JP2019196601A - Folding door - Google Patents

Abstract

To provide a folding door capable of draining indoor water and having high thermal insulation.SOLUTION: In a folding door 100, a bottom frame 12 of a frame includes: a metal outdoor side profile member 12A; a metal indoor side profile member 12B placed at the indoor side; and a connecting material 12C that connects the outdoor side profile member 12A and the indoor side profile member 12B, and has lower thermal conductivity than that of the outdoor side profile member 12A and the indoor side profile member 12B. The bottom frame 12 includes: a recessed groove G1 which is formed of an indoor side wall g13 located on the indoor side and a bottom g12 connecting the lower end of outdoor side wall g11 and the lower end of indoor side wall g13 and an airtight part 40 that comes in contact with the lower edge of shoji 2 for closing the gap T between the lower edge of shoji 2 and the bottom frame 12. The outdoor side wall g11 is formed with a drain hole 142h for draining water, in which the drain hole 142h is disposed above the connecting material 12C.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a folding door.

  2. Description of the Related Art Conventionally, a seal member that is installed in an opening of a building and that closes a gap generated between a shoji and a frame body is provided. For example, Patent Document 1 below proposes a folding door provided with a rotary seal body capable of closing a gap between a lower end portion of a shoji and a lower frame. The lower frame is formed with a groove that can accommodate the rotary seal body when the folding door is opened.

JP 2006-37424 A

However, in the lower frame in which the groove portion is formed like the folding door described in Patent Document 1, when rainwater enters the indoor side or condensed water is generated on the indoor side, water accumulates in the groove portion. There is a problem that.
In addition, when the lower frame is made of metal, there is a disadvantage that the heat insulation is poor because the cool air of the outside air is transmitted to the indoor side through the lower frame.

  Then, this invention is made | formed in view of the said situation, and provides the folding door which can drain indoor water and has high heat insulation.

In order to achieve the above object, the present invention employs the following means.
That is, the folding door according to the present invention is a folding door that can be opened and closed by disposing a shoji in the frame installed along the opening of the building, and folding and unfolding the shoji. The lower frame of the frame body is a metal outdoor side member disposed on the outdoor side, a metal indoor side member disposed on the indoor side, the outdoor side member and the indoor side member. And a connecting material having a lower thermal conductivity than the outdoor side profile and the indoor side profile, and the indoor side profile includes an outdoor side wall portion disposed on the outdoor side, an indoor side The bottom of the indoor side wall and the bottom of the outdoor side wall and the bottom of the indoor side wall are connected to each other, the groove recessed downward and the bottom of the shoji are in contact with the shoji An airtight portion that closes a gap between the lower end portion and the lower frame, and the connecting member is disposed outside the groove portion. Disposed, the outdoor side wall portion, the water formed a drainable drainage holes, drainage holes, characterized in that it is disposed above said connection member.

In the folding door configured as described above, the gap between the lower end of the shoji and the lower frame is closed by the airtight portion (airtight material) coming into contact with the lower end of the shoji. A drainage hole capable of draining water is formed in the outdoor side wall that forms the groove. As a result, water such as rain that has entered the indoor side and condensed water generated on the indoor side passes through the drainage holes in the groove. Since the drain hole is disposed above the connecting material, the water on the indoor side is drained to the outside without hindering the water that the connecting material has passed through the drain hole.
Further, between the outdoor side profile made of metal and the indoor side profile made of metal, a connecting material having lower thermal conductivity than the outdoor side profile and the indoor side profile is arranged. Therefore, since a connection material insulates the heat transfer between an outdoor side profile and an indoor side profile, heat insulation can be improved.

  Moreover, in the folding door which concerns on this invention, it is preferable that the said indoor side wall part is arrange | positioned indoors rather than the contact surface which can contact | abut with the said airtight part in the lower end part of the said shoji.

  In the folding door configured as described above, the indoor side wall portion that forms the groove portion is disposed on the indoor side of the contact surface that can contact the airtight portion at the lower end portion of the shoji. Therefore, the water on the indoor side than the shoji can be drained to the outdoor side through the drain hole of the groove.

  In the folding door according to the present invention, the airtight portion is movable between a sealing position for closing the gap between the lower end portion of the shoji and the lower frame and an open position for opening the gap. It is preferable that the groove is housed in the open position.

  In the folding door configured as described above, since the airtight portion is accommodated in the groove portion at the open position, the airtight portion provided on the lower frame does not interfere with walking or the like when the shoji is opened.

  Moreover, in the folding door which concerns on this invention, at least one part of the said connection material may be arrange | positioned on the outdoor side rather than the said contact surface of the said shoji.

  In the folding door configured as described above, since at least a part of the connecting material is disposed on the outdoor side with respect to the contact surface of the shoji, the heat insulating property of the indoor side portion is improved more than the airtight material.

  According to the folding door which concerns on this invention, while being able to drain the water of indoor side, it has high heat insulation.

It is the perspective view which looked at the folding door which concerns on one Embodiment of this invention from the indoor side. It is a cross-sectional view of a folding door according to an embodiment of the present invention. It is a longitudinal cross-sectional view of the folding door which concerns on one Embodiment of this invention. It is an enlarged view of the lower part of FIG.

Hereinafter, the folding door which concerns on one Embodiment of this invention is demonstrated based on FIGS. 1-4.
FIG. 1 is a perspective view of a folding door according to an embodiment of the present invention as viewed from the indoor side.
As shown in FIG. 1, the folding door 100 is provided at an opening of a building, and a frame 1 formed in a rectangular frame shape, and two shojis 2 provided on the frame 1 so as to be opened and closed, It has. The folding door 100 can be opened and closed by folding and unfolding each shoji 2. In the present embodiment, the two shojis 2 are arranged in the frame 1, but the number of shojis 2 can be set as appropriate.
In the following description, a direction connecting the outdoor side and the indoor side is referred to as an indoor / outdoor direction. Moreover, the horizontal direction which ties the left side and the right side when it sees from the direction (direction which opposes a wall part) through which the opening part penetrates the wall part of a building is called left-right direction.

FIG. 2 is a cross-sectional view of the folding door 100. FIG. 3 is a longitudinal sectional view of the folding door 100.
As shown in FIGS. 2 and 3, the frame 1 includes a metal frame 1 </ b> A disposed on the outdoor side and formed of a metal material such as an aluminum alloy, and a resin frame 1 </ b> X disposed on the indoor side and formed of a synthetic resin material. And are connected.

  The frame 1 extends in the up-down direction by connecting the upper frame 11 and the lower frame 12 extending in the left-right direction, the both ends in the left-right direction of the upper frame 11 and the both ends in the left-right direction of the lower frame 12, respectively. And a vertical frame 13.

  As shown in FIG. 3, the metal frame 1A of the upper frame 11 has an outer metal upper frame portion 11A disposed on the outdoor side and an inner metal upper frame portion 11B disposed on the indoor side.

  The outer metal upper frame portion 11A and the inner metal upper frame portion 11B are connected via a bridge member 11C formed of a material having a lower thermal conductivity than the outer metal upper frame portion 11A and the inner metal upper frame portion 11B. Yes. The bridge material 11C is formed of a resin material, rubber, or the like having low thermal conductivity.

  The metal frame 1A of the lower frame 12 includes an outer metal lower frame part (outdoor side profile) 12A arranged on the outdoor side, and an inner metal lower frame part (indoor side profile) 12B arranged on the indoor side. Have.

  The outer metal lower frame portion 12A and the inner metal lower frame portion 12B are connected via a bridge material (connecting material) 12C formed of a material having lower thermal conductivity than the outer metal lower frame portion 12A and the inner metal lower frame portion 12B. Are connected. In other words, no member other than the bridge member 12C is disposed between the outer metal lower frame portion 12A and the inner metal lower frame portion 12B. The bridge member 12C is formed of a resin material or rubber having a low thermal conductivity.

  As shown in FIG. 1, each shoji 2 has a pair of door bodies 2D and a connecting rod 3 that connects the door bodies 2D.

  Each door 2D has a housing 20 formed in a quadrangular shape, and a glass 29 fitted in the housing 20.

  As shown in FIGS. 2 and 3, the housing 20 includes an upper collar 21 and a lower collar 22 extending in the left-right direction, both ends in the left-right direction of the upper collar 21, and both ends in the left-right direction of the lower collar 22. Are connected to each other and a vertical rod 23 extending in the vertical direction.

  As shown in FIG. 3, a suspension wheel (not shown; the same applies hereinafter) is provided on the upper end of each vertical shaft 23 (see FIG. 2, the same applies hereinafter) protruding upward. The suspension vehicle is engaged on a suspension rail 110 provided in the upper frame 11 and extending in the left-right direction, and can travel along the suspension rail 110. As described above, the folding door 100 according to the present embodiment has a so-called upper suspension structure in which the upper end portion of the shoji 2 is supported by the upper frame 11.

  A guide roller (not shown; the same applies hereinafter) is provided projecting downward at the lower end of the vertical rod 23 on the opposite side of the vertical rod 23 to the connecting rod 3 side. The guide roller is inserted into a guide groove G3 provided in the lower frame 12 and extending in the left-right direction, and is guided in the guide groove G3 so as to be movable in the left-right direction.

  As shown in FIG. 1, the connecting rod 3 connects one end portions of the pair of door bodies 2D (end portions on the adjacent door body 2D side). The connecting rod 3 is provided with a hinge shaft 31 (see FIG. 2; the same applies hereinafter) extending in the vertical direction. The door 2 </ b> D is rotatable around the hinge shaft 31.

  A handle 32 is provided on the indoor side of the connecting rod 3. As shown in FIG. 3, a lock member 33 is provided in the hollow portion 3 s (see FIG. 2, the same applies hereinafter) in the connecting rod 3. The lock member 33 is connected to the handle 32 (see FIG. 2, the same applies hereinafter) via an interlocking mechanism (not shown), and is configured to be movable in the vertical direction in conjunction with the operation of the handle 32.

  A lock portion 33 a and a pressing portion 33 b projecting downward are provided at the lower end portion of the lock member 33. By operating the handle 32 (locking operation), the lock member 33 moves downward in the hollow portion 3s of the connecting rod 3, and the lock portion 33a is inserted into the guide groove G3 of the lower frame 12. Thereby, door 2D is locked in a closed state. Further, by operating the handle 32 (unlocking operation), the lock member 33 moves upward in the hollow portion 3s of the connecting rod 3, and the lock portion 33a is pulled out from the guide groove G3 of the lower frame 12. Thereby, the lock | rock of door 2D is cancelled | released. A rod guide 34 that can be inserted into a hanging rail 110 that is provided on the upper frame 11 and extends in the left-right direction is provided at the upper end of the connecting rod 3.

Next, the configuration of the lower frame 12 and the rotary seal body 40 provided on the lower frame 12 will be described in detail.
FIG. 4 is an enlarged view of the lower part of FIG.
As shown in FIG. 4, the outer metal lower frame portion 12A of the lower frame 12 includes an intermediate plate portion 121, a lower plate portion 122, a lower outer plate portion 123, an inner plate portion 124, and an outer groove constituting plate portion 127. And an upper outer plate portion 128 and an upper plate portion 129.

  The middle plate portion 121 is formed in a plate shape. The middle plate portion 121 is arranged with the plate thickness direction directed in the vertical direction.

  A groove constituting member 160 is provided on the upper surface of the middle plate portion 121. The groove constituting member 160 has a fixed plate portion 161 and an inner groove constituting plate portion 162. The groove constituting member 160 is provided over substantially the entire length in the extending direction (left-right direction) of the lower frame 12.

  The fixed plate portion 161 is formed in a plate shape. The fixed plate portion 161 is arranged with the plate thickness direction directed in the vertical direction. The fixed plate portion 161 is screwed to the middle plate portion 121.

  The inner groove constituting plate portion 162 is erected from the fixed plate portion 161. The inner groove constituting plate portion 162 is formed in a plate shape. The inner groove constituting plate portion 162 is arranged with the plate thickness direction facing the indoor / outdoor direction.

  A drain hole 162h penetrating indoors and outdoors is formed at the lower part of the inner groove constituting plate part 162. In the present embodiment, the drain holes 162h are formed in the vicinity of both ends of the lower frame 12 in the left-right direction.

  The lower plate portion 122 is formed in a plate shape. The lower plate portion 122 is disposed below the middle plate portion 121. The lower plate portion 122 is inclined so that the outdoor side is disposed below the indoor side.

  The lower outer side plate portion 123 connects the end portion on the outdoor side of the middle plate portion 121 and the end portion on the outdoor side of the lower plate portion 122. The lower outer side plate portion 123 is formed in a plate shape. The lower outer side plate portion 123 is arranged with the plate thickness direction facing the indoor / outdoor direction.

  The inner side plate portion 124 connects the end portion on the indoor side of the middle plate portion 121 and the end portion on the indoor side of the lower plate portion 122. The inner side plate part 124 is formed in a plate shape. The indoor side end portion of the middle plate portion 121 is arranged on the outdoor side of the indoor side end portion of the lower plate portion 122. For this reason, the inner side board part 124 is inclined and arrange | positioned so that it may go to an outdoor side gradually as it goes upwards.

  The inner plate portion 124 is formed with a pair of protrusions 124a and 124b that protrude toward the indoor side. The protrusions 124a and 124b are spaced apart in the vertical direction.

  The outer groove constituting plate portion 127 is erected upward from the middle in the indoor / outdoor direction of the middle plate portion 121. The outer groove constituting plate portion 127 is disposed on the outdoor side with respect to the inner groove constituting plate portion 162. The outer groove constituting plate part 127 is formed in a plate shape. The outer groove constituting plate portion 127 is disposed with the plate thickness direction facing the indoor / outdoor direction.

  A drain hole 127h penetrating indoors and outdoors is formed in the lower part of the outer groove constituting plate part 127. In the present embodiment, the drain holes 127h are formed in the vicinity of both end portions of the lower frame 12 in the left-right direction.

  The upper outer plate portion 128 is erected upward from the outdoor side portion of the middle plate portion 121. The upper outer plate portion 128 is formed in a plate shape. The upper outer plate portion 128 is arranged with the plate thickness direction facing the indoor / outdoor direction.

  A drain hole 128h penetrating indoors and outdoors is formed in the lower part of the upper outer plate part 128. In the present embodiment, the drain holes 128h are formed in the vicinity of both end portions of the lower frame 12 in the left-right direction. A drainage cover 138 capable of draining from the indoor side to the outdoor side is provided in the drainage hole 128h.

  The upper plate portion 129 connects the upper end portion of the outer groove constituting plate portion 127 and the upper end portion of the upper outer plate portion 128. The upper plate portion 129 is formed in a plate shape. The upper plate portion 129 is arranged with the plate thickness direction directed in the vertical direction. The outdoor side portion of the upper plate portion 129 is slightly inclined so as to gradually go downward as it goes to the outdoor side.

  The middle plate portion 121, the lower outer plate portion 123, the lower plate portion 122, and the inner plate portion 124 form a lower hollow S1 extending in the left-right direction. An upper hollow S2 extending in the left-right direction is formed by the upper plate portion 129, the upper outer plate portion 128, the middle plate portion 121, and the outer groove constituting plate portion 127. The lower hollow S1 and the upper hollow S2 are formed over substantially the entire length of the lower frame 12 in the extending direction (left-right direction).

  The inner metal lower frame portion 12B of the lower frame 12 has a cylindrical portion 140 formed in a cylindrical shape. Inside the tubular portion 140, an indoor side hollow S3 extending in the left-right direction is formed. The indoor side hollow S3 is formed over substantially the entire length in the extending direction (left-right direction) of the lower frame 12.

  The cylindrical portion 140 includes a bottom plate portion 141, a seal support plate portion 142, a standing wall portion 143, a bent wall portion 144, a pair of locking wall portions 145 and 146, an inclined plate portion 147, and a lower portion. Wall 148.

  The bottom plate portion 141 is formed in a plate shape. The bottom plate portion 141 is disposed with the plate thickness direction directed in the vertical direction.

  The seal support plate portion 142 is erected upward from an end portion on the outdoor side of the bottom plate portion 141. The seal support plate portion 142 is formed in a plate shape. The seal support plate portion 142 is disposed with the plate thickness direction facing the indoor / outdoor direction.

  A rotation shaft portion 142a having a substantially circular cross section along the indoor / outdoor direction and the vertical direction is provided at the upper end portion of the seal support plate portion 142. The rotation shaft portion 142a extends in the left-right direction.

  A drain hole 142h penetrating indoors and outdoors is formed in the lower part of the seal support plate 142. In the present embodiment, the drain holes 142h are formed in the vicinity of both end portions of the lower frame 12 in the left-right direction. A check valve 132 is provided in the drain hole 142h to suppress the backflow of water (intrusion into the indoor side).

  The standing wall portion 143 is erected upward from the indoor side end of the bottom plate portion 141. The bent wall portion 144 extends from the upper end portion of the standing wall portion 143 toward the indoor side.

  The pair of locking wall portions 145 and 146 are erected upward from the bent wall portion 144 and are spaced apart in the indoor and outdoor directions. The resin frame 1X of the lower frame 12 is locked to the locking walls 145 and 146. The locking wall portion 145 is disposed on the outdoor side of the locking wall portion 146.

  The inclined plate portion 147 is provided so as to extend obliquely downward from the end portion on the indoor side of the bottom plate portion 141. The inclined plate portion 147 is disposed so as to be gradually inclined toward the indoor side as it goes downward.

  The lower wall portion 148 connects the lower end portion of the inclined plate portion 147 and the indoor side end portion of the bent wall portion 144.

  The inclined plate portion 147 is formed with a pair of protrusions 147a and 147b that protrude toward the outdoor side. The protrusions 147a and 147b are spaced apart in the vertical direction.

  The bridge member 12C of the lower frame 12 is sandwiched between the inner plate portion 124 of the outer metal lower frame portion 12A and the inclined plate portion 147 of the inner metal lower frame portion 12B. The bridge member 12C is locked to the pair of protrusions 124a and 124b of the outer metal lower frame part 12A and the pair of protrusions 147a and 147b of the inner metal lower frame part 12B.

  The bridge member 12C is arranged along the surface facing the outdoor side of the inclined plate portion 147 arranged to be inclined toward the indoor side as it goes downward, and stands upward from the upper end portion of the inclined plate portion 147. Since the drainage hole 142h is formed in the seal support plate portion 142, the drainage hole 142h is disposed above the bridge member 12C.

  In the lower frame 12, a seal groove (groove portion) G <b> 1 is formed between the seal support plate portion 142, the standing wall portion 143, and the locking wall portion 145 that can accommodate a rotary seal body 40 described later. Specifically, the seal groove G <b> 1 is formed by the seal support plate portion 142, the bottom plate portion 141, the standing wall portion 143, and the locking wall portion 145. The seal groove G1 has a shape recessed downward. A bridge member 12C is disposed outside the seal groove G1 (outside the groove).

  The seal support plate part 142 forms a wall part (outdoor side wall part) g11 on the outdoor side of the seal groove G1. The bottom plate part 141 forms the bottom part g12 of the seal groove G1. The standing wall portion 143 and the locking wall portion 145 form a wall portion (indoor side wall portion) g13 on the indoor side of the seal groove G1.

  In the lower frame 12, an insertion groove G <b> 2 in which the pressing portion 33 b of the lock member 33 is disposed is formed between the inner groove forming plate portion 162 of the groove forming member 160 and the seal support plate portion 142. Specifically, the insertion groove G2 includes the inner groove constituting plate portion 162, the fixing plate portion 161 of the groove constituting member 160, the protruding portion 124a of the inner plate portion 124, the upper surface of the bridge member 12C, the protruding portion 147a of the inclined plate portion 147, and the like. The seal support plate portion 142 is formed. The insertion groove G2 has a shape that is recessed downward.

  In the lower frame 12, a guide groove G <b> 3 is formed between the outer groove constituting plate portion 127 and the inner groove constituting plate portion 162 of the groove constituting member 160, into which the guide roller and the lock portion 33 a of the lock member 33 are inserted. Yes. Specifically, the guide groove G3 is formed by the outer groove constituting plate portion 127, the fixed plate portion 161 of the groove constituting member 160, and the inner groove constituting plate portion 162. The guide groove G3 has a shape recessed downward.

  The rotary seal body 40 is rotatably provided on the lower frame 12. As shown in FIG. 1, in the present embodiment, a pair of rotary seal bodies 40 are disposed adjacent to each other and are provided over substantially the entire length of the lower frame 12 in the extending direction (left-right direction).

  As shown in FIG. 4, the rotary seal body (airtight portion) 40 includes an inner peripheral member 41, an outer peripheral member 42, and a seal member 43.

  The inner peripheral member 41 has a substantially fan shape in a cross section along the indoor / outdoor direction and the vertical direction. The inner circumferential member 41 has a pair of extending portions 411 that extend from the rotating shaft portion 142a and are gradually separated from each other as the distance from the rotating shaft portion 142a increases. The portions of the extending portion 411 opposite to the rotating shaft portion 142a are connected to each other by an inner peripheral curved portion 412.

  A bearing portion 413 is provided at the end of the pair of extending portions 411 opposite to the inner circumferential curved portion 412. The bearing portion 413 is provided so as to be rotatable around the rotation shaft portion 142a.

  A pressed part 414 is provided along the outer peripheral surface of the bearing part 413. In the open state in which the shoji 2 is opened, the rotary seal body 40 is arranged at the open position A1 indicated by a two-dot chain line in FIG. 4, and the bearing portion 413 is arranged so as to gradually go downward as it goes to the outdoor side. In the closed state in which the shoji 2 is closed, the rotary seal body 40 is disposed at the seal position A2 indicated by a solid line in FIG. 4, and the bearing portion 413 is disposed vertically downward.

  The outer peripheral member 42 is provided on the outer peripheral side of the inner peripheral side curved portion 412 of the inner peripheral member 41 in the circumferential direction centering on the rotation shaft portion 142a. The outer peripheral member 42 has an outer peripheral side curved portion 421 along the outer peripheral side of the inner peripheral side curved portion 412 of the inner peripheral member 41. The outer peripheral side curved portion 421 and the inner peripheral side curved portion 412 are locked and connected.

  The seal member 43 is locked to the side of the inner peripheral member 41 adjacent to the shoji 2 in the closed state of the shoji 2. The seal member 43 is in contact with the lower collar 22 of the shoji 2 at the seal position A2.

  In the open state, the rotary seal body 40 is disposed so that the outer circumferential curved portion 421 side faces downward due to the weight of the rotary seal body 40. The rotary seal body 40 is accommodated in the seal groove G1 of the lower frame 12, and is disposed at the open position. In the open position, the gap T between the lower end of the shoji 2 and the lower frame 12 is open.

  In this state, when the handle 32 is operated (locking operation) and the lock member 33 moves downward, the pressing portion 33 b comes into contact with the pressed portion 414 of the rotary seal body 40. When the lock member 33 moves further downward, the rotary seal body 40 rotates around the rotary shaft portion 142a of the lower frame 12 and protrudes from the seal groove G1 by the pressing force acting on the pressed portion 414 from the pressing portion 33b. And disposed at the seal position A2. At the seal position A2, the surface 43a facing the outdoor side of the seal member 43 of the rotary seal body 40 contacts the surface (contact surface) 22a facing the indoor side of the lower arm 22 of the shoji 2, and the lower end of the shoji 2 and the bottom The gap T between the frame 12 is closed.

  At the seal position A2, an airtight line L is formed along a substantially vertical plane along the surface 43a of the seal member 43 and the surface 22a of the lower collar 22.

  At least a part of the seal groove G1 is disposed on the indoor side of the airtight line L. In the present embodiment, the surface of the seal groove G1 that faces the indoor side of the seal support plate portion 142 is disposed so as to substantially follow the airtight line L.

  The bridge member 12C is disposed on the hermetic line L (vertically below the hermetic line L). At least a part of the bridge member 12 </ b> C is disposed on the outdoor side of the airtight line L. In the present embodiment, most of the bridge member 12C is disposed on the outdoor side of the airtight line L.

  Water such as rain water that has entered the seal groove G1 or dew condensation water generated indoors passes through the drain hole 142h of the seal support plate 142 and proceeds into the insertion groove G2. Next, the water passes through the drain hole 162h of the inner groove constituting plate portion 162 and proceeds into the guide groove G3, passes through the drain hole 127h of the outer groove constituting plate portion 127, and proceeds into the upper hollow S2, and passes through the upper outer side. Water is drained outdoors through the drain holes 128h of the plate portion 128 (see the two-dot chain line B1 shown in FIG. 4).

  In the folding door 100 configured as described above, the gap T between the lower end portion of the shoji 2 and the lower frame 12 is closed by the seal member 43 of the rotary seal body 40 coming into contact with the lower end portion of the shoji 2. . A drain hole 142h is formed in the outdoor-side wall portion g11 (seal support plate portion 142) that forms the seal groove G1. Accordingly, water such as rain that has entered the indoor side and dew condensation water generated on the indoor side passes through the drain hole 142h of the seal groove G1. Since the drain hole 142h is disposed above the bridge member 12C, the water on the indoor side is drained to the outside without hindering the water that the bridge member 12C has passed through the drain hole 142h.

  Further, the indoor-side wall portion g13 that forms the seal groove G1 is disposed on the indoor side of the airtight line L. A drain hole 142h is formed in the outdoor-side wall portion g11 (seal support plate portion 142) that forms the seal groove G1. Therefore, the water on the indoor side from the airtight line L can be drained to the outdoor side through the drain hole 142h of the seal groove G1.

  If water enters the indoor side beyond the airtight line L and the water accumulates in the seal groove G1, the rotary seal body 40 in the open position floats with the water accumulated in the seal groove G1, and the rotary seal body 40 There are cases where it cannot be accommodated in the seal groove G1. In this embodiment, since water can be drained from the drain hole 142h of the wall part g11 (seal support plate part 142) of the seal groove G1, the rotary seal body 40 can be reliably accommodated in the seal groove G1.

  Further, between the metal outer metal lower frame portion 12A and the metal inner metal lower frame portion 12B, a material having lower thermal conductivity than the outer metal lower frame portion 12A and the inner metal lower frame portion 12B is formed. The bridge member 12C is disposed. Therefore, since the bridge member 12C insulates heat transfer between the outer metal lower frame portion 12A and the inner metal lower frame portion 12B, the heat insulation can be enhanced.

  Further, since the rotary seal body 40 is accommodated in the seal groove G1 at the open position, the rotary seal body 40 provided on the lower frame 12 does not hinder walking or the like when the shoji 2 is opened.

  Further, the water accumulated in the seal groove G1 joins and drains the water accumulated in the insertion groove G2 and the guide groove G3. Therefore, it is possible to efficiently collect the drainage paths rather than separately providing the drainage paths for the grooves G1, G2, and G3.

  When the outer metal lower frame portion 12A and the inner metal lower frame portion 12B are connected by the bridge member 12C, the inner plate portion 124 of the outer metal lower frame portion 12A and the inclined plate portion 147 of the inner metal lower frame portion 12B. The bridge material 12C is sandwiched between the two. The bridge member 12C is pressed with a roller from an obliquely vertical direction, and the protrusions 124a, 124b, 147a, 147b are caulked to the bridge member 12C. In the present embodiment, since the groove constituting member 160 is screwed to the outer metal lower frame portion 12A, before attaching the groove constituting member 160 to the outer metal lower frame portion 12A, the roller is connected to the outer groove constituting plate portion 127. It can be inserted into the space between the seal support plate part 142. Therefore, since the space which arrange | positions a roller between the outer side groove | channel structure board part 127 and the seal | sticker support board part 142 can be ensured, the workability | operativity at the time of attaching 12 C of bridge materials is good.

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

  For example, in the embodiment described above, the airtight portion is the rotary seal body 40 that is rotatably provided on the lower frame 12, but the present invention is not limited to this. The hermetic portion is configured to be movable in the vertical direction on the lower frame 12, projecting upward in the closed state of the shoji 2, and configured to be in contact with the shoji 2, or fixed to the lower frame 12 (not movable). Also good.

  Moreover, in embodiment shown above, although a groove part is the seal groove G1 which the rotary seal body 40 can accommodate, this invention is not limited to this. The screen door (not shown) may be provided in the indoor side of the shoji 2, and the structure by which the lower end part of a screen door is arrange | positioned at a groove part may be sufficient.

DESCRIPTION OF SYMBOLS 1 ... Frame 1A ... Metal frame 1X ... Resin frame 2 ... Shoji 2D ... Door 3 ... Connecting rod 11 ... Upper frame 12 ... Lower frame 12A ... Outer metal lower frame part (outdoor side profile)
12B ... Inside metal bottom frame (indoor side profile)
12C ... Bridge material (connecting material)
13 ... Vertical frame 20 ... Housing 22a ... Surface (contact surface)
32 ... Handle 33 ... Lock member 33a ... Lock portion 33b ... Pressing portion 40 ... Rotary seal body (airtight portion)
43 ... Seal member 100 ... Folding door 142a ... Turning shaft 142h ... Drain hole 414 ... Pressed portion A1 ... Opening position A2 ... Sealing position G1 ... Seal groove (groove)
G2 ... Insertion groove G3 ... Guide groove g11 ... Sealing groove (groove part) Outdoor side wall part (outdoor side wall part) G1
g12 ... Bottom g13 ... Wall on the indoor side (indoor side wall) of the seal groove (groove) G1
L ... Airtight line S1 ... Lower hollow S2 ... Upper hollow S3 ... Indoor side hollow T ... Gap

Claims (4)

A folding door in which a shoji is placed in a frame installed along the opening of the building, and the shoji is folded and unfolded to be opened and closed,
The lower frame of the frame body is
Metal outdoor side profile placed on the outdoor side,
Metal indoor side profile placed on the indoor side,
Connecting the outdoor side profile and the indoor side profile, and having a lower thermal conductivity than the outdoor side profile and the indoor side profile,
In the indoor side profile,
An outdoor side wall portion disposed on the outdoor side, an indoor side wall portion disposed on the indoor side, and a bottom portion connecting the lower end portion of the outdoor side wall portion and the lower end portion of the indoor side wall portion, and a groove portion recessed downward.
An airtight part that abuts the lower end of the shoji and closes the gap between the lower end of the shoji and the lower frame; and
The connecting material is disposed outside the groove,
The outdoor side wall is formed with a drain hole capable of draining water,
The folding door is characterized in that the drain hole is disposed above the connecting material.   The folding door according to claim 1, wherein the indoor side wall portion is disposed on an indoor side with respect to a contact surface capable of contacting the airtight portion at a lower end portion of the shoji.   The airtight portion is movable between a sealing position for closing the gap between the lower end portion of the shoji and the lower frame and an opening position for opening the gap, and at the opening position, The folding door of Claim 1 or 2 accommodated in the groove part.   The folding door according to claim 2, wherein at least a part of the connecting material is disposed on the outdoor side of the contact surface of the shoji.

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