40 having a substantially U-shaped cross section is formed so as to surround the glazing channel 43.

In the glass receiving portion 40 of the metal lower stile 92A, the side portions 40b extend upward on the outdoor side and the indoor side of the receiving portion 40a facing the base portion 43a of the glazing channel 43, respectively. A thick pressing portion 40c that abuts on the flat surface portion 45 of the glazing channel 43 is formed on the side portion 40b. On the indoor side, the front protrusion 92c of the resin lower stile 92B is fitted between the pressing portion 40c and the protrusion 46a of the tip fin portion 46. As a result, the rising portion 43b on the indoor side is pressed toward the double glazing 2 side by the pressing portion 40c of the glass receiving portion 40 and the front protruding portion 92c.
Therefore, both rising portions 43b of the glazing channel 43 covering one end of the double glazing 2 are pressed and supported by the glass receiving portion 40 of the metal lower stile 92A. Moreover, a space is formed between the base portion 43a of the glazing channel 43 and the receiving portion 40a of the glass receiving portion 40.

In this way, the pressing portion 40c on the indoor side of the glass receiving portion 40 presses the protruding portion 46a of the glazing channel 43 via the front protruding portion 92c of the resin lower stile 92B. Further, on the indoor side portion 40b of the glass receiving portion 40, a locking receiving portion 40d that is branched in the vicinity of the pressing portion 40c and bent in a substantially hook shape is formed. The locking receiving portion 40d is engaged with a substantially L-shaped locking portion (resin side pressing portion) 92d branched from the front protruding portion 92c of the resin lower stile 92B.

Therefore, even if the resin lower stile 92B expands and contracts due to heat, the front protrusion 92c and the locking portion 92d do not come off or shift from the metal lower stile 92A, so that the expansion and contraction displacement of the resin lower stile 92B can be suppressed. ..
Since the upper stile 91 also has the same configuration, the description thereof will be omitted.

Further, the left and right vertical stiles 93 of the inner sash 20Y basically have a structure of holding the end portion of the double glazing 2 as in the lower stile 92.
As a difference, in the vertical stile 93 on the door end side of the internal shoji 20Y, the rising portion 43b of the glazing channel 43 is pressed against the indoor side 40b provided on the glass receiving portion 40 of the metal vertical stile 93A. A pressing portion (metal side pressing portion) 40e having a substantially U-shape and a further bent tip is formed. The front protruding portion 92c of the resin vertical frame 93B is sandwiched and engaged between the pressing portion 40e and the protruding portion 46a of the tip fin portion 46 of the glazing channel 43, and presses the rising portion 43b. Further, the locking portion 92d branched from the front protruding portion 92c is engaged with the inside of the pressing portion 40e.
Since the vertical stile 93 on the door end side and the vertical stile 93 on the hanging source side of the external shoji 20X have the same configuration, the description thereof will be omitted.

Further, in the vertical stile 93 on the combined side in the internal shoji 20Y, a pair of pressing portions 40f and 40g are provided on the indoor side side portion 40b provided in the glass receiving portion 40 of the metal vertical stile 93A. One pressing portion (metal side pressing portion) 40f presses the rising portion 43b of the glazing channel 43. The tip of the front protrusion 92c of the resin vertical frame 93B is sandwiched between the tip of the pressing portion 40f and the protrusion 46a of the tip fin portion 46 to press the rising portion 43b of the glazing channel 43.

In the lower frame 20 and the lower frame 92, an airtight line A3 is formed continuously from the indoor side surface of the metal lower frame 92A to the upper surface of the metal lower frame 20A and the indoor side surface of the metal lower frame 20A. Further, a heat insulating line A4 is continuously formed from the upper surface of the resin lower stile 92B to the indoor side and the upper surface of the resin lower frame 20B. A lower valve 70 is provided on the upper portion 110 arranged on the airtight line A3 of the metal lower frame 20A.
As shown in FIG. 13, even if a minute gap 204S is provided between the fin portion 204 provided at the outdoor end of the resin lower stile 20B and the lower end of the resin lower stile 92B. The heat insulating line A4 for ensuring heat insulating property is configured.

Further, also in the upper frame 10 and the upper stile 91, an airtight line A3 is formed continuously from the indoor side surface of the metal upper stile 91A to the horizontal plane of the metal upper frame 10A and the indoor side surface of the metal upper frame 10A. There is. Further, a heat insulating line A4 is formed continuously from the indoor side surface of the resin upper frame 91B to the horizontal surface of the resin upper frame 10B and the indoor side surface of the resin upper frame 10B.

Further, also in the vertical frame 30 and the vertical frame 93, the airtight line A3 is formed continuously from the indoor side surface of the metal vertical frame 93A to the indoor side surface of the metal vertical frame 30A. Further, a heat insulating line A4 is formed continuously from the indoor side surface of the resin vertical frame 93B to the indoor side surface of the resin vertical frame 30B.

(Modified example of the second embodiment)
Next, the sliding window 100Y according to the modified example of the second embodiment will be described with reference to FIGS. 14 and 15.
FIG. 14 is a vertical sectional view of a sliding window according to a modified example of the second embodiment of the present invention. FIG. 15 is a cross-sectional view of a sliding window according to a modified example of the second embodiment of the present invention.
The basic configuration of the sliding window 100Y according to this modification is the same as that of the sliding window 100X according to the second embodiment. As shown in FIGS. 14 and 15, in the sliding window 100Y, a heat insulating material L is provided below the lower frame 20 and between the sliding window 100Y and the skeleton K. The heat insulating material L is arranged so as to be continuous with the heat insulating line L4.

Further, above the upper frame 10, a heat insulating material L is provided between the upper frame 10 and the skeleton K. The heat insulating material L is divided in the prospective direction, and an intervening member M of a sealing material or a backup material is arranged between the heat insulating material L. The heat insulating material L is arranged so as to be continuous with the heat insulating line L4 while being continuous with the intervening member M.

Further, on the outside of the vertical frame 30 in the finding direction, a heat insulating material L is provided between the vertical frame 30 and the skeleton K. The heat insulating material L is divided in the prospective direction, and an intervening member M of a sealing material or a backup material is arranged between the heat insulating material L. The heat insulating material L is arranged so as to be continuous with the heat insulating line L4 while being continuous with the intervening member M.

The various shapes and combinations of the constituent members shown in the above-described embodiment are examples, and can be variously changed based on design requirements and the like without departing from the gist of the present invention.

For example, a through hole (not shown) in the vertical direction may be formed directly below the resin ridge 50B in the resin lower frame 20B. Alternatively, a gap (not shown) may be formed between the end of the resin lower frame 20B and the metal vertical frame 30A. Condensed water can be drained from these through holes and gaps.

Further, in the above-described embodiment, the FIX window and the sliding window have been described as examples of the fittings, but the present invention is not limited to this, and the present invention can be applied to other fittings such as a stile door and a sliding window. is there. In the case of sliding windows, stile doors, and siding windows, the frame corresponds to a stile into which the end of a glass panel such as double glazing is fitted.

100 ... FIX window 1 ... Frame (composite frame)
2 ... Double glazing (glass panel)
5 ... Indentation 10 ... Upper frame 10A ... Metal upper frame (metal member)
10B ... Resin upper frame (resin member)
20 ... Lower frame 20A ... Metal lower frame (metal member)
20B ... Resin lower frame (resin member)
30 ... Vertical frame 30A ... Metal vertical frame (metal member)
30B ... Resin vertical frame (resin member)
31 ... Fin 40 ... Glass receiving part (panel support groove)
40S ... Surface clearance 41 ... Elastic material 42 ... Sealing material (sealing material)
50A ... Metal ridge (metal member)
50B ... Resin ridge (resin member)
60 ... Upper cap 70 ... Lower valve (check valve)
75H ... Valve hole 80 ... Valve body 82 ... Valve body 110H ... Rainwater drainage hole 110J ... Second dew condensation water drainage hole 110R ... Communication passage 110T ... Upward piece 111S ... Drainage space 115 ... Sealing material support wall (metal side pressing part) )
117, 118 ... Engagement piece (first engagement part)
130H ... Final drainage hole 201H ... First dew condensation water drainage hole 201T ... Upward piece 203 ... Engagement wall part (resin side pressing part, second engaging part)
522 ... Support wall part (pressing part)
A1, A3 ... Airtight lines A2, A4 ... Insulation line W ... Opening X ... Rainwater drainage channel Y ... First condensation water drainage channel Z ... Second condensation water drainage channel

The present invention relates to a composite fitting provided at an opening of a structure.

Therefore, the present invention has been made in view of the above circumstances, and provides a composite fitting capable of improving airtightness while maintaining heat insulating properties.

In order to achieve the above object, the present invention employs the following means.
That is, the composite fitting according to the present invention is a composite fitting provided at the opening and provided with a composite frame formed by connecting a metal member and a resin member, and a glass panel housed in the composite frame. a is, the metal member has a panel supporting groove for supporting an end portion of the glass panel, the resin member is disposed over the interior side of the panel support grooves be on the metal member An airtight line that prevents outside air from being ventilated to the indoor side is formed continuously from the indoor side surface of the panel support groove to the prospective surface of the metal member, and a heat insulating line is formed along the resin member. A heat insulating space is formed between the airtight line and the heat insulating line, and a sealing material is sandwiched between the metal member and the resin member and the glass panel. The resin member comes into contact with the sealing material, the sealing material is provided on the peripheral edge of the glass panel, and the panel support groove is a metal-side pressing portion that presses the sealing material toward the glass panel. It is characterized by having .

In the composite fitting configured as described above, since the resin member is arranged so as to cover the metal member on the indoor side of the panel support groove that supports the end portion of the glass panel, heat insulation can be ensured.
Further, since an airtight line is formed continuously from the indoor side surface of the panel support groove of the metal member to the prospective surface of the metal member to prevent the ventilation of the outside air to the indoor side, the airtightness can be ensured. ..
Further, it is assumed that the metal side pressing portion of the panel support groove of the metal member presses the sealing material provided on the peripheral edge of the glass panel toward the glass panel side, so that the resin member is thermally shrunk due to a change in the outside temperature or the like. However, since the metal member does not shrink due to heat, airtightness can be ensured by blocking the flow of outside air and sound indoors and outdoors between the glass panel and the panel support groove of the metal member sandwiching the sealing material.

Further, in the composite fitting according to the present invention, the metal side pressing portion may be continuously formed over the side edge portion of the entire circumference of the glass panel .

Further, in the composite fitting according to the present invention, it is preferable that the resin member has a resin-side pressing portion that presses the metal-side pressing portion toward the glass panel side.

In the composite fitting configured in this way, the resin side pressing portion of the resin member presses the metal side pressing portion toward the glass panel side, so that the airtightness between the glass panel and the panel support groove of the metal member sandwiching the sealing material You can improve your sex.

Further, in the composite fittings according to the present invention, the metal member has a first engaging portion of the pair spaced apart in the vertical direction, the resin member, first the first engaging portion of the pair of sandwiching It may have two engaging portions.
Further, in the composite fitting according to the present invention, even if the sealing material is formed of a sealing material that abuts on the indoor side surface of the glass panel, the metal member and the resin member and keeps them airtight and heat insulating. Good.
Further, in the composite fitting according to the present invention, the sealing material is brought into contact with the indoor surface of the glass panel, the metal member and the resin member to be kept airtight and heat-insulating, and the sealing material is used as a roof. It may have a protrusion protruding inward.

In the composite fitting configured in this way, since the pair of first engaging portions of the metal member and the pair of second engaging portions of the resin member are engaged, displacement due to thermal expansion and contraction of the resin member is suppressed. To. Furthermore, since the second engaging portion of the pair of the resin member has a first engaging portion of the pair of metal members pinched, exposure to indoor side of the metal member can be suppressed.

Claims (4)

A composite frame provided at an opening and formed by connecting a metal member and a resin member.
The metal member has a panel support groove that supports the end of the glass panel.
The resin member is arranged on the metal member so as to cover the indoor side of the panel support groove.
A composite frame characterized in that an airtight line is formed so as to be continuous from the indoor side surface of the panel support groove to the prospective surface of the metal member to prevent outside air from being ventilated to the indoor side. The composite frame according to claim 1 and
The glass panel housed in the composite frame and
A sealing material provided on the peripheral edge of the glass panel is provided.
The panel support groove is a fitting having a metal-side pressing portion that presses the sealing material toward the glass panel side. The fitting according to claim 2, wherein the resin member has a resin-side pressing portion that presses the metal-side pressing portion toward the glass panel side. The metal member has a pair of first engaging portions separated in the vertical direction.
The fitting according to claim 2 or 3, wherein the resin member has a pair of second engaging portions that sandwich the first engaging portion from above and below.

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