Nickel alloys offer excellent strength, corrosion resistance, and stability even at extreme temperatures. They are essential in the aerospace, energy, and chemical industries, where reliability in demanding conditions is required. Their ability to withstand high stress and aggressive environments makes them an ideal material for turbines, heat exchangers, and power system components.

These alloys are designed for applications requiring precisely controlled magnetic properties, thermal expansion, or electrical conductivity or resistance. Magnetically soft alloys based on iron, nickel, and cobalt (Fe-Ni, Fe-Co) are used in transformers, sensors, and shielding, where they provide low coercivity and high permeability. Alloys with a defined coefficient of thermal expansion (Fe-Ni, Fe-Ni-Co) ensure dimensional stability in aviation, precision mechanics, and electronic components. Copper-nickel alloys (Cu-Ni) are key for electrical resistors, cryogenic systems, and power electronics, where they offer stable performance and long life in demanding conditions.

Stainless steels are designed to withstand high humidity, seawater, acids, alkalis, chlorides, oxidizing chemicals, or high temperatures in combination with corrosive media. Thanks to alloying with chromium and other elements such as nickel, molybdenum, or nitrogen, these materials retain high chemical stability even during long-term exposure. Stainless steels combine mechanical strength, toughness, and thermal stability with excellent formability and weldability, making them a versatile material for the food, chemical, pharmaceutical, and energy industries.

Heat-resistant steels are designed for long-term operation at elevated temperatures, resisting oxidation, abrasion, and creep. They are alloyed with elements such as chromium, nickel, molybdenum, and silicon, which ensure mechanical strength and dimensional stability even under aggressive thermal stress. They are mainly used in furnace structures, petrochemicals, energy, heat exchangers, and exhaust systems.

Structural steels provide exceptional mechanical properties for construction, energy, transport, and heavy machinery. They are designed to withstand high loads and exhibit high toughness even at low temperatures.

Tool steels are essential in the manufacture of cutting tools, molds, and dies, where extreme resistance to stress is required.

Modern high-strength steels contribute to vehicle safety, weight reduction, and energy efficiency. Thanks to their high strength and ability to absorb impact energy, they meet the latest standards in lightweight construction and safety. Whether used in chassis components or body reinforcements, these steels are essential for a sustainable future in the automotive industry.

Pressure vessels require materials that can withstand extreme pressures and temperatures. These materials excel in toughness, weldability, and resistance to brittle fracture. They are the ideal choice for the manufacture of boilers, reactors, gas storage tanks, and other product and energy pipelines.

We also participate in research and development of high-strength and ballistically resistant materials for defense and security applications. From armor plates for military vehicles to aircraft components. These alloys and steels are developed for maximum durability, reliability, and protection in critical conditions.

Our production facilities are also equipped for the research and development of experimental materials, particularly for the energy industry, electrical engineering industry, and healthcare. Nowadays, there is a strong emphasis on recycling metallic materials. That is why we are intensively focused on the possibilities of utilizing waste from ferrous and non-ferrous metals and their alloys.

For applications where conventional materials are not sufficient, we offer specially developed, tailor-made steels and alloys. These include high-entropy alloys, refractory metals, and ultra-high-strength steels designed for the most advanced technological challenges.