JP6277096B2 - Double glazing - Google Patents

Description

  The present invention relates to a multilayer glass.

  Multi-layer glass having a plurality of plate glasses facing each other is already well known. In such a multi-layer glass, a spacer filled with a desiccant is interposed between the adjacent plate glasses. A sealed space is provided on the inner side in the in-plane direction of the plate glass than the spacer.

JP 2000-8719 A

  In the multilayer glass as described above, there is a problem in rigidity when the multilayer glass is constituted by aluminum or resin spacers. In addition, it has been required to ensure the water tightness and air tightness performance of the sealed space while ensuring the rigidity.

  This invention is made | formed in view of this subject, The place made into the objective is to implement | achieve the multilayer glass excellent in the watertightness and airtight performance of the sealed space part with high rigidity.

In order to achieve such an object, the multilayer glass of the present invention has a plurality of plate glasses facing each other, an aggregate made of steel or stainless steel, a spacer filled with a desiccant, and a sealed space portion. ,
The aggregate is interposed in the glass peripheral edge between the plate glasses adjacent to each other, and is joined to the plate glass,
The spacer is provided to be joined to the aggregate so as to form a hollow chamber between the spacer and the inner side in the in-plane direction of the plate glass than the hollow chamber,
The multi-layer glass is characterized in that a passage communicating from the hollow chamber to the sealed space is filled with a sealing material.

  According to such a multi-layer glass, since the aggregate is interposed in the peripheral edge of the glass between the adjacent plate glasses and joined to the plate glass, the adjacent plate glasses have high strength and rigidity. It is joined by the material. For this reason, the multi-layer glass in which the plate glass and the aggregate having high strength and rigidity are joined is a glass having high rigidity. Further, since the aggregate is provided, a hollow chamber is formed between the aggregate and the spacer, and a passage communicating from the hollow chamber to the sealed space portion is filled with the seal material. Members and parts can be bonded to the double-glazed glass without impairing excellent watertightness and airtightness performance.

In such a multi-layer glass, the aggregate is
An outer peripheral wall portion exposed between the plate glasses on the peripheral end surface of the multilayer glass; and
A first extending portion and a second extending portion extending from the outer peripheral wall portion toward the inner side in the in-plane direction of the plate glass,
The hollow chamber is surrounded by the outer peripheral wall portion, the first extension portion, the second extension portion, the spacer,
The first extension part is
While extending from the side edge of the spacer in the out-of-plane direction of the plate glass to the outer position outside in the out-of-plane direction,
It is desirable that the second extension portion does not extend to the outer position.

  According to such a double-glazed glass, when the spacer is combined with the aggregate in the process of assembling the double-glazed glass, the spacer is transverse to the aggregate in a state where both the spacer and the aggregate are assembled (expected). It is possible to fit in the direction. Therefore, the assemblability of the multilayer glass is improved. In addition, by preparing a plurality of spacers for one type of aggregate, it is possible to cope with various glass thicknesses without preparing a plurality of aggregates.

In such a multilayer glass, the second extension portion extends to an outer end portion in the in-plane direction of the spacer,
The first plate glass of one of the plate glasses adjacent to each other is provided on the outer side of the outer position from which the first extension portion extends,
The first extending portion is sandwiched between the first plate glass and the side end portion of the spacer,
The side end portion sandwiching the first extension portion is a first side end portion, and a second side end portion opposite to the first side end portion is a second plate glass adjacent to the first plate glass. Facing each other
The first gap between the portion located at the outer position of the first extension and the first side end, and the second gap between the second plate glass and the second side end, The passage,
The sealing material is preferably provided in the first gap and the second gap.

  According to such a multilayer glass, it becomes possible to prevent liquid and gas from passing through these gaps by providing the sealing material in the first gap and the second gap. Therefore, it is possible to suppress a decrease in watertightness / airtightness of the sealed space.

  In such a multi-layer glass, it is desirable that the sealing material is provided in a space surrounded by the second extending portion, the second plate glass, and the outer end portion.

  According to such a multilayer glass, it is possible to prevent liquid or gas from passing through the space by providing the sealing material in the space. Therefore, it is possible to suppress a decrease in watertightness / airtightness of the sealed space.

  In such a multilayer glass, it is desirable that a screw hole for attaching the casing to the multilayer glass with a screw is provided in the outer peripheral wall portion.

  According to such a double-glazed glass, the water-tight / air-tight performance of the sealed space is likely to be impaired, so that the present invention is effective.

  According to the present invention, it is possible to realize a double-glazed glass having high rigidity and excellent watertight / airtight performance in a sealed space.

It is principal part sectional drawing of the multilayer glass 14 which concerns on this Embodiment. It is a perspective view of the aggregate 13 and the spacer 25 which concern on this Embodiment. 3 is a view showing a passage communicating from a hollow chamber 34 to a sealed space 32. FIG. It is sectional drawing in the corner part 13a of the multilayer glass 14 which concerns on this Embodiment. It is an explanatory conceptual diagram for explaining a problem in the assembly process of the multilayer glass. It is explanatory drawing for demonstrating that it is not necessary to prepare the aggregate 13 of the magnitude | size corresponding to this even if the thickness of the plate glass 12 changes.

=== About the structure of the multilayer glass 14 according to the present embodiment ===
Hereinafter, the multilayer glass 14 which concerns on one Embodiment of this invention is demonstrated with reference to drawings. FIG. 1 is a cross-sectional view of a main part of a multilayer glass 14 according to the present embodiment. FIG. 2 is a perspective view of the aggregate 13 and the spacer 25 according to the present embodiment, and shows the state of the aggregate 13 and the spacer 25 before and after the spacer 25 is combined with the aggregate 13. FIG. 3 is a view showing a passage communicating from the hollow chamber 34 to the sealed space portion 32, and the passage is indicated by an arrow. FIG. 4 is a cross-sectional view at the corner portion 13a of the multilayer glass 14 according to the present embodiment. In addition, in FIG. 4, description of the housing 16 is abbreviate | omitted.

  In the following description, when the shoji 10 attached to a building or the like is viewed from the indoor side, the vertical direction of the shoji 10 is the up-down direction, the left-right direction is the left-right direction, and the depth is the indoor-outdoor direction. The direction is shown as the prospective direction. Further, the members constituting the shoji 10 will be described by specifying the directions in the vertical direction, the left-right direction, the prospective direction, and the like in a state where the shoji 10 is attached to a building or the like even in a single state. The center (middle) side of the multi-layer glass 14 is defined as the inner side in the in-plane direction of the plate glass 12, and the plan view end side of the multi-layer glass 14 is defined as the outer side in the in-plane direction of the plate glass 12. Further, the center (middle) side in the expected direction (thickness direction) of the multilayer glass 14 is defined as the inner side in the out-of-plane direction of the plate glass 12, and the end side in the expected direction (thickness direction) of the multilayer glass 14 is defined as The outside in the out-of-plane direction.

  The multilayer glass 14 of the present embodiment is a glass to which the shoji 10 is attached. The casing 16 of the shoji 10 is fixed to the multilayer glass 14 with screws 18 (screws) (see FIG. 1). The multi-layer glass 14 includes a plurality of (two in the present embodiment) plate glass 12 facing each other, an aggregate 13, a spacer 25, and a primary seal 26 and a secondary seal 27 as an example of a seal material. And have.

  The two plate glasses 12 have a rectangular shape and face each other with an interval in the prospective direction.

  The aggregate 13 is for increasing the rigidity of the multilayer glass 14 and, in addition, enables the housing 16 and components to be attached to the multilayer glass 14. The aggregate 13 is a member made of steel or stainless steel (in the present embodiment, made of steel).

  The aggregate 13 is positioned up and down, the aggregate upper portion 131 and the aggregate lower portion 132 whose longitudinal direction is along the left and right direction, and the aggregate left portion 133 and the aggregate that are positioned on the left and right and whose longitudinal direction is along the vertical direction. Right portion 134. The central part surrounded by the aggregate upper part 131, the aggregate lower part 132, the aggregate left part 133, and the aggregate right part 134 is hollow (see FIG. 2). And the aggregate upper part 131, the aggregate lower part 132, the aggregate left part 133, and the aggregate right part 134 are each interposed by the glass peripheral part 12a of the four sides of the two glass plates 12. FIG. That is, the aggregate 13 is interposed in the glass peripheral edge portion 12 a between the adjacent glass plates 12.

  The aggregate 13 provided on the four glass peripheral portions 12a of each plate glass 12 between the two sheet glasses 12 has the same cross-sectional shape (see FIG. 1) (however, as will be described later, the aggregate 13 corner portions 13a are different). Hereinafter, the cross-sectional shape will be described with reference to FIG.

  As shown in FIG. 1, the aggregate 13 includes an outer peripheral wall portion 21 exposed on the peripheral end surface 14 a of the multilayer glass 14 between the two sheet glasses 12 of the multilayer glass 14, and The first extending portion 22 and the second extending portion 23 extending toward the inner side in the in-plane direction (upper side in FIG. 1), and the inner side in the out-of-plane direction of the glass sheet 12 from the first extending portion 22 (in FIG. 1). Projecting portion 24 projecting to the left side). The aggregate 13 is formed by bending a steel plate material by roll forming.

  Here, the 1st extension part 22 is more in this out-of-plane direction (the 1st side end part 25a) than the side end part (1st side end part 25a) of the spacer 25 mentioned later in the out-of-plane direction (in other words prospective direction) of the plate glass 12. While extending to the outer position P on the outer side (right side in FIG. 1) in the prospective direction), the second extending portion 23 faces the outer position (ie, the second side end portion 25b of the spacer 25). It does not extend to the outside outside position) in the outward direction.

  That is, the outer peripheral wall portion 21 is formed with a width narrower than the interval between the two sheet glasses 12, and the first extending portion 22 and the second extending portion 23 extend from both edges in the prospective direction of the outer peripheral wall portion 21. ing. The first extending portion 22 extends inward in the in-plane direction (upper side in FIG. 1) and outward in the out-of-plane direction (outside in the prospective direction; right side in FIG. 1) of the glass sheet 12 and reaches the outer position P (hereinafter referred to as “the outer position P”). Then, for the sake of convenience, the portion before reaching the outer position is referred to as a pre-arrival portion 22a, and the portion after reaching the outer position is referred to as a post-arrival portion 22b). One of the glass plates 12 adjacent to each other (referred to as the first glass plate 12b) is located on the outer side of the outer position P where the first extending portion 22 extends (in other words, on the outer side of the post-arrival portion 22b). ) And a post-arrival portion 22b of the first extending portion 22 is sandwiched between the first glass plate 12b and the first side end portion 25a of the spacer 25. On the other hand, the second extending portion 23 extends inward in the in-plane direction (upward in FIG. 1), and the outer end 25d (in FIG. 1) of the spacer 25 in the in-plane direction (vertical direction in FIG. 1). , The lower end) and abuts on the outer end 25d.

  Further, a protruding portion 24 protrudes from the edge of the post-arrival portion 22b on the side opposite to the pre-arrival portion 22a to the inside in the out-of-plane direction (left side in FIG. 1). The projecting portion 24 extends along the inner end portion 25c (upper end portion in FIG. 1) of the spacer 25 in the in-plane direction (vertical direction in FIG. 1) (in other words, the inner end portion 25c is Projecting along the out-of-plane direction.

  Further, as described above, the casing 16 of the shoji 10 is fixed to the multilayer glass 14 with the screw 18, but the aggregate 13 of the multilayer glass 14, more specifically, The body 16 is fixed with screws 18. That is, the housing 16 is located outside the outer peripheral wall portion 21 in the in-plane direction (lower side in FIG. 1). The housing 16 and the outer peripheral wall portion 21 are respectively provided with the housing. A housing screw hole 16a for attaching 16 to the multilayer glass 14 with a screw 18 and an outer peripheral wall screw hole 21a are provided. And the outer peripheral wall part 21 is being fixed to the housing 16 in the state which the screw 18 penetrated these screw holes.

  The spacer 25 is a member provided between the two glass plates 12 in the out-of-plane direction (in other words, the prospective direction). The spacer 25 is filled with a desiccant, and the spacer 25 dries the sealed space portion 32 provided on the inner side in the in-plane direction (upper side in FIG. 1) than the spacer 25 (dehumidification). Play a role.

  The spacer 25 is located above and below, and a spacer upper portion 251 and a spacer lower portion 252 whose longitudinal direction is along the left and right direction, a spacer left portion 253 and a spacer right portion 254 that are located on the left and right and whose longitudinal direction is along the up and down direction, It has. The spacer upper portion 251, the spacer lower portion 252, the spacer left portion 253, and the spacer right portion 254 are respectively interposed in the four glass peripheral portions 12 a of the two plate glasses 12. That is, the spacer 25 is also interposed in the glass peripheral edge portion 12 a between the adjacent glass plates 12, like the aggregate 13.

  The spacers 25 provided on the four glass peripheral portions 12a of each plate glass 12 between the two glass plates 12 have the same cross-sectional shape (see FIG. 1). Hereinafter, the cross-sectional shape will be described with reference to FIG.

  As shown in FIG. 1, the spacer 25 includes a first side end 25a, a second side end 25b opposite to the first side end 25a, the inner end 25c, and the outer end 25d. The interior surrounded by these is filled with the desiccant.

  The spacer 25 is provided so as to form a hollow chamber 34 with the aggregate 13 and on the inner side in the in-plane direction (upper side in FIG. 1) than the hollow chamber 34. That is, the hollow chamber 34 is surrounded by the outer peripheral wall portion 21 of the aggregate 13, the pre-arrival portion 22 a of the first extension portion 22, the second extension portion 23, and the outer end portion 25 d of the spacer 25.

  As described above, the first side end portion 25a sandwiches the first extension portion 22 (the post-arrival portion 22b) between the first plate glass 12b. The second side end portion 25b faces the other one of the glass plates 12 adjacent to each other (that is, the second glass plate 12c adjacent to the first glass plate 12b).

  The sealing materials (primary seal 26 and secondary seal 27) are for joining the plate glass 12, the aggregate 13, and the spacer 25 to each other. Further, as will be described later, it also serves to fill a passage communicating from the hollow chamber 34 to the sealed space portion 32. In the present embodiment, polyisobutylene is used as the primary seal 26 and a silicone sealant is used as the secondary seal 27.

  The primary seal 26 fills the gap G <b> 1 between the post-arrival portion 22 b located at the outer position P of the first extension portion 22 and the first glass sheet 12 b. The aggregate 13 and the plate glass 12 are joined by providing the primary seal 26 in the gap G1. Further, the primary seal 26 fills a gap G <b> 2 (corresponding to the first gap) between the post-arrival portion 22 b and the first side end portion 25 a of the spacer 25. The aggregate 13 and the spacer 25 are joined by providing the primary seal 26 in the gap G2. Further, the primary seal 26 fills a gap G3 (corresponding to the second gap) between the second side end portion 25b of the spacer 25 and the second glass sheet 12c. By providing the primary seal 26 in the gap G3, the plate glass 12 and the spacer 25 are joined.

  The secondary seal 27 fills the space S1 between the part 22a before reaching the first extension portion 22 and the first glass sheet 12b (filled in the space S1). By providing the secondary seal 27 in the space S1, the aggregate 13 and the plate glass 12 are joined. The secondary seal 27 fills the space S2 surrounded by the second extending portion 23, the second glass sheet 12c, and the outer end portion 25d (filled in the space S2). By providing the secondary seal 27 in the space S2, the plate glass 12, the aggregate 13 and the spacer 25 are joined to each other.

  Further, the sealing material plays a role of preventing the watertight / airtight performance of the sealed space portion 32 from being deteriorated by filling a passage communicating from the hollow chamber 34 to the sealed space portion 32. That is, as shown in FIG. 3, the gap G <b> 2 and the gap G <b> 3 are passages that communicate from the hollow chamber 34 to the sealed space portion 32. Therefore, by providing the primary seals 26 in these gaps, it becomes possible to prevent liquid (water, etc.) or gas (air, etc.) from passing through these gaps, and the watertight / airtightness of the sealed space portion 32 is prevented. A decrease in performance can be suppressed.

  Further, as shown in FIG. 3, the space S <b> 2 is similarly a passage communicating from the hollow chamber 34 to the sealed space portion 32. Therefore, by providing the secondary seal 27 in the space S2, it becomes possible to prevent the liquid (water, etc.) or gas (air, etc.) from passing through the space S2, and the watertight / airtight performance of the sealed space portion 32. Can be suppressed.

  Next, the structure in the corner part 13a (refer FIG. 2) of the aggregate 13 is demonstrated, referring FIG.2 and FIG.4. The corner portion 13a is a portion where the aggregate 13 is bent at a right angle, and has a configuration different from the configuration shown in FIG. 1 as will be described below in order to further ensure the watertight / airtight performance of the sealed space portion 32.

  That is, as shown in FIG. 2, a part of the aggregate 13 is notched in the corner portion 13a. Specifically, as is clear by comparing FIG. 1 and FIG. 4, a portion (referred to as the first notch portion 40) corresponding to the aforementioned pre-arrival portion 22 a of the first extension portion 22, A portion corresponding to the two extending portions 23 (referred to as a second cutout portion 42) is cut out. And by providing such a notch portion, the hollow chamber 34 can be filled with the secondary seal 27.

  That is, the secondary seal 27 is a fluid sealing material, and as shown in FIG. 4, between the first plate glass 12b and the outer peripheral wall portion 21 and between the second plate glass 12c and the outer peripheral wall portion 21 (see FIG. 4), the secondary seal 27 is injected into the multi-layer glass 14. At this time, if the pre-arrival portion 22a and the second extension portion 23 are present, the hollow chamber 34 cannot be filled, so the secondary seal 27 is injected by cutting out the pre-arrival portion 22a and the second extension portion 23. The hollow chamber 34 can be filled by securing a passage. Thus, in the corner portion 13a, the hollow chamber 34 is filled with the secondary seal 27, so that liquid (water or the like) or gas (air or the like) is less likely to reach the sealed space portion 32. Therefore, in the corner portion 13a, it is possible to further ensure the watertight / airtight performance of the sealed space portion 32.

=== Effectiveness of Double-Layer Glass 14 According to the Present Embodiment ===
As described above, the multilayer glass 14 according to the present embodiment includes a plurality of plate glasses 12 facing each other, an aggregate 13 made of steel or stainless steel, a spacer 25 filled with a desiccant, and a sealed space portion 32. The aggregate 13 is interposed at the glass peripheral edge between the adjacent glass plates 12 and joined to the glass plate 12, and the spacer 25 is a hollow chamber 34 between the aggregate 13. And a passage communicating from the hollow chamber 34 to the sealed space portion 32 is provided as a sealing material on the inner side in the in-plane direction of the plate glass 12 relative to the aggregate 13. It was decided that it was buried by.

  Thus, according to this Embodiment, since the aggregate 13 is interposed by the glass peripheral part 12a between the mutually adjacent plate glasses 12, and is joined to the plate glass 12, the adjacent plate glasses 12 are It is joined by an aggregate 13 having high strength and rigidity. For this reason, the multilayer glass 14 in which the plate glass 12 and the aggregate 13 having high strength and rigidity are joined is a glass having high rigidity. Further, in the present embodiment, by providing the aggregate 13, a hollow chamber 34 is formed between the aggregate 13 and the spacer 25. Since the passage communicating with 32 is filled with the sealing material, it is possible to realize the excellent water tightness / air tightness performance of the sealed space portion 32.

  Specifically, as described above, by providing the primary seal 26 in the gap G2 and the gap G3, it is possible to prevent liquid (water, etc.) and gas (air, etc.) from passing through these gaps. Become. Therefore, it is possible to suppress a decrease in watertightness / airtightness performance of the sealed space portion 32.

  Further, as described above, by providing the secondary seal 27 in the space S2, it becomes possible to prevent liquid (water or the like) or gas (air or the like) from passing through the space S2. Therefore, it is possible to suppress a decrease in watertightness / airtightness performance of the sealed space portion 32.

  Furthermore, in the present embodiment, the outer peripheral wall portion 21 is provided with the outer peripheral wall portion screw hole 21a for attaching the housing 16 to the multilayer glass 14 with the screw 18. Therefore, it is in a situation where liquid (water or the like) or gas (air or the like) easily enters the hollow chamber 34 from the outside. That is, the double-glazed glass 14 according to the present embodiment is in a situation where liquid or the like moves through the passage and the watertight / airtight performance of the sealed space portion 32 is likely to be impaired. It will work effectively.

  In the present embodiment, the first extension portion 22 extends to the outer side position P outside the side end portion (first side end portion 25a) of the spacer 25 in the out-of-plane direction. The two extending portions 23 are not extended to the outer position (that is, the outer position outside the second end portion 25b of the spacer 25 in the out-of-plane direction). Therefore, the assemblability of the multilayer glass 14 is improved.

  As in the case of the first extension portion 22, if the second extension portion 23 extends to the outer position (for example, in FIG. 1, the first extension portion 22 and the second extension portion 23 are As shown in FIG. 5, when the spacer 25 is combined with the aggregate 13 in the process of assembling the multilayer glass 14, when the multilayer glass 14 extends to the outer position and has a symmetrical shape. After the incision C is made in the aggregate 13, an operation of winding the aggregate 13 around the spacer 25 is necessary. Therefore, the problem that an assembly process becomes complicated may arise.

  On the other hand, in the present embodiment, the double-glazed glass 14 does not have a bilaterally symmetric shape and the second extending portion 23 is not extended to the outer position, so that as shown in FIG. When the spacer 25 is combined with the aggregate 13 in the assembling process of the multilayer glass 14, the spacer 25 and the aggregate 13 are both assembled, and the spacer 25 is transverse (prospective) with respect to the aggregate 13 ( In FIG. 1, it is possible to fit in the direction from left to right. Therefore, it is not necessary to perform complicated winding work. Therefore, the assemblability of the multilayer glass 14 is improved.

  Furthermore, in the present embodiment, when the spacer 25 is fitted into the aggregate 13 in the direction from left to right in FIG. 1, the above-described protrusion 24 guides the spacer 25 (guide member). As a role. Therefore, the operator can easily perform the fitting operation, and the assemblability of the multilayer glass 14 is further improved.

  In addition, the first extension portion 22 extends to the outer side outer position P in the out-of-plane direction from the side end portion of the spacer 25, while the second extension portion 23 does not extend to the outer side position. As a result, the following advantages also arise.

  As in the case of the first extension portion 22, if the second extension portion 23 extends to the outer position (for example, in FIG. 1, the first extension portion 22 and the second extension portion 23 are When the laminated glass 14 extends to the outer position and has a symmetrical shape), it is necessary to prepare an aggregate 13 having a size corresponding to the thickness of the glass sheet 12 whenever the thickness of the glass sheet 12 changes. . For example, when the thickness of the second glass sheet 12c is thinner, the distance in the out-of-plane direction from the first glass sheet 12a to the second glass sheet 12b is longer, and thus is larger (that is, the length in the out-of-plane direction is longer). ) Aggregate 13 needs to be prepared. On the other hand, when the thickness of the second glass sheet 12c is thicker, the distance in the out-of-plane direction from the first glass sheet 12a to the second glass sheet 12b is shortened, and therefore smaller (that is, the length in the out-of-plane direction is shorter). ) Aggregate 13 needs to be prepared.

  On the other hand, in the present embodiment, the multi-layer glass 14 does not have a symmetrical shape and the second extending portion 23 is not extended to the outer position, so that as shown in FIG. Even if the thickness of the plate glass 12 changes, it is not necessary to prepare the aggregate 13 having a size corresponding to this. That is, as shown in FIG. 6A, even if the thickness of the second glass sheet 12c is thinner and the distance in the out-of-plane direction from the first glass sheet 12a to the second glass sheet 12b is increased, a larger spacer is used. 25 need to be prepared, but there is no need to change the aggregate 13 (see (a) and (b) of FIG. 6 for comparison. Note that (b) of FIG. 6 is similar to FIG. 1). is there). On the other hand, as shown in FIG. 6C, even if the second plate glass 12c is thicker and the distance in the out-of-plane direction from the first plate glass 12a to the second plate glass 12b is shortened, the smaller spacer However, it is not necessary to change the aggregate 13 (see (b) and (c) of FIG. 6 for comparison). Thus, in this embodiment, by preparing a plurality of spacers 25 for one type of aggregate 13, it is possible to cope with various glass thicknesses without preparing a plurality of aggregates 13. .

  The above embodiments are for facilitating the understanding of the present invention, and are not intended to limit the present invention. The present invention can be changed and improved without departing from the gist thereof, and it is needless to say that the present invention includes equivalents thereof.

12 Plate glass, 12a Glass peripheral part, 12b 1st plate glass, 12c 2nd plate glass 13 Aggregate 14 Multi-layer glass, 14a Circumferential end face 16 Housing, 18 Screw 21 Outer peripheral wall part, 21a Outer peripheral wall part screw hole, 22 First extension Protruding part, 23 Second extending part 25 Spacer 25a First side end part, 25b Second side end part, 25c Inner end part, 25d Outer end part 26 Primary seal, 27 Secondary seal 32 Sealed space part, 34 Hollow chamber G1 gap, G2 gap, G3 gap P Outer position S1 space, S2 space

Claims (5)

A plurality of plate glass facing each other, an aggregate made of steel or stainless steel, a spacer filled with a desiccant, and a sealed space,
The aggregate is interposed in the glass peripheral edge between the plate glasses adjacent to each other, and is joined to the plate glass,
The spacer is provided to be joined to the aggregate so as to form a hollow chamber between the spacer and the inner side in the in-plane direction of the plate glass than the hollow chamber,
A multilayer glass characterized in that a passage communicating from the hollow chamber to the sealed space is filled with a sealing material. The multilayer glass according to claim 1,
The aggregate is
An outer peripheral wall portion exposed between the plate glasses on the peripheral end surface of the multilayer glass; and
A first extending portion and a second extending portion extending from the outer peripheral wall portion toward the inner side in the in-plane direction of the plate glass,
The hollow chamber is surrounded by the outer peripheral wall portion, the first extension portion, the second extension portion, the spacer,
The first extension part is
While extending from the side edge of the spacer in the out-of-plane direction of the plate glass to the outer position outside in the out-of-plane direction,
Said 2nd extension part is not extended to this outer side position, The multilayer glass characterized by the above-mentioned. The multilayer glass according to claim 2,
The second extending portion extends to an outer end portion in the in-plane direction of the spacer,
The first plate glass of one of the plate glasses adjacent to each other is provided on the outer side of the outer position from which the first extension portion extends,
The first extending portion is sandwiched between the first plate glass and the side end portion of the spacer,
The side end portion sandwiching the first extension portion is a first side end portion, and a second side end portion opposite to the first side end portion is a second plate glass adjacent to the first plate glass. Facing each other
The first gap between the portion located at the outer position of the first extension and the first side end, and the second gap between the second plate glass and the second side end, The passage,
The double-glazed glass, wherein the sealing material is provided in the first gap and the second gap. The multilayer glass according to claim 3, wherein
The multilayer glass, wherein the sealing material is provided in a space surrounded by the second extending portion, the second plate glass, and the outer end portion. A multilayer glass according to any one of claims 2 to 4,
The outer peripheral wall is provided with a screw hole for attaching a casing to the multilayer glass with a screw.

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