Every year, industries across various sectors of the national economy produce a vast array of goods that require transportation from the manufacturer to retail outlets serving end consumers. Most of these goods also require temporary storage in specially equipped hangars and other types of buildings. Loading, unloading, and transporting are labor-intensive, requiring manual labor and considerable resource expenditure, which ultimately impacts the cost of goods.
To ensure competitive pricing, it's advisable to properly prepare them at the factory for subsequent repeated tilting, lifting, and handling procedures, ensuring a substantial batch can be processed in a single cycle. To achieve this, manufacturers package their products in containers of varying sizes, most often rectangular parallelepipeds, as this allows for tightly packed storage spaces during storage, thereby maximizing the efficient use of available space. Much attention is also paid to the cost and durability of packaging, so the materials used are inexpensive and strong enough to successfully withstand multiple stages of loading, transportation, and unloading at the final destination. Currently, the most commonly used materials for container construction are:
- thick and dense cardboard that can withstand mechanical stress well, but still needs protection from moisture;
- polyethylene or polypropylene film, which, with the help of special packaging machines, allows for a very tight compression of a batch of goods, while providing reliable waterproofing;
- Fiberboard or three-layer thin plywood in combination with small cross-section wooden slats have also not lost their relevance, although they are used less frequently these days than in the last century.
In most cases, the resulting container made from the above materials is not strong enough for practical use, so they are reinforced by tightly wrapping them with various materials. These can be made from natural or synthetic fibers and can be constructed as narrow strips of fabric, but better results can be achieved with stainless steel tape, which is a typical type of ferrous rolled metal and is sold in compact coils rolled at a metallurgical plant.
Its main advantages when used for this purpose are high tensile strength, low weight due to its insignificant thickness, exceptional flexibility, and the absence of corrosion, which not only leads to the gradual destruction of the metal, but also to the appearance of a dark brown, unpleasant-looking, loose layer of rust on the surface of iron products galvanized tape However, in appearance it is significantly inferior to the always shiny stainless steel, so it is mainly used for packaging budget-priced goods, while luxury items, for marketing reasons, must look attractive even when packaged in containers.
Practical application of stainless steel tape and its analogues in other areas of economic activity
Of course, stainless steel tape's applications aren't limited to packaging. For example, it's widely used in the production of metal profiles used in modern metal-plastic doors and windows, fasteners and decorative parts, and body repair. There are also similar products made from other raw materials, which deserve a separate discussion.
Brass tape for electrical engineering
In electrical engineering, the most important characteristic of any material is its ability to conduct electric current, and they are divided into three large groups:
- conductors with low specific resistance;
- dielectrics that practically do not support the directional movement of electric charges;
- semiconductors occupying an intermediate position between the two listed above.
Copper and alloys created on its basis are among the best representatives of the first group, therefore they are in high demand in the electrical engineering industry brass tape It serves as a source material for the manufacture of many electrical components, foil coating of flat, thin sheets of insulators to produce etching of conductive tracks for printed circuit boards, and other purposes.