JPWO2019130603A1 - Aluminum ingot packing body and aluminum ingot packing method - Google Patents

Abstract

The aluminum ingot packing body (10) has a shorter interval than the aluminum ingot (1) length (11) in the first stage so that a gap for inserting the fork of the forklift can be secured even if the length of the aluminum ingot is short. In (12), three aluminum ingots (111, 112, 113) are arranged in parallel downward, and in the second stage, they intersect with the three aluminum ingots (111, 112, 113) in the first stage almost at right angles. However, the aluminum ingots (121, 122) are arranged so as to bridge the gaps (B1, B2) between the two adjacent aluminum ingots among these three aluminum ingots (111, 112, 113), respectively. , 1st stage aluminum ingots (111, 112, 113) and 9th stage aluminum ingots (191, 192, 193) located along the long side direction of the groove (1c) on the upper surface (1a). It is characterized in that the binding band (2a) is tightened.

Description

The present invention relates to a packing body of an aluminum ingot typically carried by a forklift and a method of packing such an aluminum ingot.

Patent Document 1 describes a specific embodiment of the stacked aluminum ingots. In such an aluminum ingot, a gap is created at the lowermost end by arranging two aluminum ingots at the lowermost end like clog teeth. This gap has a width and height that allows the fork of a forklift to be inserted. As a result, the stacked aluminum ingots can be transported by a forklift.

Japanese Unexamined Patent Publication No. 6-156428 (Fig. 15)

The weight of a conventional aluminum ingot is typically 5 kg, but recently, half of that weight, 2.5 kg, is being used. Such a 2.5 kg aluminum ingot is about half the length of a 5 kg aluminum ingot. Then, if the aluminum ingots are stacked in the same manner as before, there is a problem that a gap for inserting the fork of the forklift cannot be secured.

In view of the above circumstances, an object of the present invention is to provide a packing body of an aluminum ingot and a packing method of the aluminum ingot that can secure a gap for inserting a fork of a forklift even if the length of the aluminum ingot is short.

In order to achieve the above object, the aluminum ingot packing body according to one embodiment of the present invention is an aluminum ingot packing body formed by packing a plurality of aluminum ingots having grooves in the vertical and horizontal directions on the upper surface, and is the lowermost stage. Three bottom aluminum ingots arranged in parallel downward at intervals shorter than the length of the aluminum ingots, and on top of the bottom aluminum ingots, intersecting and these three bottom aluminum ingots. Of the three bottom aluminum ingots, a bridge aluminum ingot arranged so as to bridge between two adjacent bottom aluminum ingots, a top aluminum ingot arranged upward on the top, and each of the above. It is provided with a binding band that passes through the groove in the long side direction of the lowermost aluminum ingot and the groove of the uppermost aluminum ingot and binds between each of the lowermost aluminum ingot and the uppermost aluminum ingot.

In the present invention, the three aluminum ingots at the lowermost end serve as legs for securing a gap for inserting a fork when transporting by a forklift. In particular, the central aluminum ingot among the three aluminum ingots at the lowermost end is arranged on the lowermost aluminum ingot and acts as a pier of the aluminum ingot that bridges between the two adjacent lowermost aluminum ingots. As a result, even if the length of the aluminum ingot is short, a gap for inserting the fork of the forklift can be secured.

In addition, in the present invention, the wide bottom surface of each aluminum ingot at the bottom and the wide bottom surface of each aluminum ingot at the top are arranged so as to face each other, and the aluminum ingot between them is sandwiched by a binding band. Tightening. By doing so, the aluminum ingots located between the bottom aluminum ingot and the top aluminum ingot and arranged so as to intersect these aluminum ingots are firmly fixed like a bridge girder, and this aluminum ingot It is possible to prevent the aluminum package from collapsing even if it is scooped up with a forklift.

Further, in the present invention, grooves are provided in the vertical and horizontal directions on the upper surface of the aluminum ingot, and the binding band can be passed through the grooves to prevent the binding band from shifting. Further, even if the upper surface of the aluminum ingot is in contact with the aluminum ingot, a binding band can be passed between them, and the binding band is used to bind the aluminum ingot at an appropriate position to more effectively prevent the aluminum ingot from collapsing. it can. Further, at the bottom portion of the lowermost aluminum ingot, it is possible to prevent the binding band from being rubbed and broken.

In the package of the aluminum ingot according to one embodiment of the present invention, the uppermost aluminum ingot is arranged so as to face each of the lowermost aluminum ingots, and the binding band is a long side of each of the lowermost aluminum ingots. It may pass through the groove in the direction and the groove in the long side direction of each of the uppermost aluminum ingots facing the lowermost aluminum ingot.

In the packaging body of the aluminum ingot according to one embodiment of the present invention, the uppermost aluminum ingot is arranged so as to intersect the lowermost aluminum ingot, and the binding band is arranged in the long side direction of each of the lowermost aluminum ingots. It may pass through the groove and the groove in the short side direction of the uppermost aluminum ingot.

The package of the aluminum ingot according to one embodiment of the present invention is for adjusting the height of a gap arranged so as to overlap each of the bottom aluminum ingots between each of the bottom aluminum ingots and the bridged aluminum ingot. An aluminum ingot may be further provided. This makes it possible to handle cases where the thickness of the fork of the forklift exceeds the thickness of the aluminum ingot. The height adjusting aluminum ingot may be facing upward or downward.

In the aluminum ingot packing body according to one embodiment of the present invention, the above aluminum ingot packing bodies are stacked in at least two upper and lower stages, and the binding band of the upper aluminum ingot packing body and the lower aluminum ingot packing body are stacked. The binding band is positioned on top of these binding bands so as to pass through the binding bands at the same position, and the upper and lower aluminum ingot packages are bound by this binding band.

In the aluminum ingot packing body according to one embodiment of the present invention, the above aluminum ingot packing bodies are arranged at least front and back, and the binding band of the front aluminum ingot packing body and the rear aluminum ingot packing body are positioned at the same position. The binding band is positioned on top of these binding bands so as to pass through the binding bands of the above, and the packaging of the front and rear aluminum ingots is bound by the binding band.

Of course, the upper and lower and front and rear aluminum ingot packages may be bundled in the same manner.

The method for packing an aluminum ingot according to an embodiment of the present invention is a method for packing a plurality of aluminum ingots having grooves in the vertical and horizontal directions on the upper surface thereof, and three aluminum ingots are placed at the bottom of the aluminum ingot. Arranged downward in parallel at intervals shorter than the length of the aluminum ingot, intersecting these three aluminum ingots on the lowermost aluminum ingot, and adjacent two aluminums out of these three aluminum ingots. The aluminum ingots are arranged so as to bridge the ingots, and the aluminum ingots are arranged upward on the uppermost stage, and pass through the groove in the long side direction of each of the lowermost aluminum ingots and the groove of the uppermost aluminum ingot. The aluminum ingot at the bottom and the aluminum ingot at the top are bound by a binding band.

As a result, even if the length of the aluminum ingot is short, a gap for inserting the fork of the forklift can be secured. In addition, it is possible to prevent the aluminum ingot package from collapsing even when scooped up with a forklift.

According to the present invention, even if the length of the aluminum ingot is short, a gap for inserting the fork of the forklift can be secured. In addition, it is possible to prevent the aluminum ingot package from collapsing even if it is scooped up with a forklift.

It is a front view of the aluminum ingot alone which concerns on one Embodiment of this invention. It is a top view of the aluminum ingot alone which concerns on one Embodiment of this invention. It is a side view of the aluminum ingot alone which concerns on one Embodiment of this invention. It is a front view of the packing body of the aluminum ingot which concerns on one Embodiment of this invention. It is a top view of the package body of the aluminum ingot which concerns on one Embodiment of this invention. It is a side view of the package body of the aluminum ingot which concerns on one Embodiment of this invention. It is a front view of the packing body of the aluminum ingot which concerns on other embodiment of this invention. It is a side view of the package body of the aluminum ingot which concerns on other embodiment of this invention. It is a front view of the package body of the aluminum ingot which concerns on still another embodiment of this invention. It is a side view of the package body of the aluminum ingot which concerns on still another embodiment of this invention. It is a front view of the package body of the aluminum ingot which concerns on another embodiment of this invention. It is a side view of the package body of the aluminum ingot which concerns on another embodiment of this invention. It is a front view of the package body of the aluminum ingot which concerns on still another Embodiment of this invention. It is a top view of the package body of the aluminum ingot according to still another embodiment of this invention. It is a side view of the package body of the aluminum ingot which concerns on still another Embodiment of this invention. It is a front view of the packing body of the aluminum ingot which concerns on the modification of FIG. It is a top view of the packing body of the aluminum ingot which concerns on the modification of FIG. It is a side view of the packing body of the aluminum ingot which concerns on the modification of FIG. It is a front view of the aluminum ingot alone which concerns on other embodiment of this invention. It is a top view of the aluminum ingot alone which concerns on other embodiment of this invention. It is a side view of the aluminum ingot alone which concerns on other embodiment of this invention. It is a front view of the packing body which concerns on embodiment using the aluminum ingot shown in FIG. FIG. 5 is a plan view of a package according to an embodiment using the aluminum ingot shown in FIG. It is a side view of the packing body 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 a single aluminum ingot according to an embodiment of the present invention, respectively.

The aluminum ingot 1 is long and has the shape of a quadrangular pyramid, and its weight is typically 2.5 kg. The length of the aluminum ingot 1 is shorter than the fork spacing of a general forklift.

Of the front and back surfaces of the aluminum ingot 1, the one having a smaller area is called the upper surface 1a, and the one having a larger area is called the bottom surface 1b. The upper surface 1a is provided vertically and horizontally, specifically, a cross groove 1c. The width of the groove 1c should be larger than the width of the binding band 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 cross groove 1c is provided on the side surface of the aluminum ingot on the short side side.

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

The packing body 10 of the aluminum ingot is configured by stacking the above aluminum ingot 1 in nine upper and lower stages. Here, the lowest stage is referred to as the first stage, and hereinafter, the second to ninth stages are referred to in order up to the uppermost stage. In the figure, pointing upward is called upward, and pointing downward is called downward. Further, in the aluminum ingot alone in this embodiment, the code thereof is the aluminum ingot 1, but in the stacked state, a specific code is given to the specific aluminum ingot in order to clarify the position of the specific aluminum ingot. Attach.

In the aluminum ingot packing body 10, three aluminum ingots 1 ₁₁ , 1, ₁₂ , and ₁₃ are arranged in parallel downward at intervals l ₂ shorter than the length l ₁ of the aluminum ingot 1 in the first stage. It is preferable that the interval l ₂ is equal on the left and right.

In the second stage, the three aluminum ingots 1 ₁₁ , 1 ₁₂ and 1 ₁₃ in the first stage intersect at almost right angles, and two of these three aluminum ingots 1 ₁₁ , 1 ₁₂ and 1 ₁₃ are adjacent to each other. 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 ingot _{1 21, 1 22} are disposed downward.

In the ninth stage, the aluminum ingots 1 ₉₁ , ₁₉₂ , and ₁₉₃ are arranged upward so as to face the aluminum ingots 1 ₁₁ , 1, ₁₂ , and _{13 of} the first stage, respectively. 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, suitably aluminum ingot 1 is placed three aluminum ingots _{1 91,} 1 _{92, 1 93} clearance 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, upward aluminum ingot 1 and down the aluminum ingot 1 is placed between the aluminum ingot 1 ₉₂ and 1 _93.

In the fourth, sixth, and eighth stages, the aluminum ingot 1 is arranged in the same manner as in 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, 1 _{92, 1 93} along the longitudinal direction of the groove 1c of the upper surface 1a of the located respectively, through the three binding band 2a 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, located along the short side direction of the groove 1c of 1,1,1 ₉₃ of the upper surface 1a, through a single binding band 2b to wind the whole.

By tightening the binding band 2a, the first stage of the aluminum ingot _{1 11,} 1 _{12, 1 13} and the ninth stage of the aluminum ingot _{1 91,} 1 _{92, 1 93} is 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 is tightened. As a result, all the stacked aluminum ingots 1 alone are tightly bound, and the package 10 of the aluminum ingots becomes like one lump.

Here, the three aluminum ingots 1 ₁₁ , 1, ₁₂ , and ₁₃ of the first stage serve as "legs" for securing _two gaps B ₁ and B ₂ into which the fork is inserted when the fork is transported by the 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 To do. As a result, even if the length of the aluminum ingot 1 is short, it is possible to secure _two gaps B ₁ and B ₂ into which the fork of the forklift is inserted.

The first stage of the aluminum ingot _{1 11,} 1 _{12, 1} wide and becomes the bottom surface 1b of the ₁₃ and the ninth stage of the aluminum ingot _{1 91,} 1 _{92, 1} arranged in the form of facing a bottom surface 1b as a ₉₃ wide , The aluminum ingot 1 between them is sandwiched and fastened with the binding band 2a. By doing so, it is between the first stage of the aluminum ingot _{1 11,} 1 _{12, 1 13} and the aluminum ingot ₁ 91 of the ninth _stage, 1 _{92, 1 93,} and these aluminum ingots ₁ 11, 1 _{12, 1 13,} 1 _91, 1 _{92, 1 93} arranged to intersect with been even-numbered stages (second stage, the fourth stage, the sixth stage) aluminum ingot 1 is firmly fixed as "girders" , It is possible to avoid collapsing even if the packing body 10 of this aluminum ingot is scooped up with a forklift.

In the aluminum ingot 1 according to this embodiment, since the upper surface 1a of each aluminum ingot 1 is provided with a cross groove 1c having a groove width larger than the width of the binding bands 2a and 2b, the binding band 1c is provided with the binding band 1c. By passing 2a and 2b, it is possible to prevent the binding bands 2a and 2b from being displaced.

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 space with the binding band 2b, the collapse of the packing body 10 of the aluminum ingot is prevented more effectively, but the binding band 2b may be passed through different positions, and further, this may be performed in two or more places. Such a binding band 2b may be passed through.

Further, it is possible to prevent the binding band 2a from being rubbed and broken at the bottom portion of the first stage aluminum ingots 1 ₁₁ , 1, ₁₂ , and ₁₃ .

The present invention is not limited to the above-described embodiment, and can be implemented in various forms within the scope of the technical idea of the present invention, and the scope of the embodiment also belongs to the technical scope of the present invention.

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

Generally, 100 to 200 5 kg aluminum ingots are stacked and packed at 500 kg to 1 ton per package. Depending on where the aluminum ingot is received and melted, a facility is provided in which the packaged body of the aluminum ingot is directly put into the melting furnace with a weight of 500 kg to 1 ton.

In the present invention, a 2.5 kg aluminum ingot can be used so as to be able to handle such equipment in the same manner as the package of the above 5 kg aluminum ingot. An example thereof is shown in FIGS. 3A to 3B.

In the aluminum ingot packing body 20 shown in FIGS. 3A to 3B, two aluminum ingot packing bodies 10 shown in FIGS. 2A to 2C are arranged in the front-rear direction, and further placed on the aluminum ingot packing bodies 10 in two stages, for a total of four aluminum ingots. The packing body 10 of the above is bundled with a binding band 2c.

In the aluminum ingot packing body 20, the binding bands 2c pass over the left and right binding bands 2a of the binding bands 2a of FIGS. 2A to 2C, respectively, and these binding bands 2c are the lower binding bands of the aluminum ingot. By making the packing body 10 of the aluminum ingot in the upper stage 10 and the packing body 10 of the upper aluminum ingot the same, it is possible to align the packing body 10 of the aluminum ingot when stacking the two stages.

Since the aluminum ingot packing body 10 shown in FIGS. 2A to 2C is strong as a lump, the aluminum ingot packing body 20 in which the aluminum ingot packing body 10 is bundled into four by the method shown in FIGS. 3A to 3B is used. If there is, it can be transported by forklift.

Further, the present invention is not limited to such an embodiment, for example, as shown in FIGS. 4A to 4B, an aluminum ingot in which two packing bodies 10 of the aluminum ingots shown in FIGS. 2A to 2C are arranged in front and behind and bundled into two. The packing body 30 may be configured, or as shown in FIGS. 5A to 5B, two packing bodies 10 of the aluminum ingots shown in FIGS. 2A to 2C are stacked one above the other and bundled into two packing bodies of the aluminum ingot. 40 may be configured.

In the aluminum ingot packing body 30, for example, the binding bands 2c pass over the left and right binding bands 2a of the binding bands 2a of FIGS. 2A to 2C, respectively, and these binding bands 2c are used to pack the front aluminum ingot. By making the body 10 and the back aluminum ingot packing body 10 do the same, the front and rear aluminum ingot packing bodies 10 can be aligned.

Further, in the aluminum ingot packing body 40, for example, the binding bands 2c pass over the left and right binding bands 2a of the binding bands 2a shown in FIGS. 2A to 2C, and these binding bands 2c are the lower aluminum ingots. By making the packing body 10 of the above aluminum ingot and the packing body 10 of the upper aluminum ingot the same, the upper and lower packing bodies 10 of the aluminum ingot can be aligned.

Further, in the above embodiment, the first stage (bottom stage) aluminum ingots 1 ₁₁ , 1, ₁₂ , and ₁₃ for serving as "legs" for securing the _two gaps B ₁ and B ₂ into which the fork of the forklift is inserted are Each of them was composed of one piece, but when the thickness of the fork of the forklift exceeds the thickness of the aluminum ingot, such a gap cannot be secured. Therefore, as shown in FIGS. 6A to 6C, as the packing body 50, between the aluminum ingots 1 ₁₁ , 1, ₁₂ , and _{13 of} the first stage (bottom stage) and the specific aluminum ingot 1 of the second stage, respectively. 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 '.} As a result, even when 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, the aluminum ingot _{1 11, 1 12} of the first stage (the lowest stage), it may be arranged downward in the same way as 1 _13.

Further, in the above embodiment, the cross groove 1c is provided on the upper surface 1a of the aluminum ingot 1, and in the uppermost stage (9th stage), the aluminum ingots 1 _{11 11} , 1 ₁₂ 1 _{13 of the} lowermost stage (1st stage) are provided. The aluminum ingots 1 ₉₁ , ₁₉₂ , and ₁₉₃ were arranged upward so as to face each other, but they 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 shown in FIGS. 9A to 9C, the packing body 60 is made of aluminum upward so as to intersect with the aluminum ingots 1 ₁₁ , 1, ₁₂ , and _{13 of} the bottom (first stage) at the top (9th stage). Ingots 1 ₉₁ , ₁₉₂ , and ₁₉₃ are arranged, and the binding band 2c is the lowermost aluminum ingots 1 ₁₁ , 1 ₁₂ and 1 _{13 in} the long side direction groove 1e and the uppermost aluminum ingots 1 ₉₁ , 1 ₉₂ , 1 _93. It is configured to pass through the groove 2f in the short side direction of.

Further, aluminum ingots other than the specific aluminum ingots in the first stage, the second stage, and the uppermost stage may be arranged in various forms.

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

1 Aluminum ingot 1 _{11 11} , 1 ₁₂ 1 ₁₃ 1st stage (bottom) aluminum ingot 1 ₂₁ 1 ₂₂ 2nd stage specific aluminum ingot 1 ₉₁ 1, _{92 2} , 1 ₉₃ 9th stage (top) certain aluminum ingots 1a upper surface 1c, 1e, 1f grooves 2a, 2b, the packing body _{1 11} of 2c binding band 10, 20, 30, 40 of aluminum _{ingots', 1 12 ', 1 13'} gap height adjustment Aluminum ingot for

Claims (7)

It is a packing body of an aluminum ingot that is made by packing a plurality of aluminum ingots having grooves in the vertical and horizontal directions on the upper surface.
Three bottom aluminum ingots arranged in parallel downward at intervals shorter than the length of the aluminum ingot at the bottom,
Arranged on the lowermost aluminum ingot so as to intersect with these three lowermost aluminum ingots and to bridge between two adjacent lowermost aluminum ingots among these three lowermost aluminum ingots. With the bridged aluminum ingot,
The top aluminum ingot placed upward on the top and
An aluminum ingot comprising a binding band that passes through a groove in the long side direction of each of the lowermost aluminum ingots and a groove of the uppermost aluminum ingot and binds between each of the lowermost aluminum ingots and the uppermost aluminum ingot. Packing body. The package of the aluminum ingot according to claim 1.
The uppermost aluminum ingot is arranged so as to face each of the lowermost aluminum ingots.
The binding band is a packing body of an aluminum ingot that passes through a groove in the long side direction of each of the lowermost aluminum ingots and a groove in the long side direction of each of the uppermost aluminum ingots facing the lowermost aluminum ingot. The package of the aluminum ingot according to claim 1.
The top aluminum ingot is arranged so as to intersect the bottom aluminum ingot.
The binding band is a package of an aluminum ingot that passes through a groove in the long side direction of each of the lowermost aluminum ingots and a groove in the short side direction of the uppermost aluminum ingot. The package of the aluminum ingot according to any one of claims 1 to 3, further comprising.
A packing body of an aluminum ingot provided with an aluminum ingot for adjusting the height of a gap arranged so as to overlap each of the bottom aluminum ingots between each of the bottom aluminum ingots and the bridged aluminum ingot. The aluminum ingot packing body according to any one of claims 1 to 4 is stacked in at least two upper and lower stages, and the binding band of the upper aluminum ingot packing body and the lower aluminum ingot packing body are the same. An aluminum ingot packing body formed by superimposing a binding band on these binding bands so as to pass through the binding band at the position and binding the upper and lower aluminum ingot packing bodies with the binding band. The aluminum ingot packing body according to any one of claims 1 to 4 is arranged side by side at least in front and behind, and the binding band of the front aluminum ingot packing body and the rear aluminum ingot packing body are bound at the same position. An aluminum ingot packing body formed by superimposing a binding band on these binding bands so as to pass through the bands and binding the front and rear aluminum ingot packing bodies with this binding band. It is a packing method of an aluminum ingot that packs a plurality of aluminum ingots having grooves in the vertical and horizontal directions on the upper surface.
At the bottom, three aluminum ingots are placed in parallel downward at intervals shorter than the length of the aluminum ingots.
An aluminum ingot is placed on the lowermost aluminum ingot so as to intersect with these three aluminum ingots and to bridge between two adjacent aluminum ingots among these three aluminum ingots.
Place the aluminum ingot facing up on the top,
An aluminum ingot that passes through a groove in the long side direction of each of the lowermost aluminum ingots and a groove of the uppermost aluminum ingot, and binds between each of the lowermost aluminum ingots and the uppermost aluminum ingot with a binding band. Packing method.

Images