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How Do steel products Work?

Author: Benjamin

Nov. 28, 2023

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Tags: Minerals & Metallurgy

Steel Fabricating

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Introduction

This article offers complete information about steel fabrication. Read further to learn more about:

  • What is steel fabricating?
  • Raw materials
  • Preliminary processes
  • Cutting, bending, and joining
  • And much more…

Chapter 1: What is Steel Fabricating?

Steel fabrication is the process of creating steel products through secondary metal manufacturing processes. Examples of these processes are cutting, bending, and joining. Additional processes such as finishing and heat treatment are made to impart additional characteristics to the metal product. Steel fabrication is an important trade that caters to almost all industrial sectors. Steel products are essential to construction, transportation, energy, mining, agriculture, and consumer goods manufacturing.

The steel fabricating process is completed by trained steel fabricators who complete the cutting, bending, and shaping process. They are licensed and highly trained professionals who are knowledgeable in regard to the characteristics and properties of steel.


Primary vs. Secondary Metal Manufacturing Processes

To understand steel fabricating better, it is important to determine the difference between primary and secondary metal manufacturing processes. Primary manufacturing processes create simple, semi-finished metal products such as plates, sheets, tubes, and bars. These metal products are created by casting, forging, rolling, extrusion, wire drawing, and sintering. All of these processes transform raw metal ingots or billets into metal products that will be used for secondary manufacturing processes. Primary manufacturing processes are done in foundries and steel mills.


Secondary manufacturing processes, or fabrication, is completed by steel fabricators who work on products from primary processing to create metal parts or structures. For these processes, a fabricator takes a semi-finished metal product and reshapes it. Their goal is to take the products and modify them to suit customer specifications and requirements. Examples of steel fabrication products are steel trusses, storage tanks, automotive chassis, and metal enclosures. Fabricators work in machine shops, “fab shops,” or on site, depending on the type of fabrication required and the needs of customers.


Chapter 2: Raw Materials for Steel Fabrication

Steel is a type of metal composed of an iron base metal alloyed by carbon. Other types of metals can also be used as fabrication workpiece items. Commonly used metals are aluminum, copper, and nickel alloys. Steel is the most widely used metal because of its availability and cheap price. Though aluminum is more abundant, the process of smelting iron is less energy-consuming and thus, less expensive.


One of the special steel alloys is stainless steel that has a variety of uses and can be fabricated in the same way as steel. Like steel, stainless steel has various grades each of which is ideal for use in different applications. Grades 300 and 400 are the most commonly used with grade 304 being the most popular and widely used. For high temperature exhaust applications, stainless steel grade 321 is ideal since part of its alloy is titanium, which ensures very little weld decay.

Stainless steel grade 316, with molybdenum, is used for water applications due to its resistance to corrosion. It is referred to as marine grade stainless and can be used in applications where chloride is present, which is something that grade 304 is unable to do. The resilience and strength of grade 316 makes ideal for use in building nuclear reprocessing plants.

A resurgence of the use of stainless steel has been found in the space exploration industry that used to prefer various composite metals but has found stainless steel to be more durable.

Castings:

These are metal products produced from melting and solidifying metal ingots. Castings are shaped according to the end product but have some dimensions that are usually out-of-tolerance. Secondary processes such as machining, finishing, and heat treatment are used to produce a final product.

Blooms:

Blooms are metal stocks with a nearly square cross-section that has a dimension equal to or greater than 6 x 6 inches. They are the product from the first breakdown of the metal ingot.

Slabs:

Slabs are produced from rolling metal ingots in a steel mill. They have a rectangular cross-section with thicknesses around 8 inches or greater.


Billets:

Billets are similar to blooms but have a square cross-section with dimensions of about 2 x 2 inches to 5 x 5 inches. They are blooms that have been further formed by either rolling, forging, or extrusion.

Plates, Sheets, and Strips:

These semi-finished products are produced by further rolling blooms and slabs. Plates have a thickness greater than a quarter of an inch. Sheets and strips are thinner than plates. Sheets differ from strips by their large width-to-thickness ratio.


Bars:

These are long, solid metal products with square, round, or rectangular cross-sections. They are produced by further rolling billets into smaller cross-sections. Typical cross-sections of bars are around 0.5 to 2 inches.

Rods:

Rods are similar to bars but with a smaller cross-section. Their cross-sections are typically 0.2 to 0.5 inches. Since they have smaller cross-sections, they are easily bent. Rods are typically supplied in rolls or coils.

Beams, Channels, Angles, and Rails:

These are metal products with irregular cross-sections formed from blooms by progressive rolling. Grooved rolls are mated together with a gap in between. The product takes form as it passes through the gap.


Tubes and Pipes:

Tubes and pipes are hollow metal products typically with a square, rectangular, or round form. They generally fall into two types: welded and seamless. Welded tubes and pipes are made by rolling a slab or plate into a coil. The edge of the coil is welded together by electric resistance welding. Seamless tubes and pipes are manufactured by rolling a round bar while piercing using a rotating cone. Forming the seamless tube is done at elevated temperatures near the transition temperature of the metal.


Wires:

These are metal products with cross-sections that are greatly reduced by forming. Wires are formed by a metalworking process called drawing. In this process, a metal piece, typically a rod, is pulled from a die. Drawing is a cold working process since it is done at room temperature.

Leading Manufacturers and Suppliers

    Chapter 3: Preliminary Processes of Steel Fabrication

    Before proceeding with the actual fabrication processes, it is important to know the preliminary steps. This involves conceptualizing and planning the design and features of the final product. The workpiece must be prepared before working to prevent any errors and material wastage.

    Design and Drafting:

    Design and drafting is the preliminary stage of a fabrication process which involves:

    • Determining the dimensions and physical features of the final product.
    • Calculating design properties and attributes such as structural strength, deflection, surface hardness, fatigue life, etc.
    • Estimating the type and quantity of raw material.
    • Planning the work methods, operations, and necessary precautions involved in producing the parts.
    • Creating construction and assembly drawings.

    Before, design and drafting were done using manual methods. The outputs are hand-drafted engineering drawings and manual calculations. Today, most designs are carried using computer software. Software such as AutoCAD, SolidWorks, and Tekla Structures are popular examples that perform both designing and drafting. Advanced calculations and modeling can be done which can streamline the process through quick design iterations.

    Workpiece Preparation:

    Sub-finished metal products are typically supplied with a protective coat to keep the surface free of corrosion. The level of protection is not always effective, and some rusting can still occur. Handling, transfer, and storage can also build debris on the surface that must be removed before performing work on the workpiece. Coatings, scales, oils, old paint, rust, dirt, or any other surface contaminant that can impede or affect the fabrication processes and quality of the product must be removed.

    Common workpiece preparations are pneumatic blasting, waterjet cleaning, mild pickling, scraping, and brushing.


    Marking:

    Marking is the process of laying off the measurements from the design and into the workpiece. This is sometimes included in the preparation process. Edges, fold lines, and hole centers are scribed on the surface of the workpiece. These scribes or marks must remain visible during the actual fabrication. Common marking tools are metal scribers, pencils, chalks, dividers, and punches. Aside from the measuring devices, marking is aided by tools such as rulers, center squares, and T-squares.


    Chapter 4: Cutting

    Cutting is one of the three main steps of metal fabrication. Cutting involves the removal or separation of unwanted material from the main workpiece or product. These unwanted materials are in the form of metal chips and scraps that are collected and recycled.

    Cutting can also involve a scrap-less operation wherein no material is lost for recycling. This method is commonly seen in cutting sheet metal. To conserve material, pieces of metal from both sides of the cut are used. A new part is produced with each cut.


    Cutting can be divided into several main categories. These are shear cutting, wedge-action cutting, abrasion, and non-traditional methods.

    Shear Cutting:

    Shear cutting, or shearing, is the process of cutting using two moving cutting tools. A cut is done by moving the two tools past each other with the metal in between. As the cutting tools press against the workpiece, the stress at the contact overcomes the material‘s shear resistance. A crack or tear starts to form which propagates through the material. This crack becomes the cutting line that separates the two pieces.

    Shearing is further divided into other cutting processes. These are enumerated below.

    Blanking:

    Blanking is a shearing process performed by a punch and die. Its cutting line is a closed-ended line forming a closed region. This line becomes the outside features of the workpiece. The workpiece is the inner portion of the metal stock while the outer is discarded as scrap. Blanking is typically done in a sheet or strip metal.


    Piercing:

    Piercing is the same as blanking where the cutting line completely bounds an area. However, in piercing, the cutting line forms the edges of the internal features of the workpiece. The scrap is the inner portion of the metal stock.

    Fine Blanking:

    This is a special type of blanking where the metal stock is completely clamped down during punching. The result is a clean cut with minimal burrs.

    Parting:

    This type involves shearing with a cutting line whose ends do not meet. Parting divides a metal stock into two.

    Lancing:

    This is a shearing process where the cutting line does not completely divide the metal stock. This allows one side or area to be bent or formed.


    Notching:

    Another open-ended cutting method used to create features (notches) along the edges of the metal stock.

    Trimming:

    Trimming is a shearing operation where excess material is removed from the edge of the stock to establish the final dimensions of the workpiece.

    Wedge-action Cutting or Traditional Machining:

    This is a type of cutting that involves removing material from stock using a tool with a sharp tip or edge. The cutting tool partially penetrates the material and moves towards the direction of the cutting line. Material is removed gradually until the final dimensions of the workpiece are obtained. The metal stock worked by these processes is solid blocks such as bars, rods, and slabs.

    Wedge-action cutting can be further divided into different types as summarized below.

    Turning:

    This is a cutting process where the stock is rotated while a cutting tool is made to move laterally past its outside surfaces. This generates the external features of the workpiece. The cutting tool slightly penetrates the stock as the stock rotates. A turning process is typically done in a lathe machine.


    Boring

    This process is the same as turning but the cutting tool moves along the inside surfaces of metal stock. It is typically done after drilling. Boring is used for creating large holes with greater dimensional accuracy.

    Drilling

    Drilling is a cutting process for creating holes in a solid material. Its cutting tool consists of multiple cutting edges rotated against the metal stock. Drilling is often done with other machining processes such as boring, trepanning, reaming, and countersinking.


    Trepanning:

    Trepanning involves cutting the face of round stock to produce a circular groove. Either the stock rotates, or the cutting tool revolves to create a cut. Trepanning is used for producing large circular holes and round disks.

    Reaming:

    This is the same as boring, but the cut is done at a lesser depth. It is used to improve the dimensional accuracy of the bored hole.

    Countersinking:

    This process is used to enlarge the openings of drilled holes to accommodate the heads of a fastener such as bolts and screws.

    Milling:

    This process removes material using a rotating cutting tool with multiple cutting tips. There are two major classifications of milling processes. These are face milling and peripheral milling. Face milling has the cutting tips oriented on one side of the cutter. Peripheral milling, on the other hand, has the cutting tips oriented radially outward along the circular edge of the cutter. Milling can produce a variety of cuts and can perform operations similar to other machining processes.


    Planing:

    Planing is a machining process that removes excess material by moving a cutting tool against a stationary stock in a reciprocating motion. This process is used for flattening or creating straight contours on the surface of a large workpiece.

    Sawing

    Sawing is a cutting process where a solid material is partially or completely cut using reciprocating or rotating tools such as power band saws, hack saws, and circular saws.

    Abrasion:

    This process uses materials with high hardness and rough surfaces for scratching, eroding, rubbing, or wearing the surface of a workpiece. In fabrication, abrasion is done in a controlled manner which gradually removes excess material from the workpiece. The types of abrasion processes are mentioned below.

    Grinding

    Grinding involves pressing an abrasive material against the surface of the workpiece with a force perpendicular to the contact plane. A relative motion parallel (or tangential for circular grinding tools) to the contact plane is made between the two surfaces.


    Honing:

    Honing is a low-speed abrading process. This is commonly done on cylindrical surfaces. It combines a simultaneous rotating and reciprocating motion creating a crosshatch lay pattern. The main purpose of honing is to create a part with high dimensional accuracy and a fine finish.

    Lapping:

    Lapping is the same as honing but generally uses lower speed and lower pressure abrasions. It also produces parts with excellent surface finish and precise dimensions. Lapping is usually done by mating a workpiece with a tool called a lap or with another workpiece. The rubbing surfaces are separated by a film of an abrasive mixture.

    Non-traditional Cutting Methods:

    These are non-conventional methods of cutting. They do not use mechanical action to remove material. Rather, they use electrical, electromagnetic, chemical, thermal, acoustic, or special mechanical phenomena to cut metal. These are usually preferred over traditional methods because of their precision and burr-free cuts. Examples of these methods are mentioned below.

    Waterjet Cutting:

    This method uses high-speed jets of water to cut through a material. A special type of waterjet cutting, known as abrasive jet cutting, uses water mixed with abrasive materials to cut harder materials such as metals. Waterjet cutting cuts the material by eroding the exposed surface of the material along the cutting line.

    Laser Cutting

    Laser cutting is a cutting method that uses an intensely focused, coherent stream of light called lasers to cut through the material.


    Electrochemical Machining (ECM):

    This process removes material by electrolytically dissolving the unwanted part. ECM is typically used for machining hard metals such as titanium, Inconel, and other high-strength alloys.

    Chapter 5: Bending

    Bending is a fabrication process where the metal is formed according to its final shape by supporting the stock on at least two points and applying pressure in between. The metal stock is deformed according to the profile of the press or punch and the configuration of the supports or dies. Bending is commonly used to form metal sheets, plates, strips, rods, and bars.

    The output of the bending process is angle bars, channels, V-shape and U-shaped bars, profiled sheets, and rounded plates.

    Bending processes can be further classified according to how the bending load is applied. These are summarized below.

    Air Bending:

    Air bending, also called free bending, is the most common type of bending process in metal fabrication. In this process, the workpiece is supported on two points by a die. Pressure is applied by a punch on the upper side of the workpiece. The opposite side or the bottom of the workpiece is free to bend and does not contact the die. This results in only three contact points. The position and movement of the punch depend on the desired cross-section of the part.


    Bottom Bending:

    In bottom bending, the workpiece is also supported at two-point similar to air bending. However, bottom bending involves fully pressing the workpiece until its bottom side contacts the die. The resulting radius of the bend depends on the radius of the punch tip and some amount of spring back. Bottom bending is typically used for producing V-shaped cross-sections.


    Coining:

    Coining involves fully pressing the workpiece against the die with enough force to cause the metal to flow. Thus, this process requires higher forces than air and bottom bending since it completely deforms the material in contact. The resulting cross-section depends on the profile of the punch and die. Coining is a highly accurate and repeatable bending process since it eliminates spring back.


    Roll Bending:

    Roll bending is done by passing the metal stock into a set of three rolls. A common configuration is composed of two stationary lower rolls and one moving upper roll. The movement of the upper roller bends the metal at a radius that depends on the radii and distances between the rolls.


    Chapter 6: Assembly and Joining

    This stage of the metal fabrication process involves combining and integrating all the cut and shaped parts to form a single, larger structure. The parts are first assembled piece by piece to get a general view of the structure to be made. Initial assembly is done using non-permanent joints such as temporary tack welds or bolted connections. This process is important to ensure that every part mates with the other parts properly.

    Once the metal parts are properly aligned and put in place, permanent joints are created. Examples of permanent joints are final or full welds and adhesive-bonded surfaces. In most metal fabrications, welding is the most commonly used joining method followed by bolting, screwing, and riveting. These joining processes are explained below.



    Welding:

    Welding is a fabrication process commonly used to join metals. It involves heating and melting the metal joints and filler metal. The molten metals are mixed to form a weld pool. This molten metal pool is then cooled and fused forming a solid joint. There are many different types of welding which are classified according to the method of producing heat to melt the metal, type of shielding used to protect the weld, thickness of the material to weld, and so on. Common examples of welding processes are shielded metal arc welding (SMAW), gas tungsten arc welding (GTAW/TIG), gas metal arc welding (GMAW/MIG), and electroslag welding (ESW).

    Soldering and Brazing:

    Soldering and brazing are two joining processes that involve melting a filler metal and depositing it into the joint. Unlike welding, these two processes do not melt the workpiece or the base metal. In principle, soldering and brazing are the same. However, brazing uses filler metals that melt at a higher temperature. Brazing typically uses brass as filler while soldering uses tin-lead alloys and silver alloys.

    Bolting and Screwing:

    Bolting and screwing create joints by using threaded machine elements. The result is a semi-permanent joint that can be dismantled without damaging the part. These joining processes require holes for inserting the fasteners while having access to one or both sides. Bolts and screws must be checked regularly since vibrations can cause these fasteners to loosen over time.


    Riveting:

    This is another semi-permanent joint that typically joins sheet metals. Like bolting and screwing, it does not cause permanent deformation or damage to the workpiece.

    Chapter 7: Steel Fabricator Processes

    Steel fabricators add features to steel products by refining and modifying external and inherent characteristics. The types for fabricator processes that are used depend on a product’s original design and intended application. Below are some common fabrication processes


    Heat Treatment:

    Heat treatment is a secondary process that modifies the microstructure of the metal parts. This process can make a material have higher ductility or increased strength and hardness. It can also relieve residual stresses caused by primary manufacturing processes and welding.

    Coating:

    Coating is a general term used to describe processes of applying a layer of material onto the surface of a part. These materials are typically curable polymers which can be in powder or liquid form. Typical types of coating processes are powder coating and painting. The coating imparts improved surface quality, durability, enhanced appearance, various textures, and chemical resistance.

    Galvanizing:

    This process involves coating the surface of a metal part with a layer of zinc to prevent steel from rusting. The most common application method is hot-dip galvanizing where the metal is submerged in a molten zinc bath.

    Anodizing:

    This process promotes the formation of a thicker oxide layer on the surface of a metal. It is done by passing a current through the material while submerged in an electrolyte bath. This is commonly done in aluminum parts.

    Deburring:

    Deburring enhances the final quality of the product by removing raised edges and unwanted pieces of material, known as burrs, left by the initial machining processes. Burrs are created from shearing, bending, cutting, piercing, and compressing metals.

    Chapter 8: Leading Steel Fabricating Machines

    There are various machines available for steel fabrication in the United States and Canada. These machines are essential in today's society as they enable efficient and precise fabrication of steel components used in industries such as construction, infrastructure, manufacturing, and transportation, contributing to economic growth and technological advancement. We examine many of these machines below.

    Peddinghaus HSFDB-C Plate Processing System

    Manufacturer: Peddinghaus Corporation

    The HSFDB-C is a highly advanced CNC plate processing system used for drilling, cutting, and thermal processing of steel plates. It offers high-speed drilling capabilities with multiple tool heads, reducing processing time and increasing productivity. This machine features a robust steel frame and precise linear guides to ensure accuracy and stability during cutting and drilling operations and is equipped with a user-friendly control interface and advanced software for efficient programming and nesting of parts.

    Messer MetalMaster Xcel

    Manufacturer: Messer Cutting Systems

    The MetalMaster Xcel is a versatile CNC plasma cutting system known for its exceptional accuracy and cut quality. It can handle various steel plate thicknesses and is suitable for a wide range of steel fabrication applications. This machine is equipped with automatic torch height control to maintain the optimal cutting distance from the workpiece. Additionally, Messer's Global Control Plus software allows for easy programming and efficient material utilization. The Messer MetalMasterXcel’s robust construction ensures durability and longevity even under demanding operating conditions.

    Trumpf TruLaser Series

    Manufacturer: Trumpf Inc.

    The TruLaser series includes a range of CNC laser cutting machines designed for precise and efficient steel cutting. These machines utilize fiber laser technology, offering high cutting speeds and lower energy consumption. Trumpf's TruTops software provides powerful programming and nesting capabilities for optimizing material usage and reducing waste. TruLaser machines can process various steel thicknesses, offer automatic nozzle changing and piercing detection features,.and are known for their reliability and ease of maintenance.

    Accurpress Press Brake

    Manufacturer: Accurpress America Inc.

    Accurpress manufactures a line of hydraulic press brakes that are widely used in steel fabrication shops. These press brakes offer a high level of precision and repeatability in bending steel plates and sheets. They come equipped with advanced CNC controls for easy programming and precise control of bending parameters. Accurpress press brakes are also designed with a heavy-duty frame and quality components to ensure long-term durability and stability. They offer various bending lengths and tonnage capacities to suit different fabrication needs.

    Haas VF Series CNC Vertical Machining Centers

    Manufacturer: Haas Automation, Inc.

    While not exclusively dedicated to steel fabrication, Haas VF Series CNC machining centers are widely used for precision milling and drilling of steel components in the metalworking industry. These vertical machining centers offer high spindle speeds and rapid traverse rates for efficient metal removal. Haas machines are known for their reliability and ease of operation, making them popular choices in various fabrication shops. Their CNC Vertical Machining Centers are equipped with Haas' intuitive CNC control and user-friendly software for easy programming and operation, and the rigid construction and precise ball screws contribute to the overall accuracy and stability of these machines.

    Remember, the popularity of each machine can vary depending on specific fabrication needs and the preferences of individual companies. Before making any purchasing decisions, it's essential to thoroughly research and consult with manufacturers or industry experts to find the most suitable machine for a particular application.

    Chapter 9: Steel vs Metal Fabrication

    When speaking of steel, it is very common to interchange it with the word metal since most people believe that metal and steel are the same. Though there are metals that have the same look and feel as steel and may have characteristics and properties that are similar, they are quite different. In many ways, steel is an entity unto itself with traits that exceed other metals.

    Metal and Steel Differences

    A metal is made of multiple substances that naturally occur in the Earth’s crust. Common metals are titanium, copper, and nickel. Unlike steel, metals do not have to be blended or mixed with alloys but can be dug up and used. Steel is an alloy made from naturally occurring iron ore, a metal that is necessary for the composition of steel and one of the most abundant metals in the Earth’s crust.

    The alloying of steel makes it a far stronger and resilient metal than naturally occurring metals. Natural metals, taken from the earth, are commonly used for jewelry, decorations, and surgical implants because they are so malleable. Processed steel requires far more tooling and working to shape it.

    The manufacture of steel requires the purification of iron ore by removing its impurities such as silica, phosphorus, and sulfur. Once the ore is purified, carbon is added to enhance steel’s durability, strength, and machinability.

    Fabrication of Metals

    Metal fabrication is a process that uses flat metal sheets that are formed and shaped. The sheets are about a quarter inch thick or less, which makes them pliable enough to be shaped and configured. Much like steel fabrication, the sheets of metal are subjected to cutting, stamping, folding, welding, and other processes to reach the necessary shape.

    To strengthen metals, other processes may be used to enhance the properties of the metal and make it more resilient. The types of things that may be added include plating, expanding, wiring, various types of hardware, fittings, and castings. How these factors are added is dependent on the final application for which the piece is created. In many cases, fabrication shops begin with several types of metals and form them into one piece. Fabricator shops begin with several types of metals and form them into one piece.

    Though metals are more pliable and adaptable than steel, similar fabrication methods are used. Unlike steel, which requires aggressive and forceful operations to form it, metals can be shaped with the same processes but in a less dynamic way.

    Metal Fabrication Terms

    • Cutting: Cutting is the most fundamental of the processes of metal fabrication and is accomplished in a variety of ways. It is necessary to shape the metal to the required shape and size.
    • Casting: In the casting process, the metal is melted and poured into a mold. The metal is cooled, and a metal part is removed.
    • Forging: Forging includes the use of high pressure machinery to compress, bend, and shape raw metal.
    • Punching: Punching machines punch patterns and shapes into metal.
    • Drawing: Drawing is a metalworking process that uses tensile forces to stretch metal. As the metal is pulled, it becomes thinner and conforms to the desired shape.
    • Milling: Milling includes a variety of fabricating functions such as shaping, cutting, and punching. The process of milling is capable of adding fine details and intrigue patterns to metals.
    • Drilling: Drilling is the process of placing perfectly positioned holes in metals.
    • Turning: Turning is the most basic machining process commonly completed on a lathe. During turning, a cutting tool removes portions of the outer diameter of a metal piece as it rotates. Turning is normally performed on metals that have gone through other processes, such as casting, forging, drawing, or extrusion.
    • Extrusion: In metal extrusion, a billet is forced through a die that has the shape of the desired cross section. The billet is pushed by mechanical force or a hydraulic press. Common extruded metals are aluminum, copper, steel, magnesium, and lead.

    Conclusion

    • Steel fabricating is the process of creating steel products through secondary metal manufacturing processes. Examples of these processes are cutting, bending, and joining.
    • Cutting involves the removal or separation of unwanted material from the main workpiece or product.
    • Bending is a fabrication process where the metal is formed according to its final shape by supporting the stock on at least two points and applying pressure between them.
    • Joining is the stage of the metal fabrication process that involves combining and integrating all the cut and shaped parts to form a single, larger structure.
    • The shaping, bending, and cutting for steel fabrication is completed by highly trained professionals referred to as fabricators.

    Leading Manufacturers and Suppliers

       

      Key points

      • Steel is ‘iron with most of the carbon removed’
      • Iron constitutes about five per cent of the Earth's crust and is the fourth most abundant element in the crust.
      • 98% of the iron ore mined is used to make steel
      • Steel represents around 95% of all metals produced
      • The biggest producer of steel by far is China (1607 million metric tonnes in 2013), followed by the EU (165), Japan (110), USA (87) and India (81)
      • Steel use per capita increased from 150kg in 2001 to 220kg in 2010 (Wsteel Assoc)
      • 51% of global steel is used for construction (Wsteel Assoc
      • 6.5% of CO2 emissions derive from iron and steel production (IEA 2010)

       

      1 Mineral Extraction

      Iron ore

      • Iron doesn’t occur naturally. Being highly reactive, it combines easily with other minerals to form ores. Those with the highest iron content are found near the surface of the earth and are relatively easy to mine.
      • The principal iron ores are hematite (Fe2O3) and magnetite (Fe3O4).
      • Most iron ore is extracted through opencast mines.
      • To be economically viable for mining, iron ore must contain at least 20% iron.
      • The three major sources of iron are China (23%), Australia (18%) and Brazil (18%). (2011 figures)

       

      Where to find it

       

      Iron ore mining in Western Australia

       

      Iron ore is converted into various types of iron through several processes. The most common process is the use of a blast furnace to produce pig iron which is about 92-94% iron and 3-5% carbon with smaller amounts of other elements. Pig iron has only limited uses, and most of this iron goes on to a steel mill where it is converted into various steel alloys by further reducing the carbon content and adding other elements such as manganese and nickel to give the steel specific properties.

       

      Limestone

      • Limestone is calcium carbonate (CaCO3). It is mainly composed of the skeletal remains of marine organisms.
      • Geologically, limestone occurs as a sedimentary layer over bedrock. As such it is relatively easy to extract through quarrying. 
      • Limestone is removed from the quarry, crushed and transported to steel mills.

       

      Coke

      Coke is produced from coal. The coal is heated, or ‘carbonised’ in an oven until it becomes coke. It is then removed from the oven and cooled before use in the blast furnace. The coal gas produced during carbonisation is collected and used as a fuel in the manufacturing process while by-products such as tar, benzole and sulphur are extracted for further refining.

       

      2 Manufacture of Iron 

      Pig Iron

      Coke, ore and sinter are fed, or ‘charged’, into the top of the blast furnace, together with limestone. A hot air blast, from which the furnace gets its name, is injected through nozzles, called ‘tuyeres’, in the base of the furnace. The blast fans the heat in the furnace to white-hot intensity, and the iron in the ore and sinter is melted out to form a pool of molten metal in the bottom, or hearth, of the furnace. The limestone combines with impurities and molten rock from the iron ore and sinter, forming a liquid ‘slag' which, being lighter than the metal, floats on top of it.

      • 2C (carbon(coke)) + 02 (oxygen) >>> 2CO (carbon monoxide)
      • Fe2O3 (iron ore) + 3 CO (carbon monoxide) >>> 2Fe(iron) + 3 CO2 (carbon dioxide)

       

      Cast Iron

      The molten iron from the bottom of the furnace can be used as cast iron.

      Cast iron is very runny when it is molten and doesn't shrink much when it solidifies. It is therefore ideal for making castings - hence its name. However, it is very impure, containing about 4% of carbon. This carbon makes it very hard, but also very brittle.

       

      3 Manufacture of Steel

      Methods for manufacturing steel have evolved significantly since industrial production began in the late 19th century. Modern methods, however, are still based around the Bessemer Process, namely, how to most efficiently use oxygen to lower the carbon content in iron.

      Today, steel making comes from both recycled as well as from raw materials. Two processes:

      • Basic Oxygen Steelmaking (BOS)/ Basic Oxygen Furnace (BOF) and
      • Electric Arc Furnace (EAF) account for virtually all steel production.

       

       

      Primary steel production

      Primary steelmaking methods differ between BOS and EAF methods. BOS methods add recycled scrap steel to the molten iron in a converter. At high temperatures, oxygen is blown through the metal, lowering silicon, manganese and phosphorous levels and lowering carbon content to between 0-1.5%. The addition of chemical cleaning agents called fluxes help to reduce the sulfur and phosphorous levels.

      EAF methods, alternatively, derive from 90 -100% recycled steel scrap and passed high power electric arcs (temperatures up to 1650 °C) to melt the metal and convert it to high quality steel. 

      Secondary steel production

      Secondary steelmaking involves treating the molten steel produced from both BOS and EAF routes to adjust the steel composition. This is done by adding or removing certain elements and/or manipulating the temperature and production environment.

      Continuous Casting

      The molten steel is cast into a cooled mould causing a thin steel shell to solidify. The shell strand is withdrawn using guided rolls and fully cooled and solidified. The strand is cut into desired lengths depending on application; slabs for flat products (plate and strip), blooms for sections (beams), billets for long products (wires) or thin strips.

      Primary Forming

      The steel that is cast is then formed into various shapes, often by hot rolling, a process that eliminates cast defects and achieves the required shape and surface quality. Hot rolled products are divided into flat products, long products, seamless tubes, and specialty products.

      Manufacturing, Fabrication and Finishing

      Finally, secondary forming techniques give the steel its final shape and properties. These techniques include:

      • shaping (e.g. cold rolling)

      • machining (e.g. drilling)

      • joining (e.g. welding)

      • coating (e.g. galvanising)

      • heat treatment (e.g. tempering)

      • surface treatment   (e.g. carburising)

       

      4 Types of Steel

      Carbon Steels

      Carbon steels contain trace amounts of alloying elements and account for 90% of total steel production. Carbon steels can be further categorised into three groups depending on their carbon content:

      • Low Carbon Steels/Mild Steels contain up to 0.3% carbon
      • Medium Carbon Steels contain 0.3 – 0.6% carbon
      • High Carbon Steels contain more than 0.6% carbon
         

      Alloy Steels

      Alloy steels contain alloying elements (e.g. manganese, silicon, nickel, titanium, copper, chromium and aluminium) in varying proportions in order to manipulate the steel's properties, such as its hardenability, corrosion resistance, strength and ductility along with its abilities to be formed and welded

      Stainless Steels

      stainless steel pipes

      Stainless steels generally contain between 10-20% chromium as the main alloying element and are valued for high corrosion resistance. Stainless steels can be divided into three groups based on their crystalline structure:

      • Austenitic: Austenitic steels generally contain 18% chromium, 8% nickel and less than 0.8% carbon. They form the largest portion of the global stainless steel market. Typical use of austenitic steel is in masonry support systems.

      • Ferritic: Ferritic steels are weaker and less ductile than austenitic steels. They contain trace amounts of nickel, 12-17% chromium, less than 0.1% carbon. They are prone to ‘pitting’ so if appearance is important, their use tends to be limited to internal applications such as shop fitting.

      • Martensitic: Martensitic steels are strong but brittle and harder to weld and shape. They contain 11-17% chromium, less than 0.4% nickel and up to 1.2% carbon. Though cheaper than austenitic steels, their low resistance to corrosion limits the range of suitable applications.

      • Duplex Steels: Are a mixture of austentic and ferritic  which makes them suitable for applications where corrosion resistance and strength are equally important . 

       

      5 Types of coating

      • Zinc coated steel (galvanised) 
      • Aluminium-zinc alloy coated steel
      • Organic coated: PVC plastisol
      • Organic coated: Polyvinylidene difluoride (PVDF aka PVF2)
      • Organic coated: Polyester
      • Organic coating: Enamel
         

      Galvanised steel sheet

      6 Energy

      • Total world crude steel production 2013: 1,606 Mt
      • Average energy in the production of primary steel: 18.68 GJ/t
      • Average CO2 intensity: 1.77 t CO2/t


      Of which:

      • Basic Oxygen Steelmaking (BOS): 70% of total production energy
      • Electric Arc Furnace (EAF): 30% of total production energy
         

      Electric Arc Furnace in operation

      Energy sources in producing primary steel:

      • 50% coking coal
      • 35% electricity
      • 5% natural gas
      • 5% other gasses

      (source World Steel Association)

       

      7 Recycling & Reuse

      Recycling

      • 42% of crude steel produced is recycled material
      • Re-melting proportion of steel scrap is constrained by availability. Availability can sometimes be defined as cost effective recovery.

      Iron and steel are the world's most recycled materials, and among the easiest materials to reprocess, as they can be separated magnetically from the waste stream. Recycling is via a steelworks: scrap is either re-melted in an electric arc furnace (90-100% scrap), or used as part of the charge in a Basic Oxygen Furnace (around 25% scrap). Any grade of steel can be recycled to top quality new metal, with no 'downgrading' from prime to lower quality materials as steel is recycled repeatedly.

      Recovery and reuse in construction

      Globally around 85% of construction steel is currently recovered from demolition (sourceWSA) (UK 96% source steelconstruction.info)

      Re-use of structural steel

      Steel reuse is any process where end-of-life steel is not re-melted but rather enters a new product use phase.

      Steel buildings and products are intrinsically demountable. Easily re-usable components include:

      • Piles (sheet and bearing piles)
      • Structural members including hollow sections
      • Light gauge products such as purlins and rails.

       

      Reclaimed steel

       Design for reuse

      To facilitate greater reuse it is important that designers not only use steel but also do what they can to optimise future reuse. Steps that the designer can take to maximise the opportunity for reusing structural steel include:

      • End plate beam to column and beam to beam connections
      • Use bolted connections in preference to welded joints to allow the structure to be dismantled during deconstruction
      • Use standard connection details including bolt sizes and the spacing of holes
      • Ensure easy and permanent access to connections
      • Where feasible, try to ensure that the steel is free from coatings or coverings that will prevent visual assessment of the condition of the steel.
      • Minimise the use of fixings to structural steel elements that require welding, drilling holes, or fixing with Hilti nails; use clamped fittings where possible
      • Identify the origin and properties of the component for example by bar-coding or e-tagging or stamping and keep an inventory of products
      • Use long-span beams as they are more likely to allow flexibility of use and to be reusable by cutting the beam to a new length. (source: SteelConstruction.info)

       

      8 The environmental impact of steel production

      Steel production has a number of impacts on the environment, including air emissions (CO, SOx, NOx, PM2), wastewater contaminants, hazardous wastes, and solid wastes. The major environmental impacts from integrated steel mills are from coking and iron-making.

      Climate change

      Virtually all of the greenhouse gas emissions associated with steel production are from the carbon dioxide emissions related to energy consumption.

      Emissions to air

      Coke production is one of the major pollution sources from steel production. Air emissions such as coke oven gas, naphthalene, ammonium compounds, crude light oil, sulfur and coke dust are released from coke ovens. 

      Emissions to water

      Water emissions come from the water used to cool coke after it has finished baking. Quenching water becomes contaminated with coke breezes and other compounds. While the volume of contaminated water can be great, quenching water is fairly easy to reuse. Most pollutants can be removed by filtration.

      Waste

      Slag, the limestone and iron ore impurities collected at the top of the molten iron, make up the largest portion of iron-making by-products. Sulfur dioxide and hydrogen sulfide are volatized and captured in air emissions control equipment and the residual slag is sold to the construction industry. While this is not a pollution prevention technique, the solid waste does not reach landfills.

      Gaseous emissions and metal dust are the most prominent sources of waste from electric arc furnaces.

       

      How Do steel products Work?

      Steel production & environmental impact

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