Steel bars applications and their usages

In the manufacturing industry, steel bars constitute as an imperative component. In fact, for any industry that depends upon machineries, steel bars act as a core element. Steel bars cannot be replaced in the industry because whether they are concrete, wood or synthetic fibers- their anti-corrosion properties, durability, strength and reliability factor of stain steel bright bars remain unbeatable.

Steel bars with their multifaceted uses tend to be at the center of most engineering industries- be it textile, construction, defense and many more. Due to their feature of having the ability to be produced in varied types, shapes, sizes and grades of bars which can be catered to the required technical requirements.

In terms of applications of steel bars, their shape tends to define their application area. Their shapes are varied- flat, round, hexagonal or square. Flat bars are generally used as base plates and brackets for construction industries. For the production of fasteners and machineries, round bars are employed due to their corrosion resistance. The channel and hexagonal bars are weight bearing bars applied in the use of fabrication of I beams, H beams, C beams or any other major structural material. Square bars are applied in machines, fasteners and equipment.

Apart from the applications of steel bars on the basis of their shapes, it’s also important to discuss the same in terms of their functional requirements. The foundation of electromagnetic instrument industries are solenoid bars which possess good wear resistance and better resistivity. Some of the uses of these bars are that they are used as control valves, printers, electronic fuel injectors and many more. For the most part, the usage of the bars tends to define the manufacturing techniques and the techniques for heat treatment. Therefore, with regard to the particular manufacturing techniques, how these bars perform always end up superseding the technical requirements and the expectations. Most importantly, to determine the role of the steel bars in the manufacturing industry- the approval from the quality control department is very important.

Out of all kinds of bars, the round steel bar has one of the most important applications. There are a few properties that are attached to the round metal bar which makes it unique. For starters, they possess the strength to endure any kind of physical and most kinds of chemical conditions. They also are prone to handling extreme weather conditions and are mostly resistant to those. Last but not the least, they are mostly cost effective and are durable as well. These round stainless steel bars can be cut and engineered into tools easily. This is essentially the reason as to why the round bars are used to create machine parts and automotive components.

A rebar or reinforcing bar is used to reinforce concrete and masonry structures. It is also known as common steel. There are two broad types of steel bars in the market- mild steel bars and deformed steel bars. The mild steel bars are used for tensile stress of RCC (Reinforced cement concrete) slab beams in reinforced cement concrete work. These roads are long and can be cut quickly and bent easily without manage. Deformed bars on the other hand are rods of steels, deformed on the surface of the bar which minimizes slippage in concrete and increases the bond between the two materials.

Steel has always been one of the primary choices for the energy industry and with the present conditions of deteriorating climatic conditions and impending environmental concerns- this will be more essential than ever. The steel flat bars that have always served to provide infrastructure for anything and everything from refineries to pressure valves are now providing foundation within tower structures and concrete-reinforcing bars foundations with turbines and water gate their generators.

Thus, this piece highlighted the various types of steel bars along with their applications and usages.

Discuss the most common uses for Spring Steel

spring-steel

Spring steel is popularly referred to as an annealed spring steel and “general use” steel. Spring steel is generally classified in different categories such as a low alloy, medium carbon steel or high carbon steel with a very high yield strength. Spring steel has certain properties such as it is resistant to water, environmental and pollution exposure. Stainless spring steel can essentially come under two types which is either austenitic or martensitic. The austenitic stainless spring steel strips like 301 and 302 are temper rolled for light springs versus the martensitic spring steels, such as the 420 stainless strips, that are heat treatable for high hardness and toughness and are typically used for hardened tools.

Spring steel has many applications and uses attached to it. It also has many unique properties attached to it. For example, spring steel is said to have high yielding strength and also known to be resilient. Moreover, it also has the capacity to be formed, shaped and post heat treated. It is in fact these physical characteristics that make spring steel a general use steel. Since spring steel is essentially general use steel, it has a varied amount of commercial applications. Therefore, with its common material and its properties, spring steel is used to manufacture objects such as washers, lick picks, scrapers, saw blades, springs and antennas.

One of the common uses for spring steel is that it is used to create lawn mower parts, vehicle coil springs and tubular spring is used for the landing gear of small aircrafts as it has the ability to absorb the impact of landing. Another common usage of spring steel is that they are used as piano wires, such as ASTM A228. One popular use of spring steel is that it is used for the manufacturing of metal sword which are used for stage combat due to its resistance to bending, snapping or shattering. It is also used in the fabrication of lockpicks due to its flexibility and resilience. Spring steel is also utilized in making knives, especially for the Nepalese kukri and also used to binder clips. It is also extensively used in the making of shims as it possesses the resistance to deformation in low thicknesses.

Therefore, this piece highlighted the various properties attached to spring steel and also discussed many of its applications and usages.

BIBLIOGRAPHY

https://www.meadmetals.com/blog/common-uses-for-spring-steel

https://www.engineersedge.com/materials/spring-steel.htm

https://www.acxesspring.com/properties-of-common-spring-materials-spring-wires.html

https://www.precisionsteel.com/spring-steel

https://marketing.hardwareproducts.com/blog/classes-of-spring-steel-used-in-spring-manufacturing

http://www.nevatiasteel.com/know-significant-uses-spring-wire-various-application/

The 5 Steps of Steel Manufacturing and Production

The 5 Steps of Steel Manufacturing and Production

Steel is easily one of the most popular construction and production alloys in the world. It is a versatile product that blends durability with cost effectiveness and flexibility to work with. India happens to be one of the top five producers of steel in the world. But while steel is a highly preferred production material, have you ever wondered how steel itself is produced?

IRON MAKING

The first step to making steel is to make the iron from which it will be made. This is usually done with the help of coal. Raw bits of iron ore, coke, and lime are put into something called a blast furnace. Here, they result in molten iron (which is also called “hot metal”

STEELMAKING

Steelmaking is of two types – primary, and secondary.

The primary steelmaking process either involves a BOS method (basic oxygen steelmaking) or EAF method (electric arc furnace). In BOS, recycled scrap steel is added into the molten iron. At a really high temperature, oxygen is blown into this mixture to reduce the overall carbon content. In EAF, however, the recycled steel scrap is put through high-power electric arcs (of temperatures as high as 1650 C) in order to fully melt it and convert it to high quality steel.

Secondary steelmaking puts together both these processes. This is mainly done to fine-tune the composition of the steel being produced. Elements are added in specific temperature and environmental controls to create the perfect composition. These controls can include stirring, ladle-furnace, ladle injections, degassing, and CAS-OB (Composition Adjustment by Sealed Argon Bubbling with Oxygen Blowing).

STEEL CASTING

The molten iron is now put into a cooling mold, which sets the shape to a certain degree. It also causes the formation of a thin, hard shell. This shell is separated by the use of guided rolls. The strands of the shell are malleable, and can be worked into the desired shape, length depending on what they will be used for. Examples include flat sheets, beams, wires, or thin strips.

PRIMARY STEEL FORMING

This is the final shaping process, where hot rollers are used to fine tune the cast. The defects of casting are removed, and the steel is molded into the exact desired shape and surface finish. This is the stage at which the rough shape of the steel transforms into definitive ones – like, pipes, wire rods, bars, rails, and more.

MANUFACTURING AND FINISHING

The final step to steel production is the secondary forming technique, which gives the steel products their final shape and properties. This is done by:

  1. shaping (cold rolling methods)
  2. machining (eg: drilling)
  3. joining (by means of welding)
  4. coating – galvanising with zinc, or cold coating and electro coating
  5. heat treatment (usually tempering)
  6. surface treatment (carburising).

In today’s world, steelmaking is trying to produce alternate and more sustainable methods that allow for this process to continue with minimal damage to natural resources. While steel remains a powerful and durable alloy, its production is massively carbon-based. Steel companies in India are trying to find alternate routes to this.

For instance, a process called Pulverized Coal Injection is sometimes used in the primary steelmaking process. In this case, coal is directly injected into the furnace instead of coke. The coal used can be of low carbon content, which also reduces the cost of production.

Another fact is that steel is completely, 100% recyclable. The BOF process uses 30% of recycled steel, while EAF uses up to 90-100%. This is a far more sustainable option instead of mining more iron ore as a fresh ingredient in the steelmaking process.

There is also an alternate steelmaking process called HIsarna ironmaking. In HIsarna, iron ore is processed immediately into hot metal. The blast furnace used is a cyclone converter furnace, which skips the making of iron pellets. This skipped step makes the entire process far more energy-efficient and lowers the carbon footprint of steel production.

Steelmaking remains crucial in the industrialized world, an unavoidable process from massive scale infrastructure to the smallest kitchen utensils. It is simply a matter of finding a process that can be sustainable in the future, and cause minimal environmental damage while doing so.

What are Stainless steel reinforcing bars? How are they used?

What are Stainless steel reinforcing bars How are they used

    If you have ever happened upon a construction site, chances are that you have come across stainless steel reinforcing bars without even realizing it. With their unique grooves, stainless finish, and incredible versatility – they are difficult to miss in this day and age of concrete jungles. But what exactly are they, and what function do they serve? Let’s find out.

    WHAT ARE STAINLESS STEEL REINFORCING BARS?

    Reinforcing bars – or “rebars”, as they are more commonly referred to – are steel bars that are used to reinforce a structure. These structures are usually of concrete, and require additional structural integrity in times of tension, by way of using steel. The rebar might either just be one bar of steel, or a bundle of steel wires. In addition, the bars aren’t smooth, they have grooves, gashes, and deformations to create a surface with friction that the concrete can latch onto and tightly bind with.The reason that concrete requires these rebars is because it does not have a lot of tensile strength of its own. As a result, even if it holds its integrity under compression, it cannot under tension. In that case, rebars help.

    A stainless steel rebar, as the name suggests, are rebars made of stainless steel instead of carbon steel. Compared to carbon steel, stainless steel reinforcing bars do not corrode as easily. This leads to longevity and less risk of the structure being damaged.

    HOW ARE STAINLESS STEEL REINFORCING BARS USED?

    Stainless steel reinforcing bars are not a homogenous category. There are different types of stainless steel bars depending on their microstructure, and they perform different functions. For instance, stainless steel rebars with higher level of chromium make it easier for the bar to not corrode (by forming an oxide film). On the other hand, stainless steel rebars with higher amount of nickel prove to be more ductile and easier to form. Similarly, elements like molybdenum and nitrogen also improve anti-corrosive properties.

    Depending on the composition, stainless steel rebars are divided into different categories, and even within those categories they are divided into different grades. In general, however, stainless steel rebars are best used in places where the chance of easy replacement is low and/or corrosive tendencies are much higher.

    1. STRUCTURES CLOSE TO WATER

    Given the anti-corrosive properties of stainless steel rebars, naturally one of the most common uses for them are in structures close to water (especially saline water). It also holds true for hot and humid climates, where chances of steel corroding are very high. This includes, but is not limited to, sea walls, bridges, piers and docks, anchors for things like lamp-posts, railings, electricity and signal towers, etc. Stainless steel rebars are also used for water plants, or factory structures that involve tanks.

    2. STRUCTURES REQUIRING HIGH DUCTILE STRENGTH

    Given the high ductility of stainless steel rebars while surviving tension, they are very popular for structures that get put through a lot. For example, they are used quite frequently for flyovers, parking garages, overpasses, airport structures, high-rise buildings. They are also crucial for structures built in high earthquake prone zones, in order to help the structure, survive in tremors.

    3. UNFAMILIAR/UNKNOWN ENVIRONMENTS

    Stainless steel rebars are a very reliable choice for environments that are unfamiliar or unknown. This holds true for places where either inspection is not possible, or repairs are impossible and/or extremely expensive. In that case, it is safer to go with a stainless steel rebar which can promise longevity.

    4. PLACES REQUIRING LOW MAGNETIC PERMEABILITY

    Another quality of stainless steel rebars is that they have low magnetic permeability. Unlike carbon steel rebars, which form their own magnetic field when subject to a field, stainless steel rebars form less fields. This makes them ideal for buildings that need less exposure to magnetic fields caused by iron. For example, hospitals (with MRI machines), toll booths (with tag systems), chemical plants, labs, nuclear plants, etc. all have steel.

    Stainless steel rebars are helpful for the long life of any product of masonry. Bars from companies like Sunflag Steels are good because not only do they improve your construction process and outcome, but they are also reliable in their production.

    The Environmental Impact of the Steel Industry

    Environmental Impact of the Steel Industry

    Like any modern day industry, the steel industry is one that has grown rapidly since the past several years. This is particularly true for India, which has massive amounts of natural resources to produce steel and other alloys. But in the twenty first century, we are approaching a host of environmental issues, such as climate change, resource mismanagement, and heavy pollution. India ranks fairly low on its air quality, and overall quality of health and life.Over the last two decades, the focus of environmentalists has been to promote self-awareness of carbon footprints and introduce grass roots level lifestyle changes to help promote eco-friendly practices. However, more recently, the general public is beginning to hold large corporations responsible for their environmental impacts, and encouraging them to introduce eco-friendly practices under the CSR (corporate social responsibility) umbrella.

    WHAT IS THE ENVIRONMENTAL IMPACT OF THE STEEL INDUSTRY?

    One of the biggest environmental impacts of the steel industry is the air emission (particularly from the production of coke). The oven gas, naphthalene, and ammonium compounds are contributors to greenhouse emissions. These same products also contaminate water in the cooling processes.

    The furnaces and combustions of oil also contribute to greenhouse gas emissions, including contamination by gases like carbon dioxide, nitrogen oxides, and Sulphur Dioxide. Moreover, contamination is further caused by large amounts of dust.

    To top it all, an industry of this size will naturally be incredibly energy-consuming. The pollution (namely carbon dioxide) that is produced from running the facilities is massive. Just this year, the world has produced over 1 million tonnes of steel – and you can imagine the energy required to do that.

    HOW CAN THE STEEL INDUSTRY WORK IN AN ENVIRONMENTALLY FRIENDLY WAY?

    However, it is not an entirely bleak prospect. Despite the threats to the environment that the steel industry may pose, it is still a production process that relies largely on recycling and reusing. A majority of steel produced today is from recycled scrap steel, and not from freshly mined iron ores. Many steel products are also manufactured in a way that there is little to no waste in the recycle process.

    The issue of air and water contamination is being dealt with by introducing new machinery that has higher grade filtration systems. The Ministry of Steel in India is also introducing action plans for the efficient production of steel, promising a brighter future for the industry.

    Getting The Perfect Mirror Finish For Stainless Steel

    Getting The Perfect Mirror Finish For Stainless Steel

    When working with stainless steel, a mirror finish is important – not just because it looks good but because it also has other benefits. In this article, we understand how to get the perfect mirror finish on your stainless steel.

    First, let us answer the main question: what is a mirror finish? As the name suggests, a mirror finish is highly smooth and reflective. It gives a scratch free appearance to the stainless steel. A mirror finish is also called a #8 finish.

    Mirror finishes are usually used on those products that need to look aesthetically pleasing: for instance, artwork, architecture, or kitchen fittings. However, appearance is not the only thing that a mirror finish improves. This finish also makes the stainless steel highly resistant to corrosion. The procedure of polishing gets rid of the scratches that could possibly have any corrosive particles. Therefore, in architectural projects in coastal regions, mirror finishes become extremely important because there, the stainless steel is exposed to salt air.

    In order to mirror polish your stainless steel, start by leveling or removing the weld. This can be done using a fiber disk. The weld can be leveled without distorting the steel in any way.

    The next step is sanding. Leveling the weld removes all heavy marks of fabrication. Those areas can be brought up to the product finish of the base. Using a sanding disk, the areas where the fiber disk was used earlier can be sanded. First the fabricated areas will be sanded so as to bring it to the finish of the original sheet. Thereafter, the entire surface will be sanded. How much you need to sand will depend on how high you want your mirror finish to be.

    After the sanding, we come to polishing. With a sander, a clean polishing mop, and some polishing compound of your choice, you can begin polishing by setting the sander to 2000-3000 RPM.

    In order to ensure that the mirror finish is perfect, clean the surface of the steel before sanding. This ensures that particles don’t get rooted in the metal. It is also necessary to always use a clean mop for polishing. Even if using different polishes, use a clean mop for each type of polish.

    Sunflag Iron and Steel Company Limited is BIS certified and the best place for all your steel needs. We have flats, rounds, round cornered squares, hexes, and coils for all your steel needs.

    What Does Carbon Steel Mean?

    What Does Carbon Steel Mean?

    Steel is easily one of the most versatile alloys to ever be created. From jewelry to kitchenware, railroads and skyscrapers – it has an important use in multiple industries across the globe. Given this versatility, it is only natural that different types of steel be created depending on what their use is.

    Of all the types of steel, carbon steel happens to be a very vast but important category. It is also the most common one. As the name suggests, carbon steel contains the element of carbon.

    The different types of carbon steel are classified depending on the amount of carbon present in them. Low carbon steel, also known as mild steel, contains 0.04% to 0.3% of carbon. Medium carbon steel contains 0.31% to 0.6% of carbon. High carbon steel (also called carbon tool steel) has the highest composition of 0.61% to 1.50% of carbon.

    The amount of carbon in carbon steel can greatly change its properties, and thus, determine its uses. The presence of carbon reduces the ductility of steel – that is, the ability of the steel to be bent and stretched without breaking. However, it increases the tensile strength and how effectively it hardens when exposed to high temperatures.

    Low carbon steel is usually the most common group of carbon steel, and is very ductile. It is often used for steel sheets and beams. Depending on its exact use, it can be combined with aluminum or manganese to alter its properties. In comparison, medium carbon steel is slightly tougher. It is not the easiest form of steel to work this. More often, it is found in products that require high strength and resistance to wear and tear (such as railway tracks, machinery parts, or train wheels).

    High carbon steel is the toughest of all three, with high carbon and manganese composition. It is often used in cutting tool components, or in high-strength wires.

    Carbon steel is usually made from recycled steel (or a combination of recycled and virgin steel). Steel, in the beginning, has a much higher carbon composition than required. The carbon content is controlled by a process of decarburization to produce the right type of carbon steel. Carbon steel is one of the most versatile and commonly used forms of steel, and at Sunflag Steel we can ensure that it is produced to the highest quality, for long use and wearability.

    What is the difference between Stainless Steel & Mild Steel

    With different types of steel out there, it is understandable that there would be confusion about what each one means. Not only are they vastly different in their uses and durability, they are also made in different ways with very different components. Knowing what components different steel is made with is a great way to determine how it is useful to your needs, and which one to choose. In this piece, we will look at the key differences between stainless steel and mild steel, in order to better understand them and their potential.

    STAINLESS STEEL

    Stainless steel is a steel alloy with a minimum chromium content of 11.5%. Unlike other steels, it is known for not corroding or rusting as easily. The chromium is what prevents it from staining – so, the higher the chromium, the more resistant it is to oxidizing. While not 100% rust proof, it is certainly much less likely to go through weather damage in comparison to regular steel.

    MILD STEEL

    Mild steel is a form of steel alloy that is also called “plain carbon steel”. It is one of the most common forms of steel, which is used in a variety of manners – particularly in the transport and construction industries. Carbon steel with less than 0.5% of carbon is referred to as mild, or low carbon steel. In comparison to steel with high carbon content, this is far more ductile. It can be made into many shapes, from sheets to beams, depending on its use.

    HOW ARE THEY DIFFERENT?

    As the name suggests, stainless steel is more resistant to corrosion. Unlike mild steel, which needs to be galvanized to prevent corrosion, stainless steel merely requires polishing. This makes stainless steel highly sought after for uses that require aesthetic integrity. Examples include household items, as well as clothing and fashion industry (watch straps, belt buckles, shoe components). This is also because stainless steel is more lustrous in appearance to the dull, matte finish of mild steel. Stainless steel is also resistant to high impact because of the presence of chromium.

    With different types of steel out there, it is understandable that there would be confusion about what each one means. Not only are they vastly different in their uses and durability, they are also made in different ways with very different components. Knowing what components different steel is made with is a great way to determine how it is useful to your needs, and which one to choose. In this piece, we will look at the key differences between stainless steel and mild steel, in order to better understand them and their potential.

    STAINLESS STEEL

    Stainless steel is a steel alloy with a minimum chromium content of 11.5%. Unlike other steels, it is known for not corroding or rusting as easily. The chromium is what prevents it from staining – so, the higher the chromium, the more resistant it is to oxidizing. While not 100% rust proof, it is certainly much less likely to go through weather damage in comparison to regular steel.

    MILD STEEL

    Mild steel is a form of steel alloy that is also called “plain carbon steel”. It is one of the most common forms of steel, which is used in a variety of manners – particularly in the transport and construction industries. Carbon steel with less than 0.5% of carbon is referred to as mild, or low carbon steel. In comparison to steel with high carbon content, this is far more ductile. It can be made into many shapes, from sheets to beams, depending on its use.

    HOW ARE THEY DIFFERENT?

    As the name suggests, stainless steel is more resistant to corrosion. Unlike mild steel, which needs to be galvanized to prevent corrosion, stainless steel merely requires polishing. This makes stainless steel highly sought after for uses that require aesthetic integrity. Examples include household items, as well as clothing and fashion industry (watch straps, belt buckles, shoe components). This is also because stainless steel is more lustrous in appearance to the dull, matte finish of mild steel. Stainless steel is also resistant to high impact because of the presence of chromium.

    However, this makes it less malleable. Mild steel is easier to produce and shape depending on its usage. For this reason, it is used in construction and electronic industries. Its ability to be stretched into sheets, beams, wires makes it an attractive option for non-aesthetic and versatile uses. It is the most common steel with a high volume of production. In places where a large amount of steel is used, it is convenient and more cost-effective to opt for mild steel.

    Stainless steel is also fairly harder compared to mild steel. This is because stainless steel is resistant to water based corrosion. Unfortunately, this makes stainless steel less ductile. It is a lot more difficult to weld, unlike mild steel. Of course, mild steel can be easily hardened by introducing more carbon into it if the need is present. However, it’s lower hardness makes it more attractive for large-scale work.

    These properties also make mild steel much lighter than stainless steel – another factor which boosts its use in construction. Unless construction work requires resistance from corrosion (like in building cladding, where stainless steel is used), using mild steel for internal structures is easier. It is also convenient to transport in large quantities for this reason.

    Another difference is the cost of production. Stainless steel’s components make it expensive to produce, unlike regular carbon steel. This is not just because of the cost of raw ingredients, but also the manufacturing process. There are more steps involved, and highly skilled workers are required to produce stainless steel. So, if money-saving is your goal, then opting for mild carbon steel is much better on the wallet compared to stainless steel.

    Which type of steel you opt for is dependent on your specific needs. At Sunflag Steel, we value competitive pricing along with high quality production so that you get the right kind of product for the right uses. If you are unsure about which steel works best for you, then getting a consultation from knowledgeable engineers helps in understanding how the difference will make an impact on the finished product.

    What Are the Different Steel Welding Procedures?

    Welding-steel-Process

    Steel happens to be one of the most versatile alloys in production. Often made from recycled scrap metal, and combined with different metals to create different properties, it is used from structural strength to accessories.

    But as helpful as steel is, it would be nothing without the ability to weld it into different shapes and forms. Welding is an integral part of any metallic or alloy creative process, and steel has its own set of rules for which processes to follow. What kind of welding is done depends on the material properties of the steel, its thickness, as well as the finish of the metal?

    Deciding which procedure to use starts with knowing which type of joint you are aiming for. Different joints serve different purposes – and the end result will be determined by the material used, as well. You have to consider factors such as strength of material, heat resistance, and how accessible the joint will be upon completion.

    The main types of joints are butt, corner, edge, lap, and tee. They can be used in multiple permutations and combinations for a certain desired effect. Once you know which type of joint/joints you are aiming for, you can then decide which process is best suited for your choice of materials.

    Don’t fret! We have a helpful guide for you. Sunflag Steel has combined a list for you to understand what some of these procedures of steel welding are.

    GAS TUNGSTEN ARC WELDING

    Commonly also known as TIG Welding, this is one of the most used forms of welding for stainless steel. It offers a lot of longevity, as well as a high quality end product. Since the heat input level is fairly low, it is ideal for thinner sheets. The method uses argon, and other gases depending on what the intended final product is. These include nitrogen, helium, and hydrogen.

    SPOT WELDING

    Resistance welding, also known as Spot Welding, is considered to be an extremely cost-effective form of steel welding. It can be used for projects of different scales, making it flexible in its usage range. Resistance welding uses an electric current. The current produces heat, which is used to melt and seal the edges of frayed metal. It is useful for steels that have a lower melting point because it can also prevent warping of the raw material.

    MIG WELDING

    Gas Metal Arc Welding is also called MIG welding (Metal Inert Gas), because of the gas used in this process. It is a relatively semi-automatic process. Since the method uses an electric supply, it’s much preferred for very specific welding in spots where other methods can’t easily reach. Sometimes other gases are added to the mix to further stabilize the current.

    PLASMA ARC WELDING

    This process is actually derived from TIG welding. It involves a nozzle that produces a plasma arc. This arc penetrates the steel and allows it to fuse together. This method is frequently used in more mechanical welding processes, where there is need for high speed movement and high productivity.

    SHIELDED METAL ARC WELDING

    Shielded Metal Arc Welding might be one of the oldest welding processes for steel. It involves electrodes, and is a fairly manual process. The coating of the electrodes is decided based on what the use for the welding is – what is the composition of the steel being welded, and what are the desired characteristics in the electrode upon use.

    FLUX CORED WELDING

    Flux Cored Welding was developed as an alternative to Shielded Metal Arc Welding. It is derived from the MIG process, but instead of a solid wire, there is a flux or a metal powder used in the tube. There are two wires produced, and are used according to the demand of the procedure. The flux provides a higher degree of stabilization, shielding, and de-oxidization. There is also a massive reduction of fumes produced in this procedure. It is mostly used in construction projects.

    ELECTRIC RESISTANCE WELDING

    This form of steel welding is only used for mass production and welding of thinner material. It exists to prevent the crevice from detracting from corrosion resistance.

    With Sunflag Steel we get you the best quality steel services for our customers with enhances capabilities.

    Steel Flanges: What Are They, and How Do They Work?

    steel-flangles

    Steel flanges are one of the most useful steel inventions in the world of machinery. Albeit only a connecting material, their design plays a massive role in how the entire machine functions. Flanges are metal rings – either forged or cast – which connect sections of pipes, or join the pipe to a pressure valve or another equipment piece. They are also used in sports equipment (such as skis) or in train wheels and tracks, for the smooth motion they provide

    Flanges are considered an internal component, and make it very easy for machine maintenance to take place. Their structural integrity is dependent on the material they are made of, which in turn, is decided by how the machine itself will be used. They are most commonly made of carbon steel, alloy steel, stainless steel, or steel heavy with titanium and nickel alloys.

    One of the main advantages of flanges is that they allow for quick assembly and removal of different parts of a machine. This is crucial, not just for maintenance work, but also for versatility in the machine’s primary functions.

    There are different kinds of steel flange, and the type defines the function. For instance:

    1. Threaded flanges follow a screw-on mechanism, where the flange has threading inside and needs to be fixed to the pipe of the matching size. It helps to avoid welding in most cases.
    2. Socket Weld flanges are great for small pipe diameters, and where the work is low-temperature, low pressure. They’re fairly simple to install, too.
    3. Slip-on flanges are one of the most common ones. They’re found in a wide range of sizes and fittings, which makes them easy to use in multiple machinery. Although the installation requires some welding, finding the right size and fitting it on is a fairly easy task.
    4. Lap joint flanges are a two-piece design. They need butt welding to be connected, but they are excellent for us in restrictive physical spaces. Given that they are in more than one piece, they are also very easy to dismantle.
    5. Weld neck flanges also require butt welding when being installed. They have high integrity and are preferred in systems that involve high pressure or high temperature work.
    6. Blind flanges are used to isolate pipe sections. They are blank disks, bolted into place to stop the flow, and act as a seal when installed correctly.