GR20210100233A - Box of changing dimensions and volume with double side walls for the transport and storage of products - Google Patents

Abstract

There is disclosed a box of changing dimensions and volume with double side walls, meant for the transport and storage of products, without requiring the use of cutting tools to configure the different sizes. It is easy to assemble and more economical in its construction and transport throughout a remote supply chain, making it more environmentally friendly.

Description

DESCRIPTION

Variable dimensions and volume box with double side walls for transporting and storing products

The present invention relates to a reinforced and environmentally friendly box, and in particular to an improved box for transporting, selling and storing products of variable dimensions with double side walls without requiring the use of cutting tools for shaping the sizes, which is made from a sheet flexible material such as paper, corrugated cardboard, plastic sheet or other suitable material.

Products, after production, are packed into boxes for transport from the factory to the points of storage and sale through the supply chain. The modern way of disposing of products and especially the online sale of goods requires transport boxes to have the necessary strength to protect the products from unexpected falls and bumps during the journey of the product from the point of production to the sale and transport them in the consumer space.

Transport and storage boxes are known, they can consist of 1 or 2 pieces. They can be single-walled as shown in figure 7 or double-walled as shown in figure 9a and use various construction materials to achieve the desired strength. Transporting products via couriers and post offices requires the most durable boxes to ensure that the products are delivered to the consumer in excellent condition.

Double sided boxes are usually made from unformed corrugated cardboard or other flexible material which is formed after being cut to the desired shape and assembled by hand. There are many variations regarding its lid both in terms of its closure as shown in figure 9a, figure 9b and figure 9c as well as variations in the tongue it carries and which can have a perforated mechanism (zipper) for easy opening and adhesive tape for secure closure or bring a second adhesive tape to reseal the box for returning the product back to the supplier.

In general, product transport and storage boxes, apart from their usefulness, also have weaknesses. It is known that the products are of various dimensions, as a result of which boxes of different dimensions and in different quantities are required, each depending on the dimensions and marketability of the product. An important reason why a different box size is required is that the cost of transportation should be as low as possible, since it is known that the cost of transportation is dependent on the volume and weight of the box and in the case that the cost is high this factor can have a negative impact the sale. In the event that the product is placed in a larger box than ideal, this implies higher transport costs that make it financially unprofitable since fillers need to be placed inside the box at additional cost, in order to protect the product during its transport, while in addition it is also environmentally friendly harmful since, in addition to the use of unnecessary fillers, it takes up more volume. This has the effect of moving fewer boxes with the means of transport which has the consequence of corresponding to each box more environmental pollutants since fewer products are moved with the means of transport. On the other hand, the number of boxes of different dimensions create a big problem of both management and production costs. On the management side there should be a frequent check on the stock of boxes so that new boxes are reproduced in time. An additional problem is the maintenance of stock boxes for a long period of time, especially for non-tradable items if their minimum production quantities are also taken into account, with what this implies in terms of the financial side and also in terms of available storage spaces. In addition, each box of a different dimension requires high production costs both for the production of molds and for the design of the models and the production of each different size. An important role is also played by the friendliness of the box towards the environment, especially with climate change and the phenomenon of global warming.

A single wall variable dimension box is known in JP3120435U which has single walls which requires a cutting tool to adjust to the desired size and use packing tape to close it as shown in Figure 8. Such single walled boxes require a thicker paper for increased strength compared to double-walled boxes.

It is also known and described in FR2987824 which is a box of variable dimensions of two pieces, i.e. a box with a base and a lid. The disadvantage of the above invention is the high production cost, since it requires two sheets of paper, a double mold and double printing to produce it, while as mentioned in the description of the above invention, each different size should be 3 cm smaller than the previous one. This limitation exists because it has small sections of paper that must be removed by hand to create the final design of the box before it is folded, and it is the minimum distance required to grasp and cut these sections by a human hand. In addition, it has single sidewalls which means less strength if a lot of time is required to remove the waste paper sections. In addition to the high cost of production, it is less resistant to falls and the severity of the blows it can receive during its journey in the supply chain, while it is time-consuming to manufacture and also limiting in terms of the sizes it can take.

The advantages of the present invention are to provide a more environmentally friendly box, which can easily, quickly and accurately change its dimensions in order to take the ideal size required by the dimensions of the product without limiting the number of sizes that can be get, reinforced with double sidewalls, easy to assemble and use so that it reduces the cost of handling the product due to reduced volume and has a low environmental footprint. In addition, there is no need to stock boxes of less marketable product codes, resulting in lower production costs, less time and costs to manage the stock of boxes in warehouses. It has the advantage of obtaining its desired dimensions by a quick method of folding and tearing sections, without the use of cutting tools such as chisels, scissors or other similar tools, in such a way that the folding surfaces create a kind of cutting guide for the sections to be to tear with an excellent result and without limitation of the minimum distance of condensations for the scale of its sizes. In addition, it has the advantage of giving a box of variable dimensions with both parallelogram and trapezoidal double side walls.

In order to better understand the invention, it will describe an embodiment given by way of non-limiting example with reference to the attached drawings in which: • figure 1 shows the box open in three-dimensional form;

• figure 1a shows the tongue with a zipper mechanism and 2 adhesive strips of the box of figure 1,

• figure 1 b shows the tongue of the box of figure 1,

· figure 1 c shows the box of figure 1 closed,

• figure 2 shows the mechanical plan of the box of figure 1,

Figure 2a shows an alternative ear of the box of Figure 1;

• figure 2b shows the box of figure 1 without ears,

• figure 2c shows an alternative fin form of the box of figure 1 , • figure 3 shows the mechanical design with tabled side walls of the box, • figure 3a shows the box with tabled side walls in 3D form, • figure 4 shows the side view of the box with table side walls,

• figure 5 shows how to couple 2 boxes of figure 1,

• figure 6 shows the coupling of 3 boxes of figure 1,

· figure 7 shows an earlier single wall box,

Figure 8 shows a prior art single wall box of variable dimension using a cutting medium;

• figure 9a shows an earlier double-walled box,

• figure 9b shows an earlier double-walled box,

· figure 9c shows an earlier double-walled box,

• figure 10 shows the development of the box of figure 1,

• figure 11 shows the first step of the box folding method of figure 1 , • figure 12 shows the second step of the box folding method of figure 1 , • figure 13 shows the third step of the box folding method of figure 1 , · figure 14 shows the fourth step of the box folding method of figure 1 , • figure 15 shows the fifth step of the box folding method of figure 1 , • figure 16 shows the sixth step of the box folding method of figure 1 , • figure 17 shows the seventh step of the box folding method of figure 1 , • figure 18 shows the eighth step of the box folding method of figure 1 , • figure 19 shows the ninth step of the box folding method of Figure 1, Figure 20 shows the tenth step of the box folding method of Figure 1, Figure 21 shows the eleventh step of the box folding method of Figure 1,

figure 22 shows the box closed with the tongue touching the outside of the box of figure 1;

figure 23 shows the figure box closed with the tongue touching the inside of the figure 1 box;

figure 24 shows the fins abutting the rear wall of the box of figure 1 .

Figure 25 shows the optional flaps carried by the box tongue of Figure 1.

The invention relates to a box as shown in figure 1 made from an unformed sheet of flexible material such as paper, cardboard, corrugated paper, paper pulp, plastic or other flexible material or future suitable material.

The box shown in figure 1 is made by cutting and shaping the blank sheet in the pattern shown in figure 2.

The cut and now formed sheet has a base 1 which has a number of folds corresponding to the sizes that the box can take. The box of figure 1, as shown in figure 2 in its mechanical plan, has folds a, b, c that are parallel to the front wall. The padding α defines the maximum dimension of base 1 and the padding γ defines the smallest dimension of base 1 . Between the condensations a, c there may be a number of condensations. It has when folded over the base 1 , a front wall 3, a back wall 4, double side walls consisting of the outer side walls 2, the inner side walls 8 and in the case made of thick material, between the outer side walls 2 and internal side walls 8, the walls 10 are inserted. It has a cap 6 and a tongue 7.

From said base 1 extends the rear wall 4 which has fins 5 of any shape and size as shown in figures 2a and 2c which extend from the sides 22 of the rear wall 4 and may optionally be joined to the side walls 2 as shown in figure 2 and the joint side 23 which can be either thickened or perforated. In the event that said flaps 5 are joined to the side walls 2, they have diagonal braiding 18 or perforations for folding them inside the box.

From the rear wall 4 extends the lid 6 of the box which has a number of folds a, b, c equal to the sizes that the box can take and the number of folds that define the sizes of the boxes which are not limited by the number of concentrations of the example as it is indicative. Ears 16 as shown in figure 2, or 16a as shown in figure 2a can optionally extend from said lid 6 and they can be of any size and shape and which when the box is folded enter the holes 12. From said lid 6 extends the tongue 7 which can either enter inside the box to close it as shown in figure 23 or contact the outside of the front wall 3 as shown in figure 22 and can have an adhesive tape 24 for sealing the box or and zipper mechanism 17 for easier opening or a second adhesive tape 25 for resealing the box to return the product as shown in figure 1a and can have optional flaps (80) as shown in figure 25.

From the base 1 extend the outer side walls 2 which have perforation numbers 19a, 19b, 19c equal to the sizes that the box can take as shown in figure 2. From the base 1 extends the front wall 3 which has fins 9 which extend from its sides and both the front wall 3 and its wings 9 bear a number of thickenings b, c or perforations and which are joined to the outer side walls 2. Their joining point is the perforation 19a, 19b, 19c corresponding to each size of base 1 derived from the condensations a, b, c of said base. On the front wall 3 the side 26 defines the maximum dimension of the box.

From the outer side walls 2 extend the inner side walls 8 while in the case that the material is thick, for example corrugated paper, the outer side walls 2 and the inner side walls 8 are connected by means of the optional walls 10. In the case that the lid 6 has wings 16, the aforementioned walls 10 can have holes 12. Optional wings 21 are attached to the inner walls 8 which when the box folds are placed inside and touch the inside of the front wall 3 giving greater strength to the box.

The thickenings a, b, c located on the base 1, on the front wall 3 the sides 26 and the thickenings b, c, on the lid 6 the thickenings a, , b , c, on the inner side walls the thickenings a, b, c but also the perforations 19a, 19b, 19c correspond to the dimensions that the box can take. In the front wall 3 in the case that no additional wall extends as shown in figure 2, there is no thickening α but the side 26 defines the boundary of the front wall 26. The thickening α and the perforation 19a refer to the largest possible dimension that the box, while the thickening c and the perforation 19c refer to the smallest possible dimension that the box can carry. As many thickenings and perforations as are between the thickening a and thickening c and the perforations 19a and 19c are alternative sizes of the box, which sizes are not limited in number.

In the case that the side walls 2, 8 are parallelograms, the distances between the thickenings and the perforations, remain constant both in the base 1 and in the front wall 3 in the lid 6 and the side walls 2, 8.

In the case that the side walls 2, 8 are tables, the thicknesses of the base a, b, c that define the sizes of the box, and the thicknesses of the front wall 3 and the side walls 2, 8 are calculated trigonometrically as shown in figure 4.

The fins 5 of the back wall 4 of figure 2 in the case that the side walls 2, 8 are parallelograms and when the fins 5 are joined to the side walls 2 and are C-shaped as shown in figure 2 give a more environmentally friendly and more economical in the construction of the box and the joint side 23 is either thickened or perforated. In this case, the flaps 5 have diagonal braiding 18 or perforations for folding them inside the box. C-shaped flaps 5 allow coupling of at least 2 boxes as shown in figure 5 while maintaining the same paper width and shorter length since the boxes come closer to each other as shown in figure 6 which is not possible to achieve with traditional flaps of figure 2c with the result that the coupling of 2 boxes as shown in figure 2c is less environmentally friendly since, apart from requiring more paper for their production, it also requires more waste paper that must be thrown away, significantly increasing production costs. The C-shaped 5 fin box when pairing 2 or more boxes as shown in Figure 6 has lower production costs and is more environmentally friendly. The flaps 5 when the box is closed may abut internally between the inner side walls 8 and the outer side walls 2 as shown in figure 19 or abut against the rear wall 4 as shown in figure 24.

In the case of the box with tabular side walls as shown in figures 3 and 3a, the difference compared to the box of varying dimensions with parallelogram side walls is that the thickenings a, b, c and the perforations 19a, 19b, 19c have different distances from each other . Figure 4 shows the side view of the trapezoidal box and the distances between the base folds μ, μ1, μ2, the lid folds λ, λ1, λ2 and the front wall κ, κ1, κ2.

The Pythagorean theorem is used to calculate distances and angles are calculated using the law of sines.

The variable size box can easily be made to the desired dimensions with the simple method that follows. In the shaped sheet of figure 10 we fold to the desired thickness of the base 1 corresponding to the desired box size as shown in figure 11. Unfolding the flaps 21 as shown in figure 12 the flaps are torn and shaped to their correct dimension. Then, the formed sheet is completely unfolded as shown in figure 13. The flaps 21 are folded back and abut against the inner side walls 8 as shown in figure 14. The folded flaps 21 and the inner side walls 8 are folded and abut against the inner side walls 2 as shown in figure 15 creating a guide for cutting the flaps 9. Then, the flaps 9 after being folded inside, are torn and formed into their final shape as shown in figure 16. The formed box is unfolded having now taken the final dimensions as shown in the figure 17. Fold the front wall 3 to the appropriate thickness as shown in figure 18. Then fold the side outer walls 2 and flaps 9 as shown in figure 19 and then fold the flaps 21 and the front wall 3 to the thickness of the base 1 defined as shown in figure 20. The assembly of the box is completed with the hemming of the inner side walls 8 as shown in figure 21. The box of variable dimensions can be closed in 2 ways, either with the tongue 7 touching the outside of the front wall 3 as shown in figure 22 or touching the inside of the front wall 3 as shown in figure 23.

Claims (10)

1. A box of variable dimensions and volume with double side walls for the transportation and storage of products created from a surface of flexible material characterized in that it has a base (1) of variable dimensions, the number of which is defined by the number of ridges it carries between front (3) and rear wall (4), a front wall (3) extending from the base (1) and having at least one thickening and two fins (9) connected to the sides of said wall and which are connected to the two external side walls (2) which extend from the base (1) and carry at least one perforation and that the dimensions of the aforementioned lateral external walls (2) are formed by splitting the perforations corresponding to the desired base dimension by separating and shaping at the same time the fins (9) of the front wall and the external side walls (2) while the two flaps (9) contact when the box is folded on the inner surface of the side outer walls (2), two inner side walls (8) each having at least one thickening and extending from the above outer side walls (2), a rear wall ( 4) extending from the base (1) and having fins (5) of any shape extending from its sides, a cap (6) extending from the rear wall (4) and having at least one ridge in addition to the sides of and a tongue (7) of any shape and dimension, 2. Box of variable dimensions and volume with double side walls for the transport and storage of products created by a surface of flexible material according to claim 1 characterized in that the flaps (5) of the back wall (4) are C-shaped and carry at least a diagonal thickening (18) and are connected both to the lateral sides of the rear wall (4) and to the lateral outer walls (2); 3. A box of variable dimensions and volume with double side walls for transporting and storing products created by a surface of flexible material according to claim 1 or claim 2 characterized in that the base (1) has at least one hole (11) and the inner side walls (8) have at least one notch on their outer side 4. A box of variable dimensions and volume with double side walls for the transport and storage of products created from a surface of flexible material according to claim 1 or claim 2 or claim 3 characterized by having a wall (10) connected and positioned between the outer (2) and the inner side walls (8) and has at least one perforation, 5. A box of variable dimensions and volume with double side walls for the transport and storage of products created from a surface of flexible material according to claim 1 or claim 2 or claim 3 or claim 4 characterized by having at least one hole ( 12) the wall connected and placed between the outer (2) and the inner side walls (8); 6. A box of variable dimensions and volume with double side walls for the transport and storage of products formed from a surface of flexible material according to claim 1 or claim 2 or claim 3 or claim 4 or claim 5 characterized in that the lateral inner (8) and outer walls (2) are trapezoidal. 7. A box of variable dimensions and volume with double side walls for the transport and storage of products formed from a surface of flexible material according to claim 1 or claim 2 or claim 3 or claim 4 or claim 5 or claim 6 characterized by in that the tongue (7) has a zipper (17) and at least one adhesive tape (24) 8. A box of variable dimensions and volume with double side walls for the transport and storage of products formed from a surface of flexible material according to claim 1 or claim 2 or claim 3 or claim 4 or claim 5 or claim 6 or claim 7, characterized in that fins (80) of any size and shape extend to the free sides of the tongue (7) 9. A box of variable dimensions and volume with double side walls for the transport and storage of products formed from a surface of flexible material according to claim 1 or claim 2 or claim 3 or claim 4 or claim 5 or claim 6 claim 7 or claim 8 characterized in that ears (16) of any size and shape extend from the cap (6). 10. A method of rapidly assembling either manually or automatically a product transport and storage box of variable dimensions and volume with double side walls created from a surface of flexible material without the use of cutting means by first folding the gusset (a) or (b) or ( c) or any in addition to the front wall (3) in the desired dimension where the thickening (a) is the largest size and by bringing it into contact with the base (1) and then unfolding the inner side walls (d) the perforations are automatically torn ( 20) of the inner side walls (8) by forming the flaps (21) of the inner side walls (d) and then folding the aforementioned flaps (21) again and bringing them into contact with the outer side walls (2) which by folding them together so that they touch the inner side walls (2) a guide is created so that by folding the flaps (9) of the front wall (3) inwards until the corresponding perforations (19a) or (19b) or (19c) or any additional ones are torn at the same time and with this method both the outer side walls (2) and the wings (9) of the front wall (3) are shaped in correct dimensions of the box to then fold if required the corresponding thickening (b) W (H) W any additional of the front wall (3) and complete the assembly of the box to the desired size.