WO2019130603A1

WO2019130603A1 - Aluminum ingot package and aluminum ingot packaging method

Info

Publication number: WO2019130603A1
Application number: PCT/JP2018/004258
Authority: WO
Inventors: 康之樹神
Original assignee: 株式会社豊栄商会
Priority date: 2017-12-27
Filing date: 2018-02-07
Publication date: 2019-07-04
Also published as: JPWO2019130603A1

Abstract

In order to secure a space for inserting the forks of a forklift even with aluminum ingots that are short in length, this aluminum ingot package (10) is characterized in that: on a first level, three aluminum ingots (111, 112, 113) are placed face-down and in parallel with one another at an interval (I2) shorter than the length (I1) of the aluminum ingots (1); on a second level, aluminum ingots (121, 122) are placed so as to intersect in a substantially orthogonal manner with the three aluminum ingots (111, 112, 113) on the first level and span spaces (B1, B2) between two adjacent aluminum ingots among the three aluminum ingots (111, 112, 113); and a tying band (2a) is positioned and tightened along the longitudinal direction of a groove (1c) formed on the upper face (1a) of each of the aluminum ingots (111, 112, 113) on the first level and each of aluminum ingots (191, 192, 193) on a ninth level.

Description

Package of aluminum ingot and packing method of aluminum ingot

The present invention relates to a package of aluminum ingots, which is typically carried by a forklift and a method of packaging such aluminum ingots.

Patent Document 1 describes a specific embodiment of stacked aluminum ingots. In such an aluminum ingot, a gap is formed at the lowermost end by arranging two aluminum ingots at the lowermost end like a seta tooth. This gap just has the width and height to which the fork of the forklift can be inserted. Thus, stacked aluminum ingots can be transported by a forklift.

JP-A-6-156428 (FIG. 15)

The weight of the conventional aluminum ingot was typically 5 kg, but recently half of that 2.5 kg aluminum ingot is going to be used. Such a 2.5 kg aluminum ingot is about half as long as 5 kg. As a result, when aluminum ingots are stacked in the conventional manner, there arises a problem that a gap into which the fork of a forklift can be inserted can not be secured.

In view of the circumstances as described above, it is an object of the present invention to provide an aluminum ingot package and an aluminum ingot packing method capable of securing a gap into which a fork of a forklift can be inserted even if the length of the aluminum ingot is short.

In order to achieve the above object, a package of an aluminum ingot according to an aspect of the present invention is a package of an aluminum ingot formed by packaging a plurality of aluminum ingots having grooves provided longitudinally and transversely on the upper surface thereof. And three lowermost aluminum ingots disposed parallel to each other at a distance shorter than the length of the aluminum ingot and crossing the three lowermost aluminum ingots on the lowermost aluminum ingot and Of the three lowermost aluminum ingots, a bridging aluminum ingot arranged so as to bridge between each two adjacent lowermost aluminum ingots, an uppermost aluminum ingot placed upward in the uppermost step, and each of the aforementioned Grooves along the long side of the lowermost aluminum ingot and Serial through the groove of the uppermost aluminum ingots comprises a binding band for binding between each said uppermost aluminum ingots and bottom aluminum ingots.

In the present invention, the lowermost three aluminum ingots serve as legs for securing a gap into which the fork is inserted when transporting by a forklift. In particular, among the lowermost three aluminum ingots, the central aluminum ingot is disposed on the lowermost aluminum ingot and plays a role as a bridge pier of the aluminum ingot which bridges between the two adjacent lowermost aluminum ingots. Thereby, even if the length of the aluminum ingot is short, it is possible to secure a gap into which the fork of the forklift is inserted.

In addition, in the present invention, the wide bottom surface of the lowermost aluminum ingot and the wide bottom surface of the uppermost aluminum ingot are disposed to face each other, and the aluminum ingot in between is sandwiched between the binding bands. I'm tightening. By doing so, aluminum ingots disposed between the lowermost aluminum ingot and the uppermost aluminum ingot and arranged to intersect with these aluminum ingots are firmly fixed like a bridge girder, and this aluminum ingot It is possible to avoid such things as collapsing even if the package is scooped up with a forklift.

Further, according to the present invention, by providing grooves vertically and horizontally on the upper surface of the aluminum ingot, and passing the binding band through the grooves, it is possible to prevent the binding band from shifting. Also, even if the upper surface of the aluminum ingot is in contact with the aluminum ingot, the binding band can be passed between them, and the appropriate position is bound by the binding band to more effectively prevent the package of the aluminum ingot from being broken it can. Furthermore, at the bottom of the lowermost aluminum ingot, it is possible to prevent the binding band from being broken off.

In the package of aluminum ingots according to one aspect of the present invention, the uppermost aluminum ingot is disposed to face each of the lowermost aluminum ingots, and the binding band is a long side of each of the lowermost aluminum ingots. It is sufficient to pass through the grooves in the direction and the grooves in the long side direction of the uppermost aluminum ingots facing the lowermost aluminum ingots.

In the package of aluminum ingot according to one aspect of the present invention, the uppermost aluminum ingot is disposed to intersect with the lowermost aluminum ingot, and the binding band is provided along the long side of each lowermost aluminum ingot. It is sufficient to pass through the groove and the groove in the short side direction of the top aluminum ingot.

The package of the aluminum ingot according to one aspect of the present invention is for adjusting the height of the gap disposed between the lowermost aluminum ingot and the bridging aluminum ingot so as to overlap with the lowermost aluminum ingot. An aluminum ingot may further be provided. Accordingly, it is possible to cope with the case where the thickness of the fork of the forklift exceeds the thickness of the aluminum ingot. The height adjusting aluminum ingot may be upward or downward.

The package of aluminum ingot according to one aspect of the present invention is obtained by stacking the above package of aluminum ingots in at least two upper and lower tiers, and the package band of the package of upper aluminum ingot and the package of lower aluminum ingot The bundling band is placed on the bundling band so as to pass through the bundling band at the same position, and the bundling band is positioned, and the bundling body of the upper and lower aluminum ingots is bound with this bundling band.

The package of the aluminum ingot according to one aspect of the present invention has the package of the aluminum ingot described above arranged at least back and forth, and the same position of the binding band of the package of the front aluminum ingot and the package of the back aluminum ingot. The bundling bands are stacked on the bundling bands so as to pass through the bundling bands, and the bundling bands are positioned, and the bundling bands of the front and back aluminum ingots are bound with this bundling band.

Of course, the upper and lower and front and rear aluminum ingot packages may be similarly bound.

The packing method of aluminum ingot according to one aspect of the present invention is a packing method of aluminum ingot for packing a plurality of aluminum ingots provided with grooves in the vertical and horizontal directions on the upper surface, which comprises three aluminum ingots in the lowermost stage. Are disposed parallel to each other at a distance shorter than the length of the lower ingot, and intersect with these three aluminum ingots on the lowermost aluminum ingot, and adjacent two of these three aluminum ingots The aluminum ingots are disposed to bridge the ingots, and the aluminum ingots are disposed upward in the top row, passing through the grooves in the long side direction of the lowermost aluminum ingots and the grooves of the top aluminum ingot, Each said lowermost aluminum Wherein the ingot for binding by binding band between the top of the aluminum ingot.

Thereby, even if the length of the aluminum ingot is short, it is possible to secure a gap into which the fork of the forklift is inserted. In addition, it is possible to avoid collapsing even if the aluminum ingot package body is picked up by a forklift.

According to the present invention, even if the length of the aluminum ingot is short, a gap into which the fork of the forklift can be inserted can be secured. In addition, it is possible to prevent the aluminum ingot package from collapsing even if it is picked up by a forklift.

It is a front view of the aluminum ingot single-piece concerning one embodiment of the present invention. It is a top view of a single aluminum ingot concerning one embodiment of the present invention. It is a side view of a single aluminum ingot concerning one embodiment of the present invention. It is a front view of the package of the aluminum ingot which concerns on one Embodiment of this invention. It is a top view of the package of the aluminum ingot which concerns on one Embodiment of this invention. It is a side view of the package of the aluminum ingot concerning one embodiment of the present invention. It is a front view of the package of the aluminum ingot which concerns on other embodiment of this invention. It is a side view of the package of the aluminum ingot which concerns on other embodiment of this invention. It is a front view of the package of the aluminum ingot which concerns on further another embodiment of this invention. It is a side view of the package of the aluminum ingot which concerns on further another embodiment of this invention. It is a front view of the package of the aluminum ingot which concerns on another embodiment of this invention. It is a side view of the package of the aluminum ingot which concerns on another embodiment of this invention. It is a front view of the package of the aluminum ingot which concerns on still another embodiment of this invention. It is a top view of the package of the aluminum ingot which concerns on still another embodiment of this invention. It is a side view of the package of the aluminum ingot which concerns on still another embodiment of this invention. It is a front view of the package of the aluminum ingot which concerns on the modification of FIG. It is a top view of the package of the aluminum ingot which concerns on the modification of FIG. It is a side view of the package of the aluminum ingot which concerns on the modification of FIG. It is a front view of the aluminum ingot single-piece concerning the other embodiment of the present invention. It is a top view of the aluminum ingot single-piece concerning the other embodiment of the present invention. It is a side view of the aluminum ingot single-piece concerning the other embodiment of the present invention. It is a front view of the package which concerns on embodiment using the aluminum ingot shown in FIG. It is a top view of the package which concerns on embodiment using the aluminum ingot shown in FIG. It is a side view of the package which concerns on embodiment using the aluminum ingot shown in FIG.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1A to 1C are a front view, a plan view, and a side view of an aluminum ingot alone according to an embodiment of the present invention.

The aluminum ingot 1 is in the shape of a long rectangular pyramidal frustum, and its weight is typically 2.5 kg. The length of the aluminum ingot 1 is shorter than the spacing of a typical forklift fork.

Of the front and back of the aluminum ingot 1, the one with the smaller area is called the top surface 1a, and the one with the larger area is called the bottom surface 1b. Specifically, a cross groove 1c is provided on the upper surface 1a in the vertical and horizontal directions. The width of the groove 1c is larger than the width of the binding band to be described later, and the depth of the groove 1c should be deeper than the thickness of the binding band. A groove 1d communicating with the groove 1c of the cross is provided on the side surface on the short side of the side surface of the aluminum ingot.

FIGS. 2A to 2C are a front view, a plan view and a side view of a package of an aluminum ingot according to an embodiment of the present invention, respectively.

The package 10 of aluminum ingots is configured by stacking the above-mentioned aluminum ingots 1 in 9 upper and lower stages. Here, the lowermost stage is referred to as the first stage, and the uppermost stage is hereinafter referred to as the second stage to the ninth stage. The upward direction in the figure is called upward, and the downward direction is called downward. Moreover, in the aluminum ingot single substance in this embodiment, the code | symbol is made into the aluminum ingot 1, However, in the stacked state, in order to clarify the position of a specific aluminum ingot, a specific code | symbol is added to a specific aluminum ingot. Attached.

In the packaging body 10 of aluminum ingots, aluminum ingots 1 of length _l 3 present parallel downward at short intervals _{l 2} than ₁

Aluminum ingots

₁ _11, 1 _{12, 1 13} is disposed in the first stage. The distance l ₂ is more preferable equal right and left.

In the second stage, the first stage of the three aluminum ingot ₁ _11, 1 _{12, 1 13} and intersect substantially at a right angle, and adjacent ones of these three aluminum ingot ₁ _11, 1 _{12, 1 13} 2 aluminum ingots ₁ _{11, 1 12} of the present, the aluminum ingot ₁ _{21, 1 22} are arranged so that _one _{12, 1} between ₁₃

gap

_B 1, _{B 2} and bridging, respectively. In the second stage, such aluminum ingot 1 _21, 1 ₂₂ 3 rows back and forth, is arranged in contact, three rows before and after the column of the aluminum ingot 1 _21, 1 ₂₂ upward, the columns in aluminum The

ingots

1 ₂₁ and 1 ₂₂ are disposed downward.

In the ninth stage, the first stage of the aluminum ingot ₁ _11, 1 _{12, 1 13} and upwardly aluminum ingot ₁ 91 so as to face _each, 1 _{92, 1 93} are arranged. That is, each aluminum ingot ₁ 11 of the first _stage, 1 _{12, 1 13} and the ninth stage of the aluminum ingot ₁ _91, 1 _{92, 1 93,} respectively of the bottom surface 1b, i.e. a large surface area are facing each other . In the ninth stage, the aluminum ingot 1 is appropriately disposed in the gap between the three

aluminum ingots

₉₁ 1, 1 ₉₂ and 1 ₉₃ described above. For example, upward aluminum ingot 1 and down the aluminum ingot 1 is placed between the

aluminum ingot

1 ₉₁ and 1 _92. Similarly, the upward aluminum ingot 1 and the downward aluminum ingot 1 are disposed between the

aluminum ingots

1 ₉₂ and 1 ₉₃ .

In the fourth, sixth and eighth stages, the aluminum ingot 1 is disposed in the same manner as the second stage. In the third, fifth and seventh stages, the aluminum ingot 1 is arranged in the same manner as in the ninth stage.

Each aluminum ingot ₁ 11 of the first _stage, 1 _{12, 1 13} longitudinal direction and these aluminum ingots grooves 1c of the upper surface 1a of the ₁ _11, 1 _{12, 1 13} 9 stage of the aluminum ingot _{1 91} corresponding to, The three binding bands 2a are passed along the long side direction of the groove 1c of the top surface 1a of the 1 ₉₂ and 1 ₉₃ so as to wind the whole.

All aluminum ingot ₁ 91 in the long side direction and ninth stage of the two aluminum ingots ₁ _{21, 1 22} of the upper surface (downward) 1a groove 1c of the column in the second stage, 1,1,1 _92, It is located along the short side direction of the groove 1c of the top surface 1a of the 1, 1, 1 ₉₃ , and one banding band 2b is passed so as to wind the whole.

By tightening the binding band 2a, the first-stage aluminum ingots _{11 11} ₁₂ ₁₃ and the ninth-stage aluminum ingots ₉₁ 1 1 ₉₂ 1 ₁₉₃ are tightened. By tightening the binding band 2b, 2 pieces of aluminum ingots ₁ 21 column in the second _{stage, 1 22} and the ninth stage all of the

aluminum ingot

₁ _91, 1, 1, 1 92, 1, 1, 1 ₉₃ and tightened. As a result, all the stacked aluminum ingots 1 alone are strongly bound, and the package 10 of aluminum ingots is in a state of one lump.

Here, the three aluminum ingots 1 ₁₁ 1 1 ₁₂ 1 1 ₁₃ of the first stage become “legs” for securing _two gaps B _{1 1} B ₂ into which the forks are inserted when transporting with a forklift. In particular, the center of the aluminum ingot _{1 12} of the first stage of the three aluminum ingot ₁ _11, 1 _{12, 1 13,} the role corresponding to "piers" that bridging the second stage of the aluminum ingot ₁ _{21, 1 22,} respectively Do. Thereby, even if the length of the aluminum ingot 1 is short, two clearances B ₁ and B ₂ into which the forks of the forklift are inserted can be secured.

The bottom surface 1b of the first-stage aluminum ingots _{11 11} , _{12 12} and 113 ₁₃ wide and the bottom 1b of the ninth-

stage aluminum ingots

₉₁ 1, 1 ₉₂ and 1 ₉₃ wide are disposed facing each other. , The aluminum ingot 1 which exists between these is pinched and it clamps with the binding band 2a. By doing so, it is between the first

stage aluminum ingot

1 ₁₁ , 1 ₁₂ , 1 ₁₃ and the 9th

stage aluminum ingot

1 ₉₁ , 1 ₉₂ , 1 ₉₃ , and these

aluminum ingots

₁₁ 1, 1 1 The aluminum ingots 1 of even-numbered stages (the second stage, the fourth stage, the sixth stage) arranged to intersect with the ₁₂ 1, ₁₃ 1, 1 ₉₁ , 1 ₉₂ , 1 ₉₃ are firmly fixed like a “bridge girder” It is possible to prevent the aluminum ingot package 10 from collapsing even if it is raised by a forklift.

In the aluminum ingot 1 according to this embodiment, a cross groove 1c having a groove width larger than the width of the binding

bands

2a and 2b is provided on the upper surface 1a of each aluminum ingot 1. By passing 2a and 2b, the displacement of the binding

bands

2a and 2b can be prevented.

Further, even if the upper surface 1a of the aluminum ingot 1 is in contact with the aluminum ingot 1, the binding

bands

2a and 2b can be passed between them, and the appropriate positions are bound by the binding

bands

2a and 2b to pack the aluminum ingot The collapse of the body 10 can be prevented more effectively. In this embodiment, the two aluminum ingots ₁ 21 column in the second _{stage, 1 22} all of the aluminum ingot ₁ 91 of the ninth _stage, 1,1,1 92, with 1,1,1 ₉₃ By tightening the gap with the binding band 2b, the collapse of the package 10 of the aluminum ingot is prevented more effectively, but the binding band 2b may be passed through a different position, and further, it may be made in two or more places. It may be made to pass such a binding band 2b.

Furthermore, in the bottom portion of the first-

stage aluminum ingot

1 ₁₁ , 1 ₁₂ , 1 ₁₃ , it is possible to prevent the binding band 2 a from being scraped off.

The present invention is not limited to the above embodiments, and can be implemented in various forms within the scope of the technical idea of the present invention, and the scope of the implementation also falls within the technical scope of the present invention.

For example, in the above-described embodiment, the package of aluminum ingots stacked in nine stages is used, but the present invention can be applied whether stacked more or less. Further, the number of aluminum ingots arranged in each stage is not limited to the above embodiment.

In general, 100 to 200 of 5 kg aluminum ingots are circulated, and packaged at 500 kg to 1 t per package. Depending on the point of receiving and melting such an aluminum ingot, there is provided a facility for throwing the package of the aluminum ingot into the melting furnace as it is at 500 kg to 1 t.

In the present invention, in order to be able to cope with such equipment, it is possible to use 2.5 kg of aluminum ingot so that it can be handled in the same manner as the package of 5 kg of aluminum ingot described above. An example is shown in FIGS. 3A-B.

In the package 20 of aluminum ingots shown in FIGS. 3A to 3B, the package 10 of aluminum ingots shown in FIGS. 2A to 2C is arranged two by two in front and back to make two stages, and a total of four aluminum ingots. The package 10 is bundled with a binding band 2c.

In this package 20 of aluminum ingots, the binding bands 2c are respectively stacked on the left and right binding bands 2a of the binding bands 2a in FIGS. 2A to 2C, and these binding bands 2c are in the lower stage package of aluminum ingots. By aligning the package 10 of the aluminum ingot 10 with the package 10 of the upper stage in the same manner, alignment when stacking the package 10 of aluminum ingots in two stages can be performed.

Since the package 10 of the aluminum ingot shown in FIGS. 2A to C has strength as a lump, the package 20 of the aluminum ingot obtained by bundling the package 10 of aluminum ingots in four pieces by the method shown in FIGS. If there is, it can be transported by a forklift.

Further, the present invention is not limited to such an embodiment, for example, as shown in FIGS. 4A to 4B, an aluminum ingot obtained by bundling two aluminum ingot packages 10 shown in FIGS. A package 30 may be configured, or as shown in FIGS. 5A to 5B, a package of an aluminum ingot in which two packages 10 of aluminum ingots shown in FIGS. 40 may be configured.

In the package 30 of aluminum ingots, for example, the binding bands 2c overlap and pass over the left and right binding bands 2a among the binding bands 2a in FIGS. 2A to C, and these binding bands 2c are the packaging of the aluminum ingot in front. By aligning the body 10 and the back aluminum ingot package 10 in the same manner, the front and back aluminum ingot package 10 can be aligned.

Further, in the package body 40 of the aluminum ingot, for example, the bundling bands 2c overlap and pass over the left and right bundling bands 2a among the bundling bands 2a in FIG. The package 10 of the upper and lower aluminum ingots can be aligned with each other by making the package 10 and the package 10 of the upper aluminum ingots the same.

Furthermore, in the above embodiment, the first-stage (lowermost) aluminum ingots _{11 11} _{12 12} , and ₁₃ for providing “legs” for securing _two gaps B ₁ and B ₂ into which the fork of the forklift is inserted are Although each was comprised by one sheet, when the thickness of the fork of a forklift exceeds the thickness of an aluminum ingot, such a clearance gap can not be ensured. Therefore, as shown in FIGS. 6A ~ C, as packaging body 50, between the aluminum ingot ₁ _11, 1 _{12, 1 13} and a specific aluminum ingot 1 of the second stage of the first stage (the lowest stage), each the first stage aluminum ingot ₁ _11, 1 _{12, 1 13} and for height adjustment of the gap so as to face the aluminum ingot _{1 11} (bottom) _', _{1 12'} may be placed _{1 13 '.} Thereby, it is possible to cope with the case where the thickness of the fork of the forklift exceeds the thickness of the aluminum ingot 1. Incidentally, aluminum ingot _{1 11} for height adjustment of the gap _', _{1 12',} _{1 13 ',} as shown in FIG. 7A ~ C, aluminum ingot ₁ _{11, 1 12} of the first stage (the lowest stage), It may be disposed downward as in the case of 1 ₁₃ .

Further, in the above embodiment, a cross groove 1c is provided on the upper surface 1a of the aluminum ingot 1, and in the uppermost stage (ninth stage), the respective lowermost (first stage) aluminum ingots _{11 11} _{12 12} ₁₃ The

aluminum ingots

₉₁ 1, 1 ₉₂ and 1 ₉₃ are disposed upward facing each other, but may be configured as follows. That is, as shown in FIGS. 8A to 8C, one groove 1e is provided in the long side direction of the upper surface 1a of the aluminum ingot 1, and two grooves 2f are provided in the short side direction. As the package 60, as shown in FIGS. 9A to 9C, in the uppermost stage (the ninth stage), aluminum is upwardly directed so as to intersect with the lowermost (first stage) aluminum ingots _{11 11} _{12 12} , and _13.

Ingots

1 ₉₁ , 1 ₉₂ and 1 ₉₃ are disposed, and the binding band 2c is the lowermost aluminum ingot 1 ₁₁ 1 ₁₂ 1 ₁₃ and the groove 1e in the direction of the long side and the uppermost aluminum ingot 1 ₉₁ 1 ₉₂ and 1 ₉₃ It is configured to pass through the groove 2f in the short side direction of.

In addition, aluminum ingots other than the first, second, and uppermost stages of the specific aluminum ingots may be arranged in various manners.

Furthermore, the size and form of the aluminum ingot alone are not limited to the above embodiment.

1 Aluminum ingots ₁ _11, 1 _{12, 1 13} aluminum ingot ₁ _{21, 1 22} second stage specific aluminum ingot ₁ 91 of the first stage (the lowest _stage), 1 _{92, 1 93} 9-stage (uppermost stage) Specific aluminum ingot

1a Upper surface

1c, 1e,

1f Groove

2a, 2b,

2c Bundle band

10, 20, 30, 40, 50, 60 Package of

aluminum ingot

1 _{11 '} , 1 _12' , 1 _{13 '} gap height adjustment Aluminum ingot for

Claims

A package of aluminum ingots formed by packing a plurality of aluminum ingots in which grooves are provided vertically and horizontally on the upper surface,
Three lowermost aluminum ingots arranged in parallel downward at intervals lower than the length of the aluminum ingot at the lowermost one, and
These three lowermost aluminum ingots are arranged on the lowermost aluminum ingot so as to cross between the two adjacent lowermost aluminum ingots among the three lowermost aluminum ingots. Bridged aluminum ingot,
A top aluminum ingot placed upward on the top, and
An aluminum ingot comprising a binding band for passing between the lowermost aluminum ingot and the uppermost aluminum ingot through the groove in the long side direction of the lowermost aluminum ingot and the groove of the uppermost aluminum ingot Package.
It is a package of the aluminum ingot of Claim 1, Comprising:
The uppermost aluminum ingot is disposed to face each of the lowermost aluminum ingots,
The bundling body of the aluminum ingot passes through a groove in the long side direction of each lowermost aluminum ingot and a groove in the long side direction of each uppermost aluminum ingot opposite to the lowermost aluminum ingot.
It is a package of the aluminum ingot of Claim 1, Comprising:
The uppermost aluminum ingot is disposed to intersect with the lowermost aluminum ingot.
The packing band is a package of an aluminum ingot passing through a groove in the long side direction of each lowermost aluminum ingot and a groove in the short side direction of the uppermost aluminum ingot.
A package of the aluminum ingot according to any one of claims 1 to 3, further comprising:
A packaged body of an aluminum ingot comprising an aluminum ingot for adjusting the height of a gap disposed between each lowermost aluminum ingot and the bridging aluminum ingot so as to overlap with each lowermost aluminum ingot.
The package of the aluminum ingot according to any one of claims 1 to 4 is stacked in two or more upper and lower layers, and the binding band of the package of the upper aluminum ingot and the package of the lower aluminum ingot are the same. A package of aluminum ingots which is formed by bundling a bundle of upper and lower aluminum ingots by placing the bundling band on the bundling band so as to pass through the bundling band in the position and positioning the bundling band with this bundling band.
The package of the aluminum ingot according to any one of claims 1 to 4 is arranged at least back and forth, and the binding between the binding band of the package of the front aluminum ingot and the package of the back package of the aluminum ingot A package of aluminum ingots formed by placing the binding band on the binding band so as to pass through the band and positioning the binding band with this binding band.
A packing method of an aluminum ingot for packing a plurality of aluminum ingots provided with grooves vertically and horizontally on the upper surface,
At the bottom, three aluminum ingots are arranged in parallel downward at intervals smaller than the length of the aluminum ingot,
An aluminum ingot is disposed on the lowermost aluminum ingot so as to cross between these three aluminum ingots and to bridge between two adjacent aluminum ingots among these three aluminum ingots,
Place the aluminum ingot on top in the top row,
An aluminum ingot is bound by a binding band between the lowermost aluminum ingot and the uppermost aluminum ingot through the groove in the long side direction of each lowermost aluminum ingot and the groove of the uppermost aluminum ingot. Packing method.