WO2016068307A1 - Window - Google Patents

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Publication number
WO2016068307A1
WO2016068307A1 PCT/JP2015/080783 JP2015080783W WO2016068307A1 WO 2016068307 A1 WO2016068307 A1 WO 2016068307A1 JP 2015080783 W JP2015080783 W JP 2015080783W WO 2016068307 A1 WO2016068307 A1 WO 2016068307A1
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WO
WIPO (PCT)
Prior art keywords
shoji
window
frame
glass
spacer
Prior art date
Application number
PCT/JP2015/080783
Other languages
French (fr)
Japanese (ja)
Inventor
横山 和義
原口 博光
勇一 臼井
稔之 久次米
悦史 北原
篤 吉本
耕一 八田
Original Assignee
Agc-Lixilウィンドウテクノロジー株式会社
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Agc-Lixilウィンドウテクノロジー株式会社 filed Critical Agc-Lixilウィンドウテクノロジー株式会社
Priority to JP2016556668A priority Critical patent/JPWO2016068307A1/en
Publication of WO2016068307A1 publication Critical patent/WO2016068307A1/en

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    • EFIXED CONSTRUCTIONS
    • E06DOORS, WINDOWS, SHUTTERS, OR ROLLER BLINDS IN GENERAL; LADDERS
    • E06BFIXED OR MOVABLE CLOSURES FOR OPENINGS IN BUILDINGS, VEHICLES, FENCES OR LIKE ENCLOSURES IN GENERAL, e.g. DOORS, WINDOWS, BLINDS, GATES
    • E06B1/00Border constructions of openings in walls, floors, or ceilings; Frames to be rigidly mounted in such openings
    • E06B1/56Fastening frames to the border of openings or to similar contiguous frames
    • EFIXED CONSTRUCTIONS
    • E06DOORS, WINDOWS, SHUTTERS, OR ROLLER BLINDS IN GENERAL; LADDERS
    • E06BFIXED OR MOVABLE CLOSURES FOR OPENINGS IN BUILDINGS, VEHICLES, FENCES OR LIKE ENCLOSURES IN GENERAL, e.g. DOORS, WINDOWS, BLINDS, GATES
    • E06B3/00Window sashes, door leaves, or like elements for closing wall or like openings; Layout of fixed or moving closures, e.g. windows in wall or like openings; Features of rigidly-mounted outer frames relating to the mounting of wing frames
    • E06B3/04Wing frames not characterised by the manner of movement
    • E06B3/06Single frames
    • E06B3/24Single frames specially adapted for double glazing
    • EFIXED CONSTRUCTIONS
    • E06DOORS, WINDOWS, SHUTTERS, OR ROLLER BLINDS IN GENERAL; LADDERS
    • E06BFIXED OR MOVABLE CLOSURES FOR OPENINGS IN BUILDINGS, VEHICLES, FENCES OR LIKE ENCLOSURES IN GENERAL, e.g. DOORS, WINDOWS, BLINDS, GATES
    • E06B3/00Window sashes, door leaves, or like elements for closing wall or like openings; Layout of fixed or moving closures, e.g. windows in wall or like openings; Features of rigidly-mounted outer frames relating to the mounting of wing frames
    • E06B3/54Fixing of glass panes or like plates
    • E06B3/58Fixing of glass panes or like plates by means of borders, cleats, or the like
    • EFIXED CONSTRUCTIONS
    • E06DOORS, WINDOWS, SHUTTERS, OR ROLLER BLINDS IN GENERAL; LADDERS
    • E06BFIXED OR MOVABLE CLOSURES FOR OPENINGS IN BUILDINGS, VEHICLES, FENCES OR LIKE ENCLOSURES IN GENERAL, e.g. DOORS, WINDOWS, BLINDS, GATES
    • E06B3/00Window sashes, door leaves, or like elements for closing wall or like openings; Layout of fixed or moving closures, e.g. windows in wall or like openings; Features of rigidly-mounted outer frames relating to the mounting of wing frames
    • E06B3/66Units comprising two or more parallel glass or like panes permanently secured together
    • E06B3/663Elements for spacing panes

Definitions

  • the present invention relates to a window capable of increasing the depth of the window with respect to the existing window and increasing the heat insulation of the window by attaching a new window frame to the existing window frame.
  • Patent Document 2 discloses a sliding window in which a new frame (corresponding to a second window frame) is fitted inside an existing frame (corresponding to a first window frame) and a new shoji is mounted on the new frame. It is disclosed. According to Patent Literature 2, since the depth dimension of the window is longer than the existing window by increasing the thickness of the shoji fitted into the new frame, rather than the shoji fitted into the existing frame, the window is highly insulated. Can be achieved.
  • the structure for attaching a new frame to an existing frame according to Patent Document 2 is provided with an angle portion provided with an engaging portion, this angle portion is fixed to the existing frame with a screw, and the new frame is attached to the engaging portion of the angle portion.
  • This is a structure for engaging the engaged portion.
  • JP 2014-133675 A Japanese Patent No. 4822808
  • the window described in Patent Document 2 requires an angle portion having an engagement portion, and thus has a problem that the number of parts increases. Moreover, since the window described in Patent Document 2 requires an operation of fixing the angle portion to the existing frame with screws, there is a problem that it takes time to attach the new frame to the existing frame.
  • This invention is made
  • a first shoji groove portion configured to be fitted with a peripheral edge portion of the first shoji, and a first edge on which a pressing edge is detachably attached.
  • a first window frame provided with a groove for attaching a ledge, and a peripheral edge of a second shoji that is attached to the first groove for attaching a ledge and is thicker than the first shoji.
  • a window characterized by having.
  • the pressing edge is removed from the first pressing edge mounting groove, and the new second frame is mounted in the first pressing edge mounting groove. That is, according to one aspect of the present invention, since the second frame body is mounted using the existing groove for mounting the pressing edge provided in the first window frame, the number of parts can be increased without increasing the number of parts. The second frame can be easily attached to one window frame.
  • the second window frame is provided with a second pressing edge mounting groove portion on which the pressing edge is mounted.
  • the pressing edge is mounted in the second pressing edge mounting groove provided in the second window frame.
  • the second shoji is attached to the second frame, and the second shoji is pressed by the pushing edge by attaching the pushing edge to the second groove for the pushing edge of the second frame.
  • the pushing edge for 1st shoji can be utilized as a pushing edge for 2nd shoji.
  • the second shoji includes a first glass plate and a second glass plate that are separated by a frame around the first glass plate and a hollow layer is formed. It is preferable that the glass is a double-glazed glass that is sealed to the frame at the periphery and in which at least one intermediate glass plate is disposed in the hollow layer.
  • a double glazing and two double glazings are provided. Higher heat insulation can be achieved as compared with the shoji screen.
  • the heat insulating performance can be maximized. It is assumed.
  • the hollow layer is preferably sealed with argon gas or krypton gas having a lower thermal conductivity than air. Thereby, the heat insulation performance of a window can be improved further.
  • the second shoji groove portion of the second window frame is divided into at least a third shoji groove portion and a fourth shoji groove portion, and the second shoji 3 shoji and 4 shoji, the peripheral part of the 3rd shoji is mounted in the groove part for the 3rd shoji, and the peripheral part of the 4th shoji is mounted in the groove part for the 4th shoji It is preferred that
  • a double window that is composed of a third shoji and a fourth shoji and has excellent heat insulation performance.
  • At least one shoji among the third shoji and the fourth shoji is made of a multilayer glass.
  • a double window with further excellent heat insulation performance can be configured.
  • the second window frame has a fitting portion with the first window frame, and the fitting portion is formed in the first edge mounting groove portion of the first window frame. It is preferable that the second window frame is fitted and attached to the first window frame.
  • the first window frame is preferably an existing window frame provided in a housing of a building.
  • the present invention it is possible to provide a window in which the second frame can be easily attached to the first window frame without increasing the number of parts.
  • FIG. 1 is a vertical cross-sectional view of a lower portion of an existing window 10, and a double-layer glass shoji (a first shoji groove portion) 22 is formed on a prospective wall 22 of an existing window frame (first window frame) 20.
  • the first shoji (shoulder) 30 is configured by being attached to the peripheral portion.
  • the window frame 20 is fixed to an opening (not shown) of the building frame.
  • the window frame 20 is provided with a pressing edge 50 and an airtight material 52.
  • the pressing edge 50 is detachably mounted with a fitting portion 50A in a pressing edge mounting groove portion (that is, a first pressing edge mounting groove portion) 24 provided on the prospective wall 22 of the window frame 20, and the lip portion 50B is attached to the pressing edge 50.
  • the glass sheet 32 on the outdoor side of the multilayer glass shoji 30 is closely attached.
  • the airtight member 52 is fitted with the fitting portion 52A in the groove portion 26 for attaching the airtight material provided on the indoor side wall 23 of the window frame 20, and the lip portion 52B is provided on the indoor side of the multilayer glass shoji 30. It is in close contact with the glass plate 34. Thereby, the multilayer glass shoji 30 is pressed against the pressing edge 50 and the airtight material 52 from the outdoor side and the indoor side and is held by the window frame 20.
  • the multi-layer glass shoji 30 is usually a rectangular glass plate 32, a rectangular glass plate 34, a frame-like spacer (that is, a frame) 36, a primary sealing material 38, and a secondary sealing material. 40.
  • the glass plates 32 and 34 have the same surface area and are spaced apart via a spacer 36.
  • Each side surface of the spacer 36 facing the glass plate 32 and the glass plate 34 is bonded to the glass plate 32 and the glass plate 34 by butyl rubber which is a primary sealing material 38.
  • a hollow layer 42 is formed between the glass plate 32 and the glass plate 34.
  • the outer periphery of the spacer 36 is filled with a polysulfide-based or silicone-based sealing material as the secondary seal material 40. Thereby, the multilayer glass shoji 30 is constituted.
  • the spacer 36 is constituted by a hollow pipe, and the gas in the hollow layer 42 is dried by the desiccant 44 filled therein.
  • Reference numeral 46 denotes an opening of the spacer 36 formed to expose the desiccant 44 to the hollow layer 42, and the openings 46 are arranged at predetermined intervals along the longitudinal direction of the spacer 36.
  • the primary sealing material 38 and the secondary sealing material 40 may be the same material. Moreover, you may have another sealing material which protects the secondary sealing material 40 in the outer periphery of the secondary sealing material 40, and may arrange a collar member.
  • the multi-layer glass shoji 30 in which the hollow layer in which the two glass plates 32 and 34 are spaced apart is exemplified as the first shoji, but is not limited to this, and three or more sheets are used. Multi-layer glass provided with a glass plate may be used, or a single plate glass plate may be used.
  • FIG. 2 is a longitudinal sectional view of the lower part of the window 100 according to the embodiment.
  • the window 100 of the embodiment leaves the existing window frame (that is, the first frame) 20 attached to the opening of the building frame, and also has the double-layer glass shoji (that is, the first frame) shown in FIG. ) 30 is removed from the first window frame 20, and an attachment frame (that is, a second window frame) 110, which is a new window frame, is attached to the first window frame 20 from the outdoor side. And a multi-glass shoji 120 (ie, a second shoji) 120, which is a new shoji, is attached to the attachment frame 110.
  • the peripheral edge of the multiple glass shoji 120 is mounted on the prospective wall 22 of the window frame 20 and the prospective wall (second shoji groove portion) 112 of the attachment frame 110.
  • the window 100 of the embodiment by using the multiple glass shoji (second shoji) 120 having a thickness T1 thicker than the thickness T2 of the multi-layer glass shoji (first shoji) 30 of FIG.
  • the depth dimension of the window 100 is made longer than that of FIG. 1 to achieve high heat insulation.
  • the window frame 20 is configured by a four-sided frame of a lower frame 20A, an upper frame (not shown), and left and right vertical frames, and each frame member of the window frame 20 is fixed to the housing by screws.
  • the attachment frame 110 is configured by a four-sided frame of a lower frame 110A, an upper frame (not shown), and left and right vertical frames.
  • the window frame 20 and the attachment frame 110 of the embodiment are both extruded materials of a hard synthetic resin material or an aluminum alloy.
  • the window frame 20 and the attachment frame 110 are for FIX windows that cannot be opened and closed. It is a window frame.
  • the multiple glass shoji 120 uses, for example, a frame in which four spacers, which will be described later, are integrated, and five glass plates that are assumed to be able to exhibit the maximum heat insulation performance are separated. This is a type having four divided hollow layers. The four divided hollow layers are filled with argon gas whose thermal conductivity is smaller than that of air, and the heat insulation performance is further improved.
  • the multiple glass shoji 120 is included in the category of the multi-layer glass shoji.
  • FIG. 3 is an overall perspective view of the multiple glass screen 120
  • FIG. 4 is a vertical sectional view of the lower portion of the multiple glass screen 120. As shown in FIG.
  • the multiple glass shoji 120 includes a glass plate (first glass plate) 122 disposed on the outdoor side of the building and a glass plate (second glass plate) 124 disposed on the indoor side. And three intermediate glass plates 126A, 126B, 126C disposed between the glass plate 122 and the glass plate 124, the glass plate 122 and the glass plate 124, and the intermediate glass plates 126A, 126B, It includes a spacer (frame body) 128 that holds 126C in a spaced manner, and a support plate 200 that supports the spacer 128 from the outside. As shown in FIG. 5 and FIG.
  • the four parts are connected to each other by a corner key (also referred to as a corner piece) 150 that is a spacer connecting member, and are configured in a frame shape, and at the four corners where the end portions of the four support plates 200 are respectively abutted.
  • a support plate corner key also referred to as a corner piece
  • the intermediate glass plates 126A, 126B, and 126C are simply referred to as the intermediate glass plate 126 when collectively referred to.
  • the glass plate 122 and the glass plate 124 are separated by a spacer 128 around the periphery. Thereby, a hollow layer is formed between the glass plate 122 and the glass plate 124.
  • the hollow layer formed by the glass plate 122, the glass plate 124, and the spacer 128 is sealed by the spacer 128 at the periphery, and the three intermediate glass plates 126A, 126B, and 126C are arranged apart from each other.
  • the hollow layer is divided into four divided hollow layers 130.
  • the spacer 128 is connected to the inner surface portion 132 and the outer surface side portion 134, and the inner surface portion 132 and the outer surface side portion 134 that maintain the distance between the glass plate 122 and the glass plate 124. It is comprised from the side part 136,136 contact
  • the spacer 128 is provided with three rows of groove portions 142 on the inner surface portion 132 of the spacer 128 in order to hold a part of the peripheral portion of the three intermediate glass plates 126A, 126B, 126C.
  • the three rows of grooves 142 are formed in parallel along the longitudinal direction of the spacer 128 so that the three intermediate glass plates 126A, 126B, 126C are arranged in parallel.
  • the space portion 140 is divided into four in the left-right direction by forming the groove portion 142 for holding the intermediate glass plate 126 in the spacer 128.
  • the number of spaces 140 is determined according to the number of intermediate glass plates 126.
  • the spacer 128 of the embodiment is integrally formed so as to have a plurality of spaces 140 and a plurality of grooves 142.
  • the spacer 128 is molded from a spacer forming material.
  • a molding method such as an extrusion molding method, a co-extrusion molding method, or an injection molding method can be used.
  • the spacer forming material a synthetic resin material is preferably used.
  • the synthetic resin material for forming the spacer is preferably a hard vinyl chloride resin material, an acrylonitrile / styrene resin material, or a material in which a glass fiber material is added, but is not limited to these thermoplastic synthetic resin materials.
  • Various thermoplastic synthetic resin materials can also be used.
  • the spacer frame forming material is not limited to one type, and may be a composite structure using a plurality of types of materials.
  • it may be a composite structure frame made of different synthetic resin materials partially by different co-extrusion molding methods, or a composite structure frame made of a synthetic resin material and an aluminum material.
  • this composite structure it is only necessary that the composite structure is integrally formed of any one kind of spacer forming material.
  • the integrally molded spacer 128 may be partially or entirely joined with different synthetic resin materials and / or metal materials.
  • the spacer 128 formed of a hard vinyl chloride resin material or an acrylonitrile / styrene resin material has excellent heat insulation when used as the multiple glass shoji 120, is easy to be integrally molded, has excellent durability, and is inexpensive. It is.
  • a glazing channel 144 for supporting the end portions of the intermediate glass plates 126A, 126B, and 126C is fitted.
  • the intermediate glass plates 126 ⁇ / b> A, 126 ⁇ / b> B, 126 ⁇ / b> C can be easily adhered and fixed to the groove 142 of the spacer 128 by the glazing channel 144. Further, the thickness of each divided hollow layer 130 can be changed by decentering the glazing channel 144.
  • the pressure applied to the intermediate glass plates 126A, 126B, and 126C from the spacer 128 by the glazing channel 144 is reduced. Can be mitigated by the glazing channel 144.
  • the glazing channel 144 can be partially arranged in the groove 142. By providing a portion where the glazing channel 144 is not disposed in the groove portion 142, the divided hollow layers 130 can be communicated with each other, and the pressure inside each divided hollow layer 130 can be equalized.
  • the glazing channel 144 is not partially provided, it is preferably provided near the corners of the respective sides of the intermediate glass plates 126A, 126B, and 126C.
  • the glazing channel 144 is preferably made of a resin having a Shore A hardness of 50 to 90 degrees (for example, vinyl chloride resin or urethane resin) or rubber. If the Shore A hardness is less than 50 degrees, it is too soft and it is difficult to obtain a sufficient holding force for the intermediate glass plates 126A, 126B, 126C. If the Shore A hardness exceeds 90 degrees, the intermediate glass plate is too hard. This is because it is difficult to fit 126A, 126B, and 126C.
  • a resin having a Shore A hardness of 50 to 90 degrees for example, vinyl chloride resin or urethane resin
  • the glazing channel 144 is not limited to the shape shown in FIGS. 2 and 3, and a glazing channel 144 having another shape may be used.
  • the glass plates 122 and 124 When the two glass plates 122 and 124 have a rectangular flat plate shape, the glass plates 122 and 124 are separated by four spacers 128 arranged in the vicinity of the periphery of the four sides.
  • FIG. 5 is a perspective view showing a corner key 150 for connecting the spacers 128 to each other.
  • a corner key 150 that is a spacer connecting member, and a continuous frame-shaped spacer (frame body) is configured.
  • the spacer 128 has an end face 160 that faces the main body 152 of the corner key 150.
  • a through hole 162 is formed in the inner surface 132 of the spacer 128. The through hole 162 communicates with the space 140 (see FIG. 4).
  • the corner key 150 has a main body portion 152 and an insertion portion 154 that protrudes from the main body portion 152 and is arranged in an L shape, and a through hole 156 is formed in the insertion portion 154.
  • an insertion portion 154 arranged in an L shape is integrally formed with the main body portion 152 corresponding to the plurality of space portions 140 of the spacer 128.
  • the insertion portion 154 of the corner key 150 is inserted into the space portion 140 of the spacer 128 until the end surface 160 of the spacer 128 contacts the main body portion 152 of the corner key 150.
  • the cross-sectional area of the insertion portion 154 is smaller than the cross-sectional area of the space portion 140, and the insertion portion 154 is inserted with almost no contact with the inner wall of the space portion 140, so that the occurrence of cracks and the like in the spacer 128 is suppressed. can do.
  • the through hole 162 of the spacer 128 and the through hole 156 of the insertion portion 154 of the corner key 150 are aligned to a position where they are seen from the inner surface portion 132 side.
  • a screw 158 as a fixing member is inserted into the through hole 162 of the spacer 128 from the outside of the space 140.
  • the screw 158 passes through the inner surface portion 132 of the spacer 128 and reaches the through hole 156 of the insertion portion 154.
  • the screw 158 is fastened to the through hole 162 of the spacer 128 and the through hole 156 of the insertion portion 154. Since the screw 158 penetrates the spacer 128, the spacer 128 and the insertion portion 154 of the corner key 150 can be securely fixed by the screw 158.
  • the outside of the space part 140 means the opposite side of the space part 140 with the spacer 128 as a boundary with respect to the space part 140 formed inside the spacer 128.
  • the screw 158 is inserted from the outer side of the inner surface part 132 toward the space part 140.
  • the outer side part 134 or the outer side parts 136 and 136 are outside. It is also possible to insert a screw 158 toward the space 140 from the top.
  • the through hole 162 is formed in the spacer 128 and the through hole 156 is formed in the insertion portion 154 as the pilot hole of the screw 158.
  • a through-hole can be directly opened in the spacer 128 and the insertion portion 154.
  • the corner key 150 is fixed to the corner 128 at two locations near the glass plates 122 and 124 of the spacer 128 by the screws 158, but is not limited thereto. For example, it can be fixed at four locations where the space 140 is formed or at two locations located inside the spacer 128.
  • the corner key 150 having the main body 152 and the insertion portion 154 is preferably integrally molded with a hard synthetic resin material (for example, a hard polyvinyl chloride resin material, an acrylonitrile / styrene resin material, or a polypropylene resin material).
  • the integral molding means that the corner key forming material is molded by an integral molding method such as a shaving method, a molding method, a modeling method using a 3D printer, or an injection molding method. If integrally molded in this way, the corner key 150 can be easily formed into a single member, the number of parts of the corner key 150 can be reduced, and the assembly process can be simplified.
  • the four divided hollow layers 130 are filled with argon gas having a thermal conductivity smaller than that of air, so that the heat insulation performance of the multiple glass shovel 120 is enhanced.
  • the argon gas is dried by the desiccant 138 stored in the space 140 of the spacer 128. This prevents internal condensation of the glass plates 122 and 124 and the intermediate glass plates 126A, 126B, and 126C.
  • the thickness of the divided hollow layer 130 is set to 13 mm to 17 mm, which is a thickness that can sufficiently exhibit the heat insulation performance.
  • the thickness of the divided hollow layer 130 is set so as to have a width of 2 mm before and after the optimum value (15 mm) at which the heat insulation performance can be maximized.
  • the number of divided hollow layers 130 is determined according to the number of intermediate glass plates 126. If high heat insulation is not particularly required, the above-described divided hollow layer 130 may be filled with dry air or other inert gas.
  • the glass plates 122 and 124 are usually rectangular flat glass plates in many cases, and the thickness of each is preferably in the range of 1.3 mm to 3 mm in order to reduce the weight. , 124 are the same or substantially the same size.
  • the glass plates 122 and 124 may have different thicknesses as long as they are within the above thickness range. Furthermore, the glass plates 122 and 124 are preferably chemically strengthened glass having sufficient strength even if the thickness is reduced. That is, by making the glass plates 122 and 124 chemically tempered glass, impact resistance performance and wind pressure resistance performance can be obtained even if the thickness is 1.3 mm to 3 mm.
  • a chemically strengthened glass plate is a glass plate containing a Na component or a Li component such as soda lime silicate glass immersed in a molten salt such as potassium nitrate, and has a small atomic diameter Na ion and / or Alternatively, the strength is increased by replacing the Li ions with K ions having a large atomic diameter present in the molten salt to form a compressive stress layer on the surface layer of the glass plate. According to the chemically strengthened glass, even a glass plate having a thickness of 2 mm or less has a sufficiently high breaking strength.
  • the thin glass plates 122 and 124 having a thickness of 1.3 mm to 3 mm are sufficient as the glass plates 122 and 124 disposed on the outside. High strength can be obtained.
  • the intermediate glass plates 126A, 126B, and 126C are rectangular flat glass plates, and the thicknesses of the intermediate glass plates 126A, 126B, and 126C are in the range of 1 mm to 2 mm in order to reduce the weight.
  • the dimensions of the intermediate glass plates 126A, 126B, and 126C are as follows. Are the same or substantially the same size.
  • the intermediate glass plates 126A, 126B, 126C may have different thicknesses as long as they are within the above thickness range. Further, similar to the glass plates 122 and 124, the intermediate glass plates 126A, 126B, and 126C may be chemically strengthened glass having sufficient strength even if the thickness is reduced. For example, chemically tempered glass having a thickness of 1 mm to 2 mm has a static bending strength equivalent to that of non-tempered glass such as float glass having a thickness of 3 mm to 6 mm.
  • the intermediate glass plates 126A, 126B, and 126C are preferably formed in a similar rectangular shape with a smaller dimension than the glass plates 122 and 124 so that they can be inserted into the groove 142 of the spacer 128.
  • the multiple glass shoji 120 is configured by including at least one intermediate glass plate 126.
  • the number of intermediate glass plates may be four or more. Therefore, according to the multiple glass shoji 120, even when the temperature of the divided hollow layer 130 decreases and the internal pressure of the divided hollow layer 130 decreases, the end of the intermediate glass plate 126 supports the spacer 128.
  • the intermediate glass plate 126 can suppress deformation toward the divided hollow layer 130.
  • Low-E Low-Emissivity
  • Low-E Low-Emissivity
  • the glass plates 122 and 124 and the intermediate glass plates 126A and 126C can be configured as Low-E glass.
  • Low-E glass is, for example, a low emission film mainly composed of tin oxide (SnO 2 ) formed on the surface of a glass plate using a chemical vapor deposition apparatus, a sputtering apparatus, or the like, or silver (Ag).
  • the main low emission film is formed using a sputtering apparatus or the like, and has a function of reducing the emissivity of thermal energy by infrared rays.
  • the low emission film mainly composed of silver (Ag) includes a type in which a silver film is laminated with an oxide film, a nitride film or the like. That is, Low-E glass has a performance that hardly allows heat to pass through, and thus has high heat shielding properties and heat insulation properties.
  • the low-emission film mainly composed of silver has the property of being easily oxidized by moisture in the air. Therefore, when used for double-glazed glass, it should be formed on the side facing the sealed hollow layer. Is preferred.
  • the low-emission film mainly composed of tin oxide has lower heat ray reflection performance and lower heat-shielding performance than the low-emission film mainly composed of silver, but compared with the low-emission film mainly composed of silver.
  • a low radiation film mainly composed of tin oxide can be provided on at least one outer surface of the glass plates 10 and 12.
  • the emissivities of the low emission films 166A, 166B, 166C, 166D can be made different. Thereby, the temperature of the division
  • thermo cracking can be suppressed by providing a heat insulating material on the lower surface of the window frame 20 and the attachment frame 110. Moreover, you may provide a heat insulating material in the hollow part 202 of the support plate 200 mentioned later.
  • a low radiation film 166A having a relatively low emissivity is formed on the inner surface of the glass plate 122 outside the room.
  • a low emission film 166B having a higher emissivity than the low emission film 166A is formed on the surface of the intermediate glass plate 126A facing the intermediate glass plate 126B.
  • a low emission film 166B having a higher emissivity than the low emission film 166A is formed on the surface of the intermediate glass plate 126C facing the intermediate glass plate 126B.
  • a low radiation film 166D having a higher emissivity than the low radiation film 166A is formed on the inner surface of the glass plate 122 on the outdoor side.
  • the low radiation films 166B, 116C, and 116D may have the same or different vertical emissivities. Further, no low radiation film is formed on the intermediate glass plate 126B.
  • the low radiation film 166A having a relatively low emissivity on the glass plate 122 on the outdoor side it is possible to suppress the temperature rise inside the divided hollow layer 130 and the temperature rise of the intermediate glass plates 126A, 126B, 126C. Further, by using a transparent glass plate instead of Low-E glass as the central intermediate glass plate 126B where the glass temperature rises greatly, an increase in temperature near the center of the intermediate glass plate 126 can be suppressed.
  • the low radiation films 166A and 166C of the intermediate glass plates 126A and 126C have a higher emissivity than the low radiation film 166A, the solar radiation heat is highly permeable and heat is prevented from being absorbed by the central glass plate 126. It is easy to be transmitted to the glass plate 124 on the indoor side. Therefore, it is possible to suppress the temperature absorption of the intermediate glass plates 126A and 126C of the divided hollow layer 130 while ensuring the heat insulating performance.
  • the temperature rise of the intermediate glass plates 126A, 126B, 126C and the divided hollow layer 130 can be suppressed, the thermal stress can be reduced, and “thermal cracking” can be suppressed.
  • the support plate 200 is a member that supports and reinforces the spacer 128. For this reason, the support plate 200 is disposed at a position facing the outer surface side portion 134 of each spacer 128.
  • the support plate 200 is connected by a corner key 250.
  • the support plate 200 Since the spacer 128 is supported from the outside by the support plate 200, even if the internal pressure of the divided hollow layer 130 increases due to the temperature rise and the spacer 128 tries to expand to the opposite side of the divided hollow layer 130, the support plate 200 It is possible to suppress the spacer 128 from expanding outward.
  • the thickness of the hollow layer between the glass plate 122 and the glass plate 124 becomes very thick compared to a multi-layer glass composed of two normal glass plates. For this reason, the pressure that the spacer 128 receives from the thermally expanding hollow layer is much larger than that of the multi-layer glass, and a single spacer 128 may not be able to cope with it.
  • the spacer 128 is made of resin, it has a property of being easily expanded as compared with a metal. Therefore, in the multiple glass shovel 120 of the embodiment, since the support plate 200 that supports the outside of the spacer 128, reinforces the spacer 128, and suppresses the expansion of the spacer 128 is provided, it can counter the increased internal pressure. Can do. Thereby, the multiple glass shoji 120 with a long service life can be provided.
  • the support plate 200 has a hollow structure having four hollow portions 202 inside in a cross-sectional shape. Since it has a hollow structure, the rigidity of the support plate 200 can be maintained. Moreover, the heat insulation performance of the window 100 can be improved by inserting a heat insulating material into the hollow portion 202.
  • the support plate 200 has substantially the same length as the spacer 128 in order to support the spacer 128, and has a width shorter than the width of the spacer 128.
  • a secondary sealant 182 is provided between the support plate 200 and the glass plate 122 and between the support plate 200 and the glass plate 122. Further, a moisture permeation preventing layer 190 is provided between the spacer 128 and the support plate 200.
  • the support plate 200 is integrally formed so as to have a plurality of hollow portions 202.
  • the support plate 200 is molded from a support plate forming material.
  • a molding method such as an extrusion molding method, a coextrusion molding method, or an injection molding method can be used.
  • the support plate forming material a synthetic resin material is preferably used.
  • the synthetic resin material for forming the support plate is preferably a hard vinyl chloride resin material, an acrylonitrile / styrene resin material, or a material in which a glass fiber material is added, but is not limited to these thermoplastic synthetic resin materials.
  • Various thermoplastic synthetic resin materials can also be used.
  • the support frame forming material is not limited to one type, and may be a composite structure using a plurality of types of materials.
  • it may be a composite structure frame made of different synthetic resin materials partially by different co-extrusion molding methods, or a composite structure frame made of a synthetic resin material and an aluminum material.
  • this composite structure it is only necessary that the composite structure is integrally formed of any one kind of spacer forming material.
  • the integrally formed support plate 200 may be partially or entirely joined with different synthetic resin materials and / or metal materials.
  • the support plate 200 formed of a hard vinyl chloride resin material or acrylonitrile / styrene resin material is excellent in heat insulation when used as the multiple glass shoji 120, easy to be integrally molded, and excellent in durability. Inexpensive.
  • FIG. 6 is a perspective view of a corner key 250 that connects the support plates 200 together.
  • the adjacent support plates 200 are connected to each other by a corner key 250 that is a support plate connecting member, thereby forming a continuous frame-shaped support plate. .
  • the support plate 200 has an end face 230 that faces the main body 252 of the corner key 250.
  • a through hole 232 is formed in the outer surface portion 214 of the support plate 200. The through hole 232 passes through the hollow portion 202.
  • the corner key 250 has a main body portion 252 and an insertion portion 254 that protrudes from the main body portion 252 and is arranged in an L shape, and a through hole 256 is formed in the insertion portion 254.
  • an insertion portion 254 arranged in an L shape is formed integrally with the main body portion 252 corresponding to the plurality of hollow portions 202 of the support plate 200.
  • the insertion portion 254 of the corner key 250 is inserted into the hollow portion 202 of the support plate 200 until the end surface 230 of the support plate 200 contacts the main body portion 252 of the corner key 250.
  • the cross-sectional area of the insertion portion 254 is smaller than the cross-sectional area of the hollow portion 202, and the insertion portion 254 is hardly in contact with the inner wall of the hollow portion 202, and it is possible to suppress the occurrence of cracks or the like in the support plate 200.
  • the through hole 232 of the support plate 200 and the through hole 256 of the insertion portion 254 of the corner key 250 are aligned with each other.
  • a screw 258 as a fixing member is inserted into the hole 232 of the support plate 200 from the outer surface portion 214.
  • the screw 258 passes through the support plate 200 and reaches the through hole 256 of the insertion portion 254.
  • the screw 258 is fastened to the through hole 232 of the support plate 200 and the through hole 256 of the insertion portion 254. Since the screw 258 penetrates the support plate 200, the support plate 200 and the insertion portion 254 of the corner key 250 can be securely fixed by the screw 258.
  • the through hole 232 is formed in the support plate 200 and the through hole 256 is formed in the insertion portion 254 as the pilot hole of the screw 258.
  • the tapping screw is used as the screw 258 as a fixing member.
  • a through hole can be directly opened in the support plate 200 and the insertion portion 254.
  • the corner keys 250 are fixed to the corner plate 250 at two locations near the glass plates 122 and 124 of the support plate 200 by the screws 258, but the present invention is not limited to this. For example, it can be fixed at four locations where the hollow portion 202 is formed, or at two locations located inside the support plate 200.
  • the corner key 250 having the main body portion 252 and the insertion portion 254 is preferably integrally molded with a hard synthetic resin material (for example, a hard polyvinyl chloride resin material, an acrylonitrile / styrene resin material, or a polypropylene resin material).
  • the integral molding means that the corner key forming material is molded by an integral molding method such as a shaving method, a molding method, a modeling method using a 3D printer, or an injection molding method. If integrally molded in this way, the corner key 250 can be easily formed into a single member, the number of parts of the corner key 250 can be reduced, and the assembly process can be simplified. .
  • FIG. 7 is an explanatory view showing a state in which the spacer 128 and the corner key 150 are connected by screws 158 and a state in which the support plate 200 and the corner key 250 are connected by screws 258.
  • the support plate 200 is disposed outside the spacer 128, and the spacer 128 is supported by the support plate 200 and reinforced.
  • the multiple glass shoji 120 includes a sealing material 180 and a secondary sealing material 182. Side portions 136 and 136 of the spacer 128 facing the glass plate 122 and the glass plate 124 are joined to the glass plate 122 and the glass plate 124 by butyl rubber which is a sealing material 180. The outer surface side portion 134 of the spacer 128 is filled with a polysulfide-based or silicone-based sealing material that is the secondary seal material 182. Thereby, the multiple glass shoji 120 is configured.
  • the sealing material 180 and the secondary sealing material 182 are not limited to the above forms, and the sealing material to be bonded on the glass plates 122 and 124 and the sealing material applied to the outer surface side portion 134 side of the spacer 128 are made of the same material. Also good. Furthermore, you may have another sealing material which protects the secondary sealing material 182 in the outer periphery of the secondary sealing material 182. FIG.
  • the secondary sealant 182 is provided between the support plate 200 and the glass plate 122 and between the support plate 200 and the glass plate 124. Provided.
  • the usage amount of the secondary sealing material 182 can be reduced. Further, the secondary sealing material 182 can be formed in an optimal shape by the support plate 200. Further, even if the total thickness of the multiple glass shoji 120 is changed, the secondary sealing material 182 can be set to a predetermined size by the support plate 200.
  • the support plate 200 is an object to which the secondary sealant 182 is attached, stable adhesion performance can be ensured (that is, two-sided adhesion). That is, the holding force of the secondary sealing material 182 can be expressed.
  • a moisture permeation preventive layer 190 that prevents moisture from permeating from the outside is formed on the side of the divided hollow layer 130 of the multiple glass shoji 120.
  • the spacer 128 is formed of a synthetic resin material, for example, a hard polyvinyl chloride resin material, or an acrylonitrile / styrene resin material
  • the material itself is about the same as an aluminum spacer that has a high moisture permeation prevention property.
  • moisture permeability prevention There is a demand for moisture permeability prevention.
  • the moisture permeation preventing layer 190 a layer made of a material capable of preventing moisture from passing through the spacer 128 itself into the divided hollow layer 130 is selected.
  • the moisture permeation preventive layer 190 is preferably a layer formed by applying a moisture permeation preventive paint and cured, or a layer formed by attaching a moisture permeation preventive film.
  • Typical examples of the moisture permeation preventing paint include a fluororesin paint and a polyvinylidene chloride resin paint.
  • Moisture permeation-preventing film-like body includes metal-coated film with anti-moisture performance, ceramic-coated film, composite coating film of metal and ceramic, metal tape, and the film itself made of resin with anti-moisture performance Examples thereof include a prevention resin film or a moisture permeation prevention resin-coated film.
  • a moisture permeation-preventing film-like body obtained by laminating a butyl tape made of a butyl rubber adhesive and a metal tape such as an aluminum foil or a stainless steel foil can also be preferably used.
  • the space 140 can be filled with a desiccant 138 such as zeolite or silica gel. With this desiccant 138, the gas in the divided hollow layer 130 can be dried. The desiccant 138 is exposed to the divided hollow layer 130 through an opening (not shown) formed in the inner surface 132 of the spacer 128.
  • a desiccant 138 such as zeolite or silica gel.
  • the moisture permeation preventing layer 190 can be protected.
  • the above is the configuration of the multiple glass shoji 120.
  • the pressing edge 50 is removed from the pressing edge mounting groove portion (that is, the first pressing edge mounting groove portion) 24, and the pressing edge mounting groove portion 24 is removed.
  • the fitting portion 114 of the attachment frame (that is, the second window frame) 110 is attached to the. That is, the window 100 of the embodiment uses the existing pressing edge mounting groove portion 24 provided in the window frame 20, and the attachment frame 110 for mounting the multiple glass shoji (that is, the second shoji) 120.
  • the attachment frame 110 can be easily attached to the window frame 20 without significantly increasing the number of parts.
  • the fitting portion 50 ⁇ / b> A of the pressing edge 50 is mounted in the pressing edge mounting groove portion (that is, the second pressing edge mounting groove portion) 116 provided in the attachment frame 110, and the lip of the pressing edge 50 is mounted.
  • the multiple glass screen 120 is held by pressing the multiple glass screen 120 from the outdoor side and the indoor side by the portion 50B and the lip 52B of the airtight member 52 of the window frame 20. That is, the multiple glass shoji 120 can be pressed against the airtight member 52 by attaching the multiple glass shoji 120 to the attachment frame 110 and attaching the press rim 50 to the push edge mounting groove 116 of the attachment frame 110.
  • the pushing edge 50 of the multilayer glass shoji (that is, the first shoji) 30 can be effectively used as the pushing edge 50 of the multiple glass shoji 120.
  • the attachment frame 110 includes a leg portion 118 at a lower portion of the outdoor front end, and the leg portion 118 and the fitting portion 114 are used to support the attachment frame 110 in the window so that the leg portion 118 is supported by the inclined portion 28 of the window frame 20. It can be stably attached to the frame 20.
  • FIG. 8 is a longitudinal sectional view of the lower part of the window 300 of another embodiment.
  • the shoji 320 which is the second shoji is shown in a simplified manner.
  • the structure of the window 300 in FIG. 8 differs from the window 100 in FIG. 2 in that the attachment side wall 312 is provided on the attachment frame 310, which is the second window frame, and the indoor side wall 312 is pressed by the airtight member 52. Is provided with a lip portion 314 that contacts the shoji 320.
  • FIG. 9 is a longitudinal sectional view of the lower part of the window 400 of another embodiment.
  • the shoji 420 which is the second shoji is shown in a simplified manner.
  • the window 400 of FIG. 9 differs from the window 300 of FIG. 8 in that the attachment frame 410, which is the second window frame, includes an outdoor wall 412 and the outdoor wall 412 has a lip portion 414 that contacts the shoji 420. Is provided.
  • the pushing edge 50 of FIG. 8 is not used, but the outdoor side wall 412 can be substituted as the pushing edge.
  • FIG. 10 is a longitudinal sectional view of the lower part of the window 500 of another embodiment.
  • the second shoji is composed of two multi-layer glass shojis 30 (where one multi-layer glass shoji is the third shoji and the other multi-layer glass shoji is the fourth shoji.
  • the second shoji that is, the third shoji and the fourth shoji are attached to an attachment frame 510 which is a second window frame.
  • the example of a multilayer glass shoji is given as the third shoji and the fourth shoji, but one of the third shoji and the fourth shoji may be a multiple glass shoji.
  • a single glass plate may be used.
  • the prospective wall 512 which is the second groove part for the shoji of the attachment frame (second window frame) 510, is divided into the outdoor side and the indoor side by the partition wall 514 erected substantially at the center of the prospective wall 512.
  • the third shoji groove and the fourth shoji groove are divided.
  • the multi-layer glass shoji 30 which is the 3rd shoji and the multi-layer glass shoji 30 which is the 4th shoji in each of the groove part for 3rd shoji and the 4th groove of the shoji of the divided prospect wall 512
  • the peripheral part is installed.
  • a lip portion 516 is provided on the outdoor side surface of the partition wall 514, and a lip portion 518 is also provided on the indoor side surface.
  • the multi-layer glass shoji 30 attached to the outdoor side is held by the lip portion 414 and the lip portion 516, and the multi-layer glass shoji 30 attached to the indoor side is held by the lip portion 314 and the lip portion 518. .
  • a double window composed of two double-layer glass shojis 30 and excellent in heat insulation performance can be configured.
  • one of the two multilayer glass shojis 30 may be replaced with a multiple glass shoji or may be replaced with a single glass plate.
  • the window which can attach a 2nd frame to a 1st window frame easily can be provided, without increasing a number of parts. It should be noted that the entire contents of the specification, claims, drawings and abstract of Japanese Patent Application No. 2014-221620 filed on October 30, 2014 are incorporated herein by reference. .
  • fitting portion 116 ... groove for attaching ledge (second groove for attaching ledge), 118 ... leg, 120 ... multiple glass shoji (second shoji), 122, 124 ... glass plate, 126, 126A, 126B, 126C ... intermediate glass plate 128 ... spacers 130 ... split hollow layers 132 ... Surface part, 134 ... Outer surface side part, 136 ... Side edge part, 138 ... Desiccant, 140 ... Space part, 142 ... Groove part, 144 ... Glazing channel, 150 ... Corner key, 152 ... Body part, 154 ... Insertion part, 156 ... Through hole, 158 ... screw, 160 ... end face, 162 ...

Landscapes

  • Engineering & Computer Science (AREA)
  • Civil Engineering (AREA)
  • Structural Engineering (AREA)
  • Securing Of Glass Panes Or The Like (AREA)
  • Door And Window Frames Mounted To Openings (AREA)

Abstract

Provided is a window which makes it possible to easily attach a second frame body to a first window frame without increasing the number of components thereof. A window 100, wherein molding 50 is removed from a molding-mounting groove 24 in an existing window frame 20, and an engaging part 114 of an attachment frame 110 is mounted to the molding-mounting groove 24. In other words, by using the existing molding-mounting groove 24 provided in the window frame 20, the window 100 makes it possible to mount the attachment frame 110 for mounting a multilayer-glass sliding door 120. As a result, it is possible to easily attach the attachment frame 110 to the window frame 20 without increasing the number of components involved. In addition, the window 100 makes it possible to mount an engaging part 50A of the molding 50 to a molding-mounting groove 116 provided in the attachment frame 110, and to hold the multilayer-glass sliding door 120 by pressing on the multilayer-glass sliding door 120 from the outside and from the inside by using a lip section 50B of the molding 50 and a lip section 52B of an airtightness member 52 in the window frame 20.

Description

window
 本発明は、既設の窓枠に新設の窓枠を装着することにより、既設の窓に対して窓の奥行き寸法を長くして窓の高断熱化を図ることができる窓に関する。 The present invention relates to a window capable of increasing the depth of the window with respect to the existing window and increasing the heat insulation of the window by attaching a new window frame to the existing window frame.
 建築物の外壁として窓ガラスを使用する場合には、室内の冷暖房の効率を高めるために、所定の断熱性能(熱貫流率:U値(JIS R3107:1998年)、単位:W/m・K)が要求される。このため、近年では、単板のガラス板と比較して断熱性能が高い(すなわち、U値が低い)複層ガラス(特許文献1等参照)が、窓ガラスのガラス板として使用される傾向にある。 When using window glass as the outer wall of a building, in order to increase the efficiency of indoor air conditioning, the prescribed heat insulation performance (heat transmissivity: U value (JIS R3107: 1998), unit: W / m 2 · K) is required. For this reason, in recent years, a double-glazed glass (see Patent Document 1 or the like) having a high thermal insulation performance (that is, a low U value) compared to a single-plate glass plate tends to be used as a glass plate for window glass. is there.
 ところで、特許文献2には、既設枠(第1の窓枠に相当)の内側に新設枠(第2の窓枠に相当)を嵌め込み、新設枠に新しい障子を装着してなる引き違い窓が開示されている。特許文献2によれば、既設枠に嵌め込まれる障子よりも、新設枠に嵌め込む障子の厚さを厚くすることにより、既設の窓に対して窓の奥行き寸法が長くなるので、窓の高断熱化を図ることができる。 By the way, Patent Document 2 discloses a sliding window in which a new frame (corresponding to a second window frame) is fitted inside an existing frame (corresponding to a first window frame) and a new shoji is mounted on the new frame. It is disclosed. According to Patent Literature 2, since the depth dimension of the window is longer than the existing window by increasing the thickness of the shoji fitted into the new frame, rather than the shoji fitted into the existing frame, the window is highly insulated. Can be achieved.
 特許文献2による既設枠に対する新設枠の取り付け構造は、係合部を備えたアングル部を用意し、このアングル部をねじによって既設枠に固定し、アングル部の前記係合部に、新設枠の被係合部を係合させる構造である。 The structure for attaching a new frame to an existing frame according to Patent Document 2 is provided with an angle portion provided with an engaging portion, this angle portion is fixed to the existing frame with a screw, and the new frame is attached to the engaging portion of the angle portion. This is a structure for engaging the engaged portion.
特開2014-133675号公報JP 2014-133675 A 特許第4822808号公報Japanese Patent No. 4822808
 しかしながら、特許文献2に記載の窓は、係合部を備えたアングル部を必要とするので、部品点数が増えるという問題があった。また、特許文献2に記載の窓は、アングル部を既設枠にねじによって固定する作業を要するので、既設枠に対する新設枠の取り付けに手間がかかるという問題もあった。 However, the window described in Patent Document 2 requires an angle portion having an engagement portion, and thus has a problem that the number of parts increases. Moreover, since the window described in Patent Document 2 requires an operation of fixing the angle portion to the existing frame with screws, there is a problem that it takes time to attach the new frame to the existing frame.
 本発明は、このような事情に鑑みてなされたもので、部品点数を増やすことなく、第1の窓枠に第2の枠体を容易に取り付けることができる窓を提供することを目的とする。 This invention is made | formed in view of such a situation, and it aims at providing the window which can attach a 2nd frame to a 1st window frame easily, without increasing a number of parts. .
 本発明の一態様は、前記目的を達成するために、第1の障子の周縁部が装着されるように構成された第1の障子用溝部と、押縁が着脱自在に装着される第1の押縁装着用溝部とを備えた第1の窓枠と、前記第1の押縁装着用溝部に装着されて、前記第1の障子よりも厚さの厚い第2の障子の周縁部が装着されるように構成された第2の障子用溝部を備えた第2の窓枠と、前記第2の窓枠の前記第2の障子用溝部に周縁部が装着された前記第2の障子と、を有することを特徴とする窓を提供する。 In order to achieve the above object, according to one aspect of the present invention, a first shoji groove portion configured to be fitted with a peripheral edge portion of the first shoji, and a first edge on which a pressing edge is detachably attached. A first window frame provided with a groove for attaching a ledge, and a peripheral edge of a second shoji that is attached to the first groove for attaching a ledge and is thicker than the first shoji. A second window frame having a second shoji groove configured as described above, and the second shoji having a peripheral edge attached to the second shoji groove of the second window frame. Provided is a window characterized by having.
 本発明の一態様によれば、既設の第1の窓枠において、第1の押縁装着用溝部から押縁を取り外し、第1の押縁装着用溝部に新設の第2の枠体を装着する。すなわち、本発明の一態様は、第1の窓枠に備えられている、既存の押縁装着用の溝部を利用して、第2の枠体を装着したので、部品点数を増やすことなく、第1の窓枠に第2の枠体を容易に取り付けることができる。 According to one aspect of the present invention, in the existing first window frame, the pressing edge is removed from the first pressing edge mounting groove, and the new second frame is mounted in the first pressing edge mounting groove. That is, according to one aspect of the present invention, since the second frame body is mounted using the existing groove for mounting the pressing edge provided in the first window frame, the number of parts can be increased without increasing the number of parts. The second frame can be easily attached to one window frame.
 本発明の一態様は、前記第2の窓枠には、前記押縁が装着される第2の押縁装着用溝部が備えられることが好ましい。 In one aspect of the present invention, it is preferable that the second window frame is provided with a second pressing edge mounting groove portion on which the pressing edge is mounted.
 本発明の一態様によれば、第2の窓枠に備えられた第2の押縁装着用溝部に押縁を装着する。すなわち、第2の枠体に第2の障子を取り付け、第2の枠体の第2の押縁用溝部に押縁を装着することにより、押縁によって第2の障子を押し付ける。これにより、本発明の一態様によれば、第1の障子用の押縁を、第2の障子用の押縁として利用することができる。 According to one aspect of the present invention, the pressing edge is mounted in the second pressing edge mounting groove provided in the second window frame. In other words, the second shoji is attached to the second frame, and the second shoji is pressed by the pushing edge by attaching the pushing edge to the second groove for the pushing edge of the second frame. Thereby, according to 1 aspect of this invention, the pushing edge for 1st shoji can be utilized as a pushing edge for 2nd shoji.
 本発明の一態様は、前記第2の障子は、第1のガラス板と第2のガラス板とがその周囲において枠体により隔置されて中空層が形成されるとともに、前記中空層が前記周囲において前記枠体に封着され、かつ前記中空層に少なくとも1枚の中間ガラス板が配置されてなる複層ガラスであることが好ましい。 In one embodiment of the present invention, the second shoji includes a first glass plate and a second glass plate that are separated by a frame around the first glass plate and a hollow layer is formed. It is preferable that the glass is a double-glazed glass that is sealed to the frame at the periphery and in which at least one intermediate glass plate is disposed in the hollow layer.
 本発明の一態様によれば、断熱性能を有効に発揮できる、少なくとも3枚のガラス板を有する複層ガラスを、第2の窓枠に装着することにより、単板ガラス及び2枚の複層ガラスからなる障子と比較して、高断熱化を図ることができる。また、中空層に3枚の中間ガラスが隔置されてなる、5枚のガラス板からなる多重ガラス障子を、第2の障子として適用することにより、断熱性能を最大限に発揮することができると想定される。中空層には、空気よりも熱伝導率が小さいアルゴンガスまたはクリプトンガスを封入することが好ましい。これにより、窓の断熱性能をより一層向上させることができる。 According to one aspect of the present invention, by mounting a double glazing having at least three glass plates capable of effectively exhibiting heat insulation performance on a second window frame, a single glazing and two double glazings are provided. Higher heat insulation can be achieved as compared with the shoji screen. In addition, by applying a multiple glass shoji made of five glass plates in which three intermediate glasses are spaced apart in the hollow layer as the second shoji, the heat insulating performance can be maximized. It is assumed. The hollow layer is preferably sealed with argon gas or krypton gas having a lower thermal conductivity than air. Thereby, the heat insulation performance of a window can be improved further.
 本発明の一態様は、前記第2の窓枠の前記第2の障子用溝部は、少なくとも第3の障子用溝部と第4の障子用溝部とに分割され、前記第2の障子は、第3の障子と第4の障子とを備え、前記第3の障子用溝部に前記第3の障子の周縁部が装着され、前記第4の障子用溝部に前記第4の障子の周縁部が装着されることが好ましい。 In one aspect of the present invention, the second shoji groove portion of the second window frame is divided into at least a third shoji groove portion and a fourth shoji groove portion, and the second shoji 3 shoji and 4 shoji, the peripheral part of the 3rd shoji is mounted in the groove part for the 3rd shoji, and the peripheral part of the 4th shoji is mounted in the groove part for the 4th shoji It is preferred that
 本発明の一態様によれば、第3の障子と第4の障子とからなる、断熱性能に優れた二重窓を構成することができる。 According to one aspect of the present invention, it is possible to configure a double window that is composed of a third shoji and a fourth shoji and has excellent heat insulation performance.
 本発明の一態様は、前記第3の障子又は前記第4の障子のうち少なくとも一つの障子は、複層ガラスによって構成されていることが好ましい。 In one embodiment of the present invention, it is preferable that at least one shoji among the third shoji and the fourth shoji is made of a multilayer glass.
 本発明の一態様によれば、断熱性能が更に優れた二重窓を構成することができる。
 本発明の一態様は、前記第2の窓枠は前記第1の窓枠との嵌合部を有し、当該嵌合部は前記の第1の窓枠の第1の押縁装着用溝部に嵌合されて第2の窓枠が第1の窓枠に装着されていることが好ましい。
 また、本発明の一態様は、前記第1の窓枠が建物の躯体に設けられた既設の窓枠であることが好ましい。
According to one embodiment of the present invention, a double window with further excellent heat insulation performance can be configured.
In one aspect of the present invention, the second window frame has a fitting portion with the first window frame, and the fitting portion is formed in the first edge mounting groove portion of the first window frame. It is preferable that the second window frame is fitted and attached to the first window frame.
In one embodiment of the present invention, the first window frame is preferably an existing window frame provided in a housing of a building.
 本発明によれば、部品点数を増やすことなく、第1の窓枠に第2の枠体を容易に取り付けることができる窓を提供できる。 According to the present invention, it is possible to provide a window in which the second frame can be easily attached to the first window frame without increasing the number of parts.
既設の窓の下部の縦断面図Vertical section of the lower part of an existing window 実施形態に係る窓の下部の断面図Sectional drawing of the lower part of the window which concerns on embodiment 図2に示した多重ガラス障子の全体斜視図Overall perspective view of the multiple glass shoji shown in FIG. 図3に示した多重ガラス障子の下部の縦断面図Vertical section of the lower part of the multiple glass shoji shown in FIG. スペーサ同士を接続するコーナーキーの斜視図Perspective view of corner key connecting spacers 支持板同士を接続するコーナーキーの斜視図Perspective view of corner key that connects support plates together スペーサとコーナーキーとをビスにより接続した状態、及び支持板とコーナーキーとをビスにより接続した状態を示した要部説明図Main part explanatory drawing showing a state where the spacer and the corner key are connected by screws, and a state where the support plate and the corner key are connected by screws. 他の実施形態の窓の下部の縦断面図Vertical section of the lower part of the window of another embodiment 他の実施形態の窓の下部の縦断面図Vertical section of the lower part of the window of another embodiment 他の実施形態の窓の下部の縦断面図Vertical section of the lower part of the window of another embodiment
 まず、建物の既設の窓について説明する。 First, the existing windows in the building will be explained.
 〔既設の窓10〕
 図1は、既設の窓10の下部の縦断面図であり、既設の窓枠(第1の窓枠)20の見込壁(すなわち、第1の障子用溝部)22に、複層ガラス障子(第1の障子)30の周縁部が装着されることにより構成される。また、窓枠20は、建物の躯体の開口部(不図示)に固定されたものである。
[Existing windows 10]
FIG. 1 is a vertical cross-sectional view of a lower portion of an existing window 10, and a double-layer glass shoji (a first shoji groove portion) 22 is formed on a prospective wall 22 of an existing window frame (first window frame) 20. The first shoji (shoulder) 30 is configured by being attached to the peripheral portion. Further, the window frame 20 is fixed to an opening (not shown) of the building frame.
 窓枠20には、押縁50、気密材52が備えられる。押縁50は、窓枠20の見込壁22に備えられた押縁装着用溝部(すなわち、第1の押縁装着用溝部)24に、その嵌合部50Aが着脱自在に装着され、そのリップ部50Bが、複層ガラス障子30の室外側のガラス板32に密着される。一方、気密材52は、窓枠20の室内側壁23に備えられた気密材装着用溝部26に、その嵌合部52Aが装着され、そのリップ部52Bが、複層ガラス障子30の室内側のガラス板34に密着される。これにより、複層ガラス障子30は、室外側及び室内側から押縁50、気密材52に押し付けられて窓枠20に保持される。 The window frame 20 is provided with a pressing edge 50 and an airtight material 52. The pressing edge 50 is detachably mounted with a fitting portion 50A in a pressing edge mounting groove portion (that is, a first pressing edge mounting groove portion) 24 provided on the prospective wall 22 of the window frame 20, and the lip portion 50B is attached to the pressing edge 50. The glass sheet 32 on the outdoor side of the multilayer glass shoji 30 is closely attached. On the other hand, the airtight member 52 is fitted with the fitting portion 52A in the groove portion 26 for attaching the airtight material provided on the indoor side wall 23 of the window frame 20, and the lip portion 52B is provided on the indoor side of the multilayer glass shoji 30. It is in close contact with the glass plate 34. Thereby, the multilayer glass shoji 30 is pressed against the pressing edge 50 and the airtight material 52 from the outdoor side and the indoor side and is held by the window frame 20.
 複層ガラス障子30は、通常、多くの場合は、矩形状のガラス板32、矩形状のガラス板34、枠状のスペーサ(すなわち、枠体)36、一次シール材38、及び二次シール材40を備えて構成される。 In many cases, the multi-layer glass shoji 30 is usually a rectangular glass plate 32, a rectangular glass plate 34, a frame-like spacer (that is, a frame) 36, a primary sealing material 38, and a secondary sealing material. 40.
 ガラス板32、34は、表面積が等しく、かつスペーサ36を介して隔置される。ガラス板32とガラス板34とに対向するスペーサ36の各側面が、一次シール材38であるブチルゴムによってガラス板32とガラス板34とに接着される。これにより、ガラス板32とガラス板34との間に中空層42が形成される。そして、スペーサ36の外周部に、二次シール材40としてのポリサルファイド系又はシリコーン系のシーリング材が充填される。これによって、複層ガラス障子30が構成される。 The glass plates 32 and 34 have the same surface area and are spaced apart via a spacer 36. Each side surface of the spacer 36 facing the glass plate 32 and the glass plate 34 is bonded to the glass plate 32 and the glass plate 34 by butyl rubber which is a primary sealing material 38. Thereby, a hollow layer 42 is formed between the glass plate 32 and the glass plate 34. The outer periphery of the spacer 36 is filled with a polysulfide-based or silicone-based sealing material as the secondary seal material 40. Thereby, the multilayer glass shoji 30 is constituted.
 スペーサ36は、中空のパイプによって構成され、その内部に充填された乾燥剤44によって中空層42の気体が乾燥される。符号46は、乾燥剤44を中空層42に露出するために形成された、スペーサ36の開口部であり、開口部46は、スペーサ36の長手方向に沿って所定の間隔で配置されている。 The spacer 36 is constituted by a hollow pipe, and the gas in the hollow layer 42 is dried by the desiccant 44 filled therein. Reference numeral 46 denotes an opening of the spacer 36 formed to expose the desiccant 44 to the hollow layer 42, and the openings 46 are arranged at predetermined intervals along the longitudinal direction of the spacer 36.
 なお、一次シール材38及び二次シール材40は、同一の材料としてもよい。また、二次シール材40の外周に二次シール材40を保護する別のシール材を有してもよく、框部材を配置してもよい。図1では、第1の障子として、2枚のガラス板32,34を隔置した中空層が1層の複層ガラス障子30を例示したが、これに限定されるものではなく、3枚以上のガラス板を備えた複層ガラスであってもよく、単板のガラス板であってもよい。 The primary sealing material 38 and the secondary sealing material 40 may be the same material. Moreover, you may have another sealing material which protects the secondary sealing material 40 in the outer periphery of the secondary sealing material 40, and may arrange a collar member. In FIG. 1, the multi-layer glass shoji 30 in which the hollow layer in which the two glass plates 32 and 34 are spaced apart is exemplified as the first shoji, but is not limited to this, and three or more sheets are used. Multi-layer glass provided with a glass plate may be used, or a single plate glass plate may be used.
 次に、本発明の実施形態の窓を添付した図面に基づいて説明する。 Next, a window according to an embodiment of the present invention will be described with reference to the accompanying drawings.
 なお、図面は、本発明の好ましい実施形態を例示したものであり、本発明は、例示の図面とその説明に限定されるものではない。 The drawings illustrate preferred embodiments of the present invention, and the present invention is not limited to the illustrated drawings and the description thereof.
 〔実施形態の窓100〕
 図2は、実施形態に係る窓100の下部の縦断面図である。
[Window 100 of Embodiment]
FIG. 2 is a longitudinal sectional view of the lower part of the window 100 according to the embodiment.
 実施形態の窓100は、建物の躯体の開口部に取り付けられている既設の窓枠(すなわち、第1の枠体)20を残すとともに、図1に示した複層ガラス障子(すなわち、第1の障子)30を第1の窓枠20から取り外し、第1の窓枠20に室外側から新設の窓枠である、アタッチメント枠(すなわち、第2の窓枠)110を第1の窓枠20に装着し、アタッチメント枠110に新規の障子である、多重ガラス障子(すなわち、第2の障子)120を装着することにより構成される。多重ガラス障子120は、窓枠20の見込壁22とアタッチメント枠110の見込壁(第2の障子用溝部)112とにその周縁部が装着される。 The window 100 of the embodiment leaves the existing window frame (that is, the first frame) 20 attached to the opening of the building frame, and also has the double-layer glass shoji (that is, the first frame) shown in FIG. ) 30 is removed from the first window frame 20, and an attachment frame (that is, a second window frame) 110, which is a new window frame, is attached to the first window frame 20 from the outdoor side. And a multi-glass shoji 120 (ie, a second shoji) 120, which is a new shoji, is attached to the attachment frame 110. The peripheral edge of the multiple glass shoji 120 is mounted on the prospective wall 22 of the window frame 20 and the prospective wall (second shoji groove portion) 112 of the attachment frame 110.
 また、実施形態の窓100によれば、図1の複層ガラス障子(第1の障子)30の厚さT2よりも厚さT1の厚い多重ガラス障子(第2の障子)120を用いることにより、窓100の奥行き寸法を、図1の奥行き寸法と比較して長くし、高断熱化を実現している。 Further, according to the window 100 of the embodiment, by using the multiple glass shoji (second shoji) 120 having a thickness T1 thicker than the thickness T2 of the multi-layer glass shoji (first shoji) 30 of FIG. The depth dimension of the window 100 is made longer than that of FIG. 1 to achieve high heat insulation.
 窓枠20は、下枠20Aと不図示の上枠及び左右の縦枠とを四方枠組みして構成されており、窓枠20の各枠材は、前記躯体に、ねじによって固定される。アタッチメント枠110も同様に、下枠110Aと不図示の上枠及び左右の縦枠とを四方枠組みして構成されている。実施形態の窓枠20、アタッチメント枠110は、いずれも硬質合成樹脂材料又はアルミニウム合金の押出形材であり、図示した例では、窓枠20、アタッチメント枠110は、開閉することができないFIX窓用の窓枠である。 The window frame 20 is configured by a four-sided frame of a lower frame 20A, an upper frame (not shown), and left and right vertical frames, and each frame member of the window frame 20 is fixed to the housing by screws. Similarly, the attachment frame 110 is configured by a four-sided frame of a lower frame 110A, an upper frame (not shown), and left and right vertical frames. The window frame 20 and the attachment frame 110 of the embodiment are both extruded materials of a hard synthetic resin material or an aluminum alloy. In the illustrated example, the window frame 20 and the attachment frame 110 are for FIX windows that cannot be opened and closed. It is a window frame.
 実施形態の窓100の特徴を説明する前に、まず、多重ガラス障子120の構成について説明する。 Before describing the characteristics of the window 100 of the embodiment, first, the configuration of the multiple glass shoji 120 will be described.
 ここで、多重ガラス障子120とは、例えば、後述する4本のスペーサが一体化された枠体を用い、断熱性能を最大限に発揮できると想定される5枚のガラス板を隔置して構成された4層の分割中空層を有するタイプのものである。この4層の分割中空層には、空気よりも熱伝導率が小さいアルゴンガスが封入されており、断熱性能がより一層向上されている。なお、多重ガラス障子120は、複層ガラス障子の範疇に含まれるものである。 Here, the multiple glass shoji 120 uses, for example, a frame in which four spacers, which will be described later, are integrated, and five glass plates that are assumed to be able to exhibit the maximum heat insulation performance are separated. This is a type having four divided hollow layers. The four divided hollow layers are filled with argon gas whose thermal conductivity is smaller than that of air, and the heat insulation performance is further improved. In addition, the multiple glass shoji 120 is included in the category of the multi-layer glass shoji.
 〔多重ガラス障子120の全体構成〕
 図3は、多重ガラス障子120の全体斜視図であり、図4は、多重ガラス障子120の下部の縦断面図である。
[Overall configuration of multiple glass shoji 120]
FIG. 3 is an overall perspective view of the multiple glass screen 120, and FIG. 4 is a vertical sectional view of the lower portion of the multiple glass screen 120. As shown in FIG.
 図3、図4の如く、多重ガラス障子120は、建物の室外側に配置されるガラス板(第1のガラス板)122と、室内側に配置されるガラス板(第2のガラス板)124と、ガラス板122とガラス板124との間に配置された3枚の中間ガラス板126A、126B、126Cと、ガラス板122とガラス板124とを隔置し、かつ中間ガラス板126A、126B、126Cを隔置して保持するスペーサ(枠体)128と、スペーサ128を外側から支持する支持板200とを備えている。図5、図6の如く、ガラス板122とガラス板124の角部であって、4本のスペーサ128の各端部がそれぞれ突き合わされる4箇所のコーナーにおいては、突き合わされたスペーサ128の端部同士がスペーサ接続部材であるコーナーキー(コーナーピースとも言う。)150によってそれぞれ接続されて枠状に構成され、また4本の支持板200の各端部がそれぞれ突き合わされる4箇所のコーナーにおいても、突き合わされた支持板200の端部同士が支持板接続部材である支持板用コーナーキー(同じく、コーナーピースとも言う。)250によってそれぞれ接続されて枠状に構成される。
 なお、中間ガラス板126A、126B、126Cを総称する場合には、単に中間ガラス板126と称する。
As shown in FIGS. 3 and 4, the multiple glass shoji 120 includes a glass plate (first glass plate) 122 disposed on the outdoor side of the building and a glass plate (second glass plate) 124 disposed on the indoor side. And three intermediate glass plates 126A, 126B, 126C disposed between the glass plate 122 and the glass plate 124, the glass plate 122 and the glass plate 124, and the intermediate glass plates 126A, 126B, It includes a spacer (frame body) 128 that holds 126C in a spaced manner, and a support plate 200 that supports the spacer 128 from the outside. As shown in FIG. 5 and FIG. 6, at the corners of the glass plate 122 and the glass plate 124 at the four corners where the end portions of the four spacers 128 are abutted, the ends of the abutted spacers 128. The four parts are connected to each other by a corner key (also referred to as a corner piece) 150 that is a spacer connecting member, and are configured in a frame shape, and at the four corners where the end portions of the four support plates 200 are respectively abutted. In addition, the ends of the supported support plates 200 are connected to each other by a support plate corner key (also referred to as a corner piece) 250, which is a support plate connection member, and is configured in a frame shape.
The intermediate glass plates 126A, 126B, and 126C are simply referred to as the intermediate glass plate 126 when collectively referred to.
 ガラス板122とガラス板124とは、その周囲においてスペーサ128により隔置される。これにより、ガラス板122とガラス板124との間に中空層が形成される。ガラス板122とガラス板124とスペーサ128とにより形成される中空層は、周囲においてスペーサ128により封着されるとともに、3枚の中間ガラス板126A、126B、126Cが隔置して配置されることにより、中空層が4層の分割中空層130に分割される。 The glass plate 122 and the glass plate 124 are separated by a spacer 128 around the periphery. Thereby, a hollow layer is formed between the glass plate 122 and the glass plate 124. The hollow layer formed by the glass plate 122, the glass plate 124, and the spacer 128 is sealed by the spacer 128 at the periphery, and the three intermediate glass plates 126A, 126B, and 126C are arranged apart from each other. Thus, the hollow layer is divided into four divided hollow layers 130.
 <スペーサ(枠体)128>
 図4の如く、スペーサ128は、ガラス板122とガラス板124との間隔を保持する内面部132及び外面側部134、内面部132及び外面側部134に連設されてガラス板122、124の内面に当接する側辺部136、136、及び乾燥剤138(図2参照)が充填される複数の空間部140から構成される。
<Spacer (frame) 128>
As shown in FIG. 4, the spacer 128 is connected to the inner surface portion 132 and the outer surface side portion 134, and the inner surface portion 132 and the outer surface side portion 134 that maintain the distance between the glass plate 122 and the glass plate 124. It is comprised from the side part 136,136 contact | abutted to an inner surface, and the several space part 140 with which the desiccant 138 (refer FIG. 2) is filled.
 スペーサ128には、3枚の中間ガラス板126A、126B、126Cの周辺部の一部を保持するために、スペーサ128の内面部132に3列の溝部142が設けられる。3列の溝部142は、3枚の中間ガラス板126A、126B、126Cを平行に配置するように、スペーサ128の長手方向に沿って平行に形成される。 The spacer 128 is provided with three rows of groove portions 142 on the inner surface portion 132 of the spacer 128 in order to hold a part of the peripheral portion of the three intermediate glass plates 126A, 126B, 126C. The three rows of grooves 142 are formed in parallel along the longitudinal direction of the spacer 128 so that the three intermediate glass plates 126A, 126B, 126C are arranged in parallel.
 実施形態では、スペーサ128に中間ガラス板126を保持するための溝部142を形成することによって、空間部140が左右方向に4分割されている。空間部140の個数は、中間ガラス板126の枚数に応じて決定される。実施形態のスペーサ128は、複数の空間部140と複数の溝部142とを有するように一体的に形成されている。 In the embodiment, the space portion 140 is divided into four in the left-right direction by forming the groove portion 142 for holding the intermediate glass plate 126 in the spacer 128. The number of spaces 140 is determined according to the number of intermediate glass plates 126. The spacer 128 of the embodiment is integrally formed so as to have a plurality of spaces 140 and a plurality of grooves 142.
 スペーサ128は、スペーサ形成材料によって成型される。成型方法としてスペーサ形成材料を押し出し成型法、共押し出し成型法、又は射出成型法等の成型法を用いることができる。 The spacer 128 is molded from a spacer forming material. As the molding method, a molding method such as an extrusion molding method, a co-extrusion molding method, or an injection molding method can be used.
 スペーサ形成材料としては、合成樹脂材料が好ましく使用される。スペーサ形成用の合成樹脂材料としては、硬質塩化ビニル樹脂材料、アクリロニトリル・スチレン樹脂材料、及びこれらにガラス繊維材を入れたものが好ましいが、これらの熱可塑性合成樹脂材料に限定されるものではなく、各種熱可塑性合成樹脂材料も使用できる。 As the spacer forming material, a synthetic resin material is preferably used. The synthetic resin material for forming the spacer is preferably a hard vinyl chloride resin material, an acrylonitrile / styrene resin material, or a material in which a glass fiber material is added, but is not limited to these thermoplastic synthetic resin materials. Various thermoplastic synthetic resin materials can also be used.
 また、スペーサ枠体形成材料としては、一種に限らず、複数種の材料を用いて複合構造としてもよい。例えば、異なる樹脂材料を共押し出し成型法により部分的に異なる合成樹脂材料からなる複合構造の枠体でもよく、合成樹脂材料とアルミニウム材料からなる複合構造の枠体でもよい。この複合構造の場合、いずれか一種のスペーサ形成材料により一体成型されていればよい。一体成型されたスペーサ128は、部分的に、又は全体に異なる合成樹脂材料及び/又は金属材料が接合されていてもよい。特に、硬質の塩化ビニル樹脂材料やアクリロニトリル・スチレン樹脂材料により形成されたスペーサ128は、多重ガラス障子120として用いたとき、断熱性に優れており、一体成型が容易で、耐久性に優れ、安価である。 Further, the spacer frame forming material is not limited to one type, and may be a composite structure using a plurality of types of materials. For example, it may be a composite structure frame made of different synthetic resin materials partially by different co-extrusion molding methods, or a composite structure frame made of a synthetic resin material and an aluminum material. In the case of this composite structure, it is only necessary that the composite structure is integrally formed of any one kind of spacer forming material. The integrally molded spacer 128 may be partially or entirely joined with different synthetic resin materials and / or metal materials. In particular, the spacer 128 formed of a hard vinyl chloride resin material or an acrylonitrile / styrene resin material has excellent heat insulation when used as the multiple glass shoji 120, is easy to be integrally molded, has excellent durability, and is inexpensive. It is.
 実施形態のスペーサ128の溝部142には、中間ガラス板126A、126B、126Cの端部を支持するための、グレージングチャンネル144が嵌合されている。グレージングチャンネル144により、スペーサ128の溝部142に中間ガラス板126A、126B、126Cを容易に密着固定することができる。また、グレージングチャンネル144を偏芯させることで各分割中空層130の厚さを変えることもできる。また、温度低下時において、分割中空層130の内圧が減少しスペーサ128が分割中空層130に向けて変形した場合でも、グレージングチャンネル144がスペーサ128から中間ガラス板126A、126B、126Cにかかる圧力を、グレージングチャンネル144によって緩和することができる。 In the groove portion 142 of the spacer 128 of the embodiment, a glazing channel 144 for supporting the end portions of the intermediate glass plates 126A, 126B, and 126C is fitted. The intermediate glass plates 126 </ b> A, 126 </ b> B, 126 </ b> C can be easily adhered and fixed to the groove 142 of the spacer 128 by the glazing channel 144. Further, the thickness of each divided hollow layer 130 can be changed by decentering the glazing channel 144. Further, even when the internal pressure of the divided hollow layer 130 decreases and the spacer 128 deforms toward the divided hollow layer 130 when the temperature is lowered, the pressure applied to the intermediate glass plates 126A, 126B, and 126C from the spacer 128 by the glazing channel 144 is reduced. Can be mitigated by the glazing channel 144.
 また、グレージングチャンネル144を、溝部142において部分的に配置することもできる。溝部142にグレージングチャンネル144を配置しない部分を設けることで、各分割中空層130の間の連通させることができ、各分割中空層130の内部の圧力を均等化することができる。 Also, the glazing channel 144 can be partially arranged in the groove 142. By providing a portion where the glazing channel 144 is not disposed in the groove portion 142, the divided hollow layers 130 can be communicated with each other, and the pressure inside each divided hollow layer 130 can be equalized.
 したがって、温度上昇、温度低下に伴い、分割中空層130の体積が増減した場合でも、複数の分割中空層130の全体でその体積変化の増減を吸収することができる。グレージングチャンネル144を部分的に設けない場合、中間ガラス板126A、126B、126Cの各辺の隅部近くに設けるのが好ましい。 Therefore, even when the volume of the divided hollow layer 130 increases or decreases as the temperature rises or decreases, the change in the volume change can be absorbed by the whole of the plurality of divided hollow layers 130. When the glazing channel 144 is not partially provided, it is preferably provided near the corners of the respective sides of the intermediate glass plates 126A, 126B, and 126C.
 グレージングチャンネル144は、ショアA硬度が50度から90度の樹脂製(例えば、塩化ビニル樹脂、ウレタン樹脂)、又はゴム製であることが好ましい。ショアA硬度が50度未満であると、軟らか過ぎるため中間ガラス板126A、126B、126Cに対する十分な保持力を得難く、また、ショアA硬度が90度を超えると硬くなり過ぎるため、中間ガラス板126A、126B、126Cを嵌め込み難くなるからである。 The glazing channel 144 is preferably made of a resin having a Shore A hardness of 50 to 90 degrees (for example, vinyl chloride resin or urethane resin) or rubber. If the Shore A hardness is less than 50 degrees, it is too soft and it is difficult to obtain a sufficient holding force for the intermediate glass plates 126A, 126B, 126C. If the Shore A hardness exceeds 90 degrees, the intermediate glass plate is too hard. This is because it is difficult to fit 126A, 126B, and 126C.
 グレージングチャンネル144として、図2、図3に示す形状に限定されず他の形状のグレージングチャンネル144を使用することもできる。 The glazing channel 144 is not limited to the shape shown in FIGS. 2 and 3, and a glazing channel 144 having another shape may be used.
 2枚のガラス板122、124が矩形の平板形状である場合、ガラス板122、124は、4辺の周縁付近に配置された4本のスペーサ128により隔置される。 When the two glass plates 122 and 124 have a rectangular flat plate shape, the glass plates 122 and 124 are separated by four spacers 128 arranged in the vicinity of the periphery of the four sides.
 〈コーナーキー150〉
 図5は、スペーサ128同士を接続するコーナーキー150を示した斜視図である。
<Corner key 150>
FIG. 5 is a perspective view showing a corner key 150 for connecting the spacers 128 to each other.
 スペーサ128の各端部が突き合わされる4つの角においては、隣接するスペーサ128同士がスペーサ接続部材であるコーナーキー150により連結され、連続する枠状のスペーサ(枠体)が構成される。 At the four corners where each end of the spacer 128 is abutted, adjacent spacers 128 are connected by a corner key 150 that is a spacer connecting member, and a continuous frame-shaped spacer (frame body) is configured.
 スペーサ128は、コーナーキー150の本体部152に対面する端面160を有している。スペーサ128の内面部132には通し孔162が形成されている。通し孔162は、空間部140(図4参照)に連通されている。 The spacer 128 has an end face 160 that faces the main body 152 of the corner key 150. A through hole 162 is formed in the inner surface 132 of the spacer 128. The through hole 162 communicates with the space 140 (see FIG. 4).
 コーナーキー150は、本体部152と、本体部152から突出しL字状に配置された挿入部154を有しており、挿入部154には通し孔156が形成されている。コーナーキー150は、L字状に配置された挿入部154がスペーサ128の複数の空間部140に対応して本体部152と一体的に形成されている。 The corner key 150 has a main body portion 152 and an insertion portion 154 that protrudes from the main body portion 152 and is arranged in an L shape, and a through hole 156 is formed in the insertion portion 154. In the corner key 150, an insertion portion 154 arranged in an L shape is integrally formed with the main body portion 152 corresponding to the plurality of space portions 140 of the spacer 128.
 スペーサ128の端面160がコーナーキー150の本体部152に接する位置まで、コーナーキー150の挿入部154がスペーサ128の空間部140に挿入される。挿入部154の断面積は、空間部140の断面積より小さく、挿入部154は、空間部140の内壁とはほとんど接触することなく挿入されるので、スペーサ128にクラック等が発生するのを抑制することができる。 The insertion portion 154 of the corner key 150 is inserted into the space portion 140 of the spacer 128 until the end surface 160 of the spacer 128 contacts the main body portion 152 of the corner key 150. The cross-sectional area of the insertion portion 154 is smaller than the cross-sectional area of the space portion 140, and the insertion portion 154 is inserted with almost no contact with the inner wall of the space portion 140, so that the occurrence of cracks and the like in the spacer 128 is suppressed. can do.
 スペーサ128とコーナーキー150とを連結した際、スペーサ128の通し孔162とコーナーキー150の挿入部154の通し孔156とが、内面部132の側から見て重なる位置に、位置合わせされる。固定部材であるビス158が、空間部140の外側からスペーサ128の通し孔162に挿入される。ビス158は、スペーサ128の内面部132を貫通し、挿入部154の通し孔156に達する。ビス158を空間部140の外側からねじ込むことにより、ビス158がスペーサ128の通し孔162と挿入部154の通し孔156とに締結される。ビス158がスペーサ128を貫通しているので、スペーサ128とコーナーキー150の挿入部154とをビス158により確実に固定することができる。 When the spacer 128 and the corner key 150 are connected, the through hole 162 of the spacer 128 and the through hole 156 of the insertion portion 154 of the corner key 150 are aligned to a position where they are seen from the inner surface portion 132 side. A screw 158 as a fixing member is inserted into the through hole 162 of the spacer 128 from the outside of the space 140. The screw 158 passes through the inner surface portion 132 of the spacer 128 and reaches the through hole 156 of the insertion portion 154. By screwing the screw 158 from the outside of the space portion 140, the screw 158 is fastened to the through hole 162 of the spacer 128 and the through hole 156 of the insertion portion 154. Since the screw 158 penetrates the spacer 128, the spacer 128 and the insertion portion 154 of the corner key 150 can be securely fixed by the screw 158.
 ここで空間部140の外側とは、スペーサ128の内部に形成された空間部140に対して、スペーサ128を境界にして空間部140の反対側を意味する。実施形態では、内面部132の外側から空間部140に向けてビス158を挿入した例を示したが、空間部140の外側であれば、外面側部134、又は側辺部136、136の外側から空間部140に向けてビス158を挿入することもできる。 Here, the outside of the space part 140 means the opposite side of the space part 140 with the spacer 128 as a boundary with respect to the space part 140 formed inside the spacer 128. In the embodiment, an example in which the screw 158 is inserted from the outer side of the inner surface part 132 toward the space part 140 is shown. However, if the screw 158 is outside the space part 140, the outer side part 134 or the outer side parts 136 and 136 are outside. It is also possible to insert a screw 158 toward the space 140 from the top.
 実施形態では、ビス158の下孔として、スペーサ128に通し孔162、挿入部154に通し孔156を形成したが、例えば、固定部材であるビス158として、タッピングビスを使用した場合、タッピングビスによりスペーサ128及び挿入部154に貫通孔を直接開けることもできる。 In the embodiment, the through hole 162 is formed in the spacer 128 and the through hole 156 is formed in the insertion portion 154 as the pilot hole of the screw 158. For example, when a tapping screw is used as the screw 158 that is a fixing member, A through-hole can be directly opened in the spacer 128 and the insertion portion 154.
 実施形態では、ビス158により、スペーサ128のガラス板122、124に近い側の2箇所でコーナーキー150と固定しているが、これに限定されない。例えば、空間部140の形成されている4箇所、又はスペーサ128の内側に位置する2箇所で固定することもできる。 In the embodiment, the corner key 150 is fixed to the corner 128 at two locations near the glass plates 122 and 124 of the spacer 128 by the screws 158, but is not limited thereto. For example, it can be fixed at four locations where the space 140 is formed or at two locations located inside the spacer 128.
 本体部152及び挿入部154を有するコーナーキー150は、硬質の合成樹脂材料(例えば、硬質ポリ塩化ビニル樹脂材料やアクリロニトリル・スチレン樹脂材料、ポリプロピレン樹脂材料)により一体成型されたものが好ましい。一体成型とは、コーナーキー形成材料を削り出し法、モールド法、3Dプリンターによる造形法、あるいは射出成型法等の一体成型法により成型することを意味する。このように一体成型されていれば、コーナーキー150を一つの部材にピース化することが容易であり、コーナーキー150の部品点数を削減することができ、組み立て工程も簡略化することができる。 The corner key 150 having the main body 152 and the insertion portion 154 is preferably integrally molded with a hard synthetic resin material (for example, a hard polyvinyl chloride resin material, an acrylonitrile / styrene resin material, or a polypropylene resin material). The integral molding means that the corner key forming material is molded by an integral molding method such as a shaving method, a molding method, a modeling method using a 3D printer, or an injection molding method. If integrally molded in this way, the corner key 150 can be easily formed into a single member, the number of parts of the corner key 150 can be reduced, and the assembly process can be simplified.
 <分割中空層130>
 4層の分割中空層130には、空気よりも熱伝導率が小さいアルゴンガスが封入され、多重ガラス障子120の断熱性能が高められている。また、スペーサ128の空間部140に収納された乾燥剤138によってアルゴンガスが乾燥される。これによって、ガラス板122、124、及び中間ガラス板126A、126B、126Cの内部結露が防止されている。更に、分割中空層130の厚さは、断熱性能を十分に発揮できる厚さである13mm~17mmに設定されている。つまり、分割中空層130の厚さは、断熱性能を最大限に発揮できる最適値(15mm)に対して、前後に2mmの幅を持たせて設定されている。分割中空層130の個数は、中間ガラス板126の枚数に応じて決定される。
 なお、高い断熱性が特に要求されない場合には、上述の分割中空層130には、乾燥空気や、その他の不活性ガスが充填されてもよい。
<Divided hollow layer 130>
The four divided hollow layers 130 are filled with argon gas having a thermal conductivity smaller than that of air, so that the heat insulation performance of the multiple glass shovel 120 is enhanced. In addition, the argon gas is dried by the desiccant 138 stored in the space 140 of the spacer 128. This prevents internal condensation of the glass plates 122 and 124 and the intermediate glass plates 126A, 126B, and 126C. Furthermore, the thickness of the divided hollow layer 130 is set to 13 mm to 17 mm, which is a thickness that can sufficiently exhibit the heat insulation performance. That is, the thickness of the divided hollow layer 130 is set so as to have a width of 2 mm before and after the optimum value (15 mm) at which the heat insulation performance can be maximized. The number of divided hollow layers 130 is determined according to the number of intermediate glass plates 126.
If high heat insulation is not particularly required, the above-described divided hollow layer 130 may be filled with dry air or other inert gas.
 <ガラス板122、124>
 ガラス板122、124は、通常、多くの場合は、矩形の平板のガラス板であり、それぞれの厚さは、軽量化を図るために好ましくは1.3mm~3mmの範囲であり、ガラス板122、124の寸法は、同一、又は略同寸法である。
< Glass plates 122 and 124>
The glass plates 122 and 124 are usually rectangular flat glass plates in many cases, and the thickness of each is preferably in the range of 1.3 mm to 3 mm in order to reduce the weight. , 124 are the same or substantially the same size.
 また、ガラス板122、124は、前記厚さの範囲内であれば、厚さが異なっていてもよい。更に、ガラス板122、124は、厚さを薄くしても充分な強度を有する化学強化ガラスであるのが好ましい。つまり、ガラス板122、124を化学強化ガラスとすることにより、厚さが1.3mm~3mmであっても、耐衝撃性能と耐風圧性能を得ることができる。 Further, the glass plates 122 and 124 may have different thicknesses as long as they are within the above thickness range. Furthermore, the glass plates 122 and 124 are preferably chemically strengthened glass having sufficient strength even if the thickness is reduced. That is, by making the glass plates 122 and 124 chemically tempered glass, impact resistance performance and wind pressure resistance performance can be obtained even if the thickness is 1.3 mm to 3 mm.
 化学強化ガラス板とは、ソーダライムシリケートガラス等のNa成分やLi成分を含有するガラス板を、硝酸カリウム等の溶融塩中に浸漬させ、ガラス板の表面に存在する原子径の小さなNaイオン及び/又はLiイオンと、溶融塩中に存在する原子径の大きなKイオンとを置換してガラス板の表面層に圧縮応力層を形成して強度が高められたガラス板である。化学強化ガラスによれば、板厚が2mm以下のガラス板でも、充分に高い破壊強度を有する。したがって、ガラス板122、124として化学強化ガラス板を使用すれば、厚さが1.3mm~3mmの薄板のガラス板122、124であっても、外側に配置されるガラス板122、124として十分な強度を得ることができる。 A chemically strengthened glass plate is a glass plate containing a Na component or a Li component such as soda lime silicate glass immersed in a molten salt such as potassium nitrate, and has a small atomic diameter Na ion and / or Alternatively, the strength is increased by replacing the Li ions with K ions having a large atomic diameter present in the molten salt to form a compressive stress layer on the surface layer of the glass plate. According to the chemically strengthened glass, even a glass plate having a thickness of 2 mm or less has a sufficiently high breaking strength. Therefore, if a chemically strengthened glass plate is used as the glass plates 122 and 124, the thin glass plates 122 and 124 having a thickness of 1.3 mm to 3 mm are sufficient as the glass plates 122 and 124 disposed on the outside. High strength can be obtained.
 <中間ガラス板126A、126B、126C>
 中間ガラス板126A、126B、126Cは、矩形の平板のガラス板であり、それぞれの厚さは、軽量化を図るために1mm~2mmの範囲であり、中間ガラス板126A、126B、126Cの寸法は、同一、又は略同寸法である。
< Intermediate glass plates 126A, 126B, 126C>
The intermediate glass plates 126A, 126B, and 126C are rectangular flat glass plates, and the thicknesses of the intermediate glass plates 126A, 126B, and 126C are in the range of 1 mm to 2 mm in order to reduce the weight. The dimensions of the intermediate glass plates 126A, 126B, and 126C are as follows. Are the same or substantially the same size.
 また、中間ガラス板126A、126B、126Cは、前記厚さの範囲内であれば、厚さが異なっていてもよい。更に、中間ガラス板126A、126B、126Cは、ガラス板122、124と同様に、厚さを薄くしても充分な強度を有する化学強化ガラスでもよい。例えば、厚さが1mmないし2mmの化学強化ガラスは、厚さが3mmないし6mmのフロートガラス等の非強化ガラスと同等の静的曲げ強度を有する。 Further, the intermediate glass plates 126A, 126B, 126C may have different thicknesses as long as they are within the above thickness range. Further, similar to the glass plates 122 and 124, the intermediate glass plates 126A, 126B, and 126C may be chemically strengthened glass having sufficient strength even if the thickness is reduced. For example, chemically tempered glass having a thickness of 1 mm to 2 mm has a static bending strength equivalent to that of non-tempered glass such as float glass having a thickness of 3 mm to 6 mm.
 なお、中間ガラス板126A、126B、126Cは、スペーサ128の溝部142に挿入できるようにガラス板122、124よりも小寸法の相似形の矩形状とされるのが好ましい。 The intermediate glass plates 126A, 126B, and 126C are preferably formed in a similar rectangular shape with a smaller dimension than the glass plates 122 and 124 so that they can be inserted into the groove 142 of the spacer 128.
 実施形態では、3枚の中間ガラス板126A、126B、126Cを例示したが、中間ガラス板126は、ガラス板122、124の間に少なくとも1枚あればよい。すなわち、多重ガラス障子120は、少なくとも一枚の中間ガラス板126を備えることにより構成される。例えば、中間ガラス板は、4枚以上であってもよい。したがって、多重ガラス障子120によれば、分割中空層130の温度の低下し、分割中空層130の内圧が減少した場合でも、中間ガラス板126の端部がスペーサ128を支持するので、スペーサ128が分割中空層130に向けて変形するのを中間ガラス板126によって抑制することができる。 In the embodiment, three intermediate glass plates 126A, 126B, and 126C are illustrated, but at least one intermediate glass plate 126 may be provided between the glass plates 122 and 124. That is, the multiple glass shoji 120 is configured by including at least one intermediate glass plate 126. For example, the number of intermediate glass plates may be four or more. Therefore, according to the multiple glass shoji 120, even when the temperature of the divided hollow layer 130 decreases and the internal pressure of the divided hollow layer 130 decreases, the end of the intermediate glass plate 126 supports the spacer 128. The intermediate glass plate 126 can suppress deformation toward the divided hollow layer 130.
 <低放射膜166A、166B、166C、166D>
 図2の如く、ガラス板122、124の分割中空層130に対向する少なくとも一方の内面、及び中間ガラス板126A、126Cの中間ガラス板126Bに対向する内面には、Low-E(Low-Emissivity)膜等の低放射膜166A、166B、166C、166Dが成膜されている。すなわち、ガラス板122、124、及び中間ガラス板126A、126CをLow-Eガラスとして構成することもできる。
< Low Emission Films 166A, 166B, 166C, 166D>
As shown in FIG. 2, Low-E (Low-Emissivity) is provided on at least one inner surface of the glass plates 122 and 124 facing the divided hollow layer 130 and on the inner surface of the intermediate glass plates 126A and 126C facing the intermediate glass plate 126B. Low emission films 166A, 166B, 166C, and 166D such as films are formed. That is, the glass plates 122 and 124 and the intermediate glass plates 126A and 126C can be configured as Low-E glass.
 Low-Eガラスとは、ガラス板の表面に、例えば、酸化スズ(SnO2)を主体とした低放射膜を化学蒸着装置やスパッタリング装置等を用いて成膜したもの、又は銀(Ag)を主体とした低放射膜を、スパッタリング装置等を用いて成膜したものであり、赤外線による熱エネルギーの放射率を低くする機能を有する。ここで、銀(Ag)を主体とした低放射膜とは、銀膜を酸化物膜、窒化物膜等で積層化したタイプのものも含む。すなわち、Low-Eガラスは、熱を通し難い性能を有するので、遮熱性及び断熱性が高い。また、銀を主体とした低放射膜は、空気中の水分等によって酸化し易い性質を有するため、複層ガラスに用いる場合は、密閉された中空層に面する面側に成膜されることが好ましい。更に、酸化スズを主体とする低放射膜は、銀を主体とする低放射膜と比較して、熱線の反射性能が低く、遮熱性能は低いが、銀を主体とする低放射膜と比較して、酸化し難く、機械耐久性が高いため傷付き難いという利点がある。よって、酸化スズを主体とする低放射膜であれば、ガラス板10、12の少なくとも一方の外面に備えさせることもできる。 Low-E glass is, for example, a low emission film mainly composed of tin oxide (SnO 2 ) formed on the surface of a glass plate using a chemical vapor deposition apparatus, a sputtering apparatus, or the like, or silver (Ag). The main low emission film is formed using a sputtering apparatus or the like, and has a function of reducing the emissivity of thermal energy by infrared rays. Here, the low emission film mainly composed of silver (Ag) includes a type in which a silver film is laminated with an oxide film, a nitride film or the like. That is, Low-E glass has a performance that hardly allows heat to pass through, and thus has high heat shielding properties and heat insulation properties. In addition, the low-emission film mainly composed of silver has the property of being easily oxidized by moisture in the air. Therefore, when used for double-glazed glass, it should be formed on the side facing the sealed hollow layer. Is preferred. In addition, the low-emission film mainly composed of tin oxide has lower heat ray reflection performance and lower heat-shielding performance than the low-emission film mainly composed of silver, but compared with the low-emission film mainly composed of silver. Thus, there is an advantage that it is difficult to oxidize and is not easily damaged because of high mechanical durability. Therefore, a low radiation film mainly composed of tin oxide can be provided on at least one outer surface of the glass plates 10 and 12.
 多重ガラス障子120において、Low-Eガラスを使用する場合、低放射膜166A、166B、166C、166Dの放射率を異ならせることができる。これにより、分割中空層130の温度と中間ガラス板126A、126B、126Cの温度上昇を抑制し、「熱割れ」と称されるリスクを解消することができる。「熱割れ」は、多重ガラス障子120と多重ガラス障子120を装着する窓枠20及びアタッチメント枠110において、日射(特に朝日)を受ける多重ガラス障子120が、窓枠20及びアタッチメント枠110に対して先に熱せられて膨張するため、膨張率の違いから窓枠20及びアタッチメント枠110に収納されている多重ガラス障子のガラス辺付近に引張応力が発生し、ガラス板の許容度(例えば、エッジ許容応力:17.7MPa)を超えた場合に発生する。このような「熱割れ」は、窓枠20、アタッチメント枠110の下面に断熱材を設けることにより抑制することができる。また、後述する支持板200の中空部202に断熱材を設けてもよい。 When Low-E glass is used in the multiple glass shoji 120, the emissivities of the low emission films 166A, 166B, 166C, 166D can be made different. Thereby, the temperature of the division | segmentation hollow layer 130 and the temperature rise of intermediate | middle glass plate 126A, 126B, 126C can be suppressed, and the risk called a "thermal crack" can be eliminated. “Heat cracking” is caused when the multiple glass shoji 120 that receives the solar radiation (especially the morning sun) is attached to the window frame 20 and the attachment frame 110. Since it is heated first and expands, tensile stress is generated in the vicinity of the glass side of the multiple glass shoji accommodated in the window frame 20 and the attachment frame 110 due to the difference in expansion coefficient, and the tolerance of the glass plate (for example, edge tolerance) This occurs when the stress exceeds 17.7 MPa. Such “thermal cracking” can be suppressed by providing a heat insulating material on the lower surface of the window frame 20 and the attachment frame 110. Moreover, you may provide a heat insulating material in the hollow part 202 of the support plate 200 mentioned later.
 例えば、室外側のガラス板122の内面に、放射率の比較的低い低放射膜166Aを成膜する。中間ガラス板126Aの中間ガラス板126Bに対向する面に、低放射膜166Aよりも放射率の高い低放射膜166Bを形成する。中間ガラス板126Cの中間ガラス板126Bに対向する面に、低放射膜166Aよりも放射率の高い低放射膜166Bを形成する。室外側のガラス板122の内面に、低放射膜166Aよりも放射率の高い低放射膜166Dを成膜する。低放射膜166B、116C、116Dは、垂直放射率が同値のものでもよく異なっていてもよい。また、中間ガラス板126Bには、低放射膜を形成しない。 For example, a low radiation film 166A having a relatively low emissivity is formed on the inner surface of the glass plate 122 outside the room. A low emission film 166B having a higher emissivity than the low emission film 166A is formed on the surface of the intermediate glass plate 126A facing the intermediate glass plate 126B. A low emission film 166B having a higher emissivity than the low emission film 166A is formed on the surface of the intermediate glass plate 126C facing the intermediate glass plate 126B. A low radiation film 166D having a higher emissivity than the low radiation film 166A is formed on the inner surface of the glass plate 122 on the outdoor side. The low radiation films 166B, 116C, and 116D may have the same or different vertical emissivities. Further, no low radiation film is formed on the intermediate glass plate 126B.
 室外側のガラス板122に放射率の比較的低い低放射膜166Aを設けることで、分割中空層130の内部の温度上昇、及び中間ガラス板126A、126B、126Cの温度上昇を抑えることができる。また、ガラス温度の上昇が大きい中央の中間ガラス板126BをLow-Eガラスではなく、透明ガラス板を使用することで、中間ガラス板126の中央付近の温度上昇を抑えることができる。 By providing the low radiation film 166A having a relatively low emissivity on the glass plate 122 on the outdoor side, it is possible to suppress the temperature rise inside the divided hollow layer 130 and the temperature rise of the intermediate glass plates 126A, 126B, 126C. Further, by using a transparent glass plate instead of Low-E glass as the central intermediate glass plate 126B where the glass temperature rises greatly, an increase in temperature near the center of the intermediate glass plate 126 can be suppressed.
 一方で、中間ガラス板126A、126Cの低放射膜166A、166Cは、低放射膜166Aより放射率が高いので、日射熱の透過性が高く、熱が中央ガラス板126に吸収されるのを抑え、室内側のガラス板124まで伝わりやすい。したがって、断熱性能を確保しつつ、分割中空層130の中間ガラス板126A、126Cの温度吸収を抑えることができる。 On the other hand, since the low radiation films 166A and 166C of the intermediate glass plates 126A and 126C have a higher emissivity than the low radiation film 166A, the solar radiation heat is highly permeable and heat is prevented from being absorbed by the central glass plate 126. It is easy to be transmitted to the glass plate 124 on the indoor side. Therefore, it is possible to suppress the temperature absorption of the intermediate glass plates 126A and 126C of the divided hollow layer 130 while ensuring the heat insulating performance.
 上述の構成とすることにより、中間ガラス板126A、126B、126Cと分割中空層130の温度上昇を抑制し熱応力を低下することができ、「熱割れ」を抑制することができる。 By adopting the above-described configuration, the temperature rise of the intermediate glass plates 126A, 126B, 126C and the divided hollow layer 130 can be suppressed, the thermal stress can be reduced, and “thermal cracking” can be suppressed.
 <支持板200>
 図2、4の如く、支持板200は、スペーサ128を支持し、補強する部材である。このため、支持板200は、各スペーサ128の外面側部134に対向する位置に配置されている。支持板200は、コーナーキー250により連結される。
<Support plate 200>
As shown in FIGS. 2 and 4, the support plate 200 is a member that supports and reinforces the spacer 128. For this reason, the support plate 200 is disposed at a position facing the outer surface side portion 134 of each spacer 128. The support plate 200 is connected by a corner key 250.
 スペーサ128が支持板200によって、その外側から支持されているので、温度上昇により分割中空層130の内圧が上昇し、スペーサ128が分割中空層130と反対側に膨張しようとしても、支持板200によりスペーサ128が外に膨らむのを抑制することができる。 Since the spacer 128 is supported from the outside by the support plate 200, even if the internal pressure of the divided hollow layer 130 increases due to the temperature rise and the spacer 128 tries to expand to the opposite side of the divided hollow layer 130, the support plate 200 It is possible to suppress the spacer 128 from expanding outward.
 多重ガラス障子120の構成によって、ガラス板122とガラス板124との間の中空層の厚さは、通常の2枚のガラス板からなる複層ガラスと比較して非常に厚くなる。このため、熱膨張する中空層からスペーサ128が受ける圧力は、前記複層ガラスと比較して非常に大きくなり、1枚のスペーサ128では対応できない場合が生じる。また、スペーサ128が樹脂製の場合には、金属製と比較して膨張しやすいという性質がある。そこで、実施形態の多重ガラス障子120では、スペーサ128の外側を支持し、スペーサ128を補強して、スペーサ128の膨張を抑制する支持板200を設けたので、前記上昇した内圧にも対抗することができる。これにより、使用寿命の長い多重ガラス障子120を提供することができる。 Depending on the configuration of the multiple glass shoji 120, the thickness of the hollow layer between the glass plate 122 and the glass plate 124 becomes very thick compared to a multi-layer glass composed of two normal glass plates. For this reason, the pressure that the spacer 128 receives from the thermally expanding hollow layer is much larger than that of the multi-layer glass, and a single spacer 128 may not be able to cope with it. In addition, when the spacer 128 is made of resin, it has a property of being easily expanded as compared with a metal. Therefore, in the multiple glass shovel 120 of the embodiment, since the support plate 200 that supports the outside of the spacer 128, reinforces the spacer 128, and suppresses the expansion of the spacer 128 is provided, it can counter the increased internal pressure. Can do. Thereby, the multiple glass shoji 120 with a long service life can be provided.
 また、支持板200は、断面形状において、内部に4つの中空部202を有するホロー構造で構成される。ホロー構造を有しているので、支持板200の剛性を維持することができる。また、中空部202に断熱材を挿入することにより、窓100の断熱性能を向上させることができる。 Further, the support plate 200 has a hollow structure having four hollow portions 202 inside in a cross-sectional shape. Since it has a hollow structure, the rigidity of the support plate 200 can be maintained. Moreover, the heat insulation performance of the window 100 can be improved by inserting a heat insulating material into the hollow portion 202.
 支持板200の形状に関して、例えば、支持板200はスペーサ128を支持するため、スペーサ128と略同じ長さを有し、スペーサ128の幅より短い幅を有している。 Regarding the shape of the support plate 200, for example, the support plate 200 has substantially the same length as the spacer 128 in order to support the spacer 128, and has a width shorter than the width of the spacer 128.
 支持板200とガラス板122との間、支持板200とガラス板122との間には、二次シール材182が設けられている。また、スペーサ128と支持板200との間には透湿防止層190が設けられている。 A secondary sealant 182 is provided between the support plate 200 and the glass plate 122 and between the support plate 200 and the glass plate 122. Further, a moisture permeation preventing layer 190 is provided between the spacer 128 and the support plate 200.
 実施形態では、支持板200は、複数の中空部202を有するように一体的に形成されている。支持板200は、支持板形成材料によって成型される。成型方法として支持板形成材料を押し出し成型法、共押し出し成型法、又は射出成型法等の成型法を用いることができる。 In the embodiment, the support plate 200 is integrally formed so as to have a plurality of hollow portions 202. The support plate 200 is molded from a support plate forming material. As the molding method, a molding method such as an extrusion molding method, a coextrusion molding method, or an injection molding method can be used.
 支持板形成材料としては、合成樹脂材料が好ましく使用される。支持板形成用の合成樹脂材料としては、硬質塩化ビニル樹脂材料、アクリロニトリル・スチレン樹脂材料、及びこれらにガラス繊維材を入れたものが好ましいが、これらの熱可塑性合成樹脂材料に限定されるものではなく、各種熱可塑性合成樹脂材料も使用できる。 As the support plate forming material, a synthetic resin material is preferably used. The synthetic resin material for forming the support plate is preferably a hard vinyl chloride resin material, an acrylonitrile / styrene resin material, or a material in which a glass fiber material is added, but is not limited to these thermoplastic synthetic resin materials. Various thermoplastic synthetic resin materials can also be used.
 また、支持体枠体形成材料としては、一種に限らず、複数種の材料を用いて複合構造としてもよい。例えば、異なる樹脂材料を共押し出し成型法により部分的に異なる合成樹脂材料からなる複合構造の枠体でもよく、合成樹脂材料とアルミニウム材料からなる複合構造の枠体でもよい。この複合構造の場合、いずれか一種のスペーサ形成材料により一体成型されていればよい。一体成型された支持板200は、部分的に、又は全体に異なる合成樹脂材料及び/又は金属材料が接合されていてもよい。特に、硬質の塩化ビニル樹脂材料やアクリロニトリル・スチレン樹脂材料により形成された支持板200は、多重ガラス障子120として用いたとき、断熱性に優れており、一体成型が容易で、耐久性に優れ、安価である。 Further, the support frame forming material is not limited to one type, and may be a composite structure using a plurality of types of materials. For example, it may be a composite structure frame made of different synthetic resin materials partially by different co-extrusion molding methods, or a composite structure frame made of a synthetic resin material and an aluminum material. In the case of this composite structure, it is only necessary that the composite structure is integrally formed of any one kind of spacer forming material. The integrally formed support plate 200 may be partially or entirely joined with different synthetic resin materials and / or metal materials. In particular, the support plate 200 formed of a hard vinyl chloride resin material or acrylonitrile / styrene resin material is excellent in heat insulation when used as the multiple glass shoji 120, easy to be integrally molded, and excellent in durability. Inexpensive.
 〈コーナーキー250〉
 図6は、支持板200同士を接続するコーナーキー250の斜視図である。
<Corner key 250>
FIG. 6 is a perspective view of a corner key 250 that connects the support plates 200 together.
 支持板200の各端部が突き合わされる4つの角のコーナーにおいては、隣接する支持板200同士が支持板接続部材であるコーナーキー250により連結され、連続する枠状の支持板が構成される。 At the corners of the four corners where each end of the support plate 200 is abutted, the adjacent support plates 200 are connected to each other by a corner key 250 that is a support plate connecting member, thereby forming a continuous frame-shaped support plate. .
 支持板200は、コーナーキー250の本体部252に面する端面230を有している。支持板200の外面部214には通し孔232が形成されている。通し孔232は、中空部202に貫通されている。 The support plate 200 has an end face 230 that faces the main body 252 of the corner key 250. A through hole 232 is formed in the outer surface portion 214 of the support plate 200. The through hole 232 passes through the hollow portion 202.
 コーナーキー250は、本体部252と、本体部252から突出しL字状に配置された挿入部254を有しており、挿入部254には通し孔256が形成されている。コーナーキー250は、L字状に配置された挿入部254が支持板200の複数の中空部202に対応して本体部252と一体的に形成されている。 The corner key 250 has a main body portion 252 and an insertion portion 254 that protrudes from the main body portion 252 and is arranged in an L shape, and a through hole 256 is formed in the insertion portion 254. In the corner key 250, an insertion portion 254 arranged in an L shape is formed integrally with the main body portion 252 corresponding to the plurality of hollow portions 202 of the support plate 200.
 支持板200の端面230がコーナーキー250の本体部252に接する位置まで、コーナーキー250の挿入部254が支持板200の中空部202に挿入される。挿入部254の断面積は、中空部202の断面積より小さく、挿入部254を中空部202の内壁とはほとんど接触せず、支持板200にクラック等が発生するのを抑制することができる。 The insertion portion 254 of the corner key 250 is inserted into the hollow portion 202 of the support plate 200 until the end surface 230 of the support plate 200 contacts the main body portion 252 of the corner key 250. The cross-sectional area of the insertion portion 254 is smaller than the cross-sectional area of the hollow portion 202, and the insertion portion 254 is hardly in contact with the inner wall of the hollow portion 202, and it is possible to suppress the occurrence of cracks or the like in the support plate 200.
 支持板200とコーナーキー250とを連結した際、支持板200の通し孔232とコーナーキー250の挿入部254の通し孔256とは重なる位置に、位置合わせされる。固定部材であるビス258が、外面部214から支持板200の孔232に挿入される。ビス258は、支持板200を貫通し、挿入部254の通し孔256に達する。ビス258を外面部214の外側からねじ込むことにより、ビス258が支持板200の通し孔232と挿入部254の通し孔256とに締結される。ビス258が支持板200を貫通しているので、支持板200とコーナーキー250の挿入部254とをビス258により確実に固定することができる。 When the support plate 200 and the corner key 250 are connected, the through hole 232 of the support plate 200 and the through hole 256 of the insertion portion 254 of the corner key 250 are aligned with each other. A screw 258 as a fixing member is inserted into the hole 232 of the support plate 200 from the outer surface portion 214. The screw 258 passes through the support plate 200 and reaches the through hole 256 of the insertion portion 254. By screwing the screw 258 from the outside of the outer surface portion 214, the screw 258 is fastened to the through hole 232 of the support plate 200 and the through hole 256 of the insertion portion 254. Since the screw 258 penetrates the support plate 200, the support plate 200 and the insertion portion 254 of the corner key 250 can be securely fixed by the screw 258.
 実施形態では、ビス258の下孔として、支持板200に通し孔232、挿入部254に通し孔256を形成したが、例えば、固定部材であるビス258として、タッピングビスを使用した場合、タッピングビスにより支持板200及び挿入部254に貫通孔を直接開けることできる。 In the embodiment, the through hole 232 is formed in the support plate 200 and the through hole 256 is formed in the insertion portion 254 as the pilot hole of the screw 258. For example, when a tapping screw is used as the screw 258 as a fixing member, the tapping screw is used. Thus, a through hole can be directly opened in the support plate 200 and the insertion portion 254.
 実施形態では、ビス258により、支持板200のガラス板122、124に近い側の2箇所でコーナーキー250と固定しているが、これに限定されない。例えば、中空部202の形成されている4箇所、又は支持板200の内側に位置する2箇所で固定することもできる。 In the embodiment, the corner keys 250 are fixed to the corner plate 250 at two locations near the glass plates 122 and 124 of the support plate 200 by the screws 258, but the present invention is not limited to this. For example, it can be fixed at four locations where the hollow portion 202 is formed, or at two locations located inside the support plate 200.
 本体部252及び挿入部254を有するコーナーキー250は、硬質の合成樹脂材料(例えば、硬質ポリ塩化ビニル樹脂材料やアクリロニトリル・スチレン樹脂材料、ポリプロピレン樹脂材料)により一体成型されたものが好ましい。一体成型とは、コーナーキー形成材料を削り出し法、モールド法、3Dプリンターによる造形法、あるいは射出成型法等の一体成型法により成型することを意味する。このように一体成型されていれば、コーナーキー250を一つの部材にピース化することが容易であり、コーナーキー250の部品点数を削減することができ、又組み立て工程を簡略化することができる。 The corner key 250 having the main body portion 252 and the insertion portion 254 is preferably integrally molded with a hard synthetic resin material (for example, a hard polyvinyl chloride resin material, an acrylonitrile / styrene resin material, or a polypropylene resin material). The integral molding means that the corner key forming material is molded by an integral molding method such as a shaving method, a molding method, a modeling method using a 3D printer, or an injection molding method. If integrally molded in this way, the corner key 250 can be easily formed into a single member, the number of parts of the corner key 250 can be reduced, and the assembly process can be simplified. .
 図7は、スペーサ128とコーナーキー150とをビス158により接続した状態、及び支持板200とコーナーキー250とをビス258により接続した状態、を示す説明図である。図7の如く、スペーサ128の外側には支持板200が配置され、スペーサ128が支持板200に支持され、かつ補強されている。 FIG. 7 is an explanatory view showing a state in which the spacer 128 and the corner key 150 are connected by screws 158 and a state in which the support plate 200 and the corner key 250 are connected by screws 258. As shown in FIG. 7, the support plate 200 is disposed outside the spacer 128, and the spacer 128 is supported by the support plate 200 and reinforced.
 <シール材180、二次シール材182>
 図2、図4の如く、多重ガラス障子120は、シール材180及び二次シール材、182を備えている。ガラス板122とガラス板124とに対向するスペーサ128の側辺部136、136が、シール材180であるブチルゴムによってガラス板122とガラス板124とに接合される。そして、スペーサ128の外面側部134の側に二次シール材182であるポリサルファイド系又はシリコーン系のシーリング材が充填される。これによって、多重ガラス障子120が構成される。シール材180及び二次シール材182は、上記形態に限定されず、ガラス板122、124において接合するシール材と、スペーサ128の外面側部134の側に塗布するシール材とを同一の材料としてもよい。さらに、二次シール材182の外周に二次シール材182を保護する別のシール材を有してもよい。
<Sealant 180, secondary sealant 182>
As shown in FIGS. 2 and 4, the multiple glass shoji 120 includes a sealing material 180 and a secondary sealing material 182. Side portions 136 and 136 of the spacer 128 facing the glass plate 122 and the glass plate 124 are joined to the glass plate 122 and the glass plate 124 by butyl rubber which is a sealing material 180. The outer surface side portion 134 of the spacer 128 is filled with a polysulfide-based or silicone-based sealing material that is the secondary seal material 182. Thereby, the multiple glass shoji 120 is configured. The sealing material 180 and the secondary sealing material 182 are not limited to the above forms, and the sealing material to be bonded on the glass plates 122 and 124 and the sealing material applied to the outer surface side portion 134 side of the spacer 128 are made of the same material. Also good. Furthermore, you may have another sealing material which protects the secondary sealing material 182 in the outer periphery of the secondary sealing material 182. FIG.
 多重ガラス障子120において、スペーサ128を支持する支持板200が設けられているので、二次シール材182は、支持板200とガラス板122との間、支持板200とガラス板124との間に設けられる。 In the multiple glass shoji 120, since the support plate 200 that supports the spacer 128 is provided, the secondary sealant 182 is provided between the support plate 200 and the glass plate 122 and between the support plate 200 and the glass plate 124. Provided.
 支持板200を設けることにより、二次シール材182の使用量を減らすことができる。また、支持板200により、二次シール材182を最適の形状とすることができる。また、多重ガラス障子120の総厚を変更したとしても支持板200により、二次シール材182を所定の寸法とすることができる。 By providing the support plate 200, the usage amount of the secondary sealing material 182 can be reduced. Further, the secondary sealing material 182 can be formed in an optimal shape by the support plate 200. Further, even if the total thickness of the multiple glass shoji 120 is changed, the secondary sealing material 182 can be set to a predetermined size by the support plate 200.
 また、支持板200が二次シール材182の被着対象となるので、安定した接着性能を確保(すなわち、2面接着)することができる。つまり、二次シール材182の保持力の発現することができる。 In addition, since the support plate 200 is an object to which the secondary sealant 182 is attached, stable adhesion performance can be ensured (that is, two-sided adhesion). That is, the holding force of the secondary sealing material 182 can be expressed.
 <透湿防止層190>
 図2、図4の如く、多重ガラス障子120の分割中空層130の側に外側から水分が透過するのを防止する透湿防止層190が形成される。特に、スペーサ128が、合成樹脂材料、例えば硬質ポリ塩化ビニル樹脂材料、又はアクリロニトリル・スチレン樹脂材料により形成されている場合、素材自体として水分の透湿防止性が高いアルミニウム製のスペーサと同等程度の透湿防止性が求められている。
<Moisture permeation prevention layer 190>
As shown in FIGS. 2 and 4, a moisture permeation preventive layer 190 that prevents moisture from permeating from the outside is formed on the side of the divided hollow layer 130 of the multiple glass shoji 120. In particular, when the spacer 128 is formed of a synthetic resin material, for example, a hard polyvinyl chloride resin material, or an acrylonitrile / styrene resin material, the material itself is about the same as an aluminum spacer that has a high moisture permeation prevention property. There is a demand for moisture permeability prevention.
 透湿防止層190としては、分割中空層130内にスペーサ128自体を通して水分が透過することを防止できる材質からなるものが選ばれる。透湿防止層190としては、透湿防止塗料を塗布し、硬化されてなる層や、透湿防止フィルム状体を貼り付けてなる層が好ましい。透湿防止塗料としては、代表的には、フッ素樹脂系塗料、ポリ塩化ビニリデン樹脂系塗料などが挙げられる。透湿防止塗料の塗布により透湿防止層を形成する場合、2種以上の透湿防止塗料を塗布して2層、あるいは3層以上の複数層の構成としてもよい。 As the moisture permeation preventing layer 190, a layer made of a material capable of preventing moisture from passing through the spacer 128 itself into the divided hollow layer 130 is selected. The moisture permeation preventive layer 190 is preferably a layer formed by applying a moisture permeation preventive paint and cured, or a layer formed by attaching a moisture permeation preventive film. Typical examples of the moisture permeation preventing paint include a fluororesin paint and a polyvinylidene chloride resin paint. When the moisture permeation preventive layer is formed by application of the moisture permeation preventive paint, two or more kinds of moisture permeation preventive paints may be applied to form a two-layer or three or more layers.
 透湿防止フィルム状体としては、透湿防止性能をもった金属被覆フィルム、セラミック被覆フィルム、金属及びセラミックの複合被覆フィルム、金属テープ、フィルム自身が透湿防止性能をもった樹脂からなる透湿防止樹脂フィルム、又は透湿防止樹脂被覆フィルムが挙げられる。ブチルゴム系接着材からなるブチルテープと、金属テープ、例えばアルミニウム箔、ステンレス箔等を積層した透湿防止フィルム状体も好ましく使用することができる。 Moisture permeation-preventing film-like body includes metal-coated film with anti-moisture performance, ceramic-coated film, composite coating film of metal and ceramic, metal tape, and the film itself made of resin with anti-moisture performance Examples thereof include a prevention resin film or a moisture permeation prevention resin-coated film. A moisture permeation-preventing film-like body obtained by laminating a butyl tape made of a butyl rubber adhesive and a metal tape such as an aluminum foil or a stainless steel foil can also be preferably used.
 また、図2の如く、スペーサ128は、空間部140を有しているので、空間部140にゼオライト又はシリカゲル等の乾燥剤138を充填することができる。この乾燥剤138により分割中空層130の気体を乾燥させることができる。なお、乾燥剤138は、スペーサ128の内面部132に形成された開口部(不図示)により、分割中空層130に露出される。 Further, as shown in FIG. 2, since the spacer 128 has the space 140, the space 140 can be filled with a desiccant 138 such as zeolite or silica gel. With this desiccant 138, the gas in the divided hollow layer 130 can be dried. The desiccant 138 is exposed to the divided hollow layer 130 through an opening (not shown) formed in the inner surface 132 of the spacer 128.
 なお、実施形態において、支持板200が設けられているので、透湿防止層190を保護することができる。以上が、多重ガラス障子120の構成である。 In the embodiment, since the support plate 200 is provided, the moisture permeation preventing layer 190 can be protected. The above is the configuration of the multiple glass shoji 120.
 次に、図2に示した実施形態の窓100の特徴について説明する。 Next, features of the window 100 of the embodiment shown in FIG. 2 will be described.
 〔窓100の特徴〕
 実施形態の窓100は、既設の窓枠(すなわち、第1の窓枠)20において、押縁装着用溝部(すなわち、第1の押縁装着用溝部)24から押縁50を取り外し、押縁装着用溝部24にアタッチメント枠(すなわち、第2の窓枠)110の嵌合部114を装着している。すなわち、実施形態の窓100は、窓枠20に備えられている、既存の押縁装着用溝部24を利用して、多重ガラス障子(すなわち、第2の障子)120を装着するためのアタッチメント枠110を装着したので、大幅に部品点数を増やすことなく、窓枠20にアタッチメント枠110を容易に取り付けることができる。
[Features of window 100]
In the window 100 of the embodiment, in the existing window frame (that is, the first window frame) 20, the pressing edge 50 is removed from the pressing edge mounting groove portion (that is, the first pressing edge mounting groove portion) 24, and the pressing edge mounting groove portion 24 is removed. The fitting portion 114 of the attachment frame (that is, the second window frame) 110 is attached to the. That is, the window 100 of the embodiment uses the existing pressing edge mounting groove portion 24 provided in the window frame 20, and the attachment frame 110 for mounting the multiple glass shoji (that is, the second shoji) 120. The attachment frame 110 can be easily attached to the window frame 20 without significantly increasing the number of parts.
 また、実施形態の窓100によれば、アタッチメント枠110に備えられた押縁装着用溝部(すなわち、第2の押縁装着用溝部)116に押縁50の嵌合部50Aを装着し、押縁50のリップ部50Bと、窓枠20の気密材52のリップ部52Bとによって多重ガラス障子120を室外側及び室内側から押し付けて多重ガラス障子120を保持している。すなわち、アタッチメント枠110に多重ガラス障子120を取り付け、アタッチメント枠110の押縁装着用溝部116に押縁50を装着することにより、多重ガラス障子120を気密材52に押し付けることができる。これにより、実施形態の窓100によれば、複層ガラス障子(すなわち、第1の障子)30の押縁50を、多重ガラス障子120の押縁50として有効利用することができる。 Further, according to the window 100 of the embodiment, the fitting portion 50 </ b> A of the pressing edge 50 is mounted in the pressing edge mounting groove portion (that is, the second pressing edge mounting groove portion) 116 provided in the attachment frame 110, and the lip of the pressing edge 50 is mounted. The multiple glass screen 120 is held by pressing the multiple glass screen 120 from the outdoor side and the indoor side by the portion 50B and the lip 52B of the airtight member 52 of the window frame 20. That is, the multiple glass shoji 120 can be pressed against the airtight member 52 by attaching the multiple glass shoji 120 to the attachment frame 110 and attaching the press rim 50 to the push edge mounting groove 116 of the attachment frame 110. Thereby, according to the window 100 of the embodiment, the pushing edge 50 of the multilayer glass shoji (that is, the first shoji) 30 can be effectively used as the pushing edge 50 of the multiple glass shoji 120.
 更に、アタッチメント枠110は、室外側先端の下部に脚部118を備え、脚部118を窓枠20の傾斜部28に支持させるため、脚部118と嵌合部114とによってアタッチメント枠110を窓枠20に安定して装着することができる。 Furthermore, the attachment frame 110 includes a leg portion 118 at a lower portion of the outdoor front end, and the leg portion 118 and the fitting portion 114 are used to support the attachment frame 110 in the window so that the leg portion 118 is supported by the inclined portion 28 of the window frame 20. It can be stably attached to the frame 20.
 〔本発明の他の実施形態の窓〕
 図8は、他の実施形態の窓300の下部の縦断面図である。同図においては、第2の障子である障子320を簡略して示している。
[Windows of another embodiment of the present invention]
FIG. 8 is a longitudinal sectional view of the lower part of the window 300 of another embodiment. In the figure, the shoji 320 which is the second shoji is shown in a simplified manner.
 図2の窓100に対する図8の窓300の構造の相違点は、第2の窓枠であるアタッチメント枠310に室内側壁312を備え、室内側壁312を気密材52によって押し付けている室内側壁312には、障子320に当接されるリップ部314が備えられている。 The structure of the window 300 in FIG. 8 differs from the window 100 in FIG. 2 in that the attachment side wall 312 is provided on the attachment frame 310, which is the second window frame, and the indoor side wall 312 is pressed by the airtight member 52. Is provided with a lip portion 314 that contacts the shoji 320.
 図9は、他の実施形態の窓400の下部の縦断面図である。同図においては、第2の障子である障子420を簡略して示している。 FIG. 9 is a longitudinal sectional view of the lower part of the window 400 of another embodiment. In the same figure, the shoji 420 which is the second shoji is shown in a simplified manner.
 図8の窓300に対する図9の窓400の構造の相違点は、第2の窓枠であるアタッチメント枠410に室外側壁412を備え、室外側壁412に、障子420に当接されるリップ部414が備えられている。図9の窓400では、図8の押縁50を使用しないが、室外側壁412を押縁として代用できる。 The window 400 of FIG. 9 differs from the window 300 of FIG. 8 in that the attachment frame 410, which is the second window frame, includes an outdoor wall 412 and the outdoor wall 412 has a lip portion 414 that contacts the shoji 420. Is provided. In the window 400 of FIG. 9, the pushing edge 50 of FIG. 8 is not used, but the outdoor side wall 412 can be substituted as the pushing edge.
 図10は、他の実施形態の窓500の下部の縦断面図である。 FIG. 10 is a longitudinal sectional view of the lower part of the window 500 of another embodiment.
 同図に示す窓500において、第2の障子は、2枚の複層ガラス障子30(ここにおいて、一方の複層ガラス障子を第3の障子、他方の複層ガラス障子を第4の障子と称する。)から構成され、この第2の障子、すなわち、第3の障子および第4の障子は、第2の窓枠であるアタッチメント枠510に装着されている。なお、この例において、第3の障子および第4の障子として、複層ガラス障子の例を挙げているが、第3の障子および第4の障子の一方は、多重ガラス障子であってもよいし、また単板のガラス板であってもよい。 In the window 500 shown in the figure, the second shoji is composed of two multi-layer glass shojis 30 (where one multi-layer glass shoji is the third shoji and the other multi-layer glass shoji is the fourth shoji. The second shoji, that is, the third shoji and the fourth shoji are attached to an attachment frame 510 which is a second window frame. In addition, in this example, the example of a multilayer glass shoji is given as the third shoji and the fourth shoji, but one of the third shoji and the fourth shoji may be a multiple glass shoji. In addition, a single glass plate may be used.
 アタッチメント枠(第2の窓枠)510の第2の障子用溝部である見込壁512は、見込壁512の略中央部に立設された仕切り壁514によって室外側及び室内側に分割され、すなわち、第3の障子用溝部、第4の障子用溝部に分割されている。そして、分割された見込壁512の第3の障子用溝部および第4の障子用溝部のそれぞれに、第3の障子である複層ガラス障子30および第4の障子である複層ガラス障子30の周辺部が装着されている。また、仕切り壁514の室外側面にはリップ部516が備えられ、室内側面にもリップ部518が備えられている。 The prospective wall 512, which is the second groove part for the shoji of the attachment frame (second window frame) 510, is divided into the outdoor side and the indoor side by the partition wall 514 erected substantially at the center of the prospective wall 512. The third shoji groove and the fourth shoji groove are divided. And the multi-layer glass shoji 30 which is the 3rd shoji and the multi-layer glass shoji 30 which is the 4th shoji in each of the groove part for 3rd shoji and the 4th groove of the shoji of the divided prospect wall 512 The peripheral part is installed. In addition, a lip portion 516 is provided on the outdoor side surface of the partition wall 514, and a lip portion 518 is also provided on the indoor side surface.
 室外側に装着された複層ガラス障子30は、リップ部414とリップ部516とによって保持され、室内側に装着された複層ガラス障子30は、リップ部314とリップ部518とによって保持される。 The multi-layer glass shoji 30 attached to the outdoor side is held by the lip portion 414 and the lip portion 516, and the multi-layer glass shoji 30 attached to the indoor side is held by the lip portion 314 and the lip portion 518. .
 図10の窓500によれば、2枚の複層ガラス障子30からなる、断熱性能に優れた二重窓を構成することができる。 According to the window 500 in FIG. 10, a double window composed of two double-layer glass shojis 30 and excellent in heat insulation performance can be configured.
 なお、2枚の複層ガラス障子30のうち1枚を多重ガラス障子に代えてもよく、単板のガラス板に代えてもよい。 It should be noted that one of the two multilayer glass shojis 30 may be replaced with a multiple glass shoji or may be replaced with a single glass plate.
 本発明によれば、部品点数を増やすことなく、第1の窓枠に第2の枠体を容易に取り付けることができる窓を提供できる。
 なお、2014年10月30日に出願された日本特許出願2014-221620号の明細書、特許請求の範囲、図面および要約書の全内容をここに引用し、本発明の開示として取り入れるものである。
ADVANTAGE OF THE INVENTION According to this invention, the window which can attach a 2nd frame to a 1st window frame easily can be provided, without increasing a number of parts.
It should be noted that the entire contents of the specification, claims, drawings and abstract of Japanese Patent Application No. 2014-221620 filed on October 30, 2014 are incorporated herein by reference. .
 10…窓、20…窓枠(第1の窓枠)、22…見込壁、23…室内側壁、24…押縁装着用溝部(第1の押縁装着用溝部)、26…気密材装着用溝部、28…傾斜部、30…複層ガラス障子(第1の障子)、32、34…ガラス板、36…スペーサ、38…一次シール材、40…二次シール材、42…中空層、44…乾燥剤、46…開口部、50…押縁、52…気密材、100、300、400、500…窓、110…アタッチメント枠(第2の窓枠)、112…見込壁、114…嵌合部、116…押縁装着用溝部(第2の押縁装着用溝部)、118…脚部、120…多重ガラス障子(第2の障子)、122、124…ガラス板、126、126A、126B、126C…中間ガラス板、128…スペーサ、130…分割中空層、132…内面部、134…外面側部、136…側辺部、138…乾燥剤、140…空間部、142…溝部、144…グレージングチャンネル、150…コーナーキー、152…本体部、154…挿入部、156…通し孔、158…ビス、160…端面、162…通し孔、166A、166B、166C、166D…低放射膜、180…シール材、182…二次シール材、190…透湿防止層、200…支持板、202…中空部、214…外面部、232…通し孔、250…コーナーキー、252…本体部、254…挿入部、256…通し孔、258…ビス、310…アタッチメント枠(第2の窓枠)、312…室内側壁、314…リップ部、320…障子(第2の障子)、410…アタッチメント枠(第2の窓枠)、412…室外側壁、414…リップ部、420…障子(第2の障子)、510…アタッチメント枠(第2の窓枠)、512…見込壁、514…仕切り壁、516、518…リップ部。 DESCRIPTION OF SYMBOLS 10 ... Window, 20 ... Window frame (1st window frame), 22 ... Look-in wall, 23 ... Interior side wall, 24 ... Groove part for pressing edge mounting (first pressing edge mounting groove part), 26 ... Groove part for airtight material mounting, 28 ... Inclined part, 30 ... Multi-layer glass shoji (first shoji), 32, 34 ... Glass plate, 36 ... Spacer, 38 ... Primary sealant, 40 ... Secondary sealant, 42 ... Hollow layer, 44 ... Dry Agent, 46 ... opening, 50 ... pushing edge, 52 ... airtight material, 100, 300, 400, 500 ... window, 110 ... attachment frame (second window frame), 112 ... prospect wall, 114 ... fitting portion, 116 ... groove for attaching ledge (second groove for attaching ledge), 118 ... leg, 120 ... multiple glass shoji (second shoji), 122, 124 ... glass plate, 126, 126A, 126B, 126C ... intermediate glass plate 128 ... spacers 130 ... split hollow layers 132 ... Surface part, 134 ... Outer surface side part, 136 ... Side edge part, 138 ... Desiccant, 140 ... Space part, 142 ... Groove part, 144 ... Glazing channel, 150 ... Corner key, 152 ... Body part, 154 ... Insertion part, 156 ... Through hole, 158 ... screw, 160 ... end face, 162 ... through hole, 166A, 166B, 166C, 166D ... low radiation film, 180 ... sealing material, 182 ... secondary sealing material, 190 ... moisture permeation preventing layer, 200 ... support Plate 202, hollow portion, 214 outer surface portion, 232 through-hole, 250 corner key, 252 body portion, 254 insertion portion, 256 through-hole, 258 screw, 310 attachment frame (second window) Frame), 312 ... indoor side wall, 314 ... lip, 320 ... shoji (second shoji), 410 ... attachment frame (second window frame), 412 ... outdoor side wall, 414 ... lip Department, 420 ... shoji (second Shoji), 510 ... attachment frame (second window frame), 512 ... prospective wall, 514 ... partition wall, 516, 518 ... lip.

Claims (7)

  1.  第1の障子の周縁部が装着されるように構成された第1の障子用溝部と、押縁が着脱自在に装着される第1の押縁装着用溝部とを備えた第1の窓枠と、
     前記第1の押縁装着用溝部に装着されて、前記第1の障子よりも厚さの厚い第2の障子の周縁部が装着されるように構成された第2の障子用溝部を備えた第2の窓枠と、
     前記第2の窓枠の前記第2の障子用溝部に周縁部が装着された前記第2の障子と、
     を有することを特徴とする窓。
    A first window frame including a first shoji groove portion configured to be fitted with a peripheral edge portion of the first shoji, and a first push-edge mounting groove portion to which the press rim is detachably attached;
    A second shoji groove portion that is mounted in the first pushing edge mounting groove portion and configured to be mounted on the peripheral edge portion of the second shoji, which is thicker than the first shoji. Two window frames,
    The second shoji with a peripheral edge attached to the second groove for the second shoji of the second window frame;
    The window characterized by having.
  2.  前記第2の窓枠には、前記押縁が装着される第2の押縁装着用溝部が備えられる請求項1に記載の窓。 The window according to claim 1, wherein the second window frame is provided with a second pressing edge mounting groove portion to which the pressing edge is mounted.
  3.  前記第2の障子は、第1のガラス板と第2のガラス板とがその周囲において枠体により隔置されて中空層が形成されるとともに、前記中空層が前記周囲において前記枠体に封着され、かつ前記中空層に少なくとも1枚の中間ガラス板が配置されてなる複層ガラスである請求項1又は2に記載の窓。 In the second shoji, a first glass plate and a second glass plate are separated by a frame around the first glass plate to form a hollow layer, and the hollow layer is sealed to the frame around the circumference. The window according to claim 1 or 2, wherein the window is a double-glazed glass formed by being attached and having at least one intermediate glass plate disposed in the hollow layer.
  4.  前記第2の窓枠の前記第2の障子用溝部は、少なくとも第3の障子用溝部と第4の障子用溝部とに分割され、
     前記第2の障子は、第3の障子と第4の障子とを備え、
     前記第3の障子用溝部に前記第3の障子の周縁部が装着され、前記第4の障子用溝部に前記第4の障子の周縁部が装着される請求項1又は2に記載の窓。
    The second shoji groove portion of the second window frame is divided into at least a third shoji groove portion and a fourth shoji groove portion,
    The second shoji includes a third shoji and a fourth shoji.
    3. The window according to claim 1, wherein a peripheral portion of the third shoji is attached to the third shoji groove portion, and a peripheral portion of the fourth shoji is attached to the fourth shoji groove portion.
  5.  前記第3の障子又は前記第4の障子のうち少なくとも一つの障子は、複層ガラスによって構成されている請求項4に記載の窓。 The window according to claim 4, wherein at least one of the third shoji or the fourth shoji is made of double-glazed glass.
  6.  前記第2の窓枠は前記第1の窓枠との嵌合部を有し、当該嵌合部は前記の第1の窓枠の第1の押縁装着用溝部に嵌合されて第2の窓枠が第1の窓枠に装着されている請求項1~5のいずれか1項に記載の窓。 The second window frame has a fitting portion with the first window frame, and the fitting portion is fitted into the first pressing edge mounting groove portion of the first window frame to be second. The window according to any one of claims 1 to 5, wherein the window frame is attached to the first window frame.
  7.  前記第1の窓枠が建物の躯体に設けられた既設の窓枠である請求項1~6のいずれか1項に記載の窓。 The window according to any one of claims 1 to 6, wherein the first window frame is an existing window frame provided in a building frame.
PCT/JP2015/080783 2014-10-30 2015-10-30 Window WO2016068307A1 (en)

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2020016118A (en) * 2018-07-27 2020-01-30 Ykk Ap株式会社 Fixture
CN113167099A (en) * 2018-11-21 2021-07-23 约翰·朱克 Frame assembly

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS537941A (en) * 1976-07-09 1978-01-24 Morio Watanabe Structure of multiilayer hollow window
FR2515244A1 (en) * 1981-10-26 1983-04-29 Heiligenstein Jean Paul Profile for adapting double glazing frame to existing window - has double U-section to house glazing panes with dehydrating infill
JPS61137778U (en) * 1985-02-16 1986-08-27
JPS61137777U (en) * 1985-02-16 1986-08-27
US4625479A (en) * 1984-07-16 1986-12-02 Donat Flamand Inc. Casing window

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS537941A (en) * 1976-07-09 1978-01-24 Morio Watanabe Structure of multiilayer hollow window
FR2515244A1 (en) * 1981-10-26 1983-04-29 Heiligenstein Jean Paul Profile for adapting double glazing frame to existing window - has double U-section to house glazing panes with dehydrating infill
US4625479A (en) * 1984-07-16 1986-12-02 Donat Flamand Inc. Casing window
JPS61137778U (en) * 1985-02-16 1986-08-27
JPS61137777U (en) * 1985-02-16 1986-08-27

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2020016118A (en) * 2018-07-27 2020-01-30 Ykk Ap株式会社 Fixture
JP7041019B2 (en) 2018-07-27 2022-03-23 Ykk Ap株式会社 Joinery
CN113167099A (en) * 2018-11-21 2021-07-23 约翰·朱克 Frame assembly

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