[ Wiki ]HOW IS STAINLESS STEEL MADE?

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Stainless steel is known for excellent corrosion resistance. It is an integral part of modern life and is used in a range of applications, including heavy industry, architecture, automotive manufacture, surgery and dentistry.

Until the 1950s and 1960s, which saw the development of AOD (argon oxygen decarburization) and VOD (vacuum oxygen decarburization), the processes to produce stainless steel were slow and expensive. However, these two developments revolutionized stainless steelmaking and significantly decreased the raw material costs, increased productivity, and improved quality. This led to dramatic growth of steelmaking from the 1970s until the present.

How Is Stainless Steel Made?

Raw materials

Stainless steel is an iron alloy with added elements such as chromium, nickel, silicon, manganese, nitrogen and carbon. The properties of the final alloy can be fine-tuned by altering the amounts of the various elements.

The importance of chromium in making stainless steel

Chromium is essential for the production of stainless steel; in fact there’s no viable alternative. Chromium is a hard, corrosion-resistant transition element that gives stainless steel its corrosion resistance. In general, the higher the chromium content, the more corrosion-resistant the steel.

The manufacturing process

Melting

The raw materials are melted together in an electric arc furnace. It can take 8 to 12 hours of intense heat until the metal becomes molten.

Removal of carbon content

The next stage is to remove excess carbon. This is done by processing the molten metal in an AOD (Argon Oxygen Decarburization) converter. The converter reduces the carbon by injecting an oxygen-argon mixture. At this stage, further alloying elements like nickel and molybdenum can be added to the AOD converter.

Alternatively a VOD (Vacuum Oxygen Decarburization) converter can be used to when a very low carbon content is required.

Tuning

Most stainless steels have exacting quality requirements. The tuning process allows fine adjustments to the chemical composition. Tuning is when the steel is slowly stirred to remove unwanted elements and improve consistency, while maintaining the required composition within the temperature limits.

Forming

Now the molten steel is cast into forms. These forms can be blooms (rectangular shapes), billets (round orsquare shapes), slabs, rods or tubes.

Hot rolling

Hot rolling occurs at a temperature above the recrystallization temperature of the steel. The precise temperature depends on the desired stainless steel grade. The steel forms are heated and passed through high rolls. Blooms and billets are formed into bar and wire. Slabs are formed into plate, strip, and sheet.

Cold rolling

Cold rolling is used where extremely precise dimensions or an attractive finish are required. The process occurs below the recrystallization temperature of the steel. Cold rolling is carried out using small-diameter rolls and a series of supporting rolls. This process allows the production of wide sheets with improved surface finishes.

Annealing

Annealing is the process used to soften stainless steel, improve ductility, and refine grain structure. It is also used to relieve internal stresses in the metal caused by previous processing. During the annealing process the steel is heated and cooled under controlled conditions.

Descaling

The annealing process causes scale to form on the steel. These scales are commonly removed using pickling, which involves bathing the steel in nitric-hydrofluoric acid. Electrocleaning is an alternative method which uses an electric current to remove the scale.

Cutting

The stainless steel can now be cut to the desired size. Mechanical cutting is the most common method. The stainless steel can be straight sheared with guillotine knives, circle sheared using circular knives, sawed using high-speed blades, or blanked with punches and dies. Other methods include flame cutting, which uses a flame-fired torch powered with oxygen, propane, and iron powder, or Plasma Jet cutting which uses an ionized gas column in conjunction with an electric arc to cut the metal.

Finishing

Surface finish is important for stainless steel products, especially in applications where appearances are important. While most people are familiar with the look of stainless steel used for consumer products, there are actually a number of finishing options.

Grinding wheels or abrasive belts are commonly used to grind or polish the steel. Other methods include buffing with cloth wheels with abrasive particles, dry etching using sandblasting, and wet etching using acid solutions. The smooth surface provides better corrosion resistance.

[ News ]New surface coating makes steel stronger, safer and more durable

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Holly Zhang

E-mail: sales4@sunraysteel.com

Mob: 86-13417960037 / Tel: 86-0757-63999952

Skype: hollyzhang97

Facebook: https://www.facebook.com/zhang.holly.5

Address: 1507, A6, Hao Science Park, Guicheng, Nanhai District, Foshan, Guangdong, China.

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New surface coating makes steel stronger, safer and more durable

Researchers at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) have developed a new surface coating that can make steel stronger, safer, and more durable. The coating, made from rough nanoporous tungsten oxide, is the most durable anti-fouling and anti-corrosive material to date, capable of repelling any kind of liquid even after sustaining intense structural abuse.

The team of Joanna Aizenberg, Professor of Materials Science at Amy Smith Berylson and core faculty member of the Wyss Institute for Biologically Inspired Engineering at Harvard University, first developed Slippery Liquid-Infused Porous Surfaces (SLIPS) in 2011 and has since demonstrated a broad range of applications for the super-slick coating. The new SLIPS-enhanced steel is described inNature Communications.

“Our slippery steel is orders of magnitude more durable than any anti-fouling material that has been developed before,” said Aizenberg. “So far, these two concepts – mechanical durability and anti-fouling – were at odds with each other. This research shows that careful surface engineering allows the design of a material capable of performing multiple, even conflicting, functions, without performance degradation.”

The biggest challenge in the development of this surface was to figure out how to structure steel to ensure its anti-fouling capability without mechanical degradation. The team solved this by using an electrochemical technique to grow an ultrathin film of hundreds of thousands of small and rough tungsten-oxide islands directly onto a steel surface.

“If one part of an island is destroyed, the damage doesn’t propagate to other parts of the surface because of the lack of interconnectivity between neighboring islands,” said Alexander B. Tesler, former postdoctoral fellow at SEAS, current research fellow at Weizmann Institute of Science in Israel and the paper’s first author. “This island-like morphology combined with the inherent durability and roughness of the tungsten oxide allows the surface to keep its repellent properties in highly abrasive applications, which was impossible until now.”

The material could have far-ranging applications, including non-fouling medical tools and devices, such as implants and scalpels, nozzles for 3-D printing and, potentially, larger-scale applications for buildings and marine vessels.

While a multitude of grades of steel have been developed over the past 50 years, steel surfaces have remained largely unchanged. “This research is an example of hard core, classic material science,” said Aizenberg. “We took a material that changed the world and asked, how can we make it better?”

This new academic research work shows how steel has the potential to become ever more resistant to corrosion protecting it and prolonging its lifespan in applications where it comes into direct contact with water.

a-h images show corrosion evolution as a function of contact time. Unmodified stainless steel (300 grade) (right sample) and TO-SLIPS sample with a 600-nm-thick porous TO film on steel (left sample) exposed to very corrosive Glyceregia stainless steel etchant.