Database of properties for steel and alloy materials worldwide.

 
Showing posts with label Welding Material. Show all posts
Showing posts with label Welding Material. Show all posts

How to weld mild steel to stainless steel?

Welding mild steel to stainless steel can be a challenge for new welders who are unsure of their ability to create a high-quality joint between these two dissimilar metals. The properties and compositions of these metals are different, making the welding process more difficult than welding pure stainless steel. In this article, we will discuss the challenges of welding mild steel to stainless steel and provide some tips to ensure a successful weld.

Note: Mild steel (iron containing a small percentage of carbon, strong and tough but not readily tempered), also known as plain-carbon steel and low-carbon steel, is now the most common form of steel because its price is relatively low while it provides material properties that are acceptable for many applications.

One of the most critical aspects of welding mild steel to stainless steel is to avoid over-welding and deep penetration. This is because these metals have different melting points and thermal expansion rates, which can cause cracking, distortion, and brittleness in the joint. To prevent these issues, it's important to focus the arc more on the stainless steel portion and maintain low heat.

Related post:

Reasons You Want to Avoid Welding Stainless Steel to Carbon Steel

Maintaining low heat is essential to prevent deep penetration, preserve corrosion resistance, and prevent carbon contamination. To achieve this, you can set the lowest amperage that will melt the filler metal, travel at a fast speed, use stringer beads instead of weaving, use chill bars under or on the metals, and create a symmetrical joint that requires the least amount of weld metal. Despite the uneven angle, pointing the arc towards the stainless steel portion will result in a symmetrical bead with good toe fusion.

Differences between mild and austenitic steel for welding

Property

Mild steel

Austenitic (304) steel

Thermal expansion

65

100

Thermal conductivity

100

33

Electrical resistance

12.5

72

High-temperature strength

900 °F (480 °C)

1300 °F (700 °C )

Tensile strength

60-70ksi

85ksi

Ductility

25

55

Melting point

2800 °F (1540 °C)

2600 °F (1425 °C)

Galvanic corrosion

High

Low

Top of Form

 Another challenge in welding mild steel to stainless steel is avoiding slag inclusions, which can occur when the welding process produces slag on the bead. To prevent this, the customized angle becomes even more crucial. It's also a good idea to test on similar scrap metals before welding your main project.

Contamination of the stainless steel portion with iron particles is another critical consideration in welding mild steel to stainless steel. Iron particles can cause rusting of the stainless steel portion, leading to corrosion over time. To avoid this, it's essential to use a separate set of tools to clean and bevel the stainless steel portion and avoid scratching it on any carbon steel surfaces, such as the steel portion or the welding table.

In conclusion, welding mild steel to stainless steel can be a challenging task for new welders. It requires a proper understanding of the properties and compositions of these metals and specialized techniques to ensure a successful weld. By following the tips outlined in this article, you can minimize the risks and create a strong, durable joint between these two dissimilar metals.

Reasons You Want to Avoid Welding Stainless Steel to Carbon Steel

When it comes to metalworking, welding is a commonly used technique to join different pieces of metal together. However, welding stainless steel to carbon steel is a particularly difficult task that should be avoided whenever possible. There are several reasons why welding dissimilar metals, such as stainless steel and carbon steel, can lead to problems and potentially compromise the strength and longevity of the finished product.

Difficulty

Combining dissimilar metals adds extra challenges to the welding process. Stainless steel and carbon steel have different properties, including different thermal expansion rates, melting points, and chemical compositions. Welding these two materials together creates a "dissimilar metal weld," which can cause problems such as cracking, distortion, and brittleness.
Welding stainless steel to carbon steel requires precise control of the temperature and heat input to ensure the proper fusion of the two metals. This can be difficult to achieve due to the different properties of each metal. Carbon steel has a lower melting point and is more electrically conductive than stainless steel. Welding stainless steel with resistance welding, for example, heats up the metal much faster than carbon steel. Waiting for the carbon steel to reach weld temperature can cause the stainless steel to overheat and become riddled with hot cracks. Using filler-based welding or preheating the plain carbon steel can mitigate this issue, but these methods aren't foolproof.

Related post:
Hot Cracking of the Stainless Steel

Hot cracking is a common issue when welding stainless steel to carbon steel. This occurs because stainless steel is more electrically-resistant than carbon steel, so it heats up faster. Waiting for the carbon steel to reach welding temperature can cause the stainless steel to overheat and become riddled with hot cracks. This problem is particularly prevalent when resistance welding stainless steel to carbon steel. Filler-based welding or preheating plain steel/mild steel can help alleviate this problem, but these methods aren't always sufficient.

Contamination

Welding stainless steel to carbon steel can also result in contamination of the stainless steel with carbon steel particles, which can lead to rust and other forms of corrosion over time.

Thermal Expansion in High-Temperature Service Conditions

This difference in expansion rates between the two metals can cause extra fatigue to the welded joint, reducing the structural integrity and useful life. In high-temperature service conditions, such as in power plants or chemical processing plants, this problem can be particularly acute. The difference in expansion rates between stainless steel and carbon steel can cause the welded joint to become fatigued, leading to structural failure over time.

Increased Bimetallic Corrosion

Stainless steel is resistant to corrosion, whereas carbon steel is not. When these two metals are welded together, the carbon steel can act as a cathode and the stainless steel as an anode in the presence of an electrolyte such as water, leading to corrosion of the stainless steel.
Stainless steel is generally used for its strong corrosion resistance. An uncovered weld of plain carbon steel and stainless steel that is exposed to extremely corrosive conditions, such as immersion in saltwater, could cause corrosion. This is because the intermingling of plain carbon steel particles with the stainless alloy compromises the protective oxide layer of the stainless, allowing rust to form. This type of corrosion is known as bimetallic corrosion and can severely compromise the integrity of the welded joint.

Reduced Weld Strength

Joining dissimilar metals can lead to weaker welds, even with filler-based welding methods. The differences in weld temperatures and operational tolerances alone can easily compromise the strength of the welded joint. Over time, this can lead to failure of the welded joint, which can be dangerous in high-stress applications.

Conclusion

Welding dissimilar metals together are difficult to do right and often produces inferior results compared to using metal alloys that are similar or the same. When it comes to welding stainless steel to carbon steel, there are several reasons why you should avoid it whenever possible. The difficulty of achieving a good weld, the risk of hot cracking, thermal expansion, increased bimetallic corrosion, and reduced weld strength all make it a risky proposition.

Valve Remanufacturing Welding Procedures

All weld procedures are to be approved by Quality Assurance Manager

All general repair and modification welding is to be done by Gas Metal Arc Welding (GMAW) (or MIG) method only unless prior approval has been given.


All seating surface overlay welding is to be done by Gas Tungsten Arc Welding (GTAW) (or TIG) method only unless prior approval has been given.
When applying overlays that require preheat are applied to P # 8 base materials the preheat temperature applied should be as minimal as practical.

All welds shall have dye-penetrant examination performed on them during the process as necessary and after final finishing of the part.


*       (Per ANSI B31.3) Recommended Preheat
1       (Per ANSI B31.3) 1100-1200°F for nominal thickness > ¾” and no PWHT for nominal thickness < ¾”.
2       (Per ANSI B31.3) 1300-1375°F for nominal thickness > ½” and no PWHT for nominal thickness < ½”.
3       (Per ANSI B31.3) 1300-1400°F for nominal thickness > ½” and no PWHT for nominal thickness < ½”.
4       (Per ANSI B31.3) 1350-1450°F for all thickness.
5       15 minute minimum holding time
6       (Per ASTM A182) Recommended Preheat and Interpass Temperature Range
         (Note: Some of these values conflict with ANSI/ASME B31.3 values)
7       (Per ASTM A182) 1900°F PWHT + WQ with no holding time given
         (per paragraph 12.1.5 “... may be (welded) without (PWHT)...”)
8       Listed as A5.9/28 because these classifications are in the process of being added to AWS A 5.28 and deleted from AWS A 5.9


Source: qualichek.com

WELDING CARBON STEEL

The following information is not intended to be a guide to welding structures in Industry. It is intended as a basic introduction to a complex subject known as Metallurgy. In many Industrial settings the procedure to be followed when welding a given type and grade of metal is established through testing to a specific Code or Standard or through practical experience. However; it may be useful for the welder to understand the affects of welding on metal. One of the most widely welded classifications of metal is the group of carbon steels.

WHY DOES THE WELDER NEED TO KNOW ANYTHING ABOUT THE STEEL HE IS ASKED TO WELD?
In many cases the welder needs only to know the techniques of actual welding and does not need to be concerned about the type or grade of steel being welded. This is because a large amount of steel used in fabricating a metal structure is low Carbon or plain carbon steel (also called mild steel). When welding these steels with any of the common arc welding processes like Stick Mig or Tig there are generally few precautions necessary to prevent changing the properties of the steel.  
Steels that have higher amounts of Carbon or other alloys added may require special procedures such as preheating and slow cooling, to prevent cracking or changing the strength characteristics of the steel. The welder may be involved in following a specific welding procedure to ensure weld metal and base metal have the desired strength characteristics.  

WHAT ARE THE TERMS USED TO DESCRIBE THE CHARACTERISTICS OF METAL?

Before reviewing the weldability of steel we need to understand the terms used to describe the changes that may occur due to welding the steels.
Review the definitions below as an introduction and refer back to them as necessary.

MECHANICAL PROPERTIES OF STEEL

Mechanical properties are the properties of the steel reacting to some load or mechanical working such as bending, machining, or shaping. Mechanical properties affect how the metal will react when fabricating a structure. While Iron is a relatively soft metal that can be easily shaped or formed, other elements may be added to the iron to give it a specific strength or enhanced mechanical properties.
The terms used to describe these properties are as follows:

STRESS
Stress is defined as the load per unit area and is measured in pounds per square inch. Stress is pressure acting on a weld or metal to pull it apart, twist it, compress it, or shear it, depending on the direction and type of load. In some cases one or more of the above loads may be applied in varying degrees.


STRAIN
Strain is the resulting deformation of the applied stress. For example: If a piece has stress acting to bend it, the amount or degree to which the piece bends is the measure of the strain. In other words stress and strain go together, for instance; if you stress your back by lifting or carrying a heavy load the resulting pain or damage is the strain.

ELASTICITY
Elasticity is the property of a material that when stressed or has a force applied allows the shape to return to its original shape. In other word when the load is removed there is no appreciable strain or deformation. Metals have a limit of elasticity and when the load increases beyond the limit deformation or strain will occur.

PLASTICITY
Plasticity is the ability of a metal to be deformed or shaped without rupture. For example a piece of plain carbon steel can be shaped easier then a piece of tool steel without rupturing or breaking.

STRENGTH
Strength is the ability of a material to resist deformation. Plasticity and strength work together since plasticity is the ability to take the applied load its strength is the ability to withstand or resist deforming under the load. Metals with high strength will deform less than metals with lower strength.

TENSILE STRENGTH
The tensile strength is the ability of a metal to withstand forces acting to pull it apart and is measured in pounds per square inch. For example: the E-7018 electrode produces a weld with a tensile strength of 70,000 pounds per square inch as shown by the first two digits of its number. 

DUCTILITY
Ductility is the ability of a metal to be easily shaped or elongated without failure or rupture. Generally metals with high tensile strength are tougher but have lower ductility and ductile metals are softer and have lower tensile strength. Ductility is the property that allows metals such as aluminum and copper to be drawn into wire forms. 

HARDNESS
Hardness is defined as the ability of a material to resist indentation and is a function of its elastic and plastic properties. The harder the metal the more it is able to resist wear and tear.

 MALLEABILITY
Malleability is the ability of a metal to be shaped by compressive forces without rupture. Metals with good malleability can be rolled into thin sheets. For example gold has high malleability and can be rolled and shaped into thin sheets.

 BRITTLENESS
Brittleness is basically a term used to describe the lack of plasticity or ductility. A brittle metal cannot be easily deformed or shaped. For example: a hardened steel or cast iron may be brittle and show very little resistance to impact or shock.

PHYSICAL PROPERTIES OF STEEL

Physical properties are related to the structure and nature of the steel or Alloy and include density, electrical conductivity, heat conductivity, melting point, magnetic properties, reflectivity, and coefficient of thermal expansion. 
Of the above properties, one of the most important is the coefficient of thermal expansion. Steel when heated increases in length, width, and thickness. The increase in unit length when a metal is heated one degree is called its coefficient of thermal expansion. When welding takes place a localized area is heated to melting temperature and begins cooling, steel that has a high coefficient of thermal expansion such as Stainless Steel will warp or change dimensionally more than regular steel.  Distortion or warping due to welding will be covered in a later lesson. 

CARBON STEELS

What is Carbon Steel?
Carbon Steel is principally a mixture (or Alloy) of Iron and Carbon with small amounts of silicon, sulfur, phosphorous, and manganese. Other elements may be added to the steel to impart a specific quality to enhance its usefulness.
An Alloy may be thought of as a recipe, similar to a recipe for chicken soup that has  ingredients to enhance the flavor, Iron has other elements or ingredients to enhance the properties of the Iron.
In plain carbon steels it is the Carbon additive that has the greatest effect on the strength and weldability of the steel.
The carbon is added to the Iron in varying amounts to harden or strengthen the steel. As carbon content increases the hardness and tensile strength increases and the ductility, plasticity, and malleability will decrease.
The reason the carbon content or carbon recipe varies is to produce a family of steels that exhibit the desired characteristics for a given application.

HOW DOES THE AMOUNT OF CARBON AFFECT WELDABILITY OF STEELS?
In general as the carbon content increases the weldability (how easily welded) decreases. In other words the higher the carbon content the more likely special procedures such as preheating, interpass temperature control and postheating are necessary.
The following chart groups carbon content, typical uses and weldability.


Group
Content %
Typical usage
Weldability
Low carbon steel
0.15 Maximum
Welding electrodes, rivets and nails
softer easily formed shapes.
Excellent weldability with all processes usually no preheat interpass or postheat necessary
Mild steel Plain carbon
0.15 to 0.30
Plate, angle, and bar stock for general fabrication.  Mild steel accounts for a large segment of welded parts of Industry where good plasticity and ductility is required.


Readily weldable with all processes without preheat, interpass, or postheat except for very thick sections.
Medium carbon steel
0.30 to 0.50
Used for Machine parts, gears, and where parts may be hardened by heat treating.

 Parts may be readily welded with all process  if preheat, interpass temperature controls, and post heat recommendations are followed.
Use Low hydrogen Electrodes and appropriate filler wire.
Heat treating after welding may be applied
High carbon steels
0.50 To 1.0

Springs, Dies, Railroad Track, Many tools, Band saws, and Knives. Also used where a sharp edge is required.

Usually require preheat  interpass temperature control and postheat. Special heating and cooling procedures in a furnace such as normalizing may be required to restore the properties of the metal after welding. High carbon Electrodes designed for welding tool steels or the specific alloy are readily available from welding supply companies.

 
Note: As carbon increases steel toughness and welding precautions increase

WHAT TOOLS DO WELDERS TYPICALLY USE WHEN PREHEATING, INTERPASS TEMPERATURE CONTROL AND POSTHEATING RECOMMENDATIONS ARE MADE?

When sophisticated inspection tools, ovens, and furnaces are not required or used a welder may use an oxy-fuel torch and tempelsticks (tempilstik) to control preheating, interpass temperatures, and postheat. Tempilstiks are crayon like indicators made of materials that melt within 1% of their rated temperature. Mark the workpiece before heating begins. The dry opaque Tempilstik mark will change to a distinct melted mark when the temperature rating of the selected Tempilstik has been reached. Tempilstiks are available in a range of temperatures making them useful for controlling temperature fluctuations between multiple pass welds (interpass temperature) and for cooling parts.


 To slow the cooling rate of small parts welders use methods to keep the part warm and exclude air such as; burying in sand or some other medium, or wrapping in a fire retardant blanket.
 

         


 HOW ARE STEELS CLASSIFIED?

 The American Iron and Steel Institute (AISI) and the Society Of Automotive Engineers (SAE) use a four or five digit numbering system to classify steels by chemical composition. The first digit indicates the type of steel, the second digit indicates the approximate percentage of the main alloying element, and the last two or three digits indicate the average carbon content. For example; in the case of the widely used 1020 steel, the first digit indicates carbon steel the second digit indicates no predominant alloy other than carbon and the last two digits indicate .20 carbon content.

The following shows some of the AISI SAE series designations of steel with xx representing the range of carbon content for the group.


SERIES DESIGNATION
TYPE OF STEEL
Carbon Steels

10xx
Plain Carbon
11xx
Machining Resulferized
12xx
Machining Resulferized Phospherized
Manganese Steels

13xx
Manganese 1.75
Nickel Steels

31xx
Nickel 3.5
25xx
Nickel 5.0
Nickel Chromium Steels

31xx
Nickel 1.25 Chromium 0.60
32xx
Nickel 1.75 Chromium 1.00
33xx
Nickel 3.5 Chromium 1.5
34xx
Nickel 3.0 Chromium 0.77
Molybdenum Steels

40xx
Molybdenum Carbon
41xx
Molybdenum Chromium
43xx
Molybdenum Nickel Chromium
Nickel  Chromium Molybdenum Steels

43xx
Nickel  Chromium Molybdenum
Nickel Molybdenum Steels

46xx
Nickel Molybdenum
48xx
Nickel Molybdenum
Chromium Steels

50xx
Chromium
51xx
Chromium

As shown by the above chart the first group of steels are the Carbon steels. The other groups of steels have additional elements ( alloys) added to enhance their properties in some specific way.

HOW DOES THE ADDITIONAL ELEMENTS IN THE ABOVE CHART AFFECT THE STEEL AND WELDABILITY?

Low alloy steels are Carbon steels that have additional elements added (alloyed) to produce a classification of steel that has a specific benefit for production use. Although Carbon is the main alloy that affects hardenability and weldability other elements also harden steel and play a role in the weldability of steel. For example Manganese and Molybdenum aid in hardening steels. For this reason a formula may be applied to a classification of steel to roughly determine the hardenability and hence the weldability and need for pre-heating. One example of a formula is shown below.

 Carbon equivalent for alloy steels

CE = % C + %Mn + Ni + Cr + Mo + V
                            6       15     6        4       5

CE = Carbon Equivalent
 C = Carbon
Mn = Manganese
Ni = Nickel
Cr = Chromium
Mo = Molybdenum
V = Vanadium

 Manganese
Manganese is used to harden steels and increase its toughness and strength. High manganese content coupled with increased carbon content lowers the ductility and weldability. Consideration of preheat and or postheat techniques usually apply.

Molybdenum
May be used in conjunction with other elements to aid in hardening and provide steel with good strength at elevated temperatures. Preheating may be required for welding and they are often heat treated after welding.

 Nickel
Nickel may be used to Increase toughness and impact strength and improve corrosion resistance. Good strength and ductility may be obtained even with lower carbon content. Depending on the amount added special procedures may be necessary when welding.

Chromium
Chromium helps improve the hardenability of steels and improves wear resistance, heat resistance, and corrosion resistance. Depending on the amount added special procedures may be necessary when welding.
Chromium and Chromium Nickel are used in the production of Stainless Steel.

 The Strength and Mechanical properties of carbon and alloy steels may be changed or shaped for a specific application by heat treating in furnaces or ovens. When two pieces of metal are welded using any of the commonly used arc welding processes: Stick, Mig, Or Tig the metals and filler are heated to the melting temperature under the arc and allowed to solidify to form the weld.

HOW DOES THE WELDER KNOW HOW TO WELD A GIVEN STEEL STRUCTURE?

The best way for a welder to know how to weld a particular steel or steel classification is through the use of a Welding Procedure Specification (WPS).  A WPS is a written set of instructions (specifications) detailing the welding procedure, joint preparation, filler metal, current type and range as well as any required preheat, interpass temperature controls and postheat treatments. Whenever possible welders request and use a Welding Procedure Specification for the type and grade of metal they are welding.
A welding Procedure Specification is developed by engineering or inspection personnel using qualified welders to weld a specific type of metal and joint configuration that will be used on the job, while recording the welding parameters and variables. The completed joint is then tested in accordance with a specific Code or Standard. The resulting information is written on a form called a Procedure Qualification Record. The information from the Welding Procedure Qualification Record is used to write the Welding specification and as long as the procedure is carefully followed the resulting welded products will have the required strength characteristics.
Some companies that do not have a formal Welding Specification have through practical experience developed a set of instructions that the welder must follow to successfully weld the given project.
If no Welding Procedure is provided at a minimum the welder MUST know what the base metal is and find out if special precautions are necessary for welding.
There should always be some method of traceability for metals used to fabricate parts. Metals sections and shapes should be stamped color coded or made from known materials. There are ways to test unknown metals through appearance, magnetic properties or spark testing; however, these test are subjective and may not be reliable for all cases. When you can trace the material through purchase orders or metal identification you know or can find out how to weld it.


WHAT IS THE HEAT AFFECTED ZONE AND HOW DOES IT AFFECT WELDABILITY?

The heating and cooling action that occurs when welding is a form of heat treating in the localized area of the puddle and weld joint that may result in changes to the mechanical properties of the base metal and surrounding area. The area most affected by heating and cooling during welding is called the HEAT AFFECTED ZONE (HAZ)


THE HEAT AFFECTED ZONE

The heating and cooling rate of welding directly under the arc is from the melting temperature to normal temperatures and may occur relatively quickly or methods may be used to slow the cooling rate of the joint. These methods include postheating the weld area with an oxy-fuel torch, blanketing the weld area, or using a precise heating and cooling method in a furnace or industrial setting.
The more expensive and precise method of using a furnace under controlled conditions restores the mechanical properties of the weld joint and the surrounding base metal.
The area surrounding the joint is heated to various temperatures depending on the distance from the arc, the heat input of the process and the number of weld passes. This area is referred to as the Heat Affected Zone.


The grains structure in the melted weld area may form a desirable size and shape, while the grain structure of the surrounding heat affected area may change to a less desirable shape and size and may cause cracking when welding on medium or high carbon steels. Often when welding a hardenable steel the heat affected area can harden to undesirable levels, while welding an already hardened steel may result in a softened heat affected zone with loss of desired hardness.

The heat affected zone may also have locked in stresses that can lead to problems when the welded structure is in service. Some industries employ a heat treating process called stress relieving to relieve residual stresses due to working or welding the structure.

It is imperative to use the correct electrode for the application so that weld metal is compatible with the base metal and fewer changes occur due to the carbon or alloy content of the filler wire. Electrodes are available for welding tool steels and Cast iron.

When welding thick sections, medium carbon, high carbon, and high alloy steels check the recommended procedures for control of the heating and cooling rate

There are heat treating options such as annealing or normalizing that may be used to restore the grain structure of the welded piece.

When welding low carbon, mild steels and most low alloy steels the heat affected area does not change the properties of the metal enough to become a problem regardless of the cooling rate.

The heating and cooling that occurs in the heat affected area and surrounding metal may also lead to heat distortion of the parts being joined.

Procedures may be used before, during, and after welding to minimize distortion.

 WHAT IS HEAT DISTORTION?

Steel when heated increases in length, width, and thickness. The increase in unit length when a metal is heated one degree is called its coefficient of thermal expansion. I f a small square block of steel were heated evenly under ideal conditions it would expand with the heat and contract when cooling relatively evenly. When welding a piece of steel only the joint and surrounding area is heated and cooled. This cause uneven expansion and cooling and the piece begins to warp or distort. Uncontrolled Distortion may lead to a serious dimensional defect or lead to failure of the part. Steps may be taken before, during, and after welding to minimize or control the effects of heat distortion.

WHAT ARE SOME OF THE THINGS A WELDER CAN DO BEFORE WELDING TO LIMIT HEAT DISTORTION?

Joint Preparation
The joint should be planned and prepared to limit the amount of weld and weld passes. For example: Wide angle V grooves welded from one side would distort more than double V grooves welded from both sides.
Select the proper Equipment
Higher welding speeds using iron powder electrodes (E-7018) and larger diameters may reduce the amount and effect of heat distortion. Semi-automatic and fully automatic welding processes limit the heat input and distortion.

Use Clamps Jigs and Fixtures
Jigs and fixtures with clamps hold parts in alignment and reduce the free movement of parts from heat expansion. The clamps are left in place until the parts are welded and cooled. In addition to clamps pieces called stiffeners may be temporarily added to areas that tend to distort and removed when the part cools.





WHAT ARE SOME OF THE THINGS A WELDER CAN DO DURING WELDING TO LIMIT HEAT DISTORTION?

Sequencing Welding
Use a skip or backstep method of welding to distribute the heat around the joint. This involves making shorter welds at different locations of the joint then joining them together. 




 Welding the joint
If possible two welders weld opposite sides of the joint at the same time.

Use the smallest size fillet welds practical to reduce heat input.

If solid welding is not necessary for strength use intermittent welding and stagger the sequence.

 


Weld flat or horizontal positions with larger size electrodes that allow for more weld deposit at faster speeds whenever practical. Vertical positions and multiple pass welds result in more heat input.

CONTROL OF DISTORTION AFTER WELDING

Distortion is more difficult to control after welding. Techniques like alternating heating and cooling to remove warpage called straightening require a degree of skill and practice. Postheating to remove stresses and warpage in controlled environments such as normalizing and annealing, often involving the use of furnaces is usually done by qualified personnel.

SUMMARY
Although the vast majority of carbon steels used in fabricating parts are mild steel or low carbon and presents little difficulty in welding, some carbon steels that have more carbon such as tool steels, high alloy steels and cast Iron require special procedures to prevent cracking and weld failure.  The welder should know the type of steel he is asked to weld to prevent problems that may lead to questions of his or her ability. If you are unsure ask questions and research the type of steel and its weldability.

Source: http://deltaschooloftrades.com

How to weld stainless steel, Metals and Properties of Stainless Steels

How to weld stainless steel
If you want to weld stainless steel, there are few things you should know. First, stainless steel is not one metal, but a family of metals. An outer layer of chromium oxide makes them resistant to rust. They also come in different thicknesses. You have to know exactly what type of stainless steel you are dealing with before you start. Secondly, stainless steel is harder to weld than other metals because it warps and distorts under high heat. This can affect its strength and appearance. Electric arc welding is used, but there are several different kinds, so you must know which one is right for your project. The most common types for stainless steel welding are Stick (SMAW), Tig (GTAW) and Mig FCAW or GMAW.)
Tools and Materials Needed:
  • Welder
  • Welding rods (also called welding electrodes)
  • Safety glasses
  • Filter mask
  • Welding helmet
  • Leather gauntlet style welding gloves
  • Leather welding jacket
  • Jeans with no holes in them
  • Good, non-conductive leather shoes
Step 1 – Safety

As with any welding, safety is very important. Welding produces fumes, sparks, and smoke that can be harmful. Don't skimp on your safety equipment, you might regret it. Make sure there is nothing flammable in the area. Look for pools of oil, scraps, rags, anything that could ignite. Make sure there is proper ventilation. Don't start until you completely understand your equipment.

Step 2 - Plan Ahead

Be sure that your pieces of stainless steel fit well before you start. Make sure the metal surfaces are clean. Plan which type of weld you are going to use. The five basic types are butt, corner, edge, lap & t. To prevent heat damage, clamp a piece of brass or aluminum behind the weld. This acts as a heat sink, so the steel doesn't overheat. Read and understand any instructions that came with the metal and the welder.

Step 3 – Practice

Just like getting to Carnegie Hall, it helps to practice before your big performance. Since stainless steel is trickier than other metals, even if you are an experienced welder you will want to try it on pieces you don't need before you do the real thing.

Step 4 – Weld

Make sure that the metal stays in place while welding. Use some kind of clamp or fixture if necessary. Stainless steel scratches easily, so don't let it move on a surface that will scratch it. Move the welding gun at a steady speed to keep it uniform. Keep your eye on the "puddle," the melted metal, to keep it under control. Be careful when you finish the weld to prevent the high heat from discoloring the steel.

Welding takes control and skill, so it's best to know what you are doing before you start the project. If you do it carefully and plan things out ahead of time, your project should look good and be useful and strong for many years.

Metals and Properties of Stainless Steels
Properties of Stainless Steel and some best practices for welding stainless steel to retain corrosion properties. 300 series and specifically 304 stainless is the most commonly welded stainless


Q: What is stainless steel?
A: Predominately Iron with 10.5% or more Chromium. Other elements such as nickel are sometimes added to achieve certain properties
Stainless steels are commonly divided into five groups:
*martensitic stainless steels
*ferritic stainless steels
*austenitic stainless steels
*duplex (ferritic-austenitic) stainless steel
*precipitation-hardening stainless steels

martensitic stainless steels
: the most common for types of martensitic stainless steels for aerospace usage are :410, Greek Ascoloy, Jethete
properties of stainless steels in the martensitic group are high strength and resist scaling and oxidation at elevated temperatures.
for knifemaking, the most popular martensitic grade is probably 440c. 440C can be hardened to 60 hrc
They are magnetic, hardenable by heat treatments, and are generally resistant to corrosion only to relatively mild environments. Chromium content is generally in the range of 10.5 to 18%, and carbon content may exceed 1.2%. The chromium and carbon contents are balanced to ensure a martensitic structure after hardening.
Ferritic stainless steels:are magnetic non heat-treatable steels that contain chromium but not nickel. 409, 430 , 436Common use: auto exhaust pipes
properties of stainless steels in the ferritic group ...not hardenable by heat treat and hold up well at elevated temperatures.
Austenitic stainless steels: Usually contain 17-20 % Chromium, and 7-12% Nickel. (18/8)Non heat treatable300 series is most common, 301, 303, 304, 321, 347
304 is the most widely used and is what you see in restaurants, on boats, pool ladders, etc.
properties of stainless steels in the austenitic group ...corrosion resistant, not hardenable by heat treat. very weldable.

Duplex (ferritic-austenitic) stainless steel
Has a combination of the properties of ferritic and Austenitic stainless steels. Widely used 2205 duplex SS contains 22% Cr and 5% Ni
Precipitation-hardening stainless steels:
Some contain as much as 1.5% Al which make them more difficult to weld.
17-4PH - easy 17-7PH - difficult
13-8MO - difficult
15-5 - easy
15-7MO - difficult
properties of stainless in the ph grades...much stronger than austenitic while still corrosion resistant.
Break it down!!!!!!!!
Hardenable stainless steels-martensitic, precipitation hardenable 410, Greek Ascoloy, Jethete, 13-8, 15-5, 15-7, 17-4, 17-7, A286
Non-hardenable,
ferritic grades like 409, 430, - 300 series......301,304, 321, 347,
300 Series stainless steels are among the most widely used stainless steels. They are classified as austenitic, and are hardenable only by cold working methods. These grades of stainless have chromium (approx. 18 to 30%) and nickel (approx. 6 to 20%) as their major alloying additions. Type 304 (also known as 18-8) is the most widely used alloy of all stainless steels.
301An austenitic stainless steel. The high strength of this grade of steel in the six available conditions or tempers, its resistance to atmosphere corrosion and its bright, attractive surface make it an excellent choice for decorative structural applications in the
Architectural, Automotive, Transportation, and Food Industries.
Strength of 301 work hardenable stainless steel
Condition Ksi
Annealed 75 1/4 Hard 125 1/2 Hard 150 3/4 Hard 175 Full Hard 185
301 ssAnnealing Temperature1850-2050°F
what does welding do to it??
welding will remove the work hardening effects.
303 ssA non-magnetic austenitic stainless steel specifically designed to exhibit improved machinability.
Can we weld it????
303 is not recommended for welding because of the sulfur that is added to improve machinability.
Sulfur causes cracking in most welds.
303 can be welded using special filler metals and techniques that minimize dilution and heat input. (but only for low stress non-critical applications)
304L
Chromium-Nickel austenitic alloy. Used for a wide variety of applications, this is one of the most familiar and most frequently used alloys in the stainless steel family.
Applications:
Food and beverage, Pulp and Paper, Chemical Processing, Transportation, Automotive
321 and 347 stainless
Stabilized stainless steels which offers an excellent resistance to intergranular corrosion following exposure to temperature in the chromium carbide precipitation range from 800 to 1500 Deg F.
What does stabilized mean??
stabilized stainless steels ...refers to additions of titanium or tantalum / columbium that binds up carbon or stabilizes carbon and prevents carbon from combining with chromium.
Applications; Aerospace, Refining, Automotive
AISI/SAE Stainless Steel Numbering System Alloy numbering systems vary greatly from one alloy group to the next. To help alleviate this problem the Unified Numbering System (UNS) for metals and alloys was developed.
To make things more complicated, hardly anyone uses this new numbering systemNUMBERING SYSTEMS;Oh well, so there is no simple numbering system!!!
Remember this:
300 series are approximately 18/8 Cr, Ni and are non heat treatable


400 series are mostly straight Cr (around 12%)
Grades like 17-4, 15-7 and anything with a PH behind it is heat treatable
300 series SS: food service industry
400 series (409 is most commonly used for auto exhaust)
Precipitation Hardening Stainless Steelscommon in aviation and aerospace welding...harden by extended time at elevated temperature
HARDENING MECHANISMS
300 series can only be work hardened and can not be hardened by heat treat
martensitic grades like 410 harden by reaching a transition temperature and then cooling quickly
precipitation hardening grades like 15-7 and 17-7 harden by reaching an aging temperature for a prescribed time period

Best practices
NEVER USE CARBON STEEL WIRE BRUSHES ON STAINLESS STEELMAKE SURE MATERIAL IS FREE OF CONTAMINANTS (OIL, PLASMA SPRAY, OXIDATION etc.)NEVER WELD WITHOUT BACKUP SHIELDING GASLIMIT HEAT INPUTANTICIPATE DISTORTIONUSE THE CORRECT FILLER ROD


More on welding 304 stainless steel

What are the properties of stainless steel ....and What makes Stainless Steel Stainless?
Chromium, Chrome, Cr...thats what.in order for a stainless steel to be called a stainless steel, it has to have more than 10% chromium.
first lets talk about the most common run of the mill stainless steel used all over the world.
304 stainless. 304 contains roughly 18% chromium, 8% nickel, and the rest is iron.its also known as one of the 300 series stainless steels, also known as 18/8 stainless.
Have you ever heard that stainless steel wont rust?
Well guess what? It will rust if not welded using the right methods,and it will get severe corrosion pits if exposed to certain environments. Especially if welded using the wrong methods.
What are the wrong methods?Here Are Some:
Using a Carbon Steel Wire Brush Or Wire Wheel
Using a Grinding Wheel That Has Been Used On Carbon Steel
Using a Wire Brush Or Wheel That Has Not Been Dedicated For Stainless Steel
Getting The Weld Too Hot And For Too Long
Too Much Oxidation In The Weld...( A Black Weld Can Be Sanded Smooth And Polished Shiny But That Does Not Change The Fact That It Got Hot And Oxidized)
Wrong Rod ( 308L Is The Preferred Rod For Welding 304 Stainless Steel...The L Is For Low Carbon)
Insufficient Shielding Gas
No Shielding Of The Back Side On A Full Penetration Weld
Abusive Grinding
Using A Carbon Steel Brush Or A Brush Or Grinding Wheel That Has Been Used On Carbon Steel Can Embed Carbon Or Iron Particles In The Stainless And Cause Rusting Later On
Getting The Weld Too Hot For Too Long Can Cause Rusting Later On Too.
Getting stainless too hot lets the chromium combine with carbon and that leaves areas depleted of chromium and chromium is the element that resists corrosion.
not shielding the back side of a weld with argon causes something called sugaring or granulation. Again the chromium can be depleted from the molten metal not being protected.
Another problem is all the pits and crevices in the sugared weld metal that are a natural place for corrosion to begin.
When you first learn to weld stainless steel, its easy to get some misconceptions.
Its easy to assume that mistakes made welding stainless can be undone and everything will be fine.
So you get a weld that is black instead of shiny. You just grind and polish and no one will ever know. right?
maybe, maybe not.
Welders who have years of experience know different. And I am not just talking about welding experience.
I am talking about experience being around the same welds for years after they have been put into service.
I have a friend who installs stainless steel piping for sanitary application and also does maintenance on the same plants he has piped in.He gets to see which welds rust later.He remembers when he had a purge problem or when he got a weld too hot.
It bites him squarely in the ass.
Review...
what are some of the properties of 304 stainless?
pretty good corrosion resistancenon magnetic ( unless severely cold worked)resists rustnot very thermally conductivemoderate strengthcan not be hardened by heat treatment exit properties of stainless steel and learn more about the tig finger heatshield.
Source: http://www.weldingtipsandtricks.com/properties-of-stainless-steel.html

 
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