JP2000255665A - Transporting jig for double glazing and method of fixing double glazing - Google Patents

Abstract

PROBLEM TO BE SOLVED: To transport a double sheet glass while being fixed to a glass transporting member even if an adhesive agent is not completely hardened during transportation of a double glazing in which the adhesive agent is filled between the two sheet glasses. SOLUTION: There is provided a resin transporting jig 17 having an L-shaped section. In the case that a total thickness of a double glazing G is defined as T1 and a thickness of one sheet glass g1 (or a sheet glass g2) is defined as t1, a glue size W in one flange 42 of the transporting jig 17 is set to be smaller than T1 and larger than (T1-t1). With such an arrangement as above, since the flange 42 is always abutted against the edges of the two sheet glasses, g1, g2, an external force can be equally acted against the two sheet glasses g1, g2 from the flange 42 when the external force is applied to the flange 42.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a double glazing for transporting a double glazing, particularly a double glazing having an incompletely solidified adhesive, which is suitable for fixing to a glass carrier or the like. The present invention relates to a jig and a method for fixing a double glazing.

[0002]

2. Description of the Related Art Double-glazed glass having improved heat insulation and soundproofing properties is used for windows of houses, buildings, vehicles and the like. The structure of the double glazing is described below. FIG. 10 (a), (b)
It is explanatory drawing explaining the structure of a double glazing, (a) is a perspective view of the principal part, (b) is the arrow b view of (a).
In FIG. 1A, a double-glazed glass 100 is a glass in which a frame-shaped spacer 102 is interposed between two glass sheets 101, 101.

In FIG. 1B, a spacer 102 is formed by filling and bonding two types of adhesives 103 and 104 between sheet glasses 101 and 101. The adhesive 104 is used to bond an outer surface 105 of the sheet glasses 101 and 101 to each other. Edge 106, 10
6 is almost the same as that of FIG. (The other edges of the sheet glass 101, 101 are also
Was similarly formed. )

[0004] The adhesives 103 and 104 are two sheets of glass 1
01, 101, and also serves as a sealant,
In particular, the adhesive 103 has an extremely high moisture permeability resistance. For the adhesive 104, the sheet glass 1 after curing
01 and 101 have a large holding force. The spacer 102 accommodates a desiccant 107... (Indicating a plurality of the same, the same applies hereinafter), and connects the air layer 108 surrounded by the plate glasses 101, 101 and the spacer 102 with the inside of the spacer 102 by a communication hole 109. Since the communication is established, the inside of the air layer 108 is dehumidified.

[0005] A conventional method of fixing the above-described double glazing 100 to a glass carrier for transporting the same will now be described. The double glazing 100A, 100B,
‥‥, 100K are the same as the double-glazed glass 100, but are distinguished for convenience. FIG. 11 is a perspective view for explaining a conventional fixing method for fixing the double-glazed glass to the glass carrier. The two multi-layered glasses 100A and 100B are placed on the bottom surface 111 of the glass carrier 110, and the glass carrier 110 is mounted. Glass 10 on the wall 112
0A and 100B along one side thereof, and the double glazings 100C and 10 are successively placed on these double glazings 100A and 100B.
0D, 重 ね are stacked, the double glazing 100K is laid on both of the double glazings 100I, 100J, and the double glazing 100A, 100B, ‥‥, 100K is tied to the glass carrier 110 with band members 113, 113 and fixed. Indicates that

FIGS. 12 (a) and 12 (b) are illustrations for explaining a method of fixing a double-layer glass, and substantially correspond to the plan view of FIG. However, the number of double glazings was reduced for convenience of explanation. In (a), first, the glass carrier 110
The double glazings 100A, 100B are erected along the wall surface 112 of the slab.
14 is interposed.

Next, the multi-layer glass 100A, 100B is interposed between the multi-layer glass 100A and the
C, stack 100D. Further, the double glazing 100C, 1
The double glazing 100K is stacked on both sides of 00D via the cushioning materials 115 and 115. In (b), the double glazing 10
0A to 100D and 100 K of double glazing are used for the band member 1.
Tighten with 13.

[0008]

In the above (b), since the band member 113 directly hangs on the corners of the double glazings 100C and 100D, the band glass C1 and D1 constituting the double glazings 100C and 100D are applied in the width direction. Forces FC1 and FD1 (left and right directions in the figure) act.

For example, if the respective adhesives 104 of the double glazings 100C and 100D are not completely cured, the above-described forces FC1 and FD1 in the width direction are used.
The glass sheets C1 and D1 are paired with the glass sheets C, respectively.
2, there is an inconvenience that D2 is shifted in the direction of the arrow. Further, a force in the width direction is generated when the band member 113 is hung or removed from the plate glass K1 of the double-glazed glass 100K, and the plate glass K1 becomes a pair of plate glass K2.
May be shifted in the width direction.

Accordingly, an object of the present invention is to provide a carrying jig for a double-glazed glass which can be fixed and transported to a glass carrying device even when the adhesive is not completely cured, and a fixing of the double-glazed glass. It is to provide a method.

[0011]

In order to achieve the above-mentioned object, a first aspect of the present invention is a transporting jig for a double glazing, wherein an adhesive for fixing the glazing is filled between two glazings. The transport jig is a resin part having an L cross section. When the total thickness of the double-glazed glass is T1 and the thickness of one sheet of glass is t1, the transport jig is provided. The inner dimension W of one of the flanges is smaller than T1, and (T1-t
1) Set larger.

The inner dimension W of one of the flanges is set smaller than T1 and larger than (T1−t1), and the flange is always brought into contact with the edges of the two glass sheets. Therefore, when an external force is applied to the flange, the external force uniformly acts on the two glass sheets from the flange.

When the inner dimension W is set smaller than (T1−t1), the flange hits only one of the glass sheets. Therefore, when an external force acts on the flange, the external force from the flange acts on only one of the glass sheets. When the inner dimension W is set larger than T1,
The flange may hit another double glazing sheet glass. Therefore, when an external force acts on the flange, the external force from the flange also acts on the sheet glass of another double glazing.

The second aspect of the present invention is to set the inner dimension W to (T1-
0.5t1). Since the tip of one of the flanges is located at the center of the thickness of the glass sheet, the flange hits the two glass sheets even if the inner dimension W varies due to processing.

According to a third aspect of the present invention, the double-glazed glass in which the adhesive for fixing the spacer is incompletely solidified is leaned or placed on a glass carrier, and the double-glazed glass is mounted on a corner of the double-glazed glass. By attaching a band or a band from above the carrying jig with a carrying jig, the adhesive is fixed to the glass carrying tool while the adhesive is incompletely solidified. The clamping force of the band or the band acts equally on the two sheets of double-glazed glass from the band or the band via the carrying jig.

[0016]

Embodiments of the present invention will be described below with reference to the accompanying drawings. The drawings should be viewed in the direction of reference numerals. FIG. 1 is a perspective view of a glass carrier using a transporting jig (first embodiment) for a double-glazed glass according to the present invention, and shows a state in which the double-glazed glass is vertically stacked and fixed. The glass carrier 10 includes a carrier body 13 including a floor 11 and a wall 12, and elastic bands 16, 16 extending from one side 14 to the other side 15 of the wall 12.
, And a backing plate 17 serving as a jig for transporting the multi-layer glass G interposed between the bands 16, 16 and the multi-layer glass G. The multilayer glass G is the same as the multilayer glass 100 shown in FIG.

The floor 11 of the carrier 13 has side frames 21 and 21 provided on both sides, and front and rear legs 22 extending to the front and rear ends of the side frames 21 and 21 respectively. , 23 (the rear leg 23 is not shown) and a floor surface 24 provided between the side frames 21 and 21 with the rear side lowered.
And the horizontal leg 2 provided below the side frames 21 and 21
5, 25 (one side not shown). 26 are openings (rear leg 23, one side leg 25) of front and rear legs 22, 23 and side legs 25, 25 for inserting fork-shaped claws of a forklift or the like. The opening is not shown)
It is. The floor surface 24 is formed by attaching a sheet made of rubber or a soft resin to the surface so that the double-glazed glass G is not damaged.

The wall portion 12 of the carrier 13 has a rear frame 2 standing up from the side frames 21 and 21 of the floor 11.
8, 28 (one side not shown) and these rear frames 2
8 and 28, the inclined frames 32 and 32 which are inclined from the side frames 21 and 21 to the rear frames 28 and 28, and the rear surface of the floor 11 so as to be inclined rearward at substantially right angles. The inclined frame 32,3
The band attachment portions 34 attached to the side surfaces of the rear frames 28, 28 for attaching the wall surface 33 provided between the two and the both ends of the bands 16, 16 (the band attachment portions 34, 34 of the rear frame 28 on one side are not shown). ). The wall surface 33
A sheet made of rubber or a soft resin is stuck on the surface so that the double-layer glass G is not damaged.

FIG. 2 is a view substantially corresponding to the plan view of FIG. 1 and is a view substantially corresponding to the plan view of FIG. This shows a state in which one sheet on the front side is overlapped in the front-rear direction, and one sheet on the front side is overlapped in the center of two rows. A first cushion material 36 is arranged between the left and right rows, and a second cushion material 37, 37 is interposed between the overlapping double-glazed glasses G, G so that the double-glazed glasses G are conveyed during transportation. Prevents damage or scratches caused by contact or slippage.

The band 16 has one end provided with a hook 38 to be hooked on the band mounting portion 34. Patch plate 1
Reference numeral 7 denotes an L-shaped cross section, and when the band 16 is hung, two corners of one double-glazed glass G on the front side are provided;
This is a resin part to be applied to each of two corners of the double-glazed glass G on the rear side of the single glass.

FIG. 3 is a perspective view of the first embodiment of the backing plate according to the present invention. The backing plate 17 has a long flange 41 having an inner diameter V and an inner diameter smaller than the inner diameter V of the long flange 41. A short flange 42 having a dimension W is provided. A band-hung groove 44 is formed in the outer corner 43 to prevent the band 16 from coming off when the band 16 (see FIG. 2) is hung.
Is provided.

FIG. 4 is a sectional view taken along the line 4-4 in FIG. 3, and shows the relationship between the dimensions of the double-glazed glass G and the backing plate 17. Two glass sheets g1 and g2 constituting the double-glazed glass G
, The plate glass g1 has one side surface f1, another side surface f2, and an edge e1, and the plate glass g2 has one side surface f3, another side surface f4, and an edge e2.

In the long flange 41 and the short flange 42 constituting the backing plate 17, the long flange 41 is
a and an outer surface 41b, and the short flange 42
2a, an outer side surface 42b and a tip portion 42c. Inner surface 41a of long flange 41 and inner surface 42 of short flange 42
a is a substantially right angle. In addition, long flange 4
1 outer surface 41b and outer surface 42b of short flange 42
Is not limited to a plane, and may have any shape.

The total thickness of the multilayer glass G is T1, and the thickness of each of the two glass sheets g1 and g2 of the multilayer glass G is t1.
Then, the inner dimension W of the short flange 42 of the backing plate 17
Is (T1-t1) <W <T1. That is, the backing plate 1
When the inner surface 41a of the long flange 41 is applied to one side f1 of the glass sheet g1, the inner surface 42a of the short flange 42
Always the respective edges e1, e2 of the sheet glass g1, g2
Indicates that

Here, assuming that the distance from the other side f4 of the sheet glass g2 to the tip end 42c of the short flange 42 is S,
S = T1-W. Therefore, 0 <S <t1 is satisfied. If the distance S is 0.5t1, the inner dimension W is W = (T1−0.5t1).

As described above, the distance S is set to 0.5t1.
That is, by setting the front end portion 42c of the short flange 42 at the center of the thickness of the plate glass g2, the contact plate 17 is formed by processing.
Even if the inner dimension W varies, the short flange 42 can always be applied to the two glass sheets g1 and g2.

Also, by providing the band hanging groove 44,
While transporting the double-glazed glass G with the band 16
There is no fear that the backing plate 17 interposed between the glass and the double-glazed glass G will fall off. Further, since the bottom surface 44a of the band hooking groove 44 is formed in an arc shape, the sliding between the band 16 and the bottom surface 44a can be improved.
Scratches are less likely to occur, and the life of the band 16 can be extended.

Furthermore, the inner dimension V of the long flange 41
Is made larger than the inner dimension W of the short flange 42, the area of the long flange 41 in contact with the double-glazed glass G is increased, and
When a force in the front-rear direction is applied to the double-glazed glass G on the most front side shown in FIG.

Next, a method for fixing the above-described double-layer glass G will be described. FIGS. 5A to 5D are explanatory views illustrating a method of fixing a double-glazed glass according to the first embodiment of the backing plate according to the present invention. It should be noted that the number of the multi-layer glass G is smaller than that in FIG. 2 for convenience of explanation. Further, the spacer 102 and the adhesive 103 are omitted. Further, in order to identify each of the multi-layer glasses G, Ga, Gb,
Gc, Gd, and Ge were used, and the reference numerals 17a, 17b, 17c, and 17d were used to identify the respective backing plates 17. In (a), the wall surface 3 of the glass carrier 10
3, the double-glazed glass Ga, Gb is arranged in two rows, and one surface of each of the double-glazed glass Ga, Gb is arranged along the wall surface 33.
6 is sandwiched.

In (b), the multilayer glasses Gc and Gd are overlapped on the multilayer glasses Ga and Gb via the second cushion members 37 and 37, respectively.
The double-layer glass Ge is laminated on Gd via the second cushion members 37,37. The above-mentioned multilayer glass Ga to Ge is transported to the next step in a state where the curing of the adhesive 104 is incomplete (incompletely solidified) in order to improve productivity.

In (c), the contact plate 17a is applied to the right corner of the multilayer glass Gd, and the band 16 is pressed from above. Then, the contact plate 17b is applied to the right corner of the multilayer glass Ge. The band 16 is pressed from above, and thereafter, the contact plate 17c is applied to the left corner of the multilayer glass Ge, the band 16 is pressed from above, and the contact plate 17d is pressed to the left corner of the multilayer glass Gc. And press the band 16 from above. At this time, as the band 16 is pulled in the direction of the arrow, the force F1, F in the left direction in the figure is applied to the double-glazed glass Gd, Ge via the contact plates 17a, 17b.
2 works.

In (d), the hook 38 of the band 16
Is hung on the band attaching portion 34 of the wall portion 12. At this time, due to the tightening force of the band 16, a rightward force F3 is generated in the multilayer glass Gc, and a leftward force F4 is generated in the multilayer glass Gd.
Due to these forces F3 and F4, the multilayer glasses Gc and Gd move inward by a distance d, respectively. Further, a rightward force F5 and a leftward force F6 act on the multilayer glass Ge, but since these forces F5 and F6 face each other and have the same magnitude, the multilayer glass Ge does not move.

After transporting the multi-layer glass Ga to Ge, the band 1
When the band 6 is removed, as the band 16 shrinks, (c)
As shown in (1), forces F7 and F8 in the right direction act on the double-glazed glass Gc and Ge via the contact plates 17d and 17c, respectively.

As described in the above (c) and (d), 2
The multi-layered glass Ga to Ge in which the adhesive 104 fixing the two glass sheets is incompletely solidified is leaned or placed on the glass carrier 10 and applied to the corners of the multi-layered glass Gc, Gd, Ge to contact the plates 17d, 17a, 17c and 17b are attached, and the band 16 is hung from above the contact plates 17d, 17a, 17c and 17b.
a, Gc, Gd, G
The force F1 from the band 16 is applied to each plate glass g1 and g2 of e.
F8 acts evenly, and no deviation occurs between the sheet glasses g1 and g2. The above F1 to F8 are considered to act even during transportation by the glass carrier 10, but even during transportation of such a double-layer glass Ga to Ge, the sheet glass g1,
The displacement between g2 can be prevented.

The operation of the above-mentioned backing plate 17 will now be described. 6 (a) to 6 (c) are explanatory views for explaining the operation of the caul plate, where (a) is the present embodiment (first embodiment),
(B) shows Comparative Example 1, and (c) shows Comparative Example 2. In (a), as described with reference to FIG. 4, the inner dimension W of the backing plate 17 satisfies (T1−t1) <W <T1. Further, the distance S is 0 <S <t1.

In the comparative example 1 shown in FIG. 7B, the inner dimension W1 of the short flange 121 of the backing plate 120 is smaller than (T1-t1), that is, W1 <(T1-t1).
Assuming that S1 = T1-W1, t1 <S1 is an example where the short flange 121 does not hit one plate glass g2. Therefore, when a leftward force F11 acts on the double-glazed glass G in an incompletely cured state of the adhesive 104 via the backing plate 120, only the flat glass g1 moves and the flat glass g
1 and the sheet glass g2.

The comparative example 2 shown in FIG.
In this example, the inner dimension W2 of the short flange 126 is larger than T1, that is, T1 <W2.
6 corresponds to both plate glasses g1 and g2.

For example, when the laminated glass sheets G, G are close to each other, the short flange 126 also hits the laminated glass sheet G, which is different from the laminated glass sheet G with the backing plate 125. At this time, when the force F12 acts on the backing plate 125, the whole of the double-layer glass G and the plate glass g1 of another double-layer glass G move together, and the gap between the plate glasses g1 and g2 of another double-layer glass G changes. Occurs.

FIG. 7 is a perspective view showing a second embodiment of the backing plate according to the present invention, in which a protruding portion 52 having a substantially triangular cross section is provided at a corner 51 of the backing plate 50, and The protrusion 5 is provided at the edge e3 (which is also the edge of the glass sheet g1).
Indicates that 2 was applied. The protruding portion 52 may be formed integrally with the long flange 53 and the short flange 54 of the backing plate 50, or may be attached to the long flange 53 and the short flange 54 by bonding, welding, or the like. Thus, by providing the protruding portion 52 on the backing plate 50, the bands 16, 1 in FIG.
It is possible to keep the backing plate 50 hooked on the double-glazed glass G before applying 6, so that the banding work can be performed easily.

FIGS. 8A and 8B are explanatory views for explaining a third embodiment of the backing plate according to the present invention. (A)
Is a double-glazed glass G at the corner 61 of the backing plate 60 (see FIG. 4).
A relief 62 is formed to prevent contact with the corners, and chamfers 65, 64 are formed on edges 63, 64 of backing plate 60, respectively.
66, 67 and 68 are formed, and the corner 71 of the backing plate 60 is formed in an arc shape.

In (b), the escape portion 62 is
Is formed, the corner 72 of the multi-layer glass G does not come into contact with the backing plate 60 when the backing plate 60 is attached to the multi-layer glass G, so that the backing plate 60 does not rattle. Further, by forming the chamfered portions 65 and 67 on the backing plate 60, it is possible to remove the burrs generated when the edges 63 and 64 of the backing plate 60 are processed, and to attach the backing plate 60 to the multi-layer glass G. At times, the contact plate 60 can be brought into close contact with the double-glazed glass G. Further, by forming the arc-shaped corner portion 71 on the backing plate 60, the slip between the band 16 and the corner portion 71 can be improved, so that the band 16 is less likely to be worn or scratched. Life can be extended.

FIG. 9 is a perspective view showing a fourth embodiment of the backing plate according to the present invention, in which the backing plate 80 is long and a plurality of banding grooves 82, 83, 84, 85 are formed in a corner 81. Is formed, and the backing plate 80 is attached to the corner of the double-glazed glass G and stands on the floor surface 24 of the glass carrier 10 (see FIG. 1).
This shows that the bands 16 and 16 are hung and bound by the band hanging grooves 82 and 85, respectively. Here, the band hook groove 8
2, 83, 84 and 85 are banding grooves 4 shown in FIG.
It has the same shape as 4.

By using such a caul plate 80, the number of caul plates 80 to be used can be reduced, and the caul plate 80 can be erected on the floor surface 24 before the bands 16, 16 are applied. Therefore, the work of fixing the double-glazed glass G can be performed easily. Also, a plurality of band hanging grooves 82,
83, 84, and 85, the band 1 is inserted into the banding grooves 82, 83, 84, and 85 in accordance with the height of the multilayer glass G.
6 can be hung, and the multi-layer glass G can be securely fixed to the glass carrier 10.

Note that the backing plate 17 shown in FIG. 4 is not limited to the L-section having the long and short flanges 41 and 42, but has, for example, an L-shaped recess, groove or notch. Attached to the corner of the double-glazed glass G, the band 16 can be hung,
What is necessary is just to be able to prevent the displacement between the plate glasses g1 and g2. Further, the long and short flanges 41 of the backing plate 17,
42 may have the same inner width W. In this case, either of the flanges may be applied to the edge of the multilayer glass G, so that the multilayer glass G can be easily fixed.

Further, (1) In the above-described embodiment, 2
A description has been given of a double-layer glass in which a spacer is interposed between two glass sheets and is filled with an adhesive for fixing the two glass sheets. However, the adhesive is filled between the glass sheets without using the spacer to fix the two glass sheets. The present invention is also applicable to the following types of double glazing. (2) In the above-described embodiment, an example in which the double-layer glass is fixed using a band has been described. However, the double-layer glass may be fixed using a band (for example, a film). (3) In the above-described embodiment, an example was described in which the outer surface of the adhesive was made to be substantially flush with the edges of the two glass sheets. The present invention is also applicable to a double glazing configured to be inside.

[0046]

According to the present invention, the following effects are exhibited by the above configuration. The transportation jig for the double glazing of claim 1 is L
When a cross section is presented and the total thickness of the multi-layer glass is T1 and the thickness of one sheet of glass is t1, the inner dimension W of one flange of the transportation jig is smaller than T1, and (T1-t1)
Since the flange is set to be larger, the flange always hits the edge of the two glass sheets, so that when an external force is applied to the flange, the external force can be uniformly applied to the two glass sheets from the flange.

According to the second aspect of the present invention, since the inner dimension W is set to (T1−0.5t1), even if the inner dimension W varies by processing, two flanges can be used. It can be applied to a sheet glass.

According to a third aspect of the present invention, there is provided a method for fixing a double-glazed glass, wherein the double-glazed glass in which the adhesive is incompletely solidified is leaned or mounted on a glass carrying frame, and is mounted on a corner of the double-glazed glass. By attaching the band or the band from above the carrying jig with the carrying jig described in the above, the adhesive is fixed to the glass carrying frame with incomplete solidification. The clamping force of the band or the band can be evenly applied to the two glass sheets of the double-layer glass via the jig, and even if the adhesive is in an incompletely solidified state, a shift occurs between the two glass sheets. Can be prevented.

[Brief description of the drawings]

FIG. 1 is a perspective view of a glass transport device using a transport jig (first embodiment) for a double glazing according to the present invention.

FIG. 2 is a view taken in the direction of arrow 2 in FIG. 1;

FIG. 3 is a perspective view of the first embodiment of the backing plate according to the present invention.

FIG. 4 is a sectional view taken along line 4-4 in FIG. 3;

FIG. 5 is an explanatory view illustrating a method for fixing a double-glazed glass according to the first embodiment of the backing plate according to the present invention.

FIG. 6 is an explanatory view for explaining the operation of the backing plate.

FIG. 7 is a perspective view showing a second embodiment of the backing plate according to the present invention.

FIG. 8 is an explanatory view illustrating a third embodiment of the backing plate according to the present invention.

FIG. 9 is a perspective view showing a fourth embodiment of the backing plate according to the present invention.

FIG. 10 is an explanatory view illustrating the structure of a double-glazed glass.

FIG. 11 is a perspective view illustrating a conventional fixing method of fixing a double-glazed glass to a glass carrier.

FIG. 12 is an explanatory view illustrating a method for fixing a double-glazed glass.

[Explanation of symbols]

10: glass carrier, 16: band, 17, 17a-1
7d, 50, 60, 80: jig for transporting double-glazed glass (applying plate); 42, 54: flange (short flange);
102: spacer, 104: adhesive, e1, e2: edge of sheet glass, G, Ga to Ge: double-layer glass, g1, g
2: Plate glass, T1: Total thickness of double-glazed glass, t1: Thickness of plate glass, W: Inner dimension of flange.

Continued on the front page (72) Inventor Masahiro Maetani 3-5-1, Doshumachi, Chuo-ku, Osaka-shi, Osaka Inside Nippon Sheet Glass Co., Ltd. (72) Inventor Shigeki Nagasaka 3-5-Doshucho, Chuo-ku, Osaka-shi, Osaka No. 11 F term in Nippon Sheet Glass Co., Ltd. (reference) 3E066 AA77 BA02 FA11 GA03 GA05 HA05 MA09 NA30 3E096 AA09 BA24 BB05 CA21 CA22 DA03 DA11 DA14 EA02Y EA07Y FA09 GA01 GA11 GA14 4G061 BA01 BA02 CD21 DA67

Claims (3)

[Claims] 1. A jig for transporting a double-glazed glass in which an adhesive for fixing the glass sheet is filled between two glass sheets, the transportation jig having an L section. It is a resin part, and the total thickness of the double glazing is T1, and the thickness of one sheet of glass is t1.
Wherein the inner dimension W of one flange of the transport jig is set to be smaller than T1 and larger than (T1-t1). 2. The inner diameter W is defined as (T1-0.5t)
2. The jig for transporting a double-glazed glass according to claim 1, wherein 1) is set. 3. The jig for transport according to claim 1, wherein the double-glazed glass in which the adhesive for fixing the spacer is incompletely solidified is leaned or placed on a glass carrier and the corner of the double-glazed glass. And fixing the adhesive to the glass carrier while the adhesive is incompletely solidified by hanging a band or a band from above the carrier jig.