RU219549U1 - PACKING LIST FOR PROTECTION OF METAL PRODUCTS AGAINST MECHANICAL DAMAGE - Google Patents

Abstract

The utility model relates to packaging, namely to a packing list for fastening and tightening metal products, as well as a shock-absorbing material and protection against mechanical damage to metal products during operation, transportation and storage, in the form of a packing list. The packing list for protection against mechanical damage of the packed products is made of a flexible polymeric material. The sheet is made monolithic with embossing on one side and a smooth surface on the other side. Moreover, the embossing is made continuous along the entire surface of the sheet and is formed by cells in the form of figures of regular polygons, where the bottom of each embossing cell is made with a rounded recess. The technical result of the utility model is the expansion of the arsenal of technical means, protection of metal products from mechanical damage during operation, transportation and storage, and use in the form of a packing list. Also, the technical result of the utility model is to increase the strength of the device. 8 w.p. f-ly, 12 ill.

Description

The utility model relates to packaging, namely to a packing list for fastening and tightening metal products, as well as a shock-absorbing material and protection against mechanical damage to metal products during operation, transportation and storage, in the form of a packing list.

Patent RU91980U is known from the prior art, published: 03/10/2010, which describes an anti-corrosion packaging product containing a base of breathable durable paper, a reinforcing mesh layer and a top layer of molecularly oriented polyethylene film, interconnected by hot-melt adhesive to form an elastic sheet made with cut edges.

Patent RU163798U is known from the prior art, published: 08/10/2016, which describes an anti-corrosion packaging material consisting of three inextricably interconnected layers, the first layer being made of inhibited crepe paper, the intermediate layer being made of an airtight polymer film, the third reinforcing layer, characterized in that the reinforcing layer is made of a non-woven fabric, while a melt of polymer granules is used as an airtight polymer film.

Patent RU125167U is known from the prior art, published on February 27, 2013, which describes a flexible packaging material containing upper and lower thermoplastic polymer films, reinforcing inserts fixed between them, which are made of solid materials and are located between the films at a distance from each other and parallel to each other, characterized in that the reinforcing inserts are fixed from each other at a distance that makes it possible to bend the material web by 180°, in addition, the upper thermoplastic polymer film is covered with a woven polymer web that is the outer surface of the packaging material, while their interacting surfaces are inextricably connected in addition, between the reinforcing inserts and the upper thermoplastic polymer film, kraft paper is placed and inextricably connected to them, while the lower thermoplastic polymer film is inextricably connected to the reinforcing inserts, and is covered on the outside with kraft paper, which is the inner side of the packaging material and is inextricably connected with bottom thermoplastic polymer film corresponding surface.

The technical problem of known analogues is the design complexity of their manufacture.

The closest analogue is the patent RU97713U, published: 09/20/2010., which describes the device of the packaging material, which is a multilayer structure consisting of at least two layers, the first of which is a polymer layer in the form of a sleeve, bag or web with volatile corrosion inhibitor, the second is a strength layer containing substances that increase its hardness and tensile and puncture strength, while in the presence of the third and subsequent layers they are various combinations of polymer and strength layers of the same or different types of origin, including intermediate layers of polymer between the polymer and strength layers with a total thickness of all intermediate layers of 10-80 microns.

The technical problem of the prototype is also the structural complexity of manufacturing the packaging material.

The objective of the utility model is to eliminate these technical problems.

The technical result of the utility model is the expansion of the arsenal of technical means, protection of metal products from mechanical damage during operation, transportation and storage, and use in the form of a packing list. Also, the technical result of the utility model is to increase the strength of the device.

This technical result is achieved due to the fact that a packing sheet is claimed for protection against mechanical damage to metal products, made of a flexible polymeric material, characterized in that the sheet is made monolithic with embossing on one side and a smooth surface on the other side, and the embossing is made continuous along the entire surface of the sheet and is formed by cells in the form of figures of regular polygons, and the bottom of each embossing cell can be made with a rounded recess.

Preferably, the sheet is rectangular and is rolled up or palletized in transport condition.

It is possible that the sheet is formed from a rectangular sheet by a ring-shaped cutout.

Preferably, the embossing cells are in the shape of a regular hexagon.

It is possible that the embossing cells are made in the form of an equilateral triangle, or a square, or a regular pentagon.

The sheet may be made of polymers selected from the group or mixtures thereof: polypropylene (PP), or high pressure polyethylene (LDPE) or low pressure polyethylene (HDPE). Also, the sheet can be made from the above-described recycled polymers.

The sheet can be made according to the thickness agreed with the customer up to 10 mm (H), and the embossing height does not change h=1 mm, which ensures the ratio 3.5⋅H : h = 1 mm.

Brief description of the drawings

Figure 1 shows the packing list device (side view and enlarged fragment).

Figure 2 shows an example of a packing list with hexagonal cells (top view and enlarged fragment).

Fig. 3 shows an example of a prototype cutting of a packing sheet with hexagonal cells (top view in volume).

Figure 4 shows an example of a prototype trimming a packing sheet (bottom view from a smooth side).

Fig. 5 shows an example of a prototype trimming of a hexagonal packing sheet (top view).

Figure 6 shows the flexibility of a prototype trimming of a hexagonal packing sheet (top view in volume).

Figure 7 - Figure 10 shows an example of roll packaging using a prototype packaging sheet with hexagonal cells of metal products (rolls of metal).

Figure 11 shows an example of a possible execution of a packing list with triangular cells (top view).

Figure 12 shows an example of a possible execution of a packing list with square cells (top view).

In the drawings: 1 - side of the sheet with embossing, 2 - side of the sheet without embossing (smooth), 3 - cells, 4 - recessed rounding of the bottom of the cells, h - embossing height, H - sheet thickness.

Implementation of the utility model

The packing list for protection against mechanical damage of the packed products is made of a flexible polymeric material.

What is new is that the sheet (see figure 1) is made monolithic with embossing on one side 1 and a smooth surface on the other side 2. The embossing itself is made continuous along the entire surface of the sheet and is formed by cells 3 in the form of figures of regular polygons.

At the same time, the strength properties sufficient to protect metal products from mechanical damage during operation, transportation and storage, and use in the form of a packing sheet, are ensured by the fact that the sheet itself is made of flexible polymer material with embossing, which stiffens the package. The latter is provided by stiffening ribs, which are formed by cells of regularly shaped polygons.

Due to the fact that embossing with cells is performed immediately during the production of the sheet, and the sheet itself is made monolithic in one layer, the design of the sheet and the process of its manufacture are simplified in comparison with analogues that use many layers in the production of packaging

Cells of regular polygons are important in terms of ensuring a uniform load on each unit of sheet area.

In addition, the figures of regular polygons from a triangle to a hexahedron, as you know, form closed systems, in contrast to irregular shapes. At the same time, regular hexagons distribute the load more evenly relative to the center of the cell, since they are close to the shape of a circle. Therefore, it is preferable that the embossing cells are made in the form of a regular hexagon (see Fig.2, 3, 5, 6). Empirically, it was found that the dimensions of the hexagonal cell are preferably such that the hexagon face of the cell is at least 2 mm ± 10%. Such dimensions are optimal in terms of packaging strength and material savings.

But it is possible that the embossing cells can also be made in the form of an equilateral triangle (see the example in Fig. 11), or a square (see the example in Fig. 12), or a regular pentagon.

In order to enhance the strength of the cell, the bottom of each embossing cell can be made with a rounded recess.

The thickness of the packing sheet H can be different depending on the packaging requirements and the amount of metal material to be packed. The thicker the packing list, the stronger it will be.

Empirically, it was found that it is optimal from the point of view of packaging strength and material savings when the proportions between the ratio H: h are made as 3.5⋅H : h = 1 mm, regardless of the thickness of the packaging sheet, so that strength is ensured due to stiffeners formed by embossing cells.

The packing list can be produced by stamping or extrusion.

Stamping of sheet plastics includes cutting, punching, punching, bending, drawing and molding operations.

In extrusion manufacturing, an extrudable material is obtained by extrusion of a polymer melt, then it is fed into a calibration device with cooling systems and calibrated to form the geometric dimensions of the product and crystallize the polymer, and then carry out further processing of the resulting product. The shaping surfaces are placed on the shaping inserts.

The sheet can be made of flexible polymeric materials: polypropylene (PP), or high-pressure polyethylene (LDPE), or low-pressure polyethylene (HDPE). Polymers PP, PVD, HDPE are distinguished by the following features that have become competitive advantages: acceptable wear resistance and resistance to "compression ↔ stretching", associated with high crystallinity of the material, increased heat resistance, low coefficient of friction, high moisture resistance, the ability not to interact with an aggressive environment, dielectric properties.

In the manufacture of a flexible packing list, PND grades: 20508-007, 20608-012, 20808-024, 20908-040, 21008-075, PP grades: 21003, 21007, 21012, 21015, 21020, 21030, 21060, 21100, 21130 21180, 21230, 22007, 22015, 22030 03-035, 18303-120. Also, the sheet can be made from the above-described recycled polymers.

It is possible to produce a sheet with additives that improve the physical and mechanical properties.

Information (including a logo) can be applied to a smooth surface. It is possible to laminate the sheet with film and other materials, incl. with flexographic printing.

The color of the sheet is not critical. When using lamination, the color of the front surface is determined by the color of the film used. The color of the back is not important.

On the smooth and embossed surface of the sheet there should be no sagging and welded joints.

When manufacturing a rectangular sheet, the preferred sheet dimensions are up to 2200 mm ± 10% in width and a given length as agreed with the customer.

In the manufacture of a rectangular sheet of great length in the transport state, it can be rolled up.

The utility model is used as a packing list as follows.

Metal products, such as sheets of metal, are stacked first on the bottom packing sheet. The stack is formed in such a height that it corresponds to the width of the packing list. After the stack is formed, the top packing sheet is laid, and one packing sheet is also applied on the sides. On the end edges, they are crimped with metal, polyester, polypropylene, etc. tape and the entire stack is fixed with ties.

When packing metal products in a roll, a roll of metal sheet pre-formed on a reel is wrapped with a packing sheet of the required length. And rings are cut out from a rectangular packing sheet, which are used at the ends of the bobbin, as shown in Fig.7-10.

After forming a roll of metal products and lining it with packing sheets, the bobbin and the edges of the roll are crimped along the end edges with metal, polyester, polypropylene, etc. tape and the entire roll is fixed with ties.

According to the utility model, prototypes were made (see examples in Figs. 3-6). The packing sheet had the required flexibility (FIG. 6) and strength. Using these prototypes were packed metal products in rolls (see examples in Fig.7-10).

Claims (9)

1. Packing sheet for protection against mechanical damage of packaged products, made of a flexible polymeric material, characterized in that the sheet is made monolithic with embossing on one side and a smooth surface on the other side, and the embossing is continuous along the entire surface of the sheet and is formed by cells in the form figures of regular polygons, where the bottom of each embossing cell is made with a rounded recess. 2. Packing list according to claim 1, characterized in that it is made rectangular. 3. Packing list according to claim 2, characterized in that the sheet in the transport state is rolled up or placed on a pallet. 4. Packing list according to claim 1, characterized in that it is made in the form of a ring. 5. Packing list according to claim 1, characterized in that the embossing cells are made in the form of a regular hexagon. 6. Packing list according to claim 1, characterized in that the embossing cells are made in the form of an equilateral triangle, or a square, or a regular pentagon. 7. The packing list according to claim 1, characterized in that it is made of polymers selected from the group or mixtures thereof: polypropylene (PP), or high-pressure polyethylene (LDPE), or low-pressure polyethylene (HDPE). 8. Packing list according to claim 7, characterized in that it is made of recycled polymers. 9. Packing sheet according to claim 1, characterized in that it is made in thickness (H) and embossing height (h=1 mm) in such a way that a ratio of 3.5⋅H : h = 1 mm is provided.