Tungsten Inert Gas (TIG) welding, also known as Gas Tungsten Arc Welding (GTAW), is a process that involves using a non-consumable tungsten electrode to produce the weld. The TIG filler rods are a critical component in this process. They are used to fill the weld joint with additional metal, providing strength and durability to the welded structure. The choice of TIG filler rod significantly impacts the quality of the weld, its properties, and its suitability for the specific application.
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Selecting the right filler rod is influenced by various factors. Primarily, the base metal or metals being welded dictate the choice of filler rod. The filler metal should be compatible with the base metal&#;s properties, ensuring a strong and reliable weld. Other factors that might influence the choice of filler rod include the welding position (e.g., flat, horizontal, vertical, or overhead), the welding procedure, and the desired properties of the finished weld, such as corrosion resistance, ductility, and tensile strength.
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Understanding the roles and importance of TIG filler rods is crucial for anyone involved in TIG welding. As we move forward in this guide, we will discuss different types of TIG filler rods, their characteristics, and their suitable applications, providing valuable information for both novice and experienced welders.
TIG filler rods for high strength steel are an essential component for any welder working with this durable material. High strength steel is often utilized in applications where strength and durability are paramount, such as in the construction, automotive, and shipbuilding industries.
Characteristics of these filler rods are typically defined by their superior tensile strength and toughness, making them ideal for welding high strength steel structures. Moreover, these filler rods are designed to deliver a weld metal capable of achieving high impact toughness at low temperatures, which is often a requirement for high strength steel applications.
The selection of the appropriate TIG filler rod for high strength steel depends on various factors. These include the type of steel, the specific application, and the desired properties of the completed weld. Factors such as the steel&#;s yield strength, its chemical composition, and the welding position can also influence the selection of the appropriate filler rod.
When it comes to welding with TIG filler rods for high strength steel, there are several tips that can ensure a successful outcome. First, it is crucial to ensure that the steel surface is clean and free from contaminants, such as rust, oil, or paint, before starting the welding process. Second, preheating the steel can be beneficial in reducing the risk of cracking in the weld and the heat-affected zone. Finally, it&#;s important to remember that the cooling rate can impact the properties of the weld, so controlling the rate of cooling post-welding might be necessary in some instances.
TIG filler rods for super duplex stainless steel have unique features that make them ideal for welding this particular type of steel. Super duplex stainless steel is known for its superior strength and excellent corrosion resistance, particularly in environments with high chloride levels. It also has good resistance to stress corrosion cracking, pitting, and crevice corrosion.
When selecting a filler rod for super duplex stainless steel, it&#;s crucial to opt for one that matches the base material&#;s chemical composition. This can ensure a weld deposit that provides equivalent properties in terms of strength, corrosion resistance, and durability. Often, these filler rods are over-alloyed with higher percentages of nickel, chromium, and molybdenum to maintain the favorable properties of the super duplex stainless steel after welding.
In terms of use, TIG welding with super duplex filler rods requires a high level of skill and control. Since super duplex stainless steel has a higher thermal expansion rate and lower thermal conductivity compared to austenitic stainless steel, careful control of heat input is crucial. This can help prevent detrimental effects such as loss of corrosion resistance, changes in the microstructure, and distortion. Furthermore, it&#;s crucial to clean the workpiece before welding to remove any contaminants that could compromise the weld quality.
TIG filler rods for super duplex stainless steel play an integral role in welding this high-performance material. Understanding their properties, appropriate selection, and proper welding techniques can ensure a high-quality, durable weld that leverages the full potential of super duplex stainless steel.
Hard facing refers to the process of adding a layer of wear-resistant material to the surface of a metal component to increase its lifespan by reducing wear and tear. TIG filler rods for hard facing have specific characteristics that make them suitable for this purpose.
The choice of TIG filler rods for hard facing is often driven by the wear conditions the finished piece will be exposed to, such as high temperature, abrasion, impact, or a combination of these. They are typically made of complex carbides in a matrix, with different types designed to withstand different kinds of wear.
The selection and use of these rods require a thorough understanding of the base metal and the expected wear conditions. Some common considerations when choosing a rod include the hardness of the overlay, the toughness required, and the potential for cracking. These rods are often used in industries like mining, agriculture, or any other industry where equipment is exposed to severe wear conditions.
When welding with TIG filler rods for hard facing, it is crucial to maintain the appropriate temperature and travel speed. Because hardfacing materials tend to be more brittle than the base metal, they can be susceptible to cracking if cooled too quickly. It&#;s also important to take into account the number of layers required; in some instances, two layers of hardfacing material may provide longer wear life than a single layer.
TIG filler rods for hard facing play a crucial role in extending the life of metal parts exposed to harsh wear conditions. Understanding the properties of these rods, and how to properly use them, can significantly enhance the performance and longevity of the finished piece.
Aluminium, known for its lightweight and high thermal conductivity, is a common material in various industries such as automotive, aerospace, and construction. TIG filler rods for aluminium play a crucial role in joining and repairing aluminium structures.
These rods possess key properties that align with aluminium&#;s distinct characteristics. They typically exhibit a lower melting point compared to steel rods, ensuring compatibility with the base aluminium&#;s melting behaviour. The rods also demonstrate excellent corrosion resistance, mirroring one of aluminium&#;s renowned properties.
The application areas for these filler rods are vast, considering the extensive use of aluminium in manufacturing. From engine parts and aircraft structures to aluminium frames and structures in construction, these filler rods are fundamental in creating sturdy, reliable joints.
When it comes to best practices for welding, it&#;s important to remember that aluminium requires a clean surface to ensure a successful weld. Hence, any oxide layer should be removed before welding. Additionally, preheating the aluminium can be beneficial, especially for thicker pieces, to prevent cracking. The choice of the specific type of aluminium TIG filler rod, whether a or a alloy, for instance, should depend on the specific application, the desired mechanical properties, and the base aluminium alloy being welded.
TIG filler rods for aluminium are invaluable tools in the welding world, particularly considering the ubiquitous use of aluminium. Understanding their properties, applications, and best practices for use can significantly improve the quality of the welding process and its resultant output.
TIG filler rods for magnesium possess a set of unique characteristics that make them particularly well-suited to welding this lightweight, yet robust metal. The filler rods share the intrinsic properties of magnesium, including its strength-to-weight ratio and its excellent machinability, among other attributes. When using these filler rods, welders can achieve seamless, high-quality welds that retain the integrity and beneficial characteristics of magnesium.
These filler rods have applications in various sectors where the use of magnesium is prevalent. For example, in the aerospace and automotive industries, magnesium is favored for its lightweight nature, which significantly contributes to fuel efficiency without compromising strength. Similarly, it&#;s used in the manufacturing of electronic devices and sports equipment due to its weight and durability.
When it comes to welding magnesium with TIG filler rods, certain practices can help optimize results. For instance, thorough pre-cleaning of the base metal is crucial, as magnesium is highly reactive and can form an oxide layer that hinders proper fusion. Using a brush made of stainless steel to clean the area to be welded can effectively remove this oxide layer. Another tip is to ensure the appropriate shielding gas&#;typically argon&#;is used. Additionally, it&#;s recommended to keep the welding heat as low as possible to prevent warping and distortion, given that magnesium has a lower melting point compared to many other metals.
TIG filler rods for magnesium allow welders to effectively join magnesium parts, leveraging the metal&#;s beneficial properties. By following best welding practices, these filler rods can be used to create high-quality, durable welds for a wide range of applications.
When it comes to welding mild steel, which is one of the most commonly used materials in various industries, TIG filler rods designed specifically for this purpose are essential. These rods possess specific features that make them well-suited for working with mild steel. The characteristics of these rods typically include a high level of tensile strength and excellent ductility, enabling them to form a strong, durable bond with the mild steel base metal.
Mild steel TIG filler rods find applications across a wide range of industries, including automotive, construction, and general fabrication. They&#;re perfect for tasks that require the joining of mild steel components or for repair and maintenance work on mild steel structures. These rods can also be used effectively for sheet metal work due to their versatility.
The use of these rods requires a clear understanding of welding guidelines to ensure the desired results. For instance, it&#;s crucial to match the filler rod&#;s diameter with the thickness of the mild steel base metal being welded. Moreover, the rods should be kept clean and dry to prevent contamination that could weaken the weld. It&#;s also necessary to adopt the right welding technique, with the preferred method for TIG welding being the &#;dip and dab&#; technique, where the rod is dipped into the weld pool and then withdrawn to allow for cooling.
The choice of TIG filler rod can significantly influence the quality of a mild steel weld. By understanding the specific properties of these rods and following the recommended welding guidelines, welders can ensure the durability and strength of their mild steel welding projects.
Stainless steel is an alloy renowned for its corrosion resistance, strength, and wide range of applications, making it a common material in many welding projects. The selection of TIG filler rods for stainless steel requires a clear understanding of the unique properties and types of stainless steel.
Stainless steel TIG filler rods typically share the same corrosion resistance, ductility, and toughness as the base metal. They come in various grades, each designed for specific types of stainless steel. For instance, 308L rods are often used for 304 stainless steel, while 316L rods are compatible with 316 stainless steel. The choice of rod depends on the type of stainless steel being welded and the desired characteristics of the weld.
The use cases for stainless steel TIG filler rods span various industries, including food service, healthcare, and construction. They are commonly employed in situations requiring high corrosion resistance, such as in the production of kitchen utensils, hospital equipment, and outdoor structures.
Welding stainless steel presents unique challenges due to its lower thermal conductivity and higher coefficient of thermal expansion compared to carbon steel. Therefore, when welding with stainless steel TIG filler rods, it&#;s essential to control the heat input carefully to prevent warping or distortion. Using a backing gas is also recommended to ensure the back of the weld is protected from oxidation.
TIG filler rods for stainless steel play a crucial role in many welding applications. Understanding their properties and the specific use cases they&#;re designed for is key to producing high-quality, durable welds. Always remember to follow appropriate welding practices to ensure the integrity and longevity of your welds.
TIG filler rods used for brazing or bronze welding possess a unique set of characteristics and applications. They are typically comprised of copper and zinc alloys and are used primarily for brazing or bronze welding tasks. These rods provide excellent fluidity, solidification strength, and are distinguished by their superior anti-corrosion properties. They can be used in a wide range of applications, including the repair of cast iron components, sheet metal fabrication, and when working with dissimilar metals.
The selection criteria for these filler rods largely depend on the specific requirements of the task at hand. This might include factors such as the base metals being joined, the joint design, and the desired strength and appearance of the final weld. It&#;s worth noting that proper cleaning and preparation of the base material are crucial steps when using these rods, as this can significantly impact the quality of the resultant weld.
When it comes to welding with TIG filler rods for brazing or bronze welding, there are a few best practices to keep in mind. Firstly, the welding process should be carried out at a lower temperature compared to traditional welding. This is because brazing involves melting the filler metal to a liquid state and allowing it to flow into the joint via capillary action. Moreover, proper control of the heat input is essential to prevent overheating and to ensure an even and strong weld. Lastly, post-weld cleaning is a necessary step to remove any residual flux and to inspect the weld for any defects.
TIG filler rods for brazing or bronze welding provide a versatile solution for joining a variety of base metals. By understanding their characteristics and following the correct welding procedures, one can achieve effective and high-quality welds with these specialized filler rods.
TIG filler rods designed for copper and copper-nickel alloys hold unique properties that make them suitable for specific welding applications. These filler rods are often used to weld copper and its alloys due to their ability to create strong, high-quality welds with excellent thermal conductivity and corrosion resistance.
The selection of copper/copper-nickel TIG filler rods should be primarily guided by the composition of the base metals being welded. When welding pure copper, it is typically best to use a filler rod that closely matches the base metal. For copper-nickel alloys, selecting a filler rod with a similar alloy content can ensure a homogenous weld deposit that matches the corrosion resistance and mechanical properties of the base metal.
Typical applications of copper/copper-nickel TIG filler rods include welding copper piping in the plumbing industry, electrical components due to copper&#;s excellent conductivity, and marine applications, where copper-nickel alloys are widely used for their superior resistance to seawater corrosion.
To achieve effective welding results with these filler rods, a few tips can be beneficial. Firstly, maintaining a clean work environment is paramount, as copper and its alloys are susceptible to contamination. Therefore, the welding area, base metal, and filler rod should be thoroughly cleaned before starting the welding process. Secondly, considering copper&#;s high thermal conductivity, managing heat input to prevent overheating or warping of the base metal is crucial. Lastly, using a shielding gas like argon can help prevent oxidation and ensure a smooth, clean weld.
Dissimilar steel welding refers to the process of joining two different types of steel together. It presents unique challenges due to the varying properties and compositions of the base metals. TIG filler rods specifically designed for dissimilar steels play a crucial role in achieving strong and reliable welds in such applications.
The selection and use of TIG filler rods for dissimilar steels require careful consideration. One of the primary factors to consider is the compatibility of the filler rod with the base metals. Filler rods with similar composition and mechanical properties to the base metals are typically preferred to ensure a compatible and homogeneous weld.
Additionally, the difference in thermal expansion coefficients between dissimilar steels can lead to distortion and residual stresses in the weld. Choosing a filler rod with a composition that minimizes this difference can help mitigate these issues and improve the overall weld quality.
Welding dissimilar steels often involves dealing with different melting points and heat input requirements. Thus, selecting a filler rod with a suitable melting point and heat transfer characteristics is crucial to achieving a balanced and controlled welding process. It is important to consult welding procedure specifications (WPS) and follow the recommended welding parameters to ensure proper fusion and minimize the risk of defects.
Proper joint preparation, including cleaning and removal of contaminants, is essential when welding dissimilar steels. Thoroughly cleaning the base metals and using appropriate pre-weld cleaning methods can help ensure sound welds with good penetration.
TIG filler rods designed for dissimilar steels are indispensable when joining different types of steel. Through careful selection and consideration of compatibility, composition, melting point, and heat transfer characteristics, these filler rods enable welders to achieve strong and reliable welds in dissimilar steel applications. Adhering to proper joint preparation and following recommended welding parameters are equally important to ensure successful outcomes.
Duplex stainless steel is a popular material choice for its excellent corrosion resistance and high strength. When it comes to TIG welding duplex stainless steel, using the appropriate filler rod is crucial to maintain the desired mechanical properties and corrosion resistance of the weld.
TIG filler rods for duplex stainless steel are specifically designed to match the composition and properties of this material. These filler rods typically have a balanced composition of austenite and ferrite to ensure a proper weld structure and maintain the duplex characteristics.
When selecting TIG filler rods for duplex stainless steel, consider the grade and chemical composition of the base material. Match the filler rod&#;s grade to that of the base metal to achieve optimal weld integrity. It&#;s essential to refer to the material specifications and consult with welding experts or suppliers to ensure the correct filler rod is chosen.
During welding, maintaining a balanced heat input is crucial to prevent the formation of detrimental phases and maintain the desired microstructure. Controlling the interpass temperature and using appropriate preheating and post-weld heat treatment techniques can help achieve the desired mechanical and corrosion properties in the weld joint.
Proper cleaning and preparation of the base material are essential to prevent contamination during the welding process. Thoroughly remove any surface contaminants, such as oils, grease, or oxides, before starting the TIG welding process. This ensures a clean and defect-free weld joint.
Welding parameters, such as welding current, travel speed, and shielding gas composition, should be optimized for the specific duplex stainless steel grade and filler rod combination being used. Fine-tuning these parameters, along with maintaining proper shielding gas coverage, can help minimize the risk of defects like porosity and ensure a sound weld.
Regular inspection and testing of the welded joints are crucial to ensure the quality and integrity of the weld. Non-destructive testing methods such as visual inspection, dye penetrant testing, and ultrasonic testing can be employed to detect any potential defects or discontinuities in the weld.
When TIG welding duplex stainless steel, selecting the appropriate filler rod is essential for achieving welds with the desired mechanical properties and corrosion resistance. Consider the base material&#;s grade and chemical composition, maintain proper heat input, clean and prepare the base material thoroughly, optimize welding parameters, and conduct regular inspections to ensure high-quality welds in duplex stainless steel applications.
Nickel alloys offer excellent resistance to high temperatures, corrosion, and wear, making them ideal for a wide range of applications in industries such as aerospace, chemical processing, and power generation. TIG welding with the appropriate filler rod is commonly used to join nickel alloys, ensuring strong and durable welds.
Nickel alloys are known for their exceptional heat and corrosion resistance, along with high strength and excellent mechanical properties. They are often used in environments with extreme temperatures or aggressive chemical conditions. Common applications of nickel alloys include turbine components, chemical reactors, and equipment for the oil and gas industry.
When selecting TIG filler rods for nickel alloy welding, it is crucial to choose a rod that matches the base metal&#;s composition. Nickel alloy filler rods are available in various grades, such as Inconel, Hastelloy, and Monel, each designed for specific nickel alloy compositions. Consult the material specifications or seek guidance from the manufacturer to ensure the correct filler rod selection.
Cleanliness is essential when working with nickel alloys, as contaminants can lead to porosity and reduced weld quality. Thoroughly clean the base metal before welding, and use a dedicated stainless steel wire brush or designated cleaning solution to remove any surface contaminants, such as oils, greases, or oxides.
Welding nickel alloys requires careful attention to welding parameters and techniques to achieve high-quality results. Here are some best practices:
By adhering to these welding best practices and using the correct TIG filler rod for the specific nickel alloy, welders can achieve high-quality and reliable welds in nickel alloy applications, ensuring the desired performance and longevity of the welded components.
TIG filler rods for titanium play a critical role in welding applications involving this lightweight and corrosion-resistant metal. Titanium requires filler rods with specific properties to achieve strong and reliable welds. These filler rods are specifically designed to match the characteristics and chemistry of titanium, ensuring optimal results.
One of the key features of TIG filler rods for titanium is their high purity. Impurities can compromise the integrity of the weld and cause issues such as porosity and reduced mechanical strength. Therefore, it is crucial to select filler rods that have low levels of impurities, ensuring clean and high-quality welds.
When using TIG filler rods for titanium, it is important to consider the grade of titanium being welded. Different grades of titanium have varying compositions and mechanical properties, requiring corresponding filler rods that match those specific characteristics. This ensures that the filler metal can seamlessly integrate with the base metal, resulting in a strong and reliable weld joint.
Proper handling and storage of TIG filler rods for titanium are essential. Titanium filler rods are highly sensitive to moisture and contaminants, which can negatively impact the weld quality. It is important to store these rods in a dry environment and protect them from exposure to moisture, oils, and other contaminants that may be present in the welding environment.
Welding titanium requires precise control over the welding parameters, including heat input, travel speed, and shielding gas flow. The use of suitable filler rods is critical in maintaining the desired mechanical properties and preventing the formation of undesirable intermetallic compounds. It is recommended to refer to the manufacturer&#;s guidelines and specifications for the specific grade of titanium being welded to ensure the proper selection and use of TIG filler rods.
TIG filler rods for titanium are specifically formulated to match the unique properties and chemistry of titanium. Their high purity, compatibility with different grades of titanium, and proper handling ensure clean and reliable welds. By using the appropriate TIG filler rods and following recommended welding parameters, welders can achieve strong and durable weld joints in titanium applications.
Correct selection and utilization of TIG filler rods are crucial aspects of achieving successful and high-quality welds. The variety of available filler rods cater to specific materials and applications, providing welders with the versatility necessary to meet diverse welding needs.
Throughout this article, we have explored various types of TIG filler rods, including those designed for high-strength steel, super duplex stainless steel, hard facing, aluminium, magnesium, mild steel, stainless steel, brazing/bronze welding, copper/copper-nickel, dissimilar steels, duplex stainless steel, nickel alloy, and titanium.
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By understanding the characteristics, applications, and selection criteria of each type, welders can make informed decisions to ensure optimal welding results. Following recommended welding techniques, including appropriate amperage settings, gas shielding, and electrode manipulation, further contributes to achieving strong and durable welds.
It is essential for welders to familiarize themselves with the specific properties and requirements of the materials they are working with, as well as the corresponding filler rods. This knowledge allows for the best match between filler rod and base metal, promoting proper fusion and minimizing the risk of defects such as cracks, porosity, or inadequate penetration.
To enhance welding proficiency and expertise, ongoing education and practice are highly recommended. Manufacturers&#; guidelines, industry standards, and welding resources can provide valuable insights into the selection, handling, and utilization of TIG filler rods.
In conclusion, the proper selection and use of TIG filler rods are critical in achieving high-quality welds with superior strength and integrity. By considering the characteristics and requirements of the base metal, welders can make informed decisions regarding the most suitable filler rod for each welding application. Continuous learning and adherence to best practices will contribute to the welder&#;s proficiency and the overall success of welding projects.
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The acronym TIG stands for Tungsten Inert Gas. Tungsten refers to the type of conductor (a tungsten electrode) that is used to transfer the welding current to the job and create the arc. Inert Gas refers to the fact that the process relies on an inert gas (eg Argon) to shield the weld and prevent weld oxidisation.
TIG is also referred to as Gas Tungsten Arc Welding (GTAW).
In simple terms, TIG welding is probably most similar to oxy flame welding. However, instead of a flame it uses an electrical arc to melt the job and filler metal, and instead of a preheat flame it uses inert gas to prevent weld oxidisation. Like oxy flame welding, the filler metal is fed into the weld by hand as required. Due to the fact that the current is not conducted to the job via the filler metal, (as it is in MIG and MMA welding), the arc is much more controllable.
Tungsten Inert Gas (TIG) welding, also known as Gas Tungsten Arc Welding (GTAW), was invented during early s by a team of researchers at the Northrop Aircraft Company in the United States. This invention was led by Russell Meredith, who developed the process to meet the needs of welding magnesium in aircraft production. TIG welding uses a non-consumable tungsten electrode to produce the weld, and an inert gas, typically argon, is used to protect the weld area from atmospheric contamination. This method was revolutionary because it provided a way to create high-quality, precise, and clean welds on a variety of metals, including aluminum and stainless steel, which were becoming increasingly important in the aviation and aerospace industries. The invention of TIG welding significantly advanced the capabilities of modern manufacturing and fabrication, allowing for more robust and reliable construction in critical applications.
Very low amperages can be achieved making this process ideal for welding thin materials. Also, due to the independence of the arc and the filler metal application, TIG welding is very controllable and can therefore achieve very high quality welds with excellent appearance. Unlike MIG and MMA welding, TIG welding does not produce spatter so clean up is very minimal.
TIG is typically used where weld appearance is critical (e.g. handrails) or where weld quality is vital (e.g. pressure vessels or pipes).
Whilst TIG welding is very controllable, it can also be slower and more tedious than MIG or stick/MMA welding and it will generally not operate well on dirty or rusty materials meaning that additional weld preparation is sometimes necessary.
"DC" (Direct Current) TIG welding machines can be used to weld a variety of "ferrous metals" including mild steel & stainless steel, and also copper and chrome moly. (But NOT aluminium).
Many (but not all) inverter stick/MMA welders have DC TIG capability - including most of the Weldclass Stick/TIG and MIG/Multifunction welding machine range.
An important feature to enable effective TIG welding is lift-arc ignition - read more about this here.
To weld Aluminium, you need a machine with "AC" (Alternating Current) capability.
Such machines usually have both AC and DC capability ("AC/DC") in the one machine - this allows them to weld most metals including; aluminium, steel, stainless-steel, copper, chrome moly, etc.
Typically AC/DC machines, such as the FORCE 201T, are dedicated TIG welding machines (sometimes with stick/MMA capacity as an additional feature).
Pure argon (100% Ar) is required for most common TIG welding applications. Some critical applications may require speciality gases.
Polarity refers to the direction of current flow when welding.
All DC TIG welding (steel, stainless, etc) is done on DC- polarity where the TIG torch is connected to the negative (-) terminal and the earth lead to the positive (+) terminal.
For AC TIG welding (aluminium) the polarity is usually* the opposite to DC: the TIG torch is connected to the positive (+) terminal and the earth lead to the negative (-) terminal.
*Note: Whilst "torch positive" is the most common polarity for AC/DC TIG welding, some AC/DC TIG machines may require "torch negative". Consult the instruction manual for your machine, or contact the manufacturer.
The most common tungsten electrode types are as follows;
Tungstens for DC TIG welding of steel, stainless-steel, chrome molly, copper:
Thoriated (red tip)
Lanthanated 1.5% (gold tip)
Tungstens for AC welding of Aluminium:
Zirconiated (white tip)
"All-Metal" Tungstens suitable for AC or DC welding:
Rare-earth (purple tip)
Lanthanated 2% (blue tip)
Ceriated (grey tip)
Weldclass RE4 rare-earth tungstens are proven to perform well on both AC & DC applications.
Because of the many variables in any given TIG welding application, there is no single formula to say "for X thickness you need X amps".
The many factors that influence this include; material being welded, type of tungsten elecrode used, type of weld joint, weld position, operator technique, skill and/or experience, required strength or quality of the weld joint, etc.
However, here is a rough guide for TIG welding of steel, stainless or aluminium:
Material
Thickness*
Suggested
Tungsten
Size*
Amps
Required*
<1mm
1.0mm
10-30A
<2mm
1.6mm
30-80A
2-3mm
2.4mm
80-150A
4-5mm
3.2mm
150-200A
*This is a general guide only and should not be used as specific advice for any particular application
TIG torches come in various styles, models and configurations to suit different types of welding machines, required capacity and operator preferences.
TIG Torch Selection Guide
Following is a typical breakdown of a TIG torch head & consumables. For more details, see TIG Parts Explained
What is Scratch-Start, Lift-Arc and HF Ignition?
Weldclass TIG and Multifunction Welding Machines
While all care has been taken, Weldclass accepts no responsibility for any inaccuracies, errors or omissions in this information or links and attachments. Any comments, suggestions & recommendations are of a general nature only and may not apply to certain applications. It is the sole responsibility of the user and/or operator to select the appropriate product for their intended purpose and to ensure that the product selected is capable of performing correctly and safely in the intended application. E.&O.E.
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